Project description:Temperature sensitive (TS) missense mutants have been foundational in the characterization essential gene function. However, an unbiased approach for the analysis of the biochemical and biophysical changes in TS missense mutants within the context of their functional proteomes is lacking. We applied mass spectrometry (MS) based thermal proteome profiling (TPP) to investigate the proteome-wide effects of missense mutations in a specific application that we refer to as mutant Thermal Proteome Profiling (mTPP). This study characterized the global changes in mRNA abundance, protein abundance, and protein thermal stability as a result of missense mutants within two subunits of the yeast ubiquitin-proteasome system. Global protein abundance measurements and RNA sequencing data resulted in a large number of possible candidates that could be causing the phenotypic changes observed in the mutant strains. The additional information gained from mTPP along with complementary proteomic and transcriptomic experiments allows for multiomic intersection analysis that may reveal interesting regulatory categories to pursue in follow-up mechanistic experiments.

Project description:Temperature sensitive(TS)missense mutants have been foundational in the characterization of the function of essential genes due to their pronounced cellular phenotypes that are likely associated with protein functional disruption. However, an unbiased approach for the analysis of the biochemical and biophysical changes in missense mutants within the context of their functional proteomes is lacking. We applied mass spectrometry (MS) based thermal proteome profiling (TPP)to investigate the proteome-wide effects of missense mutations in a specific application of TPP that we refer to as mutant Thermal Proteome Profiling (mTPP). This study characterized the global changes in mRNA abundance, protein abundance, and protein thermal stability as a result of missense mutants within two subunits of the yeast ubiquitin-proteasome system. Global protein abundance measurements and RNA sequencing data resulted in a large number of possible candidates that could be causing the phenotypic changes observed in the mutant strains. The additional information gained from mTPP along with complementary proteomic and transcriptomic experiments allows for multiomic intersection analysis that may reveal interesting regulatory categories to pursue in follow-up mechanistic experiments.

Project description:Temperature sensitive Mutant Proteome Profiling: a novel tool for the characterization of the global impacts of missense mutants on the proteome

Project description:We performed two dimensional thermal proteome profiling (2D-TPP) in Escherichia coli mutants to measure changes in abundance and thermal stability.

Project description:Aging is associated with the decline of protein, cell, and organ function. Here, we use an integrated approach to characterize gene expression, bulk translation, and cell biology in the brains and livers of young and old rats. We identify 468 differences in protein abundance between young and old animals. The majority are a consequence of altered translation output, that is, the combined effect of changes in transcript abundance and translation efficiency. In addition, we identify 130 proteins whose overall abundance remains unchanged but whose sub-cellular localization, phosphorylation state, or splice-form varies. While some protein-level differences appear to be a generic property of the rats’ chronological age, the majority are specific to one organ. These may be a consequence of the organ’s physiology or the chronological age of the cells within the tissue. Taken together, our study provides an initial view of the proteome at the molecular, sub-cellular, and organ level in young and old rats.

Project description:Streptococcus agalactiae is one of the most important pathogens associated with outbreaks of streptococcis in Nile tilapia farms around the world. High water temperature (above 27°C) have been described as factor predisposing for disease in fish. On the other hand, at low temperature (below 25°C) fish mortalities are no usually observed in farms. The temperature variation can modulate the expression of genes and proteins involved with metabolism, adaptation and bacterial pathogenicity, increasing or decreasing the host susceptibility to infection. The aim of this study was to evaluate the transcriptome and proteome of fish-pathogenic S. agalactiae strain (SA53) submitted to in vitro growth under different temperatures using microarray and label-free shotgun LC-HDMSE approach, and to compare the expression trends of proteins shared among GBS strains from different hosts (SA53 and NEM316). Biological triplicates of isolates were cultured in BHIT broth at 22°C or 32°C for RNA and protein isolation and submitted to transcriptomic and proteomic analysis. Total of 1730 transcripts were identified in SA53, being 107 genes differentially expressed among the temperature evaluated. A higher number of genes related with metabolism were detected as up-regulated proteins at 32°C, mainly PTS system and ABC transport system. In proteome analysis, 1046 proteins were identified in SA53 strain, being 81 proteins differentially regulated at 22 and 32ºC. Proteins involved in Defense mechanisms (V), Lipid transport and metabolism (I), and Nucleotide transport and metabolism (F) were up-regulated at 32ºC. A higher number of interactions was observed in the category F. The induction of genes/proteins involved in virulence were detected in both temperatures evaluated. A low correlation between transcriptome and proteome datasets was observed. And there is a distinct adaptation between fish and human GBS strains at the proteome level. Our study showed that the transcriptome and proteome of fish-adapted GBS strain are modulated by temperature, especially regulating the differential expression of genes/proteins involved with metabolism, adaptation and virulence, and revealing a host specificity at proteome regulation for human and fish hosts

