Conservation of the positions of metazoan introns from sponges to humans

Sponges (phylum Porifera) are the phylogenetic oldest Metazoa still extant. They can be considered as reference animals (Urmetazoa) for the understanding of the evolutionary processes resulting in the creation of Metazoa in general and also for the metazoan gene organization in particular. In the marine sponge Suberites domuncula, genes encoding p38 and JNK kinases contain nine and twelve introns, respectively. Eight introns in both genes share the same positions and the identical phases. One p38 intron slipped for six bases and the JNK gene has three more introns. However, the sequences of the introns are not conserved and the introns in JNK gene are generally much longer. Introns interrupt most of the conserved kinase subdomains I-XI and are found in all three phases (0, 1 and 2). We analyzed in details p38 and JNK genes from human, Caenorhabditis elegans and Drosophila melanogaster and found in most genes introns at the positions identical to those in sponge genes. The exceptions are two p38 genes from D. melanogaster that have lost all introns in the coding sequence. The positions of 11 introns in each of four human p38 genes are fully conserved and ten introns occupy identical positions as the introns in sponge p38 or JNK genes. The same is true for nine, out of ten introns in the human JNK-1 gene. The introns in human p38 and JNK genes are on average more than ten times longer than corresponding introns in sponges. It was proposed that yeast HOG1-like kinases (from i.e. Saccharomyces cerevisiae and Emericella nidulans) and metazoan p38 and JNK kinases are orthologues. p38 and JNK genes were created after the split from fungi by the duplication and diversification of the HOG1-like progenitor gene. Our results further support the common origin of p38 and JNK genes and speak in favor of a very early time of duplication. The ancestral gene contained at least ten introns, which are still present at the very conserved positions in p38 and JNK genes of extant animals. Four of these introns are present at the same positions in the HOG-like gene in the fungus E. nidulans. The others probably entered the ancestral gene after the split of fungi, but before the duplication of the gene and before the creation of the common, urmetazoan progenitor of all multicellular animals. A second gene coding for an immune molecule is described, the allograft inflammatory factor, which likewise showed a highly conserved exon/intron structure in S. domuncula and in human. These data show that the intron/exon borders are highly conserved in genes from sponges to human.     

Nucleotide sequence and intron structure of the apocytochrome b gene of Neurospora crassa mitochondria

The sequence of the apocytochrome b (cob) gene of Neurospora crassa has been determined. The structural gene is interrupted by two intervening sequences of approximately 1260 bp each. The polypeptide encoded by the exons shows extensive homology with the cob proteins of Aspergillus nidulans and Saccharomyces cerevisiae (79% and 60%, respectively). The two introns are, however, located at sites different from those of introns in the cob genes of A. nidulans and S. cerevisiae (which contain highly homologous introns at the same site within the gene). The introns share several short regions of sequence homology (10-12 bp long) with each other and with other fungal mitochondrial introns. Moreover, the second intron contains a 50 nucleotide long sequence that is highly homologous with sequences within every ribosomal intron of fungal mitochondria sequenced to date. The conserved sequences may allow the formation of a core secondary structure, which is nearly identical in many mitochondrial introns. The conserved secondary structure may be required for intron splicing. The second intron contains an open reading frame, continuous with the preceding exon, of approximately 290 codons. Two stretches of 10 amino acid residues, conserved in many introns, are present in the open reading frame.     

Complete sequence of a bovine type I cytokeratin gene: conserved and variable intron positions in genes of polypeptides of the same cytokeratin subfamily

