Capturing protein communities by structural proteomics in a thermophilic eukaryote:Structural systems biology of lysates

The arrangement of proteins into complexes is a key organizational principle for many cellular functions. Although the topology of many complexes has been systematically analyzed in isolation, their molecular sociology in situ remains elusive. Here, we show that crude cellular extracts of a eukaryotic thermophile, Chaetomium thermophilum, retain basic principles of cellular organization. Using a structural proteomics approach, we simultaneously characterized the abundance, interactions, and structure of a third of the C. thermophilum proteome within these extracts. We identified 27 distinct protein communities that include 108 interconnected complexes, which dynamically associate with each other and functionally benefit from being in close proximity in the cell. Furthermore, we investigated the structure of fatty acid synthase within these extracts by cryoEM and this revealed multiple, flexible states of the enzyme in adaptation to its association with other complexes, thus exemplifying the need for in situ studies. As the components of the captured protein communities are known-at both the protein and complex levels-this study constitutes another step forward toward a molecular understanding of subcellular organization

Reduced proteasome activity in the aging brain results in ribosome stoichiometry loss and aggregation.

A progressive loss of protein homeostasis is characteristic of aging and a driver of neurodegeneration. To investigate this process quantitatively, we characterized proteome dynamics during brain aging in the short-lived vertebrate Nothobranchius furzeri combining transcriptomics and proteomics. We detected a progressive reduction in the correlation between protein and mRNA, mainly due to post-transcriptional mechanisms that account for over 40% of the age-regulated proteins. These changes cause a progressive loss of stoichiometry in several protein complexes, including ribosomes, which show impaired assembly/disassembly and are enriched in protein aggregates in old brains. Mechanistically, we show that reduction of proteasome activity is an early event during brain aging and is sufficient to induce proteomic signatures of aging and loss of stoichiometry in vivo. Using longitudinal transcriptomic data, we show that the magnitude of early life decline in proteasome levels is a major risk factor for mortality. Our work defines causative events in the aging process that can be targeted to prevent loss of protein homeostasis and delay the onset of age-related neurodegeneration

Charakterisierung der Variation von Proteinkomplexen und funktionellen Modulen im zeitlichen Kontext und zwischen Individuen

