Evolution of <Emphasis Type="Italic">Hox3</Emphasis> and <Emphasis Type="Italic">ftz</Emphasis> in arthropods: insights from the crustacean <Emphasis Type="Italic">Daphnia pulex</Emphasis>

The Drosophila melanogaster genes zerknüllt (zen) and fushi tarazu (ftz) are members of the Hox gene family whose roles have changed significantly in the insect lineage and thus provide an opportunity to study the mechanisms underlying the functional evolution of Hox proteins. We have studied the expression of orthologs of zen (DpuHox3) and ftz (Dpuftz) in the crustacean Daphnia pulex (Branchiopoda), both of which show a dynamic expression pattern. DpuHox3 is expressed in a complex pattern in early embryogenesis, with the most anterior boundary of expression lying at the anterior limit of the second antennal segment as well as a ring of expression around the embryo. In later embryos, DpuHox3 expression is restricted to the mesoderm of mandibular limb buds. Dpuftz is first expressed in a ring around the embryo following the posterior limit of the mandibular segment. Later, Dpuftz is restricted to the posterior part of the mandibular segment. This is the first report of expression of a Hox3 ortholog in a crustacean, and together with Dpuftz data, the results presented here show that Hox3 and ftz have retained a Hox-like expression pattern in crustaceans. This is in accordance with the proposed model of Hox3 and ftz evolution in arthropods and allows a more precise pinpointing of the loss of ftz “Hox-like behaviour”: in the lineage between the Branchiopoda and the basal insect Thysanura.     

Molecular mechanisms of segmental patterning in the vertebrate hindbrain and neural crest

Recent work has shown that segmentation underlies the patterning of the vertebrate hindbrain and its neural crest derivatives. Several genes have been identified with segment-restricted expression, and evidence is now emerging regarding their function and regulatory relationships. The expression patterns of Hox genes and the phenotype of null mutants indicate roles in specifying segment identity. A zinc finger gene Krox-20 is a segment-specific regulator of Hox expression, and it seems probable that retinoic acid receptors also regulate Hox genes in the hindbrain. The receptor tyrosine kinase gene Sek may mediate cell-cell interactions that lead to segmentation. These studies provide a starting point for understanding the molecular basis of segmental patterning in the hindbrain.     

<Emphasis Type="Italic">hedgehog</Emphasis> is a segment polarity gene in a crustacean and a chelicerate

The evolution of arthropod segmentation has been studied by comparing expression patterns of pair-rule and segment polarity genes in various species. In Drosophila, the formation and maintenance of the parasegmental boundaries depend on the interactions between the wingless (wg), engrailed (en) and hedgehog (hh) genes. Until now, the expression pattern of hh has not been analysed to such a great extent as en or wg. We report the cloning and expression analysis of hh genes from Euscorpius flavicaudis, a chelicerate, and Artemia franciscana, a branchiopod crustacean. Our data provide evidence that hh, being expressed in the posterior part of every segment, is a segment polarity gene in both organisms. Additional hh expression sites were observed in the rostrum and appendages of Euscorpius and in the gut of Artemia. From the available data on hh expression in various bilaterians, we review the various hypotheses on the evolution of hh function and we suggest an ancestral role of hh in proctodeum specification and gut formation.Edited by D. Tautz     

Gene expression suggests conserved mechanisms patterning the heads of insects and myriapods

Segmentation, i.e. the subdivision of the body into serially homologous units, is one of the hallmarks of the arthropods. Arthropod segmentation is best understood in the fly Drosophila melanogaster. But different from the situation in most arthropods in this species all segments are formed from the early blastoderm (so called long-germ developmental mode). In most other arthropods only the anterior segments are formed in a similar way (so called short-germ developmental mode). Posterior segments are added one at a time or in pairs of two from a posterior segment addition zone. The segmentation mechanisms are not universally conserved among arthropods and only little is known about the genetic patterning of the anterior segments. Here we present the expression patterns of the insect head patterning gene orthologs hunchback (hb), orthodenticle (otd), buttonhead-like (btdl), collier (col), cap-n-collar (cnc) and crocodile (croc), and the trunk gap gene Krüppel (Kr) in the myriapod Glomeris marginata. Conserved expression of these genes in insects and a myriapod suggests that the anterior segmentation system may be conserved in at least these two classes of arthropods. This finding implies that the anterior patterning mechanism already existed in the last common ancestor of insects and myriapods.     

