Involvement of Ecdysone Signaling in the Expression of the doublesex Gene during Embryonic Development in the Silkworm, Bombyx mori.

Steroid hormones, represented by estrogen and testosterone, act as sex hormones that play an essential role in the sexual differentiation of vertebrates. However, it remains unclear whether ecdysteroids, typical steroid hormones in insects, function as sex hormones. In this study, we investigated whether ecdysteroids or ecdysone signals are involved in the sexual differentiation of the silkworm (Bombyx mori) embryo. Quantitative analysis using LC-MS/MS demonstrated that there was no significant difference in the 20-hydroxyecdysone (20E) titer between sexes during embryonic development. Consistent with this result, expression levels of 2 genes encoding ecdysteroid-phosphate phosphatase (EPPase) and ecdysone 20-hydroxylase (E20OHase), which are essential for the biosynthesis of ecdysone and 20E in eggs, did not show a significant difference between male and female embryos. Expression levels of ecdysone receptor (EcR) and E75, which is one of a small set of genes induced directly by 20E, were also similar between the 2 sexes. However, knockdown of EPPase and one isoform of EcR (EcR-A) resulted in decreased expression of Bombyx doublesex (Bmdsx), a master regulatory gene for sexual differentiation of the silkworm in both male and female embryos. In vitro analysis with cultured testes revealed that expression levels of Bmdsx were increased in a dose-dependent manner of the ecdysone analog, ponasterone A. These results suggest that ecdysone signaling may play a role in indirectly regulating the expression of some genes involved in sexual differentiation through inducing expression of Bmdsx in the silkworm.

Dramatic replacement of histone variants during genome remodeling in nuclear-transferred embryos.

The genome of differentiated somatic nuclei is remodeled to a totipotent state when they are transplanted into enucleated oocytes. To clarify the mechanism of this genome remodeling, we analyzed changes in the composition of core histone variants in nuclear-transferred embryos, since recent evidence has revealed that chromatin structure can be remodeled as a result of variant histone replacement. We found that the donor cell-derived histone H3 variants H3.1, H3.2, and H3.3, as well as H2A and H2A.Z, were rapidly eliminated from the chromatin of nuclei transplanted into enucleated oocytes. Accompanying this removal, oocyte-stored histone H3 variants and H2A.X were incorporated into the transplanted nuclei, while the incorporation of H2A and H2A.Z was minimal or not detected. The incorporation of these variant histones was DNA replication-independent. These results suggest that most core histone H2A and H3 components are dynamically exchanged between donor nuclei and recipient cytoplasm, which further suggests that replacement of donor cell histones with oocyte-stored histones may play a key role in genome remodeling in nuclear-transferred embryos. In addition, the incorporation patterns of all of the histone variants in the nuclear-transferred embryos were virtually the same as in the fertilized embryos. Only the incorporation pattern of H3.1 differed; it was incorporated into the transplanted donor nuclei, but not in the pronuclei of fertilized embryos. This result suggests that the incorporation of H3.1 has a detrimental effect on the process of genome remodeling and contributes to the low success rate of somatic nuclear cloning.

The Bmdsx transgene including trimmed introns is sex-specifically spliced in tissues of the silkworm, Bombyx mori.

Bmdsx is an orthologue of the sex-determining gene doublesex (dsx) and known to be sex-specifically expressed in various tissues of the silkworm, Bombyx mori. Its pre-mRNA is sex-specifically spliced and encodes female-specific or male-specific polypeptides. The open reading frame of Bmdsx consists of 5 exons, of which exons 3 and 4 are female-specific and its pre-mRNA was known to undergo default processing to generate the female-type mRNA. Previous reports have shown that the mechanism of splicing of the doublesex gene is different in Drosophila melanogaster and Bombyx mori. However, intron 4 is so long that it is difficult to identify the intronic cis-element(s) required for male-specific splicing of Bmdsx pre-mRNA using Bmdsx minigenes whose introns are shortened in various manners. As a first step toward discovery of the cis-element, the Bmdsx mini gene, which consisted of exon 1 and 5 and internally shortened introns 2 to 4, was constructed, and transgenic silkworms expressing this construct were generated. Bmdsx pre-mRNA transcribed derived from transgene was sex-specifically spliced. This result shows that the mini gene contained the information necessary for the correct regulation of alternative splicing.

Role of the male BmDSX protein in the sexual differentiation of Bombyx mori.

The sex determination pathway is different between Drosophila melanogaster and Bombyx mori in the initial signal. Here we show evidence that the sex determination pathway in B. mori is similar to that of D. melanogaster at the level of the terminal regulator, doublesex (dsx), which is essential for the proper differentiation of the sexually dimorphic somatic features of D. melanogaster. In B. mori, a homolog of dsx (Bmdsx) is expressed in various tissues, and its primary transcript is alternatively spliced in males and females to yield sex-specific mRNAs that encode male-specific (BmDSXM) and female-specific (BmDSXF) polypeptides. In the studies reported here, transgenic silkworms carrying a construct with a Bmdsx male cDNA placed under the control of either an hsp70 promoter or a Bombyx actin3 promoter were generated by piggyBac-mediated germline transformation. Ectopic expression of the male cDNA in females resulted in abnormal differentiation of certain female-specific genital organs and caused partial male differentiation in female genitalia. Transgenic analysis also revealed that the expression of BmDSXM in females caused repression of the female-specifically expressed gene, the vitellogenin gene, and also resulted in activation of the pheromone-binding protein gene that is dominantly expressed in males. These results provide evidence that the role of BmDSXM includes the activation of some aspects of male differentiation as well as the repression of female differentiation. Taken together with our previous data on the function of BmDSXF, we can conclude that Bmdsx is a double-switch gene at the final step in the sex-determination cascade of B. mori.

Analysis of the biological functions of a doublesex homologue in Bombyx mori.

We have previously reported that Bmdsx, a homologue of the sex-determining gene doublesex ( dsx), was sex-specifically expressed in various tissues of the silkworm. The primary transcript of Bmdsx is alternatively spliced in males and females to yield sex-specific mRNAs that encode male-specific (BmDSXM) and female-specific (BmDSXF) polypeptides. In the studies reported here, we expressed BmDSXF in males from a ubiquitous promoter and examined its regulatory activities. We show that BmDSXF functions as a positive regulator of the hexameric storage protein termed SP1 and vitellogenin genes that are predominantly expressed in females. We also show that expression of Bmdsx(F) in males results in the repression of the pheromone-binding protein gene that is preferentially expressed in males. Gel-mobility shift assays demonstrated that BmDSX proteins bind to the sequence (ACATTGT) between -95 and -89 nt relative to the transcriptional initiation site of the vitellogenin gene. These results strongly suggest that Bmdsx is a final regulatory gene in the hierarchy of regulatory genes controlling the expression of female-specific protein in Bombyx mori.