Cracking the code of 3' ss selection in s.cerevisiae

Meyer, Markus

26 March 2010

The informational content of 3' splice sites is low and the mechanisms whereby they are selected are not clear. Here we enunciate a set of rules that govern their selection. For many introns, secondary structures are a key factor, because they occlude alternative 3'ss from the spliceosome and reduce the effective distance between the BS and the 3'ss to a maximum of 45 nucleotides. Further alternative 3'ss are disregarded by the spliceosome because they lie at 9 nucleotides or less from the branch site, or because they are weak splice sites. With these rules, we are able to explain the splicing pattern of the vast majority of introns in Saccharomyces cerevisiae. When in excess, L30 blocks the splicing of its own transcript by interfering with a critical rearrangement that is required for the proper recognition of the intron 3' end, and thus for splicing to proceed. We show that the protein Cbp80 has a role in promoting this rearrangement and therefore antagonizes splicing regulation by L30. / Tanto la información que define el sitio de splicing 3' como los mecanismos de selección del mismo son poco conocidos. En este trabajo, proponemos una serie de reglas que gobiernan esta selección. Las estructuras secundarias son claves en el caso de muchos intrones, porque son capaces de ocultar sitios de splicing alternativos 3' al spliceosoma, y además reducen la distancia efectiva entre el punto de ramificación y el sitio de splicing 3' a un máximo de 45 nucleotidos. Otros sitios de splicing alternativo 3' no son considerados por el spliceosoma como tales porque se encuentran a 9 nucleotidos o menos del punto de ramificación, o porque son sitios de splicing débiles. Con estas reglas somos capaces de explicar el splicing de la mayoría de intrones de Saccharomyces cerevisiae. El exceso de proteína L30 bloquea el splicing de su propio tránscrito porque interfiere con la reorganización necesaria para el correcto reconocimiento del 3' final del intrón, y por tanto de su splicing. Demostramos que la proteína Cbp80 está implicada en promover esta reorganización y que por tanto antagoniza la regulación del splicing por L30.

Saccharomyces cerevisiae

regulació genética

ARN empalmament

rearrangement

U2 snRNP

U1 snRNP

Cbp80

RPL30

L30

splicing regulation

secondary structure

selection

Branch site

3' splice site

5' splice site

Intron

mRNA

spliceosome

Pre-mRNA

splicing

57

Evolution and function of cellulase genes in Australian freshwater crayfish

Crawford, Allison Clare

January 2006

The most abundant organic compound produced by plants is cellulose, however it has long been accepted that animals do not secrete the hydrolytic enzymes required for its degradation, but rely instead on cellulases produced by symbiotic microbes. The recent discovery of an endogenous cDNA transcript encoding a putative GHF9 endoglucanase in the parastacid crayfish Cherax quadricarinatus (Byrne et al., 1999) suggests that similar cellulase genes may have been inherited by a range of crustacean taxa. In this study, the evolutionary history of the C. quadricarinatus endoglucanase gene and the presence of additional GHF9 genes in other decapod species were investigated. The activity of endoglucanase and endoxylanase enzymes within several cultured decapod species were also compared. The evolutionary history of the C. quadricarinatus endoglucanase gene was assessed by comparing intron/exon structure with that of other invertebrate and plant GHF9 genes. The coding region of the gene was found to be interrupted by eleven introns ranging in size from 102-902 bp, the position of which was largely conserved in both termite and abalone GHF9 genes. These structural similarities suggest GHF9 genes in crustaceans and other invertebrate taxa share a common ancestry. In addition, two introns were observed to share similar positions in plant GHF9 genes, which indicates this enzyme class may have been present in ancient eukaryote organisms. The presence of GHF9 genes in C. quadricarinatus and various other decapod species was then explored via degenerate primer PCR. Two distinct GHF9 gene fragments were determined for C. quadricarinatus and several other Cherax and Euastacus parastacid freshwater crayfish species, and a single GHF9 gene fragment was also determined for the palaemonid freshwater prawn Macrobrachium lar. Phylogenetic analyses of these fragments confirmed the presence of two endoglucanase genes within the Parastacidae, termed EG-1 and EG-2. The duplication event that produced these two genes appears to have occurred prior to the evolution of freshwater crayfish. In addition, EG-2 genes appear to have duplicated more recently within the Cherax lineage. The presence of multiple GHF9 endoglucanase enzymes within the digestive tract of some decapod species may enable more efficient processing of cellulose substrates present in dietary plant material. Endoglucanase and endoxylanase enzyme activities were compared in several parastacid crayfish and penaeid prawn species using dye-linked substrates. Endoglucanase activity levels were higher in crayfish compared with prawn species, which corresponds with the known dietary preferences of these taxa. Endoglucanase temperature and pH profiles were found to be very similar for all species examined, with optimum activity occurring at 60°C and pH 5.0. These results suggest endoglucanase activity in penaeid prawns may also be derived from endogenous sources. Additional in vitro studies further demonstrated crayfish and prawn species liberate comparable amounts of glucose from carboxymethyl-cellulose, which indicates both taxa may utilise cellulose substrates as a source of energy. Endoxylanase temperature and pH profiles were also similar for all crayfish species examined, with optimal activity occurring at 50°C and pH 5.0. These results suggest xylanase activity in crayfish may originate from endogenous enzymes, although it is unclear whether this activity is derived from GHF9 enzymes or a different xylanase enzyme class. In contrast, no endoxylanase activity was detected in the three prawn species examined. Together, these findings suggest a wide range of decapod crustacean species may possess endogenous GHF9 endoglucanase genes and enzymes. Endoglucanases may be secreted by various decapod species in order to digest soluble or amorphous cellulose substrates present in consumed plant material. Further biochemical studies may confirm the presence and functional attributes of additional endoglucanase genes and enzymes in decapods, which may ultimately assist in the design of optimal plant based crustacean aquaculture feeds.

