Studies On Saccharomyces Cerevisiae RNA Polymerase II Subunit Rpb7 And Its Eukaryotic Orthologs

Singh, Rajkumar Sunanda

10 1900

Saccharomyces cerevisiae is an excellent experimental model organism to study various biological processes owing to its versatile genetics, biochemistry, and standard laboratory conditions. S. cerevisiae shows distinct biological responses under nutritional starvation conditions. S. cerevisiae undergoes dimorphic transition from a unicellular yeast form to a multicellular pseudohyphae (Gimeno et al., 1992) under nitrogen starvation, but in the complete absence of a fermentable carbon source, it undergoes gametogenesis called sporulation (Mitchell, 1994). While the signal transduction cascades and regulatory controls under nutritional starvation conditions are studied to great extent, the role of S. cerevisiae core RNA polymerase II (pol II) is not much understood. S. cerevisiae core RNA pol II consists of 12 subunits (Woychik and Hampsey, 2002), which is organized into a ten-subunit core and the Rpb4/7 subcomplex (Edwards et al., 1991). Rpb4/7 subcomplex is known to play important roles in stress survival (Choder 2004; Sampath and Sadhale, 2005.). S. cerevisiae rpb4 null diploid strains show reduced sporulation levels but exhibits a predisposition to pseudohyphal morphology (Pillai et al., 2003). Overexpression of Rpb7 partially rescues some of these defects (Sharma et al., 1999; Sheffer et al., 2001). Rpb7 is a highly conserved protein but Rpb4 is the least conserved amongst all RNA pol II subunits at the sequence level. Rpb4 and Rpb7 also affect different cellular functions, which are not directly dependent on each other. (a) Relative levels of RNA pol II subunits Rpb4 and Rpb7 differentially affect starvation response in Saccharomyces cerevisiae S. cerevisiae rpb4 null diploid strains show reduced sporulation levels as compared to wild type but exhibits pseudohyphal predisposition. Overexpression of RPB7 partially rescues the sporulation defect but results in an exaggeration of the pseudohyphae phenotype. We generated S. cerevisiae strains expressing different levels of Rpb4 and Rpb7 proteins in the same strains and analyzed their effect on sporulation and pseudohyphal morphology. We observed that sporulation is dependent on Rpb4 because sporulation level gradually increases with an increase in the Rpb4 protein level in the strain. Rpb7 reduces sporulation level but enhances pseudohyphal exaggeration in a dose-dependent manner. Rpb4 is dominant over Rpb7 in both the starvation responses because strain expressing an equimolar ratio of Rpb4 and Rpb7 protein exhibits RPB4+ phenotypes. (b) Domainal organization of Saccharomyces cerevisiae Rpb7 orthologs reflects functional conservation Rpb7 orthologs are known in eukaryotes and archaebacteria. The primary structure of Rpb7 is conserved. We chose Rpb7 orthologs from Candida albicans, Schizosaccharomyces pombe and Homo sapiens sapiens to investigate whether Rpb7 orthologs are also functionally conserved. We observed that all the orthologs tested are functionally conserved because they can complement the absence of RPB7 in S. cerevisiae. However, we uncovered functional differences amongst Rpb7 orthologs with respect to its function in rpb4 null strain and ess1 ts strain. Furthermore, we made N and C-terminal chimeric RPB7 constructs from these orthologs with S. cerevisiae Rpb7. These chimeras also can replace ScRpb7 in S. cerevisiae. However, functional differences were observed with each chimera pair in rpb4 null strain and ess1 ts strain, showing that the N and C-terminal domains of Rpb7 protein can be genetically dissected. The genetic observation on the domainal organization of Rpb7 orthologs is strengthened by the crystal structure of Rpb7 (Armache et al., 2005), which shows that Rpb7 is structurally organized into an N terminal RNP domain and a C terminal OB fold domain. (c) The Rpb7 subunit of Candida albicans RNA polymerase II induces lectin-mediated flocculation in Saccharomyces cerevisiae The Rpb7 ortholog of C. albicans is a conserved functional ortholog of ScRpb7. We observed that CaRpb7 induces Ca2+-dependent flocculation and agar-invasive growth in S. cerevisiae. CaRpb7 overexpression induces very high transcript levels of FLO1 and FLO11. We believe that the observed flocculation and agar-invasive phenotypes are due to Flo1 and Flo11 respectively, because Flo1 and Flo11 contribute mainly to cell-cell adhesion while Flo11 contributes mainly to cell-substrate adhesion (Verstrepen and Klis, 2006; Lo et al., 1998; Guo et al., 2000). Pathway analysis revealed that CaRpb7-induced flocculation is dependent on Mss11 transcriptional activator. Two-hybrid analysis revealed that CaRpb7 does not physically interact with transcriptional repressors known to repress FLO gene transcription, however genetic analysis revealed that CaRpb7 is epistatic to the repressor Sfl1. Rpb7 orthologs possess conserved domains with potential RNA binding ability (Orlicky et al., 1999) and ScRpb7 is known to play in mRNA stability (Lotan et al., 2007). The possibility of CaRpb7 specifically affecting the stability of FLO gene transcripts is being pursued.

