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FRANK REITH (11 June 1972–14 October 2019) The man with the gold bug

Part of: Frank Reith memorial issue

Published online by Cambridge University Press:  04 June 2020

Allan Pring ,
Joël Brugger Open the ORCID record for Joël Brugger [Opens in a new window]  and
Jeremiah Shuster
Allan Pring
Affiliation:
College of Science and Engineering, Flinders University, Bedford Park, SA 5042, Australia
Joël Brugger*
Affiliation:
School of Earth, Atmosphere and the Environment, Monash University, Clayton, VIC 3800, Australia
Jeremiah Shuster
Affiliation:
School of Biological Sciences, The University of Adelaide, Adelaide, SA 5005, Australia CSIRO Land and Water, Contaminant Chemistry and Ecotoxicology, PMB2, Glen Osmond, SA 5064, Australia
*
*Author for correspondence: Joël Brugger, Email: joel.brugger@monash.edu
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Abstract

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Information

Type
Obituary
Information
Mineralogical Magazine , Volume 85 , Issue 1 , February 2021 , pp. 3 - 11
Copyright
Copyright © Mineralogical Society of Great Britain and Ireland 2020

Frank Reith's research legacy (Fig. 1) is the discovery that bacteria make a ‘home’ on gold grains and these microorganisms render gold mobile in the surrounding environment – belying the yellow metal's reputation for inertness and resistance to corrosion (Fig. 2). Frank was the first to integrate molecular characterisation with the ‘classic’ geochemical and morphological characterisation of placer gold grains, a radical step-change from the geological literature. His interdisciplinary approach to research integrated the latest cutting-edge techniques in chemical, spectroscopic, molecular and proteomic analysis. Frank had the gift of exciting people, of all walks of life, about his research. Throughout his career, he loved collaborative research and developed a vast and diverse network of interdisciplinary collaborators (friends) across the globe. Although his academic career was relatively short, Frank published >75 scientific papers, listed in the Appendix. To the broader geoscience community, Frank was a world-leading geomicrobiologist, fascinated by gold and devoted to delineating the interactions between bacteria and precious metals. He described himself more simply as, “the man with the gold bug”.

Fig. 1.

Frank Reith demonstrating gold panning near the historic Tomakin Park gold mine, New South Wales, Australia (photo 28/3/2007; Reith et al., Reference Reith, McPhail and Christy2005, 2006).

Fig. 2.

Frank's approach to precious metal microbiology. (a) Obtaining fresh samples under field sterile conditions means dropping the lab coat (gloves are required, though) and turning to the mining methods used by small scale miners and prospectors since times immemorial (Grosses Wasser river, Gondo, Switzerland; 8/8/2014; from front to back, Frank, Emilie Delpech, Barbara Etschmann and Tina Reith). (b) The gold and PGE grains are prepared carefully on-site to preserve DNA and/or delicate surface biofilms at their surface (Kilkivan, Queensland). (c) The surface of a washed alluvial gold grain from Kilkivan shows a typical bacteriomorph feature; do such features indicate biological cycling of gold? (d) Frank discovered that fresh, carefully prepared, alluvial gold samples are often covered by extensive biofilms, as in this example from Lively's Gold Find, Flinders Ranges, South Australia. Genetic analyses revealed that the microbial communities on the gold grains differ from those of the surrounding sediments and include a number of metallophiles. (e) The biofilms also commonly contain nanoparticulate Au particles, indicating that the biofilms contribute to the cycling of gold in the near surface by transforming ‘solid gold’ into mobile and reactive gold nanoparticles. Frank demonstrated that this happens in many different environments over four continents – highlighting similarities and well as the uniqueness of each environment (gold grain from the beach placer at Orepuki, New Zealand; Reith et al., Reference Reith, Stewart and Wakelin2012b). (f) The identification of the microbial cycling occurring on the surface of natural gold grains inspired a diverse experimental program. Illustrated here is an SEM image of the results of column experiments spiked with soluble gold and selected organisms that were identified on the surface of natural gold grains. The coloured SEM image highlights the association between bacterial cells at the surface of quartz grains, secondary gold particles via a network of nanowires (Fairbrother et al., Reference Fairbrother, Etschmann, Brugger, Shapter, Southam and Reith2013).

The man

Frank Reith, the elder of two children, was born on the 11th of June 1972 to Elke and Ernst-Wolfgang Reith, a family of wine makers in the Rhine–Hesse region, Germany. Frank grew up in the town of Woerrstadt and attended High School in Nieder-Olm. After fulfilling his civil service obligations as an ambulance driver, he attended the University of Bayreuth and graduated in 1999 with a Master's Degree in Ecological Microbiology and Geo-ecology as well as a degree in Marketing and Economics. As an avid The Lord of the Rings enthusiast, and an adventurer at heart, Frank then backpacked across the USA, Canada and Australia. Captivated by Australia's diverse landscapes, spectacular coastlines, and colourful history of gold mining, he chose to do his doctorate thesis, The Microbiology of Gold, at the Australian National University in Canberra under the supervision of Professor ‘Bear’ McPhail (Fig. 3).

Fig. 3.

