Characterization of the mitochondrial respiratory pathways in Candida albicans

cDNA and genomic clones encoding guanylate cyclase activating proteins (GCAP1 and GCAP2) in the Japanese puffer fish (Fugu rubripes) were identified by probing, respectively, a retinal cDNA library and a whole genomic cosmid library with human GCAP1 and GCAP2 cDNA probes. Clones were identified as GCAP1 and GCAP2 on the basis of amino acid identity with the equivalent frog sequences and their placement into GCAP1 and GCAP2 clades within a GCAP phylogenetic tree. The Fugu genes have an identical four exon/three intron structure to GCAP1 and GCAP2 genes from other vertebrates but the introns are smaller, with the result that the four exons spread over approximately 1 kb of DNA in each case. The two genes are separated on to separate cosmids. However, the results of Southern analysis of the cosmids and of genomic DNA are consistent with a tail-to-tail gene arrangement, as in other species, but with a surprisingly large intergenic separation of around 18.7 kb. Recombinant Fugu GCAP1 failed to activate human retinal guanylate cyclase (retGC) in vitro although CD spectroscopy shows that the protein is folded with a similar secondary structure to that of human GCAP1. The failure to activate may be due therefore to a lack of molecular compatibility in this heterologous assay system.     

Intron loss in the SART1 genes of Fugu rubripes and Tetraodon nigroviridis.

The human SART1 gene was initially identified in a screen for proteins recognised by IgE, which may be implicated in atopic disease. We have examined the genomic structure and cDNA sequence of the SART1 gene in the compact genomes of the pufferfish Fugu rubripes and Tetraodon nigroviridis. The entire coding regions of both the Fugu and Tetraodon SART1 genes are contained within single exons. The Fugu gene contains only one intron located in the 5' untranslated region. Southern blot hybridisation of Fugu genomic DNA confirmed the SART1 gene to be single copy. Partial genomic structures were also determined for the human, mouse, Drosophila and C. elegans SART1 homologues. The human and mouse genes both contain many introns in the coding region, the human gene possessing at least 20 exons. The Drosophila and C. elegans homologues contain 6 and 12 exons, respectively. This is only the second time such a difference in the organization of homologous Fugu and human genes has been reported. The Fugu and Tetraodon SART1 genes encode putative proteins of 772 and 774 aa, respectively, each having 65% amino acid identity to human SART1. Leucine zipper and basic motifs are conserved in the predicted Fugu and Tetraodon proteins.     

Topoisomerase III is essential for accurate nuclear division in Schizosaccharomyces pombe.

Topoisomerases catalyse changes in the topological state of DNA and are required for many aspects of DNA metabolism. While the functions of topoisomerases I and II in eukaryotes are well established, the role of topoisomerase III remains poorly defined. We have identified a gene in the fission yeast Schizosaccharomyces pombe, designated top3 (+), which shows significant sequence similarity to genes encoding topoisomerase III enzymes in other eukaryotic species. In common with murine TOP3 alpha, but in contrast to Saccharomyces cerevisiae TOP3, the S.pombe top3 (+)gene is essential for long-term cell viability. Fission yeast haploid spores containing a disrupted top3 (+)gene germinate successfully, but then undergo only a limited number of cell divisions. Analysis of these top3 mutants revealed evidence of aberrant mitotic chromosome segregation, including the 'cut' phenotype, where septation is completed prior to nuclear division. Consistent with the existence of an intimate association (originally identified in S.cerevisiae ) between topoisomerase III and DNA helicases of the RecQ family, deletion of the rqh1 (+)gene encoding the only known RecQ helicase in S.pombe suppresses lethality in top3 mutants. This conservation of genetic interaction between two widely diverged yeasts suggests that the RecQ family helicases encoded by the Bloom's and Werner's syndrome genes are likely to act in concert with topoisomerase III isozymes in human cells. Our data are consistent with a model in which the association of a RecQ helicase and topoisomerase III is important for facilitating decatenation of late stage replicons to permit faithful chromosome segregation during anaphase.     

The topoisomerase I gene from Ustilago maydis: sequence, disruption and mutant phenotype.

The Ustilago maydis genomic TOP1 gene encoding DNA topoisomerase I was cloned by amplifying a gene fragment using the polymerase chain reaction, and using this fragment to search a genomic DNA library by hybridization. The predicted peptide sequence exhibited 30-40% identity to other eukaryotic TOP1 genes, yet differed in several features. First, an unusually long acidic region was identified near the amino terminus (28/29 residues are acidic), which resembles other nucleolar peptide motifs. Second, an atypical carboxy-terminal 'tail', absent in other TOP1 genes, followed the active site tyrosine residue. A top1 gene disruption mutant was constructed by replacing the genomic TOP1 gene, with a top1::HygR null allele. This mutant lost the abundant topoisomerase I activity evident in wild-type U.maydis, and displayed a subtle coloration phenotype evident during cell senescence.     

