Detection of homeobox genes in development and evolution

Evolution of Antp-class genes and differential expression of Hydra Hox/paraHox genes in anterior patterning

The conservation of developmental functions exerted by Antp-class homeoproteins in protostomes and deuterostomes suggested that homologs with related functions are present in diploblastic animals. Our phylogenetic analyses showed that Antp-class homeodomains belong either to non-Hox or to Hox/paraHox families. Among the 13 non-Hox families, 9 have diploblastic homologs, Msx, Emx, Barx, Evx, Tlx, NK-2, and Prh/Hex, Not, and Dlx, reported here. Among the Hox/paraHox, poriferan sequences were not found, and the cnidarian sequences formed at least five distinct cnox families. Two are significantly related to the paraHox Gsx (cnox-2) and the mox (cnox-5) sequences, whereas three display some relatedness to the Hox paralog groups 1 (cnox-1), 9/10 (cnox-3) and the paraHox cdx (cnox-4). Intermediate Hox/paraHox genes (PG 3 to 8 and lox) did not have clear cnidarian counterparts. In Hydra, cnox-1, cnox-2, and cnox-3 were not found chromosomally linked within a 150-kb range and displayed specific expression patterns in the adult head. During regeneration, cnox-1 was expressed as an early gene whatever the polarity, whereas cnox-2 was up-regulated later during head but not foot regeneration. Finally, cnox-3 expression was reestablished in the adult head once it was fully formed. These results suggest that the Hydra genes related to anterior Hox/paraHox genes are involved at different stages of apical differentiation. However, the positional information defining the oral/aboral axis in Hydra cannot be correlated strictly to that characterizing the anterior-posterior axis in vertebrates or arthropods.

A genetic screen for zygotic embryonic lethal mutations affecting cuticular morphology in the wasp Nasonia vitripennis

We have screened for zygotic embryonic lethal mutations affecting cuticular morphology in Nasonia vitripennis (Hymenoptera; Chalcidoidea). Our broad goal was to investigate the use of Nasonia for genetically surveying conservation and change in regulatory gene systems, as a means to understand the diversity of developmental strategies that have arisen during the course of evolution. Specifically, we aim to compare anteroposterior patterning gene functions in two long germ band insects, Nasonia and Drosophila. In Nasonia, unfertilized eggs develop as haploid males while fertilized eggs develop as diploid females, so the entire genome can be screened for recessive zygotic mutations by examining the progeny of F1 females. We describe 74 of >100 lines with embryonic cuticular mutant phenotypes, including representatives of coordinate, gap, pair-rule, segment polarity, homeotic, and Polycomb group functions, as well as mutants with novel phenotypes not directly comparable to those of known Drosophila genes. We conclude that Nasonia is a tractable experimental organism for comparative developmental genetic study. The mutants isolated here have begun to outline the extent of conservation and change in the genetic programs controlling embryonic patterning in Nasonia and Drosophila.

Developmental expression of specific genes detected in high-quality cDNA libraries from single human preimplantation embryos

We describe an improved highly sensitive method for generating cDNA libraries containing a high proportion of cDNAs enriched with 5'-coding sequences from single human preimplantation embryos and a 10 week old whole foetus. The embryonic mRNA was isolated using oligo-(dT) linked to magnetic beads. First-strand cDNA synthesis was carried out directly on the bound mRNA, followed by PCR designed to amplify the cDNA molecules synthesized in their entirety. The complexities of the libraries are between 10(5) and 10(6) independent clones. The average cDNA size is 1.0 kb, and the size range is 0.5-3.0 kb. PCR analysis of the embryonic libraries for specific genes has revealed transcripts for genes known to be transcribed in preimplantation stages, such as the imprinted gene SNRPN, developmental genes WNT11, HOX, OCT-1 and the embryonic OCT-4, cytoskeletal genes keratin-18 and beta-actin, the cell cycle gene C-MOS, and housekeeping genes GAPDH and HPRT. Sequencing of random clones showed the presence of a variety of sequences, such as human chorionic gonadotrophin, ubiquitin, TFIIA, guanine nucleotide-binding protein (beta-subunit), annexin I, a gene encoding a kinesin-like protein, and TWIST, which encodes a basic helix-loop-helix (bHLH) transcription factor implicated in Saethre-Chotzen syndrome (characterized by craniofacial and limb anomalies). Approximately 40% of these randomly analysed clones were full length. In addition to cDNAs matching known ESTs (Expressed Sequence Tags) in the GenBank and dbEST databases, novel sequences were detected at a frequency of 16% of randomly picked clones. The libraries are a valuable resource, providing longer cDNAs representing genes expressed during human preimplantation development.

Temporal and spatial expression of EmH-3, a homeobox-containing gene isolated from the freshwater sponge Ephydatia muelleri

Homeoboxes have been particularly valuable in identifying genes involved in development. This prompted us to look for homeobox-containing genes in sponges, the most primitive metazoans, and to explore the potential role of these genes in their development. Using the reverse transcription polymerase reaction (RT-PCR), we analyzed the expression of EmH-3 homeobox-containing gene at different stages of development, and in different cell-type populations. The patterns of EmH-3 expression show that this gene is expressed differentially in the course of development and in a cell-type specific manner. The level of transcripts increases from undetectable levels in resting gemmules to higher levels at the moment of hatching and throughout the sponge's life. EmH-3 is strongly expressed in the pluripotent archaeocytes, whether isolated from fully differentiated sponges (adult archaeocytes) or from HU-treated sponges (embryonic archaeocytes). Conversely, in differentiated cells such as pinacocytes and choanocytes, EmH-3 expression is very weak and similar to that found in the resting gemmules. On the other hand, another freshwater sponge homeobox-containing gene, prox1 from Ephydatia fluviatilis is expressed almost at the same level at all stages of development and in all the investigated cell populations. Together, these results suggest that EmH-3 plays a role in cell determination and/or differentiation. In particular EmH-3 would determine which archaeocytes will multiply and undergo differentiation and which ones will remain undifferentiated.