Saccharomyces Cerevisiae

RNA Polymerase II

Sporulation

Gene Transcription

Rpb7 Orthologs

Eukaryotic Orthologs

Flocculation

Rpb4

RNA polII

Mycology

Identification And Characterisation Of Two Silencing Barrier Sequences In Saccharomyces Cerevisiae

Biswas, Moumita

02 1900

In eukaryotic cells, genomic DNA exists as chromatin in association with histone octamers called nucleosomes, and various other chromatin proteins. Chromatin structure varies along the chromosome and this influences the state of gene expression. Based on such variations in structure and gene expression, chromatin can be broadly classified into euchromatin (transcriptionally active) and heterochromatin (silent or transcriptionally repressed). In the budding yeast, Saccharomyces cerevisiae, there are four canonical transcriptionally silent regions, namely, the HMR, the HML (cryptic mating loci), the telomeres and the RDN1. Silencing at the HM loci and the telomeres is very well characterized. The repressive structure at the HMR spans around 3.5 Kb and extends between the two silencers E and I. It is well established that silencing in HMR is due to a specialized chromatin organization brought about by Orc1p, Rap1p, Abf1p and Sir proteins. Following recruitment, the Sir proteins spread along the DNA to form a repressive chromatin domain believed to arise from the deacetylation of amino-terminal tails of histones H3 and H4 by Sir2p (an NAD dependent deacetylase) and the interaction of Sir3p and Sir4p with the histones. The bi-directional spreading of silencing at HMR is restricted by barrier or boundary elements that flank the silencers. A tRNAThr gene in the right boundary of HMR acts as a strong barrier. Mutations in the promoter of this tRNA gene (tDNA) or in RNA polymerase III subunits/ transcription factors weaken the barrier activity of this tDNA. The barrier activity of this tDNA is also dependent on histone acetyltransferases like Sas2p and Gcn5p. Silencing in HML is uniformly high between the silencers E and I and falls sharply outside I. Recently, barriers to HML silencing have been discovered. A 0.71Kb sequence near E, which maps to the upstream activating sequence of YCL069W, acts as a robust barrier to spread of HML silencing. This is effectively the left boundary of silent HML. The right boundary maps to the promoter of CHA1 gene though silencing is believed to terminate at HML-I. An unusual form of silencing occurs at the RDN1, which contains 100-150 copies of tandemly repeated rRNA genes. Some RNA polymerase II transcribed genes integrated within the array are silenced by a Sir2p dependent mechanism whereas genes driven by RNA polymerases III and I are transcriptionally active. Though all the three forms of silencing (RDN1, HM and telomere) require Sir2p, RDN1 silencing differs from the others in its relative strength and factors responsible for repression. Several trans-acting factors required for RDN1 silencing are known. However, it is still unclear as to what limits the spread of RDN1 heterochromatin into neighbouring essential genes. RDN1 silencing spreads unidirectionally in its left hand side sequence. However, the zone of RDN1 heterochromatin does not engulf the essential gene, ACS2, which is present ~3 kb away from NTS1. This implies that there is a mechanism by which rDNA heterochromatin is contained. There could be several ways by which this is accomplished. Firstly, the cell could be critically maintaining the levels of Sir2p, the protein required for silencing at all the four silenced loci, such that silencing in the left flank of RDN1 does not spread beyond 300 bp of NTS1 (Buck et al, 2002). There is a ~2.5 kb gene free intervening sequence between NTS1 of the rDNA array and the Ty1 LTR, in which interval Sir2p level could fall below the threshold mark required for causing repression. In fact Buck et al. have demonstrated that Sir2p is bound to upto 1.5 kb from the NTS1 in the left flank but there is no accompanying silencing of the mURA3 reporter in these regions (1200L and 2000L), suggesting that the level of Sir2p at these sequences could be lower than the threshold required for initiation of silencing. Secondly, there could be cis-acting boundary elements or barriers as in the case of HMR, which prevents the propagation of RDN1 silencing. The third option is that termination of RNA polymerase I transcription at the terminator sites automatically halts the spread of rDNA silencing since Buck et al. have demonstrated that progression of rDNA heterochromatin is dependent on RNA pol I transcription. This however, does not seem to be the case as deletion of both the terminator sites within NTS1 does not lengthen the zone of silencing. Finally, there could be an euchromatin organizing center further from the array, which creates an “open” chromatin configuration required to confront the Sir2p mediated condensed chromatin. The balance of these two opposing activities, much like that at the telomeres, could set up a molecular boundary for containing rDNA silent chromatin. We have attempted to identify whether there are any sequences in the unique left flank of RDN1 that can act as a heterochromatin barrier. Towards that end we tested four overlapping fragments from NTS1 of RDN1 to the promoter of ACS2 for boundary activity in a quantitative mating assay. We have found that of all the four fragments tested, only a 0.427 kb tRNAGln-Ty1 LTR fragment, which is present 2.4 Kb from the NTS1 acts as a robust barrier in this assay. Further mapping revealed that the barrier activity of this sequence resides in the tRNAGln gene and that its activity is orientation-independent. tDNAs are transcribed by RNA polymerase III from internal promoters termed Box A and Box B. It has been shown for the HMR-tRNAThr that the transcriptional potential of the tDNA is crucial for its barrier function. Mutations in genes encoding various subunits of the RNA polymerase III complex, or transitions in the conserved bases within Box B known to disrupt transcription complex assembly and subsequent transcription, abrogate the barrier activity of HMR-tRNAThr. Similarly, loss of transcriptional ability of the tRNAAla in the centromere of S. pombe also abolishes its barrier activity, enforcing the fact that RNA polymerase III transcription is a decisive factor for a tDNA barrier. Contrary to the above observations, we report that barrier activity of tRNAGln is very negligibly dependent on RNA polymerase III mediated transcription. Mating assays done with the RNA pol III mutants and promoter point mutants, G18C and C55G in boxes A and B respectively, underline the fact that for this tDNA barrier, RNA pol III driven transcription is dispensable. We also show by RT-PCR analysis that in the C55G tRNAGln mutant there