Joint field trip with Frank's PhD supervisor, D.C. ‘Bear’ McPhail, to the Northern Flinders Ranges in May 2011. Bear never visited Frank in the field during his PhD (2003–2006) – this was their first and only joint field trip. (a) Reaching Radium Ridge, the site of early mining for radium from 1910 to the mid-1930s (photo 18/5/2011). From left to right, Fred (Bear's PhD student), Yuan Mei, Bear, Joël Brugger and Frank. (b) The trip became memorable when we discovered that rain and thixotropy combined to make a dry river bed an efficient trap for vehicles. Spending an unplanned night in the wilderness revealed that Frank was best prepared, as the only person (of seven participants) with a sleeping bag and a pillow (temperature dropped to ~5°C). On the next day, Frank is celebrating one of his favourite foods, Nutella, while waiting for the rescue party (21/5/2011). No situation is hopeless with Nutella!

Frank received his PhD in November of 2006 and his curiosity to discover more of the outback (and eventually the world) through field work and research never waned. Frank's journey continued when he moved to Adelaide, South Australia, to begin a postdoctoral position at the Commonwealth Scientific and Industrial Research Organization (CSIRO) on the Waite Campus. Having made a home in the scenic sea-side southern suburb of Marino, Frank enjoyed balancing research with sailing and discovering epicurean delights in the Barossa Valley, Clare Valley and McLaren Vale. Indeed, wine appreciation was in his blood and he sought to visit every cellar door in South Australia, often bringing family and friends on wine-tasting adventures to his favourite places. Frank was also a dedicated whiskey enthusiast (Fig. 4).

Fig. 4.

Good chemistry. Frank at Paul Shand's (on the left) Spirit of Gondwana whiskey distillery in the Adelaide Hills together with Andreas Schmidt Mumm (on the right) and his wife Tina (the photographer; photo 16/5/2018).

Frank was an avid fan of Dr. Who – the ultimate adventurer. Much like this famous doctor, Frank discovered he worked and travelled best with a ‘companion’. In 2010, Frank met his future wife, Tina Reitz, on a trip back to Germany. Tina, who was working as a social worker at the time, was seeking travel advice for a trip to Australia. With strong mutual attraction and a passion for travel, they soon became a long-distance couple. Two years later, Tina travelled to Australia and embarked on a ten week-long journey with Frank. They explored the East Coast up to the historic gold town of Gympie in Queensland before returning to Adelaide, which soon became the duo's home base. Tina became Frank's companion when they married on the 20th of September 2013 and together they lived happily, taking pleasure in walking the neighbour's dog, Oscar, along the beach near their home base. For the next 5 years, the duo planned Frank's extensive research-based travels to obtain ‘fresh’ samples of gold and other precious metals from around the world (Brazil, Finland, Sweden, Norway, Switzerland, Germany, France, UK, South Africa, New Zealand, USA and Australia) to better understand bacteria–gold interactions. With their shared passion for photography, they documented each fieldtrip capturing the memories of shared experiences throughout their journey (Fig. 5).

Fig. 5.

Frank and Tina taking a pause in the chase for PGE grains. Angra dos Rei, Brazil, 10/12/2012.

The gold bug

Frank advocated that scientific research should be fun and novel discoveries come by embracing the challenge of uncertainty with friends (Fig. 3b). The need to obtain fresh gold samples – and grains of the much rarer Platinum Group Elements (PGE) – inspired many of Frank's adventures. Frank also loved driving, listening to a range of music (from Scottish bagpiping to heavy metal) and, in Australia, enjoyed hours of cricket on the radio. Many field trips became amazing road trips, logging tens of thousands of kilometres through Australia, Europe, Brazil and South Africa (Fig. 6). Frank was in his element during field work, and these trips were thrilling because they combined exciting scientific discoveries with an endless curiosity for nature and people alike. Careful and extensive planning ensured that these trips achieved their scientific goals.

Fig. 6.

