Crosstalk between H2A variant-specific modifications impacts vital cell functions.

Selection of C-terminal motifs participated in evolution of distinct histone H2A variants. Hybrid types of variants combining motifs from distinct H2A classes are extremely rare. This suggests that the proximity between the motif cases interferes with their function. We studied this question in flowering plants that evolved sporadically a hybrid H2A variant combining the SQ motif of H2A.X that participates in the DNA damage response with the KSPK motif of H2A.W that stabilizes heterochromatin. Our inventory of PTMs of H2A.W variants showed that in vivo the cell cycle-dependent kinase CDKA phosphorylates the KSPK motif of H2A.W but only in absence of an SQ motif. Phosphomimicry of KSPK prevented DNA damage response by the SQ motif of the hybrid H2A.W/X variant. In a synthetic yeast expressing the hybrid H2A.W/X variant, phosphorylation of KSPK prevented binding of the BRCT-domain protein Mdb1 to phosphorylated SQ and impaired response to DNA damage. Our findings illustrate that PTMs mediate interference between the function of H2A variant specific C-terminal motifs. Such interference could explain the mutual exclusion of motifs that led to evolution of H2A variants.

A Synthetic Approach to Reconstruct the Evolutionary and Functional Innovations of the Plant Histone Variant H2A.W.

Diversification of histone variants is marked by the acquisition of distinct motifs and functional properties through convergent evolution.1-4 H2A variants are distinguished by specific C-terminal motifs and tend to be segregated within defined domains of the genome.5,6 Whether evolution of these motifs pre-dated the evolution of segregation mechanisms or vice versa has remained unclear. A suitable model to address this question is the variant H2A.W, which evolved in plants through acquisition of a KSPK motif7 and is tightly associated with heterochromatin.4 We used fission yeast, where chromatin is naturally devoid of H2A.W, to study the impact of engineered chimeras combining yeast H2A with the KSPK motif. Biochemical assays showed that the KSPK motif conferred nucleosomes with specific properties. Despite uniform incorporation of the engineered H2A chimeras in the yeast genome, the KSPK motif specifically affected heterochromatin composition and function. We conclude that the KSPK motif promotes chromatin properties in yeast that are comparable to the properties and function of H2A.W in plant heterochromatin. We propose that the selection of functional motifs confer histone variants with properties that impact primarily a specific chromatin state. The association between a new histone variant and a preferred chromatin state can thus provide a setting for the evolution of mechanisms that segregate the new variant to this state, thereby enhancing the impact of the selected properties of the variant on genome activity.

H2A Variants in Arabidopsis: Versatile Regulators of Genome Activity.

The eukaryotic nucleosome prevents access to the genome. Convergently evolving histone isoforms, also called histone variants, form diverse families that are enriched over distinct features of plant genomes. Among the diverse families of plant histone variants, H2A.Z exclusively marks genes. Here we review recent research progress on the genome-wide distribution patterns and deposition of H2A.Z in plants as well as its association with histone modifications and roles in plant chromatin regulation. We also discuss some hypotheses that explain the different findings about the roles of H2A.Z in plants.

Large scale screening of genetic interaction with sgf73(+) in fission yeast.

Genetic interaction (GI) not only suggests functional correlations between different genes in vivo, but also provides clues for understanding the potential biological function of a specific gene. Screening of GI is an important method for understanding GI between different genes. In this study, we selected sgf73⁺ as a query, which encodes a subunit of SAGA (Spt-Ada-Gcn5 acetyltransferase) complex deubiquitination module, to perform a large scale screening of GI in fission yeast. Our data showed that 164 genes had negative GIs whereas 42 genes had positive GIs with sgf73⁺. GO (Gene ontology) analysis indicated that these genes were enriched in several important biological processes, including chromatin modification, DNA damage repair, cellular response to stress, RNA transcription and so on. By using histone modification detection, we showed for the first time that loss of sgf73⁺ led to a decreased level of histone acetylation at H3K9 and H4K16 and an increased level of histone H3K4 methylation. Furthermore, the spot assay results showed that the sgf73∆ cells exhibited increased sensitivity to DNA damage agents, HU and CPT, and sgf73⁺ was involved in responses to hyperoxia stress. All these results suggested that sgf73⁺ plays important roles in chromatin modification, DNA damage repair and hyperoxia responses.

Septin ring assembly is regulated by Spt20, a structural subunit of the SAGA complex.

Accurate cell division requires the proper assembly of high-order septin structures. In fission yeast (Schizosaccharomyces pombe), Spn1-Spn4 are assembled into a primary septin ring at the division site, and the subsequent recruitment of Mid2 to the structure results in a stable septin ring. However, not much is known about the regulation of this key process. Here, we found that deletion of Spt20, a structural subunit of the Spt-Ada-Gcn5-acetyltransferase (SAGA) transcriptional activation complex, caused a severe cell separation defect. The defect was mainly due to impaired septin ring assembly, as 80% of spt20Δ cells lost septin rings at the division sites. Spt20 regulates septin ring assembly partially through the transcriptional activation of mid2(+). Spt20 also interacted with Spn2 and Mid2 in vitro and was associated with other components of the ring in vivo. Spt20 colocalized with the septin ring, but did not separate when the septin ring split. Importantly, Spt20 regulated the stability of the septin ring and was required for the recruitment of Mid2. The transcription-dependent and -independent roles of Spt20 in septin ring assembly highlight a multifaceted regulation of one process by a SAGA subunit.

[SAGA complex subunit Spt20 involves in the calcineurin-mediated Cl- homeostasis in Schizosaccharomyces pombe].