is loss of transcription as expected, whereas other wild type copies of tRNAGln are transcribed. Studies with another tDNA barrier, TRT2-tRNAThr, yielded similar results, again emphasizing the point that transcription through the tDNA, which leads to nucleosome displacement and therefore barrier activity, may not be applicable for all tDNA barriers. Acetylation of amino terminal tails of histones is known to influence the epigenetic state of chromatin. Addition of acetyl moiety to histones H3 and H4 initiates a cascade of events, which involves recruitment of a host of other chromatin modifiers to the target sequence, and ultimately culminates in the formation of an euchromatin-favouring environment. As reported for the HMR right boundary, we find that barrier activity of tRNAGln depends on two histone acetyl transferase complexes, SAS-I (comprised of Sas2p, Sas4p and Sas5p) and SAGA (contains Gcn5p HAT). Contrary to the HMR boundary, the barrier activity of tRNAGln is independent of two other nucleoplasmic HATs, NuA3 (Sas3p being the HAT) and NuA4 (Esa1p is the HAT). Barrier function of TRT2-tRNAThr also depends on HATs. Therefore it appears that requirement of HATs for boundary activity is a conserved theme, albeit with differential effects at different barrier sequences. We next attempted to determine the function of tRNAGln in its natural location on chromosome XII. As mentioned earlier, RDN1 silencing spreads upto ~0.3 kb in its left flanking sequence. However, Sir2p occupancy has been observed till 1.5 kb although there is no silencing of reporter genes observed beyond 0.3 kb of NTS1. This lead us to speculate that there could be a boundary sequence in the left flank that stops silencing, or a euchromatin-organizing element, which counters the propagation of silencing by a long-range effect. Since over expression of Sir2p extends the domain of silencing from 0.3 kb to 2.0 kb and the tRNAGln is present at 2.3 kb from NTS1, it was a good candidate for a heterochromatin barrier/ euchromatiniser. However, deletion of tRNAGln does not affect the zone of RDN1 silencing as is evident from our cell viability assays (which is a measure of the expression of the essential gene ACS2 situated further to the left of tRNAGln). Deletion of SAS2 and GCN5, factors that are required for barrier activity of tRNAGln in mating assays, also have no effect on the extent of spreading of RDN1 silencing in normal or Sir2p over expression conditions. Together, these observations imply that in situ, tRNAGln does not act as a barrier or an element with long-range euchromatin inducing properties. It still remains unclear as to what contains RDN1 silencing. It is possible that the cell critically monitors the level of Sir2p in order to maintain boundaries of silencing at the rDNA locus. Telomeres also nucleate the formation of silenced domain which spreads along the subtelomeric region upto ~ 2Kb. The key players in the formation of telomeric heterochromation are the Sir proteins, Sir2p, Sir3p and Sir4p, Rap1p, yKu complex and ORC. Protein-protein interactions between the telosome and the subtelomeric repeat bound silencing proteins create a domain of core heterochromatin that spreads in the adjacent sequences. While Sir2p deacetylates H4K16, Sir3p interacts with the hypoacetylated histone tails and helps in the spreading of the repressive chromatin structure. As a result telomere proximal genes are silent whereas the ones further away are expressed. There is a gradient of acetylation of histone H4, with the hypoacetylated histones at the telomeric ends and the hyperacetylated ones distant from the telomere. Recently it has been shown that this gradient is maintained by the concerted and antagonistic actions of Sir2p and Sas2p. In a sas2Δ strain Sir3p spreads to ~15 kb in the subtelomeric regions and there is increase in the levels of hypoacetylated histones. Though the molecular mechanism by which telomeric silencing is restrained is beginning to be understood, it remains unanswered whether there are any cis-acting sequences, capable of recruiting euchromatin-inducing factors such as Sas2p, near the telomeres. We have identified a RNA polymerase II driven gene, AAD3, in the subtelomeric region of chromosome III that has robust anti-silencing activity. Deletion mapping revealed that only 0.381 kb in the 5′ portion of the gene (excluding the promoter) is sufficient for barrier activity and that this property is orientation-independent (henceforth referred to as TEL-B). The barrier acivity of TEL-B depends strongly on Sas2p and Esa1p but not on Gcn5p and Sas3p, and is independent of cohesin. Previous investigations have shown that acetylation of H4K16 by Sas2p at subtelomeric regions of chromosome VI leads to deposition of HTZ1 in the nucleosome and its subsequent acetylation by Esa1p of NuA4. All these events together are required to contain the onslaught of telomeric core heterochromatin on neighbouring active regions. Since barrier activity of TEL-B depends on Sas2p and Esa1p, it is possible that TEL-B has the potential to act as a bona fide barrier in situ in its endogenous context. Our hypothesis is further cemented by the observation that there is a physical association between Sas2p, the molecule at the top of the entire cascade of events, with TEL-B by yeast one hybrid analysis. Further experiments will shed light on the role of this sequence in its natural location. In summary, I have identified and characterized two different barrier sequences in S. cerevisiae. Not many barriers are known in budding yeast and there is extensive ongoing research dedicated to understand the mechanism(s) of barrier function. In chapter I of my thesis I present a review of current literature regarding silencing barriers in yeast and other systems. In chapter II I have outlined a detailed characterization of a tDNA barrier element, tRNAGln, present near the silenced rDNA array on chromosome XII. My work addresses the various models for barrier activity and their applicability to the tRNAGln barrier. I have also attempted to understand the role of this tDNA in its natural location on the chromosome with respect to limitation of RDN1 silencing. In chapter III I have described an intensive study of a RNA polymerase II transcribed gene, AAD3, present near the right telomere of chromosome III, which acts as a robust barrier to silencing. I have attempted to answer which mechanism(s) is/are operational at this sequence so as to endow it with barrier potential. My studies with the two barrier elements highlight novel trans-acting factors required for barrier function, differential and selective requirements of certain factors for different barriers, and provide a mechanistic view of the boundary activity of these sequences.

