Heritable capture of heterochromatin dynamics in Saccharomyces cerevisiae
Heterochromatin exerts a heritable form of eukaryotic gene repression and contributes to chromosome segregation fidelity and genome stability. However, to date there has been no quantitative evaluation of the stability of heterochromatic gene repression. We designed a genetic strategy to capture tra...
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| Published in | eLife Vol. 4; p. e05007 |
|---|---|
| Main Authors | , |
| Format | Journal Article |
| Language | English |
| Published |
England
eLife Sciences Publications Ltd
12.01.2015
eLife Sciences Publications, Ltd |
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| Online Access | Get full text |
| ISSN | 2050-084X 2050-084X |
| DOI | 10.7554/eLife.05007 |
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| Abstract | Heterochromatin exerts a heritable form of eukaryotic gene repression and contributes to chromosome segregation fidelity and genome stability. However, to date there has been no quantitative evaluation of the stability of heterochromatic gene repression. We designed a genetic strategy to capture transient losses of gene silencing in Saccharomyces as permanent, heritable changes in genotype and phenotype. This approach revealed rare transcription within heterochromatin that occurred in approximately 1/1000 cell divisions. In concordance with multiple lines of evidence suggesting these events were rare and transient, single-molecule RNA FISH showed that transcription was limited. The ability to monitor fluctuations in heterochromatic repression uncovered previously unappreciated roles for Sir1, a silencing establishment factor, in the maintenance and/or inheritance of silencing. In addition, we identified the sirtuin Hst3 and its histone target as contributors to the stability of the silenced state. These approaches revealed dynamics of a heterochromatin function that have been heretofore inaccessible.
A single cell from a plant, an animal or another eukaryote can contain several meters of DNA. In order to fit this length inside the nucleus of the cell, the DNA is wrapped around proteins called histones to form a compact structure known as chromatin.
Chromatin exists in two forms: loosely packed chromatin tends to contain the genes that are expressed in cells, whereas highly compacted chromatin (also called heterochromatin) silences the expression of most nearby genes. Adding small chemical markings to histone proteins can alter how much the chromatin is compacted, and newly formed cells can inherit these markings whenever a cell divides. This enables the new cell to essentially ‘remember’ which genes were active and which were repressed in the original cell. However, no one has measured how stable heterochromatin is over multiple cell divisions; as such it is unclear if genes that should remain silent are occasionally expressed after a cell has divided a number of times.
Budding yeast is a well-established model for studying heterochromatin. The genome of this single-celled organism has distinct regions of highly compacted chromatin, which are established and maintained by a number of different proteins.
Dodson and Rine have developed a new technique to detect when gene silencing is lost in individual yeast cells, even if the loss of silencing only occurs for a brief period. This approach revealed that genes in supposedly ‘silent’ heterochromatin were still expressed but only very rarely—in about 1 in every 1000 cell divisions.
Dodson and Rine's findings suggest that when silencing is lost, it is promptly re-established with the aid of a protein called Sir1. In addition, the new technique revealed that Sir1 helps to prevent losses of silencing in the first place. As such, the Sir1 protein appears to have previously unappreciated roles in the maintenance and the inheritance of heterochromatin in dividing yeast cells. Dodson and Rine also discovered that a protein called Hst3—which acts to remove chemical markings from histone proteins—also helps stabilize the silenced state. With this technique in hand, it is now possible to test any molecule, environment, or cellular process for its potential effect on the stability of gene silencing. |
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| AbstractList | Heterochromatin exerts a heritable form of eukaryotic gene repression and contributes to chromosome segregation fidelity and genome stability. However, to date there has been no quantitative evaluation of the stability of heterochromatic gene repression. We designed a genetic strategy to capture transient losses of gene silencing in Saccharomyces as permanent, heritable changes in genotype and phenotype. This approach revealed rare transcription within heterochromatin that occurred in approximately 1/1000 cell divisions. In concordance with multiple lines of evidence suggesting these events were rare and transient, single-molecule RNA FISH showed that transcription was limited. The ability to monitor fluctuations in heterochromatic repression uncovered previously unappreciated roles for Sir1, a silencing establishment factor, in the maintenance and/or inheritance of silencing. In addition, we identified the sirtuin Hst3 and its histone target as contributors to the stability of the silenced state. These approaches revealed dynamics of a heterochromatin function that have been heretofore inaccessible.Heterochromatin exerts a heritable form of eukaryotic gene repression and contributes to chromosome segregation fidelity and genome stability. However, to date there has been no quantitative evaluation of the stability of heterochromatic gene repression. We designed a genetic strategy to capture transient losses of gene silencing in Saccharomyces