A complex role for distal-less in crustacean appendage development.

The developing leg of Drosophila is initially patterned by subdivision of the leg into proximal and distal domains by the activity of the homeodomain proteins Extradenticle (Exd) and Distal-less (Dll). These early domains of gene expression are postulated to reflect a scenario of limb evolution in which an undifferentiated appendage outgrowth was subdivided into two functional parts, the coxapodite and telopodite. The legs of most arthropods have a more complex morphology than the simple rod-shaped leg of Drosophila. We document the expression of Dll and Exd in two crustacean species with complex branched limbs. We show that in these highly modified limbs there is a Dll domain exclusive of Exd but there is also extensive overlap in Exd and Dll expression. While arthropod limbs all appear to have distinct proximal and distal domains, those domains do not define homologous structures throughout arthropods. In addition, we find a striking correlation throughout the proximal/distal extent of the leg between setal-forming cells and Dll expression. We postulate that this may reflect a pleisiomorphic function of Dll in development of the peripheral nervous system. In addition, our results confirm previous observations that branch formation in multiramous arthropod limbs is not regulated by a simple iteration of the proximal/distal patterning module employed in Drosophila limb development.     

Patterning of the branched head appendages in Schistocerca americana and Tribolium castaneum

Much of our understanding of arthropod limb development comes from studies on the leg imaginal disc of Drosophila melanogaster. The fly limb is a relatively simple unbranched (uniramous) structure extending out from the body wall. The molecular basis for this outgrowth involves the overlap of two signaling molecules, Decapentaplegic (Dpp) and Wingless (Wg), to create a single domain of distal outgrowth, clearly depicted by the expression of the Distal-less gene (Dll). The expression of wg and dpp during the development of other arthropod thoracic limbs indicates that these pathways might be conserved across arthropods for uniramous limb development. The appendages of crustaceans and the gnathal appendages of insects, however, exhibit a diverse array of morphologies, ranging from those with no distal elements, such as the mandible, to appendages with multiple distal elements. Examples of the latter group include branched appendages or those that possess multiple lobes; such complex morphologies are seen for many crustacean limbs as well as the maxillary and labial appendages of many insects. It is unclear how, if at all, the known patterning genes for making a uniramous limb might be deployed to generate these diverse appendage forms. Experiments in Drosophila have shown that by forcing ectopic overlaps of Wg and Dpp signaling it is possible to generate artificially branched legs. To test whether naturally branched appendages form in a similar manner, we detailed the expression patterns of wg, dpp, and Dll in the development of the branched gnathal appendages of the grasshopper, Schistocerca americana, and the flour beetle, Tribolium castaneum. We find that the branches of the gnathal appendages are not specified through the redeployment of the Wg-Dpp system for distal outgrowth, but our comparative studies do suggest a role for Dpp in forming furrows between tissues.     

<Emphasis Type="Italic">Proboscipedia</Emphasis> represses distal signaling in the embryonic gnathal limb fields of<Emphasis Type="Italic"> Tribolium castaneum</Emphasis>

Orthologs of the Hox genes Sex combs reduced ( Scr) and proboscipedia ( pd) are active in the developing labial appendages of all insect species tested. The remarkable variation among insect gnathal structures, particularly in the distal podomeres, suggests two Hox genes may enhance the adaptive potential of gnathal appendage morphology. Functional studies in the fruitfly Drosophila melanogaster, the flour beetle Tribolium castaneum and the milkweed bug Oncopeltus fasciatus show that cooperation between Scr and pb has been generally conserved, but specific mechanisms have been altered during evolution. Cross-regulation of pb by Scr is evident in Drosophila and Tribolium, the more closely related of the three species, but not in Oncopeltus. In all three species, pb function is restricted to the distal podomeres, but details are only known for Drosophila and Oncopeltus, two species exhibiting specialized stylate-haustellate mouthparts. Drosophila pb is required for distal Scr expression, and to repress the appendage patterning genes dachshund and Distal-less ( Dll). Oncopeltus pb has the novel capacity to specify leg fates. Little is known about distal functions of Tribolium pb. Hypomorphic mutations of the Tribolium pb ortholog maxillopedia can be arranged in a graded phenotypic series of palp to leg transformations along both the proximodistal and dorsoventral axes. Mid-embryonic expression profiles of Tribolium pb, Scr, wingless ( wg) and Dll genes were examined in maxillopedia hypomorphic and null mutant backgrounds. Levels of pb and Scr are significantly reduced in the distal appendage field. Tribolium pb therefore positively regulates distal Scr expression, a role that it has in common with Drosophila pb. Tribolium wg is normally down-regulated in the distal domain of the embryonic gnathal appendage buds. It becomes activated distally in maxillopedia hypomorphs. Repression of wg by pb has not been reported in the labial imaginal discs of Drosophila. Alterations of Tribolium Scr and wg expression occur in Dll-expressing cells, however, unlike in Drosophila labial imaginal discs, Dll expression appears unaffected in pb hypomorphic backgrounds. We conclude that the Hox genes Sex combs reduced and proboscipedia control an appendage organizer and cell autonomous fate determination during embryonic labial palp development in Tribolium.     

