Sex chromosome evolution: life,death and repetitive DNA

Dimorphic sex chromosomes create problems. Males of many species, including Drosophila, are heterogametic, with dissimilar X and Y chromosomes. The essential process of dosage compensation modulates the expression of X-linked genes in one sex to maintain a constant ratio of X to autosomal expression. This involves the regulation of hundreds of dissimilar genes whose only shared property is chromosomal address. Drosophila males dosage compensate by up regulating X-linked genes 2 fold. This is achieved by the Male Specific Lethal (MSL) complex, which is recruited to genes on the X chromosome and modifies chromatin to increase expression. How the MSL complex is restricted to X-linked genes remains unknown. Recent studies of sex chromosome evolution have identified a central role for 2 types of repetitive elements in X recognition. Helitrons carrying sites that recruit the MSL complex have expanded across the X chromosome in at least one Drosophila species.¹ Our laboratory found that siRNA from an X-linked satellite repeat promotes X recognition by a yet unknown mechanism.² The recurring adoption of repetitive elements as X-identify elements suggests that the large and mysterious fraction of the genome called “junk” DNA is actually instrumental in the evolution of sex chromosomes.     

Implications of the gene balance hypothesis for dosage compensation

Dosage compensation refers to the equal expression between the sexes despite the fact that the dosage of the X chromosome is different in males and females. In Drosophila there is a twofold upregulation of the single male X. In triple X metafemales, there is also dosage compensation, which occurs by a two-thirds downregulation. There is a concomitant reduction in expression of many autosomal genes in metafemales. The male specific lethal (MSL) complex is present on the male X chromosome. Evidence is discussed showing that the MSL complex sequesters a histone acetyltransferase to the X chromosome to mute an otherwise increased expression by diminishing the histone acetylation on the autosomes. Several lines of evidence indicate that a constraining activity occurs from the MSL complex to prevent overcompensation on the X that might otherwise occur from the high level of acetylation present. Together, the evidence suggests that dosage compensation is a modification of a regulatory inverse dosage effect that is a reflection of intrinsic gene regulatory mechanisms and that the MSL complex has evolved in reaction in order to equalize the expression on both the X and autosomes of males and females.     

剂量补偿和MSL复合物研究进展

剂量补偿效应(Dosage compensation effect)广泛存在于两性真核生物,是基于性别决定、平衡不同性别间基因转录水平的遗传效应。MSL复合物(Male-specific lethal complex)是果蝇剂量补偿机制的核心,它乙酰化雄性果蝇X染色体上一些特定的位点,双倍激活X连锁活跃基因的转录,从而弥补雄性果蝇只具有单一条X染色体的不足。目前,已对果蝇MSL复合物各主要成分进行了结构分析,大体了解了各组分间的相互作用位点,并对该复合物的识别机制进行了大量的研究。与果蝇不同,哺乳动物是通过雌性个体一条X染色体的失活来实现剂量补偿。虽然哺乳动物MSL复合物的组成已被鉴定,但对其功能的研究还处于初步阶段。迄今为止,对硬骨鱼类剂量补偿及MSL复合物的研究极少。文章概括了线虫、果蝇和哺乳动物各物种剂量补偿机制的异同,综述了果蝇MSL复合物及其剂量补偿机制作用机理的研究进展,并提出有待解决的问题,同时利用同线性分析发现了不同鱼类msl3基因的多样性,为今后继续研究各物种的剂量补偿机制提供基础资料和研究方向。     

剂量补偿和MSL复合物研究进展

剂量补偿效应(Dosage compensation effect)广泛存在于两性真核生物, 是基于性别决定、平衡不同性别间基因转录水平的遗传效应。MSL复合物(Male-specific lethal complex)是果蝇剂量补偿机制的核心, 它乙酰化雄性果蝇X染色体上一些特定的位点, 双倍激活X连锁活跃基因的转录, 从而弥补雄性果蝇只具有单一条X染色体的不足。目前, 已对果蝇MSL复合物各主要成分进行了结构分析, 大体了解了各组分间的相互作用位点, 并对该复合物的识别机制进行了大量的研究。与果蝇不同, 哺乳动物是通过雌性个体一条X染色体的失活来实现剂量补偿。虽然哺乳动物MSL复合物的组成已被鉴定, 但对其功能的研究还处于初步阶段。迄今为止, 对硬骨鱼类剂量补偿及MSL复合物的研究极少。文章概括了线虫、果蝇和哺乳动物各物种剂量补偿机制的异同, 综述了果蝇MSL复合物及其剂量补偿机制作用机理的研究进展, 并提出有待解决的问题, 同时利用同线性分析发现了不同鱼类msl3基因的多样性, 为今后继续研究各物种的剂量补偿机制提供基础资料和研究方向。     

Karyotype,DNA replication and origin of sex chromosomes in Anopheles atroparvus

Anopheles atroparvus has two pairs of autosomes similar in length and morphology and two sex chromosomes with equal, heterochromatic, late replicating long arms with homologous C-, G-, and Q-bands. The short arm of the Y is shorter than that of the X and both are euchromatic. The mean number of chiasmata per cell in the male is 3.2. During mitosis there is a high grade of somatic pairing but X and Y, which form a heteropycnotic mass in the interphase nucleus, have a differential behaviour. The chronology of DNA replication was studied in spermatogonia and brain cells by autoradiography. It is hypothesized that the present sex chromosomes of A. atroparvus evolved by accumulation of sex determining factors and gene deterioration resulting in heterochromatinization of the long arms, followed by structural rearrangements.—The homology of the two sex chromosomes requires limited dosage compensation which is achieved either as in Drosophila by modifier genes or by accumulation on the short arm of the X, only of female determining factors which do not require dosage compensation.     

