Functional interaction between the coactivator Drosophila CREB-binding protein and ASH1, a member of the trithorax group of chromatin modifiers.

CREB-binding protein (CBP) is a coactivator for multiple transcription factors that transduce a variety of signaling pathways. Current models propose that CBP enhances gene expression by bridging the signal-responsive transcription factors with components of the basal transcriptional machinery and by augmenting the access of transcription factors to DNA through the acetylation of histones. To define the pathways and proteins that require CBP function in a living organism, we have begun a genetic analysis of CBP in flies. We have overproduced Drosophila melanogaster CBP (dCBP) in a variety of cell types and obtained distinct adult phenotypes. We used an uninflated-wing phenotype, caused by the overexpression of dCBP in specific central nervous system cells, to screen for suppressors of dCBP overactivity. Two genes with mutant versions that act as dominant suppressors of the wing phenotype were identified: the PKA-C1/DCO gene, encoding the catalytic subunit of cyclic AMP protein kinase, and ash1, a member of the trithorax group (trxG) of chromatin modifiers. Using immunocolocalization, we showed that the ASH1 protein is specifically expressed in the majority of the dCBP-overexpressing cells, suggesting that these proteins have the potential to interact biochemically. This model was confirmed by the findings that the proteins interact strongly in vitro and colocalize at specific sites on polytene chromosomes. The trxG proteins are thought to maintain gene expression during development by creating domains of open chromatin structure. Our results thus implicate a second class of chromatin-associated proteins in mediating dCBP function and imply that dCBP might be involved in the regulation of higher-order chromatin structure.

Cubitus interruptus requires Drosophila CREB-binding protein to activate wingless expression in the Drosophila embryo.

CREB-binding protein (CBP) serves as a transcriptional coactivator in multiple signal transduction pathways. The Drosophila homologue of CBP, dCBP, interacts with the transcription factors Cubitus interruptus (CI), MAD, and Dorsal (DL) and functions as a coactivator in several signaling pathways during Drosophila development, including the hedgehog (hh), decapentaplegic (dpp), and Toll pathways. Although dCBP is required for the expression of the hh target genes, wingless (wg) and patched (ptc) in vivo, and potentiates ci-mediated transcriptional activation in vitro, it is not known that ci absolutely requires dCBP for its activity. We used a yeast genetic screen to identify several ci point mutations that disrupt CI-dCBP interactions. These mutant proteins are unable to transactivate a reporter gene regulated by ci binding sites and have a lower dCBP-stimulated activity than wild-type CI. When expressed exogenously in embryos, the CI point mutants cannot activate endogenous wg expression. Furthermore, a CI mutant protein that lacks the entire dCBP interaction domain functions as a negative competitor for wild-type CI activity, and the expression of dCBP antisense RNAs can suppress CI transactivation in Kc cells. Taken together, our data suggest that dCBP function is necessary for ci-mediated transactivation of wg during Drosophila embryogenesis.

Mutants of cubitus interruptus that are independent of PKA regulation are independent of hedgehog signaling.

Hedgehog (HH) is an important morphogen involved in pattern formation during Drosophila embryogenesis and disc development. cubitus interruptus (ci) encodes a transcription factor responsible for transducing the hh signal in the nucleus and activating hh target gene expression. Previous studies have shown that CI exists in two forms: a 75 kDa proteolytic repressor form and a 155 kDa activator form. The ratio of these forms, which is regulated positively by hh signaling and negatively by PKA activity, determines the on/off status of hh target gene expression. In this paper, we demonstrate that the exogenous expression of CI that is mutant for four consensus PKA sites [CI(m1-4)], causes ectopic expression of wingless (wg) in vivo and a phenotype consistent with wg overexpression. Expression of CI(m1-4), but not CI(wt), can rescue the hh mutant phenotype and restore wg expression in hh mutant embryos. When PKA activity is suppressed by expressing a dominant negative PKA mutant, the exogenous expression of CI(wt) results in overexpression of wg and lethality in embryogenesis, defects that are similar to those caused by the exogenous expression of CI(m1-4). In addition, we demonstrate that, in cell culture, the mutation of any one of the three serine-containing PKA sites abolishes the proteolytic processing of CI. We also show that PKA directly phosphorylates the four consensus phosphorylation sites in vitro. Taken together, our results suggest that positive hh and negative PKA regulation of wg gene expression converge on the regulation of CI phosphorylation.