Expression of <Emphasis Type="Italic">Pax group III</Emphasis> genes in the honeybee (<Emphasis Type="Italic">Apis mellifera</Emphasis>)

Pax group III genes are involved in a number of processes during insect segmentation. In Drosophila melanogaster, three genes, paired, gooseberry and gooseberry-neuro, regulate segmental patterning of the epidermis and nervous system. Paired acts as a pair-rule gene and gooseberry as a segment polarity gene. Studies of Pax group III genes in other insects have indicated that their expression is a good marker for understanding the underlying molecular mechanisms of segmentation. We have cloned three Pax group III genes from the honeybee (Apis mellifera) and examined their relationships to other insect Pax group III genes and their expression patterns during honeybee segmentation. The expression pattern of the honeybee homologue of paired is similar to that of paired in Drosophila, but its expression is modulated by anterior–posterior temporal patterning similar to the expression of Pax group III proteins in Tribolium. The expression of the other two Pax group III genes in the honeybee indicates that they also act in segmentation and nervous system development, as do these genes in other insects.     

Hedgehog signaling pathway function conserved in Tribolium segmentation

In Drosophila, maintenance of parasegmental boundaries and formation of segmental grooves depend on interactions between segment polarity genes. Wingless and Engrailed appear to have similar roles in both short and long germ segmentation, but relatively little is known about the extent to which Hedgehog signaling is conserved. In a companion study to the Tribolium genome project, we analyzed the expression and function of hedgehog, smoothened, patched, and cubitus interruptus orthologs during segmentation in Tribolium. Their expression was largely conserved between Drosophila and Tribolium. Parental RNAi analysis of positive regulators of the pathway (Tc-hh, Tc-smo, or Tc-ci) resulted in small spherical cuticles with little or no evidence of segmental grooves. Segmental Engrailed expression in these embryos was initiated but not maintained. Wingless-independent Engrailed expression in the CNS was maintained and became highly compacted during germ band retraction, providing evidence that derivatives from every segment were present in these small spherical embryos. On the other hand, RNAi analysis of a negative regulator (Tc-ptc) resulted in embryos with ectopic segmental grooves visible during germband elongation but not discernible in the first instar larval cuticles. These transient grooves formed adjacent to Engrailed expressing cells that encircled wider than normal wg domains in the Tc-ptc RNAi embryos. These results suggest that the en–wg–hh gene circuit is functionally conserved in the maintenance of segmental boundaries during germ band retraction and groove formation in Tribolium and that the segment polarity genes form a robust genetic regulatory module in the segmentation of this short germ insect.     

Gene expression suggests decoupled dorsal and ventral segmentation in the millipede Glomeris marginata (Myriapoda: Diplopoda)

Diplopods (millipedes) are known for their irregular body segmentation. Most importantly, the number of dorsal segmental cuticular plates (tergites) does not match the number of ventral structures (e.g., sternites). Controversial theories exist to explain the origin of this so-called diplosegmentation. We have studied the embryology of a representative diplopod, Glomeris marginata, and have analyzed the segmentation genes engrailed (en), hedgehog (hh), cubitus-interruptus (ci), and wingless (wg). We show that dorsal segments can be distinguished from ventral segments. They differ not only in number and developmental history, but also in gene expression patterns. engrailed, hedgehog, and cubitus-interruptus are expressed in both ventral and dorsal segments, but at different intrasegmental locations, whereas wingless is expressed only in the ventral segments, but not in the dorsal segments. Ventrally, the patterns are similar to what has been described from Drosophila and other arthropods, consistent with a conserved role of these genes in establishing parasegment boundaries. On the dorsal side, however, the gene expression patterns are different and inconsistent with a role in boundary formation between segments, but they suggest that these genes might function to establish the tergite borders. Our data suggest a profound and rather complete decoupling of dorsal and ventral segmentation leading to the dorsoventral discrepancies in the number of segmental elements. Based on gene expression, we propose a model that may resolve the hitherto controversial issue of the correlation between dorsal tergites and ventral leg pairs in basal diplopods (e.g., Glomeris) and is suggestive also for derived, ring-forming diplopods (e.g., Juliformia).     

