Isolation and characterization of developmentally regulated sea urchin U2 snRNA genes

Genes encoding the U2 snRNA have been isolated from the sea urchins, Strongylocentrotus purpuratus and Lytechinus variegatus. Representatives of tandemly repeated gene sets have been isolated from both sea urchin species and a unique U2 gene has also been isolated from L. variegatus. The sequence of the U2 snRNA encoded by the tandemly repeated genes differs in two nucleotides between S. purpuratus and L. variegatus. The unique U2 gene from L. variegatus encodes the same U2 RNA as the tandemly repeated genes. There is a change in the U2 genes expressed between morula and pluteus embryos as judged by a change in the U2 RNA sequence in S. purpuratus embryos. The tandemly repeated genes were expressed at a higher rate in blastula than in gastrula stage relative to the single-copy gene, when the two genes were injected into sea urchin zygotes.     

Unusual gene order and organization of the sea urchin hox cluster

While the highly consistent gene order and axial colinear patterns of expression seem to be a feature of vertebrate hox gene clusters, this pattern may be less well conserved across the rest of the bilaterians. We report the first deuterostome instance of an intact hox cluster with a unique gene order where the paralog groups are not expressed in a sequential manner. The finished sequence from BAC clones from the genome of the sea urchin, Strongylocentrotus purpuratus, reveals a gene order wherein the anterior genes (Hox1, Hox2 and Hox3) lie nearest the posterior genes in the cluster such that the most 3' gene is Hox5. (The gene order is 5'-Hox1, 2, 3, 11/13c, 11/13b, 11/13a, 9/10, 8, 7, 6, 5-3'.) The finished sequence result is corroborated by restriction mapping evidence and BAC-end scaffold analyses. Comparisons with a putative ancestral deuterostome Hox gene cluster suggest that the rearrangements leading to the sea urchin gene order were many and complex.     

The complete nucleotide sequence of the chick a-actin gene and its evolutionary relationship to the actin gene family

The nucleotide sequence of the chick a-actin gene reveals that the gene is comprised of 7 exons separated by six very short intervening sequences (IVS). The first IVS interrupts the 73 nucleotide 5' untranslated segment between nucleotides 61 and 62. The remaining IVS interrupt the translated region at codons 41/42, 150, 204, 267, and 327/328. The 272 nucleotide 3' untranslated segment is not interrupted by IVS. The amino acid sequence derived from the nucleotide sequence is identical to the published sequence for chick a-actin except for the presence of a met-cys dipeptide at the amino-terminus. The IVS positions in the chick a-actin gene are identical to those of the rat a-actin gene. While there is partial coincidence of the IVS in the a-actin genes with the vertebrate b-actin genes and 2 sea urchin actin genes, there is no coincidence with actin genes from any other source except soybean where one IVS position is shared. This discordance in IVS positions makes the actin gene family unique among the eucaryotic genes analyzed to date.     

The sequence of a sea urchin muscle actin gene suggests a gene conversion with a cytoskeletal actin gene

Summary We report the nucleotide sequence of the single muscle actin gene of the sea urchinStrongylocentrotus purpuratus. Comparison of the protein-coding sequence of this muscle actin gene (pSpG28) with that of two linked sea urchin cytoskeletal actin genes (pSpG17 and CyIIa) reveals a region of exceptional sequence conservation from codon 61 through codon 120. Furthermore, when silent nucleotide changes are compared, the conservation of this region is still evident (7.9% silent site differences in the conserved region vs 43.3% silent site differences in the rest of the gene when pSpG28 and CyIIa are compared), indicating that the conservation is not due to particularly stringent selection on the portion of the protein encoded by this region of the genes. These observations suggest that a gene conversion has occurred between the muscle actin gene and a cytoskeletal actin gene recently in the evolution of the sea urchin genome. Gene conversion between nonallelic actin genes may thus play a role in maintaining the homogeneity of this highly conserved gene family.     

Characterization of the upstream region that regulates the transcription of the gene for the precursor to EGF-related peptides,exogastrula-inducing peptides,of the sea urchin Anthocidaris crassispina

The EGIP gene for exogastrula-inducing peptides (EGIPs) of the sea urchin Anthocidaris crassispina, which are structurally related to the epidermal growth factor, is activated at the onset of gastrulation in subdomains of the embryonic ectoderm. We showed in our previous study that the spatial and temporal regulation of EGIP is conducted by the upstream region from -372 to +194, and that there is an enhancer element between -372 and -210. In this study, we introduced into sea urchin embryos PCR-amplified DNA containing differently truncated EGIP flanking region that was ligated to the GFP reporter gene, and examined the transient expression of the reporter gene, showing that both the -270/-238 and -249/-210 regions were essential for the enhancer activity. We further showed that there is another activating element between -65 and -21, and that even the region between -65 and +194 is sufficient for ectoderm-specific expression of the EGIP gene. The electrophoretic mobility shift assay showed that the -270/-210 enhancer region and the proximal -61/+30 region include specific binding sites for nuclear proteins of sea urchin embryos. Besides these unique sites, the presence of multiple binding sites for GCF1-like nuclear proteins have been revealed in the upstream DNA.     

