“Transcriptional and Epigenetic regulation in the marine diatom Phaeodactylum tricornutum”

Maumus, Florian

06 July 2009

Les océans couvrent plus de 70% de la surface de la Terre (planète bleue) et la productivité primaire nette (PPN) marine est équivalente à celle terrestre. Alors qu‟il ne représente que 1% de la biomasse totale d‟organismes photosynthétiques de la planète, le phytoplancton est responsable d‟environ 45% de la PPN globale. Le terme phytoplancton décrit un assemblage polyphylétique comprenant des eucaryotes et procaryotes photosynthétiques dérivant avec les courants. Dans les océans contemporains, les diatomées constituent un groupe d‟eucaryotes unicellulaires autotrophes très abondant, responsable de 40% de la PPN marine. Les diatomées appartiennent à la lignée des straménopiles qui sont issus d‟un évènement d‟endosymbiose entre une algue rouge et un hôte hétérotrophe. Elles sont classifiées en deux groupes majeurs : les centriques qui son apparues il y a environ 200 millions d‟années (Ma), et les pennées qui ont évolué il y a environ 90 Ma. Deux génomes de diatomées ont récemment été séquencés : celui de la diatomée centrique Thalassiosira pseudonana (32 Mb), et celui de la diatomée pennée Phaeodactylum tricornutum (27 Mb). Mon sujet de doctorat s‟est focalisé sur l‟étude de différents aspects de la régulation de l‟expression génique ainsi que sur la dynamique et l‟évolution de ces génomes. L‟expression des gènes est régulée à différents niveaux: trancriptionel, post-transcriptionel, et épigénétique. Dans le cadre de mon doctorat, une étude de la régulation transcriptionelle chez les diatomées a été effectuée et comprend l‟identification et l‟analyse in silico des facteurs de transcription (FT). Cela a permis par exemple d‟établir qu‟une classe spécifique de FT, les Heat Shock Factors, sont particulièrement abondants chez les diatomées par rapport aux autres eucaryotes. L‟analyse de la représentation des FT identifiés dans différentes librairies d‟EST élaborées à partir de cultures ayant subi divers stress a permis de détecter certaines spécificités d‟expression. L‟évolution des génomes eucaryotes est largement impactée par les effets directs et secondaires des éléments transposables (ET) qui sont des éléments génétiques mobiles se trouvant dans le génome de la plupart des organismes. Dans le but d‟étudier la dynamique des génomes de diatomées, la recherche de différents types d‟ET a permis d‟établir qu‟une certaine classe, les rétrotransposons de type Copia, est la plus abondante dans ces génomes et constitue un part significativement plus importante du génome de P. tricornutum (5,8%) par rapport à T. pseudonana (1%). D‟autre part, des analyses phylogénitiques ont montré que les rétrotransposons de type copia forment deux classes distinctes et éloignées de la lignée Copia. L‟analyse de leurs niveaux d‟expression a montré que la transcription de deux éléments s‟active en réponse à des stress spécifiques comme la limitation en nitrate dans le milieu de culture. Cette activation est accompagnée par un hypométhylation de l‟ADN et l‟analyse de profils d‟insertions chez différents écotypes de P. tricornutum ainsi que l‟étude d‟autres phénomènes suggèrent que les rétrotransposons de type Copia ont joué un rôle important dans l‟évolution des diatomées. Mon grand intérêt pour les ET m‟a ensuite amené à chercher à les caractériser dans d‟autres génomes récemment séquencés tels celui de l‟algue brune Ectocarpus siliculosus. La recherche in silico de différents gènes codant des protéines capables d‟introduire ou de stabiliser des états épigénétiques telle que la modification des histones et la méthylation de l‟ADN a montré leur présence chez P. tricornutum ainsi que leurs particularités. La présence de certaines modifications d‟histones spécifiques d‟une conformation compacte ou ouverte de la chromatine dans le proteome de P. tricornutum a été montrée. De plus, la mise au point de la technique d‟immunoprécipitation de la chromatine chez P. tricornutum a permis d‟établir que les nucléosomes enrobés d‟éléments transposables étaient marqués par des modifications spécifiques. D‟autres expériences ont permis d‟établir que l‟ADN de différents types d‟éléments transposables est marqué par la méthylation de cytosines chez P. tricornutum. Une expérience permettant l‟analyse du profil de méthylation à l‟échelle de génome en utilisant une puce à ADN a été lancée et permettra de découvrir si certains gènes portent aussi des traces de méthylation. Enfin, les ARN interférents constituent un troisième mode de régulation de l‟expression se situant à l‟interface de la régulation transcriptionelle, post-transcriptionelle et épigénétique. Les mécanismes d‟interférences chez les diatomées ont été étudié par la recherche in silico d‟enzymes clés impliquées dans ce processus ainsi qu‟en établissant expérimentalement un lien direct avec la méthylation de l‟ADN.

