Herbicide response and germination behavior of two goosegrass (Eleusine indica) populations in the Australian environment

Virender Singh Hooda; Bhagirath Singh Chauhan

doi:10.1017/wsc.2023.51

Herbicide response and germination behavior of two goosegrass (Eleusine indica) populations in the Australian environment

Published online by Cambridge University Press: 15 September 2023

Virender Singh Hooda and

Bhagirath Singh Chauhan

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Virender Singh Hooda: Affiliation:
Assistant Scientist, Department of Agronomy, College of Agriculture, Chaudhary Charan Singh Haryana Agricultural University (CCSHAU), Hisar, Haryana, India
Bhagirath Singh Chauhan*: Affiliation:
Professor, Queensland Alliance for Agriculture and Food Innovation (QAAFI) and School of Agriculture and Food Sustainability (AGFS), University of Queensland, Gatton, Queensland, Australia
*: Corresponding author: Bhagirath Singh Chauhan; Email: b.chauhan@uq.edu.au

Article contents

Abstract
Introduction
Materials and Methods
Results and Discussion
Footnotes
References

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Abstract

Goosegrass [Eleusine indica (L.) Gaertn.] is one of the most problematic grassy weeds in the world. It is considered to be an important weed in summer fallows and crops grown in the eastern region of Australia. To examine the seed germination ecology of two populations (Gatton and Ingham) of E. indica and their response to postemergence herbicides in Australian conditions, experiments were carried out in the laboratory and screenhouse. Seedling survival, spike production, and plant biomass of both E. indica populations declined markedly with the application of postemergence herbicides such as butroxydim, clethodim, glufosinate, haloxyfop, and propaquizafop, whereas the application of paraquat failed to control the Ingham population. A dose–response study verified the presence of paraquat resistance in the Ingham population. In this regard, it was observed that the paraquat doses required to achieve a 50% reduction in survival and plant biomass were 27 and 21 times greater in the Ingham population compared to the Gatton population, respectively. Higher alternating temperatures (35/25 and 30/20 C) resulted in greater germination of both populations than lower alternating temperatures (20/10 and 25/15 C). At 20/10 C, the Ingham population failed to germinate; however, about 15% germination in the Gatton population was observed. At the lowest alternate temperature range (15/5 C), neither population germinated. The germination of both populations of E. indica was severely reduced under completely dark conditions compared with the alternating light/dark period. Germination was more tolerant of salt and water stress in the Ingham population compared with the Gatton population. Eleusine indica seedling emergence was comparable among populations, and the greatest emergence (83%) was observed for seeds buried at a depth of 2 cm but then declined dramatically, and no seedlings emerged from an 8-cm burial depth. The information acquired from this study could be used in developing effective management strategies for E. indica.

Keywords

Burial depth germination herbicide light resistance salt stress temperature

Information

Type: Research Article
Information: Weed Science , Volume 71 , Issue 6 , November 2023 , pp. 584 - 593

DOI: https://doi.org/10.1017/wsc.2023.51 [Opens in a new window]
Creative Commons: 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: © The Author(s), 2023. Published by Cambridge University Press on behalf of the Weed Science Society of America

Introduction

Weed infestation is a pervasive problem that affects agricultural crop production systems worldwide. In Australia, weeds produce major economic, environmental, and social impacts by causing significant damage to natural landscapes, agricultural land, waterways, and coastal areas. Weeds cost Australian grain growers more than AU$3 billion yr⁻¹ (Llewellyn et al. Reference Llewellyn, Ronning, Ouzman, Walker, Mayfield and Clarke2016). This financial impact extends beyond just grain cultivation, affecting cotton (Gossypium hirsutum L.), sugarcane (Saccharum officinarum L.), fruit, and vegetable cultivation as well. Goosegrass [Eleusine indica (L.) Gaertn.] is a C₄ annual diploid grass species (2n = 18) of rainfed agriculture that can produce 140,000 seeds plant⁻¹ (Chin Reference Chin and Kwee1979). Considered native to Africa and Asia, it is currently distributed in warm and temperate areas worldwide, infesting cultivated land, plantation crops, vegetable farms, gardens, fallows, uncultivated land, and roadsides (Holm et al. Reference Holm, Plucknett, Pancho and Herberger1977). In all Australian states, E. indica is found in disturbed habitats within natural areas as well as on the margins of natural forests, grasslands, marshes, stream banks, and coastal areas (QDPIF 2011). Additionally, it is prevalent as a weed along pavements and power line corridors. Furthermore, this weed also acts as a secondary host for several nematodes and diseases of sugarcane, peanut (Arachis hypogaea L.), corn (Zea mays L.), and rice (Oryza sativa L.) (e.g., Bendixen Reference Bendixen, Noda and Mercado1986).

