Paul Schedl

Sex-lethal, a Drosophila sex determination switch gene, exhibits sex-specific RNA splicing and sequence similarity to RNA binding proteins

The switch gene, Sex-lethal (Sxl), controls sexual development and dosage compensation. It must be active in females and inactive in males throughout development. Analysis of Sxl cDNAs shows that this on/off regulation may be explained by differential RNA splicing; only female transcripts appear to encode functional products, whereas all male transcripts contain an exon that truncates the open reading frame. The functional female product shows sequence similarities with ribonucleoproteins, suggesting that it is an RNA binding protein. Thus, we propose that Sxl encodes a factor that interacts with both its own pre-mRNA (accounting for positive autoregulation) and that of downstream genes to confer female-specific splicing. In this way, a single, simple mechanism could account for both the maintenance and expression of the sexually determined state.

Spatial expression of the Drosophila segment polarity gene armadillo is posttranscriptionally regulated by wingless

armadillo (arm) is one of a group of Drosophila segment polarity genes that are required for normal patterning within the embryonic segment. Although arm RNA is uniformly distributed in embryos, arm protein accumulates at higher levels in regions that contain wingless, another segment polarity gene which encodes a secreted protein that regulates patterning via cell-cell communication. These local increases in arm protein require wingless activity, and mutations that alter wingless distribution produce corresponding changes in the arm protein pattern. These results suggest that wingless regulates accumulation of arm protein by a posttranscriptional mechanism. Two other segment polarity genes, porcupine and dishevelled, are required for this effect. We also show that arm protein is closely associated with the plasma membrane in virtually all cell types and often colocalizes with F-actin.

Positive autoregulation of Sex-lethal by alternative splicing maintains the female determined state in Drosophila

Sex-lethal is a binary switch gene that controls all aspects of Drosophila sexual dimorphism. It must be active in females and inactive in males. The on/off regulation reflects alternative RNA splicing in which full-length proteins are produced only in females. Here we investigate the role of Sxl in maintaining sexual pathway commitments. By ectopic expression of a female Sxl cDNA in transgenic male flies, we show that Sxl protein induces a rapid switch from male- to female-specific splicing. The ectopically expressed Sxl protein wil trans-activate an endogenous wild-type Sxl gene. This establishes a feedback loop in which Sxl proteins induce their own synthesis by directing the female-specific splicing of Sxl transcripts. We conclude that the female determined state is maintained by Sxl through positive autoregulation, while the male determined state is maintained by default.

The primary sex determination signal of Drosophila acts at the level of transcription.

For Drosophila, the choice between male and female development is made by the switch gene, Sxl, in response to the X:A ratio. Once Sxl is turned on in females, it actively maintains the determined state, independent of the X:A signal, by a positive autoregulatory feedback loop in which Sxl proteins direct the female-specific splicing of Sxl transcripts. In this paper we have investigated the mechanism controlling pathway initiation. Our results suggest a two-step model for the initial activation of Sxl in females. In the first step, a special class of Sxl mRNAs is expressed in female embryos from an early promoter that responds to the genes signaling the X:A ratio. The proteins produced from these early mRNAs then initiate the autoregulatory loop by directing the female-specific processing of transcripts from the late Sxl promoter.

The iab-7 Polycomb Response Element Maps to a Nucleosome- Free Region of Chromatin and Requires Both GAGA and Pleiohomeotic for Silencing Activity

ABSTRACT In the work reported here we have undertaken a functional dissection of a Polycomb response element (PRE) from the iab-7 cis-regulatory domain of the Drosophila melanogasterbithorax complex (BX-C). Previous studies mapped the iab-7PRE to an 860-bp fragment located just distal to the Fab-7boundary. Located within this fragment is an ∼230-bp chromatin-specific nuclease-hypersensitive region called HS3. We have shown that HS3 is capable of functioning as a Polycomb-dependent silencer in vivo, inducing pairing-dependent silencing of amini-white reporter. The HS3 sequence contains consensus binding sites for the GAGA factor, a protein implicated in the formation of nucleosome-free regions of chromatin, and Pleiohomeotic (Pho), a Polycomb group protein that is related to the mammalian transcription factor YY1. We show that GAGA and Pho interact with these sequences in vitro and that the consensus binding sites for the two proteins are critical for the silencing activity of theiab-7 PRE in vivo.

