Dosage compensation of sex-linked genes in Drosophila melanogaster. The activities of glucose-6-phosphate dehydrogenase and 6-phosphogluconate dehydrogenase in flies with normal and disturbed genetic balance

Summary The phenomenon of dosage compensation in Drosophila melanogaster which consists in doubling of the activity of the X-chromosome genes in males as compared to those in females was studied.The specific activities of 6-phosphogluconate dehydrogenase (6PGD) and glucose-6-phosphate dehydrogenase (G6PD) determined by the sex-linked structural genes Pgd and Zw respectively were studied in flies carrying duplications for different regions of the X-chromosome. The increase in dose of Pgd and Zw in females resulting from the addition of an extra X-chromosome or X-fragments leads to a proportional rise in the specific activities of 6PGD and G6PD. On the other had the addition to females of the X-chromosome carrying no Pgd gene or X-fragments lacking Pgd and Zw has no effect on the enzyme activities. Thus we failed to reveal in the X-chromosome any compensatory genes envisaged by Muller, which would repress sex-linked structural genes proportional to their dose.The 6PGD and G6PD levels in phenotypically male-like intersexes carrying two X-chromosomes and three autosome sets (2X3A) is 30% higher than in diploid (2X2A) or triploid (3X3A) females. However the specific activities of the enzymes in female-like intersexes are the same as in regular females. The levels of 6PGD and G6PD per one X-chromosome are 1.5–2.0 times higher in the intersexes than in the normal females and metafemales (3X2A). The results indicate that the level of expression of the X-chromosome is determined by the X:A ratio. It is suggested that the decreased X:A ratio in males is responsible for the hyperactivation of their X-chromosomes.     

Expression of cis-regulatory mutations of the white locus in metafemales of Drosophila melanogaster.

At the white eye colour locus, there are a number of alleles that have altered expression between males and females. To test these regulatory mutations of the white eye colour locus for their phenotypic expression in metafemales (3X; 2A) compared to diploid females and males, eleven alleles or transduced copies of white were analysed. Two alleles that exhibit dosage compensation between males and females (apricot, blood) also exhibit dosage compensation in metafemales. White-ivory and white-eosin, which fail to dosage compensate in males compared to females, but that are distinct physical lesions, also show a dosage effect in metafemales. Two alleles with greater expression in males than females (spotted, spotted-55) exhibit even lower expression in metafemales. Lastly, five transduced copies of white carrying three different lengths of the white promoter, but that all exhibit higher expression in males, show reduced expression in metafemales, exhibiting an inverse correlation between the level of expression and the dosage of the X chromosome. Because these alleles of white respond to dosage compensation in metafemales as a continuum of the male and female responses, it is concluded that the same basic mechanism of dosage compensation is involved and that the dosage of the X chromosome conditions the sexually dimorphic expression.     

Phenogenetics of triploid intersexes in Drosophila melanogaster

Triploid intersexes homozygous for a mutant (msl-2) known to impede the hyperactivation of the X chromosome in diploid males differentiate into adults, sexually indistinguishable from their heterozygous sibs. A shift toward female sexual differentiation mediated by manipulating the rearing temperature is accompanied by an apparent increase in the level of an X-linked gene product. This unexpected result is rationalized in terms of differential lethality of individuals at the two extremities of the distribution of X-activity levels in intersexes raised at a particular temperature. No evidence of a mosaicism comparable to the sexual mosaicism exhibited could be found with respect to an X-linked gene product in triploid intersexes.     

Phenogenetics of triploid intersexes in Drosophila melanogaster

Triploid intersexes homozygous for a mutant (msl-2) known to impede the hyperactivation of the X chromosome in diploid males differentiate into adults, sexually indistinguishable from their heterozygous sibs. A shift toward female sexual differentiation mediated by manipulating the rearing temperature is accompanied by an apparent increase in the level of an X-linked gene product. This unexpected result is rationalized in terms of differential lethality of individuals at the two extremities of the distribution of X-activity levels in intersexes raised at a particular temperature. No evidence of a mosaicism comparable to the sexual mosaicism exhibited could be found with respect to an X-linked gene product in triploid intersexes.     

