Hostname: page-component-76fb5796d-wq484 Total loading time: 0 Render date: 2024-04-28T05:51:32.124Z Has data issue: false hasContentIssue false
  • English
  • Français

A review of the de novo domestication and cultivation of edible Australian native plants as food crops

Published online by Cambridge University Press:  22 February 2024

Nicholas Alexander George Open the ORCID record for Nicholas Alexander George [Opens in a new window] ,
Ranil Coorey ,
Kingsley Dixon  and
Sarita Jane Bennett
Nicholas Alexander George*
Affiliation:
School of Molecular and Life Sciences, Curtin University, Bentley, Perth, WA 6102, Australia
Ranil Coorey
Affiliation:
School of Molecular and Life Sciences, Curtin University, Bentley, Perth, WA 6102, Australia
Kingsley Dixon
Affiliation:
School of Molecular and Life Sciences, Curtin University, Bentley, Perth, WA 6102, Australia
Sarita Jane Bennett
Affiliation:
School of Molecular and Life Sciences, Curtin University, Bentley, Perth, WA 6102, Australia
*
Corresponding author: Nicholas Alexander George; Email: nicholas.george@curtin.edu.au
Rights & Permissions [Opens in a new window]

Abstract

Australia has a diverse and unique native flora with thousands of edible plant taxa, many of which are wild relatives of important food crops. These have the potential to diversify and improve the sustainability of Australian farming systems. However, the current level of domestication and cultivation of Australian plants as food crops is extremely limited by global standards. This review examines the current status and potential for future de novo domestication and large-scale cultivation of Australian plants as food crops. This is done in the context of international new crop development and factors that impact the success or failure of such efforts. Our review finds considerable potential for native Australian plants to be developed as food crops, but the industry faces several significant challenges. The current industry focuses on niche food markets that are susceptible to oversupply. It also suffers from inconsistent quantity and quality of product, which is attributed to a reliance on wild harvesting and the cultivation of unimproved germplasm. More active cultivation is necessary for industry growth, but attempts have historically failed due to poorly adapted germplasm and a lack of agronomic information. The de novo domestication and large-scale cultivation of Australian plants as food crops will require an investment in publicly supported multidisciplinary research and development programmes. Research programmes must prioritize the exploration of plants throughout Australia and the collection and evaluation of germplasm. Programmes must also seek to engage relevant stakeholders, pursue participatory research models and provide appropriate engagement and benefit-sharing opportunities with Indigenous Australian communities.

Keywords

agronomic researchbush tuckercrop domesticationgermplasm collectionnative foods
Type
Crops and Soils Review
Information
The Journal of Agricultural Science , Volume 161 , Issue 6 , December 2023 , pp. 778 - 793
Check for updates
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press

Introduction

Australia has a diverse and unique native flora, spanning major biome types from tropical to arid to alpine, with thousands of edible plant taxa, many of which are wild relatives of important global food crops. Over the last 40 years, individuals have argued for the domestication and cultivation of edible Australian plants as crops (e.g. Yen, Reference Yen1993; Considine, Reference Considine1996; Bell et al., Reference Bell, Bennett, Ryan and Clarke2011; Abdelghany et al., Reference Abdelghany, Wurm, Hoang and Bellairs2021; Drake et al., Reference Drake, Keitel and Pattison2021), yet, the commercial cultivation of Australian plants for food remains limited. The Macadamia nut (Macadamia integrifolia Maiden & Betche, M. tetraphylla L.A.S. Johnson, and their hybrids), native to coastal areas of the states of Queensland and New South Wales and domesticated in Hawaii from the 1920s, remains the only widely grown food crop endemic to the Australian continent (Shigeura and Ooka, Reference Shigeura and Ooka1984; Johnson and Burchett, Reference Johnson and Burchett1996).

The lack of domesticated native Australian food crops is surprising, given that multiple food crops have been derived from the native flora of every other inhabited continent (Stalker et al., Reference Stalker, Warburton and Harlan2021). However, the absence of native Australian domesticates should not imply a lack of suitability of Australian plants to become food crops. In this review, we argue that there is considerable potential for the de novo domestication and cultivation of Australian plants as food crops and that investing in such domestication and cultivation could assist in diversifying Australian farming systems, providing environmental and economic sustainability benefits (Lin, Reference Lin2011; Kahane et al., Reference Kahane, Hodgkin, Jaenicke, Hoogendoorn, Hermann, Keatinge, Hughes, Padulosi and Looney2013; Isbell et al., Reference Isbell, Adler, Eisenhauer, Fornara, Kimmel, Kremen, Letourneau, Liebman, Polley and Quijas2017; Burchfield et al., Reference Burchfield, Nelson and Spangler2019). We review the prior research and development of Australian native food plants in light of international new crop development efforts and the factors that impact the success or failure of these efforts. Constraints to developing native Australian crops and associated farming industries are identified, along with a framework for overcoming these constraints.

The need for greater crop diversity in Australian farming systems

Australia has around 60 million hectares of actively cultivated farmland (ABARES, 2022a). Around one-third of this area, predominantly in the continent's southwest, south and east, comprises monocultures of rainfed, annual grain crops (ABARES 2022a, 2022b). Three crops, wheat (Triticum aestivum L.), barley (Hordeum vulgare L.) and canola (Brassica napus L.), represent approximately 90% of the planted area (ABARES, 2022a, 2022b), and contribute significantly to globally traded staple foods and international food security (ABARES, 2022a, 2022b; FAOSTAT, 2022). These intensive, high-input, low-diversity monocultures of annual crops are not considered sustainable, given their negative environmental impacts and lack of resilience to disturbances such as climate change (FAO, 2017; Pretty et al., Reference Pretty, Benton, Bharucha, Dicks, Flora, Godfray, Goulson, Hartley, Lampkin and Morris2018). Lack of diversity in agricultural systems is not limited to Australia: globally, farming systems are underpinned by an increasingly limited number of major annual crop taxa, and global diets are becoming less diverse, which negatively impacts the resilience of global food systems (Khoury et al., Reference Khoury, Bjorkman, Dempewolf, Ramirez-Villegas, Guarino, Jarvis, Rieseberg and Struik2014; Martin et al., Reference Martin, Cadotte, Isaac, Milla, Vile and Violle2019; Bentham et al., Reference Bentham, Singh, Danaei, Green, Lin, Stevens, Farzadfar, Bennett, Di Cesare and Dangour2020).

Factors such as interannual weather variability, water insecurity, soil degradation and loss, ecosystem disturbance, pests and diseases pressure and changing global markets for agricultural commodities threaten the long-term viability of Australian agricultural systems, and such disturbances are likely to worsen in the future (Keating and Carberry, Reference Keating and Carberry2010; Cresswell et al., Reference Cresswell, Janke and Johnston2021). Climate change poses a particularly serious challenge. Productivity in Australian grain farming has already been negatively impacted by the aridification of previously mesic production environments (Sudmeyer et al., Reference Sudmeyer, Edward, Fazakerley, Simpkin and Foster2016; Hochman et al., Reference Hochman, Gobbett and Horan2017). It is predicted that Australian agricultural industries and the agricultural sector worldwide will need to make significant changes to agronomic management and species selection to adapt to future climatic conditions (Howden et al., Reference Howden, Gifford, Meinke, Stokes and Howden2010).

Increasing agrobiodiversity is a well-recognized strategy to improve the resilience and sustainability of agricultural systems (Jacobsen et al., Reference Jacobsen, Sørensen, Pedersen and Weiner2015; Isbell et al., Reference Isbell, Adler, Eisenhauer, Fornara, Kimmel, Kremen, Letourneau, Liebman, Polley and Quijas2017; Li et al., Reference Li, Stomph, Makowski, Li, Zhang, Zhang and van der Werf2023). Agrobiodiversity can be increased through the production of minor crops, the introduction of exotic crops or the de novo domestication of new taxa (Massawe et al., Reference Massawe, Mayes and Cheng2016; Toensmeier, Reference Toensmeier2016; Mustafa et al., Reference Mustafa, Mayes, Massawe, Sarkar, Sensarma and vanLoon2019; N'Danikou and Tchokponhoue, Reference N'Danikou, Tchokponhoue, Leal Filho, Azul, Brandli, Özuyar and Wall2019). De novo domestication means the domestication and cultivation of species with little or no prior history of domestication or cultivation. New species provide opportunities for diversification of farming systems and enable transformational changes required for long-term sustainability (Rickards and Howden, Reference Rickards and Howden2012; Petersen and Snapp, Reference Petersen and Snapp2015; Pretty et al., Reference Pretty, Benton, Bharucha, Dicks, Flora, Godfray, Goulson, Hartley, Lampkin and Morris2018). For example, the use of high-diversity agricultural systems which favour perennial species, termed perennial polycultures, is proposed as one strategy for increased agricultural sustainability (Brummer et al., Reference Brummer, Barber, Collier, Cox, Johnson, Murray, Olsen, Pratt and Thro2011; Iverson et al., Reference Iverson, Marín, Ennis, Gonthier, Connor-Barrie, Remfert, Cardinale and Perfecto2014; Toensmeier, Reference Toensmeier2016; Crews et al., Reference Crews, Carton and Olsson2018), but is difficult to achieve in Australia given existing crop species options (Hatton and Nulsen, Reference Hatton and Nulsen1999; Hobbs and O'Connor, Reference Hobbs and O'Connor1999; Pate and Bell, Reference Pate and Bell1999; Bell et al., Reference Bell, Wade and Ewing2010; Loomis, Reference Loomis2022). Native Australian food crops could potentially provide economically viable perennial species that are well-adapted to local production environments, making perennial polycultures more feasible (Shelef et al., Reference Shelef, Weisberg and Provenza2017).

Many of Australia's most economically important agricultural industries were developed only recently (Nelson and Hawthorne, Reference Nelson and Hawthorne2000; Salisbury et al., Reference Salisbury, Cowling and Potter2016). Nearly three-quarters of the total value of crop production in Australia from the 1950s to 1990s is derived from new crops and emerging agricultural industries (Fletcher, Reference Fletcher, Janick and Whipkey2002; Salvin et al., Reference Salvin, Bourke, Byrne and Byrne2004; Foster, Reference Foster2014). Along with diversification benefits, native Australian food crops could, therefore, also lead to new, economically valuable agricultural industries. Globally, many governments and organizations recognize the value of new crops and invest in developing new crop species to enable similar economic opportunities (Janick et al., Reference Janick, Blase, Johnson, Jolliff and Myers1996; Williams, Reference Williams2005; Foster, Reference Foster2014).

Can Australian flora be a source of new food crops?

Australia's native flora comprises approximately 20 000 recognized taxa of vascular land plants, around 85% of which are endemic (DEWR, 2007; Chapman, Reference Chapman2009; Broadhurst and Coates, Reference Broadhurst and Coates2017). Many individual taxa are known to be edible, with all plant food groups represented – cereals, pulses, nuts, roots and tubers, fruits and vegetables (Isaacs, Reference Isaacs1987; Low, Reference Low1991; Latz, Reference Latz1995; Bindon, Reference Bindon1996). Lists of edible native Australian plants have been compiled, derived predominately from records of plants traditionally eaten by Indigenous Australians (e.g. Isaacs, Reference Isaacs1987; Low, Reference Low1991; Latz, Reference Latz1995; Bindon, Reference Bindon1996; Hansen and Horsfall, Reference Hansen and Horsfall2019). Hansen and Horsfall (Reference Hansen and Horsfall2019) and Latz (Reference Latz1995) provide comprehensive and regionally specific lists. The former documents approximately 400 edible taxa in southwest Western Australia, and the latter documents 110 taxa in the central desert region. Southwestern Australia has approximately 8000 native vascular plant taxa (FloraBase, 2021), and the central desert 1500 (FloraNT, 2021; AVH, 2023), suggesting 5–7% of local plant species are edible. This is comparable to or slightly lower than global estimates, suggesting that 10–20% of local flora in temperate regions globally could be edible (Rapoport and Drausal, Reference Rapoport, Drausal and Scheiner2013).

Lists of edible species are likely incomplete due to the loss of traditional Indigenous knowledge following European colonization, a lack of comprehensive documentation, cultural preferences in plant use and differing definitions of ‘edible’ (Rapoport and Drausal, Reference Rapoport, Drausal and Scheiner2013). To illustrate this, southwestern Australia has 39 genera in the legume sub-family Faboideae, representing 500 currently named taxa, with many endemic (FloraBase, 2021). Central Australia has 41 genera representing 138 currently named taxa in Faboideae (FloraNT, 2021). Hansen and Horsfall (Reference Hansen and Horsfall2019) and Latz (Reference Latz1995) do not report the seed of these taxa as having been traditionally eaten, and there are no widely published reports of the seed of any Faboideae being eaten elsewhere in Australia. This is despite some taxa being crop wild relatives, such as Glycine Willd. and Vigna Savi. The seed composition of Australian Faboideae is not well studied, but anti-nutritional and potentially toxic compounds commonly occur in legumes (Tiwari et al., Reference Tiwari, Gowen and McKenna2011; Kumar et al., Reference Kumar, Basu, Goswami, Devi, Shivhare and Vishwakarma2022), and may have limited the traditional use of Australian taxa as food. Such compounds have been reduced or eliminated via appropriate food preparation techniques and breeding in domesticated legumes and could potentially be eliminated in Australian native legumes (Bell et al., Reference Bell, Bennett, Ryan and Clarke2011; Bohra et al., Reference Bohra, Tiwari, Kaur, Ganie, Raza, Roorkiwal, Mir, Fernie, Smýkal and Varshney2022; Zhang et al., Reference Zhang, Mascher, Abbo and Jayakodi2022). Many Australian Faboideae could, therefore, be considered ‘potentially edible’ and worth investigating for de novo domestication (Bell et al., Reference Bell, Bennett, Ryan and Clarke2011). Including even a small number of the Faboideae expands the edible proportion of Australian flora to the high end of global estimates (Rapoport and Drausal, Reference Rapoport, Drausal and Scheiner2013). This simple estimate illustrates how Australia could have 4000 or more plant species suitable for exploration as potential food crops.

