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'''Jamie S. Foster''' is an [[American]] [[astrobiologist]], [[microbiologist]], and [[academic]]. She is a [[Professor]] at the Department of [[Microbiology]] and Cell Science, and [[Genetics]] and Genomes Graduate Program at the [[University of Florida]].<ref>{{ |
'''Jamie S. Foster''' is an [[American]] [[astrobiologist]], [[microbiologist]], and [[academic]]. She is a [[Professor]] at the Department of [[Microbiology]] and Cell Science, and [[Genetics]] and Genomes Graduate Program at the [[University of Florida]].<ref name="auto">{{Cite web|url=https://microcell.ufl.edu/people/jamie-foster/|title=Jamie Foster - Microbiology and Cell Science, University of Florida - University of Florida, Institute of Food and Agricultural Sciences - UF/IFAS|first=IFAS|last=Communications|website=microcell.ufl.edu}}</ref> |
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Foster's research is focused on space biology, [[symbiosis]], and [[astrobiology]].<ref>{{ |
Foster's research is focused on space biology, [[symbiosis]], and [[astrobiology]].<ref>{{Cite web|url=https://scholar.google.com/citations?user=tlb7hIkAAAAJ&hl=en|title=Jamie S. Foster|website=scholar.google.com}}</ref> She is most known for her contributions to the fields of astrobiology and [[microbial ecology]], particularly in enhancing comprehension of the intricate interactions between [[microorganisms]] and their ecological significance. She has received the 2021 President’s Award from the American Society of Gravitational and Space Research.<ref name="auto2">{{Cite web|url=https://asgsr.org/awards/|title=ASGSR Awards – ASGSR}}</ref> |
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==Education== |
==Education== |
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Foster obtained a [[Bachelor of Science]] degree in [[Zoology]] from the [[University of Massachusetts Amherst|University of Massachusetts at Amherst]] in 1992. She then pursued a Master of Science degree in Zoology from the [[University of Southern California]] and completed it in 1996. She then chose to further her education with doctoral advisor [[Margaret McFall-Ngai]] and obtained a [[PHD]] in Zoology from the [[University of Hawaiʻi]] in 2000 where she examined the impact that beneficial microbes have on host animal development.<ref |
Foster obtained a [[Bachelor of Science]] degree in [[Zoology]] from the [[University of Massachusetts Amherst|University of Massachusetts at Amherst]] in 1992. She then pursued a Master of Science degree in Zoology from the [[University of Southern California]] and completed it in 1996. She then chose to further her education with doctoral advisor [[Margaret McFall-Ngai]] and obtained a [[PHD]] in Zoology from the [[University of Hawaiʻi]] in 2000 where she examined the impact that beneficial microbes have on host animal development.<ref name="auto"/> Later, she worked as a [[Postdoctoral Fellow]] at the National Institute of Dental and Craniofacial Research at the [[National Institutes of Health]] from 2001 to 2003 with advisor Paul Kolenbrander. She then began a second Postdoctoral Fellow in the Exobiology Branch of the NASA Ames Research Center from 2003 to 2005 with advisor Lynn Rothschild. |
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==Career== |
==Career== |
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Foster began her academic career in 2003 by joining [[Purdue University]]'s Department of Biology as a [[Visiting Scholar]] and worked there until 2004. In 2005, she joined the University of Florida, where she held multiple appointments including serving as an Assistant Professor of Microbiology and Cell Science at the University of Florida from 2005 to 2012, and as an Associate Professor of Microbiology and Cell Science from 2012 to 2019. As of 2019, she is a Full Professor in Microbiology and Cell Science<ref>{{ |
Foster began her academic career in 2003 by joining [[Purdue University]]'s Department of Biology as a [[Visiting Scholar]] and worked there until 2004. In 2005, she joined the University of Florida, where she held multiple appointments including serving as an Assistant Professor of Microbiology and Cell Science at the University of Florida from 2005 to 2012, and as an Associate Professor of Microbiology and Cell Science from 2012 to 2019. As of 2019, she is a Full Professor in Microbiology and Cell Science<ref name="auto1">{{Cite web|url=https://www.researchgate.net/profile/Jamie-Foster-11|title=Jamie FOSTER | Professor (Full) | PhD | University of Florida, FL | UF | Department of Microbiology and Cell Science | Research profile}}</ref> at the University of Florida and also holds a concurrent appointment as a Full Professor of Genetics and Genomes Graduate Program at the same institution.<ref name="auto"/> |
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Foster was elected President of the American Society for Gravitational and Space Research. |