Marine microbiology

comparative genomics

diatoms

chromalveolates

epigenetics

genome dynamics

DNA methylation

Copia elements

Transcriptional regulation

Macromolecular Matchmaking : Mechanisms and Biology of Bacterial Small RNAs

Holmqvist, Erik

January 2012

Cells sense the properties of the surrounding environment and convert this information into changes in gene expression. Bacteria are, in contrast to many multi-cellular eukaryotes, remarkable in their ability to cope with rapid environmental changes and to endure harsh and extreme milieus. Previously, control of gene expression was thought to be carried out exclusively by proteins. However, it is now clear that small regulatory RNAs (sRNA) also carry out gene regulatory functions. Bacteria such as E. coli harbor a large class of sRNAs that bind to mRNAs to alter translation and/or mRNA stability. By identifying mRNAs that are targeted by sRNAs, my studies have broadened the understanding of the mechanisms that underlie sRNA-dependent gene regulation, and have shed light on the impact that this type of regulation has on bacterial physiology. Control of gene expression often relies on the interplay of many regulators. This interplay is exemplified by our discovery of mutual regulation between the sRNA MicF and the globally acting transcription factor Lrp. Through double negative feedback, these two regulators respond to nutrient availability in the environment which results in reprogramming of downstream gene expression. We have also shown that both the transcription factor CsgD, and the anti-sigma factor FlgM, are repressed by the two sRNAs OmrA and OmrB, suggesting that these sRNAs are important players in the complex regulation that allow bacteria to switch between motility and sessility. Bacterial populations of genetically identical individuals show phenotypic variations when switching to the sessile state due to bistability in gene expression. While bistability has previously been demonstrated to arise from stochastic fluctuations in transcription, our results suggest that bistability possibly may arise from sRNA-dependent regulatory events also on the post-transcriptional level.

Small RNA

sRNA

non-coding RNA

antisense

gene regulation

post-transcriptional regulation

translational control

outer membrane protein

OmpA

MicA

biofilm

flagella

curli

bistability

Lrp

MicF

CsgD

FlgM

OmrA

OmrB

Functional organisation of the cell nucleus in the fission yeast, Schizosaccharomyces pombe

Alfredsson Timmins, Jenny

January 2009

In eukaryotes the genome adopts a non-random spatial organisation, which is important for gene regulation. However, very little is known about the driving forces behind nuclear organisation. In the simple model eukaryote fission yeast, Schizosaccharomyces pombe, it has been known for a long time that transcriptionally repressed heterochromatin localise to the nuclear membrane (NM); the centromeres attaches to spindle pole body (SPB), while the telomeres are positioned at the NM on the opposite side of the nucleus compared to the SPB. Studies presented in this thesis aimed at advancing our knowledge of nuclear organisation in Schizosaccharomyces pombe. We show that the heterochromatic mating-type region localises to the NM in the vicinity of the SPB. This positioning was completely dependent on Clr4, a histone methyl transferase crucial for the formation of heterochromatin. Additional factors important for localisation were also identified: the chromo domain protein Swi6, and the two boundary elements IR-L and IR-R surrounding this locus. We further identify two other chromo domain proteins; Chp1 and Chp2, as crucial factors for correct subnuclear localisation of this region. From these results we suggest that the boundary elements together with chromodomain proteins in balanced dosage and composition cooperate in organising the mating-type chromatin. Gene regulation can affect the subnuclear localisation of genes. Using nitrogen starvation in S. pombe as a model for gene induction we determined the subnuclear localisation of two gene clusters repressed by nitrogen: Chr1 and Tel1. When repressed these loci localise to the NM, and this positioning is dependent on the histone deacetylase Clr3. During induction the gene clusters moved towards the nuclear interior in a transcription dependent manner. The knowledge gained from work presented in this thesis, regarding nuclear organisation in the S. pombe model system, can hopefully aid to a better understanding of human nuclear organisation.