What is the potential of edible Australian flora for producing new crops?

Various traits influence crop domestication potential, the specific traits favouring domestication vary between species and crop type (DeHaan et al., Reference DeHaan, Van Tassel, Anderson, Asselin, Barnes, Baute, Cattani, Culman, Dorn, Hulke, Kantar, Larson, Marks, Miller, Poland, Ravetta, Rude, Ryan, Wyse and Zhang2016; Fuller et al., Reference Fuller, Denham and Allaby2023), and some plant taxa are more straightforward to domesticate than others (DeHaan et al., Reference DeHaan, Van Tassel, Anderson, Asselin, Barnes, Baute, Cattani, Culman, Dorn, Hulke, Kantar, Larson, Marks, Miller, Poland, Ravetta, Rude, Ryan, Wyse and Zhang2016; Stalker et al., Reference Stalker, Warburton and Harlan2021). Given the diversity of edible plant taxa native to the continent, it seems probable that some Australian species will have a combination of traits favouring de novo domestication. The development and global success of the Macadamia nut industry illustrates that some Australian species have traits that make them suitable for domestication. Furthermore, related plant taxa have often been independently domesticated in geographically separate regions, most probably because these taxa share common traits favouring their domestication (Wang et al., Reference Wang, Yu, Haberer, Marri, Fan, Goicoechea, Zuccolo, Song, Kudrna and Ammiraju2014; Renny-Byfield et al., Reference Renny-Byfield, Page, Udall, Sanders, Peterson, Arick, Grover and Wendel2016; Wu et al., Reference Wu, Wang, Xu, Korban, Fei, Tao, Ming, Tai, Khan and Postman2018). At least 130 Australian taxa are crop wild relatives (Rapoport and Drausal, Reference Rapoport, Drausal and Scheiner2013; Norton et al., Reference Norton, Khoury, Sosa, Castañeda-Álvarez, Achicanoy and Sotelo2017), including species from Oryza L. (rice) (Henry, Reference Henry2019; Abdelghany et al., Reference Abdelghany, Wurm, Hoang and Bellairs2021), Sorghum (L.) Moench (Ananda et al., Reference Ananda, Myrans, Norton, Gleadow, Furtado and Henry2020), Vigna Savi (beans) (Lawn Reference Lawn, Redden, Yadav, Maxted, Dulloo, Guarino and Smith2015) and Glycine Willd. (soybean) (Hwang et al., Reference Hwang, Wei, Schroeder, Fickus, Quigley, Elia, Araya, Dong, Costa and Ferreira2019). As well as providing a genetic resource for associated breeding programmes of domestic crops (Henry, Reference Henry2023), such taxa are likely to share some traits that favoured their relatives’ domestication, increasing their potential for de novo domestication. This suggests that edible Australian flora has good potential for producing new crops.

An overview of the current Australian native food industry

Historical use of Australian plants as food by humans

Australia's edible native flora has been extensively utilized by people since their arrival on the continent some 65 000 years ago, although a debate about whether plant cultivation was practised on the Australian continent before European colonization is ongoing (Pascoe, Reference Pascoe2014; Keen Reference Keen2021; Sutton and Walshe, Reference Sutton and Walshe2021; Denham and Donohue, Reference Denham and Donohue2023). Plant domestication and cultivation, where plants have diverged morphologically and genetically from wild ancestors due to human selection and the reliance of human communities on these plants for most of their food intake, does not appear to have occurred in the Australian continent before the arrival of Europeans (Sutton and Walshe, Reference Sutton and Walshe2021). Plant domestication is a continuum, however, without a well-defined start and endpoint (Winterhalder and Kennett, Reference Winterhalder, Kennett, Kennett and Winterhalder2006; Meyer et al., Reference Meyer, DuVal and Jensen2012; Zeder, Reference Zeder2015; Stetter et al., Reference Stetter, Gates, Mei and Ross-Ibarra2017; Stalker et al., Reference Stalker, Warburton and Harlan2021; Fuller et al., Reference Fuller, Denham and Allaby2023). Some ‘early’ plant cultivation and domestication are not readily distinguished from other forms of plant exploitation, particularly in the archaeological record (Zeder, Reference Zeder2015; Denham and Donohue, Reference Denham and Donohue2023).

There is evidence for the intensive management and manipulation of Australian flora by people via practices such as the use of fire and the translocation of food plants (Hallam, Reference Hallam, Harris and Hillman1989; Bowman, Reference Bowman1998; Clarke, Reference Clarke2011; Ens et al., Reference Ens, Walsh, Clarke and Keith2017; Silcock, Reference Silcock2018; Lullfitz et al., Reference Lullfitz, Byrne, Knapp and Hopper2020a, Reference Lullfitz, Dabb, Reynolds, Knapp, Pettersen and Hopper2020b; Keen, Reference Keen2021; Fahey et al., Reference Fahey, Rossetto, Ens and Ford2022), and ‘non-agricultural’ cultures are also known to have engaged in ‘niche constructive’ behaviours that maintained or increased the productivity of their environments (Smith, Reference Smith2011; Anderson, Reference Anderson2013; Lightfoot et al., Reference Lightfoot, Cuthrell, Striplen and Hylkema2013; Thompson et al., Reference Thompson, Wright and Ivory2021a, Reference Thompson, Wright, Ivory, Choi, Nightingale, Mackay, Schilt, Otárola-Castillo, Mercader and Forman2021b). Such activities can result in lasting changes in the geographic distribution and genetic composition of plant taxa (Levis et al., Reference Levis, Costa, Bongers, Peña-Claros, Clement, Junqueira, Neves, Tamanaha, Figueiredo and Salomão2017; Coughlan and Nelson, Reference Coughlan and Nelson2018; Levis et al., Reference Levis, Flores, Moreira, Luize, Alves, Franco-Moraes, Lins, Konings, Peña-Claros and Bongers2018; Pavlik et al., Reference Pavlik, Louderback, Vernon, Yaworsky, Wilson, Clifford and Codding2021). This appears to have resulted in detectable changes in the genetics of some Australian taxa (Rangan et al., Reference Rangan, Bell, Baum, Fowler, McConvell, Saunders, Spronck, Kull and Murphy2015; Lullfitz et al., Reference Lullfitz, Byrne, Knapp and Hopper2020a, Reference Lullfitz, Dabb, Reynolds, Knapp, Pettersen and Hopper2020b) and may have also resulted in phenotypic changes. For example, it has been proposed that the large grain size in some native Australian Oryza may reflect human selection (Henry, Reference Henry2019). This may impact efforts to domestic Australian species as crops in the future.

Features of the current industry

The possibility of cultivating edible Australian plants as crops has been acknowledged for over a century (Maiden, Reference Maiden1889). However, the Australian ‘native foods industry’ did not commence until approximately the 1980s (Cherikoff and Brand, Reference Cherikoff and Brand1983; Brand-Miller and Cherikoff, Reference Brand-Miller and Cherikoff1985; Cherikoff and Brand, Reference Cherikoff and Brand1988). Commercial native food production now takes place in all Australian states and territories (Clarke, Reference Clarke2012; Sultanbawa and Sultanbawa, Reference Sultanbawa and Sultanbawa2016), but the current industry is small in terms of total production and economic value. Excluding Macadamia, total output was estimated to average only 8 tonnes in 2010 (Clarke, Reference Clarke2013), with a farm-gate value of $21 million in 2019 (Laurie, Reference Laurie2020), in comparison to the total gross value of Australian agriculture of $55 billion in 2015–16 (ABARES 2022a, 2022b).

Most of the production and economic value of the industry is represented by only 11 taxa (Table 1) (Clarke, Reference Clarke2013; Laurie, Reference Laurie2020). These came to dominate the industry through multiple ‘organic’ routes over four decades and are mainly used as ‘niche’ food additives or flavourants (i.e. herbs and spices) or are fruits that are processed into value-added products. Feedstock material used by the food industry is obtained from wild and cultivated sources (Clarke, Reference Clarke2013; Laurie, Reference Laurie2020). Most of the taxa are native to eastern and northern Australia's tropical, subtropical and oceanic climate zones (Fig. 1A), except for Solanum centrale (Fig. 1B), which grows in arid zones of Australia. Since the native ranges of the taxa do not overlap with the Australian grain production regions, these species offer little potential to diversify existing grain industries with locally adapted crops. Those taxa that do grow in the grain belt include Santalum acuminatum (Quandong) (Fig. 1C) and multiple species of Acacia (Table 1). Quandong is an obligate root hemiparasite that requires a host tree and produces a fleshy fruit with an edible nut (Ahmed and Johnson, Reference Ahmed and Johnson2000; Lee, Reference Lee2013). These traits give it limited potential for broadscale planting in grain-producing regions. Conversely, the various species of Acacia produce a grain legume (or pulse) and offer the prospect of large-scale planting for bulk food production (Ahmed and Johnson, Reference Ahmed and Johnson2000; Bartle et al., Reference Bartle, Cooper, Olsen and Carslake2002; Lee, Reference Lee2013). Aside from the taxa in Table 1, around 40 other Australian plant taxa are sold for food (Table 2) (CNFS, 2022; Tucker Bush, 2022). These represent a greater diversity of food types than the taxa in Table 1 and are native to a broader range of environments. However, the majority are native to eastern Australia and are used only as niche food additives.

Table 1. Plant taxa and their relatives that are the current focus of the Australian native food industry (Clarke, Reference Clarke2013; Laurie, Reference Laurie2020)

The approximate native range obtained from the Australasian Virtual Herbarium (AVH 2023).

WA, Western Australia; NT, Northern Territory; SA, South Australia; Qld, Queensland; NSW, New South Wales; Vic, Victoria; Tas, Tasmania; Af, Tropical rainforest; Am, Tropical monsoon; Aw, Tropic Savanna with dry winter; Bsh/Bsk, semi-arid hot; Bwh, arid hot; Cfa, humid sub-tropical; Cfb, oceanic; Csa, Mediterranean hot summer; Csb, Mediterranean warm summer; Cwa, dry-winter humid subtropical.

Figure 1. The maps in panels A–D show the distribution of taxa listed in Table 1. The maps are based on collection information from the Australian Virtual Herbarium (AVH 2023). The Australian grain production zone is shown in grey. The distribution of (a) Acronychia acidula and A. oblongifolia, Backhousia anisata (syn Syzygium anisatum) and B. citriodora, Citrus glauca (syn Eremocitrus glauca), C. australasica (syn Microcitrus australasica), Davidsonia jerseyana, D. johnsonii, D. pruriens, Kunzea pomifera, Tasmannia lanceolata and Terminalia ferdinandiana. (b) Solanum central; (c) Santalum acuminatum and S. spicatum, (d) Acacia victoriae; A. adsurgens; A. aneura; A. colei; A. coriacea; A. cowleana; A. kempeana; A. murrayana; A. tenuissim; A. pycnantha; A. retinodes; A. sophorae.

Table 2. The edible plant taxa sold by the Tuckerbush and Creative Native Food Service companies at the time of writing in 2023

WA, Western Australia, NT, Northern Territory, SA, South Australia, Qld, Queensland, NSW, New South Wales, Vic, Victoria, Tas, Tasmania.

