ライフサイエンスコーパス: heterochromatic

1 ssing within 1 h, both in Alu repeats and in heterochromatic alpha-satellite DNA.

2 These epigenetic alterations affect mainly heterochromatic and bivalent regions and provide possibl

3 eloped an in vivo single DSB system for both heterochromatic and euchromatic loci in Drosophila melan

4 In both heterochromatic and euchromatic segments of the genome,

5 contrast to theories that Y chromosomes are heterochromatic and gene poor, the mouse MSY is 99.9% eu

6 ning Drosophila melanogaster Y chromosome is heterochromatic and has few genes.

7 euchromatic and intronic regions compared to heterochromatic and intergenic regions, respectively, an

8 D. melanogaster revealed previously unknown heterochromatic and telomeric transition sequences, and

9 somes are gene-poor, repeat-rich and largely heterochromatic and therefore represent a difficult targ

10 ciated with the nuclear lamina are generally heterochromatic and transcriptionally repressed.

11 The inactivated X chromosome becomes heterochromatic and visits a specific nuclear compartmen

12 Conversely, repair in regions classified as "heterochromatic" and "repressed" was relatively low at e

13 egions of the genome (genic, intergenic, and heterochromatic) and at different distances ( approximat

14 the Drosophila Y chromosome is degenerated, heterochromatic, and contains few genes, increasing evid

15 ated gene HvS40 and altering distribution of heterochromatic areas in the nuclei.

16 tion and reorganization of euchromatic A and heterochromatic B compartments.

17 Previous work in animals has shown that heterochromatic breaks are translocated out of the heter

18 However, heterochromatic centromeres remained recombination-suppr

19 are characterized by a lack or reduction of heterochromatic CHH methylation and enrichment of CHH me

20 (ORs) genes requires the formation of large heterochromatic chromatin domains that sequester the OR

21 ditionally, PELP1 positively correlates with heterochromatic chromatin marks and negatively correlate

22 We found a drastic loss of H3K9me2 at heterochromatic chromocenters in vim1/2/3 nuclei.

23 r show that silenced clusters associate with heterochromatic chromosomal domains toward the periphery

24 s from new juxtapositions of euchromatic and heterochromatic chromosomal regions, and manifests as st

25 In Drosophila, transcripts from heterochromatic clusters are processed into primary piRN

26 We show that Rhino binds specifically to the heterochromatic clusters that produce piRNA precursors,

27 v) increase in the number of pericentromeric heterochromatic clusters; and (v) increase in the freque

28 atin and heterochromatin, which implies that heterochromatic compaction does not reduce MNase accessi

29 ns that switched from the euchromatic to the heterochromatic compartment during neutrophil differenti

30 tion involved genomic regions located in the heterochromatic compartment in both progenitors and neut

31 for the concept that induced changes to the heterochromatic component of the genome are coincident w

32 tem, identifying certain endogenous genes in heterochromatic contexts as privileged while foreign DNA

33 ysfunction in laminopathies is relaxation of heterochromatic DNA [1].

34 e a variation on this strategy for repairing heterochromatic DNA damage.

35 Heterochromatic DNA domains have important roles in the

36 orylation of S824 is necessary for repair of heterochromatic DNA lesions and similar to cells express

37 show that lack of histone H1, which elevates heterochromatic DNA methylation in somatic tissues, does

38 X RELATED PROTEIN 5 and 6 (ATXR5/6) regulate heterochromatic DNA replication and genome stability.

39 Males often contain substantially more heterochromatic DNA than females, due to the presence of

40 affold for the anchoring of highly condensed heterochromatic DNA to the nuclear envelope, thereby est

41 ization of Tet1, but not of Tet2 and Tet3 at heterochromatic DNA.

42 for defining the boundary between active and heterochromatic DNA.

43 chromatic breaks are translocated out of the heterochromatic domain for repair.

44 this prediction, we found that shortening a heterochromatic domain in Saccharomyces had no impact on

45 360 can enhance silencing of a reporter in a heterochromatic domain of Drosophila melanogaster.

46 dary elements at the edges of a 20-kb silent heterochromatic domain where nucleosomes are methylated

47 of asymmetric tetramer inheritance within a heterochromatic domain would have the potential to desta

48 l model to test the properties of an induced heterochromatic domain.

49 es impaired the de novo establishment of the heterochromatic domain.