Frank at work. (a) Despite the heat being Frank's greatest enemy in the field, he loved the beauty of the isolated wilderness. Sampling groundwater for Au content near the Rabbit Flat Roadhouse, Northern Territory, that claimed to be the most isolated roadhouse in Australia (photo 4/11/2011; Ta et al., Reference Ta, Reith, Brugger, Pring and Lenehan2014). The insert map shows the full extent of this >10,000 km sampling trip; one soil sample was collected every 100 km to contribute to the biomes of Australian soil environments soil microbial diversity database (Bissett et al., Reference Bissett, Fitzgerald, Meintjes, Mele, Reith, Dennis, Breed, Brown, Brown, Brugger, Byrne, Caddy-Retalic, Carmody, Coates, Correa, Ferrari, Gupta, Hamonts, Haslem, Hugenholtz, Karan, Koval, Lowe, Macdonald, McGrath, Martin, Morgan, North, Paungfoo-Lonhienne, Pendall, Phillips, Pirzl, Powell, Ragan, Schmidt, Seymour, Snape, Stephen, Stevens, Tinning, Williams, Yeoh, Zammit and Young2016). (b) The team at Concession Creek, Agnes Mine, Barberton gold fields, South Africa (16/8/2016; Sanyal et al., Reference Sanyal, Shuster, Delport, Dixon, Etschmann, Brugger, Pedersen and Reith2020). This trip also delivered unexpected results. Several sites turned out to be heavily contaminated with mercury due to intense activity by illegal miners – which led to a study of the effect of heavy metals on Au cycling (Sanyal et al., Reference Sanyal, Shuster, Delport, Dixon, Etschmann, Brugger, Pedersen and Reith2020). Some of the on-going illegal mining is conducted by rather unsavoury types, requiring a well-armed security escort. From left to right: Frank, Joël (Monash University), two security personnel from Agnes Mine, Jaco Delport and Roger Dixon (University of Pretoria), Barbara Etschmann (Monash University) and our local guide, Andrea Botha. (c,d) Deciphering the geobiochemistry of palladium, gold and other platinum-group minerals at the type locality for the mineral palladium, Corrego Bom Sucesso in Brazil (Reith et al., Reference Reith, Campbell, Ball, Pring and Southam2014; Reference Reith, Nolze, Saliwan-Neumann, Etschmann, Kilburn and Brugger2019); photo (c), panning for PGE, 25/11/2012; and photo (d), sampling local soils, 29/11/2012. The remarkable dendritic Pt–Pd rich nuggets from this locality were attributed a biological origin early on, but fresh samples were required to prove this hypothesis by demonstrating the existence of specific organisms on the surface of these grains. There were some tense moments when our guide declared the trip to be a failure following the strenuous walk to the remote site: local Garimpeiros had not worked the claim in a while (one died of old age; one broke his hip; and one took a ‘real’ job), and academics could not possibly have the stamina, muscles and skills to extract the rare minerals from local sediments. Four days of hard work provided the material to prove the biological cycling of PGE in tropical sediments (Reith et al., Reference Reith, Campbell, Ball, Pring and Southam2014; Reference Reith, Verboom, Pate and Chittleborough2019). (e) Sluicing at Eldorado gold fields near Wangaratta, Victoria, Australia (3/1/2018). (f) Field laboratory at the Titania prospect near The Granites gold mine, Northern Territory (2/1/2008). Day-time temperatures well in excess of 40°C and high humidity made a 2008 expedition to the Tanami desert one of the toughest field trips in Frank's career (Reith et al., Reference Reith, Brugger, Zammit, Gregg, Goldfarb, Andersen, DeSantis, Piceno, Brodie, Lu, He, Zhou and Wakelin2012a). (g) Frank changing a sample during a late-night shift at the ID22 beamline at the European Synchrotron Research Facility (ESRF), Grenoble, France (25/2/2008; Brugger et al., Reference Brugger, Etschmann, Grosse, Plumridge, Kaminski, Paterson, Shar, Ta, Howard, de Jonge, Ball and Reith2013).

In 2007, Frank was awarded a prestigious Australian Research Council (ARC) Postdoctoral Industrial Fellowship for his research project, ‘Bacterial mechanisms of gold mobilisation and precipitation with applications to mineral processing and exploration’. Frank held this fellowship through the University of Adelaide (UA) but remained at CSIRO because he integrated comfortably into that campus. The positive outcomes of this project enabled Frank to develop as an early career researcher and build an independent research programme. As his fellowship came to a close, Frank applied for a highly competitive ARC Australian Research Fellowship in 2010. For this application, endorsement from the School of Earth and Environmental Sciences (UA) was required; however, it received tepid support. Thanks to well established collaborations at Flinders University, in the south of Adelaide, Frank's proposal received greater support and was awarded funding to explore interactions between platinum-group metals and bacteria. During this time, Frank formally joined the Minerals Microbes and Solution’ group (formerly ‘Minerals Metals and Solutions’), a consortium of researchers from the South Australian Museum and the University of Adelaide. With Frank's increasing grant success and a promising research profile, the University of Adelaide was anxious to retain his expertise. Frank relished in negotiating hard with UA authorities to not only move his fellowship to UA but to also provide him a continuing position with additional funding. During his fellowship, Frank led an ARC Linkage Project that involved the collaboration between UA, Newmont, Barrick Gold, the South Australian Museum, and a network of interdisciplinary colleagues across the globe. This collaboration successfully developed a live cell biosensor that could detect gold concentrations down to 1 ppb. While this applied research was not commercially viable for exploration, it did lead to a series of landmark papers.

In 2015, Frank was awarded a highly prestigious ARC Future Fellowship, one of only two fellowships granted to researchers based in South Australia that year. This fellowship enabled Frank to continue his research in gold geomicrobiology. In doing so, he recruited a postdoctoral fellow and another graduate student to join his research group, ‘Microbes and Heavy Metal’. In addition to leading his own research programme, Frank also contributed to the Biome of Australia Soil Environments (BASE) project (Bissett et al., Reference Bissett, Fitzgerald, Meintjes, Mele, Reith, Dennis, Breed, Brown, Brown, Brugger, Byrne, Caddy-Retalic, Carmody, Coates, Correa, Ferrari, Gupta, Hamonts, Haslem, Hugenholtz, Karan, Koval, Lowe, Macdonald, McGrath, Martin, Morgan, North, Paungfoo-Lonhienne, Pendall, Phillips, Pirzl, Powell, Ragan, Schmidt, Seymour, Snape, Stephen, Stevens, Tinning, Williams, Yeoh, Zammit and Young2016). As part of his contribution, he led an epic >10,000 km field trip starting in Adelaide, travelling across the continent to Broome, the Pilbara, Kalgoorlie, Perth and the Boddington gold mine, and back to Adelaide via the Nullarbor (Fig. 6a). Although not a golfer, Frank took great delight in playing the Nullarbor golf links, an 18-hole par 72 course that spans 1365 km on the Nullarbor plain. Aside from collecting numerous gold grains and associated samples (sediments and groundwaters), this trip produced >100 soil samples that contributed to the BASE project.

