Expression of Xist RNA is sufficient to initiate macrochromatin body formation.

MacroH2A1 is a histone variant that is found as a component of the inactive X chromosome where it is detected as a dense accumulation called a macrochromatin body (MCB). Macrochromatin bodies co-localize with Xist RNA, which is an untranslated RNA that is expressed exclusively from the inactive X chromosome of placental mammals. However, no studies to date have investigated whether Xist RNA expression is necessary or sufficient to cause the formation of MCBs. Here we show that expression of Xist RNA is sufficient to cause the formation of MCBs even when Xist is expressed from an inducible transgene at ectopic autosomal sites. Macrochromatin bodies form at sites of transgenic Xist expression in differentiating mouse ES cell lines and transgenic fibroblasts, but MCBs cannot form in undifferentiated ES cells even after prolonged Xist expression. The kinetics of MCB formation revealed that Xist expression precedes MCB formation and that differentiating ES cells undergo a rapid and synchronous transition that renders them competent to form MCBs. Once MCBs have formed, continued expression of Xist is required for their maintenance. These results show that Xist RNA and macroH2A1 function in a common pathway. Expression of Xist in a permissive nuclear environment is sufficient to initiate a chromatin-remodeling event culminating in the incorporation of macroH2A1. The results also strongly suggest the existence of additional regulatory factors for X inactivation that are regulated developmentally. In addition, we present evidence that macroH2A1 density is not simply a measure of the general degree of DNA compaction.

Centrosomal association of histone macroH2A1.2 in embryonic stem cells and somatic cells.

The histone 2A variant macroH2A1.2 is expressed in female and male mammals and is implicated in X-chromosome inactivation and autosomal gene silencing. In undifferentiated and early differentiating murine embryonic stem (ES) cells a cytosolic pool of macroH2A1.2 has recently been reported and found to be associated with the centrosome. Here, we show that the centrosomal association of macroH2A1.2 is a widespread phenomenon and is not restricted to undifferentiated and early differentiating ES cells. By indirect immunofluorescence we detect macroH2A1.2 protein in a juxtanuclear structure that duplicates once per cell cycle and colocalizes with centrosomal gamma-tubulin in both XX and XY ES cells prior to and throughout their differentiation. MacroH2A1.2 localization to the centrosome is also observed in female and male somatic cells, both in interphase and in mitosis. Biochemical analysis demonstrates that the association between macroH2A1.2 and the centrosome in somatic cells is stable, as macroH2A1.2 copurifies with centrosomes isolated from human lymphoblasts. Therefore, in addition to a nuclear pool of macroH2A1.2 a fraction of the histone is associated with the centrosome in various cell types and throughout ES cell differentiation.

MACROH2A2, a new member of the MARCOH2A core histone family.

MACROH2As are core histones that have a unique hybrid structure consisting of an amino-terminal domain that closely resembles a full-length histone H2A followed by a large nonhistone region. The human MACROH2A1 gene, on chromosome 5, encodes two MACROH2A subtypes, MACROH2A1.1 and MACROH2A1.2, produced by alternate splicing. Here we report the identification of MACROH2A2, a new MACROH2A subtype encoded by a separate gene on human chromosome 10, MACROH2A2. The amino acid sequence of human MACROH2A2 is 68% identical to human MACROH2A1.2. We show by immunofluorescence on mouse tissue sections that MACROH2A2, like MACROH2A1.2, is concentrated in the inactive X chromosome. However, MACROH2A2 has a very different pattern of expression in the cell types present in the liver and kidney. When MACROH2A2 and MACROH2A1.2 are present in the same nucleus, they have a similar, though nonidentical, pattern of localization, with both subtypes present in the inactive X chromosome. Our results suggest a developmental role for MACROH2A subtypes.

Dynamic relocalization of histone MacroH2A1 from centrosomes to inactive X chromosomes during X inactivation.

