DEAF-1, a novel protein that binds an essential region in a Deformed response element.

A 120 bp homeotic response element that is regulated specifically by Deformed in Drosophila embryos contains a single binding site for Deformed protein. However, a 24 bp sub-element containing this site does not constitute a Deformed response element. Specific activation requires a second region in the 120 bp element, which presumably contains one or more binding sites for Deformed cofactors. We have isolated a novel protein from Drosophila nuclear extracts which binds specifically to a site in this second region. This protein, which we call DEAF-1 (Deformed epidermal autoregulatory factor-1), contains three conserved domains. One of these includes a cysteine repeat motif that is similar to a motif found in Drosophila Nervy and the human MTG8 proto-oncoprotein, and another matches a region of Drosophila Trithorax. Mutations in the response element designed to improve binding to DEAF-1 in vitro resulted in increased embryonic expression. Conversely, small mutations designed to diminish binding to DEAF-1 resulted in reduced expression of the element. Thus, DEAF-1 is likely to contribute to the functional activity, and perhaps to the homeotic specificity, of this response element. Consistent with this hypothesis, we have discovered DEAF-1 binding sites in other Deformed response elements.     

Antp-type homeodomains have distinct DNA binding specificities that correlate with their different regulatory functions in embryos.

Much of the functional specificity of Drosophila homeotic selector proteins, in their ability to regulate specific genes and to assign specific segmental identities, appears to map within their different, but closely related homeodomains. For example, the Drosophila Dfd and human HOX4B (Hox 4.2) proteins, which have extensive structural similarity only in their respective homeodomains, both specifically activate the Dfd promoter. In contrast, a chimeric Dfd protein containing the Ubx homeodomain (Dfd/Ubx) specifically activates the Antp P1 promoter, which is normally targeted by Ubx. Using a variety of DNA binding assays, we find significant differences in DNA binding preferences between the Dfd, Dfd/Ubx and Ubx proteins when Dfd and Antp upstream regulatory sequences are used as binding substrates. No significant differences in DNA binding specificity were detected between the human HOX4B (Hox 4.2) and Drosophila Dfd proteins. All of these full-length proteins bound as monomers to high affinity DNA binding sites, and interference assays indicate that they interact with DNA in a way that is very similar to homeodomain polypeptides. These experiments indicate that the ninth amino acid of the recognition helix of the homeodomain, which is glutamine in all four of these Antp-type homeodomain proteins, is not sufficient to determine their DNA binding specificities. The good correlation between the in vitro DNA binding preferences of these four Antp-type homeodomain proteins and their ability to specifically regulate a Dfd enhancer element in the embryo, suggests that the modest binding differences that distinguish them make an important contribution to their unique regulatory specificities.     

Two E2 binding sites alone are sufficient to function as the minimal origin of replication of human papillomavirus type 18 DNA.

Replication of papillomaviruses requires an origin of replication and two virus-encoded proteins, E1 and E2. Using a transient replication assay for human papillomavirus type 18 (HPV-18) DNA, we have found that two adjacent sequences present within the origin of replication can independently support replication. The first, a 77-bp region, contains one E2 binding site (E2BS) and a 16-bp inverted repeat element that probably corresponds to the E1 binding site (E1BS). The other, an 81-bp region, includes two E2BS but lacks the putative E1BS. A synthetic 33-bp oligonucleotide containing two high-affinity E2BS was also found to function as an origin of replication. Replication of all these plasmids was absolutely dependent on the presence of the HPV-18 E1 and E2 proteins. The HPV-1a E1 and E2 proteins were also found to support replication of a plasmid containing the complete HPV-18 origin but failed to replicate a plasmid containing two E2BS alone. Our results suggest that the E2 protein can target E1 to the origin through the formation of an E1-E2 complex which is likely to be involved the initiation of replication.     

Specific DNA binding of the two chicken Deformed family homeodomain proteins, Chox-1.4 and Chox-a.

The cDNA clones encoding two chicken Deformed (Dfd) family homeobox containing genes Chox-1.4 and Chox-a were isolated. Comparison of their amino acid sequences with another chicken Dfd family homeodomain protein and with those of mouse homologues revealed that strong homologies are located in the amino terminal regions and around the homeodomains. Although homologies in other regions were relatively low, some short conserved sequences were also identified. E. coli-made full length proteins were purified and used for the production of specific antibodies and for DNA binding studies. The binding profiles of these proteins to the 5'-leader and 5'-upstream sequences of Chox-1.4 and Chox-a coding regions were analyzed by immunoprecipitation and DNase I footprint assays. These two Chox proteins bound to the same sites in the 5'-flanking sequences of their coding regions with various affinities and their binding affinities to each site were nearly the same. The consensus sequences of the high and low affinity binding sites were TAATGA(C/G) and CTAATTTT, respectively. A clustered binding site was identified in the 5'-upstream of the Chox-a gene, suggesting that this clustered binding site works as a cis-regulatory element for auto- and/or cross-regulation of Chox-a gene expression.     

Autoregulation of a Drosophila homeotic selector gene

The Deformed (Dfd) gene is a homeotic selector that functions in specifying the identity of the mandibular and maxillary segments. We have constructed transformed fly strains carrying a Dfd cDNA under the heat-inducible control of the hsp70 promoter. With these strains we can induce the ectopic expression of Dfd protein in other segments at various stages of embryonic development. We find that both early and persistent synthesis of the protein is required for the transformation of other body segments toward head segmental identity. The persistent expression of the Dfd protein requires an endogenous copy of the Dfd gene, and we show that the expression of the endogenous copy can be induced by hsDfd expression. This implies that the Dfd protein autoactivates expression from the Dfd locus during normal development. The autoactivation circuit supplies a simple mechanism that can account, in part, for the stability of the determined state controlled by Dfd.     