Chelicerate Hox genes and the homology of arthropod segments

Genes of the homeotic complex (HOM-C) in insects and vertebrates are required for the specification of segments along the antero-posterior axis. Multiple paralogues of the Hox genes in the horseshoe crab Limulus poliphemus have been used as evidence for HOM-C duplications in the Chelicerata. We addressed this possibility through a limited PCR survey to sample the homeoboxes of two spider species, Steatoda triangulosa and Achaearanea tepidariorum. The survey did not provide evidence for multiple Hox clusters although we have found apparent duplicate copies of proboscipedia (pb) and Deformed (Dfd). In addition, we have cloned larger cDNA fragments of pb, zerknullt (zen/Hox3) and Dfd. These fragments allowed the determination of mRNA distribution by in situ hybridization. Our results are similar to the previously published expression patterns of Hox genes from another spider and an oribatid mite. Previous studies compared spider/mite Hox gene expression patterns with those of insects and argued for a pattern of segmental homology based on the assumption that the co-linear anterior boundaries of the Hox domains can be used as markers. To test this assumption we performed a comparative analysis of the expression patterns for UBX/ABD-A in chelicerates, myriapods, crustaceans, and insects. We conclude that the anterior boundary can be and is changed considerably during arthropod evolution and, therefore, Hox expression patterns should not be used as the sole criterion for identifying homology in different classes of arthropods.

CnOtx, a member of the Otx gene family, has a role in cell movement in hydra

Otx genes have been identified in a variety of organisms and are commonly associated with the patterning of anterior structures. In some vertebrates, Otx genes are also expressed in the prechordal mesoderm, where they may have a role in cell movement. Here we report the characterization of CnOtx, an Otx gene in hydra, thereby providing evidence that Otx genes appeared early in metazoan evolution. CnOtx is expressed at high levels in developing buds and aggregates, where it appears to have a role in the cell movements that are involved in the formation of new axes. Further, the gene is expressed at a low level throughout the body column of hydra. This latter pattern may reflect a role for CnOtx in specifying tissue as competent to be anterior, although the gene does not have a direct role in the formation of the head.

Identification, chromosomal assignment, and expression analysis of the human homeodomain-containing gene Orthopedia (OTP)

Homeodomain (HD) genes are helix-turn-helix transcription factors that play key roles in the specification of cell fates. In the central nervous system (CNS), HD genes not only position cells along an axis, but also specify cell migration patterns and may influence axonal connectivity. In an effort to identify novel HD genes involved in the development of the human CNS, we have cloned, characterized, and mapped the human homologue of the murine HD gene Orthopedia (Otp), whose product is found in multiple cell groups within the mouse hypothalamus, amygdala, and brain stem. Human cDNA and genomic libraries were screened with probes derived from mouse Otp sequences to find the human homologue, OTP. The deduced amino acid sequence of the open reading frame of the human cDNA is 99% homologous to mouse Otp and demonstrates a high degree of conservation when compared to sea urchin and Drosophila. OTP was mapped to human chromosome 5q13.3 using radiation hybrid panel mapping and fluorescence in situ hybridization. Flanking markers were identified from YAC clones containing OTP. A single putative OTP gene product was found in 17-week human fetal brain tissue by Western blot analysis using a novel polyclonal antibody raised against a conserved 13-amino-acid sequence at the C-terminus of the OTP protein. Expression in the developing human hypothalamus was confirmed by immunohistochemistry.

Ancient origins of axial patterning genes: Hox genes and ParaHox genes in the Cnidaria

Among the bilaterally symmetrical, triploblastic animals (the Bilateria), a conserved set of developmental regulatory genes are known to function in patterning the anterior-posterior (AP) axis. This set includes the well-studied Hox cluster genes, and the recently described genes of the ParaHox cluster, which is believed to be the evolutionary sister of the Hox cluster (Brooke et al. 1998). The conserved role of these axial patterning genes in animals as diverse as frogs and flies is believed to reflect an underlying homology (i.e., all bilaterians derive from a common ancestor which possessed an AP axis and the developmental mechanisms responsible for patterning the axis). However, the origin and early evolution of Hox genes and ParaHox genes remain obscure. Repeated attempts have been made to reconstruct the early evolution of Hox genes by analyzing data from the triphoblastic animals, the Bilateria (Schubert et al. 1993; Zhang and Nei 1996). A more precise dating of Hox origins has been elusive due to a lack of sufficient information from outgroup taxa such as the phylum Cnidaria (corals, hydras, jellyfishes, and sea anemones). In combination with outgroup taxa, another potential source of information about Hox origins is outgroup genes (e.g., the genes of the ParaHox cluster). In this article, we present cDNA sequences of two Hox-like genes (anthox2 and anthox6) from the sea anemone, Nematostella vectensis. Phylogenetic analysis indicates that anthox2 (= Cnox2) is homologous to the GSX class of ParaHox genes, and anthox6 is homologous to the anterior class of Hox genes. Therefore, the origin of Hox genes and ParaHox genes occurred prior to the evolutionary split between the Cnidaria and the Bilateria and predated the evolution of the anterior-posterior axis of bilaterian animals. Our analysis also suggests that the central Hox class was invented in the bilaterian lineage, subsequent to their split from the Cnidaria.

Isolation of Hox genes from the scyphozoan Cassiopeia xamachana: implications for the early evolution of Hox genes

The isolation of Hox genes from two cnidarian groups, the Hydrozoa and Anthozoa, has sparked hypotheses on the early evolution of Hox genes and a conserved role for these genes for defining a main body axis in all metazoan animals. We have isolated the first five Hox genes, Scox-1 to Scox-5, from the third cnidarian class, the Scyphozoa. For all but one gene, we report full-length homeobox plus flanking sequences. Four of the five genes show close relationship to previously reported Cnox-1 genes from Hydrozoa and Anthozoa. One gene, Scox-2, is an unambiguous homologue of Cnox-2 genes known from Hydrozoa, Anthozoa, and also Placozoa. Based on sequence similarity and phylogenetic analyses of the homeobox and homeodomain sequences of known Hox genes from cnidarians, we suggest the presence of at least five distinct Hox gene families in this phylum, and conclude that the last common ancestor of the Recent cnidarian classes likely possessed a set of Hox genes representing three different families, the Cnox-1, Cnox-2, and Cnox-5 families. The data presented are consistent with the idea that multiple duplication events of genes have occurred within one family at the expense of conservation of the original set of genes, which represent the three ancestral Hox gene families.