fission yeast

heterochromatin

subnuclear organisation

chromo domain proteins

boundary elements

transcriptional regulation

epigenetics

Molecular biology

Molekylärbiologi

Cell and molecular biology

Cell- och molekylärbiologi

Genetics

Genetik

The Cyanobacterial Uptake Hydrogenase : Regulation, Maturation and Function

Holmqvist, Marie

January 2010

With accellerating global warming and pollution problems a change of energy regime is necessary. Solar energy offers a clean and unlimited energy source of enormous potential. Due to it’s intermittenet nature solar energy must be stored - ideally in the chemical bond of a carrier molecule. Hydrogen gas, H2, an energy carrier with water as only emission when used in a fuel cell, is considered to be the choise for the future. In this context cyanobacteria show promising potential as future H2 factories since they can produce H2 from solar energy and water. The main enzymes directly involved in cyanobacterial hydrogen metabolism are nitrogenases and hydrogenases. Cyanobacterial hydrogenases are either uptake hydrogenases or bidirectional hydrogenases and their maturation requires assistance of six maturation proteins and two hydrogenase specific proteases. In this thesis the transcriptional regulation, maturation and function of the cyanobacterial uptake hydrogenases were investigated in the filamentous, heterocyst forming strains Nostoc punctiforme ATCC 29133 and Nostoc sp. strain PCC 7120. Five genes, encoding proteins putatively involved in the maturation of the uptake hydrogenase were identified upstream the known maturation genes. Two transcription factors, CalA and CalB, were found interacting with the stretch of DNA forming the upstream regions of the uptake hydrogenase structural genes and the novel maturation genes. The expression of the uptake hydrogenase were  heterocysts specific and the specificity mapped to a short promoter region starting -57 bp upstream the transcription start point. In addition, the function of the uptake hydrogenase was inserted in a metabolic context. Among the proteases, a conserved region was discovered possibly involved in determining the hydrogenase specificity. This thesis has given valuable information about the transcriptional regulation, maturation and function of the uptake hydrogenase in filamentous, heterocystous cyanobacteria and identified new targets for bioengineering of mutant strains with higher H2 production rates.

Biohydrogen

CalA

Cyanobacteria

Hydrogenase

Maturation

Nostoc punctiforme ATCC 29133

Nostoc sp. PCC 7120

Transcriptional regulation

Molecular biology

Molekylärbiologi

Molecular biology

Molekylärbiologi

The Epigenetic Regulation of Cytokine Inducible Mammalian Transcription by the 26S Proteasome

Koues, Olivia I

08 July 2009

It is evident that components of the 26S proteasome function beyond protein degradation in the regulation of transcription. Studies in yeast implicate the 26S proteasome, specifically the 19S cap, in the epigenetic regulation of transcription. Saccharomyces cerevisiae 19S ATPases remodel chromatin by facilitating histone acetylation and methylation. However, it is unclear if the 19S ATPases play similar roles in mammalian cells. We previously found that the 19S ATPase Sug1 positively regulates transcription of the critical inflammatory gene MHC-II and that the MHC-II promoter fails to efficiently bind transcription factors upon Sug1 knockdown. MHC-II transcription is regulated by the critical coactivator CIITA. We now find that Sug1 is crucial for regulating histone H3 acetylation at the cytokine inducible MHC-II and CIITA promoters. Histone H3 acetylation is dramatically decreased upon Sug1 knockdown with a preferential loss occurring at lysine 18. Research in yeast indicates that the ortholog of Sug1, Rpt6, acts as a mediator between the activating modifications of histone H2B ubiquitination and H3 methylation. Therefore, we characterized the role the 19S proteasome plays in regulating additional activating modifications. As with acetylation, Sug1 is necessary for proper histone H3K4 and H3R17 methylation at cytokine inducible promoters. In the absence of Sug1, histone H3K4me3 and H3R17me2 are substantially inhibited. Our observation that the loss of Sug1 has no significant effect on H3K36me3 implies that Sug1’s regulation of histone modifications is localized to promoter regions as H3K4me3 but not H3K36me3 is clustered around gene promoters. Here we show that multiple H3K4 histone methyltransferase subunits bind constitutively to the inducible MHC-II and CIITA promoters and that over-expressing one subunit significantly enhances promoter activity. Furthermore, we identified a critical subunit of the H3K4 methyltransferase complex that binds multiple histone modifying enzymes, but fails to bind the CIITA promoter in the absence of Sug1, implicating Sug1 in recruiting multi-enzyme complexes responsible for initiating transcription. Finally, Sug1 knockdown maintains gene silencing as elevated levels of H3K27 trimethylation are observed upon Sug1 knockdown. Together these studies strongly implicate the 19S proteasome in mediating the initial reorganization events to relax the repressive chromatin structure surrounding inducible genes.