aquaculture

aquafeed

cellulase

cellulose digestion

cherax

crayfish

crustacean nutrition

decapoda

duplication

endoglucanase

euastacus

eukaryote

evolution

gene structure

GHF9

glucose

intron position

macrobrachium

multigene family

NSP

palaemonidae

parastacidae

penaeus

phylogeny

plant material

protein evolution

structural polysaccharide

xylanase

Modulating RNA Splicing of DNA Topoisomerase IIα in Human Leukemia K562 Cells: Use of CRISPR/Cas9 Gene Editing to Impact Sensitivity/Resistance to the Anticancer Agent Etoposide

Hernandez, Victor A.

January 2021

No description available.

Pharmacology

Pharmaceuticals

Pharmacy Sciences

CRISPR/Cas9

Topoisomerase II

Etoposide

Drug resistance

Alternative Pre-mRNA splicing

Intron Retention and Processing

Modulating mRNA Splicing

AML

CML

The Role of a Nuclear-Encoded DEAD-box Protein from <i>Saccharomyces</i> <i>cerevisiae</i> in Mitochondrial Group I Intron Splicing

Bifano, Abby Lynn Shumaker

January 2010

No description available.

Biochemistry

Molecular Biology

DEAD-box proteins

group I intron splicing

catalytic RNAs

mitochondrial RNA processing

Molecular, morphological, and biogeographic resolution of cryptic taxa in the Greenside Darter <i>Etheostoma blennioides</i>complex

Haponski, Amanda E.

January 2007

No description available.

Biology, Genetics

biogeography

control region

cryptic species

cytochrome <i>b</i>

Greenside Darter

nuclear S7 intron 1

Identifizierung genetischer Biomarker für die Wirksamkeit von Oxaliplatin:Kandidatengen-bezogene und Genom-weite Analysen / Identification of genetic biomarkers for the efficacy of oxaliplatin - candidate gene and genome-wide approaches

Saman, Sadik

02 December 2014

No description available.

610

Oxaliplatin

Kolorektales Karzinom

Cisplatin

Carboplatin

rs11793978

rs74382821

micro-RNA hsa-miR-1277-3p

individualisierte Therpaie

Genom-weite Analyse

ERCC1

ERCC2

ERCC5

Zytotoxizität

CFSE

Vybrant Ruby

Sytox

Zellproliferation

Zellvitalität

Proliferationshemmung

DACH-Ligand

SLC31A1

LCL

lymphoblastoide Zelllinien

1000 human genomes

HapMap

Intron 1 SLC31A1

lymphoblastoid cell lines

ERCC1

SLC31A1

rs74382821

rs11793978

genome-wide

HapMap

1000 human genomes

cisplatin

carboplatin

micro-RNA hsa-miR-1277-3p

colorectal carcinoma

ATP7A

ATP7B

Oxaliplatin

cytotoxocity

cell vitality

cell proliferation

Sytox

Vybrant Ruby

CFSE

counting beads

LCL

Intron 1 SLC31A1

Medizin (PPN619874732)