Histone variant macroH2A1 (macroH2A1) contains an NH(2)-terminal domain that is highly similar to core histone H2A and a larger COOH-terminal domain of unknown function. MacroH2A1 is expressed at similar levels in male and female embryonic stem (ES) cells and adult tissues, but a portion of total macroH2A1 protein localizes to the inactive X chromosomes (Xi) of differentiated female cells in concentrations called macrochromatin bodies. Here, we show that centrosomes of undifferentiated male and female ES cells harbor a substantial store of macroH2A1 as a nonchromatin-associated pool. Greater than 95% of centrosomes from undifferentiated ES cells contain macroH2A1. Cell fractionation experiments confirmed that macroH2A1 resides at a pericentrosomal location in close proximity to the known centrosomal proteins gamma-tubulin and Skp1. Retention of macroH2A1 at centrosomes was partially labile in the presence of nocodazole suggesting that intact microtubules are necessary for accumulation of macroH2A1 at centrosomes. Upon differentiation of female ES cells, Xist RNA expression became upregulated and monoallelic as judged by fluorescent in situ hybridization, but early Xist signals lacked associated macroH2A1. Xi acquired macroH2A1 soon thereafter as indicated by the colocalization of Xist RNA and macroH2A1. Accumulation of macroH2A1 on X chromosomes occurred with a corresponding loss of centrosomal macroH2A1. Our results define a sequence for the loading of macroH2A1 on the Xi and place this event in the context of differentiation and Xist expression. Furthermore, these results suggest a role for the centrosome in the X inactivation process.

XIST RNA associates with specific regions of the inactive X chromatin.

Microscopy studies have shown that XIST RNA colocalizes with the inactive X chromosome (Xi). However, the molecular basis for this colocalization is unknown. Here we provide two lines of evidence from chromatin immunoprecipitation experiments that XIST RNA physically associates with the Xi chromatin. First, XIST RNA can be co-precipitated by antiserum against macroH2A, a histone H2A variant enriched in the Xi. Second, XIST RNA can be co-precipitated by antisera that recognize unacetylated, but not acetylated, isoforms of histones H3 and H4. The specificity of XIST RNA association with hypoacetylated chromatin, together with the previous finding that hypoacetylated histone H4 is enriched at promoters of X-inactivated genes, raises the possibility that XIST RNA may contribute to the hypoacetylation of specific regions of the Xi so as to alter the expression of X-linked genes.

Histone macroH2A1.2 is concentrated in the XY-body by the early pachytene stage of spermatogenesis.

The pairing of sex chromosomes during meiosis in male mammals is associated with ongoing heterochromatinization and X inactivation. This process occurs in a specific area of the nucleus that can be discerned morphologically: the sex vesicle or XY-body. In contrast to X inactivation in the somatic cells of female mammals the reasons for X inactivation in the male germline remain obscure. We have recently demonstrated that the inactive X chromosome in somatic cells of female mammals is marked by a high concentration of histone macroH2A. Here we investigate X inactivation in the meiotic cells of the male germline. We demonstrate here that macroH2A1.2 is present in the nuclei of germ cells starting first with localization that is largely, if not exclusively, to the developing XY-body in early pachytene spermatocytes. Our results suggest that inactivation of sex chromosomes in the male germ cell includes a major alteration of the nucleosomal structure.

Histone macroH2A1 is concentrated in the inactive X chromosome of female preimplantation mouse embryos.

MacroH2As are core histone proteins with a hybrid structure consisting of a domain that closely resembles a full-length histone H2A followed by a large nonhistone domain. We recently showed that one of the macroH2A subtypes, macroH2A1.2, is concentrated in the inactive X chromosome in adult female mammals. Here we examine the timing of the association of macroH2A1.2 with the inactive X chromosome during preimplantation mouse development in order to assess the possibility that macroH2A1 participates in the initiation of X inactivation. The association of macroH2A1.2 with one of the X chromosomes was observed in 50% of blastocysts, occurring mostly, if not exclusively, in extraembryonic cells as was expected from previous studies, which indicated that X inactivation in embryonic lineages happens after implantation. Examination of earlier embryonic stages indicates that the association of macroH2A1 with the inactive X chromosome begins between the 8- and 16-cell stages. Of the changes that are known to happen during X inactivation in preimplantation embryos, the accumulation of macroH2A1 appears to be the earliest marker of the inactive X chromosome and is the only change that has been shown to occur during the period when transcriptional silencing is initiated.

Pyrimidine dimer formation as a probe of nucleosome core and linker structure in situ.

The photoinduced dimerization of adjacent pyrimidines in DNA is influenced in predictable ways by DNA conformation. A method is described for determining patterns of pyrimidine dimer formation under conditions in which the chromatin is minimally perturbed. The relation of such patterns to the conformation of nucleosomal core DNA and linker DNA, as well as the interaction of histone H1 with nucleosomal DNA, is presented. Such data indicate that sharp bends in the path of DNA seen in crystals of isolated nucleosome core particles are also present in intact chromatin. They also indicate that most of the linker has very little curvature except for a small bend at its junction with the nucleosome core. The linker path inferred from such experiments supports models in which the chromatin fiber consists of a zigzag chain of nucleosomes.

Histone macroH2A1.2 relocates to the inactive X chromosome after initiation and propagation of X-inactivation.