Foster was elected President of the American Society for Gravitational and Space Research. |
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==Research== |
==Research== |
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Foster has authored publications spanning the areas of [[marine biology]], microbial diversity, astrobiology, and microbial ecology including articles in peer-reviewed journals.<ref |
Foster has authored publications spanning the areas of [[marine biology]], microbial diversity, astrobiology, and microbial ecology including articles in peer-reviewed journals.<ref name="auto1"/> |
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===Beneficial interactions between animals and microbes in microgravity=== |
===Beneficial interactions between animals and microbes in microgravity=== |
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Foster’s extensive research on microbe’s interaction with microgravity has greatly contributed to the contemporary understanding of key mechanisms and factors that influence microbial behavior in space. Exploring the utility of using the squid-vibrio symbiosis model as a means to investigate the influence of microgravity on bacterial-induced animal development, her study suggested that this model is adaptable to experimental manipulation in a space environment and can offer significant insights into the role played by symbiotic bacteria in the natural development of animal tissues.<ref>{{cite web|url=https://www.semanticscholar.org/paper/Potential-of-the-Euprymna-Vibrio-Symbiosis-as-a-to-Foster-Kerney/911067081a9338206410d8a6d20adc63172ecb83|title=Potential of the Euprymna/Vibrio symbiosis as a model to assess the impact of microgravity on bacteria-induced animal development - Semantic Scholar}}</ref> While investigating the function of Hfq in an animal-microbe symbiosis during simulated microgravity conditions, she determined that simulated microgravity can impede the expression of Hfq, which plays an important role in the mutualistic association amongst V. fischeri and its animal host.<ref>{{ |
Foster’s extensive research on microbe’s interaction with microgravity has greatly contributed to the contemporary understanding of key mechanisms and factors that influence microbial behavior in space. Exploring the utility of using the squid-vibrio symbiosis model as a means to investigate the influence of microgravity on bacterial-induced animal development, her study suggested that this model is adaptable to experimental manipulation in a space environment and can offer significant insights into the role played by symbiotic bacteria in the natural development of animal tissues.<ref>{{cite web|url=https://www.semanticscholar.org/paper/Potential-of-the-Euprymna-Vibrio-Symbiosis-as-a-to-Foster-Kerney/911067081a9338206410d8a6d20adc63172ecb83|title=Potential of the Euprymna/Vibrio symbiosis as a model to assess the impact of microgravity on bacteria-induced animal development - Semantic Scholar}}</ref> While investigating the function of Hfq in an animal-microbe symbiosis during simulated microgravity conditions, she determined that simulated microgravity can impede the expression of Hfq, which plays an important role in the mutualistic association amongst V. fischeri and its animal host.<ref>{{Cite journal|url=https://www.cambridge.org/core/journals/international-journal-of-astrobiology/article/abs/role-of-hfq-in-an-animalmicrobe-symbiosis-under-simulated-microgravity-conditions/8792AB33898CFEAA454BFB4BD94274DE|title=Role of Hfq in an animal–microbe symbiosis under simulated microgravity conditions|first1=Kyle C.|last1=Grant|first2=Christina L. M.|last2=Khodadad|first3=Jamie S.|last3=Foster|date=January 5, 2014|journal=International Journal of Astrobiology|volume=13|issue=1|pages=53–61|via=Cambridge University Press|doi=10.1017/S1473550413000359}}</ref> In her assessment of host-microbe interactions in microgravity, it was revealed that microgravity conditions can disrupt these interactions, leading to a shift in the association towards pathogenicity and stressed the importance of comprehending microbial fitness under microgravity environments to uphold harmonious homeostasis between plants, humans, and their respective microbiomes during spaceflight.<ref>{{Cite web|url=https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4187166/|title=Host-Microbe Interactions in Microgravity: Assessment and Implications - PMC}}</ref> |
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Foster has designed and completed several spaceflight experiments that examine the effects of spaceflight on beneficial interactions between animals and microbes. She has had experiments aboard the last two space shuttle missions STS-134 and STS-135 and most recently completed an experiment aboard [[SpaceX CRS-22]]. |