Frank's passion for science, his love of wine – and whiskey (Fig. 4) – and his engaging personality were key in opening doors with a variety of people from different backgrounds (Fig. 7). Through his adventures, he developed many strong friendships with local small-scale miners who appreciated his adaptability in the field. Through these friendships, Frank gained access to exciting and rare sampling locations – the ultimate adventurous journey of sharing what he found fascinating about the world around him.

Fig. 7.

Communicating science and mentoring. (a) Working closely with artisanal miners is the secret to getting access to exceptional gold samples and test sites. Frank and John Parsons from the Prophet Gold Mine in Kilkivan, Australia. (b) Interviewing together with Jeremiah Shuster for Scope TV (10play.com.au; 02/03/2018) at the Waite CSIRO laboratories. (c) Guiding a field trip to the Barossa gold fields for the Waterhouse Club, a support group of the South Australian Museum (15/9/2007). (d) Graduation ceremony of Dr Maria Angelica D. Rea (29/4/2019).

“All that is gold does not glitter, Not all those who wander are lost….” J.R.R. Tolkien

One of Frank's long-time dreams was to retrace the tracks of North American gold-rush miners. As with any adventure, however, the path can take the traveller on a sudden and unexpected direction with no option to turn back. During a field excursion in California, Frank's health declined rapidly and Frank and Tina were advised to return immediately to Adelaide. Frank was diagnosed with pancreatic cancer and underwent a series of major operations. With the tireless support of Tina, Frank received all possible treatment over the next 18 months in hopes to prolong his adventures – he wanted to continue a life well lived. In doing so, Frank shared scientific discoveries by assisting his graduate students to complete their research (e.g. Fig. 7d); he visited family in Germany and hosted many friends in Adelaide when physically possible; he delivered an emotional plenary presentation at the International Mineralogical Association (IMA) 2018 Conference in Melbourne (Mills and Missen, Reference Mills and Missen2018) as well as an invited talk to commemorate the passing of his PhD mentor, ‘Bear’ McPhail; he made his last adventure to Middle Earth (New Zealand; Fig. 8). With his companion by his side and surrounded by the mementos of his adventures in their home base, Frank's life journey ended peacefully on the 14th of October 2019. Frank had a great gift in communicating the excitement and novelty of his research with people from all walks of life. His passion for sharing the joy of science, discovery, and his life lessons will be cherished in the memories of his wide circle of friends and colleagues.

Fig. 8.

Frank and Tina in Middle Earth, May 2019.

Acknowledgements

The authors are grateful to Tina Reith for contributing images and information, and Alexander Pring, Barbara Eschmann and Angel Rea for their contributions to early drafts. This obituary also benefited from careful reviews by Janice P.L. Kenney and Stuart Mills.

References

References

Bissett, A., Fitzgerald, A., Meintjes, T., Mele, P.M., Reith, F., Dennis, P.G., Breed, M.F., Brown, B., Brown, M.V., Brugger, J., Byrne, M., Caddy-Retalic, S., Carmody, B., Coates, D.J., Correa, C., Ferrari, B.C., Gupta, V.V.S.R., Hamonts, K., Haslem, A., Hugenholtz, P., Karan, M., Koval, J., Lowe, A.J., Macdonald, S., McGrath, L., Martin, D., Morgan, M., North, K.I., Paungfoo-Lonhienne, C., Pendall, E., Phillips, L., Pirzl, R., Powell, J.R., Ragan, M.A., Schmidt, S., Seymour, N., Snape, I., Stephen, J.R., Stevens, M., Tinning, M., Williams, K., Yeoh, Y.K., Zammit, C.M. and Young, A. (2016) Introducing BASE: The biomes of Australian soil environments soil microbial diversity database. Gigascience, 5, 21, 11 pp.CrossRefGoogle ScholarPubMed
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Appendix – list of publications in chronological order

