Identification of a small molecule inhibitor of Sir2p.

Sir2p is an NAD(+)-dependent histone deacetylase required for chromatin-dependent silencing in yeast. In a cell-based screen for inhibitors of Sir2p, we identified a compound, splitomicin, that creates a conditional phenocopy of a sir2 deletion mutant in Saccharomyces cerevisiae. Cells grown in the presence of the drug have silencing defects at telomeres, silent mating-type loci, and the ribosomal DNA. In addition, whole genome microarray experiments show that splitomicin selectively inhibits Sir2p. In vitro, splitomicin inhibits NAD(+)-dependent histone deacetylase activity (HDA) of the Sir2 protein. Mutations in SIR2 that confer resistance to the drug map to the likely acetylated histone tail binding domain of the protein. By using splitomicin as a chemical genetic probe, we demonstrate that continuous HDA of Sir2p is required for maintaining a silenced state in nondividing cells.

Exonuclease activity is required for sequence addition and Cdc13p loading at a de novo telomere.

The Saccharomyces cerevisiae Mre11p/Rad50p/Xrs2p (MRX) complex is evolutionarily conserved and functions in DNA repair and at telomeres [1-3]. In vivo, MRX is required for a 5' --> 3' exonuclease activity that mediates DNA recombination at double-strand breaks (DSBs). Paradoxically, abolition of this exonuclease activity in MRX mutants results in shortened telomeric DNA tracts. To further explore the role of MRX at telomeres, we analyzed MRX mutants in a de novo telomere addition assay in yeast cells [4]. We found that the MRX genes were absolutely required for telomerase-mediated addition in this assay. Furthermore, we found that Cdc13p, a single-stranded telomeric DNA binding protein essential for telomere DNA synthesis and protection [5], was unable to bind to the de novo telomeric DNA substrate in cells lacking Rad50p. Based on the results from this model system, we propose that the MRX complex helps to prepare telomeric DNA for the loading of Cdc13p, which then protects the chromosome from further degradation and recruits telomerase and other DNA replication components to synthesize telomeric DNA.

The function of a stem-loop in telomerase RNA is linked to the DNA repair protein Ku.

The telomerase enzyme lengthens telomeres, an activity essential for chromosome stability in most eukaryotes. The enzyme is composed of a specialized reverse transcriptase and a template RNA. In Saccharomyces cerevisiae, overexpression of TLC1, the telomerase RNA gene, disrupts telomeric structure. The result is both shortened telomere length and loss of a special chromatin structure that normally silences telomere-proximal genes. Because telomerase function is not required for telomeric silencing, we postulated that the dominant-negative effect caused by overexpression of TLC1 RNA originates in a normal interaction between the RNA and an unknown telomeric factor important for silencing; the overexpressed RNA presumably continues to bind the factor and compromises its function. Here we show that a 48-nt stem-loop structure within the 1.3-kb TLC1 RNA is necessary and sufficient for disrupting telomeric silencing and shortening telomeres. Moreover, this short RNA sequence appears to function through an interaction with the conserved DNA end-binding protein Ku. We propose that, in addition to its roles in telomeric silencing, homologous recombination and non-homologous end-joining (NHEJ), S. cerevisiae Ku also helps to recruit or activate telomerase at the telomere through an interaction with this stem-loop of TLC1 RNA.

Gene silencing: two faces of SIR2.

There are still many mysteries surrounding how silenced regions of the eukaryotic genome are created and maintained. But recent discoveries about the most evolutionarily conserved silencing protein, Sir2p, have provided new mechanistic insights into these processes.

Type B histone acetyltransferase Hat1p participates in telomeric silencing.

