Project description:Telomeric repeat-containing RNA (TERRA) has been implicated in the control of heterochromatin and telomerase. We demonstrate that yeast TERRA is regulated by telomere-binding proteins in a chromosome-end-specific manner that is dependent on subtelomeric repetitive DNA elements. At telomeres that contain only X-elements, the Rap1 carboxy-terminal domain recruits the Sir2/3/4 and Rif1/2 complexes to repress transcription in addition to promoting Rat1-nuclease-dependent TERRA degradation. At telomeres that contain Y' elements, however, Rap1 represses TERRA through recruitment of Rif1 and Rif2. Our work emphasizes the importance of subtelomeric DNA in the control of telomeric protein composition and telomere transcription.

Project description:Candida glabrata is a haploid opportunistic fungal pathogen that is phylogenetically related to Saccharomyces cerevisiae. Even though C. glabrata has no known sexual cycle, it contains, like S. cerevisiae, three mating type-like loci (MTL) called MTL1, MTL2, and MTL3, as well as most of the genes required for mating, meiosis, and sporulation. MTL1 is localized at an internal position on chromosome B and is thought to be the locus corresponding to the MAT locus in S. cerevisiae. MTL2 and MTL3 are localized close to two telomeres on different chromosomes (29.4 kb from Chr E-L and 10.5 kb from Chr B-L, respectively). By using URA3 reporter gene insertions at the three MTL loci, we found that in contrast to the case for S. cerevisiae, only MTL3 is subject to transcriptional silencing while MTL2 is transcriptionally active, and this is in agreement with previously reported data. We found that the silencing of MTL3 is nucleated primarily at the left telomere of chromosome B and spreads over 12 kb to MTL3, rather than nucleating at flanking, closely positioned cis-acting silencers, like those flanking HMR and HML of S. cerevisiae. Interestingly, the silencing of MTL3 absolutely requires the yKu70, yKu80, and Rif1 proteins, in sharp contrast to the silencing of the HM loci of S. cerevisiae. In addition, we found that several cell type-specific genes are expressed in C. glabrata regardless of the presence, or even absence, of mating type information at any of the MTL loci.

Project description:Accurate DNA replication and segregation is key to reproduction and cell viability in all organisms. Autonomously replicating sequence-binding factor 1 (Abf1) is a multifunctional protein that has essential roles in replication, transcription, and regional silencing in the model yeast Saccharomyces cerevisiae. In the opportunistic pathogenic fungus Candida glabrata, which is closely related to S. cerevisiae, these processes are important for survival within the host, for example, the regulation of transcription of virulence-related genes like those involved in adherence. Here, we describe that CgABF1 is an essential gene required for cell viability and silencing near the telomeres, where many adhesin-encoding genes reside. CgAbf1 mediated subtelomeric silencing depends on the 43 C-terminal amino acids. We also found that abnormal expression, depletion, or overexpression of Abf1, results in defects in nuclear morphology, nuclear segregation, and transit through the cell cycle. In the absence of ABF1, cells are arrested in G2 but start cycling again after 9 h, coinciding with the loss of cell viability and the appearance of cells with higher DNA content. Overexpression of CgABF1 causes defects in nuclear segregation and cell cycle progression. We suggest that these effects could be due to the deregulation of DNA replication.

Project description:Cohesin is a key determinant of chromosome architecture due to its DNA binding and tethering ability. Cohesin binds near centromeres and chromosome arms and also close to telomeres, but its role near telomeres remains elusive. In budding yeast, transcription within 20 kb of telomeres is repressed, in part by the histone-modifying silent information regulator (SIR) complex. However, extensive subtelomeric repressed domains lie outside the SIR-binding region, but the mechanism of silencing in these regions remains poorly understood. Here, we report a role for cohesin in subtelomeric silencing that extends even beyond the zone of SIR binding. Clusters of subtelomeric genes were preferentially derepressed in a cohesin mutant, whereas SIR binding was unaltered. Genetic interactions with known telomere silencing factors indicate that cohesin operates independent of the SIR-mediated pathway for telomeric silencing. Mutant cells exhibited Mpk1-dependent Sir3 hyperphosphorylation that contributes to subtelomeric derepression to a limited extent. Compaction of subtelomeric domains and tethering to the nuclear envelope were impaired in mutant cells. Our findings provide evidence for a unique SIR-independent mechanism of subtelomeric repression mediated by cohesin.