50 Heterochromatic domains are complex structures composed

51 Heterochromatic domains are enriched with repressive his

52 Two recent papers in Nature propose that heterochromatic domains are organized into phase-separat

53 Heterochromatic domains containing histone H3 lysine 9 m

54 We conclude that heterochromatic domains form via phase separation, and m

55 n efficiency of origins in late-replicating, heterochromatic domains is only 25% lower than in early-

56 itioning of chromosomes into euchromatic and heterochromatic domains requires mechanisms that specify

57 After removal of the HP1alpha stimulus, heterochromatic domains were heritably transmitted, undi

58 corporated macroH2A retargets the same large heterochromatic domains where macroH2A was already enric

59 This model makes a prediction that shorter heterochromatic domains would experience unbalanced tetr

60 ro- and euchromatin: H1 is necessary to form heterochromatic domains yet dispensable for silencing of

61 in firing time, including that of origins in heterochromatic domains, was established in late G1 phas

62 ns between both constitutive and facultative heterochromatic domains, with the strongest interactions

63 H3 lysine 9 (H3K9) is methylated (H3K9me) at heterochromatic domains.

64 decreasing interactions between constitutive heterochromatic domains.

65 nappreciated roles of NDR positioning within heterochromatic domains.

66 A enzymatic activity is required to relocate heterochromatic double-strand breaks outside the domain,

67 (dKDM4A) histone demethylase is required for heterochromatic DSB mobility.

68 oral kinetics and pathway utilization during heterochromatic DSB repair depend on dKDM4A-dependent de

69 Heterochromatic DSBs display specialized temporal and sp

70 hful homologous recombination (HR) repair of heterochromatic DSBs relies on the relocalization of DSB

71 hought to be the main pathway used to repair heterochromatic DSBs, direct tests of this hypothesis ar

72 ACF1-SNF2H requires RNF20 to bind heterochromatic DSBs, underlies RNF20-mediated chromatin

73 g (NHEJ) repair pathways but exclusively for heterochromatic DSBs.

74 orylation (pKAP-1) and CHD3.1 dispersal from heterochromatic DSBs; however, how heterochromatin compa

75 tion and via a mechanism distinct from known heterochromatic effects on origin function.

76 may contribute to adaptation of genes to the heterochromatic environment and, hence, facilitate the e

77 Our data suggest that the heterochromatic environment at the gDMR reinforces silen

78 past, including increased repeat-content and heterochromatic environment.

79 are strongly correlated with euchromatic and heterochromatic epigenetic histone modifications, respec

80 Global establishment of heterochromatic features occurs following MZT and requir

81 Recruitment of the heterochromatic features SMCHD1, macroH2A, H3K27me3, and

82 lates with the ability to recruit additional heterochromatic features.

83 Mu1c(Col) was intergenic and associated with heterochromatic features.

84 e performed whole-genome analyses of several heterochromatic features: dimethylation of lysine 9 and

85 MP density was measured using customized heterochromatic flicker photometery.

86 -wavelength fundus autofluorescence [AF] and heterochromatic flicker photometry [HFP]), and serum con

87 POD) measured noninvasively using customized heterochromatic flicker photometry and blood samples gen

88 MPOD was measured using heterochromatic flicker photometry in 10 eyes (5 patient

89 eccentricity was measured using a customized heterochromatic flicker photometry technique.

90 juvenile sharks, made using single flash and heterochromatic flicker photometry under conditions of d

91 Heterochromatic flicker photometry was used to measure t

92 We measured MPOD by customized heterochromatic flicker photometry.

93 l layers characterizes senescence-associated heterochromatic foci (SAHF) formation in human fibroblas

94 f heterochromatin into senescence-associated heterochromatic foci (SAHFs).

95 nucleoporins are required for aggregation of heterochromatic foci and epigenetic inheritance.

96 ells and show that H1 overexpression creates heterochromatic foci in the VC progenitor cell.

97 ne H2A, is a marker of senescence-associated heterochromatic foci that synergizes with DNA methylatio

98 decreased H3K9 dimethylation, dispersion of heterochromatic foci, and derepression of MET-2 targets.

99 s, the repaired MeCP2 protein is enriched in heterochromatic foci, reflecting restoration of normal M

100 nt chromosomes converge in a small number of heterochromatic foci.