Mutational analysis of the 18-base-pair inverted repeat element at the bovine papillomavirus origin of replication: identification of critical sequences for E1 binding and in vivo replication.

Replication of bovine papillomavirus requires two viral proteins, E1 and E2-TA. Previously we demonstrated that sequences within an imperfect 18-bp inverted repeat (IR) element were sufficient to confer specific binding of the E1 protein to the origin region (S. E. Holt, G. Schuller, and V. G. Wilson, J. Virol. 68:1094-1102, 1994). To identify critical nucleotides for E1 binding and origin function, a series of individual point mutations was constructed at each nucleotide position in the 18-bp IR. Binding of E1 to these point mutations established that both the position of the mutation and the specific nucleotide change were important for the E1-DNA interaction. Equivalent mutations from each half of the IR exhibited similar binding, suggesting that the halves were functionally symmetric for E1 interactions. Each of these mutations was evaluated also for origin function in vivo by a transient-replication assay. No single point mutation eliminated replication capacity completely, though many mutants were severely impaired, demonstrating an important functional contribution for the E1 binding site. Furthermore, E1 binding was not sufficient for replication, as several origin mutants bound E1 well in vitro but replicated poorly in vivo. This suggests that certain nucleotides within the 18-bp IR may be involved in postbinding events necessary for replication initiation. The results with the point mutations suggest that E1-E1 interactions are important for stable complex formation and also indicate that there is some flexibility with regard to formation of a functional E1 replication complex at the origin.     

A genetic and developmental analysis of mutations in the Deformed locus in Drosophila melanogaster

Individuals expressing recessive mutations in the Deformed (Dfd) locus of Drosophila melanogaster were examined for embryonic and adult defects. Mutant embryos were examined in both scanning electron microscope and light microscope preparations. The adult Dfd recessive mutant phenotype was assessed in somatic clones and in survivors homozygous for hypomorphic alleles of the gene. The time of Dfd+ action was determined by studying a temperature conditional allele. Dfd+ is required in three embryonic cephalic segments to form a normal head. Mutant embryos of Dfd display defects in derivatives of the maxillary segment, of the mandibular segment, and of some more anterior segments. In the adult fly, defects are seen in the posterior aspect of the head when the gene is mutant. A transformation from head to thoracic-like tissue is seen dorsally and a deletion of structures is seen ventrally. Shift studies utilizing a temperature conditional allele have shown that the gene product is necessary during at least two periods of development, during embryonic segmentation and head involution and during the late larval and pupal stages. From these studies we conclude that Dfd is a homeotic gene necessary for proper specification of both the embryonic and the adult head.     

Characterization of the Tribolium Deformed ortholog and its ability to directly regulate Deformed target genes in the rescue of a Drosophila Deformed null mutant

 We have analyzed the Tribolium castaneum ortholog of the Drosophila homeotic gene Deformed (Dfd) and determined its expression pattern during embryogenesis in this beetle. Tc Deformed (Tc Dfd) is expressed in the blastoderm and the condensing germ rudiment in a region that gives rise to gnathal segments. During germ band extension Tc Dfd is expressed in the mandibular and maxillary segments, their appendages, and the dorsal ridge. Comparison of insect Dfd protein sequences reveals several highly conserved regions. To determine whether common molecular features reflect conserved regulatory functions we used the Gal4 system to express the Tribolium protein in Drosophila embryos. When Tc Dfd is expressed throughout embryonic ectoderm under the control of P69B, the beetle protein autoregulates the endogenous Dfd gene. In addition, the Drosophila proboscipedia gene (a normal target of Dfd) is ectopically activated in the antennal and thoracic segments. We also compared the ability of the beetle and fly proteins to rescue defects in Dfd ^– mutants by expressing each throughout the embryonic during embryogenesis. Both proteins rescued Dfd ^– defects to the same extent in that they each restore the development of mouth hooks and cirri, as well as cause gain-of-function abnormalities of posterior mouth parts. As before, pb was ectopically activated in the antennal segment. This is the first demonstration of the ability of a heterologous homeotic selector protein to directly regulate a target gene independent of an endogenous Drosophila autoregulatory loop. Received: 11 December 1998 / Accepted: 8 March 1999     

Developmental and evolutionary implications of labial, Deformed and engrailed expression in the Drosophila head.

Prior developmental genetic analyses have shown that labial (lab) and Deformed (Dfd) are homeotic genes that function in the development of the embryonic (larval) and adult head. Using antibody probes to reveal the spatial distribution of the lab and Dfd proteins in embryonic and imaginal tissues, we have assessed the respective roles of these genes through an analysis of the correspondence of their expression patterns with their mutant phenotypes. With regard to imaginal development, lab and Dfd occupy adjacent non-overlapping expression domains in the peripodial cell layer of the eye-antennal disc, in patterns that are consistent with their adult mutant phenotypes and published fate maps. During embryogenesis, lab and Dfd exhibit limited overlapping expression in areas that are of no obvious significance to the development of larval head structures, but also in areas that may have consequences for imaginal development. The head of Drosophila and other cyclorrhaphous Dipterans is characterized by an extreme morphological difference between the larval and adult stages. Given this unique ontogenetic and phylogenetic history and the observation that homeotic transformations produced by the lab, Dfd, and proboscipedia (pb) loci are manifested only in the adult, we suggest that distinct regulatory paradigms evolved for homeotic gene function in the development of the larval versus adult head. Finally, a detailed examination of the engrailed (en) expression pattern in the embryonic head strengthens the view of insect morphologists that the clypeolabrum evolved from the fusion of paired labral appendages.