Proteogenomics of rare taxonomic phyla: A prospective treasure trove of protein coding genes

Kumar, Dhirendra; Mondal, Anupam; Kutum, Rintu; Dash, Debasis

doi:10.1002/pmic.201500263

Cited by 12 publications

(11 citation statements)

References 130 publications

(120 reference statements)

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“…However, for this task, proteogenomic methods rely on custom genomic databases, other than the annotated reference proteome, to discover novel peptides indicative of novel translated regions . While genomic databases such as six frame translated genome or ab initio predicted genes may include majority of the novel translation possibilities for a prokaryotic genome , it would have a limited representation of protein isoforms possible from a eukaryotic genome . Proteomic diversity of a eukaryote is largely attributed to alternative mRNA splicing .…”

Section: Transcriptome As a Template For Proteomics Data Analysismentioning

confidence: 99%

Integrating transcriptome and proteome profiling: Strategies and applications

et al. 2016

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Discovering the gene expression signature associated with a cellular state is one of the basic quests in majority of biological studies. For most of the clinical and cellular manifestations, these molecular differences may be exhibited across multiple layers of gene regulation like genomic variations, gene expression, protein translation and post-translational modifications. These system wide variations are dynamic in nature and their crosstalk is overwhelmingly complex, thus analyzing them separately may not be very informative. This necessitates the integrative analysis of such multiple layers of information to understand the interplay of the individual components of the biological system. Recent developments in high throughput RNA sequencing and mass spectrometric (MS) technologies to probe transcripts and proteins made these as preferred methods for understanding global gene regulation. Subsequently, improvements in "big-data" analysis techniques enable novel conclusions to be drawn from integrative transcriptomic-proteomic analysis. The unified analyses of both these data types have been rewarding for several biological objectives like improving genome annotation, predicting RNA-protein quantities, deciphering gene regulations, discovering disease markers and drug targets. There are different ways in which transcriptomics and proteomics data can be integrated; each aiming for different research objectives. Here, we review various studies, approaches and computational tools targeted for integrative analysis of these two high-throughput omics methods.

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Section: Transcriptome As a Template For Proteomics Data Analysismentioning

confidence: 99%

Integrating transcriptome and proteome profiling: Strategies and applications

et al. 2016

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“…Peptide information obtained by tandem mass spectrometry may help to establish the presence of a given gene encoding a new polypeptide or better define the translation initiation site of numerous proteins [111]. The integration of proteomics and genomics data collected on the same microorganisms is of interest for detecting such errors and improving the genome annotation quality [112,113], especially for rare taxonomic phyla [114]. Specific proteogenomic experiments could be performed in the future for exploring whether toxin-producing microorganisms are well genome annotated and further characterizing their toxin potential.…”

Section: Proteogenomics Metaproteomics and New Tools For A More mentioning

confidence: 99%

Advanced Proteomics as a Powerful Tool for Studying Toxins of Human Bacterial Pathogens

Duport

Alpha-Bazin

Armengaud

2019

Toxins

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Exotoxins contribute to the infectious processes of many bacterial pathogens, mainly by causing host tissue damages. The production of exotoxins varies according to the bacterial species. Recent advances in proteomics revealed that pathogenic bacteria are capable of simultaneously producing more than a dozen exotoxins. Interestingly, these toxins may be subject to post-transcriptional modifications in response to environmental conditions. In this review, we give an outline of different bacterial exotoxins and their mechanism of action. We also report how proteomics contributed to immense progress in the study of toxinogenic potential of pathogenic bacteria over the last two decades.

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“…It is therefore straightforward to use ribosomal proteins as biomarkers for bacterial typing by comparison with known gene sequences and their variations. One of the prerequisites of this approach is, however, that the proteins assumed behind the mass peaks of the MALDI‐TOF spectrum have been verified that may be a challenging task . Once identified, the observed mass shifts in comparison to other isolates can be correlated with sequence variations of the respective genes and typing schemes can be implemented on this basis.…”

Section: Combination Of MI With Genetic Sequence Datamentioning

confidence: 99%

Current developments to use linear MALDI‐TOF spectra for the identification and typing of bacteria and the characterization of other cells/organisms related to infectious diseases

Karger

2016

Proteomics Clinical Apps

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Within the past few years identification of bacteria by MALDI-TOF MS has become a standard technique in bacteriological laboratories for good reasons. MALDI-TOF MS identification is rapid, robust, automatable, and the per-sample costs are low. Yet, the spectra are very informative and the reliable identification of bacterial species is usually possible. Recently, new MS-based approaches for the identification of bacteria are emerging that are based on the detailed analysis of the bacterial proteome by high-resolution MS. These "proteotyping" approaches are highly discriminative and outperform MALDI-TOF MS-based identification in terms of specificity, but require a laborious proteomic workflow and far more expertise and sophisticated instrumentation than identification on basis of MALDI-TOF MS spectra, which can be obtained with relative simple and uncostly linear MALDI-TOF mass spectrometers. Thus MALDI-TOF MS identification of bacteria remains an attractive option for routine diagnostics. Additionally, MALDI-TOF MS identification protocols have been extended and improved in many respects making linear MALDI-TOF MS a versatile tool that can be useful beyond the identification of a bacterial species, e.g. for the characterization of leucocytes and arthropod vectors of infectious diseases. This review focuses on such improvements and extensions of the typical MALDI-TOF MS workflow in the field of infectious diseases.

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Proteogenomics of rare taxonomic phyla: A prospective treasure trove of protein coding genes

Cited by 12 publications

References 130 publications

Integrating transcriptome and proteome profiling: Strategies and applications

Integrating transcriptome and proteome profiling: Strategies and applications

Advanced Proteomics as a Powerful Tool for Studying Toxins of Human Bacterial Pathogens

Current developments to use linear MALDI‐TOF spectra for the identification and typing of bacteria and the characterization of other cells/organisms related to infectious diseases

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