Sex chromosome inactivation in the male

Mammalian females have two X chromosomes, while males have only one X plus a Y chromosome. In order to balance X-linked gene dosage between the sexes, one X chromosome undergoes inactivation during development of female embryos. This process has been termed X-chromosome inactivation (XCI). Inactivation of the single X chromosome also occurs in the male, but is transient and is confined to the late stages of first meiotic prophase during spermatogenesis. This phenomenon has been termed meiotic sex chromosome inactivation (MSCI). A substantial portion (~15-25%) of X-linked mRNA-encoding genes escapes XCI in female somatic cells. While no mRNA genes are known to escape MSCI in males, ~80% of X-linked miRNA genes have been shown to escape this process. Recent results have led to the proposal that the RNA interference mechanism may be involved in regulating XCI in female cells. We suggest that some MSCI-escaping miRNAs may play a similar role in regulating MSCI in male germ cells.     

Live imaging of X chromosome inactivation and reactivation dynamics

The epigenetic phenomenon called X chromosome inactivation plays critical roles in female development in eutherian mammals, and has attracted attention in the fields of developmental biology and regenerative biology in efforts to understand the pluripotency of stem cells. X chromosome inactivation is routinely studied after cell fixation, but live imaging is increasingly being required to improve our understanding of the dynamics and kinetics of X chromosome inactivation and reactivation processes. Here, we describe our live imaging method to monitor the epigenetic status of X chromosomes using a gene knock‐in mouse strain named “Momiji” and give an overview of the application of this strain as a resource for biological and stem cell research.     

Imprint switching for non-random X-chromosome inactivation during mouse oocyte growth

In mammals, X-chromosome inactivation occurs in all female cells, leaving only a single active X chromosome. This serves to equalise the dosage of X-linked genes in male and female cells. In the mouse, the paternally derived X chromosome (X(P)) is imprinted and preferentially inactivated in the extraembryonic tissues whereas in the embryonic tissues inactivation is random. To investigate how X(P) is chosen as an inactivated X chromosome in the extraembryonic cells, we have produced experimental embryos by serial nuclear transplantation from non-growing (ng) oocytes and fully grown (fg) oocytes, in which the X chromosomes are marked with (1) an X-linked lacZ reporter gene to assay X-chromosome activity, or (2) the Rb(X.9)6H translocation as a cytogenetic marker for studying replication timing. In the extraembryonic tissues of these ng/fg embryos, the maternal X chromosome (X(M)) derived from the ng oocyte was preferentially inactivated whereas that from the fg oocyte remained active. However, in the embryonic tissues, X inactivation was random. This suggests that (1) a maternal imprint is set on the X(M) during oocyte growth, (2) the maternal imprint serves to render the X(M) resistant to inactivation in the extraembryonic tissues and (3) the X(M) derived from an ng oocyte resembles a normal X(P).     

De novo DNA methylation independent establishment of maternal imprint on X chromosome in mouse oocytes

In female mouse embryos, the paternal X chromosome (Xp) is preferentially inactivated during preimplantation development and trophoblast differentiation. This imprinted X-chromosome inactivation (XCI) is partly due to an activating imprint on the maternal X chromosome (Xm), which is set during oocyte growth. However, the nature of this imprint is unknown. DNA methylation is one candidate, and therefore we examined whether disruptions of the two de novo DNA methyltransferases in growing oocytes affect imprinted XCI. We found that accumulation of histone H3 lysine-27 trimethylation, a hallmark of XCI, occurs normally on the Xp, and not on the Xm, in female blastocysts developed from the mutant oocytes. Furthermore, the allelic expression patterns of X-linked genes including Xist and Tsix were unchanged in preimplantation embryos and also in the trophoblast. These results show that a maternal disruption of the DNA methyltransferases has no effect on imprinted XCI and argue that de novo DNA methylation is dispensable for Xm imprinting. This underscores the difference between imprinted XCI and autosomal imprinting.     

Sex chromosome homology and incomplete, tissue-specific X-inactivation suggest that monotremes represent an intermediate stage of mammalian sex chromosome evolution

Female mammals have two X chromosomes and males have a single X and a smaller, male-determining Y chromosome. The dosage of X-linked gene products is equalized between the sexes by the genetic inactivation of one X chromosome in females. The characteristics of the mechanism of X-chromosome inactivation differ in eutherian and metatherian mammals, and it has been suggested that the metatherian system represents a more primitive stage. The present study of monotreme sex chromosomes and X-chromosome inactivation suggests that the prototherian mammals may represent an even more primitive stage. There is extensive G-band homology between the monotreme X and Y chromosomes, and differences in the patterns of replication of the two X chromosomes in females suggest that X inactivation is tissue specific and confined to the unpaired segment of the X. On the basis of these results, we propose a model for the differentiation of mammalian sex chromosomes and the evolution of the mechanism of X-chromosome inactivation. This model involves a gradual reduction of the Y chromosome and an accompanying gradual recruitment of (newly unpaired) X-linked loci under the control of a single inactivation center.     