Silencing Barrier Sequences

Gene Sequences

Saccharomyces Cerevisiae

Gene Transcription

Histone Code Hypothesis

Ribosomal DNA Silencing

Microbiology

Diversidade na arquitetura e expressão gênica: uma análise quantitativa de Exon shuffling e splicing alternativo / Diversity in architecture and gene expression: a quantitative analysis of Exon shuffling and alternative splicing

Fabio Passetti

20 June 2002

A função e a arquitetura dos genes está começando a ser elucidada a partir do estudo de genomas completos tanto de procariotos como de eucariotos. Diversos estudos foram ultimamente realizados a respeito de exon shuffling do ponto de vista evolutivo, fenômeno relacionado à origem de novos genes através de recombinações de DNA mediadas por introns. Apesar de eventos de exon shuffling serem responsáveis pelo aumento da modularidade gênica, outros processos foram desenvolvidos ao longo da evolução para que houvesse o aumento da diversidade do proteoma sem a conseqüente expansão dos genomas, sendo splicing alternativo um dos mais freqüentes. Apresentamos nesta dissertação duas extensivas análises: 1) a análise de uma base de dados de genes eucarióticos contendo pelo menos um intron que apresentou excesso de introns de fase 0 e exons simétricos, dados que suportam exon shuffling como um importante mecanismo de evolução gênica. Avaliamos também a confiabilidade de introns preditos por programas de computador através de alinhamento de ESTs; e 2) a análise do uso alternativo de exons (UAE), um tipo de splicing alternativo, em transcritos humanos detectando que cerca de 51% dos genes humanos possuem mais de uma variante de splicing e que este tipo de processamento pós-transcricional parece ser mais freqüentemente encontrado em tecidos tumorais. / Abstract not available.

Bioinformática

DNA recombinante

Expressão gênica

Genomas (Estudo)

Transcrição gênica

Transcriptoma

Bioinformatics

Gene expression

Gene transcription

Genomes (Study)

Recombinant DNA

Transcriptome

Transcriptional Activation of the Cholesterol 7α-Hydroxylase Gene (CYP7A) by Nuclear Hormone Receptors

Crestani, Maurizio, Sadeghpour, Azita, Stroup, Diane, Galli, Giovanni, Chiang, John Y.L.

01 November 1998

The gene encoding cholesterol 7α-hydroxylase (CYP7A), the rate-limiting enzyme in bile acid synthesis, is transcriptionally regulated by bile acids and hormones. Previously, we have identified two bile acid response elements (BARE) in the promoter of the CYP7A gene. The BARE II is located in nt - 149/-118 region and contains three hormone response element (HRE)-like sequences that form two overlapping nuclear receptor binding sites. One is a direct repeat separated by one nucleotide DR1 (-146-TGGACTtAGTTCA-134) and the other is a direct repeat separated by five nucleotides DR5 (-139- AGTTCAaggccGGGTAA-123). Mutagenesis of these HRE sequences resulted in lower transcriptional activity of the CYP7A promoter/reporter genes in transient transfection assay in HepG2 cells. The orphan nuclear receptor, hepatocyte nuclear factor 4 (HNF-4)1, binds to the DR1 sequence as assessed by electrophoretic mobility shift assay, and activates the CYP7A promoter/reporter activity by about 9-fold. Cotransfection of HNF-4 plasmid with another orphan nuclear receptor, chicken ovalbumin upstream promoter- transcription factor II (COUP-TFII), synergistically activated the CYP7A transcription by 80-fold. The DR5 binds the RXR/RAR heterodimer. A hepatocyte nuclear factor-3 (HNF-3) binding site (-175-TGTTTGTTCT-166) was identified. HNF-3 was required for both basal transcriptional activity and stimulation of the rat CYP7A promoter activity by retinoic acid. Combinatorial interactions and binding of these transcription factors to BAREs may modulate the promoter activity and also mediate bile acid repression of CYP7A gene transcription.

bile acid response element

bile acid synthesis

cholesterol 7α- hydroxylase

cytochrome P450

gene transcription and regulation

nuclear hormone receptor

Expressão temporal dos genes do nucleopoliedrovírus Anticarsia gemmatalis e sua influência sobre a célula. / Temporal expression of the Anticarsia gemmatalis nucleopolyhedrovirus genes and its influence on the cell.

Oliveira, Juliana Velasco de Castro

06 October 2010

Desde a década de 80, o nucleopoliedrovírus Anticarsia gemmatalis (AgMNPV) tem sido utilizado no Brasil como agente de controle biológico no combate à lagarta-da-soja, resultando para o país significativos benefícios econômicos e ecológicos. Este vírus envelopado, pertencente à família Baculoviridae, possui DNA circular de fita dupla (132.239 pb) contido em um capsídeo protéico, que pode estar ocluído em uma matriz para-cristalina. Neste trabalho, analisamos a expressão temporal de seus genes em duas linhagens celulares (UFL-AG-286 e IPLB-SF-9), por PCR em tempo real. Outro objetivo foi o estudo do efeito da multiplicação viral na malha gênica celular (GRN), visando analisar a expressão gênica celular diferenciada durante a infecção, através da técnica de hibridização subtrativa. Verificamos que todas as ORFs (exceto ORFs 64 e 83, que provavelmente não codificam a genes) foram expressas, com diferenças significativas entre as linhagens, principalmente em relação ao nível de expressão. Apesar disso, o grupo de genes ligados a replicação apresentou perfil de expressão similar nas duas linhagens, possivelmente por este ser um processo essencial à replicação viral. De uma forma geral, todos os genes apresentaram um perfil de expressão mais precoce do que o relatado na literatura, o que poderia ser tanto devido à replicação precoce do DNA do AgMNPV quanto até mesmo consequência da sensitividade do método utilizado. O agrupamento dos genes por k-means seguiu, em sua maioria, a hora pós-infecção (p.i.) onde a expressão de cada gene foi detectada, o que é coerente com a expressão gênica em cascata de baculovírus. Entretanto, por esta classificação não foi possível predizer função gênica para os genes pouco caracterizados. Em relação ao efeito da infecção do AgMNPV na GRN da UFL-AG-286, observamos que em 20h p.i., uma grande diversidade de genes e funções celulares foram hipo-expressas. / Since the 80s, the Anticarsia gemmatalis nucleopolyhedroviruses (AgMNPV) has been used in Brazil as a biological control agent against the Anticarsia gemmatalis caterpillar in soybean fields, resulting in considerable economic and ecological benefits. This enveloped virus belongs to the Baculoviridae family. It has circular double-stranded DNA (132239 bp) enclosed in a capsid, which can be occluded in a crystalline matrix. In this work we elucidated the temporal gene expression profile of the AgMNPV-2D in two cell lines (UFL-AG-286 and IPLB-SF-9), using a real time PCR. Another objective was to study the effect of viral replication on the cellular gene regulatory network (GRN), in order to analyze the differential cellular gene expression during infection, using subtractive hybridization method. We found that most ORFs (except 64 and 83 ORFs that probably do not encode genes) were expressed, with significant differences between cell lines, mainly in expression intensity. However, the group of genes associated with viral DNA replication had similar expression profile in both lineages, possibly because replication is an essential process for viral multiplication. In general, most genes had earlier expression than reported in the literature, probably due to the early DNA replication in AgMNPV. Moreover, this could be a consequence of the method sensitivity used herein. We clustered genes with the k-means algorithm according to the time pos infection (p.i.) in which each gene expression was first detected and found it to be consistent with the typical cascade of gene expression known for baculovirus. Nonetheless, following this classification, it was not possible to predict gene function for poorly characterized genes. When looking at the impact of viral replication on the host GRN using subtractive hybridization, we found considerable inhibition of cellular transcription at 20h p.i. Furthermore at this time, a large and diverse set of cellular genes and functions were found to be hypo-regulated, indicative of an extensive effect of AgMNPV infection on the UFL-AG-286 GRN.