Biochemical characterization of homing endonucleases encoded by fungal mitochondrial genomes

Guha, Tuhin

23 May 2014

The small ribosomal subunit gene of the Chaetomium thermophilum DSM 1495 is invaded by a nested intron at position mS1247, which is composed of a group I intron encoding a LAGLIDADG open reading frame interrupted by an internal group II intron. The first objective was to examine if splicing of the internal intron could reconstitute the coding regions and facilitate the expression of an active homing endonuclease. Using in vitro transcription assays, the group II intron was shown to self-splice only under high salt concentration. Both in vitro endonuclease and cleavage mapping assays suggested that the nested intron encodes an active homing endonuclease which cleaves near the intron insertion site. This composite arrangement hinted that the group II intron could be regulatory with regards to the expression of the homing endonuclease. Constructs were generated where the codon-optimized open reading frame was interrupted with group IIA1 or IIB introns. The concentration of the magnesium in the media sufficient for splicing was determined by the Reverse Transcriptase-Polymerase Chain Reaction analyses from the bacterial cells grown under various magnesium concentrations. Further, the in vivo endonuclease assay showed that magnesium chloride stimulated the expression of a functional protein but the addition of cobalt chloride to the growth media antagonized the expression. This study showed that the homing endonuclease expression in Escherichia coli can be regulated by manipulating the splicing efficiency of the group II introns which may have implications in genome engineering as potential ‘on/off switch’ for temporal regulation of homing endonuclease expression . Another objective was to characterize native homing endonucleases, cytb.i3ORF and I-OmiI encoded within fungal mitochondrial DNAs, which were difficult to express and purify. For these, an alternative approach was used where two compatible plasmids, HEase.pET28b (+)-kanamycin and substrate.pUC57-chloramphenicol, based on the antibiotic markers were maintained in Escherichia coli BL21 (DE3). The in vivo endonuclease assays demonstrated that these homing endonucleases were able to cleave the substrate plasmids when expressed, leading to the loss of the antibiotic markers and thereby providing an indirect approach to screen for potential active homing endonucleases before one invests effort into optimizing protein overexpression and purification strategies. / October 2016