Araujo, R., Gupta, V.V.S.R., Reith, F., Bissett, A., Mele, P. and Franco, C.M.M. (2020) Biogeography and emerging significance of actinobacteria in Australia and Northern Antarctica soils. Soil Biology and Biochemistry, 146, 107805, 9 pp.CrossRefGoogle Scholar
Crede, L.S., Evans, K.A., Rempel, K.U., Brugger, J., Etschmann, B., Bourdet, J. and Reith, F. (2020) Revisiting hydrocarbon phase mobilization of Au in the Au-Hg McLaughlin Mine, Geysers/Clear Lake area, California. Ore Geology Reviews, 117, 103218.CrossRefGoogle Scholar
Missen, O.P., Ram, R., Mills, S.J., Etschmann, B., Reith, F., Shuster, J., Smith, D. J. and Brugger, J. (2020) Love is in the Earth: a review of tellurium (bio)geochemistry in surface environments. Earth Science Reviews, 204, 103150, 30 pp.CrossRefGoogle Scholar
Reith, F., Falconer, D.M., Van Nostrand, J., Craw, D., Shuster, J. and Wakelin, S. (2020) Functional capabilities of bacterial biofilms on gold particles. FEMS Microbiology Ecology, 96, fiz196, 15 pp.CrossRefGoogle ScholarPubMed
Shar, S.S., Reith, F., Shahsavari, E., Adetutu, E.M., Nurulita, Y., Al-Hothaly, K., Haleyur, N. and Ball, A.S. (2019) Biomineralization of platinum by Escherichia coli. Metals, 9, 407, 8 pp.CrossRefGoogle Scholar
Sanyal, S.K., Shuster, J. and Reith, F. (2019) Cycling of biogenic elements drives biogeochemical gold cycling. Earth-Science Reviews, 190, 131147.CrossRefGoogle Scholar
Sanyal, S.K., Shuster, J. and Reith, F. (2019) Biogeochemical gold cycling selects metal-resistant bacteria that promote gold particle transformation. FEMS Microbiology Ecology, 95, fiz078, 16 pp.CrossRefGoogle ScholarPubMed
Reith, F., Verboom, W., Pate, J. and Chittleborough, D. (2019b) Collaborative involvement of woody plant roots and rhizosphere microorganisms in the formation of pedogenetic clays. Annals of Botany, 124, 10071018.CrossRefGoogle Scholar
Rea, M.A.D., Wulser, P.A., Brugger, J., Etschmann, B., Bissett, A., Shuster, J. and Reith, F. (2019) Effect of physical and biogeochemical factors on placer gold transformation in mountainous landscapes of Switzerland. Gondwana Research, 66, 7792.CrossRefGoogle Scholar
Rea, M.A., Shuster, J., Hoffmann, V.E., Schade, M., Bissett, A. and Reith, F. (2019) Does the primary deposit affect the biogeochemical transformation of placer gold and associated biofilms? Gondwana Research, 73, 7795.CrossRefGoogle Scholar
Shuster, J. and Reith, F. (2018) Reflecting on gold geomicrobiology research: Thoughts and considerations for future endeavors. Minerals, 8, 401, 12 pp.CrossRefGoogle Scholar
Shuster, J., Rea, M.A., Etschmann, B., Brugger, J. and Reith, F. (2018) Terraced iron formations: Biogeochemical processes contributing to microbial biomineralization and microfossil preservation. Geosciences, 8, 480, 20 pp.CrossRefGoogle Scholar
Rickels, W., Reith, F., Keller, D., Oschlies, A. and Quaas, M.F. (2018) Integrated assessment of carbon dioxide removal. Earths Future, 6, 565582.CrossRefGoogle Scholar
Reith, F. and Shuster, J. (2018) Editorial for special issue “Geomicrobiology and biogeochemistry of precious metals. Minerals, 8.CrossRefGoogle Scholar
Reith, F., Rea, M.A.D., Sawley, P., Zammit, C.M., Nolze, G., Reith, T., Rantanen, K. and Bissett, A. (2018) Biogeochemical cycling of gold: Transforming gold particles from arctic Finland. Chemical Geology, 483, 511529.CrossRefGoogle Scholar
Rea, M.A., Standish, C.D., Shuster, J., Bissett, A. and Reith, F. (2018) Progressive biogeochemical transformation of placer gold particles drives compositional changes in associated biofilm communities. FEMS Microbiology Ecology, 94, fiy080, 15 pp.CrossRefGoogle ScholarPubMed
Melchiorre, E.B., Orwin, P.M., Reith, F., Rea, M.A.D., Yahn, J. and Allison, R. (2018) Biological and geochemical development of placer gold deposits at Rich Hill, Arizona, USA. Minerals, 8, 56, 20 pp.CrossRefGoogle Scholar
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Butof, L., Wiesemann, N., Herzberg, M., Altzschner, M., Holleitner, A., Reith, F. and Nies, D.H. (2018) Synergistic gold-copper detoxification at the core of gold biomineralisation in Cupriavidus metallidurans. Metallomics, 10, 278286.CrossRefGoogle ScholarPubMed
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Ta, C., Brugger, J., Pring, A., Hocking, R.K., Lenehan, C.E. and Reith, F. (2015) Effect of manganese oxide minerals and complexes on gold mobilization and speciation. Chemical Geology, 407, 1020.CrossRefGoogle Scholar
Reith, F., Zammit, C.M., Pohrib, R., Gregg, A.L. and Wakelin, S.A. (2015) Geogenic factors as drivers of microbial community diversity in soils overlying polymetallic deposits. Applied and Environmental Microbiology, 81, 78227832.CrossRefGoogle ScholarPubMed
Craw, D., Kerr, G., Reith, F. and Falconer, D. (2015) Pleistocene paleodrainage and placer gold redistribution, Western Southland, New Zealand. New Zealand Journal of Geology and Geophysics, 58, 137153.CrossRefGoogle Scholar
Campbell, S.G., Reith, F., Etschmann, B., Brugger, J., Martinez-Criado, G., Gordon, R.A. and Southam, G. (2015) Surface transformations of platinum grains from Fifield, New South Wales, Australia. American Mineralogist, 100, 12361243.CrossRefGoogle Scholar
Zammit, C.M., Brugger, J., Southam, G. and Reith, F. (2014) In situ recovery of uranium – the microbial influence. Hydrometallurgy, 150, 236244.CrossRefGoogle Scholar
Weiland, F., Zammit, C.M., Reith, F. and Hoffmann, P. (2014) High resolution two-dimensional electrophoresis of native proteins. Electrophoresis, 35, 18931902.CrossRefGoogle ScholarPubMed
Watling, H.R., Collinson, D.M., Li, J., Mutch, L.A., Perrot, F.A., Rea, S.M., Reith, F. and Watkin, E.L.J. (2014) Bioleaching of a low-grade copper ore, linking leach chemistry and microbiology. Minerals Engineering, 56, 3544.CrossRefGoogle Scholar
Zammit, C.M., Quaranta, D., Gibson, S., Zaitouna, A.J., Ta, C., Brugger, J., Lai, R.Y., Grass, G. and Reith, F. (2013) A whole-cell biosensor for the detection of gold. PLOS One, 8, e69292, 8 pp.CrossRefGoogle Scholar
Zammit, C., Li, K., Etschmann, B., Brugger, J. and Reith, F. (2013) Geobiology of in situ uranium leaching. Pp. 372375 in: Integration of Scientific and Industrial Knowledge on Biohydrometallurgy (Guiliani, N., Demergasso, C., Quatrini, R., Remonsellez, F., DavisBelmar, C., Levican, G., Parada, P., Barahona, C., and Zale, R., editors) Advanced Materials Research, 825.Google Scholar