Functional analysis of the promoter of a sea urchin metallothionein gene.

The 5'-flanking region of the metallothionein (MT) gene LpMT1 of the sea urchin Lytechinus pictus includes three copies of a conserved sequence that includes the metal-responsive element (MRE) consensus core sequence required for heavy metal induction of other MT genes, a GC box, a G box of a putative basal level enhancer element which includes another MRE core element, and a poly(C) tract. A fragment of LpMT1 DNA from nucleotides +31 to -309 fused to a chloramphenicol acetyltransferase reporter gene was inducible with cadmium after injection into L. pictus embryos. This induced activity was greatly reduced in a deletion mutant which retained only 195 base pairs of 5'-flanking sequence, including the proximal pair of MREs and the G box, but excluding the poly(C) tract, GC box, and distal MRE. A potent human hMT-IIA gene promoter is marginally functional in L. pictus embryos. In contrast, the LpMT1 promoter is active in HeLa cells and in embryos of the sea urchin Strongylocentrotus purpuratus. The hMT-IIA gene may lack a cis-acting sequence element required for expression of MT genes in L. pictus embryos. The LpMT1 promoter is a powerful, inducible, promiscuous promoter useful for driving the expression of heterologous genes in sea urchin embryos.     

Isolation and characterization of a sea urchin hsp 70 gene segment

Three clones containing Paracentrotus lividus sea urchin DNA sequences which cross-hybridize to Drosophila heat shock protein (hsp) 70 gene were isolated. The sequence arrangements in the three cloned DNA inserts were compared by restriction and cross-hybridization analysis. The results showed that they contain four different genes related to one Drosophila hsp 70 gene. One of these genes was subcloned, and two of the isolated fragments were shown to hybridize to genomic DNA and to RNA from heat-treated sea urchin embryo.     

The S. purpuratus genome: a comparative perspective

The predicted gene models derived from the sea urchin genome were compared to the gene catalogs derived from other completed genomes. The models were categorized by their best match to conserved protein domains. Identification of potential orthologs and assignment of sea urchin gene models to groups of homologous genes was accomplished by BLAST alignment and through the use of a clustering algorithm. For the first time, an overview of the sea urchin genetic toolkit emerges and by extension a more precise view of the features shared among the gene catalogs that characterize the super-clades of animals: metazoans, bilaterians, chordate and non-chordate deuterostomes, ecdysozoan and lophotrochozoan protostomes. About one third of the 40 most prevalent domains in the sea urchin gene models are not as abundant in the other genomes and thus constitute expansions that are specific at least to sea urchins if not to all echinoderms. A number of homologous groups of genes previously restricted to vertebrates have sea urchin representatives thus expanding the deuterostome complement. Obversely, the absence of representatives in the sea urchin confirms a number of chordate specific inventions. The specific complement of genes in the sea urchin genome results largely from minor expansions and contractions of existing families already found in the common metazoan "toolkit" of genes. However, several striking expansions shed light on how the sea urchin lives and develops.     

Lineage-specific expansions provide genomic complexity among sea urchin GTPases

In every organism, GTP-binding proteins control many aspects of cell signaling. Here, we examine in silico several GTPase families from the Strongylocentrotus purpuratus genome: the monomeric Ras superfamily, the heterotrimeric G proteins, the dynamin superfamily, the SRP/SR family, and the "protein biosynthesis" translational GTPases. Identified were 174 GTPases, of which over 90% are expressed in the embryo as shown by tiling array and expressed sequence tag data. Phylogenomic comparisons restricted to Drosophila, Ciona, and humans (protostomes, urochordates, and vertebrates, respectively) revealed both common and unique elements in the expected composition of these families. Galpha and dynamin families contain vertebrate expansions, consistent with whole genome duplications, whereas SRP/SR and translational GTPases are highly conserved. Unexpectedly, Ras superfamily analyses revealed several large (5+) lineage-specific expansions in the sea urchin. For Rho, Rab, Arf, and Ras subfamilies, comparing total human gene numbers to the number of sea urchin genes with vertebrate orthologs suggests reduced genomic complexity in the sea urchin. However, gene duplications in the sea urchin increase overall numbers such that total sea urchin gene numbers approximate vertebrate gene numbers for each monomeric GTPase family. These findings suggest that lineage-specific expansions may be an important component of genomic evolution in signal transduction.