Structure of the sea urchin U1 RNA repeat.

The genes coding for U1 RNA in the sea urchin L. variegatus are present in a 1400 base pair tandem repeat. One member of the repeat has been cloned and its sequence determined. The repeat unit contains a single copy of the gene for L. variegatus U1 RNA. This gene encodes an RNA which is 75% homologous to mammalian U1 RNA. The L. variegatus U1 RNA could assume a secondary structure similar to that proposed for other U1 RNAs. In addition the L. variegatus U1 RNA is precipitated by anti-SM and anti-RNP antisera. Analysis of the L. variegatus genomic DNA using the cloned U1 gene as a probe reveals a major and a minor type of repeat unit. The two repeated units are the same length but differ in a number of restriction enzyme sites clustered 200-500 bases down-stream from the gene. The monomer we have cloned and sequenced is a representative of the minor repeat. A sequence (GATAA) which is -41 to -37 bases 5' to the gene has homology to the putative RNA polymerase II promoter. Fifteen bases 3' of the gene is a sequence (CAAAGAAAGAAAA) which is very similar to the sequence found 3' of the sea urchin histone genes. The two Hha I, Hpa II and Ava I sites in the repeat are all unmethylated in sperm DNA.     

An unusual evolutionary behaviour of a sea urchin histone gene cluster

DNA sequences of cloned histone coding sequences and spacers of sea urchin species that diverged long ago in evolution were compared. The highly repeated H4 and H3 genes active during early embryogenesis had evolved (in their silent sites) at a rate (0.5-0.6% base changes/Myr) similar to single-copy protein-coding genes and nearly as fast as spacer DNA (0.7% base changes/Myr) and unique DNA. Thus, evolution in the major histone genes conforms to a universal evolutionary clock based on the rate of base sequence change. By contrast, the H4 and H3 coding sequences and a non-transcribed spacer of the DNA clone h19 of Psammechinus miliaris show an exceptionally low rate of sequence evolution only 1/100 to 1/200 that predicted from the clock hypothesis. According to the classical model of gene inheritance, the h19 DNA sequences in the Psammechinus genome require unusual conservation mechanisms by selection at the level of the gene and spacer sequences. An alternative explanation could be recent horizontal gene transfer of a histone gene cluster from the very distantly related Strongylocentrotus dröbachiensis to the P. miliaris genome.     

A developmental switch in sea urchin U1 RNA

The sequence of U1 RNA has been determined in the eggs and embryos of two sea urchins, Lytechinus variegatus and Strongylocentrotus purpuratus. In both species the sequence of the U1 RNA changes as the embryos progress through development. The sequence of the major U1 RNA in the eggs of the two species differs in two nucleotides, while the sequence of the U1 RNA present in the late embryos and somatic tissue is identical in the two species. The U1 RNA in eggs and early embryos is primarily derived from the tandemly repeated gene set, which is not expressed in somatic tissues.     

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.     

Functional analysis of the sea urchin U7 small nuclear RNA.

U7 small nuclear RNA (snRNA) is an essential component of the RNA-processing machinery which generates the 3' end of mature histone mRNA in the sea urchin. The U7 small nuclear ribonucleoprotein particle (snRNP) is classified as a member of the Sm-type U snRNP family by virtue of its recognition by both anti-trimethylguanosine and anti-Sm antibodies. We analyzed the function-structure relationship of the U7 snRNP by mutagenesis experiments. These suggested that the U7 snRNP of the sea urchin is composed of three important domains. The first domain encompasses the 5'-terminal sequences, up to about nucleotides 7, which are accessible to micrococcal nuclease, while the remainder of the RNA is highly protected and hence presumably bound by proteins. This region contains the sequence complementarities between the U7 snRNA and the histone pre-mRNA which have previously been shown to be required for 3' processing (F. Schaufele, G. M. Gilmartin, W. Bannwarth, and M. L. Birnstiel, Nature [London] 323:777-781, 1986). Nucleotides 9 to 20 constitute a second domain which includes sequences for Sm protein binding. The complementarities between the U7 snRNA sequences in this region and the terminal palindrome of the histone mRNA appear to be fortuitous and play only a secondary, if any, role in 3' processing. The third domain is composed of the terminal palindrome of U7 snRNA, the secondary structure of which must be maintained for the U7 snRNP to function, but its sequence can be drastically altered without any observable effect on snRNP assembly or 3' processing.     