A fundamental question in current biology concerns the translational mechanisms leading from genetic variability to phenotypes. Technologies have evolved to the extent that they can efficiently and economically determine an individual’s genomic composition, while at the same time big data on clinical profiles and diagnostics have substantially accumulated. Genome-wide association studies linking genomic loci to certain traits, however, remain limited in their capacity to explain the cellular mechanisms that underlie the given association. For most associations, gene expression has been blamed; yet given that transcript and protein abundance oftentimes do not correlate, that finding does not necessarily decrypt the underlying mechanism. Thus, the integration of further information is crucial to establish a model that could prove more accurate in predicting genotypic effects on the human organism. In this work we describe the so-called proteotype as a feature of the cell that could provide a substantial link between genotype and phenotype. Rather than looking at the proteome as a set of independent molecules, we demonstrate a consistent modular architecture of the proteome that is driven by molecular cooperativity. Functional modules, especially protein complexes, can be further interrogated for differences between individuals and tackled as imprints of genetic and environmental variability. We also show that subtle stoichiometric changes of protein modules could have broader effects on the cellular system, such as the transport of specific molecular cargos. The presented work also delineates to what extent temporal events and processes influence the stoichiometry of protein complexes and functional modules. The re-wiring of the glycolytic pathway for example is illustrated as a potential cause for an increased Warburg effect during the ageing of the human bone marrow. On top of analyzing protein abundances we also interrogate proteome dynamics in terms of stability and solubility transitions during the short temporal progression of the cell cycle. One of our main observations in the thesis encompass the delineation of protein complexes into respective sub-complexes according to distinct stability patterns during the cell cycle. This has never been demonstrated before, and is functionally relevant for our understanding of the dis- and assembly of large protein modules. The insights presented in this work imply that the proteome is more than the sum of its parts, and primarily driven by variability in entire protein ensembles and their cooperative nature. Analyzing protein complexes and functional modules as molecular reflections of genetic and environmental variations could indeed prove to be a stepping stone in closing the gap between genotype and phenotype and customizing clinical treatments in the future.Eine fundamentale Frage in der heutigen biologischen Forschung ist durch welche Mechanismen eine gebenene genetische Variation sich in einem Phänotyp äußert. Etliche Technologien können heutzutage effizient und ökonomisch die genomische Komposition eines Individuals mit beispielloser Genaugikeit aufschlüsseln. Gleichzeitig gibt es wesentliche Erfolge und Bemühungen, große Datenmengen von Patienten zu sammeln, sowohl klinische Profile, als auch Diagnosen. Es gibt bereits mehrere genomweite Assoziationsstudien, die auf spezifische genomische Loci hinweisen, die womöglich einem bestimmenten phänotypischen Merkmalen zugrunde liegen. Obwohl für die meisten genetischen Assoziationen, eine veränderte Genexpression oftmals als Ursache diskutiert wird, ist dies wahrscheinlich nur ein Teil des zugrundeliegenden Mechanismus. Wir können dies annehmen, da RNA-Transkripte nicht unbedingt mit ihrem Protein-Produkt korrelieren aufgrund von post-transkriptioneller und translationeller Regulation. Um dementsprechend ein Modell zu etablieren, das die genotypischen Effekte auf den human Organismus akkurat vorhersagen kann, ist eine Integration von mehreren zellulären Informationsschichten notwendig. In der folgenden Arbeit beschreiben wir den sogenannten Proteotyp als ein zelluläres Merkmal, das eine substanzielle Verknüpfung zwischen dem Genotyp und dem Phänotyp eines Individuums schaffen könnte. Statt das Proteom als ein Set unabhängiger Moleküle zu betrachten, zeigen wir eine konsistent moduläre Architektur des Proteoms auf, das durch die molekulare Kooperativität zustande kommt. Funktionelle Module, v.a. Proteinkomplexe, können weiters auf Unterschiede zwischen Individuen untersucht werden, sowie deren Variabilität aufgrund genetischer oder umweltbedingter Ursachen. Wir demonstrieren u.a. auch, dass leichte stöchiometrische Veränderungen in solchen Modulen zu weitläufigen Effekten im zellulären Haushalt führen können, z.B. im Transport von spezifischen Molekülen. Die vorgestellte Arbeit beschreibt allerdings auch inwieweit temporäre Ereignisse und Prozesse die Stöchiometrie von Proteinkomplexen und funktionellen Modulen beeinflussen. Wir zeigen z.B. auf, dass eine Veränderung in der glycolytischen Enzym-Stöchiometrie die Ursache für den Warburgeffekt in gealterten Zellen des humanen Knochenmarks darstellen könnte. Neben der Analyse von Protein-Abundanzen untersucht die vorliegende Arbeit Proteomdynamik auch in Hinblick auf Stabilitäts- und Löslichkeitsveränderungen von Proteine in kürzeren Zeitabläufen wie den Zellzyklus. Wir können dabei feststellen, dass Untereinheiten von größeren Proteinkomplexen verschiedene Stabilitätsmuster aufweisen. Dies ist durchaus eine neue Erkennis, die weittragende Folgen für unser Verständnis des Ab- und Aufbauprozesses von Proteinkomplexen haben könnte. Die Einblicke, die aus dieser Arbeit gewonnen werden können, implizieren in jedem Falle, dass das Proteom mehr als die Summe der Einzelteile darstellt, und hauptsächlich durch die Variabilität von gesamten Proteinensembls und deren Kooperativität bestimmt wird. Proteinkomplexe und funktionelle Module sollten daher als molekulare Reflektionen von genetisch- und umweltbedingter Variation betrachtet werden. Solch ein Perspektivenwechsel könnte damit die Möglichkeit bieten eine mechanistische Verknüpfung von Genotyp und Phänotyp zu gewährleisten, und ein Fundament für zukünftige individuell angepasste klinische Behandlungen darstellen

A Staphylococcus aureus Proteome Overview: Shared and Specific Proteins and Protein Complexes from Representative Strains of All Three Clades

Staphylococcus aureus is an important model organism and pathogen. This S. aureus proteome overview details shared and specific proteins and selected virulence-relevant protein complexes from representative strains of all three major clades. To determine the strain distribution and major clades we used a refined strain comparison combining ribosomal RNA, MLST markers, and looking at highly-conserved regions shared between strains. This analysis shows three sub-clades (A–C) for S. aureus. As calculations are complex and strain annotation is quite time consuming we compare here key representatives of each clade with each other: model strains COL, USA300, Newman, and HG001 (clade A), model strain N315 and Mu50 (clade B) and ED133 and MRSA252 (clade C). We look at these individual proteomes and compare them to a background of 64 S. aureus strains. There are overall 13,284 S. aureus proteins not part of the core proteome which are involved in different strain-specific or more general complexes requiring detailed annotation and new experimental data to be accurately delineated. By comparison of the eight representative strains, we identify strain-specific proteins (e.g., 18 in COL, 105 in N315 and 44 in Newman) that characterize each strain and analyze pathogenicity islands if they contain such strain-specific proteins. We identify strain-specific protein repertoires involved in virulence, in cell wall metabolism, and phosphorylation. Finally we compare and analyze protein complexes conserved and well-characterized among S. aureus (a total of 103 complexes), as well as predict and analyze several individual protein complexes, including structure modeling in the three clades