Extensive zygotic control of the anteroposterior axis in the wasp Nasonia vitripennis

Insect axis formation is best understood in Drosophila melanogaster, where rapid anteroposterior patterning of zygotic determinants is directed by maternal gene products. The earliest zygotic control is by gap genes, which determine regions of several contiguous segments and are largely conserved in insects. We have asked genetically whether early zygotic patterning genes control similar anteroposterior domains in the parasitoid wasp Nasonia vitripennis as in Drosophila. Nasonia is advantageous for identifying and studying recessive zygotic lethal mutations because unfertilized eggs develop as males while fertilized eggs develop as females. Here we describe recessive zygotic mutations identifying three Nasonia genes: head only mutant embryos have posterior defects, resembling loss of both maternal and zygotic Drosophila caudal function; headless mutant embryos have anterior and posterior gap defects, resembling loss of both maternal and zygotic Drosophila hunchback function; squiggy mutant embryos develop only four full trunk segments, a phenotype more severe than those caused by lack of Drosophila maternal or zygotic terminal gene functions. These results indicate greater dependence on the zygotic genome to control early patterning in Nasonia than in the fly.

Sampling the genomic pool of protein tyrosine kinase genes using the polymerase chain reaction with genomic DNA

The polymerase chain reaction (PCR), with cDNA as template, has been widely used to identify members of protein families from many species. A major limitation of using cDNA in PCR is that detection of a family member is dependent on temporal and spatial patterns of gene expression. To circumvent this restriction, and in order to develop a technique that is broadly applicable we have tested the use of genomic DNA as PCR template to identify members of protein families in an expression-independent manner. This test involved amplification of DNA encoding protein tyrosine kinase (PTK) genes from the genomes of three animal species that are well known development models; namely, the mouse Mus musculus, the fruit fly Drosophila melanogaster, and the nematode worm Caenorhabditis elegans. Ten PTK genes were identified from the mouse, 13 from the fruit fly, and 13 from the nematode worm. Among these kinases were 13 members of the PTK family that had not been reported previously. Selected PTKs from this screen were shown to be expressed during development, demonstrating that the amplified fragments did not arise from pseudogenes. This approach will be useful for the identification of many novel members of gene families in organisms of agricultural, medical, developmental and evolutionary significance and for analysis of gene families from any species, or biological sample whose habitat precludes the isolation of mRNA. Furthermore, as a tool to hasten the discovery of members of gene families that are of particular interest, this method offers an opportunity to sample the genome for new members irrespective of their expression pattern.

Differential expression of Hox genes in multistage carcinogenesis of mouse skin

We surveyed expression of Hox genes in multiple carcinogenesis of mouse skin by RT-PCR cloning. According to the sequences of the amplified DNA fragments within the homeobox of Hox genes, 25 of the 39 known Hox genes were amplified in the normal dorsal skin of adult mice. In the papilloma and carcinoma, clones of Hox A7 and Hox B7 were preferentially isolated among others. The entire Hox D locus was silent in both papilloma and carcinoma. Our present results suggest that the majority of Hox gene family members are expressed in normal mouse skin, while the repertoire is substantially limited in the papilloma and carcinoma.

Molecules and the body plan: the Hox genes of Cirripedes (Crustacea)

Among arthropods, Cirripedia (barnacles) are remarkable in that they completely lack abdominal segments. This feature prompted us to study the Hox genes of three cirripede species, representing a wide array of the diversity of these organisms, a segmented sessile barnacle, Elminius modestus (Thoracica), the parasite of a crab, Sacculina carcini (Rhizocephala), and the burrowing barnacle Trypetesa lampas (Acrothoracica). Using PCR amplification of genomic DNA and cDNA and library probing, we have found seven clear cirripedian homologues of the eight homeotic Hox genes known in insects, including labial and proboscipedia homologues, that were not previously reported in crustaceans. In addition we have isolated a divergent Antp-like gene, named Diva, that we homologize to the ftz gene of insects. The homeotic gene abdominalA (abdA) was not retrieved from any of these three cirripede species. By contrast, we have found all eight homeotic homologue genes, including abdA, in Ulophysema oeresundense, a crustacean possessing a well-developed abdomen, belonging to the Ascothoracica, generally thought to be the sister group of Cirripedia. Since we have found in barnacles homeobox-containing genes that are more divergent from the Antennapedia type than the typical abdA, we believe that a bona fide abdA gene would not have escaped our search. Hence, the abdA gene has been lost or is profoundly derived in sequence during the evolution leading to the cirripedian lineage. If confirmed, the lack of abdA would represent the first case in which the loss of a homeotic gene is correlated with a change in body plan during the evolution of metazoans.

Homeobox genes in the ribbonworm Lineus sanguineus: evolutionary implications

From our current understanding of the genetic basis of development and pattern formation in Drosophila and vertebrates it is commonly thought that clusters of Hox genes sculpt the morphology of animals in specific body regions. Based on Hox gene conservation throughout the animal kingdom it is proposed that these genes and their role in pattern formation evolved early during the evolution of metazoans. Knowledge of the history of Hox genes will lead to a better understanding of the role of Hox genes in the evolution of animal body plans. To infer Hox gene evolution, reliable data on lower chordates and invertebrates are crucial. Among the lower triploblasts, the body plan of the ribbonworm Lineus (nemertini) appears to be close to the common ancestral condition of protostomes and deuterostomes. In this paper we present the isolation and identification of Hox genes in Lineus sanguineus. We find that the Lineus genome contains a single cluster of at least six Hox genes: two anterior-class genes, three middle-class genes, and one posterior-class gene. Each of the genes can be definitely assigned to an ortholog group on the basis of its homeobox and its flanking sequences. The most closely related homeodomain sequences are invariably found among the mouse or Amphioxus orthologs, rather than Drosophila and other invertebrates. This suggests that the ribbonworms have diverged relatively little from the last common ancestors of protostomes and deuterostomes, the urbilateria.