Literature dating back to the late 1990s has examined the utilization of Australian native plants as food crops and the development of the native food industry. Authors have consistently concluded there is a good market potential for Australian food plants, especially those considered novel and with exceptional nutritional profiles (Cherikoff, Reference Cherikoff2000; Konczak et al., Reference Konczak, Zabaras, Dunstan, Aguas, Roulfe and Pavan2009; Clarke, Reference Clarke2012; Sultanbawa and Sultanbawa, Reference Sultanbawa and Sultanbawa2016; Birch et al., Reference Birch, Benkendorff, Liu and Luke2023). They also conclude that Australian plants offer valuable opportunities for diversifying the continent's agricultural systems with well-adapted new crops that can enhance environmental and economic sustainability (Considine, Reference Considine1996; Ahmed and Johnson, Reference Ahmed and Johnson2000; Bell et al., Reference Bell, Bennett, Ryan and Clarke2011; Abdelghany et al., Reference Abdelghany, Wurm, Hoang and Bellairs2021; Drake et al., Reference Drake, Keitel and Pattison2021; Canning, Reference Canning2022). However, the various authors have also identified significant challenges. The current emphasis on niche food markets makes them susceptible to oversupply (Clarke, Reference Clarke2012; Clarke, Reference Clarke2013), necessitating the development of new crops capable of supplying larger markets. The industry also grapples with inconsistent quantity and quality of supply, attributed mainly to a reliance on wild harvesting and the cultivation of unimproved germplasm, so there is a need for more active cultivation and the use of improved cultivars to address this problem (Stynes, Reference Stynes1997; Salvin et al., Reference Salvin, Bourke, Byrne and Byrne2004; Lee, Reference Lee2013; Abdelghany et al., Reference Abdelghany, Wurm, Hoang and Bellairs2021). Although some active cultivation efforts are underway, they face obstacles such as a lack of information on cultivation methods, challenges posed by pests and diseases and an overreliance on manual labour (Ahmed and Johnson, Reference Ahmed and Johnson2000; Clarke, Reference Clarke2012, Reference Clarke2013; Lee, Reference Lee2013; Sultanbawa and Sultanbawa, Reference Sultanbawa and Sultanbawa2016). To advance the industry, ongoing research is required, with a critical need for cultivar development, general agronomy and market development (Gorst, Reference Gorst2002; Salvin et al., Reference Salvin, Bourke, Byrne and Byrne2004; Lee and Six, Reference Lee and Six2010; Clarke, Reference Clarke2012, Reference Clarke2013; Sultanbawa and Sultanbawa, Reference Sultanbawa and Sultanbawa2016).

Research on individual taxa

To quantify the extent of research on individual taxa published in the 20 years between 2001 and 2021 (the time since the last scholarly review of the industry by Ahmed and Johnson, Reference Ahmed and Johnson2000), the Thomson Reuters Web of Science database was searched for publications in scholarly journals relating to the taxa in Table 1 and Table 2. We identified 234 research articles mentioning at least one of the taxa from Table 1 (Fig. 2). Acacia was excluded, given the large number of individual taxa in the genus, taxa found outside Australia and the non-food use of the species globally. No relevant published work was found for the taxa in Table 2. For comparison, the total research output for the taxa with the most published research is comparable to the Australian research output for minor crops like kiwifruit, with 41 papers (Actinidia), or Blueberry (Vaccinium), with 106 papers over the same period (ABARES, 2022a, 2022b). Publications covered by the Web of Science Core Collection are assigned to at least one subject area category. We found that the journal articles relating to the taxa mainly related to food sciences, chemistry or nutrition (Fig. 2). Papers addressing other areas relevant to the development of the industry, such as agronomy and genetics, represented only a quarter of all publications. Ahmed and Johnson (Reference Ahmed and Johnson2000) observed that most published research at the time of their review was focused on the compositional analysis of native food plants, and other critical areas were lacking. Our literature search shows this trend has continued, and whilst compositional analysis is essential for industry development, lack of research in other areas has likely contributed to the slow pace of industry development.

Figure 2. The number of scholarly journal articles in the Web of Science database that mention: (a) at least one of the plant taxa prioritized by the Australian native food industry (Table 1), published between 2001 and 2021. (b) The number of scholarly publications of Australian native species relating to individual Web of Science subject categories.

Agrifutures Australia, previously called the Rural Industries Research & Development Corporation (RIRDC), is a statutory authority established by the Australian Federal Government to support new and emerging industries. Since 2000, Agrifutures Australia has produced 43 reports dealing wholly or partly with different aspects of the Australian native foods industry (Agrifutures, 2022), but only one has been published since 2017 (Table 1). While agronomy and germplasm improvement are addressed more frequently than in the published literature, food science or compositional analyses remain the most common area of research (Fig. 3). Like the scientific literature, it is a relatively small number of publications for any individual taxon (Fig. 4).

Figure 3. The number of reports published by Agrifutures Australia that address subject matter relating to Australian native food plants.

Figure 4. The number of reports published by Agrifutures Australia that address the native food taxa.

Some individual edible taxa have had more concerted research aimed at their domestication as crops. Germplasm screening and selection, genetics and reproductive biology studies and some agronomy have been undertaken for Kunzea pomifera (Page, Reference Page2004; Page et al., Reference Page, Moore, Will and Halloran2006a, Reference Page, Moore, Will and Halloran2000b; Do et al., Reference Do, Panakera-Thorpe, Delaporte and Schultz2014, Reference Do, Delaporte, Pagay and Schultz2018a, Reference Do, Panakera-Thorpe, Delaporte, Croxford and Schultz2018b). Native Acacia have been the focus of development as a grain crop in Australia and elsewhere (Lister et al., Reference Lister, Holford, Haigh and Morrison1996; Maslin et al., Reference Maslin, Thomson, McDonald and Hamilton-Brown1998; Bartle et al., Reference Bartle, Cooper, Olsen and Carslake2002; Hele, Reference Hele2002; Rinaudo et al., Reference Rinaudo, Patel and Thomson2002; Midgley and Turnbull, Reference Midgley and Turnbull2003; Rinaudo and Cunningham, Reference Rinaudo and Cunningham2008). Native Australian legumes, aside from Acacia, have also been explored as pulses, with the examination of grain yield and seed composition (Rivett et al., Reference Rivett, Tucker and Jones1983; Bell et al., Reference Bell, Bennett, Ryan and Clarke2011; Ryan et al., Reference Ryan, Bell, Bennett, Collins and Clarke2011; Bell et al., Reference Bell, Ryan, Bennett, Collins and Clarke2012). Several commercial Citrus varieties have been developed by hybridizing Australian native Citrus spp. with domestic Citrus spp. (Sykes, Reference Sykes1997; Hele, Reference Hele2001; Agrifutures, 2017). Native Oryza spp. has been considered as source of germplasm for improving domestic rice, but germplasm collection and characterization and the systematic identification of research priorities have also taken place with the aim of de novo domestication (Henry et al., Reference Henry, Rice, Waters, Kasem, Ishikawa, Hao, Dillon, Crayn, Wing and Vaughan2010; Henry, Reference Henry2012; Henry, Reference Henry2019; Abdelghany et al., Reference Abdelghany, Wurm, Hoang and Bellairs2021). Germplasm screening (Davies et al., Reference Davies, Waugh and Lefory2005), genetic analysis (Shapter et al., Reference Shapter, Cross, Ablett, Malory, Chivers, King and Henry2013; Mitchell et al., Reference Mitchell, Stodart and Virgona2015) and commercialization of elite lines have been undertaken for Microlaena stipodes, a widespread native grass that produces an edible grain similar to rice (Chivers et al., Reference Chivers, Warrick, Bomman and Evans2015; Shapter and Chivers, Reference Shapter and Chivers2015). Several other grass species are also being actively investigated as potential grain crops (Khoddami et al., Reference Khoddami, Drake, Pattison, Craige, Badaoui, Keitel, Roth, Leung, Lee, Cross, Phillips and Bell2020; Drake et al., Reference Drake, Keitel and Pattison2021). Despite this research and development effort, a large-scale commercial agricultural industry has yet to develop for these taxa.

Indigenous engagement and benefit sharing

Australian plants can hold cultural and spiritual significance to people in the Indigenous Australian community (Clarke, Reference Clarke2011), but their engagement and benefit-sharing with the native foods industry has historically been limited (Considine, Reference Considine1996; Stynes, Reference Stynes1997; Ahmed and Johnson, Reference Ahmed and Johnson2000; Clarke, Reference Clarke2013; Lingard and Martin, Reference Lingard and Martin2016; Sultanbawa and Sultanbawa, Reference Sultanbawa and Sultanbawa2016; Drake et al., Reference Drake, Keitel and Pattison2021). ‘The Nagoya Protocol on Access to Genetic Resources and the Fair and Equitable Sharing of Benefits Arising from their Utilization’ aims to implement the access and benefits-sharing obligations of the International Convention on Biological Diversity (Lee, Reference Lee2013; Leha et al., Reference Leha, Cubillo and Janke2019; Sherman and Henry, Reference Sherman and Henry2020; Fyfe et al., Reference Fyfe, Smyth, Schirra, Rychlik and Sultanbawa2021). Australia ratified the Convention on Biological Diversity, and while it is not presently a participant in the Nagoya Protocol, current domestic measures purport to align with the principles outlined in the protocol (DCCEEW, 2021). However, others have found that traditional knowledge and intellectual property regarding edible native plants currently lack comprehensive legal protection in Australia or may not be adequately protected by existing laws (Leha et al., Reference Leha, Cubillo and Janke2019). Food is globally recognized as an intangible cultural heritage, eligible for special recognition and protection (Di Giovine and Brulotte, Reference Di Giovine, Brulotte, Brulotte and Di Giovine2016; Galanakis, Reference Galanakis2019). So even without clear intellectual property ownership or legal frameworks for protecting traditional biological knowledge, moral and ethical obligations remain for those seeking to develop native Australian food crops (Leha et al., Reference Leha, Cubillo and Janke2019; Jarvis et al., Reference Jarvis, Maclean and Woodward2021; Maclean et al., Reference Maclean, Woodward, Jarvis, Turpin, Rowland and Rist2022). Indigenous Australian support for developing native food industries is generally considered conditional on ensuring such industries recognize and respect culturally or spiritually significant plants, along with their traditional uses (NLE, 2022). Any research and development targeting Australian native food plants must, therefore, acknowledge the ongoing cultural connections of Indigenous Australian peoples with native flora and take steps to ensure Indigenous Australian communities have opportunities to engage, lead and benefit from the industry.

We believe current ambiguities around Indigenous Australian engagement and benefit sharing will likely hinder research and development activities, and this must be addressed if the industry is to develop. Firstly, even if legislation regarding intellectual property ownership and benefit-sharing is enacted, ownership of traditional knowledge and biological resources and appropriate avenues for benefit-sharing are often unclear. This is the case when information regarding taxa is well-documented, in the public domain, and has been so for a prolonged period. There is ambiguity in the Nagoya Protocol regarding historical germplasm collections and information (Sherman and Henry, Reference Sherman and Henry2020). Moreover, some edible plant taxa have wide native ranges spanning many Indigenous Australian communities, and under these circumstances, intellectual property ownership and appropriate benefit-sharing avenues are also unclear. Surveys of Indigenous Australian stakeholders have found that most respondents support the development of a native food industry (NLE, 2022). However, stakeholders still have divergent opinions about whether the commercial development of native food plants as crops should occur and what form the industry should take (Ahmed and Johnson, Reference Ahmed and Johnson2000; Clarke, Reference Clarke2013; Drake et al., Reference Drake, Keitel and Pattison2021). This makes it challenging to identify, engage and coordinate among owners of traditional biological knowledge and find consensus regarding the appropriate way to domesticate and cultivate some species.

The complexity of creating legal and ethical frameworks that both protect and allow the use of traditional ethnobotanical knowledge is a globally recognized problem, as is a lack of engagement and benefit sharing with traditional owners when commercializing traditional foods (Zimmerer and De Haan, Reference Zimmerer and De Haan2017; Antonelli, Reference Antonelli2023). A discussion of a possible framework for the ethical development of native Australian crops that can address the challenges described above is outside the scope of this review, but the challenges will act as a major obstacle to research and development activities, and nationally consistent legislation and best practice guidelines to address them are urgently needed.

What are the ways forward for native Australian food crops?

Six key areas stand out that would support the use of Australian native plants as food: (i) active cultivation; (ii) germplasm collection, characterization and improvement; (iii) basic research; (iv) sustained public funding of critical R&D; (v) greater diversity of food types and cultivation regions; (vi) engagement with Indigenous stakeholders and participatory approaches to research and (vii) consideration of the implications of domestication for conservation, and Indigenous traditional knowledge and use. These are discussed in detail below.

Active cultivation

Wild harvesting remains the primary source of material in the native food industry for many taxa. Wild harvests can provide economic returns to communities engaged in the collection and are attractive to those advocating for ‘ecological’ approaches to agribusiness industries (Ahmed and Johnson, Reference Ahmed and Johnson2000; Clarke, Reference Clarke2013; Lee, Reference Lee2013). However, wild harvesting is also associated with challenges such as inconsistent and unpredictable yields and product quality, limited supply, limited scope for expansion, high demand for labour and possible negative impacts on natural ecosystems (Miers, Reference Miers2004; RIRDC, 2008; Clarke, Reference Clarke2013; Sultanbawa and Sultanbawa, Reference Sultanbawa and Sultanbawa2016; Laurie, Reference Laurie2020). Additionally, wild harvesting is not risk-free for workers. For example, wild harvesting of native Oryza risks attack by saltwater crocodiles (Abdelghany et al., Reference Abdelghany, Wurm, Hoang and Bellairs2021). Consequently, although wild harvesting may be viable for specific regions and species, potentially augmented by ‘active management’ or ‘enrichment planting’ of otherwise wild plant communities (Lee and Courtenay, Reference Lee and Courtenay2016), industry growth will require active cultivation.