Expression of dachshund in wild-type and Distal-less mutant Tribolium corroborates serial homologies in insect appendages

We isolated the homologue of the Drosophila gene dachshund (dac) from the beetle Tribolium castaneum. Tc'dac is expressed in all appendages except urogomphi and pleuropodia. Tc'dac is also active in the head lobes, in the ventral nervous system, in the primordia of the Malpighian tubules and in bilateral stripes corresponding to the presumptive dorsal midline. Expression of Tc'dac in the labrum lends support to the interpretation that the insect labrum is derived from a metameric appendage. The legs of Tribolium accommodate two Tc'dac domains, of which the more distal one corresponds to the single dac domain described for Drosophila leg discs. In contrast to Drosophila, where this domain is thought to intercalate between the homothorax (hth) and the Distal-less (Dll) domains, in Tribolium it arises from within the Dll domain. In embryos mutant for the Tc'Dll gene we find that the distal Tc'dac domain in the legs, as well as the expression in the labrum, are deleted while the proximal leg domain and the mandibular expression are unaffected. Based on Tc'dac expression in wild-type and mutant embryos, we demonstrate serial homology of the complete mandible with the coxa of the thoracic legs, which affirms the gnathobasic nature of the insect mandible.     

The Sp8 zinc-finger transcription factor is involved in allometric growth of the limbs in the beetle Tribolium castaneum

Members of the Sp gene family are involved in a variety of developmental processes in both vertebrates and invertebrates. We identified the ortholog of the Drosophila Sp-1 gene in the red flour beetle Tribolium castaneum, termed T-Sp8 because of its close phylogenetic relationship to the vertebrate Sp8 genes. During early embryogenesis, T-Sp8 is seen in segmental stripes. During later stages, TSp8 is dynamically expressed in the limb buds of the Tribolium embryo. At the beginning of bud formation, TSp8 is uniformly expressed in all body appendages. As the limbs elongate, a ring pattern develops sequentially and the expression profile at the end of embryogenesis correlates with the final length of the appendage. In limbs that do not grow out like the labrum and the labium, T-Sp8 expression remains uniform, whereas a two-ring pattern develops in the longer antennae and the maxillae. In the legs that elongate even further, four rings of T-Sp8 expression can be seen at the end of leg development. The role of T-Sp8 for appendage development was tested using RNAi. Upon injection of double stranded T-Sp8 RNA, larvae develop with dwarfed appendages. Affected T-Sp8(RNAi) legs were tested for the presence of medial and distal positional values using the expression marker genes dachshund and Distal-less, respectively. The results show that a dwarfed TSp8(RNAi) leg consists of proximal, medial and distal parts and argues against T-Sp8 being a leg gap gene. Based on the differential expression pattern of T-Sp8 in the appendages of the head and the thorax and the RNAi phenotype, we hypothesise that T-Sp8 is involved in the regulation of limb-length in relation to body size - a process called allometric growth.     

Analysis of maxillopedia expression pattern and larval cuticular phenotype in wild-type and mutant tribolium

The Tribolium castaneum homeotic gene maxillopedia (mxp) is the ortholog of Drosophila proboscipedia (pb). Here we describe and classify available mxp alleles. Larvae lacking all mxp function die soon after hatching, exhibiting strong transformations of maxillary and labial palps to legs. Hypomorphic mxp alleles produce less severe transformations to leg. RNA interference with maxillopedia double-stranded RNA results in phenocopies of mxp mutant phenotypes ranging from partial to complete transformations. A number of gain-of-function (GOF) mxp alleles have been isolated based on transformations of adult antennae and/or legs toward palps. Finally, we have characterized the mxp expression pattern in wild-type and mutant embryos. In normal embryos, mxp is expressed in the maxillary and labial segments, whereas ectopic expression is observed in some GOF variants. Although mxp and Pb display very similar expression patterns, pb null embryos develop normally. The mxp mutant larval phenotype in Tribolium is consistent with the hypothesis that an ancestral pb-like gene had an embryonic function that was lost in the lineage leading to Drosophila.     