Budhead, a fork head/HNF-3 homologue, is expressed during axis formation and head specification in hydra

Accumulating evidence indicates that a common set of genes and mechanisms regulates the developmental processes of a variety of triploblastic organisms despite large variation in their body plans. To what extent these same genes and mechanisms are also conserved among diploblasts, which arose earlier in metazoan evolution, is unclear. We have characterized a hydra homologue of the fork head/HNF-3 class of winged-helix proteins, termed budhead, whose expression patterns suggest a role(s) similar to that found in vertebrates. The vertebrate HNF-3 beta homologues are expressed early in embryogenesis in regions that have organizer properties, and later they have several roles, among them an important role in rostral head formation. In the adult hydra, where axial patterning processes are continuously active, budhead is expressed in the upper part of the head, which has organizer properties. It is also expressed during the formation of a new axis as part of the development of a bud, hydra's asexual form of reproduction. Expression during later stages of budding, during head regeneration and the formation of ectopic heads, indicates a role in head formation. It is likely that budhead plays a critical role in head as well as axis formation in hydra.

The mouse homeobox gene, Gbx2: genomic organization and expression in pluripotent cells in vitro and in vivo

The Gbx2 homeodomain is widely conserved in metazoans. We investigated the mouse Gbx2 locus by isolation and characterization of genomic clones and by physical localization to the genome. The Gbx2 gene contained a single intron that separated the proposed functional protein domains. This organization was conserved with human GBX2. Physical localization of Gbx2 to Chromosome 1C5-E1 indicated that the genomic relationship between the linked Gbx2 and En1 genes differs between mouse and human, making it unlikely to be of functional significance. We also extended the known expression pattern of Gbx2 beyond the gastrulation stage embryo and the developing CNS to pluripotent cells in vitro and in vivo. Gbx2 expression was demonstrated in undifferentiated embryonic stem cells but was downregulated in differentiated cell populations. In the embryo, Gbx2 expression was detected before primitive streak formation, in the inner cell mass of the preimplantation embryo. Gbx2 is therefore a candidate control gene for cell pluripotency and differentiation in the embryo.

The homeobox gene GBX2, a target of the myb oncogene, mediates autocrine growth and monocyte differentiation

The homeobox gene GBX2 was identified as a target gene of the v-Myb oncoprotein encoded by the avian myeloblastosis virus (AMV). GBX2 activation by c-Myb requires signal transduction emanating from the cell surface while the leukemogenic AMV v-Myb constitutively induces the GBX2 gene. Mutations in the DNA binding domain of AMV-Myb render it independent of signaling events and concomitantly abrogate the collaboration between Myb and CCAAT Enhancer Binding Proteins (C/EBP), which are involved in granulocyte differentiation. Ectopic expression of GBX2 in growth factor-dependent myeloblasts induces monocytic features and independence from exogenous cytokines, reflecting distinct features of AMV-transformed cells. Our results suggest that Myb or factors it interacts with contribute to hematopoietic lineage choice and differentiation in a signal transduction-dependent fashion.

A PCR survey of hox genes in the sea star, Asterina minor

The sea star, Asterina minor, was surveyed for Hox genes using the method of PCR and subsequent sequence determination. Seven different Hox-type homeobox fragments and homeobox fragments of two other types, the Gbx-type and the Xlox-type, were identified. The results of comparative analysis with known homeobox sequences suggest that the sea star has only one Hox gene cluster including two genes of the anterior group, four genes of the medial group, and one gene of the posterior group. The existence of a gene of the cognate group 1 has not been known in echinoderm species. Each of the other fragments indicated a definite relationship with one of sea urchin homeoboxes. The hypothetical cluster in the sea star is consistent with the results published for another class of echinoderm, sea urchins, in the putative number of cluster. The present result provides strong evidence that a single Hox cluster is common to echinoderms and its structure in the anterior region is more similar to other deuterostomes than previously thought.

Evolution of the entire arthropod Hox gene set predated the origin and radiation of the onychophoran/arthropod clade

BACKGROUND

Dramatic changes in body size and pattern occurred during the radiation of many taxa in the Cambrian, and these changes are best documented for the arthropods. The sudden appearance of such diverse body plans raises the fundamental question of when the genes and the developmental control systems that regulate these designs evolved. As Hox genes regulate arthropod body patterns, the evolution of these genes may have played a role in the origin and diversification of the arthropod body plan from a homonomous ancestor. To trace the origin of arthropod Hox genes, we examined their distribution in a myriapod and in the Onychophora, a sister group to the arthropods.

RESULTS

Despite the limited segmental diversity within myriapods and Onychophora, all insect Hox genes are present in both taxa, including the trunk Hox genes Ultrabithorax and abdominal-A as well as an ortholog of the fushi tarazu gene. Comparative analysis of Hox gene deployment revealed that the anterior boundary of expression of trunk Hox genes has shifted dramatically along the anteroposterior axis between Onychophora and different arthropod classes. Furthermore, we found that repression of expression of the Hox target gene Distal-less is unique to the insect lineage.

CONCLUSIONS

A complete arthropod Hox gene family existed in the ancestor of the onychophoran/arthropod clade. No new Hox genes were therefore required to catalyze the arthropod radiation; instead, arthropod body-plan diversity arose through changes in the regulation of Hox genes and their downstream targets.

A survey of homeobox genes in Chaetopterus variopedatus and analysis of polychaete homeodomains

A survey of genomic DNA from the polychaete Chaetopterus variopedatus was conducted using the polymerase chain reaction. Twelve unique homeobox-containing gene fragments were recovered. Phylogenetic analysis indicates that seven of the fragments are from genes belonging to Hox homeobox classes. Other fragments show orthology with Xlox, caudal, and Prh homeobox classes, with two fragments not definitely assignable to a homeobox class by our analysis. Orthology with gene sequences reported for the polychaete Ctenodrilus serratus, by Dick and Buss (1994), was calculated and indicated that at least eight of the C. variopedatus fragments are homologous to these previously reported sequences. Tabulation of the Hox gene relationships suggest that polychaetes have representative genes of each of the Hox cognate groups except Abd-B. This conclusion further suggests that the Hox cluster in the basal protostome ancestor had already undergone the gene duplications leading to the complete complement of homeotic genes known in Drosophila, with the possible loss of Abd-B in the polychaete lineage.