Foster has designed and completed several spaceflight experiments that examine the effects of spaceflight on beneficial interactions between animals and microbes. She has had experiments aboard the last two space shuttle missions STS-134 and STS-135 and most recently completed an experiment aboard [[SpaceX CRS-22]]. |
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===Microbialites=== |
===Microbialites=== |
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Foster’s research on microbialites has focused on the formation, structure, and ecological significance of these unique sedimentary deposits, shedding light on the diverse microbial communities that shape their development and the environmental conditions that support their growth. Her early research has uncovered the mechanisms underlying thrombolytic microbialite formation, while also identifying a unique microbial community composition predominantly dominated by bacteria from the Alphaproteobacteria taxa and Cyanobacteria, with a comparatively low diversity of eukaryotic microorganisms.<ref>{{ |
Foster’s research on microbialites has focused on the formation, structure, and ecological significance of these unique sedimentary deposits, shedding light on the diverse microbial communities that shape their development and the environmental conditions that support their growth. Her early research has uncovered the mechanisms underlying thrombolytic microbialite formation, while also identifying a unique microbial community composition predominantly dominated by bacteria from the Alphaproteobacteria taxa and Cyanobacteria, with a comparatively low diversity of eukaryotic microorganisms.<ref>{{Cite journal|url=https://pubmed.ncbi.nlm.nih.gov/20491947/|title=Biogeochemical cycling and microbial diversity in the thrombolitic microbialites of Highborne Cay, Bahamas|first1=K. L.|last1=Myshrall|first2=J. M.|last2=Mobberley|first3=S. J.|last3=Green|first4=P. T.|last4=Visscher|first5=S. A.|last5=Havemann|first6=R. P.|last6=Reid|first7=J. S.|last7=Foster|date=September 5, 2010|journal=Geobiology|volume=8|issue=4|pages=337–354|via=PubMed|doi=10.1111/j.1472-4669.2010.00245.x|pmid=20491947}}</ref> In related research, her work investigated the mechanisms responsible for the formation of microbialites and the potential adaptations and modifications of their surrounding environment by these dynamic ecosystems while also identifying several general processes linked to mineral precipitation in various habitats.<ref>{{Cite web|url=https://www.frontiersin.org/research-topics/5694/characterizing-modern-microbialites-and-the-geobiological-processes-underlying-their-formation|title=Characterizing Modern Microbialites and The Geobiological Processes Underlying Their Formation | Frontiers Research Topic|website=www.frontiersin.org}}</ref> While examining the microbial diversity and Mineralogy in the Hypersaline Storr's Lake, her molecular analysis led to the identification of 12 dominant bacterial phyla and also established the presence of both aragonite and Mg-calcite in certain microbialite morphotypes using X-ray diffraction studies.<ref>{{Cite journal|url=https://pubmed.ncbi.nlm.nih.gov/27082142/|title=Mineralogy and Microbial Diversity of the Microbialites in the Hypersaline Storr's Lake, the Bahamas|first1=Varun G.|last1=Paul|first2=David J.|last2=Wronkiewicz|first3=Melanie R.|last3=Mormile|first4=Jamie S.|last4=Foster|date=April 5, 2016|journal=Astrobiology|volume=16|issue=4|pages=282–300|via=PubMed|doi=10.1089/ast.2015.1326|pmid=27082142}}</ref> |
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===Stromatolite microbial diversity=== |
===Stromatolite microbial diversity=== |
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Foster has conducted research on stromatolites, with a particular focus on their characterization and astrobiological implications. While examining the diversity of cyanobacteria composing stromatolites located in Highbourne Cay, The Bahamas, her work has provided insights into the microbial diversity and ecology of stromatolites and revealed that the genetic diversity of the cyanobacterial populations within the stromatolites exceeds prior estimates, thereby indicating that the mechanisms underlying stromatolite formation and accretion may be more intricate than previously assumed.<ref>{{ |