19S proteasome

Sug1

26S proteasome

Class II transactivator

Histone remodeling enzymes

Histone modifications

Epigenetics

Transcriptional regulation

Biology, general

An integrative bioinformatics approach for analyses of multi-level transcriptional regulation and three-dimensional organization in the epidermis and skin appendages : exploring genomic transcriptional profiles of the distinct stages of hair follicle and sweat gland development and analyses of mechanism integrating the transcriptional regulation, linear and high-order genome organization within epidermal differentiation complex in keratinocytes

Poterlowicz, Krzysztof

January 2013

The transcription in the eukaryotic cells involves epigenetic regulatory mechanisms that control local and higher-order chromatin remodelling. In the skin, keratinocyte-specific genes are organized into distinct loci including Epidermal Differentiation Complex (EDC) and Keratin type I/II loci. This thesis introduces bioinformatics approaches to analyze multi-level regulatory mechanisms that control skin development and keratinocyte-specific differentiation. Firstly, integration of gene expression data with analyses of linear genome organization showed dramatic downregulation of the genes that comprise large genomic domains in the sweat glands including EDC locus, compared to ii hair follicles, suggesting substantial differences in global genome rearrangement during development of these two distinct skin appendages. Secondly, comparative analysis of the genetic programmes regulated in keratinocytes by Lhx2 transcription factor and chromatin remodeler Satb1 revealed that significant number of their target genes is clustered in the genome. Furthermore, it was shown in this study that Satb1 target genes are lineage-specific. Thirdly, analysis of the topological interactomes of Loricrin and Keratin 5 in hair follicle steam cells revealed presence of the cis- and trans-interactions and lineage specific genes (Wnt, TGF-beta/activin, Notch, etc.). Expression levels of the genes that comprise interactomes show correlation with their histone modification status. This study demonstrates the crucial role for integration of transcription factormediated and epigenetic regulatory mechanisms in establishing a proper balance of gene expression in keratinocytes during development and differentiation into distinct cell lineages and provides an integrated bioinformatics platform for further analyses of the changes in global organization of keratinocyte-specific genomic loci in normal and diseased skin.

570

The Epigenetic Regulation of Cytokine Inducible Mammalian Transcription by the 26S Proteasome

