Your search keyword '"y ' elements"' showing total 2 results

1. Telomere-based neo-Darwinian selection of yeast clonal subpopulations

Author

Sabrina Venditti, E Di Mauro, and G. Di Stefano

Subjects

experimental neo-darwinism, heterochromatin proteins, Heterochromatin, Population, Genes, Fungal, Saccharomyces cerevisiae, Biology, medicine.disease_cause, Histone H4, clonal selection, Genetic imbalance, Genetics, medicine, Selection, Genetic, education, Molecular Biology, Gene, education.field_of_study, Mutation, Models, Genetic, Telomere, Phenotype, y' elements, telomere sequence organization, y ' elements

Abstract

In Saccharomyces cerevisiae, imbalance of the genes coding for the heterochromatin components Sir3p and histone H4 (namely, overdosage of SIR3 and lack of one of the two genes coding for H4) causes modifications in telomere length and telomere sequence organization, favoring the insertion of Y' elements into a stably shortened (C1-3A)n repeat tract. We report here that the newly inserted Y' elements are unstable and are lost with high frequency, generating clonal subpopulations with short telomeres, as revealed by the analysis of a specific telomere (LIII) and of the overall population of telomeres. Moreover, the growth rates of the subpopulations with and without Y' elements on LIII are different, the Y'-less individuals reproducing 20% more slowly than individuals bearing Y' elements. When grown together with Y'-bearing individuals, the subpopulations with the normal LIII telomere (which are viable and genetically stable if grown alone) are rapidly competed out. Hence, genetic imbalance for the structural components of heterochromatin results in a complex and rapidly changing mixture of subpopulations in such cultures. Thus, in situations where subpopulations are allowed to compete, heterochromatin-based differential growth rates result in neo-Darwinian clonal selection.

Published

2000

2. Imbalance in dosage of the genes for the heterochromatin components Sir3p and histone H4 results in changes in the length and sequence organization of yeast telomeres

Author

Miguel A. Vega-Palas, G. Di Stefano, E Di Mauro, and Sabrina Venditti

Subjects

Heterochromatin, Gene Dosage, Telomeric heterochromatin, Saccharomyces cerevisiae, Biology, Telomere organization, Histone H4, Fungal Proteins, Histones, Gene Expression Regulation, Fungal, Genetics, telomere length, Molecular Biology, heterochromatin, histone gene imbalance, telomere sequence organization, y ' elements, y' elements, Silent Information Regulator Proteins, Saccharomyces cerevisiae, Telomere-binding protein, Telomere, Subtelomere, Phenotype, Trans-Activators, Heterochromatin protein 1, Chromosomes, Fungal

Abstract

Telomeric heterochromatin plays an essential role in telomere function, including the regulation of telomere length. We observe that in Saccharomyces cerevisiae an imbalance in the dosage of genes for two protein components of heterochromatin (namely Sir3p and histone H4) causes modifications in telomere length and telomere sequence organization. The effects of Sir3p/H4 imbalance were analyzed in yeast strains in which the wild-type SIR3 gene (normally a single-copy gene) was either absent or present in 20-30 copies, and both histone H4 genes (HHF1 and HHF2) were present or HHF1 was deleted, thus covering a wide range of viable gene-dosage combinations. Modifications of telomeres and of subtelomeric regions were identified by analyzing both the overall telomere population and by focusing on two single telomeric regions: the left telomere of chromosome III (LIII) and the right telomere of chromosome XI (RXI). The modifications induced by alteration of the Sir3p/H4 ratio consist of a reduction in the length and an increase in the instability of the terminal block of (C(1-3)A)n repeats and in susceptibility to insertion of Y' elements into this repeat element. Restoration of the wild-type gene ratio (by removal of the extra copies of SIR3 or by complementation with the missing second copy of HHF) restored the original telomere organization, both with respect to the length of the (C(1-3)A)n repeat stretch and the absence of Y' elements. This behavior shows that the stability of the wild-type sequence organization requires maintenance of the normal structure of telomeric heterochromatin.

Published

1999