Project description:Adherence to host cells is an important step in the pathogenicity of the opportunistic fungal pathogen Candida glabrata. This adherence is mediated by some members of the large family of cell wall proteins encoded by the EPA (Epithelial Adhesin) genes present in the C. glabrata genome. The majority of the EPA genes are localized close to different telomeres in C. glabrata, resulting in a negative regulation of transcription of these genes through chromatin-based subtelomeric silencing. In vitro, adherence to epithelial cells is mainly mediated by Epa1, the only member of the EPA family that is expressed in vitro. EPA1 forms a cluster with EPA2 and EPA3 at the subtelomeric region of telomere E(-R). EPA2 and EPA3 are subject to silencing that propagates from this telomere in a process that depends on the Sir2, -3, -4, and Rif1 proteins, but surprisingly not on the yKu70 and yKu80 proteins. Here we describe that the yKu70/yKu80-independent silencing of telomere E(-R) is due to the presence of a cis-acting protosilencer (Sil2126) located between EPA3 and the telomere. This element can silence a reporter gene when placed 31.9 kb away from this telomere, but not when it is removed from the telomere context, or when it is placed near other telomeres, or inverted with respect to the reporter. Importantly, we show that the cis-acting Sil2126 element is required for the yKu70/80-independent silencing of this telomere, underscoring the importance of cis-elements for repressive chromatin formation and spreading on some telomeres in C. glabrata.

Project description:Adherence, an important virulence factor, is mediated by the EPA (Epithelial Adhesin) genes in the opportunistic pathogen Candida glabrata Expression of adhesin-encoding genes requires tight regulation to respond to harsh environmental conditions within the host. The majority of EPA genes are localized in subtelomeric regions regulated by subtelomeric silencing, which depends mainly on Rap1 and the Sir proteins. In vitro adhesion to epithelial cells is primarily mediated by Epa1. EPA1 forms a cluster with EPA2 and EPA3 in the right telomere of chromosome E (E-R). This telomere contains a cis-acting regulatory element, the protosilencer Sil2126 between EPA3 and the telomere. Interestingly, Sil2126 is only active in the context of its native telomere. Replacement of the intergenic regions between EPA genes in E-R revealed that cis-acting elements between EPA2 and EPA3 are required for Sil2126 activity when placed 32 kb away from the telomere (Sil@-32kb). Sil2126 contains several putative binding sites for Rap1 and Abf1, and its activity depends on these proteins. Indeed, Sil2126 binds Rap1 and Abf1 at its native position and also when inserted at -32 kb, a silencing-free environment in the parental strain. In addition, we found that Sil@-32kb and Sil2126 at its native position can physically interact with the intergenic regions between EPA1-EPA2 and EPA2-EPA3 respectively, by chromosome conformation capture assays. We speculate that Rap1 and Abf1 bound to Sil2126 can recruit the Silent Information Regulator complex, and together mediate silencing in this region, probably through the formation of a chromatin loop.

Project description:Trypanosoma brucei causes human African trypanosomiasis and regularly switches its major surface antigen variant surface glycoprotein (VSG) to evade mammalian host immune responses at the bloodstream form (BF) stage. Monoallelic expression of BF Expression Site (BES)-linked VSGs and silencing of metacyclic VSGs (mVSGs) in BF cells are essential for antigenic variation, whereas silencing of both BES-linked and mVSGs in the procyclic form (PF) cells is important for cell survival in the midgut of its insect vector. We have previously shown that silencing BES-linked VSGs in BF cells depends on TbRAP1. We now show that TbRAP1 silences both BES-linked and mVSGs at both BF and PF stages. The strength of TbRAP1-mediated BES-linked VSG silencing is stronger in the PF cells than that in BF cells. In addition, Formaldehyde-Assisted Isolation of Regulatory Elements analysis and MNase digestion demonstrated that depletion of TbRAP1 in PF cells led to a chromatin structure change, which is significantly stronger at the subtelomeric VSG loci than at chromosome internal loci. On the contrary, no significant chromatin structure changes were detected on depletion of TbRAP1 in BF cells. Our observations indicate that TbRAP1 helps to determine the chromatin structure at the insect stage, which likely contributes to its strong silencing effect on VSGs.

Project description:Candida glabrata, a common opportunistic fungal pathogen, adheres efficiently to mammalian epithelial cells in culture. This interaction in vitro depends mainly on the adhesin Epa1, one of a large family of cell wall proteins. Most of the EPA genes are located in subtelomeric regions, where they are transcriptionally repressed by silencing. In order to better characterize the transcriptional regulation of the EPA family, we have assessed the importance of C. glabrata orthologues of known regulators of subtelomeric silencing in Saccharomyces cerevisiae. To this end, we used a series of strains containing insertions of the reporter URA3 gene within different intergenic regions throughout four telomeres of C. glabrata. Using these reporter strains, we have assessed the roles of SIR2, SIR3, SIR4, HDF1 (yKu70), HDF2 (yKu80), and RIF1 in mediating silencing at four C. glabrata telomeres. We found that, whereas the SIR proteins are absolutely required for silencing of the reporter genes and the native subtelomeric EPA genes, the Rif1 and the Ku proteins regulate silencing at only a subset of the analyzed telomeres. We also mapped a cis element adjacent to the EPA3 locus that can silence a reporter gene when placed at a distance of 31 kb from the telomere. Our data show that silencing of the C. glabrata telomeres varies from telomere to telomere. In addition, recruitment of silencing proteins to the subtelomeres is likely, for certain telomeres, to depend both on the telomeric repeats and on particular discrete silencing elements.