Cell-type-specific modulation of Hox gene expression by members of the TGF-beta superfamily: a comparison between human osteosarcoma and neuroblastoma cell lines

Homeobox gene expression in osteoblast-like cells was investigated using the polymerase chain reaction (PCR). A total of 13 homeobox genes was detected in U-2 OS (human osteosarcoma) and MC3T3-E1 (mouse osteoblast) cells by sequencing cloned PCR products. Using specific primers, a different pattern of Hox gene expression was shown for the neuroblastoma cell line SK-N-SH relative to U-2 OS and MC3T3-E1. Additionally, we showed that expression of HOXC6 in U-2 OS and SK-N-SH was differentially regulated by rhBMP-2, TGF-beta and activin-A. This suggests that specific Hox genes may be target genes for TGF-beta superfamily members, and allows us to further understand the complex functions of these growth factors and how they relate to growth and development.

Identification of POU-class homeobox genes in a freshwater sponge and the specific expression of these genes during differentiation

We reported previously the identification of three homeobox-containing genes, prox1, prox2 and prox3, in sponges [Seimiya, M., Ishiguro, H., Miura.,K., Watanabe, Y. & Kurosawa, Y. (1994) Eur. J. Biochem. 221, 219-225]. The transcripts of prox1 and prox2 were identified in cells at all stages of differentiation. In the present study, we have identified two POU-class homeobox genes, designated spou-1 and spou-2, in a freshwater sponge (Ephydatia fluviatilis). These genes each encode a POU-specific domain and a POU-type homeodomain. The amino acid sequences of the POU-specific domain and the POU-type homeodomain encoded by the spou-1 gene were 76% and 67% similar to those of the human Pit-1 gene, respectively. The amino acid sequence of the POU-specific domain encoded by the spou-2 gene was also most similar to that encoded by the human Pit-1 gene among all the POU-class homeobox genes that have been sequenced to date. In contrast to the results for prox1 and prox2, transcripts of the spou-1 and spou-2 genes were identified in cells only at specific stages during the differentiation of the sponge.

Predicting developmental processes from evolutionary patterns: a molecular phylogeny of the zebrafish (Danio rerio) and its relatives

Central to most evolutionary research is the desire to understand the proximate and ultimate factors leading to increased biological diversity. Developmental and evolutionary biology are intimately linked since one factor that limits evolutionary diversification is ontogenetic feasibility to diversify morphology. The connection between these two biological disciplines, although historically recognized, remained long unappreciated. Most work in developmental biology is exclusively concerned with elucidating developmental processes in a small number of model systems, which are then assumed to be representative of a much larger number of species. Typically in this work developmental mutants are induced through mutagens and subsequently mutated genes are identified that are responsible for the altered (loss of function) and wildtype developmental phenotypes. Recently, the zebrafish,Danio rerio, has become one of the most popular model systems in vertebrate developmental biology. We present a DNA-based phylogeny for the zebrafish and 20 of its close relatives. The molecular phylogeny is based on homologous regions of the large (16S) and small (12S) mitochondrial ribosomal RNA genes. We argue that these closely related species of zebrafish, if viewed in an explicitly phylogenetic context, can be treated asnatural mutantsthat lend themselves well to comparative developmental work. Such comparisons might include the study of the developmental mechanisms of somatogenesis in various species of danios that differ in segment numbers (through hybridization, transgenic or other experimental embryological techniques). Based on the extensive zebrafish phylogeny we explore the connection between ontogeny and phylogeny and argue that evolutionary biology cannot only test plausible historical scenarios, but might also be able to predict and help characterize which differences in developmental processes are responsible for differences between species and more general evolutionary trends.

Genetic redundancy caused by gene duplications and its evolution in networks of transcriptional regulators

In various organisms loss-of-function mutations of individual genes with unexpectedly weak or no phenotypic effects in the homozygous state have been observed. In several of these case, independent evidence shows that the respective gene products do have essential biological functions. An explanation emerging from detailed biochemical and genetic studies on such genes is that two or more genetically redundant genes contribute to that function, i.e., a group of genes that is able to substitute partially for a loss of function in one member of that group. The often-observed sequence similarity among redundant genes suggests gene duplications as a frequent source of genetic redundancy. Aside from this observation, the evolution of genetic redundancy is poorly understood. Genetic redundancy is potentially of great relevance to organismal evolution, since it may (i) 'protect' organisms from potentially harmful mutations, and (ii) maintain pools of functionally similar, yet diverse gene products, and thus represent a source of evolutionary novelty at the biochemical level. The question of how genetic redundancy evolves should ideally be answered by experimentation. However, the large time scales involved and insufficient quantitative understanding of the underlying regulatory pathways are likely to preclude such an approach in the foreseeable future. Preliminary answers are sought here by using a biochemically motivated model of a small but central part of a developmental pathway. Sets of transcription regulators are modeled that mutually regulate each other's expression and thereby form stable gene expression patterns. It is then studied how genetic redundancy caused by gene duplications might evolve in such networks. The results obtained suggest that redundancy may, at least in some cases, be a global property of gene interactions within a regulatory pathway, rather than a local property of genes in that pathway. They also raise the possibility that duplications of a whole regulatory gene network, as may have taken place during the evolution of HOM/Hox genes in chordates, are less likely to be reversible (by gene deletions) than duplications of individual network genes. These findings are discussed with reference to experimental evidence on the evolution of HOM/Hox genes.

Theoretical approaches to the analysis of homeobox gene evolution

The homeobox gene system presents a unique model for experimental and theoretical analyses of gene evolution. Homeobox genes play a role in patterning the embryonic development of diverse organisms and as such are likely to have been fundamental to the evolution of the specialized body plans of many animal species. The organization of Hox-genes in chromosomal, clusters in many species implicates gene duplication as a prominent mechanism in the evolution of this multigene family. I review here various theoretical analyses that have contributed to our understanding of the molecular evolution of this class of developmental control genes. This article also illustrates relationships between theoretical predictions and experimental studies and outlines future avenues for the evolutionary analysis of developmental systems.