Project description:Eukaryotic gene expression is controlled at the transcriptional, translational and protein degradation level and its principles are starting to emerge. While transcriptional outcomes, which are commonly also used as a proxy for protein abundance, have been investigated on a larger scale, the study of translational output requires large-scale proteomics data. However, data for proteome alterations by systematic assessment of knockouts genome-wide is not available yet. We here determined the individual proteome changes for  3,308 non-essential genes in the yeast S. pombe (www.butterlab.org/SpProtQuant). We observed that genes with high proteome remodeling are predominantly involved in gene expression regulation, in particular acting as translational regulators. Focusing on those knockout strains with a large number of altered proteins, we performed paired transcriptome/proteome measurements to uncover translational regulators and features of translational regulation. Furthermore, by similarity clustering of these proteome changes, we infer gene functionality that can be extended to other species such as human or baker’s yeast.

Project description:Bacteria regulate their cellular resource allocation to enable their fast growth-adaptation to a variety of environmental niches. We studied the ribosomal allocation, growth and expression profile of two sets of fast-growing mutants of Escherichia coli K-12 MG1655. Mutants with 3 copies of the stronger ribosomal RNA operons grew faster than the wild-type strain in minimal media and show similar phenotype to previously studied rpoB mutants. All of them displayed increased ribosomal content, a longer diauxic shift and a reduced activity of the aceBAK operon, indicative of repressed gluconeogenic pathways. Transcriptomic profiles of fast-growing mutants showed common downregulation of hedging functions and upregulated growth functions. Proteome allocation estimations showed an increase in the growth-related proteome for fast-growing strains, but not an increased cellular budget for recombinant protein production. These results show that two different regulatory perturbations (rRNA promoters or rpoB mutations) increasing ribosomal allocation optimize the proteome for growth with a concomitant fitness cost.

Project description:The deregulation of complex diseases often spans multiple molecular processes. A multimodal functional characterization of these processes can shed light on the disease mechanisms and the effect of drugs. Thermal Proteome Profiling (TPP) is a mass-spectrometry based technique assessing changes in thermal protein stability that can serve as proxies of functional changes of the proteome. These unique insights of TPP can complement those obtained by other omics technologies. Here, we show how TPP can be integrated with phosphoproteomics and transcriptomics in a network-based approach using COSMOS, a framework for causal integration of multi-omics, to provide an integrated view of transcription factors, kinases and proteins with altered thermal stability. This allowed us to recover known mechanistic consequences of PARP inhibition in ovarian cancer cells on cell cycle and DNA damage response in detail and to uncover new insights into drug response mechanisms related to interferon and hippo signaling. We found that TPP complements the other omics data and allowed us to obtain a network model with higher coverage of the main underlying mechanisms. These results illustrate the added value of TPP, and more generally the power of network models to integrate the information provided by different omics technologies. We anticipate that this strategy can be used to broadly integrate functional proteomics with other omics to study complex molecular processes.

Project description:This SuperSeries is composed of the following subset Series: GSE38356: The mRNA-bound proteome and its global occupancy profile on protein-coding transcripts [RNA-seq] GSE38201: The mRNA-bound proteome and its global occupancy profile on protein-coding transcripts [PAR-CLIP] GSE38355: The mRNA-bound proteome and its global occupancy profile on protein-coding transcripts [protein occupancy profiling] Refer to individual Series