Homing endonucleases

Small ribosomal subunit gene

Nested intron

Twintron

Ribozyme based molecular switch

Group I introns

Group II introns

Bioprospecting

Native homing endonuclease

Temporal regulation

Fungal mitochondrial DNA

Magnesium induction

Cobalt antagonization

DNA cutting enzymes

LAGLIDADG homing endonuclease

Splicing

Genome engineering

Identification et étude de mécanismes régulant l’expression de MAPK

Ashton-Beaucage, Dariel

12 1900

Les fichiers accompagnant le document sont en format Microsoft Excel 2010. / Les modèles classiques de signalisation cellulaire eucaryotes sont généralement organisés en voies linéaires et hiérarchiques, impliquant un ensemble de facteurs restreint. Ces facteurs forment un circuit isolé qui transmet une information externe vers sa destination, d’où une réponse cellulaire sera alors engendrée. Or, ces modèles sont justement le fruit d’approches expérimentales réductionnistes qui ne permettent pas d’intégrer aisément la contribution de facteurs multiples, ni de faire une évaluation quantitative de l’apport des composantes du système. Le développement de techniques d’investigation plus holistiques, telles la génomique fonctionnelle et la protéomique, permettent d’examiner de manière systématique et quantitative l’apport d’ensembles larges de facteurs et de les mettre en relation avec d’autres systèmes cellulaires. Il y aurait donc lieu de réévaluer le modèle de voie de signalisation linéaire au profit d’un modèle de réseau de signalisation multiparamétrique, comportant plusieurs branches d’entrée et sortie de signal interagissant avec d’autres systèmes cellulaires. Cet ouvrage porte sur la voie RAS/MAPK, l’un des principaux axes de signalisation associé à la prolifération et la différenciation cellulaires. Le sujet y est d’abord abordé sous l’angle d’une perspective historique, en mettant l’emphase sur les contributions des études de génétique classique chez les organismes modèles D. melanogaster et C. elegans. Il fait ensuite état du développement du criblage par ARNi pan-génomique dans ces deux modèles en le comparant aux approches de criblage génétique classique. Le corps de l’ouvrage décrit ensuite les résultats expérimentaux d’une campagne de criblage par ARNi visant à dresser une carte globale des régulateurs de la voie chez la drosophile. Trois groupes de régulateurs identifiés dans ce crible ont été caractérisés de manière plus détaillée. Dans un premier article, nous démontrons que les composantes du complexe EJC ont un impact sur l’épissage de mapk; une découverte doublement intéressante puisque l’EJC était jusqu’alors associé qu’à la régulation post-épissage des ARNm. Une seconde publication fait état de l’ensemble des résultats du crible ARNi, mettant l’emphase sur un ensemble de facteurs d’épissage qui modulent également mapk. Nous y montrons que l’impact de ces facteurs sur l’épissage alternatif est différent de celui de l’EJC, suggérant ainsi deux modes de régulation distincts. Finalement, dans un troisième manuscrit, nous nous attardons au rôle d’Usp47, une déubiquitinase qui, contrairement aux autres facteurs identifiés dans le crible, régule l’expression de MAPK de manière post-traductionnelle. Nous y détaillons une stratégie de criblage d’interaction génétique par ARNi visant à identifier des facteurs reliés fonctionnellement à Usp47. Ce second crible a permis l’identification de trois facteurs reliés au « N-end rule », un mécanisme de dégradation des protéines caractérisé par la reconnaissance des résidus N-terminaux de protéines ou peptides. Il existait jusqu’alors très peu de données quant à la régulation de l’expression des composantes de la voie MAPK, ce qui rend la description d’un large réseau de régulateurs agissant sur l’expression de MAPK d’autant plus insoupçonnée. L’absence d’un réseau équivalent rattaché aux autres composantes de la voie laisse supposer que MAPK serait un noeud servant de point d’entrée à ce type de régulation dans le système RAS/MAPK. De plus, nos travaux témoignent de la capacité de la génomique fonctionnelle à mettre en relation différents systèmes cellulaires de manière plus globale et à quantifier les liens établis entre eux. / The classical model of eukaryotic cellular signalling generally involves hierarchically organized linear pathways involving a restricted set of elements. These generally function together as an insulated circuit, transmitting information from the outside to the intracellular compartment involved in eliciting a response. These models, often the fruit of reductionist experimental approaches, do not allow for the integration of multiple inputs nor for a gradation of responses. The recent emergence of more holistic investigation techniques has brought about the re-evaluation of these classical models in favor of multiparametric signalling networks. This thesis focuses on the RAS/MAPK pathway, one of the cell’s main proliferation and differentiation signalling conduits, beginning with a historical perspective covering the contributions of model organism genetics to the current pathway model. This provides context for the description of a whole-genome RNAi screen experiment that we carried out to obtain a global view of regulators in Drosophila. Three groups of factors emerging from this screen were then examined in more detail. A first article shows that the exon junction complex (EJC) plays a role in mapk alternative splicing, an observation that is unexpected given that this complex was not previously known to act on splicing. A second paper details the genome wide screening campaign and focuses on a large set of splicing factors that also regulate mapk, albeit in a distinct manner than the EJC’s. Finally, a manuscript in a third segment examines Usp47 function and finds it to control MAPK levels post-translationally. An RNAi-based genetic interaction screen is then used to identify factors functionally related to Usp47 capable of counteracting its impact on MAPK levels. Three such factors identified through this technique are linked to the N-end rule protein degradation pathway. Regulation of core pathway component expression is a poorly described process, which makes the identification of a large set of factors regulating MAPK expression all the more unusual. Moreover, the absence of such regulation linked to other pathway components suggests that MAPK may act as a node incorporating inputs of this type into RAS/MAPK signaling dynamics.

signalisation RAS/MAPK

RAS/MAPK signalling

Drosophila melanogaster

criblage par ARNi

RNAi screen

complexe EJC

exon junction complex

EJC

épissage alternatif

alternative splicing

spliceosome

exon definition

définition d'exon

intron definition

définition d'intron

système ubiquitine-protéasome

ubiquitin-proteasome system

N-end rule

Characterising (pre-)mrnp organisation at different stages of gene regulation using single-molecule microscopy