Expression of 'segmentation' genes during larval and juvenile development in the polychaetes Capitella sp. I and H. elegans

Polychaete annelids and arthropods are both segmented protostome invertebrates. To investigate whether the segmented body plan of these two phyla share a common molecular ground pattern, we report the developmental expression of orthologues of the arthropod segment polarity genes engrailed (en), hedgehog (hh), and wingless (wg/Wnt1) in larval and juvenile stages of the polychaete annelid Capitella sp. I and en in a second polychaete, Hydroides elegans. Temporally, neither Wnt1 nor hh are detected in the segmented region of the larval body until after morphological segmentation is apparent. Expression of CapI-Wnt1 is limited to a ring of ectoderm marking the future anus during larval segmentation. CapI-hh is expressed in a ring of the hindgut internal to that of CapI-Wnt1, as well as in a subset of ventral nerve cord neurons, anterior gut tissue, and mesoderm. In both H. elegans and Capitella sp. I, en is expressed in a spatially and temporally dynamic manner in segmentally iterated structures as well as a population of cells that migrate internally from ectoderm to mesoderm, possibly representing a population of ecto-mesodermal precursors. Significantly, the expression patterns we report for wg, en, and hh orthologues in Capitella sp. I and for en in larval development of H. elegans are not comparable to the highly conserved ectodermal segment polarity pattern observed in arthropods at any life history stage, consistent with distinct origins of segmentation between annelids and arthropods.     

The reinforcement-extinction process of selector gene activity: a positive feed-back loop and cell-cell interactions in Ultrabithorax patterning

Summary Most viable alleles of homeotic genes cause partial transformations within given lineages in a topographically specific fashion. We study this phenomenon as a way to understand the normal mechanisms involved in the spatial regulation of homeotic gene expression. To this end we have investigated the distribution of Ultrabithorax (Ubx) proteins in imaginai discs mutant for hypomorphic and neomorphic alleles of Ubx and alleles of trans-acting genes. We find that the morphological discontinuities observed in the adult transformations are caused by corresponding new patterns of the Ubx proteins in the imaginai anlagen. These novel patterns of Ubx proteins are understood as a consequence of a process of reinforcement-extinction of Ubx expression. The evidence suggesting that this process results from a positive feed-back loop and cell-cell interactions is discussed.     

Genetic Control of Early Embryogenesis in the Red Flour Beetle, Tribolium castaneum

SYNOPSIS. The power of genetic analysis possible with the fruitfly, Drosophila melanogaster, has yielded a detailed understandingof pattern formation controlled by homeotic and segmentationgenes in early embryogenesis. We are studying the genetic regulationof embryogenesis in the red flour beetle, Tribolium castaneum.The dynamic process of germ rudiment formation and sequentialsegmentation exhibited by Tribolium provides a context differentthan Drosophila within which to assess the function of homeoticand segmentation gene homologs. Our analyses of the genes inthe HOM-C suggest many similarities in structure and functionwith the well-characterized Drosophila genes. Abdominal resemblesits Drosophila homolog abdominal-A in functioning to establishsegmental identities in the abdomen, such that in each casemutations result in homeotic transformations to PS6. Althoughthe anterior functional boundary of abdominal-A homologs isprecisely conserved, the domain within which Abdominal is importantextends more posterior than that of abdominal-A. The final expression pattern of the segmentation gene engrailedin Tribolium is identical to Drosophila, suggesting that thesehomologs are involved in a conserved developmental process.However, as expected the development of that pattern is different;engrailed stripes anticipate the formation of each new segmentas they appear sequentially in the elongating germ band. Althoughthe grasshopper even-skipped and fushi tarazu homologs are notapparently important in segmentation, the expression patternsof the Tribolium homologs strongly suggest that they have gaineda role in segmentation in the lineage leading to beetles andflies. Nevertheless, differences between Tribolium and Drosophilain the dynamics of even-skipped expression and the fushi tarazumutant phenotype indicate divergence in the regulation and rolesof these genes.     