Single-Molecule Imaging of Transcriptionally Coupled and Uncoupled Splicing

Introns are removed from pre-mRNAs during transcription while the pre-mRNA is still tethered to the gene locus via RNA polymerase. However, during alternative splicing, it is important that splicing be deferred until all of the exons and introns involved in the choice have been synthesized. We have developed an in situ RNA imaging method with single-molecule sensitivity to define the intracellular sites of splicing. Using this approach, we found that the normally tight coupling between transcription and splicing is broken in situations where the introns polypyrimidine tract is sequestered within strong secondary structures. We also found that in two cases of alternative splicing, in which certain exons are skipped due to the activity of the RNA-binding proteins Sxl and PTB, splicing is uncoupled from transcription. This uncoupling occurs only on the perturbed introns, whereas the preceding and succeeding introns are removed cotranscriptionally. PAPERCLIP:

Novel Functions of nanos in Downregulating Mitosis and Transcription during the Development of the Drosophila Germline

It has previously been shown that germ cells in embryos derived from nos mutant mothers do not migrate to the primitive gonad and prematurely express several germline-specific markers. In the studies reported here, we have traced these defects back to the syncytial blastoderm stage. We show that pole cells in nos embryos fail to establish/maintain transcriptional quiescence; the sex determination gene Sex-lethal (Sxl) and the segmentation genes fushi tarazu and even-skipped are ectopically activated in nos- germ cells. We show that nos- germ cells are unable to attenuate the cell cycle and instead continue dividing. Unexpectedly, removal of the Sxl gene in the zygote mitigates both the migration and mitotic defects of nos- germ cells. Supporting the conclusion that Sxl is an important target for nos repression, ectopic, premature expression of Sxl protein in germ cells disrupts migration and stimulates mitotic activity.

A conserved chromatin architecture marks and maintains the restricted germ cell lineage in worms and flies.

In C. elegans, mRNA production is initially repressed in the embryonic germline by a protein unique to C. elegans germ cells, PIE-1. PIE-1 is degraded upon the birth of the germ cell precursors, Z2 and Z3. We have identified a chromatin-based mechanism that succeeds PIE-1 repression in these cells. A subset of nucleosomal histone modifications, methylated lysine 4 on histone H3 (H3meK4) and acetylated lysine 8 on histone H4 (H4acetylK8), are globally lost and the DNA appears more condensed. This coincides with PIE-1 degradation and requires that germline identity is not disrupted. Drosophila pole cell chromatin also lacks H3meK4, indicating that a unique chromatin architecture is a conserved feature of embryonic germ cells. Regulation of the germline-specific chromatin architecture requires functional nanos activity in both organisms. These results indicate that genome-wide repression via a nanos-regulated, germ cell-specific chromatin organization is a conserved feature of germline maintenance during embryogenesis.

The bluetail transposon: Evidence for independent cis-regulatory domains and domain boundaries in the bithorax complex

An extremely large cis‐regulatory region generates the parasegment‐specific expression patterns of the homeotic genes in the bithorax complex. We present evidence supporting the idea that this cis‐regulatory region is subdivided into independent cis‐regulatory domains. We describe a Ubx‐lacZ transposon which is inserted into one of these domains, iab‐7. The PS12‐specific pattern of LacZ expression from this reporter indicates that it is subject to the control of the iab‐7 cis‐regulatory domain, but is protected from the effects of adjacent regulatory domains. Protection on the proximal side appears to be provided by the Fab‐7 boundary element. Deletion of this boundary results in the ectopic activation of iab‐7 in PS11 (where the iab‐6 cis‐regulatory domain normally functions). We show that the Fab‐7 boundary, like other boundaries, has an unusual chromatin structure.

Chromatin domain boundaries in the Bithorax complex

Abstract. Eukaryotic chromosomes are thought to be organized into a series of discrete higher-order chromatin domains. This organization is believed to be important not only in the compaction of the chromatin fibre, but also in the utilization of genetic information. Critical to this model are the domain boundaries that delimit and segregate the chromosomes into units of independent gene activity. In Drosophila, such domain boundaries have been identified through two different approaches. On the one hand, elements like scs/scs′ and the reiterated binding site for the SU(HW) protein have been characterized through their activity of impeding enhancer-promoter interactions when intercalated between them. Their role of chromatin insulators can protect transgenes from genomic position effects, thereby establishing in dependent functional domains within the chromosome. On the other hand, domain boundaries of the Bithorax complex (BX-C) like Fab-7 and Mcp have been identified through mutational analysis. Mcp and Fab-7, however, may represent a specific class of boundary elements; instead of separating adjacent domains that contain separate structural genes, Mcp and Fab-7 delimit adjacent cis-regulatory domains, each of which interacts independently with their target promoters. In this article, we review the genetic and molecular characteristics of the domain boundaries of the BX-C. We describe how Fab-7 functions to confine activating as well as repressive signals to the flanking regulatory domains. Although the mechanisms by which Fab-7 works as a domain boundary remain an open issue, we provide preliminary evidence that Fab-7 is not a mere insulator like scs or the reiterated binding site for the SU(HW) protein.