Martin Mehnert scite author profile

Reproducibility in research can be compromised by both biological and technical variation, but most of the focus is on removing the latter. Here we investigate the effects of biological variation in HeLa cell lines using a systems-wide approach. We determine the degree of molecular and phenotypic variability across 14 stock HeLa samples from 13 international laboratories. We cultured cells in uniform conditions and profiled genome-wide copy numbers, mRNAs, proteins and protein turnover rates in each cell line. We discovered substantial heterogeneity between HeLa variants, especially between lines of the CCL2 and Kyoto varieties, and observed progressive divergence within a specific cell line over 50 successive passages. Genomic variability has a complex, nonlinear effect on transcriptome, proteome and protein turnover profiles, and proteotype patterns explain the varying phenotypic response of different cell lines to Salmonella infection. These findings have implications for the interpretation and reproducibility of research results obtained from human cultured cells.

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Der1 promotes movement of misfolded proteins through the endoplasmic reticulum membrane

Mehnert

2013

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Misfolded proteins of the secretory pathway are extracted from the endoplasmic reticulum (ER), polyubiquitylated by a protein complex termed the Hmg-CoA reductase degradation ligase (HRD-ligase) and degraded by cytosolic 26S proteasomes. The movement of these proteins through the lipid bilayer is assumed to occur via a protein conducting channel of unknown nature. We show that the integral membrane protein Der1 oligomerises which relies on its interaction with the scaffolding protein Usa1. Mutations in the transmembrane domains of Der1 block the passage of soluble proteins across the ER-membrane. As determined by site-specific photocrosslinking the ER-luminal exposed parts of Der1 are in spatial proximity to the substrate receptor Hrd3 whereas the membrane-embedded domains reside adjacent to the ubiquitin ligase Hrd1. Intriguingly, both regions also form crosslinks to client proteins. In summary our data imply that Der1 initiates the export of aberrant polypeptides from the ER-lumen by threading such molecules into the ER-membrane and routing them to Hrd1 for ubiquitylation.

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Protein dislocation from the ER

Bagola

Mehnert

Jarosch

et al. 2011

Biochimica et Biophysica Acta (BBA) - Biomembranes

113

109

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Protein folding within the endoplasmic reticulum (ER) of eukaryotic cells is erroneous and often results in the formation of terminally malfolded species. A quality control system retards such molecules in the ER and eventually initiates their dislocation into the cytosol for proteolysis by 26S proteasomes. This process is termed ER associated protein degradation (ERAD). The spatial separation of ER based quality control and cytosolic proteolysis poses the need for a machinery that promotes the extraction of substrates from the ER. Due to the heterogeneous nature of the client proteins this transport system displays several unique features. Selective recognition of ERAD substrates does not involve transferable transport signals in the primary sequence and thus must follow other principles than established for proteins designated for the import into organelles. Moreover, an ER dislocation system must be capable to ship polypeptides, which may be at least partly folded and are in most cases covalently modified with bulky and hydrophilic glycans, through a membrane without disrupting the integrity of the ER. In this review we present current ideas on the highly dynamic and flexible nature of the dislocation apparatus and speculate on the mechanism that removes aberrant polypeptides from the ER in the course of ERAD. This article is part of a Special Issue entitled Protein translocation across or insertion into membranes.

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Kinase Interaction Network Expands Functional and Disease Roles of Human Kinases

et al. 2020

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Summary Protein kinases are essential for signal transduction and control of most cellular processes, including metabolism, membrane transport, motility, and cell cycle. Despite the critical role of kinases in cells and their strong association with diseases, good coverage of their interactions is available for only a fraction of the 535 human kinases. Here, we present a comprehensive mass-spectrometry-based analysis of a human kinase interaction network covering more than 300 kinases. The interaction dataset is a high-quality resource with more than 5,000 previously unreported interactions. We extensively characterized the obtained network and were able to identify previously described, as well as predict new, kinase functional associations, including those of the less well-studied kinases PIM3 and protein O-mannose kinase (POMK). Importantly, the presented interaction map is a valuable resource for assisting biomedical studies. We uncover dozens of kinase-disease associations spanning from genetic disorders to complex diseases, including cancer.

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Combining Rapid Data Independent Acquisition and CRISPR Gene Deletion for Studying Potential Protein Functions: A Case of HMGN1

Mehnert

et al. 2019

Proteomics

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CRISPR‐Cas gene editing holds substantial promise in many biomedical disciplines and basic research. Due to the important functional implications of non‐histone chromosomal protein HMG‐14 (HMGN1) in regulating chromatin structure and tumor immunity, gene knockout of HMGN1 is performed by CRISPR in cancer cells and the following proteomic regulation events are studied. In particular, DIA mass spectrometry (DIA‐MS) is utilized, and more than 6200 proteins (protein‐ FDR 1%) and more than 82 000 peptide precursors are reproducibly measured in the single MS shots of 2 h. HMGN1 protein deletion is confidently verified by DIA‐MS in all of the clone‐ and dish‐ replicates following CRISPR. Statistical analysis reveals 147 proteins change their expressions significantly after HMGN1 knockout. Functional annotation and enrichment analysis indicate the deletion of HMGN1 induces histone inactivation, various stress pathways, remodeling of extracellular proteomes, cell proliferation, as well as immune regulation processes such as complement and coagulation cascade and interferon alpha/ gamma response in cancer cells. These results shed new lights on the cellular functions of HMGN1. It is suggested that DIA‐MS can be reliably used as a rapid, robust, and cost‐effective proteomic‐screening tool to assess the outcome of the CRISPR experiments.

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Martin Mehnert

Multi-omic measurements of heterogeneity in HeLa cells across laboratories

Der1 promotes movement of misfolded proteins through the endoplasmic reticulum membrane

Protein dislocation from the ER

Kinase Interaction Network Expands Functional and Disease Roles of Human Kinases

Combining Rapid Data Independent Acquisition and CRISPR Gene Deletion for Studying Potential Protein Functions: A Case of HMGN1

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