Sex,sex chromosomes and gene expression

The X chromosome has fewer testis-specific genes than autosomes in many species. This bias is commonly attributed to X inactivation in spermatogenesis but a recent paper in BMC Biology provides evidence against X inactivation in Drosophila and proposes that somatic tissue- and testis- but not ovary-specific genes tend not to be located on the X chromosome. Here, we discuss possible mechanisms underlying this bias, including sexual antagonism and dosage compensation.     

Dosage Compensation Regulatory Proteins and the Evolution of Sex Chromosomes in Drosophila

In the fruitfly Drosophila melanogaster, the four male-specific lethal (msl) genes are required to achieve dosage compensation of the male X chromosome. The MSL proteins are thought to interact with cis-acting sites that confer dosage compensation to nearby genes, as they are detected at hundreds of discrete sites along the length of the polytene X chromosome in males but not in females. The histone H4 acetylated isoform, H4Ac16, colocalizes with the MSL proteins at a majority of sites on the D. melanogaster X chromosome. Using polytene chromosome immunostaining of other species from the genus Drosophila, we found that X chromosome association of MSL proteins and H4Ac16 is conserved despite differences in the sex chromosome karyotype between species. Our results support a model in which cis-acting regulatory sites for dosage compensation evolve on a neo-X chromosome arm in response to the degeneration of its former homologue.     

Re-evaluation of the function of the male specific lethal complex in Drosophila

A set of proteins and noncoding RNAs,referred to as the male specific lethal (MSL) complex,is present on the male X chromosome in　Drosophila and has been postulated to be responsible for dosage compensation of this chromosome - the up-regulation of its expression to be　equal to that of two X chromosomes in females.This hypothesis is evaluated in view of lesser known aspects of dosage compensation such as the　fact that metafemales with three X chromosomes also have equal expression to normal females,which would require a down-regulation of each　gene copy.Moreover,when this complex is ectopically expressed in females or specifically targeted to a reporter in males,there is no increase in　expression of the genes or targets with which it is associated.These observations are not consistent with the hypothesis that the MSL complex　conditions dosage compensation.A synthesis is described that can account for these observations.     

A new strategy for isolating genes controlling dosage compensation in <Emphasis Type="Italic">Drosophila</Emphasis>using a simple epigenetic mosaic eye phenotype

Background  

The Drosophila Male Specific Lethal (MSL) complex contains chromatin modifying enzymes and non-coding roX RNA. It paints the male X at hundreds of bands where it acetylates histone H4 at lysine 16. This epigenetic mark increases expression from the single male X chromosome approximately twofold above what gene-specific factors produce from each female X chromosome. This equalises X-linked gene expression between the sexes. Previous screens for components of dosage compensation relied on a distinctive male-specific lethal phenotype.     

The rox1 and rox2 RNAs are essential components of the compensasome, which mediates dosage compensation in Drosophila.

The rox1 and rox2 RNAs have been suggested to be components of the dosage compensation machinery in Drosophila. We show that both rox RNAs colocalize with the male-specific lethal proteins at hundreds of specific bands along the male X chromosome. The rox RNAs and MSL proteins also colocalize with the X chromosome in all somatic cells and are expressed in the same temporal pattern throughout development. Genetic analysis shows that the functions of the rox genes are redundant and required for the association of the MSL proteins with the male X chromosome. These data provide compelling evidence for a direct function of the rox RNAs in dosage compensation.     

A Genome-Wide Survey of Sexually Dimorphic Expression of Drosophila miRNAs Identifies the Steroid Hormone-Induced miRNA let-7 as a Regulator of Sexual Identity

MiRNAs bear an increasing number of functions throughout development and in the aging adult. Here we address their role in establishing sexually dimorphic traits and sexual identity in male and female Drosophila. Our survey of miRNA populations in each sex identifies sets of miRNAs differentially expressed in male and female tissues across various stages of development. The pervasive sex-biased expression of miRNAs generally increases with the complexity and sexual dimorphism of tissues, gonads revealing the most striking biases. We find that the male-specific regulation of the X chromosome is relevant to miRNA expression on two levels. First, in the male gonad, testis-biased miRNAs tend to reside on the X chromosome. Second, in the soma, X-linked miRNAs do not systematically rely on dosage compensation. We set out to address the importance of a sex-biased expression of miRNAs in establishing sexually dimorphic traits. Our study of the conserved let-7-C miRNA cluster controlled by the sex-biased hormone ecdysone places let-7 as a primary modulator of the sex-determination hierarchy. Flies with modified let-7 levels present doublesex-related phenotypes and express sex-determination genes normally restricted to the opposite sex. In testes and ovaries, alterations of the ecdysone-induced let-7 result in aberrant gonadal somatic cell behavior and non-cell-autonomous defects in early germline differentiation. Gonadal defects as well as aberrant expression of sex-determination genes persist in aging adults under hormonal control. Together, our findings place ecdysone and let-7 as modulators of a somatic systemic signal that helps establish and sustain sexual identity in males and females and differentiation in gonads. This work establishes the foundation for a role of miRNAs in sexual dimorphism and demonstrates that similar to vertebrate hormonal control of cellular sexual identity exists in Drosophila.