PCR-survey of Hox-genes of the zebrafish: new sequence information and evolutionary implications

We analyzed the Hox gene complement of the zebrafish Danio rerio using a PCR survey. We found 18 new zebrafish HOM/Hox type sequences and one sequence of the msh group. For groups 1-3 and 8-10 we could unambiguously assign the zebrafish fragments to cognate groups. The assignment for cognate groups 4-7 had to remain tentative due to insufficient sequence variation. The number of zebrafish Hox fragments classified as members of cognate groups 1-4, 8, and 9 is identical to the number of genes in corresponding cognate groups of the mouse and human genomes. We found only two differences between the zebrafish and mouse Hox gene complement: four putative genes in group 10 (three in mammals) and only seven in the medial groups 5 to 7 (eight in mammals). Together with the previously published Hox gene sequences of the killifish, the larger number of zebrafish genes in group 10 is positive evidence for variation in the Hox gene complements among bony fish. In contrast, the Hox gene complement appears to be highly conserved among all tetrapods.

Sequence and expression pattern of the Stra7 (Gbx-2) homeobox-containing gene induced by retinoic acid in P19 embryonal carcinoma cells

The cDNA sequence of Stra7, a retinoic acid (RA)-inducible gene in P19 embryonal carcinoma (EC) cells, was determined. The deduced Stra7 protein contains a homeodomain highly similar to that of the previously described chicken CHox7 gene product, and is highly conserved during evolution, from hemichordates to vertebrates. The mouse Stra7 cDNA corresponds to the full-length form of the 77 bp homeodomain-encoding cDNA fragment which was previously cloned and termed MMoxA or Gbx-2. Reverse-transcriptase-PCR analysis revealed the presence of Stra7/Gbx-2 transcripts in the adult brain, spleen, and female genital tract, whereas no expression could be observed in heart, liver, lung, kidney, or testes. In situ hybridization analysis showed a restricted expression pattern of Stra7/Gbx-2 in the three primitive germ layers during gastrulation. Restricted expression was also detected in the pharyngeal arches. Subsequently, there were specific expression domains in the developing central nervous system, at the midbrain/hindbrain boundary and later in the cerebellum anlage, in certain rhombomeres, in dorsal regions of the spinal cord, and in the developing dorsal thalamus and corpus striatum.

Expression of PTPH1, a rat protein tyrosine phosphatase, is restricted to the derivatives of a specific diencephalic segment

Studies to date have identified only a few proteins that are expressed in a segment-specific manner within the mammalian brain. Here we report that a nonreceptor protein tyrosine phosphatase, PTPH1, is selectively expressed in the adult thalamus. Expression of PTPH1 mRNA is detected in most, but not all, thalamic nuclei. Nuclei that are derived embryonically from the dorsal thalamus and project to the neocortex express this gene, whereas those derived from the ventral thalamus do not. PTPH1 mRNA expression is also restricted to the dorsal thalamus during development and, thus, can serve as a specific marker for the dorsal thalamic nuclei. Since the subcellular localization of PTPH1 protein is not known, its functional role is not clear. However, the restriction of its expression to the thalamic nuclei that have thalamocortical connections suggests that PTPH1 may play a role in the maintenance of these connections or in determining the physiological properties of thalamic relay nuclei.

Identification of planarian homeobox sequences indicates the antiquity of most Hox/homeotic gene subclasses

The homeotic gene complex (HOM-C) is a cluster of genes involved in the anteroposterior axial patterning of animal embryos. It is composed of homeobox genes belonging to the Hox/HOM superclass. Originally discovered in Drosophila, Hox/HOM genes have been identified in organisms as distantly related as arthropods, vertebrates, nematodes, and cnidarians. Data obtained in parallel from the organization of the complex, the domains of gene expression during embryogenesis, and phylogenetic relationships allow the subdivision of the Hox/HOM superclass into five classes (lab, pb/Hox3, Dfd, Antp, and Abd-B) that appeared early during metazoan evolution. We describe a search for homologues of these genes in platyhelminths, triploblast metazoans emerging as an outgroup to the great coelomate ensemble. A degenerate PCR screening for Hox/HOM homeoboxes in three species of triclad planarians has revealed 10 types of Antennapedia-like genes. The homeobox-containing sequences of these PCR fragments allowed the amplification of the homeobox-coding exons for five of these genes in the species Polycelis nigra. A phylogenetic analysis shows that two genes are clear orthologues of Drosophila labial, four others are members of a Dfd/Antp superclass, and a seventh gene, although more difficult to classify with certainty, may be related to the pb/Hox3 class. Together with previously identified Hox/HOM genes in other flatworms, our analyses demonstrate the existence of an elaborate family of Hox/HOM genes in the ancestor of all triploblast animals.

Sequence, genomic organization, and expression of the novel homeobox gene Hesx1

Extensive analyses of homeobox gene expression and function during murine embryogenesis have demonstrated that homeobox gene products are key components in the establishment of pattern formation and regional identity during development. In this paper we report the molecular characterization and expression of a novel murine homeobox sequence, Hesx1, isolated from pluripotent embryonic stem cells. Hesx1 is expressed as two transcripts of 1.0 and 1.2 kilobases which encode an identical 185 amino acid open reading frame. The transcripts differ in the 3'-untranslated region due to the differential utilization of a weak splice donor site located immediately downstream of the translation termination codon. The Hesx1 homeodomain shared 80% identity with the Xenopus homeoprotein XANF-1 and was less than 50% related to other homeodomain sequences. Hesx1 and XANF-1 therefore constitute the founder members of a new homeodomain class. Hesx1 expression was down-regulated during embryonic stem cell differentiation and was detected in tissue-specific RNA samples derived from the embryonic liver, and at lower levels in viscera, amnion, and yolk sac. Expression in adult mice was not detected. These sites of expression are consistent with a role for Hesx1 in the regulation of developmental decisions in the early mouse embryo and during fetal hematopoiesis.