Wiesemann, N., Mohr, J., Grosse, C., Herzberg, M., Hause, G., Reith, F. and Nies, D.H. (2013) Influence of copper resistance determinants on gold transformation by Cupriavidus metallidurans strain CH34. Journal of Bacteriology, 195, 22982308.CrossRefGoogle Scholar
Brugger, J., Etschmann, B., Grosse, C., Plumridge, C., Kaminski, J., Paterson, D., Shar, S.S., Ta, C., Howard, D.L., de Jonge, M.D., Ball, A.S. and Reith, F. (2013) Can biological toxicity drive the contrasting behavior of platinum and gold in surface environments? Chemical Geology, 343, 99110.CrossRefGoogle Scholar
Zammit, C.M., Cook, N., Brugger, J., Ciobanu, C.L. and Reith, F. (2012) The future of biotechnology for gold exploration and processing. Minerals Engineering, 32, 4553.CrossRefGoogle Scholar
Wakelin, S.A., Anand, R.R., Reith, F., Gregg, A.L., Noble, R.R.P., Goldfarb, K.C., Andersen, G.L., DeSantis, T.Z., Piceno, Y.M. and Brodie, E.L. (2012) Bacterial communities associated with a mineral weathering profile at a sulphidic mine tailings dump in arid western Australia. FEMS Microbiology Ecology, 79, 298311.CrossRefGoogle Scholar
Wakelin, S., Anand, R.R., Macfarlane, C., Reith, F., Noble, R. and Rogers, S. (2012) Assessing microbiological surface expression over an overburden-covered VMS deposit. Journal of Geochemical Exploration, 112, 262271.CrossRefGoogle Scholar
Reith, F., Zammit, C.M., Rogers, S.L., McPhail, D.C. and Brugger, J. (2012c) Potential utilisation of micro-organisms in gold processing: A review. Transactions of the Institutions of Mining and Metallurgy Section C – Mineral Processing and Extractive Metallurgy, 121, 251260.CrossRefGoogle Scholar
Fairbrother, L., Brugger, J., Shapter, J., Laird, J.S., Southam, G. and Reith, F. (2012) Supergene gold transformation: Biogenic secondary and nano-particulate gold from arid Australia. Chemical Geology, 320, 1731.CrossRefGoogle Scholar
Cabral, A.R., Reith, F., Lehmann, B., Brugger, J., Meinhold, G., Tupinamba, M. and Kwitko-Ribeiro, R. (2012) Anatase nanoparticles on supergene platinum-palladium aggregates from brazil: Titanium mobility in natural waters. Chemical Geology, 334, 182188.CrossRefGoogle Scholar
Reith, F., Etschmann, B., Dart, R.C., Brewe, D.L., Vogt, S., Mumm, A.S. and Brugger, J. (2011) Distribution and speciation of gold in biogenic and abiogenic calcium carbonates – implications for the formation of gold anomalous calcrete. Geochimica et Cosmochimica Acta, 75, 19421956.CrossRefGoogle Scholar
Reith, F. (2011) Life in the deep subsurface. Geology, 39, 287288.CrossRefGoogle Scholar
Reith, F., Fairbrother, L., Nolze, G., Wilhelmi, O., Clode, P., Gregg, A., Parsons, J., Wakelin, S., Pring, A., Hough, R., Southam, G. and Brugger, J. (2010) Nanoparticle factories: Biofilms hold the key to gold dispersion and nugget formation. Geology, 38, 843846.CrossRefGoogle Scholar
Phillips, G., Reith, F., Qualls, C., Ali, A.M., Spilde, M. and Appenzeller, O. (2010) Bacterial deposition of gold on hair: Archeological, forensic and toxicological implications. PLOS One, 5, e9335, 7 pp.CrossRefGoogle Scholar
Brugger, J., Pring, A., Reith, F., Ryan, C., Etschmann, B., Liu, W., O'Neill, B. and Ngothai, Y. (2010) Probing ore deposits formation: New insights and challenges from synchrotron and neutron studies. Radiation Physics and Chemistry, 79, 151161.CrossRefGoogle Scholar
Southam, G., Lengke, M.F., Fairbrother, L. and Reith, F. (2009) The biogeochemistry of gold. Elements, 5, 303307.CrossRefGoogle Scholar
Reith, F., Wakelin, S.A., Gregg, A.L. and Schmidt Mumm, A. (2009) A microbial pathway for the formation of gold anomalous calcrete. Chemical Geology, 258, 315326.CrossRefGoogle Scholar
Reith, F., Etschmann, B., Grosse, C., Moors, H., Benotmane, M., Monsieurs, P., Grass, G., Doonan, C., Vogt, S., Lai, B., Martinez-Criado, G., George, G., Nies, D., Mergeay, M., Pring, A., Southam, G. and Brugger, J. (2009) Mechanisms of gold biomineralization in the bacterium Cupriavidus metallidurans. Proceedings of the National Academy of Sciences of the United States of America, 106, 1775717762.CrossRefGoogle ScholarPubMed
Reith, F. and Rogers, S.L. (2008) Assessment of bacterial communities in auriferous and non-auriferous soils using genetic and functional fingerprinting. Geomicrobiology Journal, 25, 203215.CrossRefGoogle Scholar
Reith, F., Dürr, M., Welch, S. and Rogers, S.L. (2008) The geomicrobiology of the regolith. Pp. 127159 in: Regolith Science (Scott, K. and Pain, C.F., editors). CSIRO Press, Melbourne, Australia.Google Scholar
Reith, F., Rogers, S., McPhail, D. and Brugger, J. (2007) Potential for the utilisation of micro-organisms in gold processing. Pp. 6774 in: World Gold 2007 (ISBN: 9781920806743).Google Scholar
Reith, F. and McPhail, D.C. (2007) Mobility and microbially mediated mobilization of gold and arsenic in soils from two gold mines in semi-arid and tropical Australia. Geochimica et Cosmochimica Acta, 71, 11831196.CrossRefGoogle Scholar
Reith, F., Lenke, M.F., Falconner, D., Craw, D. and Southam, G. (2007) Winogradski review – the geomicrobiology of gold. The ISME Journal, 1, 567584.CrossRefGoogle Scholar
Mumm, A.S. and Reith, F. (2007) Biomediation of calcrete at the gold anomaly of the Barns prospect, Gawler craton, South Australia. Journal of Geochemical Exploration, 92, 1333.CrossRefGoogle Scholar
Reith, F., Rogers, S.L., McPhail, D.C. and Webb, D. (2006) Biomineralization of gold: Biofilms on bacterioform gold. Science, 313, 233236.CrossRefGoogle ScholarPubMed
Reith, F. and McPhail, D.C. (2006) Effect of resident microbiota on the solubilization of gold in soil from the Tomakin Park gold mine, New South Wales, Australia. Geochimica et Cosmochimica Acta, 70, 14211438.CrossRefGoogle Scholar
Reith, F., McPhail, D.C. and Christy, A.G. (2005) Bacillus cereus, gold and associated elements in soil and other regolith samples from Tomakin Park gold mine in southeastern New South Wales, Australia. Journal of Geochemical Exploration, 85, 8198.CrossRefGoogle Scholar
Reith, F., Drake, H.L. and Kusel, K. (2002) Anaerobic activities of bacteria and fungi in moderately acidic conifer and deciduous leaf litter. FEMS Microbiology Ecology, 41, 2735.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1. Frank Reith demonstrating gold panning near the historic Tomakin Park gold mine, New South Wales, Australia (photo 28/3/2007; Reith et al., 2005, 2006).