Adivarahan, Srivathsan

07 1900

Les ARNm sont des molécules centrales pour la régulation des gènes, aidant à convertir l'information génétique stockée dans l'ADN en protéines fonctionnelles. En tant que polymère simple brin, mesurant des centaines à des milliers de nucléotides, les ARNm peuvent former des structures secondaires et tertiaires étendues formant des particules appelés ribonucléoprotéines messagères (RNPm) en s’assemblant avec des protéines. L'organisation 3D des (pré-)RNPm influence de nombreux aspects de leur métabolisme, incluant la régulation de leur maturation, de leur export et de leur traduction dans le cytoplasme. Malgré leur importance, notre compréhension de l'organisation structurelle des (pré-)RNPm in vivo, et des principes qui la régissent est minime. Au cours de ma thèse, j'ai analysé l'organisation des (pré-)mRNP en développant une vision centrée sur l'ARN. Pour cela, j'ai mis en place une approche combinant l'hybridation in situ d'ARN monomoléculaire (smFISH) avec la microscopie à illumination structurée (SIM) et l'ai utilisée pour étudier l'organisation des mRNP dans le noyau et le cytoplasme. Nos résultats suggèrent que l'organisation (pré-)mRNP varie à différents stades de sa vie. Nous montrons que l'empaquetage (pré-)mRNP commence de manière co-transcriptionnelle, avec des introns organisés en conformations compactes. Cette organisation est modifiée au cours de la transcription au fur et à mesure que la polymérase se déplace le long du gène, assemblant finalement un intron avec les extrémités à proximité l’une de l’autre, d'une manière dépendante du spliceosome, suggérant que l'organisation co-transcriptionnelle des introns pourrait être critique pour déterminer son excision. Une fois libérés, les mRNP ont une organisation linéaire compacte dans le nucléoplasme et éventuellement une conformation en tige. L'organisation d’un mRNP dans le cytoplasme est influencée par sa traduction. Alors que la traduction ouvre les mRNP, la séparation des extrémités de l'ARNm, l'inhibition de la traduction et la libération de ribosomes, ou le recrutement dans les granules de stress, donnent aux mRNP une structure très compacte. Fait intéressant, nous trouvons rarement des ARNm avec les extrémités 5' et 3' à proximité, ce qui suggère que la traduction en boucle fermée n'est pas un état universel pour tous les ARNm en cours de traduction. Ensemble, nos résultats fournissent une image essentielle de l'organisation du mRNP dans les cellules et souligne le rôle important de la conformation du RNPm dans la régulation de la traduction et de la maturation d’une RNPm. / mRNAs act as the central molecules in gene regulation, helping convert the genetic information stored in the DNA to functional proteins. As a single-stranded polymer, hundreds to thousands of nucleotides in length, mRNAs can form extensive secondary and tertiary structures and, together with proteins, are packaged into assemblies called messenger ribonucleoproteins (mRNPs). The 3D organisation of (pre-)mRNPs influences many aspects of what happens to them, including regulating their processing, export and translation in the cytoplasm. Despite their significance, our understanding of the structural organisation of (pre-)mRNPs in vivo is minimal, as is our comprehension of the principles that govern it. During my PhD, I have developed an RNA-centric view on (pre-)mRNP organisation. For this, I have established an approach combining single-molecule RNA in situ hybridisation (smFISH) with structured illumination microscopy (SIM) and used it to study mRNP organisation in the nucleus and cytoplasm. Our results suggest that (pre-)mRNP organisation is altered at various stages during its lifetime. We show that (pre-)mRNP packaging starts co-transcriptionally, with introns organised into compact conformations. This organisation is altered during the course of transcription as the polymerase travels along the gene, finally assembling an intron with the ends in proximity in a spliceosome dependent manner, suggesting that co-transcriptional intron organisation could be critical in determining its excision. Once released, mRNPs have a compact linear organisation in the nucleoplasm and possibly a rod-like conformation. mRNP organisation in the cytoplasm is influenced by its translational status. While translation opens up mRNPs, separating the ends of the mRNA, translation inhibition and release of ribosomes, or recruitment to stress granules result in mRNPs having a highly compact structure. Interestingly, we rarely find mRNAs with the 5’ and 3’ ends in proximity, suggesting that closed-looped translation is not a universal state for all translating mRNAs. Together, our results provide a unique and essential view of mRNP organisation in cells and reveal important insight into the role of mRNP conformation in regulating translation and mRNP processing.

mRNP

pre-mRNP

mRNP organization

single molecule microscopy

closed-loop model

smFISH

mRNP architecture

mRNA structure

5’-3’ communication

mRNA translation

mRNA splicing

RNA compaction

RNA imaging

super-resolution microscopy

U1-Pol II tethering

intron looping