Evidence for an association between U1 RNA and interspersed repeat single-copy RNAs in the cytoplasm of sea urchin eggs

Psoralen crosslinking of RNA-RNA intermolecular duplexes in sea urchin egg extracts reveals that some maternal poly(A)+ RNA molecules are complexed with U1 RNA, a cofactor in somatic nuclear pre-mRNA splicing. Reaction of egg extracts with a monoclonal antibody specific for U1 snRNP selects, in addition to U1, RNAs that contain repeated sequences interspersed with single-copy elements. Antibody-selection experiments with nucleate and anucleate egg halves demonstrate that most of the U1 RNA-interspersed RNA complexes are cytoplasmic, as is the egg's store of total U1 snRNP. These results raise the possibility that maternal interspersed RNAs include unprocessed pre-messenger RNA molecules in arrested complexes with splicing cofactors.     

Structure and tissue-specific developmental expression of a sea urchin arylsulfatase gene

Arylsulfatases are a group of enzymes that remove sulfate moieties from a diverse set of substrates including glycoproteins, steroids, and cerebrosides. We have isolated recombinant cDNA clones corresponding to an arylsulfatase (SpARS) message that encodes an abundant protein of pluteus larvae of the sea urchin Strongylocentrotus purpuratus. Although vertebrate arylsulfatases have broad tissue distributions, in situ hybridization with a probe for SpARS shows that the sea urchin message accumulates in the embryo only in the single cell type of aboral ectoderm and its precursors. The message is first detectable by RNase protection assays around hatching blastula stage and accumulates through pluteus larva stage. The open reading frame of cDNA clones is 1701 nt long and encodes a deduced protein with a predicted molecular mass of 61 kDa. Analysis of corresponding genomic DNA clones reveals that the pre-mRNA contains six exons. Consistent with the fact that arylsulfatase enzyme activity is extracellular, this polypeptide has a hydrophobic leader sequence and three potential glycosylation sites. Furthermore, hybridization in situ shows that in blastulae arylsulfatase message is preferentially concentrated around nuclei at the basal sides of cells. The S. purpuratus sequence is very similar to that recently reported for the same enzyme from Hemicentrotus pulcherrimus and 30% of the amino acid residues are also identical to those of both human arylsulfatase C (steroid sulfatase) and arylsulfatase A. Sequence relationships among these four mRNAs suggest that, assuming equal rates of evolution, the duplication separating the human genes occurred at about the time of separation of the echinoderm and vertebrate lineages.     

Oligo(U) sequences present in sea urchin maternal RNA decrease following fertilization

Oligo(U) tracts were identified and measured in RNA from sea urchin eggs and embryos using a quantitative assay based on the amount of [3H]poly(A) protected from RNase T2 in duplexes with the oligo(U). The oligo(U) amounted to 0.0035% of egg RNA (0.063 X 10(-12) g/egg) and decreased to 0.0015% (0.027 X 10(-12) g/embryo) by 2 hr after fertilization. The oligo(U) tracts had a maximum size of 15-30 nucleotides and were associated with two size classes of RNA. In eggs about half were in 100 to 200 nucleotide RNA and half in mRNA-sized molecules. After fertilization, the oligo(U) in the population of large-mRNA-sized molecules was greatly reduced.     

