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  • Microbiology and Molecular Genetics

    • Cindy Arvidson
    • Dennis Arvidson
    • Michael Bagdasarian
    • Rob Britton
    • Todd Ciche
    • Frank Dazzo
    • George Garrity
    • Robert Hausinger
    • Julius Jackson
    • Kaz Kashefi
    • Jay Lennon
    • Richard Lenski
    • Linda Mansfield
    • Terry Marsh
    • Martha Mulks
    • C. A. Reddy
    • Gemma Reguera
    • Thomas Schmidt
    • Mike Thomashow
    • James Tiedje
    • Edward (Ned) Walker
    • Thomas Whittam
    • Barry Williams

    Kellogg Biological Station

    • Phil Robertson
    • Jay Lennon

    Center for Advancing Microbial Risk Assessment (CAMRA)

    • Joan Rose

    Animal Science

    • Paul Coussens

    Biochemistry and Molecular Biology

    • Christoph Benning
    • Shelagh Ferguson-Miller
    • Eric Hegg
    • Rawle Hollingsworth
    • Jon Kaguni
    • Lee Kroos
    • Claire Vieille
    • William Wedemeyer
    • Greg Zeikus  

    Biomedical Laboratory Diagnostics

    • Steven Cendrowski

    Chemistry

    • John Frost
    • James Gieger

    Chem. Eng. & Materials Sci.

    • Mark Worden

    Civil & Environ. Eng.

    • Sayed Hasham

    Computer Science & Eng.

    • Titus Brown
    • Charles Ofria

    Food Science and Human Nutrition

    • John Linz
    • Jim Pestka

    Medicine, CHM 

    • Mary Nettleman

     

    Pediatrics, CHM

    • Dele Davies
    • Shannon Manning
    • Stephen Obaro

     

    Physics

    • Tim Tessmer

    Plant Biology

    • Andrew Jarosz
    • Sheng Yang He
    • Jonathon Walton
    • Peter Wolk

    Plant Pathology

    • Richard Allison
    • George Sundin

    Vet. Pathobiol. Diag. Invest.

    • Carol Bolin
    • Steve Bolin

    Zoology

    • Nathaniel Ostrum
    • Peggy Ostrum
  • Target
    • Emerging Infectious Diseases
    • Microbial Population and Community Dynamics
    • Bioenergy and Biobased-technologies
    • Metabolomics in Microbes and Microbial Communities
    • Genomic Evolution
    • Archaea, the Third Domain of Life
    • Microbial Biogeochemistry

    Emerging Infectious Diseases

    There is wide recognition of the need for rapid evaluation and study of the emerging pathogens that threaten our food and water. Many of the recent disease outbreaks are associated with microbial pathogens (E. coli O157, Campylobacter, Salmonella, Listeria, and norovirus) that are often transmitted via food and water. The metagenomic approach can be applied to the microbial communities that exist in the critical animal and environmental reservoirs of human pathogens. By elucidating the full composition and dynamics of these communities, metagenomics will create an understanding of the factors that contribute to the emergence and spread of new pathogens. The MSS proposes a new faculty position for a researcher with expertise and interests in microbial ecology, microbial genomics, and/or infectious diseases to join faculty investigating food and waterborne infectious diseases caused by microbial pathogens.

    Microbial Population and Community Dynamics

    This field examines quantitative, qualitative, and temporal aspects of population dynamics, species diversity and interactions in microbial communities in specific environments. The tools of metagenomics form an important part of this analysis. A complete understanding of how an ecosystem functions requires that we integrate all components ñ microbes, water cycle, energy flow, mineral cycle, etc ñ within the framework of dynamic populations and communities that change over ecological and evolutionary timescales. The perspective of community dynamics enables us to go beyond mere descriptions of organisms and their environments. We can now begin to construct, evolve, manage, and otherwise manipulate microbial populations and communities to enable sustainable agriculture and enhanced bio-energetic production. A microbial systems-level approach, including metagenomics, will be instrumental to predictive ecosystem function and succession in changing environments. This approach also provides tools for the manipulation of native microbial populations and communities in situ and in laboratory settings. Communities of particular interest include cellulose-degrading microbial consortia for bioenergy generation from waste as well as microbial communities that promote bioremediation of contaminants.

