Metagenomic and functional analysis of hindgut microbiota of a wood-feeding higher termite

Warnecke, Falk; Luginbühl, Peter; Ivanova, Natalia; Ghassemian, Majid; Richardson, Toby H.; Stege, Justin T.; Cayouette, Michelle; McHardy, Alice C.; Djordjević, Gordana; Aboushadi, Nahla; Sorek, Rotem; Tringe, Susannah G.; Podar, Mircea; Martín, Héctor García; Kunin, Victor; Dalevi, Daniel; Madejska, Julita; Kirton, Edward; Platt, Darren; Szeto, Ernest; Salamov, Asaf; Barry, Kerrie; Mikhailova, Natalia; Kyrpides, Nikos C.; Matson, Eric G.; Ottesen, Elizabeth A.; Zhang, Xinning; Hernández, Myriam; Murillo, Catalina; Acosta, Luis; Rigoutsos, Isidore; Tamayo, Giselle; Green, Brian D.; Chang, Cathy; Rubin, Edward M.; Mathur, Eric J.; Robertson, Dan E.; Hugenholtz, Philip; Leadbetter, Jared R.

doi:10.1038/nature06269

Cited by 1,157 publications

(1,163 citation statements)

References 63 publications

Supporting

Mentioning

1,079

Contrasting

Unclassified

Order By: Relevance

“…Glycoside hydrolase genes were also identified, and over 929 genes and modules were recovered from 47 different CAZy families (carbohydrate active enzymes). Although there were not significant differences in the abundance of debranching enzymes in comparisons of the GSM, giant panda 22 , tammar 23 and termite 24 hindguts, there were considerably more GH78 sequences in GSM. As in giant panda, the abundance of cellulases and endohemicellulases in GSM was generally lower than in human, cattle and termite (Supplementary Table 34).…”

Section: Stomach Metagenomics and Cellulose Metabolismmentioning

confidence: 73%

Whole-genome sequencing of the snub-nosed monkey provides insights into folivory and evolutionary history

et al. 2014

View full text Add to dashboard Cite

Colobines are a unique group of Old World monkeys that principally eat leaves and seeds rather than fruits and insects. We report the sequencing at 146× coverage, de novo assembly and analyses of the genome of a male golden snub-nosed monkey (Rhinopithecus roxellana) and resequencing at 30× coverage of three related species (Rhinopithecus bieti, Rhinopithecus brelichi and Rhinopithecus strykeri). Comparative analyses showed that Asian colobines have an enhanced ability to derive energy from fatty acids and to degrade xenobiotics. We found evidence for functional evolution in the colobine RNASE1 gene, encoding a key secretory RNase that digests the high concentrations of bacterial RNA derived from symbiotic microflora. Demographic reconstructions indicated that the profile of ancient effective population sizes for R. roxellana more closely resembles that of giant panda rather than its congeners. These findings offer new insights into the dietary adaptations and evolutionary history of colobine primates.Knowledge of the patterns and processes underlying the evolution of alternative dietary strategies in nonhuman primates is critical to understanding hominin evolution, nutritional ecology and applications in biomedicine 1 . Colobines, a group of Old World monkeys, serve as an important model organism for studying the evolution of the primate diet because of their adaptation to folivory: they primarily eat leaves and seeds rather than fruits and insects as their major food source. In their specialized and compartmentalized stomachs, colobines allow symbiotic bacteria in the foregut to ferment structural carbohydrates and then recover nutrients by digesting the bacteria 2 . This strategy is similar to that used by other foregut fermenters found in an evolutionarily distantly related group of mammals (for example, artiodactyls). Although a number of primate genomes have been sequenced thus far, high-quality genome sequence information is absent for Asian and African colobines, a key group for elucidating the evolution and adaptation of primates as a whole. Snub-nosed monkeys (Rhinopithecus species) are a group of endangered colobines, which were once widely distributed in Asia but are now limited to mountain forests in China and Vietnam 3 (Supplementary Fig. 1).The golden snub-nosed monkey (GSM, R. roxellana) is recognized as an iconic endangered species in China for its golden coat, blue facial coloration, snub nose and specialized life history. Among its congeners, the black-white snub-nosed monkey (R. bieti), endemic to the Tibetan plateau, has the highest altitudinal distribution (>4,000 m above sea level) of any nonhuman primate. Given the above features and the fact that Rhinopithecus species consume difficult-to-digest foods that contain tannins (for example, leaves and pine seeds), we expected to identify genetic adaptations that enhance the breakdown of toxins, improve the regulation of energy metabolism and facilitate the digestion of symbiotic microbacteria. RESULTS Genomic sequences and the accumulation of...

