Integrating multiple ‘omics’ analysis for microbial biology: application and methodologies

Zhang, Weiwen; Li, Feng; Nie, Lei

doi:10.1099/mic.0.034793-0

Cited by 410 publications

(257 citation statements)

References 150 publications

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“…Transcriptomics is an excellent tool to quantify the relative abundance of mRNA levels in a single cell or a population of cells. Unlike a genomic approach, it offers a more exhaustive view of the genes that are being actively expressed in response to particular environmental conditions and thus can be employed to identify putative gene targets that can be engineered to augment lipid content in microalgae (Liu and Benning, 2012;Zhang et al, 2010). In this regard, the first de novo transcriptomics study on a potential biofuel algal feedstock, D. tertiolecta, revealed a repertoire of enzymes involved in the biosynthesis and catabolism of fatty acids, TAG, and starch (Rismani-Yazdi et al, 2011).…”

Section: Agrigenomics For Microalgal Biofuelmentioning

confidence: 99%

Agrigenomics for Microalgal Biofuel Production: An Overview of Various Bioinformatics Resources and Recent Studies to Link OMICS to Bioenergy and Bioeconomy

Misra

Panda²,

Parida³

2013

OMICS: A Journal of Integrative Biology

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Microalgal biofuels offer great promise in contributing to the growing global demand for alternative sources of renewable energy. However, to make algae-based fuels cost competitive with petroleum, lipid production capabilities of microalgae need to improve substantially. Recent progress in algal genomics, in conjunction with other ''omic'' approaches, has accelerated the ability to identify metabolic pathways and genes that are potential targets in the development of genetically engineered microalgal strains with optimum lipid content. In this review, we summarize the current bioeconomic status of global biofuel feedstocks with particular reference to the role of ''omics'' in optimizing sustainable biofuel production. We also provide an overview of the various databases and bioinformatics resources available to gain a more complete understanding of lipid metabolism across algal species, along with the recent contributions of ''omic'' approaches in the metabolic pathway studies for microalgal biofuel production.

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Section: Agrigenomics For Microalgal Biofuelmentioning

confidence: 99%

Agrigenomics for Microalgal Biofuel Production: An Overview of Various Bioinformatics Resources and Recent Studies to Link OMICS to Bioenergy and Bioeconomy

Misra

Panda²,

Parida³

2013

OMICS: A Journal of Integrative Biology

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“…Refinements on gene identification and annotation methods will help to mitigate possible differences. In addition, several factors may explain transcriptome and proteome differences, such as post-translational modifications, half-lives of mRNA and proteins, and detection limits for both technologies (Zhang et al, 2010).…”

Section: Discussionmentioning

confidence: 99%

Development of an ecophysiological model for Diplosphaera colotermitum TAV2, a termite hindgut Verrucomicrobium

et al. 2013

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Termite hindguts are populated by a dense and diverse community of microbial symbionts working in concert to transform lignocellulosic plant material and derived residues into acetate, to recycle and fix nitrogen, and to remove oxygen. Although much has been learned about the breadth of microbial diversity in the hindgut, the ecophysiological roles of its members is less understood. In this study, we present new information about the ecophysiology of microorganism Diplosphaera colotermitum strain TAV2, an autochthonous member of the Reticulitermes flavipes gut community. An integrated high-throughput approach was used to determine the transcriptomic and proteomic profiles of cells grown under hypoxia (2% O 2 ) or atmospheric (20% O 2 ) concentrations of oxygen. Our results revealed that genes and proteins associated with energy production and utilization, carbohydrate transport and metabolism, nitrogen fixation, and replication and recombination were upregulated under 2% O 2 . The metabolic map developed for TAV2 indicates that this microorganism may be involved in biological nitrogen fixation, amino-acid production, hemicellulose degradation and consumption of O 2 in the termite hindgut. Variation of O 2 concentration explained 55.9% of the variance in proteomic profiles, suggesting an adaptive evolution of TAV2 to the hypoxic periphery of the hindgut. Our findings advance the current understanding of microaerophilic microorganisms in the termite gut and expand our understanding of the ecological roles for members of the phylum Verrucomicrobia.

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“…To some extent this limitation has been resolved by the development of the field of metagenomics [2] and single cell genomics. Metagenome sequencing, coupled with other "omic" technologies, such as transcriptomics (measuring of mRNA transcript levels), proteomics (study of the protein complement) and metabolomics (study of cellular metabolites), has led to the development of sophisticated systems biology approaches [3] which facilitate the combinatorial study of microbial community functions and their interactions within, and with, the environment. To date, more than 5,000 full metagenomes and over 16,000 amplicon libraries (Metagenomics RAST server; http://metagenomics.anl.gov; publically available metagenomes as of December 2014) have been sequenced and analysed, covering a broad cross-section of the Earth"s biomes.…”

Section: Introductionmentioning

confidence: 99%

Metagenomics of extreme environments

Cowan¹,

Ramond²,

Makhalanyane³

et al. 2015

Current Opinion in Microbiology

116

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Whether they are exposed to extremes of heat, cold, or buried deep beneath the Earth"s surface, microorganisms have an uncanny ability to survive under these conditions. This ability to survive has fascinated scientists for nearly a century, but the recent development of metagenomics and "omics tools has allowed us to make huge leaps in understanding the remarkable complexity and versatility of extremophile communities. Here, in the context of the recently developed metagenomic tools, we discuss recent research on the community composition, adaptive strategies and biological functions of extremophiles.

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Integrating multiple ‘omics’ analysis for microbial biology: application and methodologies

Cited by 410 publications

References 150 publications

Agrigenomics for Microalgal Biofuel Production: An Overview of Various Bioinformatics Resources and Recent Studies to Link OMICS to Bioenergy and Bioeconomy

Agrigenomics for Microalgal Biofuel Production: An Overview of Various Bioinformatics Resources and Recent Studies to Link OMICS to Bioenergy and Bioeconomy

Development of an ecophysiological model for Diplosphaera colotermitum TAV2, a termite hindgut Verrucomicrobium

Metagenomics of extreme environments

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