Foster has conducted research on stromatolites, with a particular focus on their characterization and astrobiological implications. While examining the diversity of cyanobacteria composing stromatolites located in Highbourne Cay, The Bahamas, her work has provided insights into the microbial diversity and ecology of stromatolites and revealed that the genetic diversity of the cyanobacterial populations within the stromatolites exceeds prior estimates, thereby indicating that the mechanisms underlying stromatolite formation and accretion may be more intricate than previously assumed.<ref>{{Cite journal|url=https://pubmed.ncbi.nlm.nih.gov/19148145/|title=Molecular and morphological characterization of cyanobacterial diversity in the stromatolites of Highborne Cay, Bahamas|first1=Jamie S.|last1=Foster|first2=Stefan J.|last2=Green|first3=Steven R.|last3=Ahrendt|first4=Stjepko|last4=Golubic|first5=R. Pamela|last5=Reid|first6=Kevin L.|last6=Hetherington|first7=Lee|last7=Bebout|date=May 5, 2009|journal=The ISME journal|volume=3|issue=5|pages=573–587|via=PubMed|doi=10.1038/ismej.2008.129|pmid=19148145}}</ref> Further, her study of present-day marine stromatolites in the Exuma Cays, in The Bahamas revealed a diverse and intricate array of microorganisms, whose spatial distribution appeared linked to the physical structure of the formations. It was suggested that distinct microorganisms performed distinct functions, contributing to the precipitation of calcium carbonate and facilitating the binding of sediment particles.<ref>{{Cite journal|url=https://pubmed.ncbi.nlm.nih.gov/19601956/#:~:text=Living+marine+stromatolites+at+Highborne,layering+observed+in+ancient+stromatolites.|title=Microbial diversity in modern marine stromatolites, Highborne Cay, Bahamas|first1=Laura K.|last1=Baumgartner|first2=John R.|last2=Spear|first3=Daniel H.|last3=Buckley|first4=Norman R.|last4=Pace|first5=R. Pamela|last5=Reid|first6=Christophe|last6=Dupraz|first7=Pieter T.|last7=Visscher|date=October 5, 2009|journal=Environmental Microbiology|volume=11|issue=10|pages=2710–2719|via=PubMed|doi=10.1111/j.1462-2920.2009.01998.x|pmid=19601956}}</ref> Her research on the microbial diversity in modern stromatolites highlighted the crucial role of metagenomic sequencing approaches in comprehending the molecular-level microbial diversity and functional complexity of these dynamic ecosystems, emphasizing that these approaches have facilitated a higher resolution characterization of stromatolite diversity and function.<ref>{{Cite book|url=https://doi.org/10.1007/978-94-007-0397-1_17|title=STROMATOLITES: Interaction of Microbes with Sediments|first1=Jamie S.|last1=Foster|first2=Stefan J.|last2=Green|editor-first1=Vinod|editor-last1=Tewari|editor-first2=Joseph|editor-last2=Seckbach|date=May 5, 2011|publisher=Springer Netherlands|pages=383–405|via=Springer Link|doi=10.1007/978-94-007-0397-1_17}}</ref> |
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==Awards and honors== |
==Awards and honors== |
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*2020 – Orr-Reynolds Service Award, American Society of Gravitational and Space Research<ref |
*2020 – Orr-Reynolds Service Award, American Society of Gravitational and Space Research<ref name="auto2"/> |
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*2021 – President’s Award, American Society of Gravitational and Space Research<ref |
*2021 – President’s Award, American Society of Gravitational and Space Research<ref name="auto2"/> |
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==Selected articles== |
==Selected articles== |
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Revision as of 06:53, 5 May 2023
Jamie S. Foster | |
|---|---|
| Born | |
| Nationality | American |
| Occupation(s) | Astrobiologist, microbiologist, and academic |
| Academic background | |
| Education | BS Zoology MS Biological Sciences PHD Zoology |
| Alma mater | University of Massachusetts University of Southern California University of Hawaiʻi |
| Academic work | |
| Institutions | University of Florida |
Jamie S. Foster is an American astrobiologist, microbiologist, and academic. She is a Professor at the Department of Microbiology and Cell Science, and Genetics and Genomes Graduate Program at the University of Florida.[1]
Foster's research is focused on space biology, symbiosis, and astrobiology.[2] She is most known for her contributions to the fields of astrobiology and microbial ecology, particularly in enhancing comprehension of the intricate interactions between microorganisms and their ecological significance. She has received the 2021 President’s Award from the American Society of Gravitational and Space Research.[3]
Education
Foster obtained a Bachelor of Science degree in Zoology from the University of Massachusetts at Amherst in 1992. She then pursued a Master of Science degree in Zoology from the University of Southern California and completed it in 1996. She then chose to further her education with doctoral advisor Margaret McFall-Ngai and obtained a PHD in Zoology from the University of Hawaiʻi in 2000 where she examined the impact that beneficial microbes have on host animal development.[1] Later, she worked as a Postdoctoral Fellow at the National Institute of Dental and Craniofacial Research at the National Institutes of Health from 2001 to 2003 with advisor Paul Kolenbrander. She then began a second Postdoctoral Fellow in the Exobiology Branch of the NASA Ames Research Center from 2003 to 2005 with advisor Lynn Rothschild.
