The phylum Fibrobacteres currently comprises one formal genus, Fibrobacter, and two cultured species, Fibrobacter succinogenes and Fibrobacter intestinalis, that are recognised as major bacterial degraders of lignocellulosic material in the herbivore gut. Historically, members of the genus Fibrobacter were thought to only occupy mammalian intestinal tracts. However, recent 16S rRNA gene-targeted molecular approaches have demonstrated that novel centres of variation within the genus Fibrobacter are present in landfill sites and freshwater lakes, and their relative abundance suggests a potential role for fibrobacters in cellulose degradation beyond the herbivore gut. Furthermore, a novel subphylum within the Fibrobacteres has been detected in the gut of wood-feeding termites, and proteomic analyses have confirmed their involvement in cellulose hydrolysis. The genome sequence of F. succinogenes rumen strain S85 has recently suggested that within this group of organisms a "third" way of attacking the most abundant form of organic carbon in the biosphere, cellulose, has evolved. This observation not only has evolutionary significance, but the superior efficiency of anaerobic cellulose hydrolysis by Fibrobacter spp., in comparison to other cellulolytic rumen bacteria that typically utilise membrane-bound enzyme complexes (cellulosomes), may be explained by this novel cellulase system. There are few bacterial phyla with potential functional importance for which there is such a paucity of phenotypic and functional data. In this review, we highlight current knowledge of the Fibrobacteres phylum, its taxonomy, phylogeny, ecology and potential as a source of novel glycosyl hydrolases of biotechnological importance.
Oligonucleotide sequences selected from the 163 rRNA genes of various species of ammonia-oxidizing bacteria were evaluated as specif ic PCR amplification primers and probes. The spedficities of primer pairs for eubacterial, Nitmsospira and Nibrosomones rRNA genes were established with sequence databases, and the primer pairs were used to amplify DNA from laboratory cultures and environmental samples. Eubacterial rRNA genes amplified from samples of soil and activated sludge hybridized with an oligonucleotide probe specific for Nifmsospifa Spp.8 but not with a Nitmsomonas-specif ic probe. Lakewater and sediment samples were analysed using a nested PCR technique in which eubacterial rRNA genes were subjected to a secondary amplification with Nifmsomnas or Nitrosospira specific primers. Again, the presence of Nifmsospira DNA, but not Nitmsomonas DNA, was detected and this was confirmed by hybridization of the amplified DNA with an internal oligonucleotide probe. Enrichments of lakewater and sediment samples, incubated for two weeks in the presence of ammonium, produced nitrite and were found to contain DNA from both Nitmsospira and Nitmsomonas as determined by nested PCR amplification and probing of 163 rRNA genes. This demonstrates that Nifmsospira spp. are widespread in the environment. The implications of the detection of Nitmsomnas DNA only after enrichment culture are discussed.
A verocytotoxigenic bacteriophage isolated from a strain of enterohemorrhagic Escherichia coli O157, into which a kanamycin resistance gene (aph3) had been inserted to inactivate the verocytotoxin gene (vt 2 ), was used to infect Enterobacteriaceae strains. A number of Shigella and E. coli strains were susceptible to lysogenic infection, and a smooth E. coli isolate (O107) was also susceptible to lytic infection. The lysogenized strains included different smooth E. coli serotypes of both human and animal origin, indicating that this bacteriophage has a substantial capacity to disseminate verocytotoxin genes. A novel indirect plaque assay utilizing an E. coli recA441 mutant in which phage-infected cells can enter only the lytic cycle, enabling detection of all infective phage, was developed.Verocytotoxigenic Escherichia coli (VTEC) is a serious pathogen of considerable public health concern worldwide. Infection is usually characterized by bloody diarrhea and can be life threatening due to the subsequent development of hemolytic-uremic syndrome mediated by verocytotoxins (VTs), of which there are two forms, VT1 and VT2. In almost all cases, the VT genes are carried on temperate bacteriophages (VT phages). Although E. coli O157 is the most commonly isolated VTEC serogroup in the United Kingdom, North America, and Japan, more than 30 disease-causing non-0157 VTECs have been described (1) and over 100 serotypes are capable of producing VT (6). VT production has been observed in other members of the Enterobacteriaceae, including Enterobacter cloacae (8) and Citrobacter freundii (12), but was first described in Shigella dysenteriae as Shiga toxin (3). The localization of vt genes on a bacteriophage was first described by Smith et al. (13), but their acquisition by pathogenic E. coli strains remained anomalous because only nonpathogenic (rough) E. coli strains could apparently be infected with VT phage. Previously, the vt 2 gene of a bacteriophage (24 B ), isolated from an E. coli O157 strain, had been inactivated by insertion of a selectable marker (kanamycin resistance) (10). This provided an ideal opportunity to investigate the host range of a lysogenic VT bacteriophage and thus its potential to transfer the ability to produce VT between E. coli and related gram-negative bacteria.The host range of this recombinant VT2 phage (24 B ::Kan) was determined by infection of pathogenic and commensal strains of E. coli and other Enterobacteriaceae strains from human and animal sources. Lysogens were detected by spreading phage-infected cultures of the host bacteria (100 l) onto Luria-Bertani Miller (LB) agar (Difco) plates containing kanamycin (50 g ml Ϫ1 ). As it is clear that some phage infections create lysogens and do not result in a lytic infection, plaque assays may not necessarily detect all infectious phage particles. Induction of the VT phage lytic cycle is RecA dependent (7). RecA plays a central role in the SOS response of E. coli, during which phage-mediated lysis is induced. The recA441 mutant E. coli K-12 strain...
Microbial ecology provides insights into the ecological and evolutionary dynamics of microbial communities underpinning every ecosystem on Earth. Microbial communities can now be investigated in unprecedented detail, although there is still a wealth of open questions to be tackled. Here we identify 50 research questions of fundamental importance to the science or application of microbial ecology, with the intention of summarising the field and bringing focus to new research avenues. Questions are categorised into seven themes: host-microbiome interactions; health and infectious diseases; human health and food security; microbial ecology in a changing world; environmental processes; functional diversity; and evolutionary processes. Many questions recognise that microbes provide an extraordinary array of functional diversity that can be harnessed to solve real-world problems. Our limited knowledge of spatial and temporal variation in microbial diversity and function is also reflected, as is the need to integrate micro- and macro-ecological concepts, and knowledge derived from studies with humans and other diverse organisms. Although not exhaustive, the questions presented are intended to stimulate discussion and provide focus for researchers, funders and policy makers, informing the future research agenda in microbial ecology.
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