Tze-Bin Chou

wingless signaling acts through zeste-white 3, the Drosophila homolog of glycogen synthase kinase-3, to regulate engrailed and establish cell fate.

Intrasegmental patterning in the Drosophila embryo is regulated by cell-cell communication. One of the signaling pathways that operates to specify positional information throughout the segment is mediated by the wingless (wg) protein, which is the homolog of the proto-oncogene Wnt-1. The early role of wg is to stabilize engrailed (en) expression by initiating a phase of en autoregulation in the adjacent more posterior cells. Here, we report that the segment polarity gene zeste-white 3 (zw3; also known as shaggy) acts as a repressor of en autoregulation. Genetic epistasis experiments indicate that wg signaling operates by inactivating the zw3 repression of en autoactivation. In addition, we demonstrate that zw3 encodes the Drosophila homolog of mammalian glycogen synthase kinase-3.

Spatially localized rhomboid is required for establishment of the dorsal-ventral axis in Drosophila oogenesis

The establishment of dorsal-ventral asymmetry of the Drosophila embryo requires a group of genes that act maternally. None of the previously identified dorsal-ventral axis genes are known to produce asymmetrically localized gene products during oogenesis. We show that rhomboid (rho), a novel member of this group, encodes a protein that is localized on the apical surface of the dorsal-anterior follicle cells surrounding the oocyte. Loss of rho function causes ventralization of the eggshell and the embryo, whereas ectopic expression leads to dorsalization of both structures. Thus, spatially restricted rho is necessary and sufficient for dorsal-ventral axis formation. We propose, based on these observations and double mutant experiments, that the spatially restricted rho protein leads to selective activation of the epidermal growth factor receptor in the dorsal follicle cells and subsequently the specification of the dorsal follicle cells.

On/off regulation of gene expression at the level of splicing

Abstract The past two years have seen the discovery of three independent cases in which expression of a eukaryotic protein gene product is turned on and off by controlling splicing events necessary to produce the corresponding mRNA. Various considerations suggest that such on/off regulation at the level of splicing may be unexpectedly common.

The torso receptor tyrosine kinase can activate raf in a ras-independent pathway

Activation of the receptor tyrosine kinase (RTK) torso defines the spatial domains of expression of the transcription factors tailless and huckebein. Previous analyses have demonstrated that Ras1 (p21ras) operates upstream of the D-Raf (Raf1) serine/threonine kinase in this signaling pathway. By using a recently developed technique of germline mosaics, we find that D-Raf can be activated by torso in the complete absence of Ras1. This result is supported by analysis of D-Raf activation in the absence of either the exchange factor Son of sevenless (Sos) or the adaptor protein drk (Grb2), as well as by the phenotype of a D-Raf mutation that abolishes binding of Ras1 to D-Raf. Our study provides in vivo evidence that Raf can be activated by an RTK in a Ras-independent pathway.

Developmental expression of a regulatory gene is programmed at the level of splicing.

We report sequence and transcript structures for a 6191‐base chromosomal segment containing the presumptive regulatory gene from Drosophila, suppressor‐of‐white‐apricot [su(wa)]. Our results indicate that su(wa) expression is controlled by regulating occurrence of specific splices. Seven introns are removed from the su(wa) primary transcript during precellular blastoderm development. The sequence of this mature RNA indicates that it is a conventional messenger RNA. In contrast, after cellular blastoderm the first two of these introns cease to be efficiently removed. The mature RNAs resulting from this failure to remove the first two introns have structures quite unexpected of mRNAs. We propose that postcellular blastoderm su(wa) expression is repressed by preventing splices necessary to produce a functional mRNA. Implications and mechanisms are discussed.

Evidence that a regulatory gene autoregulates splicing of its transcript.