Gene Expression in Adult Metafemales of Drosophila Melanogaster

The expression of selected X-linked and autosomal genes was examined in metafemales (3X:2A) compared to diploid sisters. Three enzyme activities (glucose-6-phosphate dehydrogenase, 6-phosphogluconate dehydrogenase, beta-hydroxyacid dehydrogenase) encoded by X-linked genes are not significantly different in the two classes of flies. In contrast, three autosomally encoded enzyme activities (alcohol dehydrogenase, alpha-glycerophosphate dehydrogenase, isocitrate dehydrogenase) are reduced in metafemales. Protein and DNA comparisons between metafemales and diploid sisters show a lowered level of total protein whereas the total DNA measurements are similar. Thus, the total cell number in metafemales is basically unchanged but gene expression is reduced. Phenotypic analysis of three autosomal loci, glass (gl), purple (pr) and pink-peach (pp), show that all three have lowered expression in metafemales while the X-linked loci, white-apricot (wa) and Bar (B), are dosage compensated. Quantitative dot blot analysis of messenger RNA levels of the second chromosomal locus, alcohol dehydrogenase (Adh), and the X chromosomal locus, rudimentary (r), show that Adh has reduced expression and r is partially compensated per total RNA in metafemales. It is proposed that the increased dosage of the X chromosome inversely affects both the X and autosomal gene expression but the simultaneous increased dosage of the structural genes on the X results in dosage compensation. The reduced levels of expression of autosomal genes could contribute to the great inviability of metafemales.     

Sex Determination in Bees. II. Additivity of Maleness Genes in APIS MELLIFERA

Twenty-two randomly taken morphological characters were used in order to estimate the Mahalanobis generalized distance between diploid males, diploid workers, haploid males and triploid workers. It was found that adult diploid males are metamales and triploid females are slightly masculinized. These facts indicate that the maleness genes are slightly additive.     

The segmentation gene runt is needed to activate Sex-lethal, a gene that controls sex determination and dosage compensation in Drosophila.

In Drosophila, sex is determined by the relative number of X chromosomes to autosomal sets (X:A ratio). The amount of products from several X-linked genes, called sisterless elements, is used to indicate to Sex-lethal the relative number of X chromosomes present in the cell. In response to the X:A signal, Sex-lethal is activated in females but remains inactive in males, being responsible for the control of both sex determination and dosage compensation. Here we find that the X-linked segmentation gene runt plays a role in this process. Reduced function of runt results in female-specific lethality and sexual transformation of XX animals that are heterozygous for Sxl or sis loss-of-function mutations. These interactions are suppressed by SxlM1, a mutation that constitutively expresses female Sex-lethal functions, and occur at the time when the X:A signal determines Sex-lethal activity. Moreover, the presence of a loss-of-function runt mutation masculinizes triploid intersexes. On the other hand, runt duplications cause a reduction in male viability by ectopic activation of Sex-lethal. We conclude that runt is needed for the initial step of Sex-lethal activation, but does not have a major role as an X-counting element.     

Sex determination in bees. I. Balance between femaleness and maleness genes inBombus atratus franklin (Hymenoptera,Apidae)

Mating between a diploid male and a diploid female ofBombus atratus produced fertile triploid F₁ females. The F₂ descendents of these virgin females were composed of haploid males (10), diploid males (4), aneuploid males (3) and intersexes (2). These data indicate that sex is produced by a balance between male determining and female determining genes: they, also, suggest that the number of sex genes are not large.     

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.     

X-linked gene expression and sex determination in Caenorhabditis elegans

The signal for sex determination in the nematode Caenorhabditis elegans is the ratio between the number of X chromosomes and the number of sets of autosomes (the X/A ratio). Animals with an X/A ratio of 0.67 (a triploid with two X chromosomes) or less are males. Animals with an X/A ratio of 0.75 or more are hermaphrodites. Thus, diploid males have one X chromosome and diploid hermaphrodites have two X chromosomes. However, the difference in X-chromosome number between the sexes is not reflected in general levels of X-linked gene expression because of the phenomenon of dosage compensation. In dosage compensation, X-linked gene expression appears to be 'turned down' in 2X animals to the 1X level of expression. An intriguing and unexplained finding is that mutations and X-chromosome duplications that elevate X-linked gene expression also feminize triploid males. One way that this relationship between sex determination and X-linked gene expression may be operating is discussed.     

Temperature-Sensitive Nonsense Suppressors in Yeast

We have measured gene function in normal and male-like intersexual triploids of Drosophila melanogaster by assaying crude extracts of whole flies or thoraces for levels of an X-linked (6-phosphogluconate dehydrogenase) and an autosomal (NADP-dependent isocitrate dehydrogenase) enzyme activity. Our observations lead us to conclude that each dose of the X-linked gene is more active in the cells of these intersexes than it is in normal triploid or diploid female cells. These results indicate that a level of activity intermediate between the normal male and female levels is possible for X-linked genes.     