Germplasm collection, characterization and improvement

The wild phenotype of most, if not all, plant taxa is sub-optimal for commercial utilization (Wilson, Reference Wilson, Janick and Whipkey2007; Brummer et al., Reference Brummer, Barber, Collier, Cox, Johnson, Murray, Olsen, Pratt and Thro2011; DeHaan et al., Reference DeHaan, Van Tassel, Anderson, Asselin, Barnes, Baute, Cattani, Culman, Dorn, Hulke, Kantar, Larson, Marks, Miller, Poland, Ravetta, Rude, Ryan, Wyse and Zhang2016), and suboptimal germplasm is a significant obstacle to viable cultivation of edible Australian plants (Stynes, Reference Stynes1997; Salvin et al., Reference Salvin, Bourke, Byrne and Byrne2004; Lee, Reference Lee2013; Abdelghany et al., Reference Abdelghany, Wurm, Hoang and Bellairs2021). Germplasm screening and improvement will therefore be essential for the active cultivation of edible Australian plants to meet the needs of growers and consumers.

Even if wild taxa are identified that pose few challenges to de novo domestication, research and development will still be needed to address problematic traits (DeHaan et al., Reference DeHaan, Van Tassel, Anderson, Asselin, Barnes, Baute, Cattani, Culman, Dorn, Hulke, Kantar, Larson, Marks, Miller, Poland, Ravetta, Rude, Ryan, Wyse and Zhang2016; Toensmeier, Reference Toensmeier2016). Information regarding commercially important traits is unavailable for most Australian edible taxa, making it impossible to assess their potential as crops or to set research and development priorities. Furthermore, any available information often relates to germplasm of unknown provenance or collections with minimal genetic variation (e.g. see discussions in Sultanbawa and Sultanbawa (Reference Sultanbawa and Sultanbawa2016)). Many edible Australian taxa have broad distributions spanning a considerable range of climatic and edaphic conditions and display high genetic and morphological diversity, including variation in economically important traits (Davies et al., Reference Davies, Waugh and Lefory2005; Ariati et al., Reference Ariati, Murphy, Gardner and Ladiges2007; Mitchell et al., Reference Mitchell, Stodart and Virgona2015; Shapter and Chivers, Reference Shapter and Chivers2015; Broadhurst et al., Reference Broadhurst, Breed, Lowe, Bragg, Catullo, Coates, Encinas-Viso, Gellie, James and Krauss2017; Snowball et al., Reference Snowball, Norman and D'Antuono2021). Drawing conclusions regarding a species’ suitability for domestication from samples of minimal genetic diversity is, therefore, of limited value or even potentially misleading. For example, Ryan et al. (Reference Ryan, Bell, Bennett, Collins and Clarke2011) identified the representation of genetic diversity in germplasm collections and its evaluation under controlled conditions as a critical gap in assessments of Australian native pulses.

Assembling genetically diverse germplasm collections and then evaluating and selecting improved cultivars is an effective strategy for cultivar development, and remains an essential method for plant breeding globally (Murphy, Reference Murphy2007; Acquaah, Reference Acquaah, Al-Khayri, Jain and Johnson2015; Rebetzke et al., Reference Rebetzke, Ingvordsen, Bovill, Trethowan, Fletcher, Pratley and Kirkegaard2019), particularly for minor crops that lack resources for research and development (Jacobsen et al., Reference Jacobsen, Sørensen, Pedersen and Weiner2015). However, crop domestication initially involved, on average, the modification of only three major traits, which were controlled primarily by single genes (Meyer et al., Reference Meyer, DuVal and Jensen2012; Østerberg et al., Reference Østerberg, Xiang, Olsen, Edenbrandt, Vedel, Christiansen, Landes, Andersen, Pagh and Sandøe2017; Stetter et al., Reference Stetter, Gates, Mei and Ross-Ibarra2017). So, the use of molecular breeding techniques that target limited numbers of single gene traits to ‘mimic’ domestication events could increase the speed and efficiency of new crop development from Australian flora (Smýkal et al., Reference Smýkal, Nelson, Berger and Von Wettberg2018; Gasparini et al., Reference Gasparini, dos Reis Moreira, Peres and Zsögön2021; Luo et al., Reference Luo, Najafi, Correia, Trinh, Chapman, Østerberg, Thomsen, Pedas, Larson and Gao2022; Bartlett et al., Reference Bartlett, Moyers, Man, Subramaniam and Makunga2023; Henry, Reference Henry2023). Such approaches come with risks, though, including that a focus on single genes may over-simplify domestication or neglect the importance of agronomy and genotype-by-environment interactions in the crop phenotype (Passioura, Reference Passioura2020; Van Tassel et al., Reference Van Tassel, Tesdell, Schlautman, Rubin, DeHaan, Crews and Streit Krug2020; Bartlett et al., Reference Bartlett, Moyers, Man, Subramaniam and Makunga2023), and should therefore be used in conjunction with more traditional approaches. Centralized breeding may also not address the specific localized needs of growers (Fadda et al., Reference Fadda, Mengistu, Kidane, Dell'Acqua, Pè and Van Etten2020), or provide opportunities to engage with Indigenous communities (Bartlett et al., Reference Bartlett, Moyers, Man, Subramaniam and Makunga2023). Thus, we believe a range of strategies, including ‘traditional’ approaches in the early stages of crop development, genetic screening to ensure sufficient diversity and strategic investment in molecular breeding, are appropriate.

Germplasm collection and characterization must consider the historical use of taxa by people, which may have influenced the genetic diversity and geographic distribution of edible taxa. Taxa with high levels of anthropogenic translocation may show a lack of population genetic structure or a structure corresponding to human activity (Lullfitz et al., Reference Lullfitz, Byrne, Knapp and Hopper2020a, Reference Lullfitz, Dabb, Reynolds, Knapp, Pettersen and Hopper2020b). Therefore, phylogeographic patterns resulting from human translocation of food plants should be considered in germplasm collection documentation and activities. Plant populations from areas with intensive utilization could be targeted for germplasm collection because these populations may exhibit a higher frequency of individuals with useful genotypes. Further work is needed to investigate the anthropogenic influence on Australian plant genetics and phylogeographic patterns to inform germplasm collection, characterization and crop development activities.

Habitat loss due to clearing native vegetation for agriculture and subsequent land degradation has heavily impacted many ecosystems in Australia (Cresswell et al., Reference Cresswell, Janke and Johnston2021). As a result, the remaining native vegetation is often highly fragmented (Hobbs and Yates, Reference Hobbs and Yates2003; Hopper and Gioia, Reference Hopper and Gioia2004; Coates et al., Reference Coates, Byrne, Cochrane, Dunne, Gibson, Keighery, Lambers, Monks, Thiele, Yates and Lambers2014; Broadhurst and Coates, Reference Broadhurst and Coates2017), and faces ongoing pressure from pests, disease and climate change (Cresswell et al., Reference Cresswell, Janke and Johnston2021). Preservation of genetic diversity is essential for agricultural sustainability globally, as well as conservation efforts. Care must also be taken as the greater use of native plants as crops brings risks such as gene flow between domesticated and wild populations, posing potential threats to wild populations (Haygood et al., Reference Haygood, Ives and Andow2003), particularly if wild populations are small and highly fragmented.

The need for basic research

Poorly adapted germplasm, a lack of agronomic information and insufficient investment to address these issues are also commonly identified as significant obstacles to the growth and expansion of the Australian native food industry (Salvin et al., Reference Salvin, Bourke, Byrne and Byrne2004; Clarke, Reference Clarke2012; Clarke, Reference Clarke2013). Developing productive and economically viable farming systems in Australia and globally has relied on basic agricultural research (Hunt et al., Reference Hunt, Kirkegaard, Celestina, Porker, Pratley and Kirkegaard2019; Zaidi et al., Reference Zaidi, Vanderschuren, Qaim, Mahfouz, Kohli, Mansoor and Tester2019; Hunt et al., Reference Hunt, Kirkegaard, Harris, Porker, Rattey, Collins, Celestina, Cann, Hochman and Lilley2021). There is a need globally for more significant investment in basic research to increase agrobiodiversity and food security (Jacobsen et al., Reference Jacobsen, Sørensen, Pedersen and Weiner2015; Toensmeier, Reference Toensmeier2016), not just in Australia. Many wild plant taxa have been explored as potential crops (Janick, Reference Janick1996; Janick, Reference Janick and Janick1999; Janick and Whipkey, Reference Janick and Whipkey2002; Janick and Whipkey, Reference Janick and Whipkey2007), but few are now commercially viable and widely grown (DeHaan et al., Reference DeHaan, Van Tassel, Anderson, Asselin, Barnes, Baute, Cattani, Culman, Dorn, Hulke, Kantar, Larson, Marks, Miller, Poland, Ravetta, Rude, Ryan, Wyse and Zhang2016). A common issue is that basic research needed to understand and address problematic plant traits that inhibit economically viable production is missing, as is research to underpin commercially viable agronomy (Jolliff, Reference Jolliff, Janick and Simon1990; Blade and Slinkard, Reference Blade, Slinkard, Janick and Whipkey2002; Wilson, Reference Wilson, Janick and Whipkey2007; Abbo et al., Reference Abbo, van-Oss, Gopher, Saranga, Ofner and Peleg2014; DeHaan et al., Reference DeHaan, Van Tassel, Anderson, Asselin, Barnes, Baute, Cattani, Culman, Dorn, Hulke, Kantar, Larson, Marks, Miller, Poland, Ravetta, Rude, Ryan, Wyse and Zhang2016). Basic applied research will, therefore, be essential for developing the Australian native food industry.

The need for sustained public funding of R&D

Developing new crops and associated agricultural industries, particularly from undomesticated taxa, requires a sustained, long-term, and multidisciplinary research effort (Wollenweber et al., Reference Wollenweber, Porter and Lübberstedt2005; Runck et al., Reference Runck, Kantar, Jordan, Anderson, Wyse, Eckberg, Barnes, Lehman, DeHaan and Stupar2014; DeHaan et al., Reference DeHaan, Van Tassel, Anderson, Asselin, Barnes, Baute, Cattani, Culman, Dorn, Hulke, Kantar, Larson, Marks, Miller, Poland, Ravetta, Rude, Ryan, Wyse and Zhang2016). Successful new crop industries in Australia and elsewhere have relied on sustained public research investment in multi-decade and multi-disciplinary research programmes (Williams, Reference Williams2005; Collins and Norton, Reference Collins, Norton, Pratley and Kirkegaard2019; Pratley and Kirkegaard, Reference Pratley and Kirkegaard2019). This is illustrated by the introduction and development of canola (Brassica napus) (Colton and Potter, Reference Colton and Potter1999; Salisbury et al., Reference Salisbury, Cowling and Potter2016) and edible lines of lupins (Lupinus angustifolius) (Nelson and Hawthorne, Reference Nelson and Hawthorne2000). The successful development of native Australian crops will require similar research and development efforts. Public funding for such research work in Australia is relatively limited, unsustained or often non-existent and has also not attracted investment from private enterprises. This stands as a significant hurdle to the further development of the industry.

A possible funding and industry development model already exists in Australia in the form of the Research and Development Corporations (RDC). Supported partly by levies on producers, RDCs have brought demonstrable benefits to several agricultural industries (CRRDC, 2016). Agrifutures Australia is the RDC responsible for supporting research and industry development for edible Australian plants as part of a broader mandate to support new agricultural industries. However, it does not currently provide sustained funding of the sort needed for de novo domestication of food crops. Dedicating a specific RDC to native crop domestication could meet global calls for governments to support more diverse and locally adapted food systems built partly on non-conventional crops (Antonelli, Reference Antonelli2023). By administering research through national and regional RDC panels comprised of stakeholders, including members of the Indigenous Australian community, such a model could also provide a mechanism to address engagement and benefit-sharing challenges. When intellectual property ownership is complex, disputed or distributed, such a body could collect levies and administer a consolidated fund.

Greater diversity of food types and regions

The Australian native food industry is biased towards niche markets. Expanding the number of taxa under consideration to encompass more food types, such as grains or pulses, that can supply large-scale staple food markets and to include taxa adapted to a more diverse range of agroecosystems, particularly the grain production zones, will increase opportunities for large-scale native food production to diversify existing extensive agricultural industries. This necessitates research and development towards a more diverse range of edible species.

