Gene regulation during development by chromatin and the Super Elongation Complex

Dahlberg, Olle

January 2014

Developmental processes are carefully controlled at the level of transcription to ensure that the fertilized egg develops into an adult organism. The mechanisms that controls transcription of protein-coding genes ultimately ensure that the Pol II machine synthesizes mRNA from the correct set of genes in every cell type. Transcriptional control involves Pol II recruitment as well as transcriptional elongation. Recent genome-wide studies shows that recruitment of Pol II is often followed by an intermediate step where Pol II is halted in a promoter-proximal paused configuration. The release of Pol II from promoter-proximal pausing is thus an additional and commonly occurring mechanism in metazoan gene regulation. The serine kinase P-TEFb is part of the Super Elongation Complex that regulates the release of paused Pol II into productive elongation. However, little is known about the role of P-TEFb mediated gene expression in development. We have investigated the function of P-TEFb in early Drosophila embryogenesis and find that P-TEFb and other Super Elongation Complex subunits are critical for activation of the most early expressed genes. We demonstrate an unexpected function for Super Elongation Complex in activation of genes with non-paused Pol II. Furthermore, the Super Elongation Complex shares phenotypes with subunits of the Mediator complex to control the activation of essential developmental genes. This raises the possibility that the Super Elongation Complex has an unappreciated role in the recruitment of Pol II to promoters. The unique chromatin landscape of each cell type is comprised of post-translational chromatin modifications such as histone methylations and acetylations. To study the function of histone modifications during development, we depleted the histone demethylase KDM4A in Drosophila to evaluate the role of KDM4A and histone H3 lysine 36 trimethylation (H3K36me3) in gene regulation. We find that KDM4A has a male-specific function and regulates gene expression both by catalytic-dependent and independent mechanisms. Furthermore, we used histone replacement to investigate the direct role of H3K14 acetylation in a multicellular organism. We show that H3K14 acetylation is essential for development, but is not cell lethal, suggesting that H3K14 acetylation has a critical role in developmental gene regulation. This work expands our knowledge of the mechanisms that precisely controls gene regulation and transcription, and in addition highlights the complexity of metazoan development. / <p>At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 1: Manuscript. Paper 3: Manuscript.</p>

Drosophila development

gene regulation

transcription

chromatin

P-TEFb

Super Elongation Complex

KDM4A

H3K36me3

H3K14ac

histone replacement

Improving the Histone Replacement System in Drosophila melanogaster for High-Throughput Analysis

Grüblinger, Florian

08 July 2022

Eukaryotische DNA ist in Chromatin verpackt, einem Komplex aus DNA und Proteinen. Das ermöglicht Transkriptionsregulation von Genen durch Modulation ihrer Zugänglichkeit. Histone sind evolutionär konservierte Chromatinproteine, die durch posttranslationale Modifikationen (PTMs) modifiziert sind. Das legt nahe, dass deren Primärstruktur und ihre PTMs funktionellen Beschränkungen unterliegen. Genetische Ansätze zur Entschlüsselung von Struktur-Funktions-Beziehungen für Histone waren auf Einzeller und D. melanogaster beschränkt. Das Histon-Ersatz-System in D. melanogaster, bei dem Histontransgene verwendet werden, um endogene Histone zu ersetzen, war nicht für systematische Untersuchung dieser Beziehungen ausgelegt. In meiner Arbeit habe ich die Funktion von Threonin 11 in Histon H3 (H3T11) untersucht, das phosphoryliert werden kann. Ich analysierte zwei Mutationen in H3T11 (H3T11A und H3T11E) und stellte fest, dass beide zur Derepression von Transposons führen. H3T11E hat in Gegenwart von Wildtyp-Histon H3 einen dominanten Phänotyp mit transkriptomweiten Folgen. Dazu gehören Induktion von Immun-Genen und Unterdrückung von mit DNA-Stoffwechsel in Verbindung stehenden Genen. Die Mutationen wurden unter der Prämisse charakterisiert, ein Analyse-Schema für eine große Anzahl von Histon-Ersatz-Stämmen zu entwickeln und Probleme zu identifizieren, die die Analyse beeinträchtigen. Dabei habe ich das Verfahren zur Erzeugung von Histon-Ersatz-Stämmen optimiert. Dazu gehören die optionale Verwendung größerer Histon-Transgene und zuverlässigere Produktion und optimierte Rekombinations-Strategie dieser. Ich habe das Klonierungsverfahren gestrafft und eine Plasmid-Bibliothek erstellt, die es erlaubt, 178 verschiedene mutierte Histon-H3-Transgene zu erzeugen. Mit den Änderungen am Produktionsschema, ist diese Bibliothek eine wertvolle Ressource und wird dazu beitragen, die Funktion von Histon H3 und seiner PTMs während der Entwicklung eines Vielzellers besser zu verstehen. / Eukaryotic DNA is packaged into chromatin, a complex composed of DNA and proteins. This enables transcriptional regulation of genes through modulation of their accessibility. Histones are chromatin proteins, modified by post-translational modifications (PTMs) and their sequences are conserved in evolution. This suggests functional constraints for the primary structure of histones and their PTMs. Genetic approaches to decipher structure-function relationships for histone proteins were restricted to unicellular organisms and D. melanogaster. The histone replacement system in D. melanogaster, which uses histone transgenes to replace endogenous histones, was not adapted for systematic interrogation of such relationships. Here, I investigated the function of threonine 11 in histone H3 (H3T11), which can be phosphorylated. I analyzed two mutations in H3T11 (H3T11A and H3T11E) and found that both lead to de-repression of transposable elements. I also found that H3T11E, has a dominant phenotype in the presence of wildtype histone H3 with transcriptome-wide consequences. These include induction of immune-related genes and repression of genes associated with DNA metabolism. I characterized both mutations under the premise of establishing an analysis scheme suitable for a large set of histone replacement strains and identifying problems that interfere with this analysis. As a consequence, I optimized the procedure to generate histone replacement strains. These include an option to incorporate larger histone transgenes, a more reliable production of transgenes and an optimized strategy to recombine them. I streamlined the cloning procedure and created a plasmid library allowing for the generation of 178 distinct mutant histone H3 transgenes. Together with my amendments to the production scheme, this library provides a valuable resource to the field and will help to better understand the function of histone H3 and its PTMs during the development of a multicellular organism.

Drosophila melanogaster

H3T11A

Histon-Ersatz-System

Histon PTMs

Drosophila melanogaster

H3T11A

histone replacement system

histone PTMs

570 Biologie

WD 5275

ddc:570