    Bioenergy and Biobased-technologies

    The energy crisis offers a tremendous opportunity to develop novel technologies for the use of sustainable, domestic resources to provide fuel, power, and chemical needs from plants and plant-derived materials. Increased funding is available for developing and improving technologies for biomass power; for making biofuels (such as ethanol from biomass residues as well as grain) and renewable diesel; and for making plastics and chemicals from renewable, biobased materials. Indeed, MSU was recently awarded its largest grant ever for such research as part of the new Great Lakes Bioenergy Research Center (GLBRC). Of foremost importance is the study of the microbial populations and communities that process biomass in the relevant environments. Additionally, it is critical to develop new strains and consortia of microbes for enhanced bioprocessing capabilities and increased efficiency of energetic conversion, probably by using a combination of targeted genetic engineering and experimental evolution approaches (as currently being planned for the GLBRC) . Three potential areas of expertise for future hires include: a geneticist devoted to engineering and evolving fermentative organisms for increased biomass degradation and enhanced biofuel production, a biological engineer with expertise in microbial fuel cells, and an environmental microbiologist using metagenomics analysis to analyze microbial diversity and the energetic yields of natural consortia.

    Metabolomics in Microbes and Microbial Communities

    Metabolites include the intermediary and end products of gene expression in any organism. The metabolome, therefore, represents the set of all metabolites produced by a given organism. The burgeoning field of metabolomics emphasizes the numerous small, but fundamentally important, molecules that are the building-blocks and by-products of metabolism. The interactions of metabolites within and between species are of particular importance in microbial communities, where some metabolites may promote coexistence of species while others (including antibiotics) serve as potent inhibitors of competing species. Specific cellular processes leave behind unique chemical fingerprints, and metabolomic techniques can be used to explore these important interactions and relationships. This position would have a strong focus on analytical chemistry tools for characterizing and quantifying metabolites, on integrated data analysis for interpreting metabolic interactions and networks, or both. For example, nuclear magnetic resonance and mass spectrometric methods would likely play a critical role in allowing comprehensive measurements of cellular components, while the mathematical integration and analysis of genomic, proteomic, transcriptomic, and metabolomic information can provide a more complete and dynamic picture of a living organism or microbial community than is possible using any single approach. An individual working in this area would ideally integrate laboratory experimentation with mathematical modeling, and would interact closely with the Quantitative Biology and Modeling Initiative at MSU.

    Genomic Evolution

    This area encompasses some of the most fundamental questions in biology as well as areas of tremendous biomedical and economic importance, including in developing new approaches related to bioenergy and strain improvement. Investigators in this field address issues ranging from the history of life to the mechanisms of adaptation and diversification while relating their findings to food safety, the emergence of new pathogens, and the spread of antibiotic resistance. The successful candidate might study evolutionary processes that structure the genomes of Bacteria, Archaea, or unicellular Eukaryotes, while addressing fundamental questions concerning, for example, genome organization, roles of horizontal gene transfer, molecular mechanisms of recombination and mutation, minimal genomes, selfish DNA, or the origin of gene regulons and networks. Experimental approaches to genomic evolution have seen particular interest and success in recent years on several fronts, including to address basic questions about the dynamics of evolution, for tracking genome-wide changes in microbial pathogens, and for strain improvement for technological purposes, including bioenergy, where leading research groups are increasingly combining genetic engineering and experimental evolution strategies. Of particular interest in all these areas are questions related to evolvability and robustness. What genomic features ñ such as biochemical pathways that govern mutation rates, and gene-regulatory networks that influence patterns of gene interaction ñ promote rapid evolution, as would be desirable for strain improvement? And how does evolvability affect the robustness of an organism to environmental and genetic perturbations, and thus the stability of the desired phenotype? This position will complement those groups involved in microbial evolution and microbial genomics at MSU.

    Archaea, the Third Domain of Life

    The study of the Archaea, which includes many organisms that live in extreme environments, will yield a vast range of novel physiological and biochemical features, undoubtedly including some with great biotechnological potential. The study of extremophilic organisms in this Domain represents a significant gap in research not only at MSU but also nationwide. In addition to basic questions related to the mechanisms of growth and survival of thermophilic, acidophilic, and halophilic representatives, this extensive group of microbes has been a rich resource for the isolation of novel enzymes of industrial interest. This position would encompass integrative research extending from metagenomes in extreme environments to the analysis of the biochemistry of the archaeal proteome and metabolome. The overarching goals would include exploration and discovery for biotechnological applications, while broadening our current understanding of both physiological diversity and evolutionary mechanisms.

    Microbial Biogeochemistry

    Microorganisms in the earth and in water play essential roles related to global climate change and stability, nutrient pollution and management, waste recycling and bioremediation. Biogeochemical processes are a major focus of NSF and DOE microbial programs. Many economically valuable geologic deposits from oils to ores result from or are enhanced by microbial activity. A position in this area will continue MSU's long tradition in ecosystem studies centered on the carbon, nitrogen, and sulfur cycles, and may extend that expertise to mineralization and geological fingerprinting, which is of particular interest in the search for evidence of early life processes on earth and on other planets. Furthermore, research in soil and water microbial ecosystems forms a critical component of the efficiency of plant growth, which will be a key part of emerging efforts to develop a sustainable bioeconomy.

