Structure and evolution of neurexin genes: insight into the mechanism of alternative splicing

Neurexins are neuron-specific vertebrate proteins with hundreds of differentially spliced isoforms that may function in synapse organization. We now show that Drosophila melanogaster and Caenorhabditis elegans express a single gene encoding only an alpha-neurexin, whereas humans and mice express three genes, each of which encodes alpha- and beta-neurexins transcribed from separate promoters. The neurexin genes are very large (up to 1.62 Mb), with the neurexin-3 gene occupying almost 2% of human chromosome 14. Although invertebrate and vertebrate neurexins exhibit a high degree of evolutionary conservation, only vertebrate neurexins are subject to extensive alternative splicing that uses mechanisms ranging from strings of mini-exons to multiple alternative splice donor and acceptor sites. Consistent with their proposed role in synapse specification, neurexins thus have evolved from relatively simple genes in invertebrates to diversified genes in vertebrates with multiple promoters and extensive alternative splicing.     

Isolation of Hox and Parahox genes in the hemichordate Ptychodera flava and the evolution of deuterostome Hox genes

Because of their importance for proper development of the bilaterian embryo, Hox genes have taken center stage for investigations into the evolution of bilaterian metazoans. Taxonomic surveys of major protostome taxa have shown that Hox genes are also excellent phylogenetic markers, as specific Hox genes are restricted to one of the two great protostome clades, the Lophotrochozoa or the Ecdysozoa, and thus support the phylogenetic relationships as originally deduced by 18S rDNA studies. Deuterostomes are the third major group of bilaterians and consist of three major phyla, the echinoderms, the hemichordates, and the chordates. Most morphological studies have supported Hemichordata+Chordata, whereas molecular studies support Echinodermata+Hemichordata, a clade known as Ambulacraria. To test these competing hypotheses, complete or near complete cDNAs of eight Hox genes and four Parahox genes were isolated from the enteropneust hemichordate Ptychodera flava. Only one copy of each Hox gene was isolated suggesting that the Hox genes of P. flava are arranged in a single cluster. Of particular importance is the isolation of three posterior or Abd-B Hox genes; these genes are only shared with echinoderms, and thus support the monophyly of Ambulacraria.     

Role of Pax genes in eye evolution: a cnidarian PaxB gene uniting Pax2 and Pax6 functions

PaxB from Tripedalia cystophora, a cubomedusan jellyfish possessing complex eyes (ocelli), was characterized. PaxB, the only Pax gene found in this cnidarian, is expressed in the larva, retina, lens, and statocyst. PaxB contains a Pax2/5/8-type paired domain and octapeptide, but a Pax6 prd-type homeodomain. Pax2/5/8-like properties of PaxB include a DNA binding specificity of the paired domain, activation and inhibitory domains, and the ability to rescue spa(pol), a Drosophila Pax2 eye mutant. Like Pax6, PaxB activates jellyfish crystallin and Drosophila rhodopsin rh6 promoters and induces small ectopic eyes in Drosophila. Pax6 has been considered a "master" control gene for eye development. Our data suggest that the ancestor of jellyfish PaxB, a PaxB-like protein, was the primordial Pax protein in eye evolution and that Pax6-like genes evolved in triploblasts after separation from Cnidaria, raising the possibility that cnidarian and sophisticated triploblastic eyes arose independently.     

