Histone H3 lysine 4 methyltransferase is required for facultative heterochromatin at specific loci.

BACKGROUND: Histone H3 lysine 4 tri-methylation (H3K4me3) and histone H3 lysine 9 tri-methylation (H3K9me3) are widely perceived to be opposing and often mutually exclusive chromatin modifications. However, both are needed for certain light-activated genes in Neurospora crassa (Neurospora), including frequency (frq) and vivid (vvd). Except for these 2 loci, little is known about how H3K4me3 and H3K9me3 impact and contribute to light-regulated gene expression. RESULTS: In this report, we performed a multi-dimensional genomic analysis to understand the role of H3K4me3 and H3K9me3 using the Neurospora light response as the system. RNA-seq on strains lacking H3 lysine 4 methyltransferase (KMT2/SET-1) and histone H3 lysine 9 methyltransferase (KMT1/DIM-5) revealed some light-activated genes had altered expression, but the light response was largely intact. Comparing these 2 mutants to wild-type (WT), we found that roughly equal numbers of genes showed elevated and reduced expression in the dark and the light making the environmental stimulus somewhat ancillary to the genome-wide effects. ChIP-seq experiments revealed H3K4me3 and H3K9me3 had only minor changes in response to light in WT, but there were notable alterations in H3K4me3 in Δkmt1/Δdim-5 and H3K9me3 in Δkmt2/Δset-1 indicating crosstalk and redistribution between the modifications. Integrated analysis of the RNA-seq and ChIP-seq highlighted context-dependent roles for KMT2/SET1 and KMT1/DIM-5 as either co-activators or co-repressors with some overlap as co-regulators. At a small subset of loci, H3K4 methylation is required for H3K9me3-mediated facultative heterochromatin including, the central clock gene frequency (frq). Finally, we used sequential ChIP (re-ChIP) experiment to confirm Neurospora contains K4/K9 bivalent domains. CONCLUSIONS: Collectively, these data indicate there are obfuscated regulatory roles for H3K4 methylation and H3K9 methylation depending on genome location with some minor overlap and co-dependency.

The histone H3 lysine 9 methyltransferase DIM-5 modifies chromatin at frequency and represses light-activated gene expression.

The transcriptional program controlling the circadian rhythm requires coordinated regulation of chromatin. Characterization of the chromodomain helicase DNA-binding enzyme CHD1 revealed DNA methylation in the promoter of the central clock gene frequency (frq) in Neurospora crassa. In this report, we show that the DNA methylation at frq is not only dependent on the DNA methyltransferase DIM-2 but also on the H3K9 methyltransferase DIM-5 and HP1. Histone H3 lysine 9 trimethylation (H3K9me3) occurs at frq and is most prominent 30 min after light-activated expression. Strains lacking dim-5 have an increase in light-induced transcription, and more White Collar-2 is found associated with the frq promoter. Consistent with the notion that DNA methylation assists in establishing the proper circadian phase, loss of H3K9 methylation results in a phase advance suggesting it delays the onset of frq expression. The dim-5 deletion strain displays an increase in circadian-regulated conidia formation on race tubes and there is a synthetic genetic interaction between dim-5 and ras-1(bd). These results indicate DIM-5 has a regulatory role in muting circadian output. Overall, the data support a model where facultative heterochromatic at frq serves to establish the appropriate phase, mute the light response, and repress circadian output.

Meiotic silencing by unpaired DNA is expressed more strongly in the early than the late perithecia of crosses involving most wild-isolated Neurospora crassa strains and in self-crosses of N. tetrasperma.

Meiotic silencing by unpaired DNA is a presumed RNAi-mediated elimination of the transcripts of any gene that is not properly paired with a homolog in meiosis. Eighty wild-isolated strains of Neurospora crassa were classified into three types based on the apparent strength of meiotic silencing of the bml (ß-tubulin) and mei-3 genes in crosses with the ::Bml(r) and ::mei-3 tester strains. "OR" and "Sad" type wild-isolates, respectively, did or did not silence both the genes, whereas the "Esm" type (68 strains) silenced bml but not mei-3(+), suggesting an intermediate strength of silencing. Many wild strains, especially of the Esm type, gave fertile crosses with strains bearing the 148 kbp chromosome segment duplication Dp(EB4) but their crosses with the 405 kbp Dp(IBj5) were barren. Larger Dps might include more genes whose sensitivity to silencing is comparable with that of bml, consequently their crosses with the OR and Esm type strains would be about equally barren, whereas small Dps, with presumably few or no bml-like genes suffer little gene silencing in crosses with Esm and Sad strains and thus remain fertile. Using lollipop-shaped asci as indicators of silencing in crosses of the ::act tester with Esm type strains, and white-spored asci in Neurospora tetrasperma self-crosses heterozygous for an ectopic insertion of the asm-1 gene, we found that meiotic silencing was expressed more strongly in the early but not in the late perithecia of these crosses.

