Involvement of fission yeast Clr6-HDAC in regulation of the checkpoint kinase Cds1

Mutation in histone deacetylase clr6 promotes the survival of S. pombe cds1 null mutant in response to hydroxyurea

Fission yeast Cds1 is responsible for the replication checkpoint activation and helps to protect replication fork collapse in response to hydroxyurea (HU). Here, we investigated the role of histone deacetylase in response to replication fork arrest and observed that in the presence of HU, the survival of cds1Δ cells was improved when the cells were simultaneously treated with histone deacetylase inhibitors. Furthermore, a mutation in the histone deacetylase gene, clr6, also suppresses the growth defect of cds1Δ cells in response to HU indicating a suppressive role of clr6-1 mutation in cds1 deletion background upon HU treatment. Interestingly, in response to HU, phosphorylation of Chk1 kinase and the number of Rad52YFP foci was reduced in cds1Δ clr6-1 double mutant as compared to cds1Δ single mutant indicating a decrease in the level of DNA damage in response to HU. Accordingly, the single-cell gel electrophoresis assay revealed a drastic reduction in the tail length of cds1Δ clr6-1 double mutant as compared to cds1Δ cells in the presence of HU suggesting the suppression of chromosomal defects in the double mutant. Taken together, we proposed that there could be transient suppression of fork collapse in cds1Δ clr6-1 double mutant upon HU treatment due to the delay in mitotic progression that leads to the facilitation of cell growth.

The NuA4 acetyltransferase and histone H4 acetylation promote replication recovery after topoisomerase I-poisoning

BACKGROUND

Histone acetylation plays an important role in DNA replication and repair because replicating chromatin is subject to dynamic changes in its structures. However, its precise mechanism remains elusive. In this report, we describe roles of the NuA4 acetyltransferase and histone H4 acetylation in replication fork protection in the fission yeast Schizosaccharomyces pombe.

RESULTS

Downregulation of NuA4 subunits renders cells highly sensitive to camptothecin, a compound that induces replication fork breakage. Defects in NuA4 function or mutations in histone H4 acetylation sites lead to impaired recovery of collapsed replication forks and elevated levels of Rad52 DNA repair foci, indicating the role of histone H4 acetylation in DNA replication and fork repair. We also show that Vid21 interacts with the Swi1-Swi3 replication fork protection complex and that Swi1 stabilizes Vid21 and promotes efficient histone H4 acetylation. Furthermore, our genetic analysis demonstrates that loss of Swi1 further sensitizes NuA4 and histone H4 mutant cells to replication fork breakage.

CONCLUSION

Considering that Swi1 plays a critical role in replication fork protection, our results indicate that NuA4 and histone H4 acetylation promote repair of broken DNA replication forks.

Unraveling Site-Specific and Combinatorial Histone Modifications Using High-Resolution Mass Spectrometry in Histone Deacetylase Mutants of Fission Yeast

Histone deacetylases (HDACs) catalyze the removal of acetylation marks from lysine residues on histone and nonhistone substrates. Their activity is generally associated with essential cellular processes such as transcriptional repression and heterochromatin formation. Interestingly, abnormal activity of HDACs has been reported in various types of cancers, which makes them a promising therapeutic target for cancer treatment. In the current study, we aim to understand the mechanisms underlying the function of HDACs using an in-depth quantitative analysis of changes in histone acetylation levels in Schizosaccharomyces pombe (S. pombe) lacking major HDAC activities. We employed a targeted quantitative mass spectrometry approach to profile changes of acetylation and methylation at multiple lysine residues on the N-terminal tail of histones H3 and H4. Our analyses identified a number of histone acetylation sites that are significantly affected by S. pombe HDAC mutations. We discovered that mutation of the Class I HDAC known as Clr6 causes a major increase in the abundance of triacetylated H4 molecules at K5, K8, and K12. A clr6-1 hypomorphic mutation also increased the abundance of multiple acetyl-lysines in histone H3. In addition, our study uncovered a few crosstalks between histone acetylation and methylation upon deletion of HDACs Hos2 and Clr3. We anticipate that the results from this study will greatly improve our current understanding of the mechanisms involved in HDAC-mediated gene regulation and heterochromatin assembly.