The appendage role of insect disco genes and possible implications on the evolution of the maggot larval form

Though initially identified as necessary for neural migration, Disconnected and its partially redundant paralog, Disco-related, are required for proper head segment identity during Drosophila embryogenesis. Here, we present evidence that these genes are also required for proper ventral appendage development during development of the adult fly, where they specify medial to distal appendage development. Cells lacking the disco genes cannot contribute to the medial and distal portions of ventral appendages. Further, ectopic disco transforms dorsal appendages toward ventral fates; in wing discs, the medial and distal leg development pathways are activated. Interestingly, this appendage role is conserved in the red flour beetle, Tribolium (where legs develop during embryogenesis), yet in the beetle we found no evidence for a head segmentation role. The lack of an embryonic head specification role in Tribolium could be interpreted as a loss of the head segmentation function in Tribolium or gain of this function during evolution of flies. However, we suggest an alternative explanation. We propose that the disco genes always function as appendage factors, but their appendage nature is masked during Drosophila embryogenesis due to the reduction of limb fields in the maggot style Drosophila larva.     

Modes of morphogen cooperation for limb formation in vertebrates and insects.

Diffusing morphogens in cooperation can control gene expression in developing limbs. Additive cooperation corresponds to the Boolean operator OR and implies the equivalent action of the (suitably scaled) concentrations of two morphogens, either by their alternative binding to the same receptor or by another way of convergence of their effects during the signal transduction procedure. This cooperation can explain the spatial and temporal collinearities of the expression of hoxd genes in the vertebrate limb bud. A multiplicative cooperation of morphogens (corresponding to the Boolean operator AND), produced at the DPP and WG domains in the Drosophila leg imaginal disc, may account for the expression domains observed for Dll and dac. A molecular interpretation of the multiplicative morphogen cooperation is proposed. Some experiments are suggested for further testing of the model.     

Maintenance of segment and appendage primordia by the Tribolium gene knödel

For homeotic and segment-polarity genes in Drosophila, a switch in gene regulation has been described that distinguishes patterning and maintenance phases. Maintenance of segment and organ primordia involves secondary patterning and differentiation steps, as well as survival factors regulating proliferation and organ size. In a screen for embryonic lethal mutations in the flour beetle Tribolium castaneum, we have recovered two alleles of the kn?del gene, which result in short, bag-like embryos. These embryos have severely reduced appendages and differentiate a cuticle that lacks most overt signs of segmentation. In addition, they lack bristles and display defects in the nervous system. Early patterning in kn?del mutant embryos is normal up to the extended germ band stage, as indicated by the formation of regular even-skipped (Tc'eve) and wingless (Tc'wg) stripes. Afterwards, however, these patterns degenerate. Similarly, proximo-distal growth and patterning of limbs are nearly normal initially, but limb primordia shrink, and proximo-distal patterns degenerate, during subsequent stages. kn?del could be a segment polarity gene required for segment border maintenance in both trunk and appendages. Alternatively, it may have a more general role in tissue or organ maintenance.     

昆虫腹肢发育相关基因的研究进展

昆虫躯干外着生有一系列附属器官,主要包括背侧附器和腹侧附器,其中腹肢的多样性表现尤为突出。腹肢的发育过程受到多种调控因子的作用。本文就腹肢发育相关基因的表达、功能及调控因子间的相互作用等方面进行简要的综述。一方面,腹肢作为整体受Hox基因和成形素基因（Dpp/Wg）的调控,Hox基因直接决定腹肢的有无,Dpp/Wg通过其表达产物形成浓度梯度调控整个腹肢的发育,两者在腹肢整体发育中的作用不可取代。另一方面,腹肢基部、中部及远端部位分别受到各自特异的调控因子的作用。其中hth,tsh及al等均主要调节腹肢基部的发育,dac通过与Dll和Dpp/Wg相互作用从而调节腹肢中部的发育,bab,Dll及Lim1等对腹肢远端发育发挥重要作用。关节的形成对腹肢分节的形成至关重要,Notch信号通路相关因子如配体基因Dl和Ser,修饰物基因fng及下游靶基因odd,sob,drm和bowl等调节该过程。因此,研究昆虫腹肢发育相关基因,对于深入揭示腹肢的发育及其在进化过程中多样性形成的分子机制具有至关重要的作用。