Hat1p and Hat2p are the two subunits of a type B histone acetyltransferase from Saccharomyces cerevisiae that acetylates free histone H4 on lysine 12 in vitro. However, the role for these gene products in chromatin function has been unclear, as deletions of the HAT1 and/or HAT2 gene displayed no obvious phenotype. We have now identified a role for Hat1p and Hat2p in telomeric silencing. Telomeric silencing is the transcriptional repression of telomere-proximal genes and is mediated by a special chromatin structure. While there was no change in the level of silencing on a telomeric gene when the HAT1 or HAT2 gene was deleted, a significant silencing defect was observed when hat1Delta or hat2Delta was combined with mutations of the histone H3 NH(2)-terminal tail. Specifically, when at least two lysine residues were changed to arginine in the histone H3 tail, a hat1Delta-dependent telomeric silencing defect was observed. The most dramatic effects were seen when one of the two changes was in lysine 14. In further analysis, we found that a single lysine out of the five in the histone H3 tail was sufficient to mediate silencing. However, K14 was the best at preserving silencing, followed by K23 and then K27; K9 and K18 alone were insufficient. Mutational analysis of the histone H4 tail indicated that the role of Hat1p in telomeric silencing was mediated solely through lysine 12. Thus, in contrast to other histone acetyltransferases, Hat1p activity was required for transcriptional repression rather than gene activation.

DOT4 links silencing and cell growth in Saccharomyces cerevisiae.

Transcriptional silencing in Saccharomyces cerevisiae occurs at specific loci and is mediated by a multiprotein complex that includes Rap1p and the Sir proteins. We studied the function of a recently identified gene, DOT4, that disrupts silencing when overexpressed. DOT4 encodes an ubiquitin processing protease (hydrolase) that is primarily located in the nucleus. By two-hybrid analysis, the amino-terminal third of Dot4p interacts with the silencing protein Sir4p. Cells lacking DOT4 exhibited reduced silencing and a corresponding decrease in the level of Sir4p. Together, these findings suggest that Dot4p regulates silencing by acting on Sir4p. In strains with several auxotrophic markers, loss of DOT4 ubiquitin hydrolase activity also results in a slow-growth defect. The defect can be partially suppressed by mutations in a subunit of the 26S proteasome, suggesting that Dot4p has the ability to prevent ubiquitin-mediated degradation. Furthermore, wild-type SIR2, SIR3, and SIR4 are required for full manifestation of the growth defect in a dot4 strain, indicating that the growth defect is caused in part by a silencing-related mechanism. We propose that Dot4p helps to restrict the location of silencing proteins to a limited set of genomic loci.

Telomeres: structure of a chromosome's aglet.

Telomeres impart stability on linear eukaryotic chromosomes by acting as caps, preventing chromosomes from fusing together or being degraded. The structure of a telomere end binding protein in a complex with DNA provides the first molecular view of chromosome capping.

Telomeric chromatin modulates replication timing near chromosome ends.

Saccharomyces cerevisiae telomeric DNA replicates late in S phase, and telomeric genes are transcriptionally silent. Transcriptional repression of telomere-proximal genes results from silent chromatin initiating at the chromosome end, but the relationship between telomeric chromatin and DNA replication is unknown. Mutations in SIR3, a silent chromatin component, cause telomeric DNA on chromosome V to replicate much earlier because of earlier initiation of a nearby replication origin, the Y' ARS. A second telomere-proximal ARS, from an X element, does not act as an origin in a wild-type strain, whereas in a sir3 cell it does. We conclude that telomeric chromatin has a Sir3-dependent inhibitory effect on DNA replication.

Telomerase-mediated telomere addition in vivo requires DNA primase and DNA polymerases alpha and delta.

To better understand the requirements for telomerase-mediated telomere addition in vivo, we developed an assay in S. cerevisiae that creates a chromosome end immediately adjacent to a short telomeric DNA tract. The de novo end acts as a telomere: it is protected from degradation in a CDC13-dependent manner, telomeric sequences are added efficiently, and addition occurs at a faster rate in mutant strains that have long telomeres. Telomere addition was detected in M phase arrested cells, which permitted us to determine that the essential DNA polymerases alpha and delta and DNA primase were required. This indicates that telomeric DNA synthesis by telomerase is tightly coregulated with the production of the opposite strand. Such coordination prevents telomerase from generating excessively long single-stranded tails, which may be deleterious to chromosome stability in S. cerevisiae.

Identification of high-copy disruptors of telomeric silencing in Saccharomyces cerevisiae.