Dlx and other homeobox genes in the morphological development of the dentition

The dentition is a segmental system whose evolution and morphology bears analogy to the evolution of segmentation in the vertebral column and limb. Combinatorial expression of members of the large "Hox" class of homeobox regulatory genes has been shown to play an important role in positional specification in these skeletal systems. This raises the possibility that homeobox genes are also used for positional specification in the dentition, and several homeobox genes are known to be expressed in developing teeth. To identify additional dentally expressed homeobox genes, cDNA from from murine tooth germs at 9.5, 14.5, and 17.5 days gestational age was amplified by PCR using sets of degenerate primers to the homeodomains of 18 different classes of homeobox genes. Amplification products were cloned and sequenced and compared to known gene sequences. To date this approach has confirmed the presence of Msx1, Msx2, Dlx1, and Dlx2, and identified several other homeobox genes not previously known to be expressed in teeth: Dbx, MHox, and Mox2A, plus an a additional Dlx gene, Dlx7. The Msx and Dlx genes are the best current candidates for a combinatorial mechanism that controls the differentiation of structures within and between teeth, and perhaps also the evolution of those structures.

Distal-less and other homeobox genes in the development of the dentition

The mammalian tooth develops through an interaction between two tissue layers of different embryologic origin. A number of transcription factors and as well as two members of the Msx class of homeobox genes have been shown to be involved in the histogenesis of the mammalian tooth. This raised the possibility that other homeobox genes might be involved in dental morphogenesis. We have amplified mouse tooth germ cDNA from three different gestational ages by the polymerase chain reaction with degenerate primers for 18 classes of homeobox genes. Members of several classes have been isolated, including the Msx genes, two Dlx genes, and the Dbx, MHox, Mox2A genes. One of the Dlx genes, Dlx-7, had not previously been reported in mammals, and some details are presented of its cDNA sequence. This work plus that of other investigators has shown that at least six Dlx genes are expressed in developing teeth or in first branchial arches, suggesting the possibility that these genes are involved in specifying complexity within or between teeth. The screening approach with degenerate primers is a successful way to identify new as well as previously known regulatory genes expressed in developing tooth embryos.

Molecular biology of embryonic development: how far have we come in the last ten years?

The successes of molecular developmental biology over the last ten years have been particularly impressive in those directions favored by its major paradigms. New technologies have both guided and been guided by the progress of the field. I review briefly some of the major insights into embryonic development that have derived from research in four specific areas: early embryogenesis of various forms; 'pattern formation'; evolutionary conservation of regulatory elements; and spatial mechanisms of gene regulation. There remain many major problem areas, some of which may require new orientations to solve.

Review: borders, patterns, and distinctive families of homeodomains

PURPOSE

Homeotic proteins function as transcription factors in early embryogenesis of many organisms. To date, hundreds of distinctive homeoproteins have been identified, including 84 human homeodomains. However further progress in understanding functional relationships between particular homeoproteins and other embryonic regulators requires a comprehensive structural classification of these proteins.

RESULTS

The most probable borders and conservative amino acid positions inside the homeodomain region have been established using a statistical analysis of variabilities of amino acid occurrences at various positions outside and inside the domain. A new format for a homeodomain sequence presentation and regular amino acid patterns which are strongly representative of distinctive homeodomain groups are proposed. Using the established patterns, 33 families of closely related homeodomains have been distinguished and classified. The total list of 297 homeodomain amino acid sequences is presented in the Appendix.

CONCLUSION

The structural classification of homeodomains has been proposed. It can be useful for both the identification (or prediction) of new homeotic genes/proteins and the recognition of possible PCR-induced sequence errors. This systematics will also have an impact on understanding functional relationships among homeotic proteins and other genetic regulators of developmental processes.

Homeobox-containing genes in the most primitive metazoa, the sponges

The porifera represent the most primitive phylum of the metazoa. We identified three homeobox-containing genes in the freshwater sponge (Ephydatia fluviatilis). Genomic DNA of the sponge was subjected to amplification by PCR with two primers that corresponded to the helix-1 and helix-3 regions of the homeodomain. Using the amplified products as probes, we isolated two homeobox genes, designated prox1 and prox2. The amino acid sequences of the homeodomains of prox1 and prox2 were 72% and 62% identical to those of the NK-3 and Om(1D) genes of Drosophila, respectively. Screening of a sponge genomic library with degenerate oligonucleotides that corresponded to helix 3 further revealed the presence of one more homeobox gene, prox3. The amino acid sequence of the homeodomain of the prox3 product was 77% identical to that of the msh gene product of human. These results indicate that, when the metazoa appeared during the course of evolution, the multiple and distinct classes of homeobox-containing genes that have been identified in higher organisms already existed.

IDX-1: a new homeodomain transcription factor expressed in rat pancreatic islets and duodenum that transactivates the somatostatin gene

We describe the cloning from a rat islet somatostatin-producing cell line of a 1.4 kb cDNA encoding a new homeoprotein, IDX-1 (islet/duodenum homeobox-1), with close sequence similarity to the Drosophila melanogaster homeobox protein Antennapedia (Antp) and the Xenopus laevis endoderm-specific homeoprotein XlHbox8. Analyses of IDX-1 mRNA and protein in rat tissues show that IDX-1 is expressed in pancreatic islets and ducts and in the duodenum. In electrophoretic mobility shift assays IDX-1 binds to three sites in the 5' flanking region of the rat somatostatin gene. In co-transfection experiments IDX-1 transactivates reporter constructs containing somatostatin promoter sequences, and mutation of the IDX-1 binding sites attenuates transactivation. Reverse transcription-polymerase chain reaction of islet RNA using degenerate amplimers for mRNAs encoding homeoproteins indicates that IDX-1 is the most abundant of 12 different Antp-like homeodomain mRNAs expressed in adult rat islets. The pattern of expression, relative abundance and transcriptional regulatory activity suggests that IDX-1 may be involved in the regulation of islet hormone genes and in cellular differentiation in the endocrine pancreas and the duodenum.