Project description:Repressor-activator protein 1 (scRap1) is the major binding activity at Saccharomyces cerevisiae telomeres, with roles in telomere length regulation and establishment of subtelomeric silencing by recruiting the Sir proteins. scRap1 also acts as a transcription factor controlling the expression of ribosomal proteins and glycolytic enzymes. A homolog of scRap1 exist in mammals, Rap1 (also known as Terf2ip), however, its roles in telomere biology and transcriptional regulation are largely unknown. We have employed microarrays to obtain gene expression signatures related to Rap1-deleted mice when compared to the wild-type.

Project description:Repressor-activator protein 1 (scRap1) is the major binding activity at Saccharomyces cerevisiae telomeres, with roles in telomere length regulation and establishment of subtelomeric silencing by recruiting the Sir proteins. scRap1 also acts as a transcription factor controlling the expression of ribosomal proteins and glycolytic enzymes. A homolog of scRap1 exist in mammals, Rap1 (also known as Terf2ip), however, its roles in telomere biology and transcriptional regulation are largely unknown. We have employed microarrays to obtain gene expression signatures related to Rap1-deleted mice when compared to the wild-type. Construction of the Rap1 targeting vector: The strategy for disrupting the Rap1 locus was designed to conditionallty delete exon 3 (E3) through a Cre-mediated excision. Deletion of E3 leads to the removal of coding sequences encoding for the RCT domain and the NLS sequence, as well as the whole 3’UTR region and poly-adenylation signal (Fig.1A,B). Deletion of E3 was expected to destabilize the Rap1 transcript and thereby to prevent translation of any truncated RAP1 protein. The targeting vector contains homology regions isogenic with the ES cell line used (129Sv/Pas). The short homology region (SA) harbors a 2.4 kb DNA fragment encompassing exon 2 (E2) and intron 2 (Fig. 1A). The long homology region (LA) is a 5.6 kb DNA fragment downstream the end of E3 (Fig. 1A). The central part contains E3 flanked by two loxP sites and a positive selection neomycin gene (PGK-Neo) flanked by two Frt sites (Fig. 1A). At the 3’-end of the LA a Diphteria Toxin (DTA) selection marker was cloned (Fig. 1A). The vector contains a unique NruI linearization site. The targeting vector was quality controlled by sequencing of the coding exons, the junctions between the homology arms and the selection cassettes, the selection cassettes and the junctions between the homology arms and the plasmid backbone. The analysis of the sequencing results showed no polymorphis between the C57BL/6 and 129Sv/Pas genetic background within the isolated Rap1 sequences. The sequence of the primers used for the PCR amplification of the different targeting vector parts and the details of the cloning steps are available upon request. The construction of the targeting vector was performed by genOway (www.genoway.com; Lyon, France). Generation of conditional Rap1 knockout mice 129Sv/Pas ES cells were transfected with 40 µg of linearized plasmid. Positive selection was started 48 hours after electroporation by addition of 200 µg/ML G418. Approximately 230 positive resistant clones were isolated and amplified. They were PCR screened for homologous recombination first at the 5’ end of the Rap1 locus. The 6 positive identified 5’ targeted ES cells were further investigated by PCR amplification over the 3’ long homology arm to amplify the region of the targeted locus containing the distal loxP site. The direct sequencing of the PCR products amplified from the 6 ES clones revealed that 3 of them contained the distal loxP site. The recombinant clones identified by PCR were further verified by Southern blot analysis of AflII and PciI restricted genomic DNA using a 5’-internal and a 3’-external probes, respectively (data not shown). The Southern blots confirmed the correct homologous integration over the 5’ and the 3’ homology arm and the absence of any additional randomly integrated copies of the targeting vector. Chimeric mice were generated by microinjection of three independently targeted ES clones into C57BL/6J host blastocyst. The resulting offspring showed a high level of chimerism as shown by coat color, and were mated to C57BL/6J mice to assess germ line transmission. The resulting heterozygous Rap1+/flox-Neo mice were then bred to transgenic mice expressing the Flpe recombinase (Rodriguez et al., 2000) to induce excision of the Neo marker. The Rap1+/flox heterozygous mice were then intercrossed to generate Rap1flox/flox, and Rap1+/flox mice. Homozygous Rap1flox/flox mice were crossed with transgenic mice expressing the Cre recombinase under the control of the keratine 5 promoter (Tarutani et al., 1997) (Fig. 5A). Heterozygous Rap1+/D K5-Cre were crossed either to Rap1flox/flox or Rap1+/flox to generate Rap1Δ/Δ K5-Cre. The removal of exon 3 by Cre-mediated recombination was confirmed by PCR analysis using primers F and R (Fig. 1A,C and Fig. 5A). Amplification of the wild type, flox and knockout alleles renders a 3.2 kb, 3.3 kb and 0.5 kb fragments, respectively. The breeding to the F1 generation and characterization of heterozygous Rap1+/flox-Neo F1 animals was performed by geneOway (www.genoway.com; Lyon, France). All mice were generated and maintained at the Spanish National Cancer Centre (CNIO) under specific pathogen-free conditions in accordance with the recommendation of the Federation of European Laboratory Animal Science Associations.