Participatory research approaches

Participatory germplasm improvement and agronomic research are increasingly common in Australia and globally (Walters et al., Reference Walters, Milne and Thompson2018; Snapp et al., Reference Snapp, DeDecker and Davis2019; Colley et al., Reference Colley, Dawson, McCluskey, Myers, Tracy and van Bueren2021; Lacoste et al., Reference Lacoste, Cook, McNee, Gale, Ingram, Bellon-Maurel, MacMillan, Sylvester-Bradley, Kindred, Bramley, Tremblay, Longchamps, Thompson, Ruiz, García, Maxwell, Griffin, Oberthür, Huyghe, Zhang, McNamara and Hall2022). Participatory research includes stakeholders in evaluating and selecting germplasm, developing research targets and conducting agronomic research to address industry constraints (Shelton et al., Reference Shelton, Tracy, Kapuscinski and Locke2016; Walters et al., Reference Walters, Milne and Thompson2018; Snapp et al., Reference Snapp, DeDecker and Davis2019; Lacoste et al., Reference Lacoste, Cook, McNee, Gale, Ingram, Bellon-Maurel, MacMillan, Sylvester-Bradley, Kindred, Bramley, Tremblay, Longchamps, Thompson, Ruiz, García, Maxwell, Griffin, Oberthür, Huyghe, Zhang, McNamara and Hall2022). Participatory breeding has been used successfully to improve the productivity and quality of crops in several regions, notably in some minor crops (Ceccarelli, Reference Ceccarelli2015; Shelton et al., Reference Shelton, Tracy, Kapuscinski and Locke2016; Ceccarelli and Grando, Reference Ceccarelli and Grando2020; Fadda et al., Reference Fadda, Mengistu, Kidane, Dell'Acqua, Pè and Van Etten2020). On-farm agronomic research can better understand and address complex genotype, management and environmental interactions (Rotili et al., Reference Rotili, de Voil, Eyre, Serafin, Aisthorpe, Maddonni and Rodríguez2020), identify industry needs, and encourage more rapid adoption of new crops and farming practices (Hunt et al., Reference Hunt, Kirkegaard, Celestina, Porker, Pratley and Kirkegaard2019). Participatory research can yield efficiencies in a stretched research funding environment, complement traditional research programmes and create additional avenues for engagement and empowerment of Australian Aboriginal communities.

Conclusions

There is considerable potential for the de novo domestication and cultivation of native Australian plants as food crops. Such crops could provide valuable new agricultural industries that increase the long-term sustainability of Australian agricultural systems and contribute to global food security. The primary impediment is inadequate funding and policy needed to underpin appropriate research and development, particularly basic cultivar development and agronomic research needed for active cultivation. Historically, successful new crop programmes show that developing native Australian food crops will require a sustained investment in publicly supported multidisciplinary research and development. This could happen through established Australian agricultural funding frameworks like the RDCs. Research and development activities must commence with collecting and evaluating a range of edible taxa, from throughout the continent, targeting species with the potential for large-scale staple food markets and adapted to a diverse range of agroecosystems. Finally, development programmes must also engage all relevant stakeholders and provide appropriate engagement and benefit-sharing opportunities with Indigenous communities.

Acknowledgements

We sincerely thank Dr Angela Pattison, The University of Sydney, and Professor Sally Thompson, The University of Western Australia, for providing comments on drafts of this review.

Author contributions

N. A. G. and K. D. conceived the review topic and N. A. G. researched and wrote the manuscript. S. J. B., R. C. and K. D. revised the manuscript and provided additional intellectual content.

Funding statement

This research did not receive any specific funding.

Competing interests

None.

Ethical standards

Not applicable.