101 All three factors colocalize in heterochromatic foci.

102 cells destabilizes the senescence-associated heterochromatic foci.

103 nd its binding partner E2FA are recruited to heterochromatic gammaH2AX-labelled DNA damage foci in an

104 quantitative evaluation of the stability of heterochromatic gene repression.

105 e delete this trigger, dramatically altering heterochromatic gene silencing and chromatin architectur

106 ons outside of DNA replication, including in heterochromatic gene silencing and telomere maintenance.

107 he repetitive rDNA arrays are thought to use heterochromatic gene silencing as a mechanism for metabo

108 Here we show that RNA editing regulates heterochromatic gene silencing in Drosophila.

109 Heterochromatic gene silencing is an important form of g

110 y partially dependent on known components of heterochromatic gene silencing, implying that a distinct

111 and chromatin structure indicative of a more heterochromatic genome.

112 T cells revealed DNA hypomethylation in the heterochromatic genomic compartment, as well as reactiva

113 neutrophil genomes were highly enriched for heterochromatic genomic interactions across vast genomic

114 Ms by analyzing histone H3 purified from the heterochromatic germline micronucleus of the model organ

115 ed as either flickering full-field colors or heterochromatic gratings.

116 incident with the presence of high levels of heterochromatic H3 lysine nine trimethylation (H3K9me3).

117 In parallel, level of heterochromatic H3K9me2 decreases at this gene.

118 ssociated changes in spatial distribution of heterochromatic H3K9me2 patterns in the nuclei.

119 in type I latency, as well as an increase in heterochromatic H3K9me3 at these sites.

120 ectopic alphoid DNA integration site removed heterochromatic H3K9me3 modification and was sufficient

121 of transposons is mediated by 24-nucleotide heterochromatic (het)siRNAs, RDR2, DCL3 and AGO4.

122 of histone H3 lysine 9 (H3K9) methylation, a heterochromatic histone mark, from immediate early and l

123 ation rates, displayed similar decreases for heterochromatic histone marks.

124 fewer mature oligodendrocytes and decreased heterochromatic histone marks.

125 depend on dKDM4A-dependent demethylation of heterochromatic histone marks.

126 the literature around the role of the major heterochromatic histone methyltransferase Suv39h1 in the

127 Cyclin D1 and Dicer maintain heterochromatic histone modification (Tri-m-H3K9).

128 ation H3K9ac and a corresponding increase in heterochromatic histone modification H3K9me3 at the LMP2

129 gle cells and correlates positively with the heterochromatic histone modification H3K9me3.

130 NA bases to several megabases in the case of heterochromatic histone modifications.

131 -regulated interplay between euchromatic and heterochromatic histone modifications.

132 and mitosis, the contribution and extent of heterochromatic histone posttranslational modifications

133 Unexpectedly, silencing of the heterochromatic HML and HMR loci was not lost during agi

134 Maize heterochromatic knobs cheat female meiosis by forming ne

135 drive system that transforms typically inert heterochromatic knobs into centromere-like domains (neoc

136 petitive genomic features such as telomeres, heterochromatic knobs, and centromeres.

137 rnal structure of seven centromeres and five heterochromatic knobs, showing that the major tandem rep

138 lncRNA transcription in both euchromatic and heterochromatic lncRNA-based gene silencing processes.

139 is recruited by the ATF/CREB homolog Atf1 to heterochromatic loci and promoters of stress-response ge

140 Multiple heterochromatic loci are often clustered into a higher o

141 In Arabidopsis, clustering of repetitive heterochromatic loci into so-called chromocenters is an

142 osons for silencing, but not the specialized heterochromatic loci that produce piRNA precursors.

143 NAs were concentrated at a smaller number of heterochromatic loci throughout the genome, especially a

144 that Fft3 suppresses turnover of histones at heterochromatic loci to facilitate epigenetic transmissi

145 sed copies of mating-type information at the heterochromatic loci, HMLalpha and HMRa, which are locat

146 ether to elicit transcriptional silencing at heterochromatic loci.

147 he loss of which causes dramatic increase in heterochromatic loci.

148 wi6 recruitment to centromeric and telomeric heterochromatic loci.

149 (H3K9), which recruits Swi6/HP1 proteins to heterochromatic loci.