Career
Foster began her academic career in 2003 by joining Purdue University's Department of Biology as a Visiting Scholar and worked there until 2004. In 2005, she joined the University of Florida, where she held multiple appointments including serving as an Assistant Professor of Microbiology and Cell Science at the University of Florida from 2005 to 2012, and as an Associate Professor of Microbiology and Cell Science from 2012 to 2019. As of 2019, she is a Full Professor in Microbiology and Cell Science[4] at the University of Florida and also holds a concurrent appointment as a Full Professor of Genetics and Genomes Graduate Program at the same institution.[1]
Foster was elected President of the American Society for Gravitational and Space Research.
Research
Foster has authored publications spanning the areas of marine biology, microbial diversity, astrobiology, and microbial ecology including articles in peer-reviewed journals.[4]
Beneficial interactions between animals and microbes in microgravity
Foster’s extensive research on microbe’s interaction with microgravity has greatly contributed to the contemporary understanding of key mechanisms and factors that influence microbial behavior in space. Exploring the utility of using the squid-vibrio symbiosis model as a means to investigate the influence of microgravity on bacterial-induced animal development, her study suggested that this model is adaptable to experimental manipulation in a space environment and can offer significant insights into the role played by symbiotic bacteria in the natural development of animal tissues.[5] While investigating the function of Hfq in an animal-microbe symbiosis during simulated microgravity conditions, she determined that simulated microgravity can impede the expression of Hfq, which plays an important role in the mutualistic association amongst V. fischeri and its animal host.[6] In her assessment of host-microbe interactions in microgravity, it was revealed that microgravity conditions can disrupt these interactions, leading to a shift in the association towards pathogenicity and stressed the importance of comprehending microbial fitness under microgravity environments to uphold harmonious homeostasis between plants, humans, and their respective microbiomes during spaceflight.[7]
Foster has designed and completed several spaceflight experiments that examine the effects of spaceflight on beneficial interactions between animals and microbes. She has had experiments aboard the last two space shuttle missions STS-134 and STS-135 and most recently completed an experiment aboard SpaceX CRS-22.
Microbialites
Foster’s research on microbialites has focused on the formation, structure, and ecological significance of these unique sedimentary deposits, shedding light on the diverse microbial communities that shape their development and the environmental conditions that support their growth. Her early research has uncovered the mechanisms underlying thrombolytic microbialite formation, while also identifying a unique microbial community composition predominantly dominated by bacteria from the Alphaproteobacteria taxa and Cyanobacteria, with a comparatively low diversity of eukaryotic microorganisms.[8] In related research, her work investigated the mechanisms responsible for the formation of microbialites and the potential adaptations and modifications of their surrounding environment by these dynamic ecosystems while also identifying several general processes linked to mineral precipitation in various habitats.[9] While examining the microbial diversity and Mineralogy in the Hypersaline Storr's Lake, her molecular analysis led to the identification of 12 dominant bacterial phyla and also established the presence of both aragonite and Mg-calcite in certain microbialite morphotypes using X-ray diffraction studies.[10]
Stromatolite microbial diversity
Foster has conducted research on stromatolites, with a particular focus on their characterization and astrobiological implications. While examining the diversity of cyanobacteria composing stromatolites located in Highbourne Cay, The Bahamas, her work has provided insights into the microbial diversity and ecology of stromatolites and revealed that the genetic diversity of the cyanobacterial populations within the stromatolites exceeds prior estimates, thereby indicating that the mechanisms underlying stromatolite formation and accretion may be more intricate than previously assumed.[11] Further, her study of present-day marine stromatolites in the Exuma Cays, in The Bahamas revealed a diverse and intricate array of microorganisms, whose spatial distribution appeared linked to the physical structure of the formations. It was suggested that distinct microorganisms performed distinct functions, contributing to the precipitation of calcium carbonate and facilitating the binding of sediment particles.[12] Her research on the microbial diversity in modern stromatolites highlighted the crucial role of metagenomic sequencing approaches in comprehending the molecular-level microbial diversity and functional complexity of these dynamic ecosystems, emphasizing that these approaches have facilitated a higher resolution characterization of stromatolite diversity and function.[13]
Awards and honors
- 2020 – Orr-Reynolds Service Award, American Society of Gravitational and Space Research[3]
- 2021 – President’s Award, American Society of Gravitational and Space Research[3]
Selected articles
- Visick, K. L., Foster, J., Doino, J., McFall-Ngai, M., & Ruby, E. G. (2000). Vibrio fischeri lux genes play an important role in colonization and development of the host light organ. Journal of Bacteriology, 182(16), 4578-4586.