References

ABARES (2022a) Australian commodity statistics 2020. Canberra, Australian Government. Australian Bureau of Agricultural and Resource Economics and Sciences (ABARES).Google Scholar
ABARES (2022b) Snapshot of Australian Agriculture 2022. ABARES Insights. Canberra, Australian Bureau of Agricultural and Resource Economics and Sciences 14.Google Scholar
Abbo, S, van-Oss, RP, Gopher, A, Saranga, Y, Ofner, I and Peleg, Z (2014) Plant domestication versus crop evolution: a conceptual framework for cereals and grain legumes. Trends in Plant Science 19, 351360.CrossRefGoogle ScholarPubMed
Abdelghany, G, Wurm, P, Hoang, LTM and Bellairs, SM (2021) Commercial cultivation of Australian wild Oryza spp.: a review and conceptual framework for future research needs. Agronomy 12, 42.CrossRefGoogle Scholar
Acquaah, G (2015) Conventional plant breeding principles and techniques. In Al-Khayri, JM, Jain, SM and Johnson, DV (Eds). Advances in Plant Breeding Strategies: Breeding, Biotechnology and Molecular Tools. Switzerland: Springer International Publishing, pp. 115158.CrossRefGoogle Scholar
Agrifutures (2017) Desert Lime, Agrifutures. Available at https://www.agrifutures.com.au/farm-diversity/desert-lime/Google Scholar
Agrifutures. (2022) “AgriFutures Australia. Available at https://www.agrifutures.com.au/”.Google Scholar
Ahmed, AK and Johnson, KA (2000) Horticultural development of Australian native edible plants. Australian Journal of Botany 48, 417426.CrossRefGoogle Scholar
Ananda, GK, Myrans, H, Norton, SL, Gleadow, R, Furtado, A and Henry, RJ (2020) Wild sorghum as a promising resource for crop improvement. Frontiers in Plant Science 11, 1108.CrossRefGoogle ScholarPubMed
Anderson, MK (2013) Tending the Wild: Native American Knowledge and the Management of California's Natural Resources. Berkeley, CA: University of California Press.Google Scholar
Antonelli, A (2023) Indigenous knowledge is key to sustainable food systems. Nature 613, 239242.CrossRefGoogle ScholarPubMed
Ariati, SR, Murphy, DJ, Gardner, S and Ladiges, PY (2007) Morphological and genetic variation within the widespread species Acacia victoriae (Mimosaceae). Australian Systematic Botany 20, 5462.CrossRefGoogle Scholar
AVH (2023, August 2023) The Australasian Virtual Herbarium, Council of Heads of Australasian Herbaria. Available at https://avh.chah.org.au.Google Scholar
Bartle, J, Cooper, D, Olsen, G and Carslake, J (2002) Acacia species as large-scale crop plants in the Western Australian wheatbelt. Conservation Science Western Australia 4, 96108.Google Scholar
Bartlett, ME, Moyers, BT, Man, J, Subramaniam, B and Makunga, NP (2023) The power and perils of de novo domestication using genome editing. Annual Reviews of Plant Biology 74, 727750.CrossRefGoogle ScholarPubMed
Bell, LW, Wade, LJ and Ewing, MA (2010) Perennial wheat: a review of environmental and agronomic prospects for development in Australia. Crop and Pasture Science 61, 679690.CrossRefGoogle Scholar
Bell, LW, Bennett, RG, Ryan, MH and Clarke, H (2011) The potential of herbaceous native Australian legumes as grain crops: a review. Renewable Agriculture and Food Systems 26, 7291.CrossRefGoogle Scholar
Bell, LW, Ryan, MH, Bennett, RG, Collins, MT and Clarke, HJ (2012) Growth, yield and seed composition of native Australian legumes with potential as grain crops. Journal of the Science of Food and Agriculture 92, 13541361.CrossRefGoogle ScholarPubMed
Bentham, J, Singh, GM, Danaei, G, Green, R, Lin, JK, Stevens, GA, Farzadfar, F, Bennett, JE, Di Cesare, M and Dangour, AD (2020) Multidimensional characterization of global food supply from 1961 to 2013. Nature food 1, 7075.CrossRefGoogle Scholar
Bindon, P (1996) Useful Bush Plants. Perth, WA.: Western Australian Museum.Google Scholar
Birch, J, Benkendorff, K, Liu, L and Luke, H (2023) The nutritional composition of Australian native grains used by First Nations people and their re-emergence for human health and sustainable food systems. Frontiers in Sustainable Food Systems 7, 1237862.CrossRefGoogle Scholar
Blade, SF and Slinkard, AE (2002) New crop development: the Canadian experience. In Janick, J and Whipkey, A (eds). Trends in New Crops and New Uses. Alexandria, VA: ASHS, pp. 6275.Google Scholar
Bohra, A, Tiwari, A, Kaur, P, Ganie, SA, Raza, A, Roorkiwal, M, Mir, RR, Fernie, AR, Smýkal, P and Varshney, RK (2022) The key to the future lies in the past: insights from grain legume domestication and improvement should inform future breeding strategies. Plant and Cell Physiology 63, 15541572.CrossRefGoogle Scholar
Bowman, DM (1998) The impact of Aboriginal landscape burning on the Australian biota. New Phytologist 140, 385410.CrossRefGoogle ScholarPubMed
Brand-Miller, JC and Cherikoff, V (1985) Australian Aboriginal bushfoods: the nutritional composition of plants from arid and semi-arid areas. Australian Aboriginal Studies 2, 3846.Google Scholar
Broadhurst, L and Coates, D (2017) Plant conservation in Australia: current directions and future challenges. Plant Diversity 39, 348356.CrossRefGoogle ScholarPubMed
Broadhurst, L, Breed, M, Lowe, A, Bragg, J, Catullo, R, Coates, D, Encinas-Viso, F, Gellie, N, James, E and Krauss, S (2017) Genetic diversity and structure of the Australian flora. Diversity and Distributions 23, 4152.CrossRefGoogle Scholar
Brummer, EC, Barber, WT, Collier, SM, Cox, TS, Johnson, R, Murray, SC, Olsen, RT, Pratt, RC and Thro, AM (2011) Plant breeding for harmony between agriculture and the environment. Frontiers in Ecology and the Environment 9, 561568.CrossRefGoogle Scholar
Burchfield, EK, Nelson, KS and Spangler, K (2019) The impact of agricultural landscape diversification on US crop production. Agriculture, Ecosystems & Environment 285, 106615.CrossRefGoogle Scholar
Canning, AD (2022) Rediscovering wild food to diversify production across Australia's agricultural landscapes. Frontiers in Sustainable Food Systems 6, 865580.CrossRefGoogle Scholar
Ceccarelli, S (2015) Efficiency of plant breeding. Crop Science 55, 8797.CrossRefGoogle Scholar
Ceccarelli, S and Grando, S (2020) Participatory plant breeding: who did it, who does it and where? Experimental Agriculture 56, 111.CrossRefGoogle Scholar
Chapman, AD (2009) Numbers of living species in Australia and the world. Report for the Australian Biological Resources Study. Canberra., The Australian Government Department of the Environment, Water, Heritage and the Arts.: 84.Google Scholar
Cherikoff, V (2000) Marketing the Australian native food industry. Rural Industries Research and Development Corporation (RIRDC) 39.Google Scholar
Cherikoff, V and Brand, J (1983) Nutrient composition of Aboriginal bush foods. Australian Aboriginal Studies 2, 7879.Google Scholar
Cherikoff, V and Brand, JC (1988) Is there a trend towards indigenous foods in Australia. Food habits in Australia: proceedings of the first Deakin/Sydney Universities symposium on Australian nutrition. A. S. Truswell and M. L. Wahlqvist. North Balwyn, Vic, University of Sydney. 178–183.Google Scholar
Chivers, I, Warrick, R, Bomman, J and Evans, C (2015) Native grasses make new products. A review of current and past uses and assessment of potential. Rural Industries Research and Development Corporation (RIRDC) 30.Google Scholar
Clarke, PA (2011) Aboriginal People and Their Plants. Kenthurst, N.S.W.: Rosenberg Publishing.Google Scholar
Clarke, M (2012) Australian native food industry stocktake. Rural Industries Research and Development Corporation (RIRDC) 89.Google Scholar
Clarke, M (2013) Native foods R&D priorities and strategies 2013–2018. Rural Industries Research and Development Corporation (RIRDC) 53.Google Scholar
CNFS (2022) Creative Native Food Service. Available at https://creativenativefoods.com.au/Google Scholar
Coates, D, Byrne, M, Cochrane, A, Dunne, C, Gibson, N, Keighery, G, Lambers, H, Monks, L, Thiele, K and Yates, C (2014) Conservation of the kwongan flora: threats and challenges. In Lambers, H (ed). Plant Life on the Sandplains in Southwest Australia, a Global Biodiversity Hotspot. Crawley, Western Australia: UWA Publishing, pp. 263284.Google Scholar
Colley, M, Dawson, J, McCluskey, C, Myers, J, Tracy, W and van Bueren, EL (2021) Exploring the emergence of participatory plant breeding in countries of the Global North – a review. The Journal of Agricultural Science 159, 320338.CrossRefGoogle Scholar
Collins, M and Norton, R (2019) Diversifying the cropping phase. In Pratley, JE and Kirkegaard, JA (eds). Australian Agriculture in 2020: From Conservation to Automation. Wagga Wagga, N.S.W.: Australian Society for Agronomy, pp. 307322.Google Scholar
Colton, B and Potter, T (1999) History. Canola in Australia – The First 30 Years. P. A. Salisbury, T. D. Potter, G. McDonald and A. G. Green, Organising Committee of 10th International Rapeseed Congress). Available at www.regional.org.au/au/gcirc/canola/: 1–4.Google Scholar
Considine, JA (1996) Emerging Indigenous Crops of Australia. Progress in New Crops. J. Janick. Alexandria, VA. ASHS Press: p. 26–36.Google Scholar
Coughlan, MR and Nelson, DR (2018) Influences of native American land use on the colonial Euro-American settlement of the South Carolina Piedmont. PLoS ONE 13, e0195036.10.1371/journal.pone.0195036CrossRefGoogle ScholarPubMed
Cresswell, I, Janke, T and Johnston, E (2021) Australia state of the environment 2021: overview, independent report to the Australian Government Minister for the Environment, Commonwealth of Australia, Canberra: 274.Google Scholar
Crews, TE, Carton, W and Olsson, L (2018) Is the future of agriculture perennial? Imperatives and opportunities to reinvent agriculture by shifting from annual monocultures to perennial polycultures. Global Sustainability 1, e11.CrossRefGoogle Scholar
CRRDC (2016) Cross-RDC Impact Assessment and Performance Reporting Update. Stage 1: Cross-RDC Impact Assessment for the Period 1 July 2009 to 30 June 2015 The Council of Rural Research and Development Corporations. Submitted by Agtrans Research, AgEconPlus, and EconSearch: 53.Google Scholar
Davies, CL, Waugh, DL and Lefory, EC (2005) Variation in seed yield and its components in the Australian native grass Microlaena stipoides as a guide to its potential as a perennial grain crop. Australian Journal of Agricultural Research 56, 309316.CrossRefGoogle Scholar
DCCEEW (2021) Australian Government Department of Climate Change, Energy, the Environment and Water. The Nagoya Protocol – Convention on Biological Diversity. Available at https://www.dcceew.gov.au/science-research/australias-biological-resources/nagoya-protocol-convention-biological (Jan 2024).Google Scholar
DeHaan, LR, Van Tassel, DL, Anderson, JA, Asselin, SR, Barnes, R, Baute, GJ, Cattani, DJ, Culman, SW, Dorn, KM, Hulke, BS, Kantar, M, Larson, S, Marks, MD, Miller, AJ, Poland, J, Ravetta, DA, Rude, E, Ryan, MR, Wyse, D and Zhang, X (2016) Pipeline strategy for grain crop domestication. Crop Science 56, 917930.CrossRefGoogle Scholar
Denham, T and Donohue, M (2023) Putting the Dark Emu debate into context. Archaeology in Oceania 58, 275295.CrossRefGoogle Scholar
DEWR (2007) Australia's native vegetation: a summary of Australia's major vegetation groups. Canberra, ACT, Australian Government. Department of the Environment and Water Resources.Google Scholar
Di Giovine, MA and Brulotte, RL (2016) Food and foodways as cultural heritage. In Brulotte, RL and Di Giovine, MA (eds). Edible Identities: Food as Cultural Heritage. London: Routledge, pp. 127.Google Scholar
Do, C, Panakera-Thorpe, L, Delaporte, K and Schultz, C (2014) Kunzea pomifera (muntries): selection validation and evaluation of important horticultural traits. XXIX International Horticultural Congress on Horticulture: Sustaining Lives, Livelihoods and Landscapes (IHC2014): II 1117.Google Scholar
Do, CM, Delaporte, KL, Pagay, V and Schultz, CJ (2018a) Salinity tolerance of muntries (Kunzea pomifera F. Muell.), a native food crop in Australia. HortScience 53, 15621569.CrossRefGoogle Scholar
Do, CM, Panakera-Thorpe, LC, Delaporte, KL, Croxford, AE and Schultz, CJ (2018b) Genic simple sequence repeat markers for measuring genetic diversity in a native food crop: a case study of Australian Kunzea pomifera F. Muell.(muntries). Genetic Resources and Crop Evolution 65, 917937.CrossRefGoogle Scholar
Drake, A, Keitel, C and Pattison, A (2021) The use of Australian native grains as a food: a review of research in a global grains context. The Rangeland Journal 43, 223233.CrossRefGoogle Scholar
Ens, E, Walsh, F and Clarke, P (2017) Aboriginal people and Australia's vegetation: past and current interactions. In Keith, DA (ed). Australian Vegetation. Cambridge, United Kingdom: Cambridge University Press, pp. 89112.Google Scholar
Fadda, C, Mengistu, DK, Kidane, YG, Dell'Acqua, M, , ME and Van Etten, J (2020) Integrating conventional and participatory crop improvement for smallholder agriculture using the Seeds for Needs Approach: a review. Frontiers in Plant Science 11, 559515.CrossRefGoogle ScholarPubMed
Fahey, M, Rossetto, M, Ens, E and Ford, A (2022) Genomic screening to identify food trees potentially dispersed by precolonial indigenous peoples. Genes 13, 476.CrossRefGoogle ScholarPubMed
FAO (2017) The Future of Food and Agriculture – Trends and Challenges. Rome: Food and Agriculture Organization of the United Nations, 180.Google Scholar
FAOSTAT (2022) http://faostat3.fao.org. Retrieved August 2022.Google Scholar
Fletcher, RJ (2002) International new crops development incentives, barriers, processes and progress: an Australian perspective. Trends in New Crops and New Uses. Janick, J. and Whipkey, A.. Alexandria, VA, ASHS: 15.Google Scholar
FloraBase (2021) FloraBase: the Western Australian Flora. Available at http://florabase.dec.wa.gov.au, The Western Australian Department of Environment and Conservation.Google Scholar
FloraNT (2021) FLoraNT. Northern Territory Flora Online. Available at http://eflora.nt.gov.au/, Northern Territory Government.Google Scholar
Foster, M (2014) Emerging animal and plant industries – their value to Australia, Rural Industries Research and Development Corporation (RIRDC) 194.Google Scholar
Fuller, DQ, Denham, T and Allaby, R (2023) Plant domestication and agricultural ecologies. Current Biology 33, R636R649.CrossRefGoogle ScholarPubMed
Fyfe, S, Smyth, HE, Schirra, HJ, Rychlik, M and Sultanbawa, Y (2021) The framework for responsible research with Australian native plant foods: a food chemist's perspective. Frontiers in Nutrition 8, 738627.CrossRefGoogle Scholar
Galanakis, CM (2019) Innovations in Traditional Foods. Duxford, United Kingdom: Woodhead Publishing.Google Scholar
Gasparini, K, dos Reis Moreira, J, Peres, LEP and Zsögön, A (2021) De novo domestication of wild species to create crops with increased resilience and nutritional value. Current Opinion in Plant Biology 60, 102006.CrossRefGoogle ScholarPubMed
Gorst, J (2002) Indigenous fruits of Australia. ISHS Acta Horticulturae 575: International Symposium on Tropical and Subtropical Fruits(575), 555–561.CrossRefGoogle Scholar
Hallam, S (1989) Plant usage and management in Southwest Australian Aboriginal societies. In Harris, DR and Hillman, G (eds). Foraging and Farming: The Evolution of Plant Exploitation. London: Unwin Hyman Ltd, pp. 136151.Google Scholar
Hansen, V and Horsfall, J (2019) Noongar Bush Tucker. Perth, WA: UWA Publishing.Google Scholar
Hatton, T and Nulsen, R (1999) Towards achieving functional ecosystem mimicry with respect to water cycling in southern Australian agriculture. Agroforestry Systems 45, 203214.CrossRefGoogle Scholar
Haygood, R, Ives, AR and Andow, DA (2003) Consequences of recurrent gene flow from crops to wild relatives. Proceedings of the Royal Society of London. Series B: Biological Sciences 270, 18791886.CrossRefGoogle ScholarPubMed
Hele, A (2001) Australian native citrus – wild species, cultivars and hybrids., Primary Industries and Resources South Australian Available at www.pir.sa.gov.au/factsheets: 7.Google Scholar
Hele, A (2002) Issues in the commercialisation of wattle seed for food. Conservation Science Western Australia 4, 181184.Google Scholar
Henry, RJ (2012) Next-generation sequencing for understanding and accelerating crop domestication. Briefings in Functional Genomics 11, 5156.CrossRefGoogle ScholarPubMed
Henry, R (2019) Australian wild rice populations: a key resource for global food security. Frontiers in Plant Science 10, 1354.CrossRefGoogle ScholarPubMed
Henry, RJ (2023) Genomic characterization supporting the development of new food and crop options from the Australian flora. Sustainable Food Technology 1, 337347.CrossRefGoogle Scholar
Henry, RJ, Rice, N, Waters, DL, Kasem, S, Ishikawa, R, Hao, Y, Dillon, S, Crayn, D, Wing, R and Vaughan, D (2010) Australian Oryza: utility and conservation. Rice 3, 235241.CrossRefGoogle Scholar
Hobbs, RJ and O'Connor, M (1999) Designing mimics from incomplete data sets: salmon gum woodland and heathland ecosystems in South West Australia. Agroforestry Systems 45, 365394.CrossRefGoogle Scholar
Hobbs, RJ and Yates, CJ (2003) Impacts of ecosystem fragmentation on plant populations: generalising the idiosyncratic. Australian Journal of Botany 51, 471488.CrossRefGoogle Scholar
Hochman, Z, Gobbett, DL and Horan, H (2017) Climate trends account for stalled wheat yields in Australia since 1990. Global Change Biology 23, 20712081.CrossRefGoogle ScholarPubMed
Hopper, SD and Gioia, P (2004) The southwest Australian floristic region: evolution and conservation of a global hot spot of biodiversity. Annual Review of Ecology, Evolution, and Systematics 35, 623650.CrossRefGoogle Scholar
Howden, SM, Gifford, RG and Meinke, H (2010) Grains. In Stokes, C and Howden, M (eds). Adapting Agriculture to Climate Change: Preparing Australian Agriculture, Forestry and Fisheries for the Future. Collingwood, Vic.: CSIRO publishing, pp. 3670.Google Scholar
Hunt, J, Kirkegaard, J, Celestina, C and Porker, K (2019) Transformational agronomy: restoring the role of agronomy in modern agricultural research. In Pratley, JE and Kirkegaard, J (eds), Australian Agriculture in 2020: From Conservation to Automation. Wagga Wagga, NSW, Australia: Agronomy Australia and Charles Sturt University, pp. 373388.Google Scholar
Hunt, JR, Kirkegaard, JA, Harris, FA, Porker, KD, Rattey, AR, Collins, MJ, Celestina, C, Cann, DJ, Hochman, Z and Lilley, JM (2021) Exploiting genotype×management interactions to increase rainfed crop production: a case study from south-eastern Australia. Journal of Experimental Botany 72, 51895207.CrossRefGoogle Scholar
Hwang, E-Y, Wei, H, Schroeder, SG, Fickus, EW, Quigley, CV, Elia, P, Araya, S, Dong, F, Costa, L and Ferreira, ME (2019) Genetic diversity and phylogenetic relationships of annual and perennial Glycine species. G3: Genes, Genomes, Genetics 9, 23252336.CrossRefGoogle ScholarPubMed
Isaacs, J (1987) Bush Food : Aboriginal Food and Herbal Medicine. McMahons Point, NSW: Weldon Publishing.Google Scholar
Isbell, F, Adler, PR, Eisenhauer, N, Fornara, D, Kimmel, K, Kremen, C, Letourneau, DK, Liebman, M, Polley, HW and Quijas, S (2017) Benefits of increasing plant diversity in sustainable agroecosystems. Journal of Ecology 105, 871879.CrossRefGoogle Scholar
Iverson, AL, Marín, LE, Ennis, KK, Gonthier, DJ, Connor-Barrie, BT, Remfert, JL, Cardinale, BJ and Perfecto, I (2014) Do polycultures promote win-wins or trade-offs in agricultural ecosystem services? A meta-analysis. Journal of Applied Ecology 51, 15931602.CrossRefGoogle Scholar
Jacobsen, S-E, Sørensen, M, Pedersen, SM and Weiner, J (2015) Using our agrobiodiversity: plant-based solutions to feed the world. Agronomy for Sustainable Development 35, 12171235.CrossRefGoogle Scholar
Janick, J (ed.) (1996) Progress in New Crops. Alexandria, VA: ASHS Press.Google Scholar
Janick, J (1999) New crops and the search for new food resources. In Janick, J (ed.), Perspectives on New Crops and New Uses. Alexandria, VA: ASHS Press, pp. 104110.Google Scholar
Janick, J and Whipkey, A (eds) (2002) Trends in New Crops and New Uses. Alexandria, VA: ASHS Press.Google Scholar
Janick, J and Whipkey, A (eds) (2007) Issues in New Crops and New Uses. Alexandria, VA: ASHS Press.Google Scholar
Janick, J, Blase, MG, Johnson, DL, Jolliff, GD and Myers, RL (1996) Diversifying U.S. crop production. CAST Issue Paper 6. Ames, Iowa., Council of Agric. Sci. and Tech. 98–109.Google Scholar
Jarvis, D, Maclean, K and Woodward, E (2021) The Australian Indigenous-led bush products sector: insights from the literature and recommendations for the future. Ambio 51, 226240.CrossRefGoogle ScholarPubMed
Johnson, K and Burchett, M (eds) (1996) Native Australian Plants: Horticulture and Uses. Sydney: UNSW Press.Google Scholar
Jolliff, GD (1990) Strategic planning for new-crop development. In Janick, J and Simon, JE (eds), Advances in New Crops. Portland, OR: Timber Press, pp. 2940.Google Scholar
Kahane, R, Hodgkin, T, Jaenicke, H, Hoogendoorn, C, Hermann, M, Keatinge, JDHD, Hughes, JdA, Padulosi, S and Looney, N (2013) Agrobiodiversity for food security, health and income. Agronomy for Sustainable Development 33, 671693.CrossRefGoogle Scholar
Keating, B and Carberry, P (2010) Emerging opportunities and challenges for Australian broadacre agriculture. Crop and Pasture Science 61, 269278.CrossRefGoogle Scholar
Keen, I (2021) Foragers or farmers: dark emu and the controversy over Aboriginal agriculture. Anthropological Forum 31, 106128.CrossRefGoogle Scholar