The killing of human gut commensal E. coli ED1a by tetracycline is associated with severe ribosome dysfunction

Ribosomes translate the genetic code into proteins. Recent technical advances have facilitated in situ structural analyses of ribosome functional states inside eukaryotic cells and the minimal bacterium Mycoplasma. However, such analyses of Gram-negative bacteria are lacking, despite their ribosomes being major antimicrobial drug targets. Here we compare two E. coli strains, a lab E. coli K-12 and human gut isolate E. coli ED1a, for which tetracycline exhibits bacteriostatic and bactericidal action, respectively. The in situ ribosome structures upon tetracycline treatment show a virtually identical drug binding-site in both strains, yet the distribution of ribosomal complexes clearly differs. While K-12 retains ribosomes in a translation competent state, tRNAs are lost in the vast majority of ED1a ribosomes. A differential response is also reflected in proteome-wide abundance and thermal stability assessment. Our study underlines the need to include molecular analyses and to consider gut bacteria when addressing antibiotic mode of action

Co-translational binding of importins to nascent proteins

Abstract Various cellular quality control mechanisms support proteostasis. While, ribosome-associated chaperones prevent the misfolding of nascent chains during translation, importins were shown to prevent the aggregation of specific cargoes in a post-translational mechanism prior the import into the nucleoplasm. Here, we hypothesize that importins may already bind ribosome-associated cargo in a co-translational manner. We systematically measure the nascent chain association of all importins in Saccharomyces cerevisiae by selective ribosome profiling. We identify a subset of importins that bind to a wide range of nascent, often uncharacterized cargoes. This includes ribosomal proteins, chromatin remodelers and RNA binding proteins that are aggregation prone in the cytosol. We show that importins act consecutively with other ribosome-associated chaperones. Thus, the nuclear import system is directly intertwined with nascent chain folding and chaperoning

Species comparison of liver proteomes reveals links to naked mole-rat longevity and human aging

BACKGROUND: Mammals display a wide range of variation in their lifespan. Investigating the molecular networks that distinguish long- from short-lived species has proven useful to identify determinants of longevity. Here, we compared the livers of young and old long-lived naked mole-rats (NMRs) and the phylogenetically closely related, shorter-lived, guinea pigs using an integrated omics approach. RESULTS: We found that NMR livers display a unique expression pattern of mitochondrial proteins that results in distinct metabolic features of their mitochondria. For instance, we observed a generally reduced respiration rate associated with lower protein levels of respiratory chain components, particularly complex I, and increased capacity to utilize fatty acids. Interestingly, we show that the same molecular networks are affected during aging in both NMRs and humans, supporting a direct link to the extraordinary longevity of both species. Finally, we identified a novel detoxification pathway linked to longevity and validated it experimentally in the nematode Caenorhabditis elegans. cONCLUSIONS: Our work demonstrates the benefits of integrating proteomic and transcriptomic data to perform cross-species comparisons of longevity-associated networks. Using a multispecies approach, we show at the molecular level that livers of NMRs display progressive age-dependent changes that recapitulate typical signatures of aging despite the negligible senescence and extraordinary longevity of these rodents

Co-translational assembly orchestrates competing biogenesis pathways.

During the co-translational assembly of protein complexes, a fully synthesized subunit engages with the nascent chain of a newly synthesized interaction partner. Such events are thought to contribute to productive assembly, but their exact physiological relevance remains underexplored. Here, we examine structural motifs contained in nucleoporins for their potential to facilitate co-translational assembly. We experimentally test candidate structural motifs and identify several previously unknown co-translational interactions. We demonstrate by selective ribosome profiling that domain invasion motifs of beta-propellers, coiled-coils, and short linear motifs may act as co-translational assembly domains. Such motifs are often contained in proteins that are members of multiple complexes (moonlighters) and engage with closely related paralogs. Surprisingly, moonlighters and paralogs assemble co-translationally in only some but not all of the relevant biogenesis pathways. Our results highlight the regulatory complexity of assembly pathways