GeoChip for microbial community analysis

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GeoChip for microbial community analysis Zhili
He Institute for Environmental
Genomics Department of Botany and
Microbiology University of Oklahoma Email
zhili.he_at_ou.edu Phone 405-325-3958 March 23,
2007
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An example of problems Carbon transformation and
transport in soil
http//www.climatescience.gov/
Global climate change

• C, N, P, and S cyclings
• Microbial structure and function
• Metabolic cooperation
• Plant-microbe interactions

The scientific evidence is clear global climate
change caused by human activities is occurring
now, and it is a growing threat to society.
Released on the AAAS Annual Meeting in December
2006.
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Objective 4 Understanding rhizosphere microbial
communities and plant-microbe interactions

• Isolation of cellulose-degrading and
  ethanol-producing microbes
• Metagenomic analysis of rhizosphere microbial
  communities
• Development and application of functional gene
  microarrays for microbial community analysis
• Prediction of effects of changes in plant-microbe
  interactions on the environment, such as global
  warming

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Fundamental scientific questions

• How does plant diversity (LIHD vs HILD) affect
  microbial function, diversity and stability?
• How do microbial communities affect feedstock
  productivity and stability/sustainability?
• Can microbial communities improve feedstock
  productivity and stability/sustainability?
• Will changes in plant-microbe interactions have
  significant impacts on the environment, such as
  global warming?

LIHD low-input and high-diversity HILD
high-input and low-diversity
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Challenges for microbial community studies

• Small in size
• Extremely high diversity and complexity, 5000
  species/g soil
• 99 of the microbial species are uncultured
• Rapid adaptation to environmental changes
• Metabolic versatility and flexibility

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Main approaches

• Metagenomics and community sequencing
• Functional gene microarrays
• Stable isotope probing (SIP)
• Evolution

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Metagenomics

• Knowledge
• Structure and functions
• Metabolic co-operations
• Plant-microbe interactions

• Biotechnology
• Novel biocatalysts
• Natural drug compounds
• Novel genes/enzymes

Daniel. 2004. Curr Opin Biotechnol 5 199-204.
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454 pyrosequencing
Soil samples
DNA extraction

• 20-100 Mb/run, and 5,000-10,000/run.
• An average microbial genome size 4.0 Mb.
• Finish in a half day.

Margulies et al. 2005. Nature 437 376-380.
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Summary of GeoChip 3.0 probe and sequence
information by category
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Generic and specific applications

• Survey for any environmental samples soil,
  water, sediments, oil fields, deep sea, animal
  guts, etc.
• Linking microbial structures to
  functions/activities.
• Detection of functional genes and/or organisms
  in a particular environment.
• Geochemical cyclings C, N, S and P.
• Estimation of gene abundance and activity.

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GeoChip monitoring in situ bioremediation of
uranium
He et al., 2007, ISME (in press).
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What are expected from this study?
Knowledge of microbial ecology and systems
biology microbial and plant diversity, metabolic
co-operation, plant-microbe interaction, and
global climate change.
Resources for biotechnology a discovery of novel
genes/enzymes (e.g. cellulase) and natural
metabolites (e.g. drugs), and biofules (e.g.
ethanol).
Training 10 graduates, 20 undergraduate, and
10 postdocs.
Deliverables 5-10 highly-profile publications,
useful research resources (e.g. metagenomic
libraries), and a new version of GeoChip.