Protein kinase A directly regulates the activity and proteolysis of cubitus interruptus.

Cubitus interruptus (Ci) is a transcriptional factor that is positively regulated by the hedgehog (hh) signaling pathway. Recent work has shown that a 75-kDa proteolytic product of the full-length CI protein translocates to the nucleus and represses the transcription of CI target genes. In cells that receive the hh signal, the proteolysis of CI is inhibited and the full-length protein can activate the hh target genes. Because protein kinase A (PKA) inhibits the expression of the hh target genes in developing embryos and discs and the loss of PKA activity results in elevated levels of full-length CI protein, PKA might be involved directly in the regulation of CI proteolysis. Here we demonstrate that the PKA pathway antagonizes the hh pathway by phosphorylating CI. We show that the PKA-mediated phosphorylation of CI promotes its proteolysis from the full-length active form to the 75-kDa repressor form. The PKA catalytic subunit increases the proteolytic processing of CI and the PKA inhibitor, PKI, blocks the processing. In addition, cells do not process the CI protein to the 75-kDa repressor when all of the PKA sites in CI are mutated. Mutant CI proteins that cannot be phosphorylated by PKA have increased transcriptional activity compared with wild-type CI. In addition, exogenous PKA can increase further the transcriptional activity of the CI mutant, suggesting that PKA has a second positive, indirect effect on CI activity. In summary, we show that the modulation of the hh signaling pathway by PKA occurs directly at the level of CI phosphorylation.

The CRE-binding protein dCREB-A is required for Drosophila embryonic development.

We have previously described the cloning of a cyclic AMP response-element (CRE)-binding protein, dCREB-A, in Drosophila melanogaster that is similar to the mammalian CRE-binding protein CREB. dCREB-A is a member of the bZIP family of transcription factors, shows specific binding to the (CRE), and can activate transcription in cell culture. In this report, we describe the gene structure for dCREB-A, protein expression patterns throughout development and the necessary role for this gene in embryogenesis. The 4.5-kb transcript is encoded in six exons that are distributed over 21 kb of DNA. There are seven start sites and no TATA consensus sequences upstream. The dCREB-A protein is expressed in the nuclei of the embryonic salivary gland, proventriculus and stomadeum. Late in embryogenesis, tracheal cell nuclei and specific nuclei within the segments show staining with anti-dCREB-A antibodies. In adult female ovaries, dCREB-A is expressed in the stage 9 through stage 11 follicle cell nuclei. Null mutations of the dCREB-A gene give rise to animals that no longer express dCREB-A protein and die late in embryogenesis before or at hatching. The absolute requirement of dCREB-A for embryogenesis demonstrates a nonredundant function for a CRE-binding protein that will be useful in studying the role of specific signal transduction cascades in development.

Drosophila CBP is a co-activator of cubitus interruptus in hedgehog signalling.

The transcription factor CBP, originally identified as a coactivator for CREB, enhances transcription mediated by many other transcription factors. Mutations in the human CBP gene are associated with Rubinstein-Taybi syndrome, a haploinsufficiency disorder characterized by abnormal pattern formation, but the mechanism by which decreased CBP levels affect pattern formation is unclear. The hedgehog (hh) signalling pathway is an important determinant of pattern formation. cubitus interruptus (ci), a component in hh signalling, encodes a transcription factor homologous to the Gli family of proteins and is required for induction of the hh-dependent expression of patched (ptc), decapentaplegic (dpp) and wingless (wg). Haploinsufficiency for the ci-related transcription factor Gli3 causes phenotypic changes in mice (known as 'extra-toes) and humans (Greig's cephalopolysyndactyly syndrome) that have similarities to Rubinstein-Taybi syndrome. Here we show that Drosophila CBP (dCBP) functions as a coactivator of Ci, suggesting that the dCBP-Ci interaction may shed light on the contribution of CBP to pattern formation in mammals.

The Drosophila dCREB-A gene is required for dorsal/ventral patterning of the larval cuticle.