Visualization of inactive X chromosome in preimplantation embryos utilizing MacroH2A–EGFP transgenic mouse

One of the two X chromosomes is inactivated in female eutherian mammals. MacroH2A, an unusual histone variant, is known to accumulate on the inactive X chromosome (Xi) during early embryo development, and can thus be used as a marker of the Xi. In this study, we produced a transgenic mouse line expressing the mouse MacroH2A1.2–enhanced green fluorescent protein (EGFP) fusion protein (MacroH2A–EGFP) under the control of a CAG promoter and verified whether MacroH2A–EGFP would be useful for tracing the process of X chromosome inactivation by visualizing Xi noninvasively in preimplantation embryos. In transgenic female mice, MacroH2A–EGFP formed a fluorescent focus in nuclei throughout the body. In female blastocysts, the MacroH2A–EGFP focus colocalized with Xist RNA, well known as a marker of Xi. Fluorescence marking of Xi was first observed in some embryonic cells between the 4‐ and 8‐cell stages. These results demonstrate that MacroH2A can bind to the Xi by around the 8‐cell stage in female mouse embryos. These MacroH2A–EGFP transgenic mice might be useful to elucidate the process of X chromosome inactivation during the mouse life cycle. genesis 51:259–267. © 2013 Wiley Periodicals, Inc.     

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.     

哺乳动物X染色体失活机制

哺乳动物X染色体连锁基因的剂量平衡,是通过雌性胚胎发育早期随机或印记失活一条X染色体来实现的,这是一个复杂的过程,包括：启动、计数、选择、维持等一系列的步骤。X染色体失活中心是X染色体失活的主控开关座位,调节X失活的早期事件,失活发生后,X染色体的失活状态可稳定地存在并传递给后代,这一过程涉及基因组印记的形成。此外,在雄性动物,精原细胞减数分裂早期也存在着短暂的X染色体失活现象。现对哺乳动物X染色体失活机制的最新进展进行综述。     

Genomic imprinting: male mice with uniparentally derived sex chromosomes

Although it has been known that there is an X-chromosome imprinting effect during early embryogenesis in female mammals, it remains unknown if parental origin of the X chromosome has an effect in males. Furthermore, it has not been possible to produce animals with normal sex chromosomes of uniparental origin to further evaluate such imprinting effects. We have devised a breeding scheme to produce male mice, designated XPYP males, in which both the X and Y chromosomes are paternally inherited. To our knowledge, these are the first mammals produced that have a normal sex chromosome constitution but with both sex chromosomes derived from one parent. Development and reproduction in these XPYP males and the sex ratio and chromosome constitution of their offspring appeared normal; thus there is no apparent effect in males of having both sex chromosomes derive from one parent or of having the X chromosome derived from an inappropriate parent. Although we have detected no X-chromosome imprinting effect in these males, evidence from other sources suggest that the X chromosome is parentally imprinted. Thus detection and definition of an imprint can depend on the assay used.     

Meiotic sex chromosome inactivation

X chromosome inactivation is most commonly studied in the context of female mammalian development, where it performs an essential role in dosage compensation. However, another form of X-inactivation takes place in the male, during spermatogenesis, as germ cells enter meiosis. This second form of X-inactivation, called meiotic sex chromosome inactivation (MSCI) has emerged as a novel paradigm for studying the epigenetic regulation of gene expression. New studies have revealed that MSCI is a special example of a more general mechanism called meiotic silencing of unsynapsed chromatin (MSUC), which silences chromosomes that fail to pair with their homologous partners and, in doing so, may protect against aneuploidy in subsequent generations. Furthermore, failure in MSCI is emerging as an important etiological factor in meiotic sterility.     

New lessons from random X-chromosome inactivation in the mouse

X-chromosome inactivation (XCI) ensures dosage compensation in mammals. Random XCI is a process where a single X chromosome is silenced in each cell of the epiblast of mouse female embryos. Operating at the level of an entire chromosome, XCI is a major paradigm for epigenetic processes. Here we review the most recent discoveries concerning the role of long noncoding RNAs, pluripotency factors, and chromosome structure in random XCI.     

Unexpected X chromosome skewing during culture and reprogramming of human somatic cells can be alleviated by exogenous telomerase

Somatic tissues in female eutherian mammals are mosaic due to random X inactivation. In contrast to mice, X chromosome reactivation does not occur during the reprogramming of human female somatic cells to induced pluripotent stem cells (iPSCs), although this view is contested. Using balanced populations of female Rett patient and control fibroblasts, we confirm that all cells in iPSC colonies contain an inactive X, and additionally find that all colonies made from the same donor fibroblasts contain the same inactive X chromosome. Notably, this extreme "skewing" toward a particular dominant, active X is also a general feature of primary female fibroblasts during proliferation, and the skewing seen in reprogramming and fibroblast culture can be alleviated by overexpression of telomerase. These results have important implications for in?vitro modeling of X-linked diseases and the interpretation of long-term culture studies in cancer and senescence using primary female fibroblast cell lines.