The complete sequence of a bovine gene encoding an epidermal cytokeratin of mol. wt. 54 500 (No VIb) of the acidic (type I) subfamily is presented, including an extended 5' upstream region. The gene (4377 bp, seven introns) which codes for a representative of the glycine-rich subtype of cytokeratins of this subfamily, is compared with genes coding for: another subtype of type I cytokeratin; a basic (type II) cytokeratin gene; and vimentin, a representative of another intermediate filament (IF) protein class. The positions of the five introns located within the highly homologous alpha-helix-rich rod domain are identical or equivalent, i.e., within the same triplet, in the two cytokeratin I genes. Four of these intron positions are also identical with intron sites in the vimentin gene, and three of these intron positions are identical or similar in the type I and type II cytokeratin subfamilies. On the other hand, the gene organization of both type I cytokeratins differs from that of the type II cytokeratin in the rod region in five intron positions and in the introns located in the carboxy-terminal tail region, with the exception of one position at the rod-tail junction. Remarkably, the two type I cytokeratins also differ from each other in the positions of two introns located at and in the region coding for the hypervariable, carboxy-terminal portion. The introns and the 5' upstream regions of the cytokeratin VIb gene do not display notable sequence homologies with the other IF protein genes, but sequences identical with--or very similar to--certain viral and immunoglobulin enhancers have been identified.(ABSTRACT TRUNCATED AT 250 WORDS)     

Characterization of Sinorhizobium meliloti triose phosphate isomerase genes

A Tn5 mutant strain of Sinorhizobium meliloti with an insertion in tpiA (systematic identifier SMc01023), a putative triose phosphate isomerase (TPI)-encoding gene, was isolated. The tpiA mutant grew more slowly than the wild type on rhamnose and did not grow with glycerol as a sole carbon source. The genome of S. meliloti wild-type Rm1021 contains a second predicted TPI-encoding gene, tpiB (SMc01614). We have constructed mutations and confirmed that both genes encode functional TPI enzymes. tpiA appears to be constitutively expressed and provides the primary TPI activity for central metabolism. tpiB has been shown to be required for growth with erythritol. TpiB activity is induced by growth with erythritol; however, basal levels of TpiB activity present in tpiA mutants allow for growth with gluconeogenic carbon sources. Although tpiA mutants can be complemented by tpiB, tpiA cannot substitute for mutations in tpiB with respect to erythritol catabolism. Mutations in tpiA or tpiB alone do not cause symbiotic defects; however, mutations in both tpiA and tpiB caused reduced symbiotic nitrogen fixation.     

Intron structure of the human antithrombin III gene differs from that of other members of the serine protease inhibitor superfamily

Antithrombin III (ATIII) plays an integral role in the coagulation system by inhibiting thrombin and several other activated clotting factors. Inherited deficiency of ATIII is quite common and can result in life-threatening thrombotic complications. In order to understand the basis of ATIII deficiency, we have isolated and characterized the normal human ATIII gene from a recombinant Charon 4A bacteriophage genomic library. The ATIII gene contains six exons and five introns distributed over approximately 19 kilobases of DNA. The positions of introns in the ATIII gene were compared with other members of the serine protease inhibitor family which share 17-31% amino acid homology. When aligned to achieve maximal protein homology, only one of the ATIII introns corresponded to the four introns of rat angiotensinogen or human alpha 1-antitrypsin. Similarly, only one ATIII intron was homologous to the seven introns of chicken ovalbumin. We present two testable models to explain the discrepancy in intron positions among members of the serine protease inhibitor superfamily of genes.     

Structure of a gene for rat calmodulin

The structural organization of the entire rat calmodulin gene was determined by cloning and sequencing overlapping genomic and cDNA clones from rat genomic and brain cDNA libraries. The intron/exon organization was determined by direct comparison of these sequences. Rat calmodulin gene is 9000 bases long and consisted of six exons interrupted by introns of variable sizes. The first intron separates the initiation codon (ATG) from the coding region of the protein. Three out of four intron/exon junctions in the coding region reside in the middle of calcium binding subdomains and do not correlate with the quarterly divided intramolecular homology of the protein. Their positions exactly coincide with those of the corrected version of chicken calmodulin gene. The rat calmodulin gene harbors a stretch of sequences homologous to a rat middle repetitive "identifier sequence" in the middle of the third intron. Analysis of the immediate 5' upstream region detected a TATA box (TATATATAT) and three C-G boxes (CCGCCC) but not a CAT box (CCAAT). A conserved sequence (GCGCCGCGYCYYGGGGGC) was found at -125 for rat and at -204 for chicken calmodulin genes.     