The ends of chromosomes in Saccharomyces cerevisiae initiate a repressive chromatin structure that spreads internally and inhibits the transcription of nearby genes, a phenomenon termed telomeric silencing. To investigate the molecular basis of this process, we carried out a genetic screen to identify genes whose overexpression disrupts telomeric silencing. We thus isolated 10 DOT genes (disruptor of telomeric silencing). Among these were genes encoding chromatin component Sir4p, DNA helicase Dna2p, ribosomal protein L32, and two proteins of unknown function, Asf1p and Ifh1p. The collection also included genes that had not previously been identified: DOT1, DOT4, DOT5, DOT6, and TLC1, which encodes the RNA template component of telomerase. With the exception of TLC1, all these genes, particularly DOT1 and DOT4, also reduced silencing at other repressed loci (HM loci and rDNA) when overexpressed. Moreover, deletion of the latter two genes weakened silencing as well, suggesting that DOT1 and DOT4 normally play important roles in gene repression. DOT1 deletion also affected telomere tract length. The function of Dot1p is not known. The sequence of Dot4p suggests that it is a ubiquitin-processing protease. Taken together, the DOT genes include both components and regulators of silent chromatin.

Chromosome dynamics: yeast pulls it apart.

Sister chromatid cohesion and chromosome condensation are both essential to the successful completion of mitosis. The recent identification and characterization of the yeast Mcd1p/Scc1p protein reveals a previously unsuspected mechanistic link between these processes.

The ubiquitin-conjugating enzyme Rad6 (Ubc2) is required for silencing in Saccharomyces cerevisiae.

It has been previously shown that genes transcribed by RNA polymerase II (RNAP II) are subject to position effect variegation when located near yeast telomeres. This telomere position effect requires a number of gene products that are also required for silencing at the HML and HMR loci. Here, we show that a null mutation of the DNA repair gene RAD6 reduces silencing of the HM loci and lowers the mating efficiency of MATa strains. Likewise, rad6-delta reduces silencing of the telomere-located RNAP II-transcribed genes URA3 and ADE2. We also show that the RNAP III-transcribed tyrosyl tRNA gene, SUP4-o, is subject to position effect variegation when located near a telomere and that this silencing requires the RAD6 and SIR genes. Neither of the two known Rad6 binding factors, Rad18 and Ubr1, is required for telomeric silencing. Since Ubrl is the recognition component of the N-end rule-dependent protein degradation pathway, this suggests that N-end rule-dependent protein degradation is not involved in telomeric silencing. Telomeric silencing requires the amino terminus of Rad6. Two rad6 point mutations, rad6(C88A) and rad6(C88S), which are defective in ubiquitin-conjugating activity fail to complement the silencing defect, indicating that the ubiquitin-conjugating activity of RAD6 is essential for full telomeric silencing.

The major cytoplasmic histone acetyltransferase in yeast: links to chromatin replication and histone metabolism.

We have isolated the predominant cytoplasmic histone acetyltransferase activity from Saccharomyces cerevisiae. This enzyme acetylates the lysine at residue 12 of free histone H4 but does not modify histone H4 when packaged in chromatin. The activity contains two proteins, Hat1p and Hat2p. Hat1p is the catalytic subunit of the histone acetyltransferase and has an intrinsic substrate specificity that modifies lysine in the recognition sequence GXGKXG. The specificity of the enzyme in the yeast cytoplasm is restricted relative to recombinant Hat1p suggesting that it is negatively regulated in vivo. Hat2p, which is required for high affinity binding of the acetyltransferase to histone H4, is highly related to Rbap48, which is a subunit of the chromatin assembly factor, CAF-1, and copurifies with the human histone deacetylase HD1. We propose that the Hat2p/Rbap48 family serve as escorts of histone metabolism enzymes to facilitate their interaction with histone H4.

Transcription of a yeast telomere alleviates telomere position effect without affecting chromosome stability.