Dosage Regulation of the Active X Chromosome in Human Triploid Cells

In mammals, dosage compensation is achieved by doubling expression of X-linked genes in both sexes, together with X inactivation in females. Up-regulation of the active X chromosome may be controlled by DNA sequence–based and/or epigenetic mechanisms that double the X output potentially in response to autosomal factor(s). To determine whether X expression is adjusted depending on ploidy, we used expression arrays to compare X-linked and autosomal gene expression in human triploid cells. While the average X:autosome expression ratio was about 1 in normal diploid cells, this ratio was lower (0.81–0.84) in triploid cells with one active X and higher (1.32–1.4) in triploid cells with two active X''s. Thus, overall X-linked gene expression in triploid cells does not strictly respond to an autosomal factor, nor is it adjusted to achieve a perfect balance. The unbalanced X:autosome expression ratios that we observed could contribute to the abnormal phenotypes associated with triploidy. Absolute autosomal expression levels per gene copy were similar in triploid versus diploid cells, indicating no apparent global effect on autosomal expression. In triploid cells with two active X''s our data support a basic doubling of X-linked gene expression. However, in triploid cells with a single active X, X-linked gene expression is adjusted upward presumably by an epigenetic mechanism that senses the ratio between the number of active X chromosomes and autosomal sets. Such a mechanism may act on a subset of genes whose expression dosage in relation to autosomal expression may be critical. Indeed, we found that there was a range of individual X-linked gene expression in relation to ploidy and that a small subset (∼7%) of genes had expression levels apparently proportional to the number of autosomal sets.     

The interaction between daughterless and sex-lethal in triploids: a lethal sex-transforming maternal effect linking sex determination and dosage compensation in Drosophila melanogaster

Regulation of Drosophila sex determination and X-chromosome dosage compensation in response to the X-chromosome/autosome (X/A) balance of the zygote is shown to require proper functioning of both the da+ gene in the mother and the Sxl+ gene in the zygote. Previous studies led to the hypothesis that zygotic Sxl+ alleles are differentially active in females (XXAA) vs males (XYAA) in response to the X/A balance, and that maternal da+ gene product acts as a positive regulator in this connection. Sxl+ activity was proposed to impose the female developmental sequence on cells which would follow the male sequence in its absence. Important predictions of this proposal are verified. This study focuses primarily on the phenotype of triploid intersexes (XXAAA, X/A = 0.67). They are shown here to survive effects of da and Sxl mutations that would be lethal to diploids. The ambiguous X/A signal of intersexes normally causes them to develop as phenotypic mosaics of male and female tissue. Loss of maternal da+ or zygotic Sxl+ gene function shifts their somatic sexual phenotype to the male alternative. A gain-of-function mutation at Sxl has the opposite effect, imposing female development regardless of the maternal genotype with respect to da. It also reduces their rate of X-linked gene expression. The effects of a duplication of Sxl+ resemble those of the constitutive Sxl allele, but are less extreme. The role of these genes in the process of X-chromosome dosage compensation is inferred indirectly from the strict dependence of the mutations' lethal effects on the X/A balance in haploids, diploids, and triploids, and more directly from the effects of the mutations on the phenotypes of the X-linked neomorphic mutations, Bar and Hairy-wing. The relationship of da+ and Sxl+ gene functions to those of other sex-specific lethal loci in D. melanogaster, and to sex determination mechanisms in other species, is discussed.     

Influence of deficiency of the histone gene-containing 38B-40 region on X-chromosome template activity and the white gene position effect variegation in Drosophila melanogaster.

Summary The deficiency of the 38B-40 region containing histone genes in one of the 2nd chromosomes of D. melanogaster triploid intersexes increases the template activity of X-chromosomes both in vivo and in vitro without noticeably affecting autosome activity. This deficiency in the heterozygous state inhibits the variegated position effect of the white gene in the T(1;3)w ^vcotranslocation in diploid females and males, but not affect their rate of development. The variegation suppressor Su(var)hg-1 not only suppress the gene position effect in diploid flies, but also increases the template activity of X-chromosomes in triploid intersexes.The results are discussed with respect to the dependence of gene activity on the structure of chromosomes (density of DNP packing).