Figure 1

Fig. 2. Frank's approach to precious metal microbiology. (a) Obtaining fresh samples under field sterile conditions means dropping the lab coat (gloves are required, though) and turning to the mining methods used by small scale miners and prospectors since times immemorial (Grosses Wasser river, Gondo, Switzerland; 8/8/2014; from front to back, Frank, Emilie Delpech, Barbara Etschmann and Tina Reith). (b) The gold and PGE grains are prepared carefully on-site to preserve DNA and/or delicate surface biofilms at their surface (Kilkivan, Queensland). (c) The surface of a washed alluvial gold grain from Kilkivan shows a typical bacteriomorph feature; do such features indicate biological cycling of gold? (d) Frank discovered that fresh, carefully prepared, alluvial gold samples are often covered by extensive biofilms, as in this example from Lively's Gold Find, Flinders Ranges, South Australia. Genetic analyses revealed that the microbial communities on the gold grains differ from those of the surrounding sediments and include a number of metallophiles. (e) The biofilms also commonly contain nanoparticulate Au particles, indicating that the biofilms contribute to the cycling of gold in the near surface by transforming ‘solid gold’ into mobile and reactive gold nanoparticles. Frank demonstrated that this happens in many different environments over four continents – highlighting similarities and well as the uniqueness of each environment (gold grain from the beach placer at Orepuki, New Zealand; Reith et al., 2012b). (f) The identification of the microbial cycling occurring on the surface of natural gold grains inspired a diverse experimental program. Illustrated here is an SEM image of the results of column experiments spiked with soluble gold and selected organisms that were identified on the surface of natural gold grains. The coloured SEM image highlights the association between bacterial cells at the surface of quartz grains, secondary gold particles via a network of nanowires (Fairbrother et al., 2013).