Dimerization and protease resistance: New insight into the function of PR-1

The group 1 pathogenesis-related (PR-1) proteins have long been considered hallmarks of hypersensitive response/defense pathways in plants, but their biochemical functions are still obscure despite resolution of the NMR/X-ray structures of several PR-1-like proteins, including P14a (the prototype PR-1). We report here the characterization of two basic PR-1 proteins (PR-1-1 and PR-1-5) recently identified from hexaploid wheat (Triticum aestivum). Both proteins were expressed in Pichia pastoris as a single major species of ∼15 kDa. Sequence identity of the expressed PR-1 proteins was verified by MALDI-TOF/TOF analysis. Accumulation of the native PR-1-5 protein in pathogen-challenged wheat was confirmed by protein gel blot analysis. Low-temperature SDS-PAGE and yeast two-hybrid assays revealed that PR-1-1 exists primarily as a monomer whereas PR-1-5 forms homodimers. Both PR-1 proteins are resistant to proteases compared to bovine serum albumin, but PR-1-1 shows resistance mainly to subtilisin and protease K (serine proteases) whereas PR-1-5 shows resistance to subtilisin, protease K and papain (a cysteine protease). Site-specific mutations at the five putative active sites in the PR-1 domain all affected dimerization, with the mutations at Glu-72 and Glu-102 (in the PR-1-5 numeration) also diminishing protease resistance. Sequence analysis revealed that the Glu-72 and Glu-102 residues are located in motif-like sequences that are conserved in both PR-1 and the human apoptosis-related caspase proteins. These findings prompt us to examine the function of PR-1 for a role in protease-mediated programmed cell death pathways in plants.     

Five Nkx5 genes show differential expression patterns in anlagen of sensory organs in medaka: insight into the evolution of the gene family

We report the identification and characterisation of five different Nkx5-related genes in medaka fish (Oryzias latipes). They constitute homologues of genes previously isolated in higher vertebrates, Nkx5--1, Nkx5--2, Hmx1/Nkx5--3 and SOHo-1, and were named accordingly: OlNkx5--1.1, OlNkx5--2, OlNkx5--3 and OlSOHo. For the Nkx5--1 gene a new, second homologue, OlNkx5--1.2, was isolated. In medaka, Nkx5 and SOHo genes are differentially expressed in three developing sensory organs: eye, ear and lateral line and later in defined brain regions. Phylogenetic analyses of the entire Nkx5 family revealed that four paralogous Nkx5 groups, Nkx5--1, Nkx5--2, Hmx1/Nkx5--3/GH6 and SOHo, are present in vertebrates. Only some of the Nkx5 family members have been identified in singular vertebrate species so far. Here we present, for the first time, the isolation of representatives of each Nkx5 subgroup in one species, the medaka fish. Based on similarities in sequence and expression patterns, and genomic organisation we propose a model of the evolutionary history of the Nkx5 family. The model predicts that the four vertebrate Nkx5 genes arose by a tandem duplication, followed by chromosomal duplication. The two Nkx5--1 genes identified so far exclusively in medaka most probably result from an additional genome duplication in the fish lineage.     

Pax group III genes and the evolution of insect pair-rule patterning

Pair-rule genes were identified and named for their role in segmentation in embryos of the long germ insect Drosophila. Among short germ insects these genes exhibit variable expression patterns during segmentation and thus are likely to play divergent roles in this process. Understanding the details of this variation should shed light on the evolution of the genetic hierarchy responsible for segmentation in Drosophila and other insects. We have investigated the expression of homologs of the Drosophila Pax group III genes paired, gooseberry and gooseberry-neuro in short germ flour beetles and grasshoppers. During Drosophila embryogenesis, paired acts as one of several pair-rule genes that define the boundaries of future parasegments and segments, via the regulation of segment polarity genes such as gooseberry, which in turn regulates gooseberry-neuro, a gene expressed later in the developing nervous system. Using a crossreactive antibody, we show that the embryonic expression of Pax group III genes in both the flour beetle Tribolium and the grasshopper Schistocerca is remarkably similar to the pattern in Drosophila. We also show that two Pax group III genes, pairberry1 and pairberry2, are responsible for the observed protein pattern in grasshopper embryos. Both pairberry1 and pairberry2 are expressed in coincident stripes of a one-segment periodicity, in a manner reminiscent of Drosophila gooseberry and gooseberry-neuro. pairberry1, however, is also expressed in stripes of a two-segment periodicity before maturing into its segmental pattern. This early expression of pairberry1 is reminiscent of Drosophila paired and represents the first evidence for pair-rule patterning in short germ grasshoppers or any hemimetabolous insect.     