Telomeres are required for the stable maintenance of chromosomes in the yeast Saccharomyces cerevisiae. Telomeres also repress the expression of genes in their vicinity, a phenomenon known as telomere position effect. In an attempt to construct a conditional telomere, an inducible promoter was introduced adjacent to a single telomere of a chromosome such that transcription could be induced toward the end of the chromosome. Transcription toward two other essential chromosomal elements, centromeres and origins of replication, eliminates their function. In contrast, transcription toward a telomere did not affect the stability function of the telomere as measured by the loss rate of the transcribed chromosome. Transcription proceeded through the entire length of the telomeric tract and caused a modest reduction in the average length of the transcribed telomere. Transcription of the telomere substantially reduced the frequency of cells in which an adjacent URA3 gene was subject to telomere position effect. These results indicate that telomere position effect can be alleviated without compromising chromosome stability.

TLC1: template RNA component of Saccharomyces cerevisiae telomerase.

Telomeres, the natural ends of linear eukaryotic chromosomes, are essential for chromosome stability. Because of the nature of DNA replication, telomeres require a specialized mechanism to ensure their complete duplication. Telomeres are also capable of silencing the transcription of genes that are located near them. In order to identify genes in the budding yeast Saccharomyces cerevisiae that are important for telomere function, a screen was conducted for genes that, when expressed in high amounts, would suppress telomeric silencing. This screen lead to the identification of the gene TLC1 (telomerase component 1). TLC1 encodes the template RNA of telomerase, a ribonucleoprotein required for telomere replication in a variety of organisms. The discovery of TLC1 confirms the existence of telomerase in S. cerevisiae and may facilitate both the analysis of this enzyme and an understanding of telomere structure and function.

Overcoming telomeric silencing: a trans-activator competes to establish gene expression in a cell cycle-dependent way.

Genes located near telomeres in yeast are subject to position-effect variegation. To better understand the mechanism of this variegation, we investigated how a telomeric URA3 gene switches from a silent to an expressed state. We found that silencing of a telomeric URA3 gene was attributable to the elimination of its basal transcription. The reversal of that silencing was dependent on the presence of PPR1, the trans-activator protein of URA3. Maximum expression of URA3 required a higher concentration of PPR1 when URA3 was telomeric compared with when it was at a nontelomeric location. The ability of PPR1 to overcome silencing varied at different points in the cell cycle. In cells arrested in G2/metaphase, PPR1 was able to activate transcription of a telomeric URA3, but in cells arrested in G0, G1, or early S phase it was not. In comparison, a nontelomeric URA3 could be activated by PPR1 at all times. We conclude that once established, telomeric silent chromatin is a relatively stable structure, making a gene recalcitrant to activation. Following the disassembly of silent chromatin during DNA replication, competition of assembly ensues between components of telomeric chromatin, to establish a silent state, and the trans-activator, to establish gene expression. These results help explain the stochastic nature of phenotypic switching in variegated gene expression.

Silent domains are assembled continuously from the telomere and are defined by promoter distance and strength, and by SIR3 dosage.

In Saccharomyces cerevisiae, telomeres repress transcription of genes located nearby. This region-specific gene inactivation is thought to involve the packaging of telomeric domains into silent chromatin. To gain insight into the mechanism of telomeric silencing, a genetic assay to examine the spread of silencing along the distal right arm of chromosome V was developed. The frequency of silencing a telomere-adjacent URA3 gene decreased with increasing distance of the gene's promoter from the telomere, irrespective of transcriptional orientation. The distance over which telomeric silencing of URA3 was observed was extended by weakening the gene's promoter--specifically, by deleting PPR1, the trans-activator of URA3. The silent telomeric domain was extended even farther by increasing the gene dosage of SIR3. These results suggest that a gene's promoter is a key determinant in controlling silencing on that gene and that SIR3 is a crucial component of the silent chromatin domain that initiates at the telomere and is assembled inwardly along the yeast chromosome. Finally, silencing is not observed on the centromeric side of an actively transcribed telomeric gene, demonstrating that the repressed telomeric domain is propagated continuously along the DNA. Taken together, these data reflect the complex and dynamic organization of eukaryotic genomes into functionally distinct regions.