Figure 2

Fig. 3. Joint field trip with Frank's PhD supervisor, D.C. ‘Bear’ McPhail, to the Northern Flinders Ranges in May 2011. Bear never visited Frank in the field during his PhD (2003–2006) – this was their first and only joint field trip. (a) Reaching Radium Ridge, the site of early mining for radium from 1910 to the mid-1930s (photo 18/5/2011). From left to right, Fred (Bear's PhD student), Yuan Mei, Bear, Joël Brugger and Frank. (b) The trip became memorable when we discovered that rain and thixotropy combined to make a dry river bed an efficient trap for vehicles. Spending an unplanned night in the wilderness revealed that Frank was best prepared, as the only person (of seven participants) with a sleeping bag and a pillow (temperature dropped to ~5°C). On the next day, Frank is celebrating one of his favourite foods, Nutella, while waiting for the rescue party (21/5/2011). No situation is hopeless with Nutella!

Figure 3

Fig. 4. Good chemistry. Frank at Paul Shand's (on the left) Spirit of Gondwana whiskey distillery in the Adelaide Hills together with Andreas Schmidt Mumm (on the right) and his wife Tina (the photographer; photo 16/5/2018).

Figure 4

Fig. 5. Frank and Tina taking a pause in the chase for PGE grains. Angra dos Rei, Brazil, 10/12/2012.

Figure 5

Fig. 6. Frank at work. (a) Despite the heat being Frank's greatest enemy in the field, he loved the beauty of the isolated wilderness. Sampling groundwater for Au content near the Rabbit Flat Roadhouse, Northern Territory, that claimed to be the most isolated roadhouse in Australia (photo 4/11/2011; Ta et al., 2014). The insert map shows the full extent of this >10,000 km sampling trip; one soil sample was collected every 100 km to contribute to the biomes of Australian soil environments soil microbial diversity database (Bissett et al., 2016). (b) The team at Concession Creek, Agnes Mine, Barberton gold fields, South Africa (16/8/2016; Sanyal et al., 2020). This trip also delivered unexpected results. Several sites turned out to be heavily contaminated with mercury due to intense activity by illegal miners – which led to a study of the effect of heavy metals on Au cycling (Sanyal et al.,2020). Some of the on-going illegal mining is conducted by rather unsavoury types, requiring a well-armed security escort. From left to right: Frank, Joël (Monash University), two security personnel from Agnes Mine, Jaco Delport and Roger Dixon (University of Pretoria), Barbara Etschmann (Monash University) and our local guide, Andrea Botha. (c,d) Deciphering the geobiochemistry of palladium, gold and other platinum-group minerals at the type locality for the mineral palladium, Corrego Bom Sucesso in Brazil (Reith et al., 2014; 2019); photo (c), panning for PGE, 25/11/2012; and photo (d), sampling local soils, 29/11/2012. The remarkable dendritic Pt–Pd rich nuggets from this locality were attributed a biological origin early on, but fresh samples were required to prove this hypothesis by demonstrating the existence of specific organisms on the surface of these grains. There were some tense moments when our guide declared the trip to be a failure following the strenuous walk to the remote site: local Garimpeiros had not worked the claim in a while (one died of old age; one broke his hip; and one took a ‘real’ job), and academics could not possibly have the stamina, muscles and skills to extract the rare minerals from local sediments. Four days of hard work provided the material to prove the biological cycling of PGE in tropical sediments (Reith et al., 2014; 2019). (e) Sluicing at Eldorado gold fields near Wangaratta, Victoria, Australia (3/1/2018). (f) Field laboratory at the Titania prospect near The Granites gold mine, Northern Territory (2/1/2008). Day-time temperatures well in excess of 40°C and high humidity made a 2008 expedition to the Tanami desert one of the toughest field trips in Frank's career (Reith et al., 2012a). (g) Frank changing a sample during a late-night shift at the ID22 beamline at the European Synchrotron Research Facility (ESRF), Grenoble, France (25/2/2008; Brugger et al., 2013).

Figure 6

Fig. 7. Communicating science and mentoring. (a) Working closely with artisanal miners is the secret to getting access to exceptional gold samples and test sites. Frank and John Parsons from the Prophet Gold Mine in Kilkivan, Australia. (b) Interviewing together with Jeremiah Shuster for Scope TV (10play.com.au; 02/03/2018) at the Waite CSIRO laboratories. (c) Guiding a field trip to the Barossa gold fields for the Waterhouse Club, a support group of the South Australian Museum (15/9/2007). (d) Graduation ceremony of Dr Maria Angelica D. Rea (29/4/2019).

Figure 7

Fig. 8. Frank and Tina in Middle Earth, May 2019.