150 Here, we focus on a 180-kb heterochromatic locus producing Piwi-interacting RNAs (p

151 9me3 chromatin complex lies at the center of heterochromatic macromolecular assemblies and mediates m

152 ple model for the mitotic inheritance of the heterochromatic mark H3K27me1 and the protection of H3.3

153 ructure and leading to the dispersion of the heterochromatic mark H3K9me3.

154 e3, suggesting that dKDM4A demethylates this heterochromatic mark to facilitate repair.

155 ions and gene bodies marked by a facultative heterochromatic mark, which could explain the observed b

156 Progerin triggers loss of the heterochromatic marker H3K27me3, and premature senescenc

157 omatin specifically and acts in synergy with heterochromatic marks H3K9me2 and DNA methylation to mai

158 ) genomes are associated with the repressive heterochromatic marks H3K9me2/me3 and H3K27me3 during la

159 onstitutive H3K9me3 and facultative H3K27me3 heterochromatic marks in FRDA.

160 d to protect active chromatin from acquiring heterochromatic marks, such as dimethylated histone H3K9

161 ized by the presence of both euchromatic and heterochromatic marks.

162 athways in processing mRNAs of genes bearing heterochromatic marks.

163 irwise association between L1 insertions and heterochromatic marks.

164 chromatic domains, although all are close to heterochromatic masses.

165 These processes are linked to heterochromatic mo-2 minisatellite arrays, and require M

166 ent inactive X chromosome (Xi) enriched with heterochromatic modifications and XIST/Xist RNA, which e

167 Here we focus on the initial steps restoring heterochromatic modifications in the embryo.

168 of XIST/Xist RNA, and they lack the typical heterochromatic modifications of the Xi.

169 deletions that altered the distance between heterochromatic NDRs revealed a striking oscillatory rel

170 vation led to the unrestrained expression of heterochromatic noncoding RNAs (ncRNAs) that in turn tri

171 systematically altering the distance between heterochromatic nucleosome-depleted regions (NDRs), whic

172 tion complex on the neo-X and those becoming heterochromatic on the neo-Y show little overlap, possib

173 mark may be important for maintaining proper heterochromatic organization and, possibly, chromosome f

174 ith a central CENP-A(Cnp1) domain flanked by heterochromatic outer-repeat regions.

175 the number of crossovers between markers in heterochromatic pericentric regions that underwent demet

176 matic portion of the genome and 21 Mb in the heterochromatic portion, using a whole-genome shotgun as

177 re, we gained novel functional insight about heterochromatic PTMs by analyzing histone H3 purified fr

178 dant during schizogony and late gametocytes; heterochromatic PTMs mark early gametocytes.

179 ce-specifically in vitro, and localizes to a heterochromatic region in the COOLAIR promoter in vivo.

180 We observed the relocalization of a heterochromatic region, the mating-type region, from its

181 ne 9 acetylation (H3K9ac) is abundant in non-heterochromatic regions across all developmental stages.

182 This was true even for heterochromatic regions analyzed by quantitative PCR.

183 fluorescent staining pattern, with unstained heterochromatic regions and a banded distribution along

184 brid incompatibilities in Drosophila involve heterochromatic regions and factors that interact with t

185 und that transcripts of many genes native to heterochromatic regions and TEs increased with age in fl

186 Thus, associations between heterochromatic regions are a major component of the chr

187 Heterochromatic regions are associated with histone 3 ly

188 We find that attractions between heterochromatic regions are crucial for establishing bot

189 sites of transcription; however, as not all heterochromatic regions are equally active in transcript

190 d modelling suggest that attractions between heterochromatic regions are essential for the phase sepa

191 Non-coding RNAs generated from heterochromatic regions are processed into small RNAs by

192 and other chromosomes containing specialized heterochromatic regions called knobs.

193 genome assembly correspond to multi-megabase heterochromatic regions composed primarily of two relate

194 nded breaks and contributes to repair within heterochromatic regions during G2.

195 range interactions such as those among small heterochromatic regions embedded in euchromatic arms.

196 ed chromosome arms while it was inhibited in heterochromatic regions encompassing pericentromeric DNA

197 aled that sequences located within different heterochromatic regions have distinct properties, such a

198 enomic landscape of histone modifications in heterochromatic regions have revealed histone H3 lysine

199 st size of centromeres and their surrounding heterochromatic regions impede studies of genomic variat

200 lex incorporates the histone variant H3.3 at heterochromatic regions in a replication-independent man

201 cer regions in MBC-like WM and repressed and heterochromatic regions in PC-like WM.