Expression of the presumptive regulatory gene, suppressor‐of‐white‐apricot [su(wa)], is controlled at the level of splicing. Results reported here indicate that this control represents autorepression of su(wa) expression. Specifically, reverse genetic studies demonstrate that the 3.5 kb mature su(wa) RNA (produced by removal of seven introns) is a message essential for su(wa)+ function and indicate that the abundant 4.4 kb and 5.2 kb mature su(wa) RNAs (resulting when the first or first and second of the seven introns are not removed) are, unexpectedly, byproducts of repression of production of the functional 3.5 kb RNA. Moreover, several experiments indicate that this repression of splices necessary to produce the 3.5 kb RNA is dependent on the translation product of the 3.5 kb RNA itself. We propose that this regulatory gene autoregulates its expression by controlling splicing of its primary transcript.

Hepatocellular carcinoma associated with focal nodular hyperplasia. Report of a case with clonal analysis.

Abstract. We describe a hepatocellular carcinoma partially surrounded by focal nodular hyperplasia in a 65-year-old female patient. In order to clarify the relationship of the hepatocellular carcinoma and the adjacent focal nodular hyperplasia, clonal analysis was conducted. The clonal analysis was based on the methylation pattern of the polymorphic X-chromosome-linked androgen receptor gene (HUMARA). The allelic bands from the amplification of the focal nodular hyperplasia and of the hepatocellular carcinoma showed a significant reduction in the intensity of one of the two alleles as compared with two alleles of equal intensity in the buff coat after HhaI digestion, which indicated that these two parts were monoclonal. However, the inactivated allele in the focal nodular hyperplasia and that in the hepatocellular carcinoma were not identical. Therefore, the focal nodular hyperplasia and hepatocellular carcinoma probably derived from the clonal expansion of two different clones.

Molecular cloning and genetic analysis of the suppressor-of-white-apricot locus from Drosophila melanogaster

We report genetic and molecular analysis of the suppressor-of-white-apricot [su(wa)] locus, one of several retrotransposon insertion allele-specific suppressor loci in Drosophila melanogaster. First, we isolated and characterized eight new mutations allelic to the original su(wa)1 mutation. These studies demonstrated that su(wa) mutations allelic to su(wa)1 affected a conventional D. melanogaster complementation group. Second, we cloned the chromosomal region containing the su(wa) complementation group by P element transposon tagging. The ca. 14-kilobase region surrounding the su(wa) complementation group contained five distinct transcription units, each with a different developmentally programmed pattern of expression. Third, we used a modified procedure for P-mediated gene transfer to identify the transcription unit corresponding to su(wa) by gene transfer. Fourth, we found that the presumptive su(wa) transcription unit produced a family of transcripts (ranging from ca. 3.5 to ca. 5.2 kilobases) in all developmental stages, tissue fractions, and cell lines we examined, suggesting that the gene is universally expressed.

The Drosophila GOLPH3 homolog regulates the biosynthesis of heparan sulfate proteoglycans by modulating the retrograde trafficking of exostosins

The exostosin (EXT) genes encode glycosyltransferases required for glycosaminoglycan chain polymerization in the biosynthesis of heparan sulfate proteoglycans (HSPGs). Mutations in the tumor suppressor genes EXT1 and EXT2 disturb HSPG biosynthesis and cause multiple osteochondroma (MO). How EXT1 and EXT2 traffic within the Golgi complex is not clear. Here, we show that Rotini (Rti), the Drosophila GOLPH3, regulates the retrograde trafficking of EXTs. A reduction in Rti shifts the steady-state distribution of EXTs to the trans-Golgi. These accumulated EXTs tend to be degraded and their re-entrance towards the route for polymerizing GAG chains is disengaged. Conversely, EXTs are mislocalized towards the transitional endoplasmic reticulum/cis-Golgi when Rti is overexpressed. Both loss of function and overexpression of rti result in incomplete HSPGs and perturb Hedgehog signaling. Consistent with Drosophila, GOLPH3 modulates the dynamic retention and protein stability of EXT1/2 in mammalian species. Our data demonstrate that GOLPH3 modulates the activities of EXTs, thus implicating a putative role for GOLPH3 in the formation of MO.