Herbicide applications are the method most frequently used to control weeds, and a number of weeds have evolved resistance to herbicides as a result. Herbicide resistance in weeds is not a recent phenomenon, but it is appears to be becoming more prevalent (Coble and Schroeder Reference Coble and Schroeder2016). Wild carrot (Daucus carota L.) was the first weed biotype that acquired resistance to 2,4-D (Switzer Reference Switzer1957), and then common groundsel (Senecio vulgaris L.) evolved resistance to triazine (Ryan Reference Ryan1970). Today, herbicide resistance has occurred in 267 weed species (154 dicotyledons and 113 monocotyledons) in 72 countries involving 21 of the 31 known herbicide sites of action and 165 different herbicides (Heap Reference Heap2023). More than 150 cases of herbicide resistance have been reported from Australia.

Eleusine indica has developed herbicide resistance to several herbicide modes of action used on both annual and perennial crops worldwide. Paraquat resistance in E. indica was first reported in Malaysia in 1990, while the first report of paraquat resistance in E. indica in Australia was in 2015 (Preston Reference Preston2019). The evolution of herbicide (e.g., clethodim, cyhalofop, fenoxaprop, glufosinate, glyphosate, imazapyr, metribuzin, pendimethalin, and trifluralin) resistance in E. indica is attributed to widespread herbicide applications across various global regions. This resistance phenomenon has been substantiated in many countries, including Argentina, Australia, Bolivia, Brazil, China, Colombia, Costa Rica, Indonesia, Italy, Japan, Malaysia, Mexico, and the United States (Heap Reference Heap2023).

Paraquat belongs to the bipyridylium family, and this herbicide is considered to be a contact herbicide due to its reduced mobility in plants (Tahmasebi et al. Reference Tahmasebi, Alcántara-de la Cruz, Alcántara, Torra, Domínguez-Valenzuela, Cruz-Hipólito, Rojano-Delgado and De Prado2018). It is quickly absorbed by plant leaves after its application. Depending on the light intensity, this herbicide produces reactive oxygen species that damage membranes and act as electron acceptors of photosystem I (PSI) within chloroplasts, inhibiting the photosynthesis process and causing the quick mortality of plant cells (Hawkes Reference Hawkes2014).

Studies on seed germination ecology provide important information on the emergence of weeds, their establishment, and their seedbank dynamics, all of which is vital knowledge for any program to control weeds (Chauhan and Johnson Reference Chauhan and Johnson2010). For effective control of any weed, the capacity to accurately estimate when weed seeds would germinate could improve timing of cultural practices. To develop an effectual weed control program, knowledge of seed biology is necessary for developing plant simulation models (Martinson et al. Reference Martinson, Durgan, Forcella, Wiersma, Spokas and Archer2007; Nonogaki Reference Nonogaki2014, Reference Nonogaki2017; Schutte et al. Reference Schutte, Regnier, Harrison, Schmoll, Spokas and Forcella2008). In an agroecosystem, seed germination of a weed is a key event in determining its success, and light, temperature, moisture, soil salinity, burial depth, and other factors can all affect it. One of the most crucial elements affecting a seed’s ability to germinate is temperature. Due to varying temperature requirements, differential seed germination and emergence behavior have been seen in different populations of weed species such as African mustard (Brassica tournefortii Gouan) and wild mustard (Sinapis arvensis L.) (Chauhan et al. Reference Chauhan, Gill and Preston2006a; Singh et al. Reference Singh, Mahajan, Singh and Chauhan2021; Singh et al. Reference Singh, Mahajan and Chauhan2022); although, for the Australian populations of E. indica, such information has not been published.