Baculoviridae

Baculoviridae

AgMNPV

AgMNPV

Baculovirus

Baculovírus

Biological control

Controle biológico

DNA virus

Expressão gênica

Gene expression

Gene transcription

Hibridização subtrativa

Subtractive hybridization

Transcrição gênica

Vírus de DNA

O diabetes abole o aumento da expressão do gene SLC2A4 induzido pela contração muscular \"in vitro\": participação das cinases AMPK E CAMKII e dos fatores transcricionais MEF2D, GEF, HIF-1<font face=\"Symbol\">a e TR<font face=\"Symbol\">a. / Diabetes abolishes the \'\'in vitro\'\' muscle contraction-induced increase in SLC2A4 gene expression. Participation of AMPK and CAMKII kinases and MEF2D, GEF, HIF-1<font face=\"Symbol\">a and TR<font face=\"Symbol\">a1 transcriptional factors.

Lima, Guilherme Alves de

18 August 2011

O gene SLC2A4 codifica a proteína GLUT4, fundamental na homeostasia glicêmica. OBJETIVO: Investigar o efeito do diabetes na expressão do GLUT4 pela atividade contrátil. MÉTODOS: Músculos sóleos de ratos não diabéticos (ND) e diabéticos tratados com insulina (DI) ou salina (DS) foram incubados e contraídos. A expressão de GLUT4, pAMPK e CAMKII foram analisados por PCR e Western blotting, e a atividade de MEF2D, GEF, HIF-1<font face=\"Symbol\">a e TR<font face=\"Symbol\">a1 por gel shift. Células C2C12 transfectadas com plasmídeos contendo os sítios de ligação para MEF2, HIF, e TR foram tratadas com AICAR ou cafeína. RESULTADOS: Em animais ND e DI, a contração aumentou o conteúdo de GLUT4, mas não nos DS. Em animais ND, a contração aumentou a atividade da AMPK e dos fatores MEF2D, GEF e TR<font face=\"Symbol\">a1, mas não nos DS. Em animais ND, os inibidores de AMPK e CAMKII aboliram o aumento do GLUT4 e da atividade de MEF2D e GEF. Em células C2C12 a cafeína e a AMPK ativaram os 3 sítios. CONCLUSÃO: O diabetes abole o aumento da expressão do GLUT4 sob a atividade contrátil devido a redução da atividade de MEF2D, GEF e TR<font face=\"Symbol\">a1 e AMPK. / The SLC2A4 gene encodes the GLUT4 protein, which is essential in glucose homeostasis. OBJECTIVE: To investigate the diabetes effect on muscle contraction-induced in SLC2A4 gene expression. METHODS: Soleus muscles of Non diabetic rats (ND) and diabetic treated with insulin (DI) or saline (DS) were incubated and contracted. The GLUT4, pAMPK and CAMKII expressions were analyzed by PCR and Western blotting, and the MEF2D, GEF, HIF-1<font face=\"Symbol\">a and TR<font face=\"Symbol\">a1 activity by gel shift. C2C12 cells transfected with plasmids containing the binding sites for MEF2, HIF, and TR were treated with AICAR or caffeine. RESULTS: Contraction increased the GLUT4 amount in animals ND and DI, but not in DS. In ND animals, contraction increased AMPK, MEF2D, GEF and TR<font face=\"Symbol\">a1 activity, but not in DS. In ND animals, AMPK and CAMKII inhibitors abolished the GLUT4 increase as like MEF2D and GEF activity. In C2C12 cells AMPK and caffeine activated the 3 sites. CONCLUSION: Diabetes abolishes the muscle contraction-induced GLUT4 increase due to reduced of MEF2D, GEF, TR<font face=\"Symbol\">a1 and AMPK activity.