Koues, Olivia I

08 July 2009

It is evident that components of the 26S proteasome function beyond protein degradation in the regulation of transcription. Studies in yeast implicate the 26S proteasome, specifically the 19S cap, in the epigenetic regulation of transcription. Saccharomyces cerevisiae 19S ATPases remodel chromatin by facilitating histone acetylation and methylation. However, it is unclear if the 19S ATPases play similar roles in mammalian cells. We previously found that the 19S ATPase Sug1 positively regulates transcription of the critical inflammatory gene MHC-II and that the MHC-II promoter fails to efficiently bind transcription factors upon Sug1 knockdown. MHC-II transcription is regulated by the critical coactivator CIITA. We now find that Sug1 is crucial for regulating histone H3 acetylation at the cytokine inducible MHC-II and CIITA promoters. Histone H3 acetylation is dramatically decreased upon Sug1 knockdown with a preferential loss occurring at lysine 18. Research in yeast indicates that the ortholog of Sug1, Rpt6, acts as a mediator between the activating modifications of histone H2B ubiquitination and H3 methylation. Therefore, we characterized the role the 19S proteasome plays in regulating additional activating modifications. As with acetylation, Sug1 is necessary for proper histone H3K4 and H3R17 methylation at cytokine inducible promoters. In the absence of Sug1, histone H3K4me3 and H3R17me2 are substantially inhibited. Our observation that the loss of Sug1 has no significant effect on H3K36me3 implies that Sug1’s regulation of histone modifications is localized to promoter regions as H3K4me3 but not H3K36me3 is clustered around gene promoters. Here we show that multiple H3K4 histone methyltransferase subunits bind constitutively to the inducible MHC-II and CIITA promoters and that over-expressing one subunit significantly enhances promoter activity. Furthermore, we identified a critical subunit of the H3K4 methyltransferase complex that binds multiple histone modifying enzymes, but fails to bind the CIITA promoter in the absence of Sug1, implicating Sug1 in recruiting multi-enzyme complexes responsible for initiating transcription. Finally, Sug1 knockdown maintains gene silencing as elevated levels of H3K27 trimethylation are observed upon Sug1 knockdown. Together these studies strongly implicate the 19S proteasome in mediating the initial reorganization events to relax the repressive chromatin structure surrounding inducible genes.

19S proteasome

Sug1

26S proteasome

Class II transactivator

Histone remodeling enzymes

Histone modifications

Epigenetics

Transcriptional regulation

Biology

Role of the post-transcriptional regulators Pumilio1 and Pumilio2 in murine hematopoietic stem cells

Michelet, Fabio

07 November 2013

The central properties of stem cells are the pluripotency and the capacity of self-renewal. Hematopoietic stem cells (HSCs) posses such common features that allows them to generate all the cells of the hematopoietic compartments, maintaining in the same time the HSC pool. We develop approaches focused on ex vivo HSC expansion through activation by exogenous HOXB4 (human HSCs) or Notch/Dll-4 ligand (murine HSCs). Two independent transcriptomic analyses surprisingly converged toward an increased expression of two genes never identified sofar as crucial for HSC functions: Pumilio1 (Pum1) and Pumilio2 (Pum2). Pum1 and Pum2 are posttranscriptional regulators belonging to the Pumilio-FBF (PUF) family of RNA-binding proteins. Although it was established that the primordial role of PUF proteins is to sustain mitotic proliferation of stem cells in Invertebrates, so far nothing is known about the role of Pum1 and Pum2 in human and murine HSCs.For these reasons, we have investigated the roles and mechanisms of action of Pum1 and Pum2 in murine and human HSCs through shRNA strategy. Pum1 and Pum2 knockdown (KD) in murine HSCs led to a decreased HSC expansion and clonogenic potential ex vivo, associated with an increased apoptosis and a cell cycle arrest in G0/G1 phase. KD of both Pum1 and Pum2 enhanced these effects, suggesting a cooperative effect. Expansion and clonogenic potential of KD Pum1 HSCs were rescued by enforced expression of Pum1 (insensitive to our shRNA), thus validating the specificity of our shRNA. Enforced expression of Pum1 could not rescue the functions of Pum2 KD HSCs, highlighting the non-redundant role of these proteins. Furthermore, when Pum1 or Pum2 KD HSCs were inoculated into lethally irradiated mice to follow the long-term hematopoietic potential, only rare bone marrow cells derived from Pum1 and Pum2 KD HSCs were evidenced after 4 months, contrary to control HSCs. Identical results were obtained with human Pum1 or Pum2 KD HSCs.In conclusion, our results demonstrate the involvement of Pumilio factors in stemness maintenance, expansion and survival of murine and human HSCs. Identification of Pumilio factors and their targets as new regulators of HSCs expansion will allow consider them as new tools for therapeutic perspectives.