A factor in a wild isolated Neurospora crassa strain enables a chromosome segment duplication to suppress repeat-induced point mutation.

Repeat-induced point mutation (RIP) is a sexual stage-specific mutational process of Neurospora crassa and other fungi that alters duplicated DNA sequences. Previous studies from our laboratory showed that chromosome segment duplications (Dps) longer than (approx.) 300 kbp can dominantly suppress RIP, presumably by titration of the RIP machinery, and that although Dps less than 200 kbp did not individually suppress RIP, they could do so in homozygous and multiply heterozygous crosses, provided the sum of the duplicated DNA exceeds (approx.) 300 kbp. Here we demonstrate suppression of RIP in a subset of progeny carrying the normally sub-threshold 154 kbp Dp(R2394) from a cross of T(R2394) to the wild isolated Carrefour Mme. Gras strain (CMG). Thus, the CMG strain contains a factor that together with Dp(R2394) produces a synthetic RIP suppressor phenotype. It is possible that the factor is a cryptic Dp that together with Dp(R2394) can exceed the size threshold for titration of the RIP machinery and thereby causes RIP suppression.

Carrefour Mme. Gras: a wild-isolated Neurospora crassa strain that suppresses meiotic silencing by unpaired DNA and uncovers a novel ascospore stability defect.

Ordinarily, RIP-induced erg-3 mutant Neurospora crassa ascospores and their erg(+) siblings do not differ in stability during long-term storage. Consequently, the frequency of RIP-induced erg-3 mutants remains about constant regardless of the time that has elapsed between ascospore harvest and germination. We found, however, that RIP-induced erg-3 mutants were apparently selectively lost with time from among the ascospores stored from a cross with the wild-isolated Carrefour Mme. Gras strain from Haiti. The Haitian strain was also found to exert a dominant suppression of meiotic silencing by unpaired DNA. Similar loss of RIP-induced erg-3 mutant ascospores was seen among the stored ascospores from a subset of crosses heterozygous for the semi-dominant Sad-1 or Sad-2 suppressors of meiotic silencing. Our results suggest that crosses suppressed in meiotic silencing can compromise the stability during storage of ascospores that inherit RIP-induced mutations.

Neurospora crassa fmf-1 encodes the homologue of the Schizosaccharomyces pombe Ste11p regulator of sexual development.

The Neurospora crassa fmf-1 mutation exerts an unusual 'perithecium-dominant' developmental arrest; fmf-1 x fmf-1+ cross becomes arrested in perithecial development regardless of whether the mutant participates in the cross as the male or female parent. We localized fmf-1 to the LG IL genome segment between the centromere-proximal breakpoint of the chromosome segment duplication Dp(IL)39311 and the centromere. By mapping crossovers with respect to RFLP markers in this region we further localized fmf-1 to an approximately 34-kb-genome segment. Partial sequencing of this segment revealed a point mutation in the gene NCU 09387.1, a homologue of the Schizosaccharomyces pombe ste11+ regulator of sexual development. The fmf-1 mutation did not complement a NCU 09387.1 deletion mutation, and transformation with wild-type NCU 09387.1 complemented fmf-1. S. pombe Ste11 protein (Ste11p) is a transcription factor required for sexual differentiation and for the expression of genes required for mating pheromone signalling in matP and matM cells. If FMF-1 also plays a corresponding role in mating pheromone signalling in Neurospora, then protoperithecia in an fmf-1 x fmf-1+ cross would be unable to either send or receive sexual differentiation signals and thus become arrested in development.

Chromosome segment duplications in Neurospora crassa: barren crosses beget fertile science.

Studies on Neurospora chromosome segment duplications (Dps) performed since the publication of Perkins's comprehensive review in 1997 form the focus of this article. We present a brief summary of Perkins's seminal work on chromosome rearrangements, specifically, the identification of insertional and quasiterminal translocations that can segregate Dp progeny when crossed with normal sequence strains (i.e., T x N). We describe the genome defense process called meiotic silencing by unpaired DNA that renders Dp-heterozygous crosses (i.e., Dp x N) barren, which provides a basis for identifying Dps, and discuss whether other processes also might contribute to the barren phenotype of Dp x N and Dp x Dp crosses. We then turn to studies suggesting that large Dps (i.e., >300 kbp) can allow smaller gene-sized duplications to escape another genome defense process called repeat-induced point mutation (RIP), possibly by titration of the RIP machinery. Finally, we assess whether in natural populations dominant RIP suppressor Dps provide an "RIP-free" niche for evolution of new genes following the duplication of existing genes.