The histone macroH2A1.2 has been implicated in X chromosome inactivation on the basis of its accumulation on the inactive X chromosome (Xi) of adult female mammals. We have established the timing of macroH2A1.2 association with the Xi relative to the onset of X-inactivation in differentiating murine embryonic stem (ES) cells using immuno-RNA fluorescence in situ hybridization (FISH). Before X-inactivation we observe a single macroH2A1.2-dense region in both undifferentiated XX and XY ES cells that does not colocalize with X inactive specific transcript (Xist) RNA, and thus appears not to associate with the X chromosome(s). This pattern persists through early stages of differentiation, up to day 7. Then the frequency of XY cells containing a macroH2A1.2-rich domain declines. In contrast, in XX cells there is a striking relocalization of macroH2A1.2 to the Xi. Relocalization occurs in a highly synchronized wave over a 2-d period, indicating a precisely regulated association. The timing of macroH2A1.2 accumulation on the Xi suggests it is not necessary for the initiation or propagation of random X-inactivation.

Evolutionary conservation of histone macroH2A subtypes and domains.

Histone macroH2A is an unusual core histone that contains a large non-histone region, and a region that resembles a full length H2A. We examined theconservation of this novel structural arrangement by cloning chicken macroH2A cDNAs and comparing them to their rat counterparts. The amino acid sequences of the two known macroH2A subtypes are >95% identical between these species despite evolutionary separation of approximately 300 million years. The H2A region of macroH2A is completely conserved, and thus is even more conserved than conventional H2A in these species. The origin of the non-histone domain was examined by comparing its sequence to proteins found in bacteria and RNA viruses. These comparisons indicate that this domain is derived from a gene that originated prior to the appearance of eukaryotes, and suggest that the non-histone region has retained the basic function of its ancestral gene.

Histone macroH2A1 is concentrated in the inactive X chromosome of female mammals.

In female mammals one of the X chromosomes is rendered almost completely transcriptionally inactive to equalize expression of X-linked genes in males and females. The inactive X chromosome is distinguished from its active counterpart by its condensed appearance in interphase nuclei, late replication, altered DNA methylation, hypoacetylation of histone H4, and by transcription of a large cis-acting nuclear RNA called Xist. Although it is believed that the inactivation process involves the association of specific protein(s) with the chromatin of the inactive X, no such proteins have been identified. We discovered a new gene family encoding a core histone which we called macroH2A (mH2A). The amino-terminal third of mH2A proteins is similar to a full-length histone H2A, but the remaining two-thirds is unrelated to any known histones. Here we show that an mH2A1 subtype is preferentially concentrated in the inactive X chromosome of female mammals. Our results link X inactivation with a major alteration of the nucleosome, the primary structural unit of chromatin.

Developmental and tissue expression patterns of histone macroH2A1 subtypes.

MacroH2A is a novel nucleosomal core histone that contains a large nonhistone region and a region that closely resembles a full length histone H2A. We have cloned a cDNA that contains the entire coding region of macroH2A1.2, one of the two identified subtypes of macroH2A1. MacroH2A1.2 was found to differ from the other known subtype, macroH2A1.1, in a single segment of the nonhistone region. MacroH2A1 specific antibodies revealed relatively high levels of both subtypes in adult liver and kidney. MacroH2A1.1 was much lower in fetal liver and kidney in comparison to their adult counterparts, and was not detected in adult thymus and testis, tissues with active cell division and differentiation. Both subtypes were present at very low levels or absent from mouse embryonic stem cells maintained in an undifferentiated state by growth in the presence of leukemia inhibitory factor. MacroH2A1.2 increased when the embryonic stem cells were induced to differentiate in vitro, while macroH2A1.1 remained undetectable. These results support the idea that macroH2A1.1 and macroH2A1.2 are functionally distinct, and suggest that changes in their expression may play a role in developmentally regulated changes in chromatin structure and function.

Probing the conformation of nucleosome linker DNA in situ with pyrimidine dimer formation.

The distribution of pyrimidine dimers formed in nucleosomal DNA by irradiation of intact nuclei isolated from rat liver has been examined. Whereas pyrimidine dimer formation in the core region of the nucleosome occurred with peaks at approximately 10-nucleotide intervals as previously reported, the distribution of pyrimidine dimers through the linker region was nearly uniform. This distinction between core and linker DNA was found to be independent of linker length over a range of 38-60 nucleotides. Because there is now ample evidence that DNA curvature is the source of the peaks of pyrimidine dimer formation in the core region, the uniform distribution of pyrimidine dimers observed in the linker region indicates that linker DNA is relatively straight. This suggests that higher order chromatin structure in situ is based on a zigzag chain of nucleosomes.