RNA synthesis in unfertilized sea urchin eggs

We have examined the synthesis of messenger-like RNA in unfertilized sea urchin eggs. Most of the RNA synthesized is restricted to the nucleus and sediments from 16 to 30S. A small fraction can be isolated from the postmitochondrial supernatant and displays a sedimentation profile typical of embryonic mRNA with peaks at 9 and 18S. This cytoplasmic RNA is largely present as free RNPs and we estimate that less than 20% of the RNA is in polysomes. The RNA made in the egg is unstable and reaches a steady state with a half-time of about 30 min. We have examined the accumulation of RNA in the egg and have calculated a rate of synthesis of 1.4 × 10^?14 g of RNA/min/egg which is similar, on a per-nucleus basis, to that found in the just-fertilized egg and very early embryo. It is approximately 10 times greater than the rate of RNA synthesis in the blastula nucleus. We estimate that the RNA synthesized by the unfertilized egg amounts to a maximum of 3 × 10^?13 g of potential mRNA at the time of fertilization, or 10–15% of its immediate needs. This RNA cannot account for the increase in protein synthesis that occurs after fertilization, which must be the result of the translation of another population of more stable egg or oogenic mRNA that is kinetically distinct from the RNA we have measured. The steady-state level of labeled RNA present in the egg does not change upon fertilization until after the first cleavage, at about 2.5 hr after fertilization. Thus the RNA synthesis that occurs in the just-fertilized zygote appears to be merely a continuation (at least quantitatively) of the RNA synthesis taking place in the egg.     

Structure and expression of a chicken gene coding for U1 RNA

We have isolated and sequenced a genomic fragment containing sequences complementary to chicken U1 RNA. The sequence of this genomic U1 gene is completely homologous and colinear with that of chicken U1 RNA. This U1 gene is part of a multigene family (6--10 copies per haploid genome), and these loci do not appear to be closely clustered. Sequences complementary to other snRNAs are not present within the 2.5 kb genomic fragment containing the U1 gene. We have determined that U1 RNA is synthesized by polymerase II; however, a "Hogness box" is not present upstream from its cap site at the position usually observed for mRNA genes. The synthesis of U1 RNA in oviduct nuclei during different states of hormonal induction also appears to be constitutive.     

Structure and expression of the polyubiquitin gene in sea urchin embryos.

A cloned Lytechinus pictus cDNA has been identified, which includes seven direct repeats of a 228 bp sequence encoding ubiquitin and about 450 bp of 3' noncoding sequence. The deduced amino acid sequence is identical to that of ubiquitins of other animals (though repeats 3 and 5 each have single amino acid substitutions at different positions). Southern blot analysis revealed that the sea urchin genome contains a single copy of the polyubiquitin gene, and the number of 228 bp repeat units appears to vary from seven to ten among different alleles; no other ubiquitin coding sequences were detected. The size distribution of polyubiquitin mRNA is polymorphic among different individuals, probably corresponding to the differences in copy number of the repetitive coding sequence. The abundance of cytoplasmic polyubiquitin RNA is constant throughout embryogenesis and is similar in ectoderm, endoderm, and mesoderm cells. The constant prevalence of polyubiquitin mRNA apparently results from a balance between ontogenetic changes in its rate of synthesis and its stability in the presence of actinomycin D. Accumulation of polyubiquitin RNA was not heat shock-inducible during embryogenesis.     

The sea urchin histone gene complement

The only eukaryotic mRNAs that are not polyadenylated are the replication-dependent histone mRNAs in metazoans. The sea urchin genome contains two sets of histone genes that encode non-polyadenylated mRNAs. One of these sets is a tandemly repeated gene cluster with a 5.6-kb repeat unit containing one copy of each of the five alpha-histone genes and is present as a single large cluster which spans over 1 Mb. There is a second set of genes, consisting of 39 genes, containing two histone H1 genes, 34 genes encoding core histone proteins (H2a, H2b, H3 and H4) and three genes expressed only in the testis. Unlike vertebrates where these genes are clustered, the sea urchin late histone genes, expressed in embryos, larvae and adults, are dispersed throughout the genome. There are also genes encoding polyadenylated histone mRNAs, which encode histone variants, including all variants found in other metazoans, as well as a unique set of five cleavage stage histone proteins expressed in oocytes. The cleavage stage histone H1 is the orthologue of an oocyte-specific histone H1 protein found in vertebrates.