Limitations of silencing at native yeast telomeres

Autor:	Edward J. Louis, Fiona E. Pryde
Rok vydání:	1999
Předmět:	Saccharomyces cerevisiae Proteins Molecular Sequence Data Origin Recognition Complex Saccharomyces cerevisiae Biology General Biochemistry Genetics and Molecular Biology Fungal Proteins Gene Expression Regulation Fungal Consensus Sequence Centromere Gene silencing Molecular Biology Psychological repression Derepression Repetitive Sequences Nucleic Acid Recombination Genetic Genetics Fungal protein Binding Sites Base Sequence Models Genetic General Immunology and Microbiology General Neuroscience SIR proteins Telomere Subtelomere Chromatin DNA-Binding Proteins Mutation Trans-Activators Protein Binding Transcription Factors Research Article
Zdroj:	The EMBO Journal. 18:2538-2550
ISSN:	1460-2075 0261-4189
DOI:	10.1093/emboj/18.9.2538
Popis:	Silencing at native yeast telomeres, in which the subtelomeric elements are intact, is different from silencing at terminal truncations. The repression of URA3 inserted in different subtelomeric positions at several chromosome ends was investigated. Many ends exhibit very little silencing close to the telomere, while others exhibit substantial repression in limited domains. Silencing at native ends is discontinuous, with maximal repression found adjacent to the ARS consensus sequence in the subtelomeric core X element. The level of repression declines precipitously towards the centromere. Mutation of the ARS sequence or an adjacent Abf1p‐binding site significantly reduces silencing. The subtelomeric Y′ elements are resistant to silencing along their whole length, yet silencing can be re‐established at the proximal X element. Deletion of PPR1 , the transactivator of URA3 , and SIR3 overexpression do not increase repression or extend spreading of silencing to the same extent as with terminally truncated ends. sir1Δ causes partial derepression at X‐ACS, in contrast to the lack of effect seen at terminal truncations. orc2‐1 and orc5‐1 have no effect on natural silencing yet cause derepression at truncated ends. X‐ACS silencing requires the proximity of the telomere and is dependent on SIR2 , SIR3 , SIR4 and HDF1 . The structures found at native yeast telomeres appear to limit the potential of repressive chromatin.
Databáze:	OpenAIRE
Externí odkaz:	https://explore.openaire.eu/search/publication?articleId=doi_dedup___::8d6386f9d0e7fcd1c5bac10b31b8c92e https://doi.org/10.1093/emboj/18.9.2538 Zobrazit plný text záznamu Plný text