Evolutionary analysis of genes involved in early embryonic pattern formation in Drosophila

Segmentation and homeotic genes have originally been identified and analyzed in Drosophila. Molecular techniques such as low stringency hybridization or PCR now allow to clone homologs of these genes from different organisms. This provides a basis to study the evolution of pattern formation mechanisms between organisms at the gene level, creating a new discipline: molecular comparative embryology. This chapter discusses the practical and conceptual problems arising from this approach.

The HOX complex neighbored by the EVX gene, as well as two other homeobox-containing genes, the GBX-class and the EN-class, are located on the same chromosomes 2 and 7 in humans

Two newly identified human homeobox-containing genes, GBX1 and GBX2, are closely related genes, as are members of the other homeobox genes, EN-1 and EN-2. GBX1 and EN-2 have been mapped to chromosome 7q36. The present study shows that GBX2 was mapped to chromosome 2q37. EN-1 was mapped to chromosome 2q14. Moreover, two HOX complexes neighbored by the EVX gene, HOXA and HOXD, are located at chromosome 7p15-p14 and 2q31-q37, respectively. Thus, it is possible that these homeobox genes were linked to each other on an ancestral genome and that the ancestral chromosome segment was duplicated during evolution.

Presence of eight distinct homeobox-containing genes in cnidarians

Using the polymerase chain reaction, we identified four different homeobox-containing genes in Hydra magnipapillata. Three of them, cnox1-Hm, cnox2-Hm and cnox4-Hm, were equivalent to homeobox genes that had already been identified in other species of cnidarians. cnox5-Hm was a new homeobox gene and was very similar to Mox1 in the mouse. Together with the published data, our results indicate that there are at least eight distinct classes of homeobox genes in cnidarians. These homeobox genes show a maximum of 60 to 77% identity in terms of the amino acid residues in their homeodomains to certain classes of homeobox genes that have been identified in Drosophila.

Mouse Wnt genes exhibit discrete domains of expression in the early embryonic CNS and limb buds

Mutation and expression studies have implicated the Wnt gene family in early developmental decision making in vertebrates and flies. In a detailed comparative analysis, we have used in situ hybridization of 8.0- to 9.5-day mouse embryos to characterize expression of all ten published Wnt genes in the central nervous system (CNS) and limb buds. Seven of the family members show restricted expression patterns in the brain. At least three genes (Wnt-3, Wnt-3a, and Wnt-7b) exhibit sharp boundaries of expression in the forebrain that may predict subdivisions of the region later in development. In the spinal cord, Wnt-1, Wnt-3, and Wnt-3a are expressed dorsally, Wnt-5a, Wnt-7a, and Wnt-7b more ventrally, and Wnt-4 both dorsally and in the floor plate. In the forelimb primordia, Wnt-3, Wnt-4, Wnt-6 and Wnt-7b are expressed fairly uniformly throughout the limb ectoderm. Wnt-5a RNA is distributed in a proximal to distal gradient through the limb mesenchyme and ectoderm. Along the limb's dorsal-ventral axis, Wnt-5a is expressed in the ventral ectoderm and Wnt-7a in the dorsal ectoderm. We discuss the significance of these patterns of restricted and partially overlapping domains of expression with respect to the putative function of Wnt signalling in early CNS and limb development.

Homeobox genes and the patterning of skin diseases

Fundamental to our understanding of skin diseases and their presentation is an understanding of the pattern of their development. When we have established the molecular basis of their development we will be in a much better position to control and treat such diseases. The homeobox genes are a family of regulatory proteins that influence pattern formation at many levels. Their presence in skin implicates them in this important role. It seems highly likely that they will be shown to be fundamental to the development of the patterns used in diagnosing skin diseases.

Herpes simplex virus pathogenesis in transgenic mice is altered by the homeodomain protein Hox 1.3

The DNA sequence TAAT is the core binding motif for the mouse homeodomain protein Hox 1.3 (proposed new name, Hoxa-5). These sequences are present within the multiple TAATGARAT regulatory motifs in the promoters of the immediate-early genes which control herpes simplex virus type 1 replication. To investigate the role of this homeodomain protein in the regulation of herpes simplex virus gene expression and pathogenesis, transgenic mice containing a mouse Hox 1.3 cDNA under the control of the virus- and interferon-inducible Mx 1 promoter were generated. After infection of transgenic mice with herpes simplex virus, Hox 1.3 RNA and protein were expressed at the sites of virus replication. In these transgenic mice, herpes simplex virus replication, spread of virus through the host, and virus-induced mortality were markedly enhanced. Increased spread and replication of herpes simplex virus were also observed in cultured fibroblasts from transgenic mice. This finding suggests that in vivo, Hox 1.3 may increase viral spread by increasing viral replication at the level of the individual infected cells. These results demonstrate that expression of a transgene encoding a single host protein, Hox 1.3, alters the pathogenesis of experimental herpes simplex virus infection. We conclude that a protein that belongs to a class of DNA-binding proteins which are best known for their role in regulating embryonic development may also regulate herpesvirus pathogenesis.

The ets multigene family is conserved throughout the Metazoa

This study provides the first empirical evidence for the conservation of the ets proto-oncogene transcription factor family throughout the Metazoa. Using the polymerase chain reaction with degenerate primers corresponding to conserved sequences within the ETS DNA-binding domain, we have detected ets genes in a range of lower metazoans, including sponges, ctenophores, anemones, flatworms and nematodes, and in several higher invertebrate metazoans. Many of these sequences are significantly divergent from the original v-ets-1 oncogene, although most can be aligned with recently defined groups within the ets gene family. Multiple ETS domain sequences were detected in a number of the lower metazoan species, providing evidence for the existence of an ets multigene family at the earliest stages of metazoan evolution. In contrast, we were unable to detect any ETS sequences in fungal, plant or several protozoan DNAs. Our findings suggest that the duplication and divergence of ets proto-oncogenes responsible for generating the multigene family occurred concomitantly with the development of metazoan animals. In addition, these data corroborate other recent molecular evidence in providing strong support for the monophyletic origin of all multicellular animals, including sponges.