Cellular signal transduction

Diabetes mellitus

Diabetes mellitus

Fatores de transcrições

Gene transcription

Músculo esquelético

Skeletal muscle

Transcrição gênica

Transcription factors

Transdução de sinal celular

Transport through the membrane

Transporte através da membrana

Influence of light and cytokinin on organellar phage-type RNA polymerase transcript levels and transcription of organellar genes in Arabidopsis thaliana

Borsellino, Liliana

09 January 2012

Licht und Pflanzenhormone sind essentiell für das Wachstum und die Entwicklung von Pflanzen. Es ist nur wenig darüber bekannt, wie sie die Transkription organellärer Gene beeinflussen. In Arabidopsis thaliana gibt es drei kernkodierte Phagentyp-RNA-Polymerasen (RpoT), welche für die organelläre Transkription verantwortlich sind. Diese werden in die Plastiden (RpoTp), die Mitochondrien (RpoTm) oder zu beiden Organellen (RpoTmp) transportiert. Neben den beiden kernkodierten RNA-Polymerasen (NEP) existiert in den Plastiden eine plastidärkodierte RNA-Polymerase (PEP), welche zusätzliche Sigmafaktoren zur Promotererkennung benötigt. Um die Lichtabhängigkeit der Expression der RpoT Gene sowie NEP-transkribierter Chloroplastengene zu analysieren, wurde die Akkumulation von RpoT- und rpoB-Transkripten in 7-Tage alten Keimlingen unter verschiedenen Lichtbedingungen mittels quantitativer real-time PCR untersucht. Die Änderungen in der Transkriptakkumulation deuten darauf hin, dass rote, blaue und grüne Wellenlängen die Expression der drei RpoT Gene unterschiedlich stark stimulieren. Untersuchungen an verschiedenen Lichtrezeptor-Mutanten zeigten, dass die Lichtinduktion der RpoT Genexpression überaus komplex ist und ein interagierendes Netzwerk aus multiplen Rezeptoren und Transkriptionsfaktoren an der Signalweiterleitung beteiligt ist. Das Phytohormon Cytokinin wird durch Histidin Kinase Rezeptoren (AHK) detektiert. Es gibt drei unterschiedliche Rezeptoren: AHK2, AHK3 und AHK4. Diese sind Teil eines Zwei-Komponenten-Systems, welches Signale mit Hilfe einer Phosphorylierungskette überträgt. Der Einfluss von Cytokinin auf die plastidäre Transkription wurde mit Hilfe von Cytokininrezeptor-Mutanten untersucht, um die Funktion von AHK2, AHK3 und AHK4 zu analysieren. Um weitere Informationen darüber zu erhalten, wie die plastidäre Transkription durch PEP mittels Cytokinin reguliert wird, wurden die Hormoneffekte auf die plastidäre Transkription in Sigmafaktor-Mutanten untersucht. / Light and plant hormones are essential for plant growth and development. Only little information is available about how these signals influence the transcription of organellar genes. Arabidopsis thaliana possesses three nuclear-encoded phage-type RNA polymerases (RpoT) for organellar transcription. They are imported into plastids (RpoTp), mitochondria (RpoTm), or into both organelles (RpoTmp). Besides the two nuclear-encoded plastid polymerases (NEP), plastids contain an additional plastid-encoded RNA polymerase (PEP), which needs additional sigma factors for promoter recognition. Interested in the expression of RpoT genes and NEP-transcribed plastid genes in response to light we analyzed transcript levels of RpoT and rpoB genes in 7-day-old wild-type plants under different light conditions by quantitative real-time-PCR. The observed changes in transcript accumulation indicated that red, blue, and green light differentially stimulated the expression of all three RpoT genes. Further analyses using different photoreceptor mutants showed that light induction of RpoT gene expression is surprisingly complex based on a network of multiple photoreceptors an d downstream pathways. Cytokinin signals are perceived by the histidine kinase (AHK) receptor family. There exist three different membrane-bound receptors: AHK2, AHK3 and AHK4/CRE1. These receptors are part of a two-component signaling system which transfers signals via phosphorelay mechanisms. Interested in the potential role of AHK2, AHK3 and AHK4/CRE1 in the transduction of cytokinin signals into the chloroplast, we analyzed the influence of cytokinin on plastidial transcription in receptor mutants. To gain more information on how plastid transcription by PEP is regulated by cytokinin, the influence of cytokinin in sigma factor mutants was also studied.

Cytokinin

Phagentyp-RNA-Polymerasen

Lichtinduktion

Photorezeptoren

Organelläre Gentranskription

light-induction

photoreceptors

phage-type RNA polymerases

organellar gene transcription

cytokinin

580 Pflanzen (Botanik)

32 Biologie

WG 1840

ddc:580

A GtPase Rac1 participa da proliferação de células gliais de Müller após lesão excitotóxica. / Rac1 GTPase participates in the proliferation of Müller glial cells after excitotoxic injury.

Silva, Loreni Cristine da

14 April 2011

As células glias de Müller são capazes de gerar novos neurônios retinianos em resposta a lesões, atuando como uma possível fonte para regeneração retiniana. Nesse contexto, as GTPases Rho podem ter um papel interessante, visto que regulam múltiplas vias de sinalização que controlam, por exemplo, a transcrição gênica, sobrevivência e proliferação celular. No presente estudo analisamos a participação de um dos membros dessa família (Rac1) na proliferação de células gliais de Müller da retina de galinhas após lesão excitotóxica com N-Metil-D-Aspartato (NMDA). A injeção intraocular de NMDA promoveu extensa proliferação de células gliais de Müller. A inibição de Rac1 com NSC23766 não alterou a quantidade de células que entraram no ciclo celular, mas, provocou um retardo em sua progressão. Esses resultados sugerem um importante papel para a GTPase Rac1 na regulação da proliferação de células gliais de Müller em resposta a lesões retinianas. / Müller glial cells may generate new neurons in response to retinal injury, acting as a potential source for retinal regeneration. In this context, Rho GTPases may have an interesting role, since they regulate multiple signaling pathways that control, for example, gene transcription, cell proliferation and survival. This study analyzed the involvement of a member of this family (Rac1) in the proliferation of Müller glial cells of chick retina after excitotoxic injury with N-methyl-D-aspartate (NMDA). Intraocular injection of NMDA promoted extensive Müller glia proliferation. Rac1 inhibition with NSC23766 did not affect the cell cycle entry, but a delay in cell cycle progression was observed. These results suggest an important role for Rac1 in the regulation of Müller glial cells proliferation in response to retinal injury.

