Metagenomic analysis of uncultured Cytophaga and beta-1,4 glycanases in marine consortia

Culture-independent studies have shown that microbial consortia in natural environments are incredibly diverse and are dominated by bacteria and archaea substantially different from microbes maintained in pure laboratory cultures. Recent studies indicate, however, that previous culture-independent s...

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Bibliographic Details
Main Author: Kirchman, David
Other Authors: United States. Department of Energy. Office of Science.
Format: Report
Language:English
Published: David Kirchman, University of Delaware 2005
Subjects:
Dna
Mineralization
Carbon Storage
Cellulose
Chitin
Functionals
59 Basic Biological Sciences
Environmental Genomics
58 Geosciences
Carbon Cycle
Genes
Cellulase
Arctic Ocean
54 Environmental Sciences
Ecogenomics
Bacteria
Carbon Cycles
Organic Matter Carbon Storage
Arctic
Online Access:https://doi.org/10.2172/861432
http://digital.library.unt.edu/ark:/67531/metadc791518/
Description
Summary:Culture-independent studies have shown that microbial consortia in natural environments are incredibly diverse and are dominated by bacteria and archaea substantially different from microbes maintained in pure laboratory cultures. Recent studies indicate, however, that previous culture-independent studies using PCR-based methods have largely overlook an important group of uncultured bacteria, the Cytophagales. These bacteria appear to be abundant in the oceans and probably other oxic environments. Although well known to be active in degradation of structural glycans such as cellulose and chitin, no cellulase or chitinase gene has been sequenced from a Cytophaga, except those recently found by whole genome sequencing of Cytophaga hutchinsonii by the DOE Joint Genome Institute (JGI). We hypothesize that the key to understanding consortia and their function in organic matter mineralization in oxic environments is to focus on uncultured Cytophagales, genes encoding endoglycanases, and other functional genes. The ''metagenomic'' approach used by this project consisted of constructing large insert libraries with DNA directly (no PCR) from uncultured microbial consortia found in the Arctic Ocean and Delaware Estuary. Our results provide insights into new types of bacterial metabolisms which have not considered adequately before, but which may change our views of the global carbon cycle.

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