Stem cells

Hematopoietic stem cells

HSC

Pumilio

Pum1

Pum2

Notch

Delta4

Post transcriptional regulation

N-terminal isoforms of the p53 tumour suppressor protein : effects on p53 transcriptional activity and expression in cutaneous melanoma

Hafsi, Hind

20 December 2012

The p53 tumour suppressor protein has a highly complex pattern of regulation at transcriptional and posttranslationallevels. The discovery of p53 isoforms has added another layer of complexity to the mechanisms thatregulate p53 functions. Indeed, p53 is expressed as 12 isoforms that differ in their N- and C-terminus due toalternative splicing, promoter or codon initiation usage. So far, there is limited understanding of the patterns ofexpression and of the functions of each of these isoforms.In this Thesis, we have focused on the two major p53 N-terminal isoforms, Δ40p53 and Δ133p53. We haveanalysed their patterns of interactions with the full-length p53 and we have investigated whether their expressioncould be deregulated in melanoma, a cancer type in which TP53 mutations are rare. Our results show that Δ40p53 can modulate p53 function with a bi-phasic effect, acting as a repressor or activator of p53 to control itslevels and activity. Moreover, we demonstrate that the internal P2 promoter produces Δ133p53 and is regulatedby p53 in response to genotoxic stress, identifying a novel auto-regulatory loop by which p53 may control theexpression of an isoform acting as an inhibitor of p53 activities. Finally, we show that mRNAs encoding Nterminalisoforms are often over-expressed in highly metastatic melanoma when compared to non-invasiveforms, suggesting that N-terminal isoforms contribute to functionally inactivate p53. Thus, we propose that Δ40p53 and Δ133p53 modulate p53 functions within dynamic fluctuations of aprotein network. Hence, p53 isoforms may have a major role in basal p53 activities as well as in the functionalinactivation of p53 in cancer cells.

P53 tumour suppressor protein

Isoforms

Transcriptional regulation

Melanoma

Inactivation of p53

A proteome-wide strategy reveals a novel mechanism of control of cell cycle progression through modulation of cyclin mRNA stability