Crystallization and preliminary X-ray crystallographic studies of nonhistone region of macroH2A.1.

Histone macroH2A has a novel hybrid structure consisting of a large nonhistone region and a region that closely resembles a full-length histone H2A. One key to understanding macroH2A function is determining the structure and function of its nonhistone region. The nonhistone region of one of the two known macroH2A subtypes was expressed in Escherichia coli and purified using affinity and molecular sieve chromatography. Crystals of the protein suitable for structural studies were grown from polyethylene glycol solutions by vapor equilibration techniques. The crystals belong to the hexagonal space group P6(4) (or its enantiomorph P6(2)) with unit cell parameters: a = b = 106.2 A, c = 125.9 A, alpha = beta = 90 degrees, and gamma = 120 degrees. There are four molecules in the asymmetric unit. Self-rotation function studies revealed three twofold noncrystallographic rotation axes related approximately by 222 symmetry. These crystals have 47% solvent content and diffract to 3.8 A resolution.

MacroH2A, a core histone containing a large nonhistone region.

A histone, macroH2A, nearly three times the size of conventional H2A histone, was found in rat liver nucleosomes. Its N-terminal third is 64 percent identical to a full-length mouse H2A. However, it also contains a large nonhistone region. This region has a segment that resembles a leucine zipper, a structure known to be involved in dimerization of some transcription factors. Nucleosomes containing macroH2A may have novel functions, possibly involving interactions with other nuclear proteins.

Effects of DNA looping on pyrimidine dimer formation.

We have assessed the effects of DNA curvature on pyrimidine dimer (PD) formation by examining the pattern of PD formation in DNA held in a loop by lambda repressor. The loop region was composed of diverse DNA sequences such that potential PD sites occurred throughout the loop. PD formation in the loop occurred with peaks at approximately 10 base intervals, just 3' of where the bending of the DNA was inferred to be toward the major groove. This relationship between the peaks and the DNA curvature is essentially identical to that observed in the nucleosome. This indicates that DNA curvature is the major source of the periodicity of PD formation in the nucleosome, and supports an earlier model of the conformation of nucleosomal DNA based on PD formation. DNA loops containing diverse sequences should be of general value for assessing the effects of DNA curvature on DNA modification by other agents used to probe DNA-protein interactions and DNA conformation.

Thymine dimer formation as a probe of the path of DNA in and between nucleosomes in intact chromatin.

Photo-induced thymine dimer formation was used to probe nucleosome structure in nuclei. The distribution of thymine dimers in the nucleosome and recent studies of the structure of thymine dimer-containing DNA suggest that the rate of thymine dimer formation is affected by the direction and degree of DNA bending. This premise was used to construct a model of the path of DNA in the nucleosome, which has the following features. (i) There are four regions of sharp bending, two which have been seen previously by x-ray crystallography of the core particle. (ii) The DNA in H1-containing nucleosomes deviates from its superhelical path near the midpoint; this is not seen with H1-stripped chromatin. (iii) The internucleosomal (linker) DNA appears to be relatively straight.

The fate of the small micromeres in sea urchin development.

We show that in sea urchin embryos, the daughter cells of the small micromeres become part of the coelomic sacs, in contrast to the long-held view that these sacs are purely of macromere origin. In addition, after prolonged mitotic quiescence, and following their incorporation into the coelomic sacs, these cells resume dividing, contrary to the previous view that they do not divide. Since coelomic sac cells give rise to much of the adult urchin, our results indicate that the small micromeres are founders of cell lineages involved in the formation of adult tissues. The setting aside of these cells in a nondividing state may be analogous to a phenomenon in Drosophila development, in which primordial imaginal and germ cells divide approximately once after the blastoderm stage and do not resume dividing until the larval stage.

Distribution of histone H1 alpha among cells of the sea urchin embryo.

We have used immunofluorescent staining of sea urchin embryos to study how histone H1 alpha is distributed among progeny cells formed after the cessation of its synthesis. Our results are consistent with H1 alpha being distributed to both daughter cells at mitosis, resulting in it being most concentrated in cells that stop dividing shortly after H1 alpha synthesis ends, while cells that continue to divide dilute their H1 alpha content in proportion to the number of cell divisions. This rules out our earlier suggestion that H1 alpha becomes segregated in dividing cells. In addition, our results show that most dividing cells of the 3-day embryo contain predominantly H1 beta and H1 gamma. Since these subtypes are known not to undergo phosphorylation, this finding has implications regarding the roles of H1 phosphorylation in the cell cycle.