SAGA (Spt-Ada-Gcn5 acetyltransferase) is a highly conserved protein complex in eukaryotes, which plays a role in many important cellular processes, including transcriptional activation and mRNA exportation. In order to investigate the potential biological function of SAGA subunit, we performed a yeast two-hybrid screen using a core structural subunit of SAGA in fission yeast, Spt20, as the bait. Ppbl, catalytic subunit of calcineruin was identified in the test. Calcineurin is a key regulator of signal transduction. The interaction between Spt20 and Ppb1 was confirmed by yeast two-hybrid assay and co-immunoprecipitation. In S. pombe, ppb1delta was hypersensitive to high concentration of Cl-. In contrast, spt20delta could resist high concentration of Cl-, which maintained normal growth of cells. Fluorescent colocalization analysis showed that Ppb1 was translocated from cytoplasm to nucleus and colocalized with Spt20 upon the increase of extracellular Cl-. Further genetic analysis revealed that loss of spt20+ suppressed the hypersensitive phenotype to Cl- of ppbldelta. Thus, spt20+ and ppb1+ stayed in the same pathway of regulating Cl- homeostasis and spt20+ functioned downstream of ppb1+. Our data suggest that spt20delta is able to resist high concentration of extracellular Cl- and Spt20 involves in the calcineurin-mediated Cl- homeostasis. The aberrant up-regulation of intracellular Cl- is correlated with the diseases like myocardial ischemia reperfusion injury in higher organism. As Spt20 is highly conserved in eukaryotes, it might serve as a potential drug target in Cl- imbalance related diseases.

Identification of novel genes involved in DNA damage response by screening a genome-wide Schizosaccharomyces pombe deletion library.

BACKGROUND: DNA damage response (DDR) plays pivotal roles in maintaining genome integrity and stability. An effective DDR requires the involvement of hundreds of genes that compose a complicated network. Because DDR is highly conserved in evolution, studies in lower eukaryotes can provide valuable information to elucidate the mechanism in higher organisms. Fission yeast (Schizosaccharomyces pombe) has emerged as an excellent model for DDR research in recent years. To identify novel genes involved in DDR, we screened a genome-wide S. pombe haploid deletion library against six different DNA damage reagents. The library covered 90.5% of the nonessential genes of S. pombe. RESULTS: We have identified 52 genes that were actively involved in DDR. Among the 52 genes, 20 genes were linked to DDR for the first time. Flow cytometry analysis of the repair defective mutants revealed that most of them exhibited a defect in cell cycle progression, and some caused genome instability. Microarray analysis and genetic complementation assays were carried out to characterize 6 of the novel DDR genes in more detail. Data suggested that SPBC2A9.02 and SPAC27D7.08c were required for efficient DNA replication initiation because they interacted genetically with DNA replication initiation proteins Abp1 and Abp2. In addition, deletion of sgf73+, meu29+, sec65+ or pab1+ caused improper cytokinesis and DNA re-replication, which contributed to the diploidization in the mutants. CONCLUSIONS: A genome-wide screen of genes involved in DDR emphasized the key role of cell cycle control in the DDR network. Characterization of novel genes identified in the screen helps to elucidate the mechanism of the DDR network and provides valuable clues for understanding genome stability in higher eukaryotes.

[Research progress on genomic integrity regulated by epigenetics using yeast as a model.].

Genomic integrity is crucial for normal cell replication, proliferation and differentiation. DNA lesions resulted from exogenous and endogenous factors will lead to genomic instability, and consequently the cause for various diseases. Epigenetic regulation (including DNA methylation, histone modifications and non-coding RNA) plays important roles in DNA lesion repair and cell cycle regulation as well as maintaining the genetic integrity. The yeast, a type of single cell eukaryotic organism, is an ideal model for the researches of epigenetics, especially in the area of DNA lesion repair and the formation of heterochromatin. Previous researches on epigenetics were mainly focus on histone modifications. Recent re-searches have observed that non-coding RNAs are able to direct the cytosine methylation and histone modifications that are related to gene expression regulation. This paper discuss the mechanism, research progress and future development of epi-genetics in maintaining the genomic integrity, using the yeast as a model.

The fission yeast inhibitor of growth (ING) protein Png1p functions in response to DNA damage.

In budding yeast and human cells, ING (inhibitor of growth) tumor suppressor proteins play important roles in response to DNA damage by modulating chromatin structure through collaborating with histone acetyltransferase or histone deacetylase complexes. However, the biological functions of ING family proteins in fission yeast are poorly defined. Here, we report that Png1p, a fission yeast ING homolog protein, is required for cell growth under normal and DNA-damaged conditions. Png1p was further confirmed to regulate histone H4 acetylation through collaboration with the MYST family histone acetyltransferase 1 (Mst1). Additionally, both fission yeast PNG1 and MST1 can functionally complement their budding yeast correspondence homologs YNG2 and ESA1, respectively. These results suggest that ING proteins in fission yeast might also conserve function, similar to ING proteins in budding yeast and human cells. We also showed that decreased acetylation in Deltapng1 cells resulted in genome-wide down-regulation of 756 open reading frames, including the central DNA repair gene RAD22. Overexpression of RAD22 partially rescued the png1 mutant phenotype under both normal and DNA-damaged conditions. Furthermore, decreased expression of RAD22 in Deltapng1 cells was confirmed to be caused by decreased H4 acetylation at its promoter. Altogether, these results indicate that Png1p is required for histone H4 acetylation and functions upstream of RAD22 in the DNA damage response pathway.