We report on the characterization of the first loss-of-function mutation in a Drosophila CREB gene, dCREB-A. In the epidermis, dCREB-A is required for patterning cuticular structures on both dorsal and ventral surfaces since dCREB-A mutant larvae have only lateral structures around the entire circumference of each segment. Based on results from epistasis tests with known dorsal/ventral patterning genes, we propose that dCREB-A encodes a transcription factor that functions near the end of both the DPP- and SPI-signaling cascades to translate the corresponding extracellular signals into changes in gene expression. The lateralizing phenotype of dCREB-A mutants reveals a much broader function for CREB proteins than previously thought.

Setting limits on homeotic gene function: restraint of Sex combs reduced activity by teashirt and other homeotic genes.

Each of the homeotic genes of the HOM or HOX complexes is expressed in a limited domain along the anterior-posterior axis. Each homeotic protein directs the formation of characteristic structures, such as wings or ribs. In flies, when a heat shock-inducible homeotic gene is used to produce a homeotic protein in all cells of the embryo, only some cells respond by altering their fates. We have identified genes that limit where the homeotic gene Sex combs reduced (Scr) can affect cell fates in the Drosophila embryo. In the abdominal cuticle Scr is prevented from inducing prothoracic structures by the three bithorax complex (BX-C) homeotic genes. However, two of the BX-C homeotic genes, Ultrabithorax (Ubx) and abdominal-A (abd-A), have no effect on the ability of Scr to direct the formation of salivary glands. Instead, salivary gland induction by Scr is limited in the trunk by the homeotic gene teashirt (tsh) and in the last abdominal segment by the third BX-C gene, Abdominal-B (AbdB). Therefore, spatial restrictions on homeotic gene activity differ between tissues and result both from the regulation of homeotic gene transcription and from restraints on where homeotic proteins can function.

Isolation of Drosophila CREB-B: a novel CRE-binding protein.

CREB is a DNA-binding protein that stimulates gene transcription upon activation of the cAMP signaling pathway. The mammalian CREB protein consists of an amino-terminal transcriptional activation domain and a carboxy-terminal DNA-binding domain comprised of a basic region and a leucine zipper. Recent studies have shown that the mammalian CREB is one of many transcription factors that can bind to the cAMP regulated enhancer (CRE) sequence. Consequently, a complete understanding of regulation through the CRE sequence requires the elucidation of how the various CRE-binding proteins interact with each other. To accomplish this goal, we have begun to characterize the family of CRE-binding proteins in a system that is amenable to genetic manipulations, Drosophila melanogaster. We have previously cloned a protein designated dCREB-A from a Drosophila embryonic cDNA library. Here, we describe an additional member of the Drosophila CREB gene family, isolated by screening a lambda gt11 library of adult Drosophila head cDNAs with a multimerized CRE sequence. This protein, dCREB-B, contains 285 amino acids and is remarkably similar within the basic/zipper region to the corresponding portion of mammalian CREB. In contrast, the dCREB-B and mammalian CREB zipper domains differ considerably from the dCREB-A zipper in both length and composition. However, the putative DNA binding domains for all three proteins are highly conserved. The activator region of dCREB-B is completely different from that of both mammalian CREB and dCREB-A. Northern blot analysis shows that multiple transcripts of the dCREB-B gene are expressed in embryonic and adult tissues and that these transcripts arise from both strands of the DNA.(ABSTRACT TRUNCATED AT 250 WORDS)

A cyclic AMP-responsive element-binding transcriptional activator in Drosophila melanogaster, dCREB-A, is a member of the leucine zipper family.

In this report, we describe the isolation and initial characterization of a Drosophila protein, dCREB-A, that can bind the somatostatin cyclic AMP (cAMP)-responsive element and is capable of activating transcription in cell culture. Sequence analysis demonstrates that this protein is a member of the leucine zipper family of transcription factors. dCREB-A is unusual in that it contains six hydrophobic residue iterations in the zipper domain rather than the four or five commonly found in this group of proteins. The DNA-binding domain is more closely related to mammalian CREB than to the AP-1 factors in both sequence homology and specificity of cAMP-responsive element binding. In embryos, dCREB-A is expressed in the developing salivary gland. A more complex pattern of expression is detected in the adult; transcripts are found in the brain and optic lobe cell bodies, salivary gland, and midgut epithelial cells of the cardia. In females, dCREB-A is expressed in the ovarian columnar follicle cells, and in males, dCREB-A RNA is seen in the seminal vesicle, ejaculatory duct, and ejaculatory bulb. These results suggest that the dCREB-A transcription factor may be involved in fertility and neurological functions.