Expression of hunchback during trunk segmentation in the branchiopod crustacean Artemia franciscana

Comparative studies have shown that some aspects of segmentation are widely conserved among arthropods. Yet, it is still unclear whether the molecular prepatterns that are required for segmentation in Drosophila are likely to be similarly conserved in other arthropod groups. Homologues of the Drosophila gap genes, like hunchback, show regionally restricted expression patterns during the early phases of segmentation in diverse insects, but their expression patterns in other arthropod groups are not yet known. Here, we report the cloning of a hunchback orthologue from the crustacean Artemia franciscana and its expression during the formation of trunk segments. Artemia hunchback is expressed in a series of segmental stripes that correspond to individual thoracic/trunk, genital, and postgenital segments. However, this expression is not associated with the segmenting ectoderm but is restricted to mesodermal cells that associate with the ectoderm in a regular metameric pattern. All cells in the early segmental mesoderm appear to express hunchback. Later, mesodermal expression fades, and a complex expression pattern appears in the central nervous system (CNS), which is comparable to hunchback expression in the CNS of insects. No regionally restricted expression, reminiscent of gap gene expression, is observed during trunk segmentation. These patterns suggest that the expression patterns of hunchback in the mesoderm and in the CNS are likely to be ancient and conserved among crustaceans and insects. In contrast, we find no evidence for a conserved role of hunchback in axial patterning in the trunk ectoderm.     

Evolution of the pair rule gene network: Insights from a centipede

Comparative studies have examined the expression and function of homologues of the Drosophila melanogaster pair rule and segment polarity genes in a range of arthropods. The segment polarity gene homologues have a conserved role in the specification of the parasegment boundary, but the degree of conservation of the upstream patterning genes has proved more variable. Using genomic resources we identify a complete set of pair rule gene homologues from the centipede Strigamia maritima, and document a detailed time series of expression during trunk segmentation. We find supportive evidence for a conserved hierarchical organisation of the pair rule genes, with a division into early- and late-activated genes which parallels the functional division into primary and secondary pair rule genes described in insects. We confirm that the relative expression of sloppy-paired and paired with respect to wingless and engrailed at the parasegment boundary is conserved between myriapods and insects; suggesting that functional interactions between these genes might be an ancient feature of arthropod segment patterning. However, we find that the relative expression of a number of the primary pair rule genes is divergent between myriapods and insects. This corroborates suggestions that the evolution of upper tiers in the segmentation gene network is more flexible. Finally, we find that the expression of the Strigamia pair rule genes in periodic patterns is restricted to the ectoderm. This suggests that any direct role of these genes in segmentation is restricted to this germ layer, and that mesoderm segmentation is either dependent on the ectoderm, or occurs through an independent mechanism.     

Isolation and expression analysis of a poriferan <Emphasis Type="Italic">Antp</Emphasis>-class <Emphasis Type="Italic">Bar-/Bsh-</Emphasis>like homeobox gene