  • The MSS initiative is organized around three overlapping, interdisciplinary thrusts:

    Important issues being addressed in these areas are as follows.

    Analysis of the role of microbial communities in human, animal and plant health and disease using the tools of metagenomics, microbial physiology and bioinformatics. This addresses the NIH Microbiome Roadmap Initiative and programs in infectious diseases (Human Medical Departments, Biological Sciences). Emergence of new pathogens with special emphasis on food and waterborne diseases of zoonotic and environmental origin (Center for Microbial Pathogenesis, National Food Safety and Toxicology Center, Food Science and Human Nutrition, Institute of Water Research).

    Metagenomic analysis of soil, aquatic, and plant associated microbial organisms with the objective of understanding and then developing sustainable agroecosystems (Plant Sciences and KBS).Integrative science for the development of a competitive, microbially-based bioeconomy, including biofuels, chemicals and pharmaceuticals (Applied Microbiology, Engineering, Chemistry, Plant Sciences, etc.).

    Metagenomic analysis, manipulation and modeling of native microbial communities for use in bioremediation of contaminated sites (Environmental Microbiology, Microbial Ecology, Computer Science, Biochemistry, Chemistry, Geology and Engineering).

    MSU Bioinformatics Center (including the Ribosomal Database Program and Genome Consortium (Garrity)) to develop computer-based systems biology and bioinformatics studies of microbial interactions as discovered by metagenomic analysis (Ribosomal Database, Microbiology, Computer Science, Chemistry and Biochemistry).

    Microbial and metabolic diversity of extreme environments with the objective of ìminingî organisms for useful heat and/or chemical tolerant enzymes and proteins (Microbiology, Crop and Soil Science).

    Microbial physiology and experimental evolution in artificial environments including microbial fuel cells, bioreactors, etc both to develop new functionalities and discover fundamental principles (Microbiology, Engineering and Biophysics, Physics).

  • Summary

    The MSS is an interdisciplinary, cross-college initiative that draws together researchers from colleges and departments in such diverse fields as the biological and medical sciences, physics, mathematics, computer science and engineering. This program focuses on the systematic study of the complex interactions at multiple biological scales from biochemical networks to ecological communities. This unique perspective on microbiological systems will drive new knowledge towards research programs impacting contemporary societal issues ranging from sustainable agriculture and bioenergy to food safety and infectious diseases.

    Statement of the goals: Recent advances in genomics, proteomics and computer science has provided microbial science with the capacity to understand the details of the physiology (metabolism) of individual microbes and the evolution of genes and genomes in various common and extreme environments, and in infectious disease processes. Challenging questions involve the integration of the activity of networks of organisms (microbial consortia and biofilms) and their genes throughout the biosphere and in the human microbiome.

    The innovative tools of metagenomics allow complete genetic analysis of entire microbial communities and provide insights into the extreme diversity of life forms from sites as diverse as soil and the human intestinal tract. The strategy of metagenomics is a cornerstone of the MSS initiative, and it forms an important new part of modern microbiology. Such metagenomic analysis cited herein will be followed by the intensive use of bioinformatics and functional analysis of complex interacting systems. The proposed study of the intricate balance of microbial communities will help elucidate the evolution and activity of the immense genetic diversity that encodes the metabolic pathways of microbes. These complex microbial systems sustain all life on earth and, at other times, pose significant threats to life during infectious process.

  • Overview

    Initiative Bioenergy & Bioeconomy Microbial Ecology and Evolution Microbiome & Infectious Disease
    Partner groups: Microbiology & Molecular Genetics, Plant and Soil Sciences , Engineering/Physical Sciences, Biochemistry and biological sciences MMG, Kellogg Biological Station, Center for Microbial Ecology, Center for Terrestrial Microbiology, EEBB MMG, Center for Food Safety and Toxicology Deptís Medicine and Pediatrics
    Impact on Science and/or Health: Bioenergy/Bioeconomy ,  fermentation, microbial cellulase and ligninase, fuel cells Archaea, extremophiles, microbe-microbe interactions Rhizosphere and bioremediation, microbe plant interactions , Archaea, extremophiles, microbe-microbe interactions Human microbial ecosystems, food safety , probiotic foods and additives, pathogenesis, infectious disease, microbe-microbe interactions
    Mission: Production of biofuels, substrates for pharma, and industry, nanodevices Bioinformatics, sustainable agriculture, bioremediation Bioinformatics, human genome and microbiome, management of disease, disease prevention and health.
    College level partners: MAES, CNS, CVM, CHM, COM; Federal funding partners: DOE, NSF, NIH, USDA, DOD, EPA
    Common Tools:Bioinformatics, Genomics, Metagenomics, Metabolomics, Proteomics, Evolution.