as permanent, heritable changes in genotype and phenotype. This approach revealed rare transcription within heterochromatin that occurred in approximately 1/1000 cell divisions. In concordance with multiple lines of evidence suggesting these events were rare and transient, single-molecule RNA FISH showed that transcription was limited. The ability to monitor fluctuations in heterochromatic repression uncovered previously unappreciated roles for Sir1, a silencing establishment factor, in the maintenance and/or inheritance of silencing. In addition, we identified the sirtuin Hst3 and its histone target as contributors to the stability of the silenced state. These approaches revealed dynamics of a heterochromatin function that have been heretofore inaccessible. Heterochromatin exerts a heritable form of eukaryotic gene repression and contributes to chromosome segregation fidelity and genome stability. However, to date there has been no quantitative evaluation of the stability of heterochromatic gene repression. We designed a genetic strategy to capture transient losses of gene silencing in Saccharomyces as permanent, heritable changes in genotype and phenotype. This approach revealed rare transcription within heterochromatin that occurred in approximately 1/1000 cell divisions. In concordance with multiple lines of evidence suggesting these events were rare and transient, single-molecule RNA FISH showed that transcription was limited. The ability to monitor fluctuations in heterochromatic repression uncovered previously unappreciated roles for Sir1, a silencing establishment factor, in the maintenance and/or inheritance of silencing. In addition, we identified the sirtuin Hst3 and its histone target as contributors to the stability of the silenced state. These approaches revealed dynamics of a heterochromatin function that have been heretofore inaccessible.DOI: http://dx.doi.org/10.7554/eLife.05007.001 Heterochromatin exerts a heritable form of eukaryotic gene repression and contributes to chromosome segregation fidelity and genome stability. However, to date there has been no quantitative evaluation of the stability of heterochromatic gene repression. We designed a genetic strategy to capture transient losses of gene silencing in Saccharomyces as permanent, heritable changes in genotype and phenotype. This approach revealed rare transcription within heterochromatin that occurred in approximately 1/1000 cell divisions. In concordance with multiple lines of evidence suggesting these events were rare and transient, single-molecule RNA FISH showed that transcription was limited. The ability to monitor fluctuations in heterochromatic repression uncovered previously unappreciated roles for Sir1, a silencing establishment factor, in the maintenance and/or inheritance of silencing. In addition, we identified the sirtuin Hst3 and its histone target as contributors to the stability of the silenced state. These approaches revealed dynamics of a heterochromatin function that have been heretofore inaccessible. DOI: http://dx.doi.org/10.7554/eLife.05007.001 A single cell from a plant, an animal or another eukaryote can contain several meters of DNA. In order to fit this length inside the nucleus of the cell, the DNA is wrapped around proteins called histones to form a compact structure known as chromatin. Chromatin exists in two forms: loosely packed chromatin tends to contain the genes that are expressed in cells, whereas highly compacted chromatin (also called heterochromatin) silences the expression of most nearby genes. Adding small chemical markings to histone proteins can alter how much the chromatin is compacted, and newly formed cells can inherit these markings whenever a cell divides. This enables the new cell to essentially ‘remember’ which genes were active and which were repressed in the original cell. However, no one has measured how stable heterochromatin is over multiple cell divisions; as such it is unclear if genes that should remain silent are occasionally expressed after a cell has divided a number of times. Budding yeast is a well-established model for studying heterochromatin. The genome of this single-celled organism has distinct regions of highly compacted chromatin, which are established and maintained by a number of different proteins. Dodson and Rine have developed a new technique to detect when gene silencing is lost in individual yeast cells, even if the loss of silencing only occurs for a brief period. This approach revealed that genes in supposedly ‘silent’ heterochromatin were still expressed but only very rarely—in about 1 in every 1000 cell divisions. Dodson and Rine's findings suggest that when silencing is lost, it is promptly re-established with the aid of a protein called Sir1. In addition, the new technique revealed that Sir1 helps to prevent losses of silencing in the first place. As such, the Sir1 protein appears to have previously unappreciated roles in the maintenance and the inheritance of heterochromatin in dividing yeast cells. Dodson and Rine also discovered that a protein called Hst3—which acts to remove chemical markings from histone proteins—also helps stabilize the silenced state. With this technique in hand, it is now possible to test any molecule, environment, or cellular process for its potential effect on the stability of gene silencing. DOI: http://dx.doi.org/10.7554/eLife.05007.002 Heterochromatin exerts a heritable form of eukaryotic gene repression and contributes to chromosome segregation fidelity and genome stability. However, to date there has been no quantitative evaluation of the stability of heterochromatic gene repression. We designed a genetic strategy to capture transient losses of gene silencing in Saccharomyces as permanent, heritable