Messier, Vincent

01 1900

La quantité de données générée dans le cadre d'étude à grande échelle du réseau d'interaction protéine-protéine dépasse notre capacité à les analyser et à comprendre leur sens; d'une part, par leur complexité et leur volume, et d'un autre part, par la qualité du jeu de donnée produit qui semble bondé de faux positifs et de faux négatifs. Cette dissertation décrit une nouvelle méthode de criblage des interactions physique entre protéines à haut débit chez Saccharomyces cerevisiae, la complémentation de fragments protéiques (PCA). Cette approche est accomplie dans des cellules intactes dans les conditions natives des protéines; sous leur promoteur endogène et dans le respect des contextes de modifications post-traductionnelles et de localisations subcellulaires. Une application biologique de cette méthode a permis de démontrer la capacité de ce système rapporteur à répondre aux questions d'adaptation cellulaire à des stress, comme la famine en nutriments et un traitement à une drogue. Dans le premier chapitre de cette dissertation, nous avons présenté un criblage des paires d'interactions entre les protéines résultant des quelques 6000 cadres de lecture de Saccharomyces cerevisiae. Nous avons identifié 2770 interactions entre 1124 protéines. Nous avons estimé la qualité de notre criblage en le comparant à d'autres banques d'interaction. Nous avons réalisé que la majorité de nos interactions sont nouvelles, alors que le chevauchement avec les données des autres méthodes est large. Nous avons pris cette opportunité pour caractériser les facteurs déterminants dans la détection d'une interaction par PCA. Nous avons remarqué que notre approche est sous une contrainte stérique provenant de la nécessité des fragments rapporteurs à pouvoir se rejoindre dans l'espace cellulaire afin de récupérer l'activité observable de la sonde d'interaction. L'intégration de nos résultats aux connaissances des dynamiques de régulations génétiques et des modifications protéiques nous dirigera vers une meilleure compréhension des processus cellulaires complexes orchestrés aux niveaux moléculaires et structuraux dans les cellules vivantes. Nous avons appliqué notre méthode aux réarrangements dynamiques opérant durant l'adaptation de la cellule à des stress, comme la famine en nutriments et le traitement à une drogue. Cette investigation fait le détail de notre second chapitre. Nous avons déterminé de cette manière que l'équilibre entre les formes phosphorylées et déphosphorylées de l'arginine méthyltransférase de Saccharomyces cerevisiae, Hmt1, régulait du même coup sont assemblage en hexamère et son activité enzymatique. L'activité d'Hmt1 a directement un impact dans la progression du cycle cellulaire durant un stress, stabilisant les transcrits de CLB2 et permettant la synthèse de Cln3p. Nous avons utilisé notre criblage afin de déterminer les régulateurs de la phosphorylation d'Hmt1 dans un contexte de traitement à la rapamycin, un inhibiteur de la kinase cible de la rapamycin (TOR). Nous avons identifié la sous-unité catalytique de la phosphatase PP2a, Pph22, activé par l'inhibition de la kinase TOR et la kinase Dbf2, activé durant l'entrée en mitose de la cellule, comme la phosphatase et la kinase responsable de la modification d'Hmt1 et de ses fonctions de régulations dans le cycle cellulaire. Cette approche peut être généralisée afin d'identifier et de lier mécanistiquement les gènes, incluant ceux n'ayant aucune fonction connue, à tout processus cellulaire, comme les mécanismes régulant l'ARNm. / The quantity of data generated within the framework of protein-protein interaction network large-scale studies exceeds our capacity to analyze them and to understand their meaning; on one hand, by their complexity and their number, and on the other hand, by the quality of the produced data, which are populated with spurious interactions. This dissertation describes new applications of a protein-fragments complementation assay (PCA) to screen for interactions among all proteins in the budding yeast Saccharomyces cerevisiae. This approach is carried out in intact cells, with proteins expressed in their native contexts and under their endogenous promoter, thus assuring correct post-translational modifications and subcellular localization. A further novel application of PCA is described for investigating proteome wide changes in response to cellular adaptation to stresses, such as nutrient starvations and drug treatments. Finally, as a result of the latter strategy applied to characterizing proteome-wide response to the immunosuppressant drug, rapamycin, I describe the discovery of an unforeseen mechanism of modulating cell cycle progression through control of cyclin mRNA stability. In the first chapter of this dissertation, I present a pairwise screen of interactions among proteins resulting from the ~6000 open reading frames in Saccharomyces cerevisiae. We identified 2770 interactions among 1124 proteins. We estimated the quality of our screen by comparing our results to curated gold standard data and coverage of known interactions to all previous studies. The majority of our interactions were novel, but overlap with data from previous studies was as high as 40%. PCA is based on refolding of the reporter protein from complementary N- and C- terminal fragments following interaction of the two proteins to which they are fused. Thus, reporter activity is sterrically limited to interactions in which the termini of the proteins to which the complementary reporter fragments are fused are sufficiently close in space. In the case of our reporter, this limit was 8 nm. Thus PCA is a molecular ruler, providing information on both direct protein-protein interactions and sterrically restricted distances between proteins in complexes. We benchmarked and demonstrated correct topological relationships for a number of known complexes, including the proteasome, RNA polymerase II and the nuclear pore complex. Thus our study provided, for the first time, a topological map of complex organization in a living cell. The integration of the results from such efforts with those of gene regulation dynamics and protein modifications will lead to a fuller understanding of how complex cellular processes are orchestrated at a molecular and structural level in the living cell. In chapter 2, I describe the results of an application of PCA to study the dynamic rearrangement of the proteome under a specific stress; treatment of cells with rapamycin. The results of these efforts were the identification of a novel mechanism of cell cycle control at the level of cyclin mRNA. Specifically, we discovered that the balance between the phosphorylated and dephosphorylated forms of the Saccharomyces cerevisiae arginine methyltransferase, Hmt1, regulates both its assembly into a hexamer and its enzymatic activity. The Hmt1 activity modulates cell cycle progression through stabilizing the B cyclin CLB2 mRNA. We then used PCA to identify the Hmt1 regulators under rapamycin treatment. We identified the catalytic subunit of the PP2a phosphatase, Pph22, activated by the inhibition of TOR, and the kinase Dbf2, activated during entry into mitosis, as the phosphatase and the kinase responsible for the modification of Hmt1 and for its regulatory functions in the cell cycle. I thus, in the end close the circle I began in this summary, going from large-scale discovery of protein-protein interactions, to mapping dynamics of proteome changes during an adaptation and finally to mechanistic insight into a primordial control mechanism in cellular dynamics. The strategies that we devised to discover this mechanism can be generalized to identify and mechanistically link genes together, including those of unknown function, to any cellular process.

Biochimie

Biochemistry

Cycle cellulaire

Cell cycle

Régulation post-transcriptionelle

Post-transcriptional regulation

Régulation de cyclines

Cyclin regulation

Voie de TOR

TOR pathway