Ativação enzimática

Cell proliferation

Enzyme activation

Fosfolipases

Gene transcription

Phospholipase

Proliferação celular

Regeneração (fenômenos biológicos)

Regeneration (the biological phenomena)

Retina

Retina

Transcrição gênica

Around the poor use of dietary carbohydrate phenotype in trout (Oncorhynchus mykiss) : its epigenetic consequences and metabolic modulation through a programming strategy / Phénotype de faible utilisation des glucides alimentaires chez la truite arc-en-ciel (Oncorhynchus mykiss) : ses conséquences épigénétiques et sa modulation métabolique via une stratégie de programmation

Liu, Jingwei

24 September 2019

La truite arc-en-ciel carnivore (Oncorhynchus mykiss) est considérée comme une espèce pauvre utilisatrice de glucides alimentaires. Des études récentes ont montré qu'une hypométhylation globale de l'ADN hépatique induite par un régime alimentaire riche en glucides et pauvre en protéines pourrait être impliquée dans l'établissement / le maintien du de ce phénotype chez la truite, mais le détail des mécanismes sous-jacents reste inconnu. La thèse vise à étudier les mécanismes épigénétiques sous-jacents à ce phénotype de faible utilisation des glucides alimentaire chez la truite et à examiner si le métabolisme du glucose et l’épigénome chez les juvéniles peuvent être programmés par un stimulus hypoxique précoce. Nous avons d’abord identifié tous les gènes paralogues liés aux voies de méthylation / déméthylation de l’ADN (dnmt, tet et tdg) dans le génome de la truite, clarifié leurs histoires évolutives et analysé leurs profils d’expression au cours de la gamétogenèse et de l’embryogenèse chez la truite. Nous avons ensuite étudiés plus en détail les processus et les mécanismes potentiellement à l’origine de l'hypométhylation de l'ADN hépatique global constatée chez la truite après un régime riche en glucides et pauvre en protéines. Les résultats ont montré pour la première fois qu'une diminution du taux deprotéines et une augmentation du taux de glucides dans l’aliment induisent de manière indépendante et en interaction une hypométhylation hépatique globale chez la truite, qui semble établie par le biais d'une voie de déméthylation active. Nous avons également constaté qu’une forte hyperglycémie induite par une injection de glucose induit une hypométhylation globale de l’ADN au niveau des sites CmCGG dans le foie de la truite. Les mécanismes détaillés de ces processus de déméthylation restent à élucider. Enfin, grâce à la stratégie de programmation métabolique, nous avons pour la première fois confirmé que l’utilisation d’un stimulus non nutritionnel au début de la vie, l’hypoxie, pouvait moduler de façon persistante la transcription des gènes liés au métabolisme du glucose chez la truite juvénile sans nuire aux performances de croissance. De plus, selon sa nature chronique ou aigue, l’hypoxie, a tendance à induire des effets de programmation opposés sur les gènes codants pour les transporteurs au glucose notamment dans le foie et le muscle de la truite juvénile. Dans son ensemble, la thèse met en avant notre compréhension du rôle du méthylome dans la contribution à la faible capacité d'utilisation des glucides alimentaires chez la truiteLa thèse met aussi en lumière le potentiel d'utilisation de l'hypoxie comme stimulus pour programmer le métabolisme du glucose, l'épigénome et l'utilisation des glucides alimentaires chez la truite arc-en-ciel. / The carnivorous rainbow trout (Oncorhynchus mykiss) is considered as a poor user of dietary carbohydrates. Recent studies showed that a high-carbohydrate/low protein diet inducing hepatic global DNA hypomethylation could be involved in the establishment/maintenance of the poor dietary carbohydrates utilisation phenotype in trout, but the detail mechanisms remain unclear. The present thesis aimed at investigating the epigenetic mechanisms underlying this poor dietary carbohydrate utilisation phenotype in trout, and exploring if the glucose metabolism and the epigenome in juveniles can be programmed through a hypoxic stimulus during early life. We first identified all the paralogous genes related to DNA methylation/demethylation pathways (dnmt, tet and tdg) in trout genome, clarified their molecular evolution histories and monitored their transcriptional expression patterns during gametogenesis and embryogenesis in trout. Besides, we investigate further the causes, processes and potential mechanisms about the hepatic global DNA hypomethylation in trout after feeding a high carbohydrate/low protein diet. Results for the first time demonstrated that a decrease in protein content and an increase in carbohydrate content in the diet can independently as well as interactively induce hepatic global hypomethylation in trout. This global loss of methylation is probably established through an active demethylation pathway. We also found that a strong hyperglycaemia induced by glucose injection induces global CmCGG hypomethylation in the liver of trout. The detailed mechanisms of these demethylation processes remain to be elucidated. Finally, through metabolic programming strategy, we confirmed for the first time that using a non-nutritional stimulus, hypoxia, during early life stage persistently modulates the transcription of glucose metabolism-related genes in juvenile trout without negative effects on growth performance. Moreover, acute and chronic hypoxia tended to induce opposite programming effects on glucose-transporter encoding genes in both liver and muscle of juvenile trout. Together, the present thesis brings forward our understandings about the roles of epigenetics in contributing to the low ability to use dietary carbohydrates in trout, and sheds light on the potential of using hypoxia as the stimulus in metabolic programming strategy to tailor the glucose metabolism, the epigenome and dietary carbohydrate utilisation in rainbow trout.

