Population Structure of Morphological Traits in Clarkia Dudleyana I. Comparison of F(st) between Allozymes and Morphological Traits

The X-linked white gene when transposed to autosomes retains only partial dosage compensation. One copy of the gene in males expresses more than one copy but less than two copies in females. When inserted in ectopic X chromosome sites, the mini-white gene of the CaspeR vector can be fully dosage compensated and can even achieve hyperdosage compensation, meaning that one copy in males gives more expression than two copies in females. As sequences are removed gradually from the 5' end of the gene, we observe a progressive transition from hyperdosage compensation to full dosage compensation to partial dosage compensation. When the deletion reaches -17, the gene can no longer dosage compensate fully even on the X chromosome. A deletion reaching +173, 4 bp preceeding the AUG initiation codon, further reduces dosage compensation both on the X chromosome and on autosomes. This truncated gene can still partially dosage compensate on autosomes, indicating the presence of dosage compensation determinants in the protein coding region. We conclude that full dosage compensation requires an X chromosome environment and that the white gene contains multiple dosage-compensation determinants, some near the promoter and some in the coding region.     

Guilt by association: non-coding RNAs, chromosome-specific proteins and dosage compensation in Drosophila.

Dosage compensation is a striking example of the interplay between gene-specific regulation and chromosomal architecture. This process has evolved to make X-linked gene expression equivalent in males with one X chromosome and females with two. Examining species at the molecular level has shown that dosage compensation is mediated by sex-specific factors that decorate the X chromosomes to regulate chromatin structure and gene expression. In Drosophila, dosage compensation is achieved, at least in part, through site-specific histone H4 acetylation, which is modulated by a male- and X-specific protein complex. The discovery of non-coding RNAs that 'paint' dosage-compensated X chromosomes in mammals and in Drosophila suggests that RNAs play an intriguing, unexpected role in the regulation of chromatin structure and gene expression.     

Mammalian X Chromosome Dosage Compensation: Perspectives From the Germ Line

Sex chromosomes are advantageous to mammals, allowing them to adopt a genetic rather than environmental sex determination system. However, sex chromosome evolution also carries a burden, because it results in an imbalance in gene dosage between females (XX) and males (XY). This imbalance is resolved by X dosage compensation, which comprises both X chromosome inactivation and X chromosome upregulation. X dosage compensation has been well characterized in the soma, but not in the germ line. Germ cells face a special challenge, because genome wide reprogramming erases epigenetic marks responsible for maintaining the X dosage compensated state. Here we explain how evolution has influenced the gene content and germ line specialization of the mammalian sex chromosomes. We discuss new research uncovering unusual X dosage compensation states in germ cells, which we postulate influence sexual dimorphisms in germ line development and cause infertility in individuals with sex chromosome aneuploidy.     

Silence of the fathers: early X inactivation

X chromosome inactivation is the mammalian answer to the dilemma of dosage compensation between males and females. The study of this fascinating form of chromosome-wide gene regulation has yielded surprising insights into early development and cellular memory. In the past few months, three papers reported unexpected findings about the paternal X chromosome (X(p)). All three studies agree that the X(p) is imprinted to become inactive earlier than ever suspected during embryonic development. Although apparently incomplete, this early form of inactivation insures dosage compensation throughout development. Silencing of the X(p) persists in cells of extraembryonic tissues, but it is erased and followed by random X inactivation in cells of the embryo proper. These findings challenge several aspects of the current view of X inactivation during early development and may have profound impact on studies of pluripotency and epigenetics.     

X染色体的剂量补偿机制

剂量补偿机制(Dosage compensation mechanism)是雌性和雄性X染色体表达平衡的关键,保证两性间由X染色体编码的蛋白质或其他酶类物质在数量上达到平衡。不同生物的剂量补偿机制各不相同,迄今研究表明剂量补偿机制主要有以下3种模式:通过雄性的单个X染色体表达加倍;通过雌性的一条X染色体失活;通过雌性的两个X染色体的表达减半来达到平衡。对剂量补偿的研究有助于揭示X连锁基因的调控机理、性染色体的进化和分化过程,以及解释性染色体畸变的机理,因此,文章将对这种重要的调控机制研究现状及进展进行简要论述。     

The Drosophila GAGA factor is required for dosage compensation in males and for the formation of the male-specific-lethal complex chromatin entry site at 12DE

Drosophila melanogaster males have one X chromosome, while females have two. To compensate for the resulting disparity in X-linked gene expression between the two sexes, most genes from the male X chromosome are hyperactivated by a special dosage compensation system. Dosage compensation is achieved by a complex of at least six proteins and two noncoding RNAs that specifically associate with the male X. A central question is how the X chromosome is recognized. According to a current model, complexes initially assemble at approximately 35 chromatin entry sites on the X and then spread bidirectionally along the chromosome where they occupy hundreds of sites. Here, we report that mutations in Trithorax-like (Trl) lead to the loss of a single chromatin entry site on the X, male lethality, and mislocalization of dosage compensation complexes.