Histone H4 acetylation required for chromatin decompaction during DNA replication

Faithful DNA replication is a prerequisite for cell proliferation. Several cytological studies have shown that chromosome structures alter in the S-phase of the cell cycle. However, the molecular mechanisms behind the alteration of chromosome structures associated with DNA replication have not been elucidated. Here, we investigated chromatin structures and acetylation of specific histone residues during DNA replication using the meiotic nucleus of the fission yeast Schizosaccharomyces pombe. The S. pombe meiotic nucleus provides a unique opportunity for measuring the levels of compaction of chromatin along the chromosome in a defined orientation. By direct measurement of chromatin compaction in living cells, we demonstrated that decompaction of chromatin occurs during meiotic DNA replication. This chromatin decompaction was suppressed by depletion of histone acetyltransferase Mst1 or by arginine substitution of specific lysine residues (K8 and K12) of histone H4. These results suggest that acetylation of histone H4 residues K8 and K12 plays a critical role in loosening chromatin structures during DNA replication.

Pcf1, a large subunit of CAF-1, required for maintenance of checkpoint kinase Cds1 activity

Highly conserved chromatin assembly factor 1 (CAF-1) is required for histone deposition onto newly synthesized DNA to maintain genome stability. This study shows that the fission yeast Pcf1, the large subunit in CAF-1, is crucial for maintaining checkpoint kinase Cds1. Chromatin recruitment of Cds1 is enhanced by Pcf1 overproduction but is attenuated by the Δpcf1 mutation. Mutation of acetylation sites in the histone H4 tail abrogates the chromatin recruitment of Pcf1, which resembles that of Cds1 as reported previously. The present results provide evidence that chromatin recruitment of Pcf1, moderated by Clr6-HDAC activity, is essential for inactivating Cds1.

Deacetylase Rpd3 facilitates checkpoint adaptation by preventing Rad53 overactivation

The DNA damage checkpoint is tightly controlled. After its activation, the checkpoint machinery is inactivated once lesions are repaired or undergoes adaptation if the DNA damage is unable to be repaired. Protein acetylation has been shown to play an important role in DNA damage checkpoint activation. However, the role of acetylation in checkpoint inactivation is unclear. Here we show that histone deacetylase Rpd3-mediated deacetylation of Rad53 plays an important role in checkpoint adaptation. Deletion of Rpd3 or inhibition of its activity impairs adaptation. RPD3 deletion also leads to a higher acetylation level and enhanced kinase activity of Rad53. Replacement of two major acetylation sites of Rad53 with arginine reduces its activity and further suppresses the adaptation defect of rpd3Δ cells, indicating that Rpd3 facilitates adaptation by preventing Rad53 overactivation. Similar to its role in adaptation, deletion of RPD3 or inhibition of its activity also suppressed checkpoint recovery. Altogether, our findings reveal an important role of Rpd3 in promoting checkpoint adaptation via deacetylation and inhibition of Rad53.

Genome-wide screening for genes associated with valproic acid sensitivity in fission yeast

We have been studying the action mechanisms of valproic acid (VPA) in fission yeast Schizosaccharomyces pombe by developing a genetic screen for mutants that show hypersensitivity to VPA. In the present study, we performed a genome-wide screen of 3004 haploid deletion strains and confirmed 148 deletion strains to be VPA sensitive. Of the 148 strains, 93 strains also showed sensitivity to another aliphatic acids HDAC inhibitor, sodium butyrate (SB), and 55 strains showed sensitivity to VPA but not to SB. Interestingly, we found that both VPA and SB treatment induced a marked increase in the transcription activity of Atf1 in wild-type cells. However, in clr6-1, a mutant allele the clr6⁺ gene encoding class I HDAC, neither VPA- nor SB induced the activation of Atf1 transcription activity. We also found that VPA, but not SB, caused an increase in cytoplasmic Ca²⁺ level. We further found that the cytoplasmic Ca²⁺ increase was caused by Ca²⁺ influx from extracellular medium via Cch1-Yam8 channel complex. Altogether, our present study indicates that VPA and SB play similar but distinct roles in multiple physiological processes in fission yeast.