Weed seeds that require light for their germination would emerge when they are near the soil surface, and these weed species may be more common in no-till cropping systems or non-cropped areas (Chauhan and Johnson Reference Chauhan and Johnson2008; Travlos et al. Reference Travlos, Gazoulis, Kanatas, Tsekoura, Zannopoulos and Papastylianou2020). Similarly, weeds that can germinate in environments with severe salinity or moisture stress can benefit from conditions that prevent the growth of other species.

Crop residues applied to the soil surface (as mulches) may also restrict weed growth (Chauhan and Johnson Reference Chauhan and Johnson2008; Teasdale et al. Reference Teasdale, Beste and Potts1991); however, the amount and type of plant material employed will determine whether crop residues stimulate or hinder weed growth. Thus, crop residue retention could play a significant role in an integrated weed management strategy. The germination and emergence of E. indica seedlings can be impacted by the depth at which seeds are buried (Chauhan and Johnson Reference Chauhan and Johnson2008). The vertical seed distribution in the soil can be affected by tillage (Chauhan et al. Reference Chauhan, Gill and Preston2006b), and weed population dynamics may be influenced by this varying weed seed dispersal in the soil profile (Buhler Reference Buhler1991). There is little information on the ability of E. indica to emerge from different depths under Australian conditions. The objectives of this research study were to (1) evaluate the performance of different postemergence herbicides on E. indica, and (2) determine the effects of environmental factors on seed germination and seedling emergence of E. indica.

Materials and Methods

Seed Description

Two Australian populations (Gatton and Ingham) of E. indica were selected for seed collection. In the Queensland (QLD) region of the Lockyer Valley, where Gatton is situated, there is a humid subtropical climate with hot, muggy summers and pleasant, sunny winters. During the summer months, Gatton experiences average minimum and maximum temperatures ranging from 17 to 32 C, while in winter, these temperatures range from 5 to 23 C. The humidity levels typically hover around 50% to 60% during the afternoon. Ingham is situated in the tropical monsoon region of Hinchinbrook Shire, QLD. During the summer months, Ingham experiences average minimum and maximum temperatures ranging from 22 to 34 C, while in winter, these temperatures range from 14 to 26 C. The humidity typically hovers around 70% to 80% during the afternoon hours. Seeds of E. indica were collected in March 2021 from fallow fields in Gatton and Ingham. There is distance of about a 1,500 km between the two sites. To obtain experimental samples for the Gatton and Ingham populations, seeds were collected from approximately 50 plants at each site and then bulked by population. After being dehulled by rubbing them between the hands, seeds were manually cleaned, dried in the shade, and kept in airtight containers at room temperature (25 + 2 C) until being used in the experiments. The field history and herbicide usage details for each site remain unknown. Nevertheless, it is important to note that sugarcane cultivation is prevalent in the Ingham region, where paraquat sees extensive use. In contrast, the Gatton site likely has a minimal history of paraquat application.

Performance of Postemergence Herbicides

Ten seeds from each population of E. indica were planted in 14-cm-diameter pots at a depth of 1 cm. The pots were filled with a commercial potting mix (Platinum® potting mix, Centenary Landscaping, Brisbane, QLD, Australia). The potting mix contained biological organic-based products and had a pH of 5.6. Immediately after emergence, thinning of plants was done to maintain 5 plants pot⁻¹. These plants were kept on benches outdoors and regularly irrigated using an automated sprinkler system. However, the amount of water used was not measured. To measure the effectiveness of postemergence herbicides, plants were sprayed the 4- to 5-leaf stage (5- to 6-cm plant height) with different postemergence herbicides at recommended label rates typical for most grass species (Table 1). A nontreated control treatment devoid of any herbicide application was included for each population.

Table 1.

Herbicide treatments, trade names, sites of action, doses, and adjuvants used in the postemergence herbicide trial.

^a Abbreviations: ACCase, acetyl-coenzyme-A carboxylase; ALS, acetolactate synthase; EPSPS, 5-enolpyruvylshikimate-3-phosphate.