changes in genotype and phenotype. This approach revealed rare transcription within heterochromatin that occurred in approximately 1/1000 cell divisions. In concordance with multiple lines of evidence suggesting these events were rare and transient, single-molecule RNA FISH showed that transcription was limited. The ability to monitor fluctuations in heterochromatic repression uncovered previously unappreciated roles for Sir1, a silencing establishment factor, in the maintenance and/or inheritance of silencing. In addition, we identified the sirtuin Hst3 and its histone target as contributors to the stability of the silenced state. These approaches revealed dynamics of a heterochromatin function that have been heretofore inaccessible. Heterochromatin exerts a heritable form of eukaryotic gene repression and contributes to chromosome segregation fidelity and genome stability. However, to date there has been no quantitative evaluation of the stability of heterochromatic gene repression. We designed a genetic strategy to capture transient losses of gene silencing in Saccharomyces as permanent, heritable changes in genotype and phenotype. This approach revealed rare transcription within heterochromatin that occurred in approximately 1/1000 cell divisions. In concordance with multiple lines of evidence suggesting these events were rare and transient, single-molecule RNA FISH showed that transcription was limited. The ability to monitor fluctuations in heterochromatic repression uncovered previously unappreciated roles for Sir1, a silencing establishment factor, in the maintenance and/or inheritance of silencing. In addition, we identified the sirtuin Hst3 and its histone target as contributors to the stability of the silenced state. These approaches revealed dynamics of a heterochromatin function that have been heretofore inaccessible. A single cell from a plant, an animal or another eukaryote can contain several meters of DNA. In order to fit this length inside the nucleus of the cell, the DNA is wrapped around proteins called histones to form a compact structure known as chromatin. Chromatin exists in two forms: loosely packed chromatin tends to contain the genes that are expressed in cells, whereas highly compacted chromatin (also called heterochromatin) silences the expression of most nearby genes. Adding small chemical markings to histone proteins can alter how much the chromatin is compacted, and newly formed cells can inherit these markings whenever a cell divides. This enables the new cell to essentially ‘remember’ which genes were active and which were repressed in the original cell. However, no one has measured how stable heterochromatin is over multiple cell divisions; as such it is unclear if genes that should remain silent are occasionally expressed after a cell has divided a number of times. Budding yeast is a well-established model for studying heterochromatin. The genome of this single-celled organism has distinct regions of highly compacted chromatin, which are established and maintained by a number of different proteins. Dodson and Rine have developed a new technique to detect when gene silencing is lost in individual yeast cells, even if the loss of silencing only occurs for a brief period. This approach revealed that genes in supposedly ‘silent’ heterochromatin were still expressed but only very rarely—in about 1 in every 1000 cell divisions. Dodson and Rine's findings suggest that when silencing is lost, it is promptly re-established with the aid of a protein called Sir1. In addition, the new technique revealed that Sir1 helps to prevent losses of silencing in the first place. As such, the Sir1 protein appears to have previously unappreciated roles in the maintenance and the inheritance of heterochromatin in dividing yeast cells. Dodson and Rine also discovered that a protein called Hst3—which acts to remove chemical markings from histone proteins—also helps stabilize the silenced state. With this technique in hand, it is now possible to test any molecule, environment, or cellular process for its potential effect on the stability of gene silencing. |
| Author | Rine, Jasper Dodson, Anne E |
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| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/25581000$$D View this record in MEDLINE/PubMed |
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| Copyright | 2015, Dodson and Rine. This work is licensed under the Creative Commons Attribution License ( https://creativecommons.org/licenses/by/3.0/ ) (the “License”). Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License. 2015, Dodson and Rine 2015 Dodson and Rine |
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| SubjectTerms | bistability Cell cycle Cell division Deoxyribonucleic acid Diploidy DNA Enzymes epigenetic Epigenetics Gene Deletion Gene expression Gene Silencing Genes and Chromosomes Genes, Mating Type, Fungal Genomes Green Fluorescent Proteins - metabolism Hemizygote Heredity Heterochromatin Heterochromatin - metabolism histone H3 Histones - metabolism Imaging, Three-Dimensional In Situ Hybridization, Fluorescence Inheritance Patterns - genetics Integrases - metabolism Luminescent Proteins - metabolism Proteins Red Fluorescent Protein Ribonucleic acid RNA RNA polymerase Saccharomyces cerevisiae Saccharomyces cerevisiae - cytology Saccharomyces cerevisiae - genetics Saccharomyces cerevisiae - metabolism Saccharomyces cerevisiae Proteins - genetics Saccharomyces cerevisiae Proteins - metabolism Sir2 Sir3 Sir4 Sirtuins - genetics Transcription Transcription, Genetic Yeast |
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| Title | Heritable capture of heterochromatin dynamics in Saccharomyces cerevisiae |
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