Structure and function of the respiratory epithelium in the tracheal gills of stonefly larvae

The respiratory epithelium in the tracheal gills of Perla, Protonemura, and Taeniopteryx has numerous tracheoles beneath the cuticle, which are extracellularly located in deep indentations of the plasma membrane and run parallel to the longitudinal axis of the gill filaments. In the latter two species, the tracheoles are extremely densely packed at interspaces normally not exceeding the tracheolar diameters, which vary between 0·2 and 1 μ. This type of tracheation, when compared with the highly ordered tracheation in the tracheal gills of caddis fly larvae, requires a surplus of tracheolar material for the full utilization of the respiratory surface area. The functional significance of the tracheation types involving a minimum or surplus of tracheolar material is interpreted in terms of the diffusion theory of respiration.     

Pbx1/Pbx2 govern axial skeletal development by controlling Polycomb and Hox in mesoderm and Pax1/Pax9 in sclerotome

The post-cranial axial skeleton consists of a metameric series of vertebral bodies and intervertebral discs, as well as adjoining ribs and sternum. Patterning of individual vertebrae and distinct regions of the vertebral column is accomplished by Polycomb and Hox proteins in the paraxial mesoderm, while their subsequent morphogenesis depends partially on Pax1/Pax9 in the sclerotome. In this study, we uncover that Pbx1/Pbx2 are co-expressed during successive stages of vertebral and rib development. Next, by exploiting a Pbx1/Pbx2 loss-of-function mouse, we show that decreasing Pbx2 dosage in the absence of Pbx1 affects axial development more severely than single loss of Pbx1. Pbx1/Pbx2 mutants exhibit a homogeneous vertebral column, with loss of vertebral identity, rudimentary ribs, and rostral hindlimb shifts. Of note, these axial defects do not arise from perturbed notochord function, as cellular proliferation, apoptosis, and expression of regulators of notochord signaling are normal in Pbx1/Pbx2 mutants. While the observed defects are consistent with loss of Pbx activity as a Hox-cofactor in the mesoderm, we additionally establish that axial skeletal patterning and hindlimb positioning are governed by Pbx1/Pbx2 through their genetic control of Polycomb and Hox expression and spatial distribution in the mesoderm, as well as of Pax1/Pax9 in the sclerotome.     

Evolutionary conservation of gene structures of the Pax1/9 gene family

Based on amino acid sequence comparisons, Pax1 and Pax9 genes are considered to form a subgroup of vertebrate Pax genes. We show here that the gene structures of mouse Pax1, human PAX9 genes are similar to that of a single Pax1/9 related gene in Branchiostoma lanceolatum, AmphiPax1. This supports the hypothesis that Pax1 and Pax9 genes were derived from a single ancestral gene. A refined protein alignment of AmphiPax1, mouse Pax1 and human PAX9 proteins based on the determined exon boundaries indicates that sequence divergence at the C-termini may be related to the unique functions of the Pax1 and Pax9 genes in vertebrates. AmphiPax1 is expressed in adult amphioxus in the pharyngeal endoderm.     

Molecular evolution of the primate developmental genes MSX1 and PAX9

In primates, the craniofacial skeleton and the dentition are marked by high levels of interspecific variation. Despite this, there are few comparative species studies conducted at the molecular level to investigate this functional diversity. We have determined nucleotide sequences of MSX1 and PAX9, two developmental genes, in a sample of 27 diverse primate species in order to identify coding or regulatory variation that may be associated with phenotypic diversity. Our analyses have identified four highly conserved noncoding sequences, including one that is conserved across primates and with dogs but not with mice. Although we find that substitution rates vary significantly across MSX1 exons, comparisons of nonsynonymous and synonymous substitution rates (dN/dS) suggest that, as a whole, MSX1 and PAX9 amino acid sequences have been under functional constraint throughout primate evolution. Compared to all other primates in our sample, our analysis of exon 1 in MSX1 finds an unusual pattern of amino acid substitution for Tarsius syrichta, a member of a lineage (tarsiers) that has many unique features among primates. For example, tarsiers are the only extant primates without deciduous incisors, and MSX1 is expressed exclusively in the incisor regions during the earliest stages of dental development. Our overall results provide insight into the utility of comparative species analyses of highly conserved developmental genes and their roles in the evolution of complex phenotypes.     

