Encore is a member of a novel family of proteins and affects multiple processes in Drosophila oogenesis.

Mutations in the encore (enc) gene of Drosophila melanogaster cause one extra round of mitosis in the germline, resulting in the formation of egg chambers with extra nurse cells. In addition, enc mutations affect the accumulation of Gurken protein within the oocyte, leading to the production of ventralized eggs. Here we show that enc mutants also exhibit abnormalities in karyosome morphology, similar to other ventralizing mutants such as okra and spindle B. Unlike these mutants, however, the defects in Gurken accumulation and karyosome formation do not result from activation of a meiotic checkpoint. Furthermore, we demonstrate that the requirement for enc in these processes is temporally distinct from its role in germline mitosis. Cloning of the enc locus and generation of anti-Enc antibodies reveal that enc encodes a large novel protein that accumulates within the oocyte cytoplasm and colocalizes with grk mRNA. We argue that the enc mutant phenotypes reflect a role for Enc in the regulation of several RNA targets.

The transmembrane region of Gurken is not required for biological activity, but is necessary for transport to the oocyte membrane in Drosophila.

During Drosophila oogenesis, localization of the transforming growth factor alpha (TGFalpha)-like signaling molecule Gurken to the oocyte membrane is required for polarity establishment of the egg and embryo. To test Gurken domain functions, full-length and truncated forms of Gurken were expressed ectopically using the UAS/Gal4 expression system, or in the germline using the endogenous promoter. GrkDeltaC, a deletion of the cytoplasmic domain, localizes to the oocyte membrane and can signal. GrkDeltaTC, which lacks the transmembrane and cytoplasmic domains, retains signaling ability when ectopically expressed in somatic cells. However, in the germline, the GrkDeltaTC protein accumulates throughout the oocyte cytoplasm and cannot signal. In addition, we found that several strong gurken alleles contain point mutations in the transmembrane region. We conclude that secretion of Gurken requires its transmembrane region, and propose a model in which the gene cornichon mediates this process.

Versatility in signalling: multiple responses to EGF receptor activation during Drosophila oogenesis.

The Drosophila epidermal growth factor receptor (EGFR) is active in different tissues and is involved in diverse processes such as patterning of the embryonic ectoderm, growth and differentiation of imaginal discs and cell survival. During oogenesis, the EGFR is expressed in the somatic follicle cells that surround individual oocyte-nurse cell complexes. In response to germline signals, the follicle cells differentiate in a complex pattern, which in turn leads to the establishment of the egg axes. Two recent reports have shown that the strategies used to pattern posterior follicle cells are different from those used to pattern dorsal follicle cells. In posterior follicle cells, EGFR activity is translated into an on-off response, whereas, in dorsal follicle cells, patterning mechanisms are initiated and refined by feedback that modulates receptor activity over time.

Natural history of distal spinal agenesis.

We studied the natural course in patients with distal spinal agenesis (DSA). Specifically, we compared children with different types of DSA (Renshaw sacral agenesis types I-IV) and determined their maximum ambulatory abilities, identified patients at risk for decubiti, determined the average number of operations per patient, described associated congenital anomalies, and sought a correlation between different types of DSA and the risk of back pain and development of scoliosis. Through a retrospective analysis, we concluded that there are definite correlations between the specific type DSA and the natural course with regard to all these entities.

Post-transcriptional regulation of gurken by encore is required for axis determination in Drosophila.

Establishment of anterior-posterior and dorsal-ventral polarity within the Drosophila egg chamber requires signaling between the germline and the somatic cells of the ovary. The gene gurken (grk) encodes a TGFalpha-like protein that is localized within the developing oocyte and is thought to locally activate torpedo/Egfr (top/Egfr), the Drosophila homolog of the EGF receptor, which is expressed throughout the follicular epithelium surrounding the oocyte. grk-Egfr signaling is required early in oogenesis for specification of posterior follicle cell fate and later in oogenesis for dorsal follicle cell fate determination, thus establishing the axes of the egg shell and embryo. Previous studies have shown that these patterning processes are highly sensitive to changes in the levels and localization of grk mRNA. Here we show that post-transcriptional regulation of Grk protein levels is required for correct pattern formation. encore (enc), a gene that functions in the regulation of germline mitosis and maintenance of oocyte identity, is also required for the accumulation of Grk protein during oogenesis. We present evidence that enc regulates Grk post-transcriptionally to ensure adequate levels of signaling for establishment of the anterior-posterior and dorsal-ventral axes.

A gut-to-pharynx/tail switch in embryonic expression of the Caenorhabditis elegans ges-1 gene centers on two GATA sequences.

The Caenorhabditis elegans ges-1 gene (gut esterase No. 1) is expressed only in the intestinal lineage, beginning when the developing gut has only four to eight cells. We analyze the sequence requirements for this tissue-specific gene regulation by injecting deleted/mutated constructs of the ges-1 gene into a viable ges-1 (null) strain of worms and assaying heritably transformed embryos by esterase histochemistry. Many deletion constructs accurately reconstitute the wildtype gut-specific ges-1 expression. However, deletions in the neighborhood of 1100 bp upstream of the ges-1 ATG abolish ges-1 expression in the developing gut, while at the same time activating ges-1 expression in cells of the pharynx/tail that appear to belong to the sister lineage of the gut. Deletions of a 36-bp DNA region containing two tandem WGATAR sequences are sufficient to cause this gut-to-pharynx/tail switch in expression pattern. Deletion of either one of the WGATAR sites or deletion of an adjoining downstream region directs ges-1 expression only in a restricted set of cells of the anterior gut. The ges-1 GATA region acts like a gut-specific enhancer in that: (i) it restores ges-1 gut expression when reinserted elsewhere into the GATA-deleted ges-1 gene; and (ii) multiple copies direct gut expression of an hsp16-lacZ reporter gene. The ges-1 GATA-region also acts as the site of the pharynx/tail repression in that reinsertion elsewhere into the GATA-deleted ges-1 construct causes repression of ges-1 in the pharynx/tail. However, multiple copies of the GATA region are not able to repress the heat-induced expression of an hsp16-lacZ reporter gene, suggesting that the pharynx/tail repression mechanism is specific to the ges-1 environment. Finally, mutation rather than deletion of the individual GATA sequences suggests that gut activation and pharynx/tail repression may be due to separate factors. We present a molecular model that summarizes these results. The ges-1 control circuitry appears surprisingly complex for what might have been expected to be the simplest possible example of a nonessential gene expressed early in a clonal embryonic lineage.