Molecular evolution of calmodulin-like domain protein kinases (CDPKs) in plants and protists

Many genes for calmodulin-like domain protein kinases (CDPKs) have been identified in plants and Alveolate protists. To study the molecular evolution of the CDPK gene family, we performed a phylogenetic analysis of CDPK genomic sequences. Analysis of introns supports the phylogenetic analysis; CDPK genes with similar intron/exon structure are grouped together on the phylogenetic tree. Conserved introns support a monophyletic origin for plant CDPKs, CDPK-related kinases, and phosphoenolpyruvate carboxylase kinases. Plant CDPKs divide into two major branches. Plant CDPK genes on one branch share common intron positions with protist CDPK genes. The introns shared between protist and plant CDPKs presumably originated before the divergence of plants from Alveolates. Additionally, the calmodulin-like domains of protist CDPKs have intron positions in common with animal and fungal calmodulin genes. These results, together with the presence of a highly conserved phase zero intron located precisely at the beginning of the calmodulin-like domain, suggest that the ancestral CDPK gene could have originated from the fusion of protein kinase and calmodulin genes facilitated by recombination of ancient introns. Received: 11 July 2000 / Accepted: 18 April 2001     

A survey of introns in three genes of rotifers

Here we report on the occurrence and position of introns found in three genes of rotifers. A region of the gene for the TATA-box binding protein was examined in three species of Bdelloidea and one of Monogononta. There are two introns in both copies of this gene present in each of the three bdelloids examined – one at a position where introns occur in other eukaryotes and the other at a novel position; the monogonont has no introns in the region examined. A region of the gene encoding the 82 kD heat shock protein was examined in 10 species, with every rotifer class represented. Introns were found in only two species, both bdelloids: one of the species has an intron in all three copies of the gene; the other has an intron in only one of the three copies. Both introns occur at novel positions. The gene for triosephosphate isomerase was examined in one bdelloid. Both copies of the gene in this species contain introns, all at conserved positions: one copy contains five introns, the other copy three. These observations demonstrate the presence of introns in bdelloid rotifers, some in conserved positions, others apparently newly arisen during bdelloid evolution.     

The mitochondrial genome of the fission yeast Schizosaccharomyces pombe: highly homologous introns are inserted at the same position of the otherwise less conserved cox1 genes in Schizosaccharomyces pombe and Aspergillus nidulans.

The DNA sequence of the second intron in the mitochondrial gene for subunit 1 of cytochrome oxidase (cox1), and the 3'' part of the structural gene have been determined in Schizosaccharomyces pombe. Comparing the presumptive amino acid sequence of the 3'' regions of the cox1 genes in fungi reveals similarly large evolutionary distances between Aspergillus nidulans, Saccharomyces cerevisiae and S. pombe. The comparison of exon sequences also reveals a stretch of only low homology and of general size variation among the fungal and mammalian genes, close to the 3'' ends of the cox1 genes. The second intron in the cox1 gene of S. pombe contains an open reading frame, which is contiguous with the upstream exon and displays all characteristics common to class I introns. Three findings suggest a recent horizontal gene transfer of this intron from an Aspergillus type fungus to S. pombe. (i) The intron is inserted at exactly the same position of the cox1 gene, where an intron is also found in A. nidulans. (ii) Both introns contain the highest amino acid homology between the intronic unassigned reading frames of all fungi identified so far (70% identity over a stretch of 253 amino acids). However, in the most homologous region, a GC-rich sequence is inserted in the A. nidulans intron, flanked by two direct repeats of 5 bp. The 37-bp insert plus 5 bp of direct repeat amounts to an extra 42 bp in the A. nidulans intron. (iii) TGA codons are the preferred tryptophan codons compared with TGG in all mitochondrial protein coding sequences of fungi and mammalia.(ABSTRACT TRUNCATED AT 250 WORDS)     

Gene structure of two-domain arginine kinases from Anthopleura japonicus and Pseudocardium sachalinensis

