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Male or Female? The Answer Depends on When You Ask

Over 80 years ago, Bridges came to the conclusion that sex inDrosophila is determined by the X:A ratio. Doubts about this hypothesis are raised by taking a molecular look at how--and when--sex is determined.

Akey decision in the life of an organism is whether to be male or female. In Drosophila, each cell makes this choice independently of its neighbors such that diploid cells with one X chromosome (XY) are male and those with two chromosomes (XX) are female. In classic experiments carried out more than 80 years ago, Calvin Bridges made two important conclusions about how sex is determined in flies [1–3]. He showed that the Y chromosome is not a factor and suggested that sex is determined not simply by counting X chromosomes, but by calculating the ratio of X chromosomes to the number of sets of autosomes (known as the X:A ratio). The concept that sex is determined by a mechanism that evaluates the number of X chromosomes relative to autosomes was invoked to explain the observation that animals with two X chromosomes and three sets of autosomes (XX; AAA) develop as sexual mosaics rather than females. According to this model, animals with the same number of X chromosomes as autosome sets (ratio of 1) are female, animals with half as many X chromosomes as sets of autosomes are male (ratio of 0.5), and those with an intermediate ratio (XX; AAA; ratio of 0.67) are sexual mosaics. With the finding that haploid cells (X; A; ratio of 1) are female [4,5], the idea that sex is determined by the X:A ratio became enshrined in the literature.

How is sex determined in molecular terms? In diploid cells, the choice to be male or female is made when the activity state of Sex-lethal (Sxl) is set during early embryogenesis (reviewed in [6–8]). The all or none character of Sxl activation depends on the expression levels of four X-encoded proteins: SISA, SCUTE, RUNT, and UNPAIRED. When expression levels reach a threshold, as in XX individuals, the three X-encoded transcription factors—SISA, SCUTE, and RUNT—stimulate transcription by binding the SxlPe promoter [9,10]. Activation is then reinforced through the Janus kinase pathway via Unpaired, an X-encoded secreted ligand [11,12]. Once active, the presence of the female-specific SXL RNA-binding protein directs all aspects of female development. In XY animals, the expression levels of the four X-linked gene products produced from the single X chromosome fail to reach the threshold concentration needed to activate Sxl, and male development ensues.

The window of opportunity for Sxl activation is brief, ending at the cellular blastoderm stage, ~3.0 h after fertilization [6,12–14]. At this time, transcription from the SxlPe promoter is shut down, but Sxl continues to be transcribed from a different promoter (SxlPm) in all embryos. Nevertheless, Sxl expression remains female-specific, because the female-specific SXL RNA-binding protein regulates its own expression at the level of splicing (reviewed in [15]). Without the SXL protein (as in XY embryos), Sxl transcripts are nonfunctional, because they contain an exon with multiple premature stop codons. In XX embryos, the presence of SXL protein forces the translation-terminating exon to be skipped, thereby generating only protein-encoding mRNAs. The continuous supply of SXL protein produced by this autoregulatory splicing loop reinforces the sex-fate decision made earlier in development by converting the transient X-chromosome dose signal into long-term cellular memory.

How well does the hypothesis that sex is determined by the X:A ratio fit with our molecular understanding of Sxl activation? Models incorporating the idea that Sxl is the immediate downstream target of the signal emitted from the X:A ratio describe the four X-linked genes required for Sxl activation as X chromosome signal elements (XSEs). The collaboration of these proteins to stably activate Sxl provides a simple biochemical explanation for the conversion of a 2-fold difference in X chromosome number into an all-or-none response. What distinguishes the X:A ratio model from a simple X chromosome counting mechanism is the prediction that the activity of XSEs is measured against a background of autosomal signal elements (ASEs). In molecular terms, we would expect the ASE gene products to counteract the activating function of the XSEs, making Sxl activation impossible unless the XSE gene products “outnumber” the ASE products. While this fits with our understanding of how transcription of major developmental genes is tightly controlled by the competitive balancing of positively and negatively acting regulatory factors, the fact remains that, despite heroic efforts, only a single ASE, encoded by deadpan, has been identified [13,16]. Although this is disconcerting (see [6,13,16,17]), the X:A signaling hypothesis has thus far provided the best conceptual framework for explaining why haploid cells with their single X chromosome and an X:A ratio of 1 are female, and the failure to identify additional ASEs has not been considered a fatal flawuntil now.

In work reported in this issue of PLoS Biology [18], Erickson and Quintero take a molecular look at haploid embryos and find that Sxl is activated not because the X:A ratio equals one, but because the XSE products produced from the single X chromosome are allowed to accumulate longer than their diploid single X chromosome siblings are. Sxl activation, like other early events in embryogenesis, happens on a tight time schedule. Immediately after fertilization, wild-type embryos undergo 13 rapid synchronous nuclear divisions in a common cytoplasm, without forming cellular membranes. The transformation from this precellular, or syncytial, embryo to a cellular blastoderm occurs as the division rate slows down, midway through nuclear cycle 14. Embryogenesis in haploids is nearly identical to diploids with one “small” difference—the formation of the cellular blastoderm is delayed by a single division cycle and occurs during nuclear cycle 15 [19].

Erickson and Quintero realized that because sexual fate is determined before cellular blastoderm formation, a mechanism that “reads” an X:A signal predicts that the timing of SxlPe activation will be identical in haploids and diploids. By tracking the timing of scute and SxlPe expression by RNA in situ hybridization, the authors show that in diploids, the build up of this XSE reaches the necessary threshold level for SxlPe activation by nuclear cycle 12. The transition to the cellular blastoderm stage is accompanied by the rapid decrease in scute mRNA accumulation and the cessation of transcription from SxlPe. Haploid embryos undergo the same sequence of events; however, the entire process is delayed until nuclear cycle 14, when the level of scute expression reaches the same level as that in diploid cycle 12 embryos. Importantly, whereas these data thoroughly dispel the notion of a static X:A ratio–based signal, they remain entirely consistent with our molecular understanding of SxlPe activation and its dependence on reaching threshold concentrations of XSE gene products (Figure 1).

Although these studies have released us from the X:A ratio dogma, they leave open the question of why the window of opportunity for SxlPe activation is longer in haploids than in diploids. In other words, why are the events leading to SxlPe shutdown delayed in haploid embryos? That cellular blastoderm formation is also delayed provides the first hint that these two major developmental milestones are coupled. Further support that SxlPe shutdown and cellular blastoderm formation are linked comes from an examination of the SxlPe activation time course in XX; AAA embryos. Remarkably, both cellularization and SxlPe shutdown happen earlier than in diploids—during cycle 13. Thus, the development of these flies as sexual mosaics can be explained by postulating that SxlPe shuts down before some (but not all) cells have reached the concentration of XSEs necessary for SxlPe activation. Is cellular blastoderm formation the trigger that initiates SxlPe shut down? Cellular blastoderm formation marks the completion of the maternal-to-zygotic transition, a series of reprogramming events that lead to the elimination of maternal mRNAs and the activation of the zygotic genome [20–23]. Perhaps the machinery that choreographs the timing of these cellular events is also responsible for the timely shutdown of SxlPe. If so, then we have added a new regulatory dimension to the choice between male and female development.