202 ed (ORCA/LRWD1), preferentially localizes to heterochromatic regions in post-replicated cells.

203 l properties associated with euchromatic and heterochromatic regions in the genome.

204 To identify heterochromatic regions in the heavily studied model C.

205 Representation of the Y chromosome and other heterochromatic regions is particularly improved.

206 mulation of H2A.Z genome-wide, especially at heterochromatic regions normally H2A.Z-depleted in wild-

207 epeated DNAs, or satellites, are enriched in heterochromatic regions of eukaryotic genomes and contri

208 Heterochromatic regions of the genome are generally tran

209 gregation of active euchromatic and inactive heterochromatic regions of the genome(1,2).

210 ory elements to new locations, most often to heterochromatic regions of the genome.

211 stone H2A variant that is typically found in heterochromatic regions of the genome.

212 single-nucleotide alterations, primarily in heterochromatic regions of the genome.

213 hat loss of Vgl1 impairs Clr4 recruitment to heterochromatic regions of the genome.

214 1s are enriched at lamin-associated domains, heterochromatic regions of the nuclear periphery.

215 slow kinetics, including those localizing to heterochromatic regions or harboring additional lesions

216 ion is lost and is only restored in specific heterochromatic regions that have maintained competence

217 In this paper we show that tethering of heterochromatic regions to nuclear landmarks and random

218 f chromatin accessibility in euchromatic and heterochromatic regions under extended darkness in Arabi

219 n neurons and testes, often localized within heterochromatic regions, and important for viability.

220 he transcriptionally inert, late-replicating heterochromatic regions, including the constitutive hete

221 >0.10 was 95% and 91% in the euchromatic and heterochromatic regions, respectively.

222 tromeric regions, even including some of the heterochromatic regions, which are not present in gold s

223 uracil in the late replicating constitutive heterochromatic regions, while drug treatment induced a

224 sperm cells, 24-nt siRNAs were spread across heterochromatic regions, while in egg cells, 24-nt siRNA

225 de novo heterochromatin formation at native heterochromatic regions.

226 phisms (SNPs) from euchromatic and 1000 from heterochromatic regions.

227 fied the flanking sequence of breakpoints in heterochromatic regions.

228 oading factor (Nipped-B/NIPBL/Scc2) at dense heterochromatic regions.

229 atabase to further enable genomic studies of heterochromatic regions.

230 senting the endogenous centromeres and other heterochromatic regions.

231 lacking Ubp3 than in wild-type cells in all heterochromatic regions.

232 methylation and epigenetic gene silencing in heterochromatic regions.

233 H3K9me2, that mainly silences transposons in heterochromatic regions.

234 h transcript by associating with an intronic heterochromatic repeat element of IBM1.

235 criptional silencing of retrotransposons and heterochromatic repeats in plants.

236 significant differences in the stability of heterochromatic repression between various environmental

237 pression in human myeloid progenitors causes heterochromatic repression of NFI-A gene and channels gr

238 The ability to monitor fluctuations in heterochromatic repression uncovered previously unapprec

239 netic assay reveals that transient losses of heterochromatic repression, a heritable form of gene sil

240 show sporadic waves of silencing loss in the heterochromatic ribosomal DNA during the early phases of

241 and Keller et al. show distinct outcomes for heterochromatic RNAs that bind different chromodomain pr

242 ings reveal a new pathway for degradation of heterochromatic RNAs with essential roles in heterochrom

243 to heterochromatin, lead to accumulation of heterochromatic RNAs, and block spreading of H3K9me and

244 tion in differentiated cells, where it binds heterochromatic satellite repeats and chromocenters.

245 lication-where replication of constitutively heterochromatic satellite sequences is delayed-extends S

246 evance, including the preferred locations of heterochromatic satellites of different chromosomes, and

247 adults, suggesting that desilencing of many heterochromatic segments of the genome contributes to st

248 not sufficient to induce the same events in heterochromatic segments.

249 to position unmapped Drosophila melanogaster heterochromatic sequence to specific chromosomal regions

250 We find that heterochromatic sequences preferentially require DDM1 fo

251 e also identified and mapped 110 kb of novel heterochromatic sequences.