Autoregulation of convergent RNAi genes in fission yeast

RNAi plays a central role in the regulation of eukaryotic genes. In Schizosaccharomyces pombe fission yeast, RNAi involves the formation of siRNA from dsRNA that acts to establish and maintain heterochromatin over centromeres, telomeres, and mating loci. We showed previously that transient heterochromatin also forms over S. pombe convergent genes (CGs). Remarkably, most RNAi genes are themselves convergent. We demonstrate here that transient heterochromatin formed by the RNAi pathway over RNAi CGs leads to their autoregulation in G1-S. Furthermore, the switching of RNAi gene orientation from convergent to tandem causes loss of their G1-S down-regulation. Surprisingly, yeast mutants with tandemized dcr1, ago1, or clr4 genes display aberrant centromeric heterochromatin, which results in abnormal cell morphology. Our results emphasize the significance of gene orientation for correct RNAi gene expression, and suggest a role for cell cycle-dependent formation of RNAi CG heterochromatin in cellular integrity.

A novel human dynactin-associated protein, dynAP, promotes activation of Akt, and ergosterol-related compounds induce dynAP-dependent apoptosis of human cancer cells

There are several human genes that may encode proteins whose functions remain unknown. To find clues to their functions, we used the mutant yeast defective in Mad2, a component of the spindle checkpoint complex. Phenotypes that were provoked by the expression of a human C18orf26 protein in the mutant yeast encouraged further characterization of this protein in human cells. This protein was designated dynAP (dynactin-associated protein) because of its interaction with dynactin subunits that comprised a microtubule-based motor protein complex. The dynAP is a transmembrane protein localizing to Golgi apparatus and plasma membrane in a microtubule-dependent manner. This protein was expressed in half of human cancer cell lines but barely in normal human fibroblasts tested. The SV40-transformed fibroblasts expressed dynAP. Importantly, the expression of dynAP activated Akt (also known as protein kinase B) by promoting Ser⁴⁷³ phosphorylation required for the full activation, whereas knockdown of dynAP abolished this activation. The ergosterol-related compounds identified by the yeast cell-based high-throughput screen abrogated activation of Akt and induced apoptosis in a dynAP-dependent manner. We propose a possible advantage of dynAP expression in cancer cells; the survival of cancer cells that express dynAP is supported by dynAP-induced activation of Akt, sustaining high rates of proliferation. The inactivation of dynAP by the selected compounds nullifies this advantage, and thereby, the apoptotic machinery is allowed to operate. Taken together, dynAP can be a new target for cancer therapy, and the selected chemicals are useful for developing a new class of anticancer drugs.

Inhibition of type I histone deacetylase increases resistance of checkpoint-deficient cells to genotoxic agents through mitotic delay

Histone deacetylase (HDAC) inhibitors potently inhibit tumor growth and are currently being evaluated for their efficacy as chemosensitizers and radiosensitizers. This efficacy is likely to be limited by the fact that HDAC inhibitors also induce cell cycle arrest. Deletion of the class I HDAC Rpd3 has been shown to specifically suppress the sensitivity of Saccharomyces cerevisiae DNA damage checkpoint mutants to UV and hydroxyurea. We show that in the fission yeast Schizosaccharomyces pombe, inhibition of the homologous class I HDAC specifically suppresses the DNA damage sensitivity of checkpoint mutants. Importantly, the prototype HDAC inhibitor Trichostatin A also suppressed the sensitivity of DNA damage checkpoint but not of DNA repair mutants to UV and HU. TSA suppressed DNA damage activity independently of the mitogen-activated protein kinase-dependent and spindle checkpoint pathways. We show that TSA delays progression into mitosis and propose that this is the main mechanism for suppression of the DNA damage sensitivity of S. pombe checkpoint mutants, partially compensating for the loss of the G(2) checkpoint pathway. Our studies also show that the ability of HDAC inhibitors to suppress DNA damage sensitivity is not species specific. Class I HDACs are the major target of HDAC inhibitors and cancer cells are often defective in checkpoint activation. Effective use of these agents as chemosensitizers and radiosensitizers may require specific treatment schedules that circumvent their inhibition of cell cycle progression.

RNAi, heterochromatin and the cell cycle

For many decades after its initial characterization, heterochromatin was considered to be transcriptionally inert, but newer work indicates that this highly condensed chromosomal material is transcribed, and rapidly silenced, by an orchestrated sequence of events directed by RNA interference (RNAi). Recent studies shed light on the timely assembly and inheritance of heterochromatin within a short period during the cell cycle, thereby providing an explanation for how 'silent' heterochromatin can be transcribed during the S phase of the cell cycle. Together, these findings suggest a model of RNAi-directed epigenetic inheritance.