show abstract

Section: Stomach Metagenomics and Cellulose Metabolismmentioning

confidence: 73%

Whole-genome sequencing of the snub-nosed monkey provides insights into folivory and evolutionary history

et al. 2014

View full text Add to dashboard Cite

show abstract

“…Information on their GH profiles was obtained from the CAZy database (http://www.cazy.org/). Analysis of GH families not included in the original publications was carried out as described by Warnecke et al (2007).…”

Section: Linking Genomics and Metagenomics Data To Nutrition And Othementioning

confidence: 99%

Rumen microbial (meta)genomics and its application to ruminant production

Morgavi

Kelly

Janssen

et al. 2013

Animal

203

163

View full text Add to dashboard Cite

Meat and milk produced by ruminants are important agricultural products and are major sources of protein for humans. Ruminant production is of considerable economic value and underpins food security in many regions of the world. However, the sector faces major challenges because of diminishing natural resources and ensuing increases in production costs, and also because of the increased awareness of the environmental impact of farming ruminants. The digestion of feed and the production of enteric methane are key functions that could be manipulated by having a thorough understanding of the rumen microbiome. Advances in DNA sequencing technologies and bioinformatics are transforming our understanding of complex microbial ecosystems, including the gastrointestinal tract of mammals. The application of these techniques to the rumen ecosystem has allowed the study of the microbial diversity under different dietary and production conditions. Furthermore, the sequencing of genomes from several cultured rumen bacterial and archaeal species is providing detailed information about their physiology. More recently, metagenomics, mainly aimed at understanding the enzymatic machinery involved in the degradation of plant structural polysaccharides, is starting to produce new insights by allowing access to the total community and sidestepping the limitations imposed by cultivation. These advances highlight the promise of these approaches for characterising the rumen microbial community structure and linking this with the functions of the rumen microbiota. Initial results using high-throughput culture-independent technologies have also shown that the rumen microbiome is far more complex and diverse than the human caecum. Therefore, cataloguing its genes will require a considerable sequencing and bioinformatic effort. Nevertheless, the construction of a rumen microbial gene catalogue through metagenomics and genomic sequencing of key populations is an attainable goal. A rumen microbial gene catalogue is necessary to understand the function of the microbiome and its interaction with the host animal and feeds, and it will provide a basis for integrative microbiome–host models and inform strategies promoting less-polluting, more robust and efficient ruminants.

show abstract

“…For confirmatory studies, 'synthetic metagenomics' [112] can be employed to synthesize predicted genes or the genes can be mined from the actual metagenomic libraries via PCR analysis using specific oligonucleotide probes [113]. Sequence homology-based metagenomic screening has been employed to identify CAZymes [50,51,114], but only one of such experiments have resulted in the functional characterization of AcXEs [51]. However, considering their sequence similarities with other non-AcXE CEs, sequence homology-predicted AcXEs may not provide accurate information on functional properties.…”

Section: Mining Metagenomes For Novel Acxesmentioning

confidence: 99%

Phylogeny, classification and metagenomic bioprospecting of microbial acetyl xylan esterases

Adesioye

Makhalanyane

Biely

et al. 2016

Enzyme and Microbial Technology

View full text Add to dashboard Cite

Highlights• AcXEs occur in several CAZy families, and show promiscuous substrate specificities.• A strong AcXE sequence to specificity link would be a valuable functional predictor.• There is a clear need for novel AcXE enzymes with detailed substrate specificity data.• Functional metagenomics would be the most effective means for identifying new AcXEs.• A lack of suitable substrates limits high throughput metagenomic biomining of AcXEs.

show abstract

Metagenomic and functional analysis of hindgut microbiota of a wood-feeding higher termite

Cited by 1,157 publications

References 63 publications

Whole-genome sequencing of the snub-nosed monkey provides insights into folivory and evolutionary history

Whole-genome sequencing of the snub-nosed monkey provides insights into folivory and evolutionary history

Rumen microbial (meta)genomics and its application to ruminant production

Phylogeny, classification and metagenomic bioprospecting of microbial acetyl xylan esterases

Contact Info

Product

Resources

About