252 ork confirms that this important but elusive heterochromatic sex chromosome is evolving extremely rap

253 leotide microRNAs (miRNAs) and 24-nucleotide heterochromatic short interfering RNAs (siRNAs).

254 How the heterochromatic silenced loci are transcribed remains la

255 ained both by transposons to evade long-term heterochromatic silencing and by their hosts for genome

256 , intergenic transcriptional enhancers evade heterochromatic silencing and converge into interchromos

257 tiotemporal transcription factor coordinates heterochromatic silencing and male germline maturation.

258 TRX, are required for H3.3 incorporation and heterochromatic silencing at telomeres, pericentromeres,

259 that Spt6 is required for multiple steps in heterochromatic silencing by controlling chromatin, tran

260 iquitinase (DUB) Ubp10 is thought to promote heterochromatic silencing by maintaining low H2B-Ub at s

261 ts in changes of H3K9 methylation levels and heterochromatic silencing defects.

262 a challenge to SIR complex-mediated de novo heterochromatic silencing due to the presence of antagon

263 ARID1 in the generative cell causes reduced heterochromatic silencing in both bicellular and mature

264 e male germline, resulting in the release of heterochromatic silencing in the male germline.

265 itosis, mediates siRNA movement to reinforce heterochromatic silencing in the male germline.

266 regions and variant gene expression based on heterochromatic silencing is observed only in some genes

267 Budding yeast heterochromatic silencing is strictly dependent on the s

268 A prevalent view of heterochromatic silencing is that these and associated f

269 of Dos1 identifies key residues required for heterochromatic silencing, consistent with Dos1's role a

270 Surprisingly, even though qrf is needed for heterochromatic silencing, induction of qrf initially pr

271 mere length homeostasis of ESCs by mediating heterochromatic silencing.

272 nfigurations of nucleosome arrays facilitate heterochromatic silencing.

273 tion and histone H3 Lys-9 dimethylation, but heterochromatic siRNA levels were not affected.

274 ted nucleotides of 23 nt siRNAs arising from heterochromatic siRNA loci.

275 ay result from modifications added to longer heterochromatic siRNA precursors.

276 As (miRNAs), trans-acting siRNAs (tasiRNAs), heterochromatic siRNAs (hc-siRNAs) populations and their

277 In plants, 24 nucleotide long heterochromatic siRNAs (het-siRNAs) transcriptionally re

278 Heterochromatic siRNAs are derived from repetitive regio

279 However, non-templated nucleotides in plant heterochromatic siRNAs have not been deeply studied, esp

280 The existence and extent of heterochromatic siRNAs in other land plant lineages has

281 We conclude that heterochromatic siRNAs, and their biogenesis pathways, a

282 leaching measurements, which showed that, at heterochromatic sites, wild-type HELLS is very dynamic,

283 that the majority of the genome exists in a heterochromatic state defined by inaccessible chromatin

284 gradation to initiate destabilization of the heterochromatic state of endogenous silenced loci.

285 We show that the normal heterochromatic state of the donors does not impair dono

286 NA pathway components are abundant, with the heterochromatic state subsequently propagated by chromat

287 gh level of DNA polymorphisms and from their heterochromatic state, notably their dense DNA methylati

288 er of repeat copies can nucleate a transient heterochromatic state, which, on longer repeat arrays, m

289 ions and independent pathways to arrive at a heterochromatic state.

290 s and promoting a switch from euchromatic to heterochromatic states.

291 t function of H3.3 is to support chromosomal heterochromatic structures, thus maintaining genome inte

292 Here we show that about 100 heterochromatic TEs are activated in VCs, mostly by DEME

293 In ddm1 mutants, stress hyperactivates heterochromatic transcription and transcription persists

294 e release of transposable elements and other heterochromatic transcripts.

295 ly transcribed regions, cooperate to silence heterochromatic transcripts.

296 RNAs derive from dual-strand piRNA clusters, heterochromatic transposon graveyards that are transcrib

297 ve cells, likely reflecting transcription of heterochromatic transposons in this cell type.

298 sposons and repeats, as well as silencing of heterochromatic transposons.

299 In P. falciparum, the heterochromatic virulence gene cluster had a strong repr

300 HP1D2 accumulates on the heterochromatic Y chromosome in male germ cells, strongl