Project description:Proteins regulate biological processes by changing their structure or abundance to accomplish a specific function. In response to any perturbation or stimulus, protein structure may be altered by a variety of molecular events, such as post translational modification, protein-protein interaction, aggregation, allostery, or binding to other molecules. The ability to probe these structural changes in thousands of proteins simultaneously in cells or tissues can provide valuable information about the functional state of a variety of biological processes and pathways. Here we present an updated protocol for LiP-MS, a proteomics technique combining limited proteolysis with mass spectrometry, to detect protein structural alterations in complex backgrounds and on a proteome-wide scale (Cappelletti et al., 2021; Piazza et al., 2020; Schopper et al., 2017). We describe advances in the throughput and robustness of the LiP-MS workflow and implementation of data-independent acquisition (DIA) based mass spectrometry, which together achieve high reproducibility and sensitivity, even on large sample sizes. In addition, we introduce MSstatsLiP, an R package dedicated to the analysis of LiP-MS data for the identification of structurally altered peptides and differentially abundant proteins. Altogether, the newly proposed improvements expand the adaptability of the method and allow for its wide use in systematic functional proteomic studies and translational applications.

Project description:Proteins regulate biological processes by changing their structure or abundance to accomplish a specific function. In response to any perturbation or stimulus, protein structure may be altered by a variety of molecular events, such as post translational modification, protein-protein interaction, aggregation, allostery, or binding to other molecules. The ability to probe these structural changes in thousands of proteins simultaneously in cells or tissues can provide valuable information about the functional state of a variety of biological processes and pathways. Here we present an updated protocol for LiP-MS, a proteomics technique combining limited proteolysis with mass spectrometry, to detect protein structural alterations in complex backgrounds and on a proteome-wide scale (Cappelletti et al., 2021; Piazza et al., 2020; Schopper et al., 2017). We describe advances in the throughput and robustness of the LiP-MS workflow and implementation of data-independent acquisition (DIA) based mass spectrometry, which together achieve high reproducibility and sensitivity, even on large sample sizes. In addition, we introduce MSstatsLiP, an R package dedicated to the analysis of LiP-MS data for the identification of structurally altered peptides and differentially abundant proteins. Altogether, the newly proposed improvements expand the adaptability of the method and allow for its wide use in systematic functional proteomic studies and translational applications.

Project description:LiP-MS was used to assess the structural impact of transmembrane domain mutations on the overall conformation of the mycobacterial cycase Rv1625c.

Project description:The deep marine subsurface is one of the largest unexplored biospheres on Earth, where members of the phylum Chloroflexi are abundant and globally distributed. However, the deep-sea Chloroflexi have remained elusive to cultivation, hampering a more thorough understanding of their metabolisms. In this work, we have successfully isolated a representative of the phylum Chloroflexi, designated strain ZRK33, from deep-sea cold seep sediments. Phylogenetic analyses based on 16S rRNA genes, genomes, RpoB and EF-tu proteins indicated that strain ZRK33 represents a novel class within the phylum Chloroflexi, designated Sulfochloroflexia. We present a detailed description of the phenotypic traits, complete genome sequence and central metabolisms of the novel strain ZRK33. Notably, sulfate and thiosulfate could significantly promote the growth of the new isolate, possibly through accelerating the hydrolysis and uptake of saccharides. Thus, this result reveals that strain ZRK33 may play a crucial part in sulfur cycling in the deep-sea environments. Moreover, the putative genes associated with assimilatory and dissimilatory sulfate reduction are broadly distributed in the genomes of 27 metagenome-assembled genomes (MAGs) from deep-sea cold seep and hydrothermal vents sediments. Together, we propose that the deep marine subsurface Chloroflexi play key roles in sulfur cycling for the first time. This may concomitantly suggest an unsuspected availability of sulfur-containing compounds to allow for the high abundance of Chloroflexi in the deep sea.

Project description:Protein–protein interactions (PPIs) mediate multiple essential functions and regulatory events in living organisms. The physical interactome of a given protein can be abnormally altered in response to external and internal cues, thus modulating cell physiology and contributing to human pathologies including neurodegenerative diseases. Despite substantial efforts, current approaches cannot pinpoint structure-specific PPIs or their interaction interfaces on a proteome-wide scale. To address this limitation, we have adapted the structural proteomics method known as limited proteolysis–mass spectrometry to identify PPIs by probing protein structural alterations within cellular extracts upon treatment with a protein of interest. We demonstrate the feasibility of our method by analysis of well-characterized PPIs between the respiratory syncytial virus F glycoprotein and its site-specific antibodies. Known antigenic sites were identified directly in complex biological matrices.