^b Adjuvants: Adigor® (Syngenta Australia Pty Ltd, Macquarie Park, NSW) contains 440 g L⁻¹ methyl esters of canola oil fatty acids; Hasten™ (BASF Australia Ltd, Southbank, VIC) contains 704 g L⁻¹ ethyl and methyl esters of vegetable oil with 196 g L⁻¹ nonionic surfactants; and Supercharge® (Nufarm Australia Ltd, Laverton, VIC) is 471 g L⁻¹ paraffin oil.

^c Commercial mixture.

A research track sprayer and TeeJet® XR110015 flat-fan nozzles (Sprayshop, Toowoomba, QLD, Australia) were utilized to spray herbicides with a water volume of 108 L ha⁻¹. Data on plant survival and biomass were recorded at 28 d after treatment, and plants that had grown a new leaf in that time were considered to have survived. The surviving plants were harvested at the soil surface, put in paper bags, and dried for 72 h at 70 C in an oven. The dry biomass was weighed.

This trial found differential responses of both populations to paraquat. The Gatton population was completely controlled, but the Ingham population survived (100%) at the field rates of amitrole + paraquat (560 g ai ha⁻¹) and paraquat (600 g ai ha⁻¹). To further examine these differences, both populations were evaluated for paraquat in a dose–response study using the procedure described above. Plants of both populations were treated with paraquat at the 4- to 5-leaf stage (5- to 6-cm plant height) with doses of 0, 17.75, 37.5, 75, 150, 300, 600, 1,200, 2,400, 4,800, and 9,600 g ai ha⁻¹ (with the 1× rate of paraquat being 600 g ai ha⁻¹). Data were measured using the methods stated previously.

General Germination Test Protocol

To evaluate the effect of different environmental factors on seed germination of E. indica, various germination tests were conducted in 9-cm-diameter petri dishes containing a double layer of filter paper (Whatman® No. 1, Maidstone, UK). Each petri plate contained 25 seeds distributed equally, then 5 ml of distilled water or a treatment solution was added. To avoid any water vapor loss, petri dishes were placed inside plastic ziplock bags, and then these bags were placed in temperature- and light-controlled incubators (ICCBOD-300, Laboratory Equipment, Marrickville, NSW, Australia). The fluorescent light inside the incubator emitted a white light with a photosynthetic photon flux density of 85 µmol m⁻² s⁻¹.

Studies on the effects of light, salt stress, and water stress were conducted in an incubator that was set at 30/20 C with a 12-h photoperiod that coincides with the higher temperature, because this temperature range was found to be optimum for seed germination in the temperature experiment (described in the following section). As there was no germination after 28 d of incubation, the number of germinated seeds was counted at that time, and seeds were deemed to have germinated when the radicle was at least 1 mm in length.

Effect of Temperature on Germination

Seed germination was measured in incubators set at five different day/night temperatures (15/5, 20/10, 25/15, 30/20, and 35/25 C) in the light/dark (12/12-h) environment to study the best temperature conditions for germination of E. indica populations. These temperature regimes were chosen to reflect the temperature conditions present in Australia’s eastern cropping region at various times of the year.

Effect of Light on Germination

Seeds from both populations of E. indica were exposed to two light regimes (either complete darkness for 24 h or an alternating light/dark [12/12-h] period) to assess germination under the two different light regimes (light/dark and dark). The incubator was set for treatment that alternated between light and darkness so that the high temperature (i.e., 30 C) was set during the light period and the low temperature (i.e., 20 C) was set for the dark period. For the dark treatment (30/20 C; 12 h/12 h), petri dishes were wrapped in three layers of aluminum foil to prevent any light from reaching the seeds. The foil was removed after the 28-d incubation period.

Effect of Salt Stress on Germination

To measure the impact of salt stress on E. indica germination, 25 seeds from each population were placed in petri plates with 5-ml solutions of 0, 20, 40, 80, 160, and 320 mM sodium chloride (NaCl). Before the germination percentage was recorded, these plates were incubated at 30/20 C day/night temperatures for 28 d. The NaCl concentration levels were chosen to represent the ranges of soil salinity that exist in different parts of Australia (Rengasamy Reference Rengasamy2002).