A novel non-Hox Antp-class gene (BarBsh-Hb) was isolated from the marine sponge Halichondria sp. This gene shares high sequence identity with eumetazoan genes from the Bsh and Bar gene families and can be distinguished from other non-Hox Antp-class genes by diagnostic residues. We also present an alignment of all known (full-length) poriferan non-Hox Antp-class genes. Maximum likelihood methods were employed to estimate phylogenetic relationships among non-Hox genes and BarBsh-Hb. We employed RT-PCR techniques to look at expression across different developmental stages (larval to rhagon). BarBsh-Hb product was present in newly released larvae, but expression was not detected 8–16 h post-release. Expression of BarBsh-Hb was detected in later-stage (>16 h post-release), free-swimming larvae until they settled and attached to the substratum, after which expression was down-regulated. In a separate set of experiments, low levels of expression were observed in normal adult tissue and disaggregated adult tissue, but BarBsh-Hb expression increased during tissue re-aggregation. These data increase the number of non-Hox homeobox genes identified in sponges and provide evidence of regulation of this non-Hox gene during sponge development. While the Bar and Bsh genes play important roles in the development of nervous tissue—especially visual systems—in metazoans, the specific role(s) BarBsh-Hb play(s) in sponge development is unclear and deserves greater attention.Edited by C. Desplan     

The involvement of <Emphasis Type="Italic">engrailed</Emphasis> and <Emphasis Type="Italic">wingless</Emphasis> during segmentation in the onychophoran <Emphasis Type="Italic">Euperipatoides kanangrensis</Emphasis> (Peripatopsidae: Onychophora) (Reid 1996)

As the putative sister group to the arthropods, onychophorans can provide insight into ancestral developmental mechanisms in the panarthropod clade. Here, we examine the expression during segmentation of orthologues of wingless (Wnt1) and engrailed, two genes that play a key role in defining segment boundaries in Drosophila and that appear to play a role in segmentation in many other arthropods. Both are expressed in segmentally reiterated stripes in all forming segments except the first (brain) segment, which only shows an engrailed stripe. Engrailed is expressed before segments are morphologically visible and is expressed in both mesoderm and ectoderm. Segmental wingless expression is not detectable until after mesodermal somites are clearly distinct. Early engrailed expression lies in and extends to both sides of the furrow that first demarcates segments in the ectoderm, but is largely restricted to the posterior part of somites. Wingless expression lies immediately anterior to engrailed expression, as it does in many arthropods, but there is no precise cellular boundary between the two expression domains analogous to the overt parasegment boundary seen in Drosophila. Engrailed stripes extend along the posterior part of each limb bud, including the antenna, while wingless is restricted to the distal tip of the limbs and the neurectoderm basal to the limbs. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

同源盒基因(Hox)与哺乳动物生殖

哺乳动物的同源盒基因（Hox）与果蝇的同源异形基因是同源基因,该基因编码的DNA片段含183碱基对,转录由61个氨基酸残基组成的蛋白质保守结构域,称同源异型域.Hox基因碱基顺序及在染色体中的位置都是高度保守的.Hox基因在体节结构分化等空间信息调控中起着重要作用,按特异的空间模式赋予每一体节其自身的特点.近年来的研究表明,Hox基因不但影响胚胎发育,而且与成体生殖系统分化有关,在着床期子宫接受态的建立及子宫蜕膜反应的发生等生殖过程中起着重要的调节作用.     

Positive and negative cis-regulatory elements in the bithoraxoid region of the Drosophila Ultrabithorax gene

Summary The Ultrabithorax (Ubx) gene is required during embryogenesis and larval development to specify the third thoracic and first abdominal segments of Drosophila melanogaster. Mutations in the bithoraxoid (bxd) region, a 40 kb DNA stretch upstream of the Ubx promoter, affect cis-regulatory elements responsible for the ectodermal expression of the Ubx gene in the posterior compartment of the third thoracic segment and anterior compartment of the first abdominal segment. Our genetic data and the available molecular information are used to map the adult epidermal cis-regulatory elements within the bxd region. Genetic combinations involving mutations affecting the bxd region show that (1) redundant or cooperatively acting sequences are required for Ubx gene expression in the anterior compartment of the first abdominal segment, and (2) the expression of Ubx in the posterior compartment of the third thoracic segment is modulated by positive and negative cis-regulatory elements.The Wellcome Trust CRC Institute for Cancer Research and Developmental Biology, Tennis Court Road Cambridge, CB2 1QR, UKDivision de Genética, Departamento de Genética Molecular y Microbiología, Campus de San Juan, Apdo. 374, 03080 Alicante, Spain