- Kolenbrander, P. E., Andersen, R. N., Blehert, D. S., Egland, P. G., Foster, J. S., & Palmer Jr, R. J. (2002). Communication among oral bacteria. Microbiology and molecular biology reviews, 66(3), 486-505.
- Foster, J. S., & Kolenbrander, P. E. (2004). Development of a multispecies oral bacterial community in a saliva-conditioned flow cell. Applied and environmental microbiology, 70(7), 4340-4348.
- Belcaid, M., Casaburi, G., McAnulty, S. J., Schmidbaur, H., Suria, A. M., Moriano-Gutierrez, S., ... & Nyholm, S. V. (2019). Symbiotic organs shaped by distinct modes of genome evolution in cephalopods. Proceedings of the National Academy of Sciences, 116(8), 3030-3035.
- Zamkovaya, T., Foster, J. S., de Crécy-Lagard, V., & Conesa, A. (2021). A network approach to elucidate and prioritize microbial dark matter in microbial communities. The ISME journal, 15(1), 228-244.
References
- ^ a b c Communications, IFAS. "Jamie Foster - Microbiology and Cell Science, University of Florida - University of Florida, Institute of Food and Agricultural Sciences - UF/IFAS". microcell.ufl.edu.
- ^ "Jamie S. Foster". scholar.google.com.
- ^ a b c "ASGSR Awards – ASGSR".
- ^ a b "Jamie FOSTER | Professor (Full) | PhD | University of Florida, FL | UF | Department of Microbiology and Cell Science | Research profile".
- ^ "Potential of the Euprymna/Vibrio symbiosis as a model to assess the impact of microgravity on bacteria-induced animal development - Semantic Scholar".
- ^ Grant, Kyle C.; Khodadad, Christina L. M.; Foster, Jamie S. (January 5, 2014). "Role of Hfq in an animal–microbe symbiosis under simulated microgravity conditions". International Journal of Astrobiology. 13 (1): 53–61. doi:10.1017/S1473550413000359 – via Cambridge University Press.
- ^ "Host-Microbe Interactions in Microgravity: Assessment and Implications - PMC".
- ^ Myshrall, K. L.; Mobberley, J. M.; Green, S. J.; Visscher, P. T.; Havemann, S. A.; Reid, R. P.; Foster, J. S. (September 5, 2010). "Biogeochemical cycling and microbial diversity in the thrombolitic microbialites of Highborne Cay, Bahamas". Geobiology. 8 (4): 337–354. doi:10.1111/j.1472-4669.2010.00245.x. PMID 20491947 – via PubMed.
- ^ "Characterizing Modern Microbialites and The Geobiological Processes Underlying Their Formation | Frontiers Research Topic". www.frontiersin.org.
- ^ Paul, Varun G.; Wronkiewicz, David J.; Mormile, Melanie R.; Foster, Jamie S. (April 5, 2016). "Mineralogy and Microbial Diversity of the Microbialites in the Hypersaline Storr's Lake, the Bahamas". Astrobiology. 16 (4): 282–300. doi:10.1089/ast.2015.1326. PMID 27082142 – via PubMed.
- ^ Foster, Jamie S.; Green, Stefan J.; Ahrendt, Steven R.; Golubic, Stjepko; Reid, R. Pamela; Hetherington, Kevin L.; Bebout, Lee (May 5, 2009). "Molecular and morphological characterization of cyanobacterial diversity in the stromatolites of Highborne Cay, Bahamas". The ISME journal. 3 (5): 573–587. doi:10.1038/ismej.2008.129. PMID 19148145 – via PubMed.
- ^ Baumgartner, Laura K.; Spear, John R.; Buckley, Daniel H.; Pace, Norman R.; Reid, R. Pamela; Dupraz, Christophe; Visscher, Pieter T. (October 5, 2009). "Microbial diversity in modern marine stromatolites, Highborne Cay, Bahamas". Environmental Microbiology. 11 (10): 2710–2719. doi:10.1111/j.1462-2920.2009.01998.x. PMID 19601956 – via PubMed.
- ^ Foster, Jamie S.; Green, Stefan J. (May 5, 2011). Tewari, Vinod; Seckbach, Joseph (eds.). STROMATOLITES: Interaction of Microbes with Sediments. Springer Netherlands. pp. 383–405. doi:10.1007/978-94-007-0397-1_17 – via Springer Link.