Khoddami, A, Drake, A, Pattison, A, Craige, C, Badaoui, C, Keitel, C, Roth, G, Leung, H, Lee, JH, Cross, R, Phillips, S and Bell, T (2020) Native Grains from Paddock to Plate. University of Sydney, Institute of Agriculture, 40.Google Scholar
Khoury, CK, Bjorkman, AD, Dempewolf, H, Ramirez-Villegas, J, Guarino, L, Jarvis, A, Rieseberg, LH and Struik, PC (2014) Increasing homogeneity in global food supplies and the implications for food security. Proceedings of the National Academy of Sciences 111, 40014006.CrossRefGoogle ScholarPubMed
Konczak, I, Zabaras, D, Dunstan, M, Aguas, P, Roulfe, P and Pavan, A (2009) Health benefits of Australian native foods – an evaluation of health-enhancing compounds, Rural Industries Research and Development Corporation (RIRDC) 52.Google Scholar
Kumar, Y, Basu, S, Goswami, D, Devi, M, Shivhare, US and Vishwakarma, RK (2022) Anti-nutritional compounds in pulses: implications and alleviation methods. Legume Science 4, e111.CrossRefGoogle Scholar
Lacoste, M, Cook, S, McNee, M, Gale, D, Ingram, J, Bellon-Maurel, V, MacMillan, T, Sylvester-Bradley, R, Kindred, D, Bramley, R, Tremblay, N, Longchamps, L, Thompson, L, Ruiz, J, García, FO, Maxwell, B, Griffin, T, Oberthür, T, Huyghe, C, Zhang, W, McNamara, J and Hall, A (2022) On-farm experimentation to transform global agriculture. Nature Food 3, 1118.CrossRefGoogle ScholarPubMed
Latz, P (1995) Bushfires and Bushtucker: Aboriginal Plant Use in Central Australia. Alice Springs, NT: IAD Press.Google Scholar
Laurie, S (2020) Australian native foods and botanicals – 2019/20 market study. Australian Native Foods and Botanicals. The University of Sydney. 56.Google Scholar
Lawn, RJ (2015) The Australian Vigna species: a case study in the collection and conservation of crop wild relatives. In Redden, RJ, Yadav, SS, Maxted, N, Dulloo, ME, Guarino, L and Smith, P (eds). Crop Wild Relatives and Climate Change. Hoboken, NJ: John Wiley & Sons, Incorporated, pp. 318355.CrossRefGoogle Scholar
Lee, LS (2013) Horticultural development of bush food plants and rights of Indigenous people as traditional custodians – the Australian bush tomato (Solanum centrale) example: a review. The Rangeland Journal 34, 359373.CrossRefGoogle Scholar
Lee, LS and Courtenay, K (2016) Enrichment plantings as a means of enhanced bush food and bush medicine plant production in remote arid regions: a review and status report. Learning Communities. International Journal of Learning in Social Contexts. Special Issue: Synthesis & Integration Writing Forum. R. Wallace, Charles Darwin University. The Cooperative Research Centre for Remote Economic Participation. Number 19: 64–75.CrossRefGoogle Scholar
Lee, JH and Six, J (2010) Effect of climate change on field crop production and greenhouse gas emissions in the California's Central Valley. Proceedings of the 19th World Congress of Soil Science: Soil solutions for a changing world. 1–6 August 2010. R. Gilkes and N. Prakongkep. Brisbane, Australia., Australian Society of Soil Science Inc.Google Scholar
Leha, D, Cubillo, C and Janke, T (2019) IP food for thought: intellectual property and protecting indigenous bush foods. Merinj Kaartdijn: Aboriginal Food Knowledge Forum. Albany, WA, 22 & 23 November 2019: 14.Google Scholar
Levis, C, Costa, FR, Bongers, F, Peña-Claros, M, Clement, CR, Junqueira, AB, Neves, EG, Tamanaha, EK, Figueiredo, FO and Salomão, RP (2017) Persistent effects of pre-Columbian plant domestication on Amazonian forest composition. Science 355, 925931.CrossRefGoogle ScholarPubMed
Levis, C, Flores, BM, Moreira, PA, Luize, BG, Alves, RP, Franco-Moraes, J, Lins, J, Konings, E, Peña-Claros, M and Bongers, F (2018) How people domesticated Amazonian forests. Frontiers in Ecology and Evolution 5, 171.CrossRefGoogle Scholar
Li, C, Stomph, T-J, Makowski, D, Li, H, Zhang, C, Zhang, F and van der Werf, W (2023) The productive performance of intercropping. Proceedings of the National Academy of Sciences 120, e2201886120.CrossRefGoogle ScholarPubMed
Lightfoot, KG, Cuthrell, RQ, Striplen, CJ and Hylkema, MG (2013) Rethinking the study of landscape management practices among hunter-gatherers in North America. American Antiquity 78, 285301.CrossRefGoogle Scholar
Lin, BB (2011) Resilience in agriculture through crop diversification: adaptive management for environmental change. BioScience 61, 183193.CrossRefGoogle Scholar
Lingard, K and Martin, P (2016) Strategies to support the interests of Aboriginal and Torres Strait Islander peoples in the commercial development of gourmet bush food products. International Journal of Cultural Property 23, 3370.CrossRefGoogle Scholar
Lister, PR, Holford, P, Haigh, T and Morrison, DA (1996) Acacia in Australia: ethnobotany and potential food crop. Progress in new crops. J. Janick. Alexandria, VA., ASHS Press: p. 228–236.Google Scholar
Loomis, RS (2022) Perils of production with perennial polycultures. Outlook on Agriculture 51, 2231.CrossRefGoogle Scholar
Low, T (1991) Wild Food Plants of Australia. North Ryde, N.S.W.: Angus and Robertson.Google Scholar
Lullfitz, A, Byrne, M, Knapp, L and Hopper, SD (2020a) Platysace (Apiaceae) of south-western Australia: silent story tellers of an ancient human landscape. Biological Journal of the Linnean Society 130, 6178.CrossRefGoogle Scholar
Lullfitz, A, Dabb, A, Reynolds, R, Knapp, L, Pettersen, C and Hopper, SD (2020b) Contemporary distribution of Macrozamia dyeri (Zamiaceae) is correlated with patterns of Nyungar occupation in south-east coastal Western Australia. Austral Ecology 45, 933947.CrossRefGoogle Scholar
Luo, G, Najafi, J, Correia, PM, Trinh, MDL, Chapman, EA, Østerberg, JT, Thomsen, HC, Pedas, PR, Larson, S and Gao, C (2022) Accelerated domestication of new crops: yield is key. Plant and Cell Physiology 63, 16241640.CrossRefGoogle ScholarPubMed
Maclean, K, Woodward, E, Jarvis, D, Turpin, G, Rowland, D and Rist, P (2022) Decolonising knowledge co-production: examining the role of positionality and partnerships to support Indigenous-led bush product enterprises in northern Australia. Sustainability Science 17, 333350.CrossRefGoogle Scholar
Maiden, JH (1889) The Useful Native Plants of Australia: (including Tasmania). Sydney, N.S.W.: Turner and Henderson.Google Scholar
Martin, AR, Cadotte, MW, Isaac, ME, Milla, R, Vile, D and Violle, C (2019) Regional and global shifts in crop diversity through the Anthropocene. PLoS ONE 14, e0209788.CrossRefGoogle ScholarPubMed
Maslin, BR, Thomson, LAJ, McDonald, BW and Hamilton-Brown, S (1998) Edible wattle seeds of Southern Australia. A review of species for use in semi-arid regions. Perth, Australia, CSIRO Australia.CrossRefGoogle Scholar
Massawe, F, Mayes, S and Cheng, A (2016) Crop diversity: an unexploited treasure trove for food security. Trends in Plant Science 21, 365368.CrossRefGoogle ScholarPubMed
Meyer, RS, DuVal, AE and Jensen, HR (2012) Patterns and processes in crop domestication: an historical review and quantitative analysis of 203 global food crops. New Phytologist 196, 2948.CrossRefGoogle ScholarPubMed
Midgley, S and Turnbull, J (2003) Domestication and use of Australian acacias: case studies of five important species. Australian Systematic Botany 16, 89102.CrossRefGoogle Scholar
Miers, G (2004) Cultivation and sustainable wild harvest of bushfoods by Aboriginal Communities in Central Australia, Rural Industries Research and Development Corporation (RIRDC) 79.Google Scholar
Mitchell, M, Stodart, B and Virgona, J (2015) Genetic diversity within a population of Microlaena stipoides, as revealed by AFLP markers. Australian Journal of Botany 62, 580586.CrossRefGoogle Scholar
Murphy, DJ (2007) People, Plants and Genes. New York: Oxford University Press.CrossRefGoogle Scholar
Mustafa, MA, Mayes, S and Massawe, F (2019) Crop diversification through a wider use of underutilised crops: a strategy to ensure food and nutrition security in the face of climate change. In Sarkar, A, Sensarma, S and vanLoon, G (eds), Sustainable Solutions for Food Security. Cham: Springer, pp. 125149.CrossRefGoogle Scholar
N'Danikou, S and Tchokponhoue, DA (2019) Plant domestication for enhanced food security. In Leal Filho, W, Azul, A, Brandli, L, Özuyar, P and Wall, T (eds). Zero Hunger. Encyclopedia of the UN Sustainable Development Goals. New York, NY: Springer, Cham, pp. 644654.Google Scholar
Nelson, P and Hawthorne, WA (2000) Development of lupins as a crop in Australia. Linking Research and Marketing Opportunities for Pulses in the 21st Century. Current Plant Science and Biotechnology in Agriculture, vol 34. K. R., Springer: 549–559.CrossRefGoogle Scholar
NLE (2022) Yoordaning-bah, Coming Together., Noongar Land Enterprise Group. Food Innovation Australia Ltd. (FIAL): 31.Google Scholar
Norton, SL, Khoury, CK, Sosa, CC, Castañeda-Álvarez, NP, Achicanoy, HA and Sotelo, S (2017) Priorities for enhancing the ex situ conservation and use of Australian crop wild relatives. Australian Journal of Botany 65, 638645.CrossRefGoogle Scholar
Østerberg, JT, Xiang, W, Olsen, LI, Edenbrandt, AK, Vedel, SE, Christiansen, A, Landes, X, Andersen, MM, Pagh, P and Sandøe, P (2017) Accelerating the domestication of new crops: feasibility and approaches. Trends in Plant Science 22, 373384.CrossRefGoogle ScholarPubMed
Page, T (2004) Muntries: The Domestication and Improvement of Kunzea Pomifera. Canberra, ACT: Rural Industries Research and Development Corporation, 95.Google Scholar
Page, T, Moore, G, Will, J and Halloran, G (2006a) Onset and duration of stigma receptivity in Kunzea pomifera (Myrtaceae). Australian Journal of Botany 54, 559563.CrossRefGoogle Scholar
Page, T, Moore, G, Will, J and Halloran, G (2006b) Pollen viability in Kunzea pomifera (Myrtaceae) as influenced by sucrose concentration and storage. Australian Journal of Botany 54, 553558.CrossRefGoogle Scholar
Pascoe, B (2014) Dark Emu Black Seeds: Agriculture or Accident?. Broome, Western Australia: Magabala Books.Google Scholar
Passioura, JB (2020) Translational research in agriculture. Can we do it better? Crop and Pasture Science 71, 517528.CrossRefGoogle Scholar
Pate, J and Bell, T (1999) Application of the ecosystem mimic concept to the species-rich Banksia woodlands of Western Australia. Agroforestry Systems 45, 303341.CrossRefGoogle Scholar
Pavlik, BM, Louderback, LA, Vernon, KB, Yaworsky, PM, Wilson, C, Clifford, A and Codding, BF (2021) Plant species richness at archaeological sites suggests ecological legacy of Indigenous subsistence on the Colorado Plateau. Proceedings of the National Academy of Sciences 118, e2025047118.CrossRefGoogle ScholarPubMed
Petersen, B and Snapp, S (2015) What is sustainable intensification? Views from experts. Land Use Policy 46, 110.CrossRefGoogle Scholar
Pratley, JE and Kirkegaard, J (eds) (2019) Australian Agriculture in 2020: from conservation to automation. Available at https://www.csu.edu.au/research/grahamcentre/publications/e-books/australian-agriculture-in-2020, Graham Center for Agricultural Innovation.Google Scholar
Pretty, J, Benton, TG, Bharucha, ZP, Dicks, LV, Flora, CB, Godfray, HCJ, Goulson, D, Hartley, S, Lampkin, N and Morris, C (2018) Global assessment of agricultural system redesign for sustainable intensification. Nature Sustainability 1, 441446.CrossRefGoogle Scholar
Rangan, H, Bell, KL, Baum, DA, Fowler, R, McConvell, P, Saunders, T, Spronck, S, Kull, CA and Murphy, DJ (2015) New genetic and linguistic analyses show ancient human influence on baobab evolution and distribution in Australia. PLoS ONE 10, e0119758.CrossRefGoogle ScholarPubMed
Rapoport, EH and Drausal, BS (2013) Edible plants. In Scheiner, SM (Ed), Encyclopedia of Biodiversity, Vol. 3. Minneapolis, MN: Elsevier, pp. 127132.CrossRefGoogle Scholar
Rebetzke, G, Ingvordsen, C, Bovill, W, Trethowan, R and Fletcher, A (2019) Breeding evolution for conservation agriculture. In Pratley, JE and Kirkegaard, JA (eds). Australian Agriculture in 2020: From Conservation to Automation. Wagga Wagga, N.S.W.: Australian Society for Agronomy, pp. 273287.Google Scholar
Renny-Byfield, S, Page, JT, Udall, JA, Sanders, WS, Peterson, DG, Arick, MA, Grover, CE and Wendel, JF (2016) Independent domestication of two old world cotton species. Genome Biology and Evolution 8, 19401947.CrossRefGoogle ScholarPubMed
Rickards, L and Howden, SM (2012) Transformational adaptation: agriculture and climate change. Crop and Pasture Science 63, 240250.CrossRefGoogle Scholar
Rinaudo, A and Cunningham, P (2008) Australian acacias as multi-purpose agro-forestry species for semi-arid regions of Africa. Muelleria 26, 7985.CrossRefGoogle Scholar
Rinaudo, A, Patel, P and Thomson, L (2002) Potential of Australian Acacias in combating hunger in semi-arid lands. Conservation Science Western Australia 4, 161169.Google Scholar
RIRDC (2008) Native foods R&D priorities and strategies 2007–2012. Rural Industries Research and Development Corporation (RIRDC) 24.Google Scholar
Rivett, D, Tucker, D and Jones, G (1983) The chemical composition of seeds from some Australian plants. Australian Journal of Agricultural Research 34, 427432.CrossRefGoogle Scholar
Rotili, DH, de Voil, P, Eyre, J, Serafin, L, Aisthorpe, D, Maddonni, and Rodríguez, D (2020) Untangling genotype x management interactions in multi-environment on-farm experimentation. Field Crops Research 255, 107900.CrossRefGoogle Scholar
Runck, BC, Kantar, MB, Jordan, NR, Anderson, JA, Wyse, DL, Eckberg, JO, Barnes, RJ, Lehman, CL, DeHaan, LR and Stupar, RM (2014) The reflective plant breeding paradigm: a robust system of germplasm development to support strategic diversification of agroecosystems. Crop Science 54, 19391948.CrossRefGoogle Scholar
Ryan, M, Bell, L, Bennett, R, Collins, M and Clarke, H (2011). Native legumes as a grain crop for diversification in Australia. Rural Industries Research and Development Corporation (RIRDC) 68.Google Scholar
Salisbury, PA, Cowling, WA and Potter, TD (2016) Continuing innovation in Australian canola breeding. Crop & Pasture Science 67, 266272.CrossRefGoogle Scholar
Salvin, S, Bourke, M, Byrne, AM and Byrne, T (eds) (2004) The New Crop Industries Handbook. Barton, ACT: Australian Government. Rural Industries Research and Development Corporation.Google Scholar
Shapter, FM and Chivers, I (2015) Commercialisation of elite lines of Microlaena stipoides as a perennial grain. Rural Industries Research and Development Corporation (RIRDC) 38.Google Scholar
Shapter, FM, Cross, M, Ablett, G, Malory, S, Chivers, IH, King, GJ and Henry, RJ (2013) High-throughput sequencing and mutagenesis to accelerate the domestication of Microlaena stipoides as a new food crop. PLoS ONE 8, e82641.CrossRefGoogle ScholarPubMed
Shelef, O, Weisberg, PJ and Provenza, FD (2017) The value of native plants and local production in an era of global agriculture. Frontiers in Plant Science 8, 2069.CrossRefGoogle Scholar
Shelton, AC, Tracy, WF, Kapuscinski, AR and Locke, KA (2016) Participatory plant breeding and organic agriculture: a synergistic model for organic variety development in the United States participatory plant breeding and organic agriculture: a synergistic model. Elementa: Science of the Anthropocene 4, 000143.Google Scholar
Sherman, B and Henry, RJ (2020) The Nagoya Protocol and historical collections of plants. Nature Plants 6, 430432.CrossRefGoogle ScholarPubMed
Shigeura, G and Ooka, H (1984) Macadamia Nuts in Hawaii: History and Production. Hawaii: University of Hawaii, 13.Google Scholar
Silcock, J (2018) Aboriginal translocations: the intentional propagation and dispersal of plants in Aboriginal Australia. Journal of Ethnobiology 38, 390405.CrossRefGoogle Scholar
Smith, BD (2011) General patterns of niche construction and the management of ‘wild'plant and animal resources by small-scale pre-industrial societies. Philosophical Transactions of the Royal Society B: Biological Sciences 366, 836848.CrossRefGoogle ScholarPubMed
Smýkal, P, Nelson, MN, Berger, JD and Von Wettberg, EJ (2018) The impact of genetic changes during crop domestication. Agronomy 8, 119.CrossRefGoogle Scholar
Snapp, SS, DeDecker, J and Davis, AS (2019) Farmer participatory research advances sustainable agriculture: lessons from Michigan and Malawi. Agronomy Journal 111, 26812691.CrossRefGoogle Scholar
Snowball, R, Norman, H and D'Antuono, M (2021) Investigation of two native Australian perennial forage legumes for their potential use in agriculture: Indigofera australis subsp. hesperia and Glycyrrhiza acanthocarpa. Crop and Pasture Science 72, 311323.CrossRefGoogle Scholar
Stalker, HT, Warburton, ML and Harlan, JR (2021) Harlan's Crops and Man: People, Plants and Their Domestication. Hoboken, NJ: John Wiley & Sons.CrossRefGoogle Scholar
Stetter, MG, Gates, DJ, Mei, W and Ross-Ibarra, J (2017) How to make a domesticate. Current Biology 27, R896R900.CrossRefGoogle ScholarPubMed
Stynes, B (1997) Opportunities for contributing to the development of Aboriginal food plants. Tropical Grasslands 31, 311314.Google Scholar
Sudmeyer, R, Edward, A, Fazakerley, V, Simpkin, L and Foster, I (2016) Climate Change: Impacts and Adaptation for Agriculture in Western Australia. Perth, Western Australia: Department of Agriculture and Food, 177.Google Scholar
Sultanbawa, Y and Sultanbawa, F (eds) (2016) Australian native plants: cultivation and uses in the health and food industries. In Traditional Herbal Medicines for Modern Times. Boca Raton, Florida: CRC Press, p. 409.Google Scholar
Sutton, P and Walshe, K (2021) Farmers or Hunter-Gatherers?: The Dark Emu Debate. Melbourne, V.c.: Melbourne Univ. Publishing.CrossRefGoogle Scholar
Sykes, S (1997) Australian native limes (Eremocitrus and Microcitrus); a citrus breeder's viewpoint. Australian Bush Foods Magazine 3, 1215.Google Scholar
Thompson, JC, Wright, DK and Ivory, SJ (2021a) The emergence and intensification of early hunter-gatherer niche construction. Evolutionary Anthropology: Issues, News, and Reviews 30, 1727.CrossRefGoogle ScholarPubMed
Thompson, JC, Wright, DK, Ivory, SJ, Choi, J-H, Nightingale, S, Mackay, A, Schilt, F, Otárola-Castillo, E, Mercader, J and Forman, SL (2021b) Early human impacts and ecosystem reorganization in southern-central Africa. Science Advances 7, eabf9776.CrossRefGoogle ScholarPubMed
Tiwari, BK, Gowen, A and McKenna, B (eds) (2011) Pulse Foods: Processing, Quality and Nutraceutical Applications. Sydney, N.S.W.: Academic Press.Google Scholar
Toensmeier, E (2016) The Carbon Farming Solution: A Global Toolkit of Perennial Crops and Regenerative Agriculture Practices for Climate Change Mitigation and Food Security. Chelsea, Vermont.: Chelsea Green Publishing.Google Scholar
Tucker Bush (2022) Tucker Bush. Edible Australian Tucker Bush Available at https://tuckerbush.com.au/about-us/Google Scholar
Van Tassel, DL, Tesdell, O, Schlautman, B, Rubin, MJ, DeHaan, LR, Crews, TE and Streit Krug, A (2020) New food crop domestication in the age of gene editing: genetic, agronomic and cultural change remain co-evolutionarily entangled. Frontiers in Plant Science 11, 789.CrossRefGoogle ScholarPubMed
Walters, J, Milne, R and Thompson, H (2018) Online farm trials: a national web-based information source for Australian grains research, development and extension. Rural Extension and Innovation Systems Journal 14, 117123.Google Scholar
Wang, M, Yu, Y, Haberer, G, Marri, PR, Fan, C, Goicoechea, JL, Zuccolo, A, Song, X, Kudrna, D and Ammiraju, JS (2014) The genome sequence of African rice (Oryza glaberrima) and evidence for independent domestication. Nature genetics 46, 982988.CrossRefGoogle ScholarPubMed
Williams, KA (2005) An overview of the US National Plant Germplasm System's exploration program. HortScience 40, 297301.CrossRefGoogle Scholar
Wilson, RF (2007) Strategies for narrowing the gap between R&D and commercialization of new crops. In Janick, J and Whipkey, A (eds), Issues in New Crops and New Uses. Alexandria, VA: ASHS Press, pp. 46.Google Scholar
Winterhalder, B and Kennett, DJ (2006) Behavioral ecology and the transition from hunting and gathering to agriculture. In Kennett, DJ and Winterhalder, B (eds), Behavioral Ecology and the Transition to Agriculture. Berkeley, CA: University of California Press, pp. 121.Google Scholar
Wollenweber, B, Porter, JR and Lübberstedt, T (2005) Need for multidisciplinary research towards a second green revolution. Current Opinion in Plant Biology 8, 337341.CrossRefGoogle ScholarPubMed
Wu, J, Wang, Y, Xu, J, Korban, SS, Fei, Z, Tao, S, Ming, R, Tai, S, Khan, AM and Postman, JD (2018) Diversification and independent domestication of Asian and European pears. Genome Biology 19, 116.CrossRefGoogle ScholarPubMed
Yen, DE (1993) The origins of subsistence agriculture in Oceania and the potentials for future tropical food crops. Economic Botany 47, 314.CrossRefGoogle Scholar
Zaidi, SS-e-A, Vanderschuren, H, Qaim, M, Mahfouz, MM, Kohli, A, Mansoor, S and Tester, M (2019) New plant breeding technologies for food security. Science 363, 13901391.CrossRefGoogle ScholarPubMed
Zeder, MA (2015) Core questions in domestication research. Proceedings of the National Academy of Sciences 112, 31913198.CrossRefGoogle ScholarPubMed
Zhang, H, Mascher, M, Abbo, S and Jayakodi, M (2022) Advancing grain legumes domestication and evolution studies with genomics. Plant and Cell Physiology 63, 15401553.CrossRefGoogle ScholarPubMed
Zimmerer, KS and De Haan, S (2017) Agrobiodiversity and a sustainable food future. Nature Plants 3, 13.CrossRefGoogle Scholar
Figure 0

