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.     

Antagonistic roles for Ultrabithorax and Antennapedia in regulating segment-specific apoptosis of differentiated motoneurons in the Drosophila embryonic central nervous system

The generation of morphological diversity among segmental units of the nervous system is crucial for correct matching of neurons with their targets and for formation of functional neuromuscular networks. However, the mechanisms leading to segment diversity remain largely unknown. We report here that the Hox genes Ultrabithorax (Ubx) and Antennapedia (Antp) regulate segment-specific survival of differentiated motoneurons in the ventral nerve cord of Drosophila embryos. We show that Ubx is required to activate segment-specific apoptosis in these cells, and that their survival depends on Antp. Expression of the Ubx protein is strongly upregulated in the motoneurons shortly before they undergo apoptosis, and our results indicate that this late upregulation is required to activate reaper-dependent cell death. We further demonstrate that Ubx executes this role by counteracting the function of Antp in promoting cell survival. Thus, two Hox genes contribute to segment patterning and diversity in the embryonic CNS by carrying out opposing roles in the survival of specific differentiated motoneurons.     

Hox gene duplication and deployment in the annelid leech Helobdella

SUMMARY The segmented leeches are members of the phylum Annelida within the Lophotrochozoa. Here, we describe the isolation of a new Hox gene, Lox18 , in the leech Helobdella triserialis. Phylogenetic analysis indicates that Lox18 is a Deformed ( Dfd   ) ortholog. H. triserialis has at least two Dfd orthologs, Lox18 and the previously described Lox6 ( Kourakis et al. 1997 ; Wong and Macagno 1998 ), indicating that these genes duplicated after the last common ancestor of annelids and arthropods. Although the temporal appearance of Lox18 message is similar to that of Lox6 , the spatial pattern is different. Lox18 does not have a sharply defined anterior border of expression in the second neuromere of the subesophageal ganglion of the central nervous system (CNS) as does Lox6 , but is expressed uniformly in a small subset of cells in the longitudinal connectives and lateral roots in every segment of the CNS along the entire anterior-posterior (AP) axis. Even though Lox18 shares greater sequence similarity within the homeodomain and flanking regions to Drosophila Dfd than to the previously isolated Lox6 , its expression pattern suggests that its function has diverged from the ancestral Hox function. Previous sampling has indicated that the last common ancestor of protostomes and deuterostomes had as many as 10 clustered Hox genes representing distinct paralogy groups ( Irvine et al. 1997 ; de Rosa et al. 1999 ); leech Hox genes may have undergone subsequent and independent cluster or genome-wide duplication. These results point to the need for total genome level understanding for key members of the Lophotrochozoa.     

RNAi analysis of Deformed, proboscipedia and Sex combs reduced in the milkweed bug Oncopeltus fasciatus: novel roles for Hox genes in the hemipteran head

Insects have evolved a large variety of specialized feeding strategies, with a corresponding variability in mouthpart morphology. We have, however, little understanding of the developmental mechanisms that underlie this diversity. Until recently it was difficult to perform any analysis of gene function outside of the genetic model insects Drosophila melanogaster and Tribolium castaneum. In this paper, we report the use of dsRNA-mediated interference (RNAi) to dissect gene function in the development of the milkweed bug Oncopeltus fasciatus, which has specialized suctorial mouthparts. The Hox genes Deformed (Dfd), proboscipedia (pb) and Sex combs reduced (Scr) have previously been shown to be expressed in the gnathal appendages of this species. Strikingly, the milkweed bug was found to have an unusual expression pattern of pb. Here, by analyzing single and combination RNAi depletions, we find that Dfd, pb and Scr are used in the milkweed bug to specify the identity of the mouthparts. The exact roles of the genes, however, are different from what is known in the two genetic model insects. The maxillary appendages in the bug are determined by the activities of the genes Dfd and Scr, rather than Dfd and pb as in the fly and beetle. The mandibular appendages are specified by Dfd, but their unique morphology in Oncopeltus suggests that Dfd's target genes are different. As in flies and beetles, the labium is specified by the combined activities of pb and Scr, but again, the function of pb appears to be different. Additionally, the regulatory control of pb by the other two genes seems to be different in the bug than in either of the other species. These novelties in Hox function, expression pattern and regulatory relationships may have been important for the evolution of the unique Hemipteran head.     

Segment-specific prevention of pioneer neuron apoptosis by cell-autonomous, postmitotic Hox gene activity

In vertebrates, neurons often undergo apoptosis after differentiating and extending their axons. By contrast, in the developing nervous system of invertebrate embryos apoptosis typically occurs soon after cells are generated. Here, we show that the Drosophila dMP2 and MP1 pioneer neurons undergo segment-specific apoptosis at late embryonic stages, long after they have extended their axons and have performed their pioneering role in guiding follower axons. This segmental specificity is achieved by differential expression of the Hox gene Abdominal B, which in posterior segments prevents pioneer neuron death postmitotically and cell-autonomously by repressing the RHG-motif cell death activators reaper and grim. Our results identify the first clear case of a cell-autonomous and anti-apoptotic role for a Hox gene in vivo. In addition, they provide a novel mechanism linking Hox positional information to differences in neuronal architecture along the anteroposterior axis by the selective elimination of mature neurons.     

Hox gene sequences from the geophilomorph centipede Pachymerium ferrugineum (C. L. Koch, 1835) (Chilopoda: Geophilomorpha: Geophilidae): implications for the evolution of the Hox class genes of arthropods.

Here we report on a partial screen for Hox gene sequences from the geophilomorph centipede Pachymerium ferrugineum, resulting in 11 different sequences. All of these sequences could be homologized to specific Drosophila genes, yielding two representatives for the Dfd class and one each for the remaining classes. Phylogenetic analysis of these data with a broad sample of arthropod/onychophoran homologous sequences confirmed these results and provided further support for the monophyly of the Hox3/zen class. Conversely, the phylogenetic status of ftz-type genes remains uncertain. Our results complement the previous partial findings for two other centipedes (the scolopendromorph Ethmostigmus rubripes and the lithobiomorph Lithobius forficatus) and confirm the expectation that in myriapods, too, all Hox genes classes are present. This suggests that even the Chilopoda, with uniform trunk segments, have the same number of Hox genes as the more tagmatized Insecta.