Discovering Bioactive Peptides and Characterizing the Molecular Pathways that Control Their Activity

Mitchell, Andrew

15 August 2012

Bioactive peptides constitute a major class of signaling molecules in animals and have been shown to play a role in diverse physiological processes, including hypertension, appetite and sleep. As a result, knowing the identity of these molecules and understanding the mechanisms by which they are regulated has basic and medical significance. In this dissertation, I describe the development and application of novel methods for discovering bioactive peptides and the molecular pathways that control their activity. Recent analyses of mammalian RNAs have revealed the translation of numerous short open reading frames (sORFs). However, it is unknown whether these translation events produce stable polypeptide products that persist in the cell at functionally relevant concentrations. In Chapter 1, I describe a study in which we used a novel mass spectrometry-based strategy to directly detect sORF-encoded polypeptides (SEPs) in human cells. This analysis identified 115 novel SEPs, which is the largest number of mammalian SEPs discovered in a single study by more than a factor of 25. We observed widespread translation of SEPs from non-canonical RNA contexts, including polycistronic mRNAs and sORFs defined by non-AUG start codons. We also found that SEPs possess properties characteristic of functional proteins, such as stable expression, high cellular copy numbers, post-translational modifications, sub-cellular localization, the ability to participate in specific protein-protein interactions and the ability to influence gene expression. Taken together, these findings provide the strongest evidence to date that coding sORFs constitute a significant human gene class. In chapter 3, I describe a study in which we combine quantitative in vivo peptidomics, classical biochemical experiments and pharmacological studies in animal models to elucidate the metabolism of the neuropeptide substance P in the spinal cord. We identified two physiological substance P metabolites: the N- terminal fragments SP(1-9) and SP(1-7). Focusing our efforts on the SP(1-9)- producing pathway, we determined that an activity sensitive to the inhibitor GM6001 is the dominant SP(1-9)-generating activity in the spinal cord. We also show that GM6001 treatment causes a nearly three-fold increase in endogenous substance P levels in the spinal cords of mice, highlighting the functional relevance of the pathway blocked by this inhibitor.

bioactive peptide

mass spectrometry

peptidomics

short open reading frame

spinal cord

substance P

genetics

biochemistry

neurosciences

Detection and Analysis of Novel Microproteins in the Human Heart based on Protein Evidence, Conservation, Subcellular Localization, and Interacting Proteins

Schulz, Jana Felicitas

03 March 2023

Kürzlich wurde mithilfe von Ribo-seq Experimenten die Translation hunderter Mikroproteine in menschlichen Herzen entdeckt. Diese blieben zuvor aufgrund ihrer geringen Größe (< 100 Aminosäuren) unentdeckt, und ihre physiologische Rolle ist noch weitgehend unbekannt. Ziel dieser Promotionsarbeit ist es, potentielle Funktionen dieser neuartigen Mikroproteine zu entschlüsseln. Dabei sollen insbesondere die Aufklärung ihrer evolutionären Konservierungssignatur, subzellulären Lokalisierung und ihres Proteininteraktoms helfen. Die Konservierungsanalyse ergab, dass fast 90% der Mikroproteine nur in Primaten konserviert ist. Weiterhin konnte ich die Produktion von Mikroproteine in vitro und in vivo nachweisen, die subzelluläre Lokalisierung von 92 Mikroproteinen definieren, und Interaktionspartner für 60 Mikroproteine identifizieren. Dutzende dieser Mikroproteine lokalisieren in Mitochondrien. Dazu gehörte ein im Herzen angereichertes Mikroprotein, das aufgrund der Interaktions- und Lokalisationsdaten einen neuartigen Modulator der mitochondrialen Proteintranslation darstellen könnte. Der Interaktom-Screen zeigte außerdem, dass evolutionär junge Mikroproteine ähnliche Interaktionsfähigkeiten wie konservierte Kandidaten haben. Schließlich wurden kurze Sequenzmotive identifiziert, die Mikroprotein-Protein-Wechselwirkungen vermitteln, wodurch junge Mikroproteine mit zellulären Prozessen – wie z.B. Endozytose und Spleißen – in Verbindung gebracht werden konnten. Zusammenfassend wurde die Produktion vieler kleiner Proteine im menschlichen Herzen bestätigt, von denen die meisten lediglich in Primaten konserviert sind. Zusätzlich verknüpften umfangreiche Lokalisierungs- und Interaktionsdaten mehrere Mikroproteine mit Prozessen wie Spleißen, Endozytose und mitochondrialer Translation. Weitere Untersuchungen dieses zuvor verborgenen Teils des Herzproteoms werden zu einem besseren Verständnis von evolutionär jungen Proteinen und kardiologischen Prozessen beitragen. / Recently, the active translation of hundreds of previously unknown microproteins was detected using ribosome profiling on tissues of human hearts. They had remained undetected due to their small size (< 100 amino acids), and their physiological roles are still largely unknown. This dissertation aims to investigate these novel microproteins and validate their translation by independent methods. Particularly, elucidating their conservation signature, subcellular localization, and protein interactome shall aid in deciphering their potential biological role. Conservation analysis revealed that sequence conservation of almost 90% of microproteins was restricted to primates. I next confirmed microprotein production in vitro and in vivo by in vitro translation assays and mass spectrometry-based approaches, defined the subcellular localization of 92 microproteins, and identified significant interaction partners for 60 candidates. Dozens of these microproteins localized to the mitochondrion. These included a novel cardiac-enriched microprotein that may present a novel modulator of mitochondrial protein translation based on its interaction profile and subcellular localization. The interactome screen further revealed that evolutionarily young microproteins have similar interaction capacities to conserved candidates. Finally, it allowed identifying short linear motifs that may mediate microprotein-protein interactions and implicated several young microproteins in distinct cellular processes such as endocytosis and splicing. I conclude that many novel small proteins are produced in the human heart, most of which exhibit poor sequence conservation. I provide a substantial resource of microprotein localization and interaction data that links several to cellular processes such as splicing, endocytosis, and mitochondrial translation. Further investigation into this hidden part of the cardiac proteome will contribute to our understanding of recently evolved proteins and heart biology.

Mikroproteine

Ribosomen Profiling

Proteinevolution

Proteininteraktom

Herzversagen

lncRNAs

Proteintranslation

Microproteins

Short open reading frame (sORF)

Ribosome profiling

lncRNAs

sORF-encoded peptides

dilated cardiomyopathy

ORF detection

human heart

translatome

heart failure

de novo genes

protein evolution

PRISMA

short linear motifs (SLiMs)

protein interactome

primate-specific proteins

576 Genetik und Evolution

570 Biologie

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ddc:570