Evolution of developmental roles of Pax2/5/8 paralogs after independent duplication in urochordate and vertebrate lineages

Background

Gene duplication provides opportunities for lineage diversification and evolution of developmental novelties. Duplicated genes generally either disappear by accumulation of mutations (nonfunctionalization), or are preserved either by the origin of positively selected functions in one or both duplicates (neofunctionalization), or by the partitioning of original gene subfunctions between the duplicates (subfunctionalization). The Pax2/5/8 family of important developmental regulators has undergone parallel expansion among chordate groups. After the divergence of urochordate and vertebrate lineages, two rounds of independent gene duplications resulted in the Pax2, Pax5, and Pax8 genes of most vertebrates (the sister group of the urochordates), and an additional duplication provided the pax2a and pax2b duplicates in teleost fish. Separate from the vertebrate genome expansions, a duplication also created two Pax2/5/8 genes in the common ancestor of ascidian and larvacean urochordates.

Results

To better understand mechanisms underlying the evolution of duplicated genes, we investigated, in the larvacean urochordate Oikopleura dioica, the embryonic gene expression patterns of Pax2/5/8 paralogs. We compared the larvacean and ascidian expression patterns to infer modular subfunctions present in the single pre-duplication Pax2/5/8 gene of stem urochordates, and we compared vertebrate and urochordate expression to infer the suite of Pax2/5/8 gene subfunctions in the common ancestor of olfactores (vertebrates + urochordates). Expression pattern differences of larvacean and ascidian Pax2/5/8 orthologs in the endostyle, pharynx and hindgut suggest that some ancestral gene functions have been partitioned differently to the duplicates in the two urochordate lineages. Novel expression in the larvacean heart may have resulted from the neofunctionalization of a Pax2/5/8 gene in the urochordates. Expression of larvacean Pax2/5/8 in the endostyle, in sites of epithelial remodeling, and in sensory tissues evokes like functions of Pax2, Pax5 and Pax8 in vertebrate embryos, and may indicate ancient origins for these functions in the chordate common ancestor.

Conclusion

Comparative analysis of expression patterns of chordate Pax2/5/8 duplicates, rooted on the single-copy Pax2/5/8 gene of amphioxus, whose lineage diverged basally among chordates, provides new insights into the evolution and development of the heart, thyroid, pharynx, stomodeum and placodes in chordates; supports the controversial conclusion that the atrial siphon of ascidians and the otic placode in vertebrates are homologous; and backs the notion that Pax2/5/8 functioned in ancestral chordates to engineer epithelial fusions and perforations, including gill slit openings.     

Molecular insight into the regulation and function of MCAK

Chromosome stability is ensured by precisely fine-tuned dynamics of mitotic spindles, which are controlled by a network of various microtubule-associated and interacting proteins including the kinesin-13 family. The best characterized member of this family is the mitotic centromere-associated kinesin (MCAK). By efficiently depolymerizing microtubules, MCAK influences various key events during mitosis. MCAK itself is regulated by its interaction partners, its intrinsic conformation switch and the phosphorylation of mitotic kinases like Aurora A/B, cyclin-dependent kinase 1 and Polo-like kinase 1. Perturbing its regulation alters MCAK’s conformation, catalytic activity, subcellular localization and stability, leading further to mitotic defects in spindle formation and chromosome movement. Indeed, MCAK is aberrantly regulated in various cancer types, which is linked to increased invasiveness, metastasis and drug resistance. In the current review, we summarize recently published data concerning MCAK, correlate its conformation changes with its depolymerization activity and function, propose a model of its regulation by multiple mitotic kinases and highlight its potential involvement in oncogenesis and drug resistance.