Unusual two-domain arginine kinases (AKs) arose independently at least two times during molecular evolution of phosphagen kinases: AKs from the primitive sea anemone Anthopleura japonicus and from the clam Pseudocardium sachalinensis. To elucidate its unusual evolution, the structures of Anthopleura and Pseudocardium AK genes have been determined. The Anthopleura gene consisted of 4 exons and 3 introns: two domains are linked by a bridge intron, and each domain contains one intron in different positions. On the other hand, the Pseudocardium gene consisted of 10 exons and 9 introns: two domains are also linked by a bridge intron, and domains 1 and 2 contains 3 and 5 introns, respectively, of which 3 introns are located in exactly same positions. Since the two domains of Pseudocardium AK are estimated to have diverged about 290 million years ago, the 3 introns have been conserved at least for this long. Comparison of intron positions in Anthopleura, Pseudocardium and C. elegans AK genes indicates that there is no intron conserved through the three AK lineages, in sharp contrast to relatively conservative intron positions in creatine kinase (CK) gene family.     

Generation of a database containing discordant intron positions in eukaryotic genes (MIDB)

MOTIVATION: Intron sliding is the relocation of intron-exon boundaries over short distances and is often also referred to as intron slippage or intron migration or intron drift. We have generated a database containing discordant intron positions in homologous genes (MIDB--Mismatched Intron DataBase). Discordant intron positions are those that are either closely located in homologous genes (within a window of 10 nucleotides) or an intron position that is present in one gene but not in any of its homologs. The MIDB database aims at systematically collecting information about mismatched introns in the genes from GenBank and organizing it into a form useful for understanding the genomics and dynamics of introns thereby helping understand the evolution of genes. RESULTS: Intron displacement or sliding is critically important for explaining the present distribution of introns among orthologous and paralogous genes. MIDB allows examining of intron movements and allows mapping of intron positions from homologous proteins onto a single sequence. The database is of potential use for molecular biologists in general and for researchers who are interested in gene evolution and eukaryotic gene structure. Partial analysis of this database allowed us to identify a few putative cases of intron sliding. AVAILABILITY: http://intron.bic.nus.edu.sg/midb/midb.html     

Structure of the genes of two homologous intracellularly heterotopic isoenzymes. Cytosolic and mitochondrial aspartate aminotransferase of chicken

The genes of mitochondrial and cytosolic aspartate aminotransferase of chicken were cloned and sequenced. In both genes nine exons encode the mature enzyme. The additional exon for the N-terminal presequence that directs mitochondrial aspartate aminotransferase into the mitochondria is separated by the largest intron from the rest of the gene. A comparison of the two genes of chicken with the aspartate aminotransferase genes of mouse [Tsuzuki, T., Obaru, K., Setoyama, C. & Shimada, K. (1987) J. Mol. Biol. 198, 21-31; Obaru, K., Tsuzuki, T., Setoyama, C. & Shimada, K. (1988) J. Mol. Biol. 200, 13-22] reveals closely similar structures: in the gene of both the mitochondrial and the cytosolic isoenzyme all but one intron positions are conserved in the two species and five introns out of nine are placed at the same positions in all four genes indicating that the introns were in place before the genes of the two isoenzymes diverged. The variant consensus sequence (T/C)11 T(C/T)AG at the 3' splice site of the introns of the genes for nuclear-encoded mitochondrial proteins, which had been deduced from a total of 34 introns [Jureti?, N., Jaussi, R., Mattes, U. & Christen, P. (1987) Nucleic Acids Res. 15, 10,083-10,086], was confirmed by including an additional 22 introns into the comparison. The position -4 at the 3' splice site is occupied by base T in 43% of the total 56 introns and appears to be subject to a special evolutionary constraint in this particular group of genes. The following course of evolution of the aspartate aminotransferase genes is proposed. Originating from a common ancestor, the genes of the two isoenzymes intermediarily evolved in separate lineages, i.e. the ancestor eukaryotic and ancestor endosymbiontic cells. When endosymbiosis was established, part of the endosymbiontic genome, including the aspartate aminotransferase gene, was transferred to the nucleus. This process probably led to the conservation of certain splicing factors specific for nuclear-encoded mitochondrial proteins. The presequence for the mitochondrial isoenzyme was acquired by DNA rearrangement. In the eukaryotic lineage, the mitochondrial isoenzyme evolved more slowly than its cytosolic counterpart.