A single amino acid can determine the DNA binding specificity of homeodomain proteins

Many Drosophila developmental genes contain a DNA binding domain encoded by the homeobox. This homeodomain contains a region distantly homologous to the helix-turn-helix motif present in several prokaryotic DNA binding proteins. We investigated the nature of homeodomain-DNA interactions by making a series of mutations in the helix-turn-helix motif of the Drosophila homeodomain protein Paired (Prd). This protein does not recognize sequences bound by the homeodomain proteins Fushi tarazu (Ftz) or Bicoid (Bcd). We show that changing a single amino acid at the C-terminus of the recognition helix is both necessary and sufficient to confer the DNA binding specificity of either Ftz or Bcd on Prd. This simple rule indicates that the amino acids that determine the specificity of homeodomains are different from those mediating protein-DNA contacts in prokaryotic proteins. We further show that Prd contains two DNA binding activities. The Prd homeodomain is responsible for one of them while the other is not dependent on the recognition helix.     

Enhancer Traps in the Drosophila Bithorax Complex Mark Parasegmental Domains

Eight P elements carrying a β-galactosidase (lacZ) reporter have been mapped to sites within the Drosophila bithorax complex. The bithorax complex contains three homeotic genes, and at least nine regulatory regions which control their expression in successive parasegments of the fly. The enhancer traps inserted at the promoter of one of the genes, Ultrabithorax, express lacZ in patterns which mimic the Ultrabithorax protein pattern. Enhancer traps in the regulatory regions do not mimic the endogenous genes, but express lacZ globally in the relevant parasegments. Some P elements carry large DNA fragments upstream of the lacZ promoter but internal to the P element. In cases where these internal sequences specify a lacZ pattern, that pattern is generally suppressed when the element is inserted in the bithorax complex. In embryos mutant for genes of the Polycomb group, the lacZ expression from the enhancer traps spreads to all segments. Thus, the enhancer traps reveal parasegmental domains that are maintained by Polycomb-mediated repression. Such domains may be realized by parasegmental differences in chromatin structure.     

Genetic Characterization of the Homeodomain-Independent Activity of the Drosophila Fushi Tarazu Gene Product

The gene product of fushi tarazu (FTZ) has a homeodomain (HD)-independent activity. Ectopic expression of a FTZ protein that lacks half the HD in embryos results in the anti-ftz phenotype. We have characterized this FTZ HD-independent activity further. Ectopic expression of the HD-independent FTZ activity, in the absence of FTZ activity expressed from the endogenous ftz gene, was sufficient to result in the anti-ftz phenotype. Since the anti-ftz phenotype is a first instar larvae composed nearly entirely of FTZ-dependent cuticular structures derived from the even-numbered parasegments, this result suggests that expression of the HD-independent FTZ activity is sufficient to establish FTZ-dependent cuticle. Activation of FTZ-dependent Engrailed (EN) expression and activation of the ftz enhancer were HD-independent. The ftz enhancer element, AE-1, was activated by the HD-independent FTZ activity; however, the ftz enhancer element, AE-BS2CCC, which is the same as AE-1 except for the inactivation of two FTZ HD DNA-binding sites, was not. Activation of the ftz enhancer by ectopic expression of FTZ activity was effective only during gastrulation and germ band extension. In the discussion, we propose an explanation for these results.     

Tissue-specific requirements for a phosphorylation site in the Fushi tarazu homeodomain

 The homeodomain protein Fushi tarazu (Ftz) is required for several embryonic patterning processes including segmentation and neurogenesis. During the stages that these processes are regulated the protein is differentially phosphorylated, suggesting that phosphorylation plays a role in helping the protein to regulate different functions in different tissues. We showed in a recent study that one of the Ftz phosphorylation sites, a protein kinase A-type site in the N-terminal arm of the homeodomain, is required for normal Ftz-dependent segmentation. Here we test whether phosphorylation of this site (Thr-263) is also required in the developing central nervous system (CNS). A well-established role for Ftz in the CNS is for the differentiation of neurons referred to as RP2 neurons. Absence of Ftz expression in these cells causes a failure of certain target genes to be expressed and subsequent defects in RP2 differentiation. In contrast to its effect on segmentation, we find that mutation of Thr-263 to Ala (or Asp) has no effect on these CNS functions. This suggests that the phosphorylation state of this site is irrelevant for Ftz function in the CNS, and that there are tissue-specific differences in the requirements for Ftz phosphorylation. Received: 28 February 1999 / Accepted: 10 March 1999