Métabolisme du glucose

Méthylation de l'ADN

Hypoxie

Gènes dupliqués

Embryogenèse

Gamétogenèse

Transcription génique

Glucose metabolism

DNA methylation

Hypoxia

Duplicated genes

Embryogenesis

Gametogenesis

Gene transcription

572.4

Elucidation Of Differential Role Of A Subunit Of RNA Polymerase II, Rpb4 In General And Stress Responsive Transcription In Saccharomyces Cerevisiae

Gaur, Jiyoti Verma

02 1900

RNA polymerase II (Pol II) is the enzyme responsible for the synthesis of all mRNAs in eukaryotic cells. As the central component of the eukaryotic transcription machinery, Pol II is the final target of regulatory pathways. While the role for different Pol II associated proteins, co-activators and general transcription factors (GTFs) in regulation of transcription in response to different stimuli is well studied, a similar role for some subunits of the core Pol II is only now being recognized. The studies reported in this thesis address the role of the fourth largest subunit of Pol II, Rpb4, in transcription and stress response using Saccharomyces cerevisiae as the model system. Rpb4 is closely associated with another smaller subunit, Rpb7 and forms a dissociable complex (Edwards et al., 1991). The rpb4 null mutant is viable but is unable to survive at extreme temperatures (>34ºC and <12ºC) (Woychik and Young, 1989). This mutant has also been shown to be defective in activated transcription and unable to respond properly in several stress conditions (Pillai et al., 2001; Sampath and Sadhale, 2005). In spite of wealth of available information, the exact role of Rpb4 remains poorly understood. In the present work, we have used genetic, molecular and biochemical approaches to understand the role of Rpb4 as described in four different parts below: i) Studies on Genetic and Functional Interactions of Rpb4 with SAGA/TFIID Complex to Confer Promoter- Specific Transcriptional Control To carry out transcription, Pol II has to depend on several general transcription factors, mediators, activators, and co-activators and chromatin remodeling complexes. In the present study, we tried to understand the genetic and functional relationship of Rpb4 with some of the components of transcription machinery, which will provide some insight into the role of Rpb4 during transcription. Our microarray analysis of rpb4∆ strain suggests that down regulated genes show significant overlap with genes regulated by the SAGA complex, a complex functionally related to TFIID and involved in regulation of the stress dependent genes. The analysis of combination of double deletion mutants of either the SAGA complex subunits or the TFIID complex with rpb4∆ showed that both these double mutants are extremely slow growing and show synthetic growth phenotype. Further studies, including microarray analysis of these double mutants and ChIP (chromatin immunoprecipitation) of Rpb4 and SAGA complex, suggested that Rpb4 functions together with SAGA complex to regulate the expression of stress dependent genes. ii) Study of Genome Wide Recruitment of Rpb4 and Evidence for its Role in Transcription Elongation Biochemical studies have shown that Rpb4 associates sub-stoichiometrically with the core RNA polymerase during log phase but whether recruitment of Rpb4 is promoter context dependent or occurs only at specific stage of transcription remains largely unknown. Having discovered that Rpb4 can recruit on both TFIID and SAGA dominated promoters, it was important to study the genome wide role of Rpb4. Using ChIP on chip experiments, we have carried out a systematic assessment of genome wide binding of Rpb4 as compared to the core Pol II subunit, Rpb3. Our analysis showed that Rpb4 is recruited on coding regions of most transcriptionally active genes similar to the core Pol II subunit Rpb3 albeit to a lesser extent. This extent of Rpb4 recruitment increased on the coding regions of long genes pointing towards a role of Rpb4 in transcription elongation of long genes. Further studies showing transcription defect of long and GC rich genes, 6-azauracil sensitivity and defective PUR5 gene expression in rpb4∆ mutant supported the in vivo evidence of the role of Rpb4 in transcription elongation. iii) Genome Wide Expression Profiling and RNA Polymerase II Recruitment in rpb4∆ Mutant in Non-Stress and Stress Conditions Structural studies have suggested a role of Rpb4/Rpb7 sub-complex in recruitment of different factors involved in transcription (Armache et al., 2003; Bushnell and Kornberg, 2003). Though only few studies have supported this aspect of Rpb4/Rpb7 sub-complex, more research needs to be directed to explore this role of Rpb4/Rpb7 sub-complex. To study if Rpb4 has any role in recruitment of Pol II under different growth conditions, we have studied genome wide recruitment of Pol II in the presence and absence of Rpb4 during growth in normal rich medium as well as under stress conditions like heat shock and stationary phase where Rpb4 is shown to be indispensable for survival. Our analysis showed that absence of Rpb4 results in overall reduced recruitment of Pol II in moderate condition but this reduction was more pronounced during heat shock condition. During stationary phase where overall recruitment of Pol II also goes down in wild type cells, absence of Rpb4 did not lead to further decrease in overall recruitment. Interestingly, increased expression levels of many genes in the absence of Rpb4 did not show concomitant increase in the recruitment of Pol II, suggesting that Rpb4 might regulate these genes at a post-transcriptional step. iv) Role of Rpb4 in Pseudohyphal Growth The budding yeast S. cerevisiae can initiate distinct developmental programs depending on the presence of various nutrients. In response to nitrogen starvation, diploid yeast undergoes a dimorphic transition to filamentous pseudohyphal growth, which is regulated through cAMP-PKA and MAP kinase pathways. Previous work from our group has shown that rpb4∆ strain shows predisposed pseudohyphal morphology (Pillai et al., 2003), but how Rpb4 regulates this differentiation program is yet to be established. In the present study, we found that disruption of Rpb4 leads to enhanced pseudohyphal growth, which is independent of nutritional status. We observed that the rpb4∆/ rpb4∆ cells exhibit pseudohyphae even in the absence of a functional MAP kinase and cAMP-PKA pathways. Genome wide expression profile showed that several downstream genes of RAM signaling pathway were down regulated in rpb4∆ cells. Our detailed genetic analysis further supported the hypothesis that down regulation of RAM pathway might be leading to the pseudohyphal morphogenesis in rpb4∆ cells.

RNA Polymerase II (Pol II)

RNA Transcription

Saccharomyces Cerevisiae

Eukaryotes - Transcription

RPB4 Gene - Transcription

Genes - Transcription

Rpb4

Rpb7

Transcription Elongation

Pseudohyphal Growth

Pseudohyphal Morphogenesis

Biochemical Genetics