Table 1. Plant taxa and their relatives that are the current focus of the Australian native food industry (Clarke, 2013; Laurie, 2020)

Figure 1

Figure 1. The maps in panels A–D show the distribution of taxa listed in Table 1. The maps are based on collection information from the Australian Virtual Herbarium (AVH 2023). The Australian grain production zone is shown in grey. The distribution of (a) Acronychia acidula and A. oblongifolia, Backhousia anisata (syn Syzygium anisatum) and B. citriodora, Citrus glauca (syn Eremocitrus glauca), C. australasica (syn Microcitrus australasica), Davidsonia jerseyana, D. johnsonii, D. pruriens, Kunzea pomifera, Tasmannia lanceolata and Terminalia ferdinandiana. (b) Solanum central; (c) Santalum acuminatum and S. spicatum, (d) Acacia victoriae; A. adsurgens; A. aneura; A. colei; A. coriacea; A. cowleana; A. kempeana; A. murrayana; A. tenuissim; A. pycnantha; A. retinodes; A. sophorae.

Figure 2

Table 2. The edible plant taxa sold by the Tuckerbush and Creative Native Food Service companies at the time of writing in 2023

Figure 3

Figure 2. The number of scholarly journal articles in the Web of Science database that mention: (a) at least one of the plant taxa prioritized by the Australian native food industry (Table 1), published between 2001 and 2021. (b) The number of scholarly publications of Australian native species relating to individual Web of Science subject categories.

Figure 4

Figure 3. The number of reports published by Agrifutures Australia that address subject matter relating to Australian native food plants.

Figure 5

Figure 4. The number of reports published by Agrifutures Australia that address the native food taxa.