Thirteen-exon-motif signature for vertebrate nuclear and mitochondrial type IB topoisomerases

DNA topoisomerases contribute to various cellular activities that involve DNA. We previously identified a human nuclear gene that encodes a mitochondrial DNA topoisomerase. Here we show that genes for mitochondrial DNA topoisomerases (type IB) exist only in vertebrates. A 13-exon topoisomerase motif was identified as a characteristic of genes for both nuclear and mitochondrial type IB topoisomerases. The presence of this signature motif is thus an indicator of the coexistence of nuclear and mitochondrial type IB DNA topoisomerases. We hypothesize that the prototype topoisomerase IB with the 13-exon structure formed first, and then duplicated. One topoisomerase specialized for nuclear DNA and the other for mitochondrial DNA.     

Complete genomic structure of human rpS3: identification of functional U15b snoRNA in the fifth intron

Analysis of the complete genomic structure of the human ribosomal protein S3 (rpS3) gene revealed the presence of a functional U15b snoRNA gene in its intron. Human ribosomal protein S3 (rpS3) gene of 6115 bp long has been identified to contain six introns and seven exons in this study. The first and fifth introns of human S3 gene contain functional U15 snoRNA genes. Although Xenopus and Fugu counterparts also have six introns and seven exons, S3 gene of Fugu contains two functional U15 snoRNAs in the fourth and sixth introns and two pseudo genes for U15 snoRNAs in the first and fifth introns. In Xenopus S1 gene encoding ribosomal protein S3, however, three of its six introns contain U15 snoRNA gene sequence. Sequence comparison of the U15 genes from Xenopus, Fugu and human revealed that the regions involved in binding to 28S rRNA and the consensus sequence (C, D and D' boxes) for snoRNAs are highly conserved among those genes from these three species. Human U15a and U15b RNAs which are derived from the first and the fifth introns, respectively, have been identified to be functional by microinjection of human U15a and U15b snoRNAs into Xenopus oocyte. Northern blot and primer extension analyses confirm that human U15b snoRNA is expressed in vivo.     

Comparative mapping of the human 9q34 region in Fugu rubripes

Twenty-seven genes have been cloned and mapped in Fugu which have orthologues within the human chromosome 9q34 region. The genes are arranged into five cosmid and BAC contigs which physically map to two different Fugu chromosomes. Considering the gene content of these contigs, it is more probable that a translocation event took place early in the Fugu lineage to split the ancestral 9q34 region onto two chromosomes rather than the alternative hypothesis of a large-scale duplication of the region into two chromosomes with subsequent rapid and dramatic gene loss. There are considerable differences in gene order between the two species, which would appear to be the result of a series of complex chromosome inversions; thus suggesting that there have been no positional constraints on this particular gene set.     

Cloning and characterization of Drosophila topoisomerase IIIbeta. Relaxation of hypernegatively supercoiled DNA

We cloned cDNA encoding Drosophila DNA topoisomerase III. The top3 cDNA encodes an 875-amino acid protein, which is nearly 60% identical to mammalian topoisomerase IIIbeta enzymes. Similarity between the Drosophila protein and the topoisomerase IIIbetas is particularly striking in the carboxyl-terminal region, where all contain eight highly conserved CXXC motifs not found in other topoisomerase III enzymes. We therefore propose the Drosophila protein is a member of the beta-subfamily of topoisomerase III enzymes. The top3beta gene is a single-copy gene located at 5 E-F on the X chromosome. P-element insertion into the 5'-untranslated region of this gene affects topoisomerase IIIbeta protein levels, but not the overall fertility and viability of the fly. We purified topoisomerase IIIbeta to near homogeneity and observed relaxation activity only with a hypernegatively supercoiled substrate, but not with plasmid DNA directly isolated from bacterial cells. Despite this difference in substrate preference, the degree of relaxation of the hypernegatively supercoiled substrate is comparable to relaxation of plasmid DNA by other type I enzymes. Drosophila topoisomerase IIIbeta forms a covalent linkage to 5' DNA phosphoryl groups, and the DNA cleavage reaction prefers single-stranded substrate over double-stranded, suggesting an affinity of this enzyme for DNA with non-double-helical structure.     