Project description:Integral membrane proteins (IMPs) are permanently embedded within the plasma membrane and execute multiple cellular functions. IMPs constitute important targets, but development of drugs that target IMPs to modulate protein–protein interactions, which mediate their functions, has been challenging. Characterizing the structural and functional properties of IMPs as well as their regulatory PPIs is a key step toward new or improved therapeutics. Functional and structural studies of IMPs are hindered by their hydrophobicity, low expression levels in cells, flexibility, and the need to use detergents to solubilize these proteins. Representative examples of IMPs are mammalian adenylyl cyclases that play a pivotal role in the 3',5'-cyclic adenosine monophosphate signaling pathway. The activity of membrane-bound adenylyl cyclases can be regulated by direct and/or indirect binding of calcium ions, for example, via calmodulin. Unstructured and highly flexible regions of adenylyl cyclases engage in PPIs. However, the principles of classical proteomics methods do not allow mapping interactions involving regions without a defined three-dimensional structure. To address this limitation, we used limited proteolysis–mass spectrometry (LiP–MS) to study the known interaction between the adenylyl cyclases AC8 and calmodulin by probing protein structural alterations in crude membrane suspensions treated with calmodulin. The LiP–MS analysis pinpointed putative binding site regions of AC8 previously shown to participate in the interaction with calmodulin, demonstrating that this method can be used to identify interaction domains in membrane proteins in a physiologically relevant context.

Project description:The aim of the project was to characterize structural changes that occur on the rod cyclic nucleotide-gated channel upon interaction with calmodulin (CaM) directly in the native membrane.

Project description:Parkinson’s disease (PD) is a neurodegenerative disorder associated with the accumulation of intraneuronal protein aggregates called Lewy bodies. These inclusions contain aberrantly folded and aggregated alpha-synuclein (aSyn), a key protein involved in the pathology of PD, for which the mechanisms of toxicity are still largely unknown. Recent studies suggest that the conformational changes occurring during aSyn aggregation process can be expected to lead to alterations in the interactome of aSyn. Therefore, identifying changes in the interactome of monomeric and aggregated states of aSyn could help to understand the underlying molecular mechanisms of PD. Despite substantial efforts, current interactomics approaches do not enable determining structure-specific PPIs and their interaction interfaces on a proteome-wide scale. To address this limitation, we here applied the structural proteomics method limited proteolysis–mass spectrometry to systematically identify structure-specific PPIs of aSyn by probing protein structural alterations within cellular extracts upon treatment with monomeric and aggregated, fibrillar states of aSyn. Overall, we identified several previously known interactors of both monomeric and aggregated aSyn as well as novel putative structure-specific interactors including their interaction interfaces and protein binding parameters in situ. These results may constitute an important step in the understanding of how distinct structural states of disease-associated proteins are involved in disease mechanisms.

Project description:Although genome-wide transcriptional analysis has been used for many years to study bacterial gene expression, many aspects of the bacterial transcriptome remain undefined. A prominent example is antisense transcription, which has been observed in a number of bacteria, though the function of antisense transcripts, and their distribution across the bacterial genome, is still unclear. Single-stranded RNA-seq results revealed a widespread and non-random pattern of antisense transcription covering more than two-thirds of the B. anthracis genome. Our analysis revealed a variety of antisense structural patterns, suggesting multiple mechanisms of antisense transcription. The data revealed several instances of sense and antisense expression changes in different growth conditions, suggesting that antisense transcription may play a role in the ways in which B. anthracis responds to its environment. Significantly, genome-wide antisense expression occurred at consistently higher levels on the lagging strand, while the leading strand showed very little antisense activity. Intrasample gene expression comparisons revealed a gene dosage effect in all growth conditions, where genes farthest from the origin showed the lowest overall range of expression for both sense and antisense directed transcription. Additionally, transcription from both strands was verified using a novel strand-specific assay. The variety of structural patterns we observed in antisense transcription suggests multiple mechanisms for this phenomenon, indicating that some antisense transcription may play a role in regulating the expression of key genes, while some may be due to chromosome replication dynamics and transcriptional noise. Four different growth conditions (cold challenge, ethanol challenge, osmotic challenge, control) with four replicates of one read on the bottom strand.

Project description:To elucidate frequencies of genomic structural alterations, we performed an analysis using a SNP genotyping array (Illumina HumanCytoSNP-12 v2.1 DNA Analysis BeadChip Kit) for iPS cells derived from xeroderma pigmentosum patients (XP3OS, XP40OS, and XPEMB-1). Samples were collected after 10 to 25 passages to detect structural mutations occurred during the cell cultivation processes. Our results suggested a higher mutation rate of the iPS cells compared to those from normal cells. The iPS-cell samples were collected after several passages togerther with their precursor cell samples and subjected to the SNP genotyping array. We searched for structural mutations occurred during the culture of the iPS cells.