Effect of Osmotic Stress on Germination

To evaluate the impact of water stress on seed germination of E. indica, seeds from both populations were incubated in a wide range of water-deficient conditions, including 0.0, −0.1, −0.2, −0.4, −0.8, and −1.6 MPa. Following the procedure of Michel and Radcliffe (Reference Michel and Radcliffe1995), solutions with the necessary osmotic potentials were made using polyethylene glycol 8000 (Sigma-Aldrich, St Louis, MO, USA).

Effect of Burial Depth on Emergence

At the University of Queensland, Gatton, seeds from both populations of E. indica were used to measure the impact of seed burial depth on the emergence of weed seedlings. Each 14-cm-diameter plastic pot contained 50 seeds that were either sown on the top or at a depth of 1, 2, 4, or 8 cm. The soil utilized had a clay loam texture, 2.7% organic matter content, and a pH of 7.2. The soil was sterilized after being passed through a 2-mm sieve to prevent contamination. Control pots without any additional E. indica seeds were utilized to ensure that there were no seeds of E. indica in the soil. To maintain an appropriate soil moisture level, pots were subirrigated, and seedlings were considered to have emerged when a cotyledon appeared on the soil surface. The trial was terminated at 28 d after seed placement, as no further emergence occurred after that.

Statistical Analyses

All laboratory and screenhouse experiments were carried out using a randomized complete block design. Each experiment was carried out twice, and each treatment included three replications. The ANOVA revealed no interactions between treatments and runs; thus the data from the two runs were merged. Each replication served as a block in the laboratory studies and was set up on a distinct shelf in the germination chamber. Before statistical analysis (GenStat® 21), the variance of the data was visually evaluated by plotting the residuals. Regression analysis was used where appropriate; otherwise, means were separated using the LSD at 5%. The studies of the paraquat dosage response, salt, osmotic potential, and burial depth experiments were done using nonlinear regression (SigmaPlot v. 14.5, Systat Software, Palo Alto, CA, USA). Models displaying biologically relevant interpretation of coefficients were selected. In the dose–response experiment for paraquat, seedling survival, spike production, and biomass production (percent of nontreated control) data were regressed against paraquat doses using a three-parameter logistic model:

(1)

$$Y = a/\left[ {{\rm{1}} + {{\left( {x/{H_{{\rm{5}}0}}} \right)}^b}} \right]$$

In this model, Y represents the survival, spike, or biomass data at the x dose of herbicide; a represents the maximum seedling survival or production of spike/biomass; H ₅₀ represents the herbicide dose (g ai ha⁻¹) required for a 50% reduction in seedling survival (LD₅₀), spike number (SR₅₀), or plant biomass production (GR₅₀); and b represents the slope. Germination (%) values at different concentrations of NaCl were modeled using a three-parameter logistic model:

(2)

$$y = a/\left[ {{\rm{1}} + {{\left( {x/{x_{{\rm{5}}0}}} \right)}^b}} \right]$$

In this model, y represents the germination percentage at the x concentration of NaCl, a is the maximum germination (%), x ₅₀ is the NaCl concentration necessary for inhibiting 50% germination, and b represents the slope. A three-parameter sigmoid model was fit to the germination data obtained in response to different osmotic potentials:

(3)

$$y = a/\{ 1 + \exp \left[ { - {{\left( {x - {x_{{\rm{5}}0}}} \right)}^b}} \right]\} $$

In this model, y represents the germination percentage at osmotic potential x, a represents the maximum germination (%), x ₅₀ is the osmotic potential necessary for 50% inhibition of maximum germination, and b represents the slope. The seedling emergence values obtained from the seed burial experiment were fit using a three-parameter gaussian model. The model was:

(4)

$$y = a*e\{ - 0.5*{[(x - b)/c]^2}\} $$

The model’s graph is shaped like a bell curve. In the model, y represents the percentage of seedling emergence at burial depth x, a represents the peak of the curve (i.e., the maximum emergence), b represents the center of the peak (i.e., the depth required to achieve maximum seedling emergence), and c is the width of the “bell.”