Genome rearrangement in top3 mutants of Saccharomyces cerevisiae requires a functional RAD1 excision repair gene.

Saccharomyces cerevisiae cells that are mutated at TOP3, a gene that encodes a protein homologous to bacterial type I topoisomerases, have a variety of defects, including reduced growth rate, altered gene expression, blocked sporulation, and elevated rates of mitotic recombination at several loci. The rate of ectopic recombination between two unlinked, homologous loci, SAM1 and SAM2, is sixfold higher in cells containing a top3 null mutation than in wild-type cells. Mutations in either of the two other known topoisomerase genes in S. cerevisiae, TOP1 and TOP2, do not affect the rate of recombination between the SAM genes. The top3 mutation also changes the distribution of recombination events between the SAM genes, leading to the appearance of novel deletion-insertion events in which conversion tracts extend beyond the coding sequence, replacing the DNA flanking the 3' end of one SAM gene with nonhomologous DNA flanking the 3' end of the other. The effects of the top3 null mutation on recombination are dependent on the presence of an intact RAD1 excision repair gene, because both the rate of SAM ectopic gene conversion and the conversion tract length were reduced in rad1 top3 mutant cells compared with top3 mutants. These results suggest that a RAD1-dependent function is involved in the processing of damaged DNA that results from the loss of Top3 activity, targeting such DNA for repair by recombination.     

Genetic Analysis of the Gyrase a-like Domain of DNA Topoisomerase II of Saccharomyces Cerevisiae

We have undertaken a genetic analysis of heat-sensitive and cold-sensitive mutations in TOP2, the gene encoding yeast DNA topoisomerase II. Deletion mapping was used to localize 14 heat-sensitive and four cold-sensitive top2 mutations created by a method biased toward mutations in the 3' two-thirds of the gene. The mutations all appear to be located in the region of DNA topoisomerase II that shows homology to the "A" subunit of bacterial DNA gyrase. The heat-sensitive mutations and one cold-sensitive mutation lie in the center of the gene near the sequence that encodes the active site tyrosine. The three other cold-sensitive mutations map farther toward the 3' end of the gene. The cold-sensitive mutations exhibit intragenic complementation, and the complementation groups correspond to the physical map. We sequenced nine top2 mutations and found that the mutations are usually single missense mutations, frequently involve proline, and affect conserved regions of the protein. Suppressor analysis yielded two intragenic suppressors and seven independent isolates of an allele-specific extragenic suppressor we named tos1; tos1 is not allelic to any genes predicted to encode type I topoisomerase-related proteins. The two intragenic suppressors were tested for allele-specificity; the results revealed a complex pattern of suppression between heat-sensitive and cold-sensitive top2 alleles. These top2 mutations may have compensatory effects on the general stability of the protein.     

Comparative analysis of a 229-kb medaka genomic region, containing the zic1 and zic4 genes, with Fugu, human, and mouse

Medaka is one of the prominent model animals, which also include other fishes such as Fugu and zebrafish. Its genome is relatively compact but has not been well characterized. Here we have sequenced a 229-kb region of medaka, containing the Double anal fin (Da) locus, and compared its structure to those in Fugu, human, and mouse. This region, representing a gene-poor region, contains no major rearrangements and can be readily compared among different species. Comparison of G+C contents and repeats suggested that medaka and Fugu are highly related as expected and that medaka is more similar to mammals than Fugu is. Sequence comparisons of developmental genes zic1 and zic4, identified within this region, revealed that zic1, but not zic4, is highly conserved among vertebrates. The 5' coding region of zic4 is, however, extremely homologous among fishes with little synonymous substitutions, implying its distinct function in fish.     

Analysis of the spermine synthase gene region in Fugu rubripes, Tetraodon fluviatilis, and Danio rerio

A prerequisite to understanding the evolution of the human X chromosome is the analysis of synteny of X-linked genes in different species. We have focused on the spermine synthase gene in human Xp22. 1. We show that whereas the human gene spans a genomic region of 54 kb, the Fugu rubripes gene is encompassed in a 4.7-kb region. However, we could not find conserved synteny between this region of human Xp22 and the equivalent F. rubripes region. A cosmid clone containing the F. rubripes gene does not contain other X-linked genes. Instead we identified homologs of human genes that are autosomally localized: the ryanodine receptor type I (RYRI), which is implicated in malignant hyperthermia and central core disease, and the HE6 gene. Comparison of the F. rubripes, Tetraodon fluviatilis, mouse, human, and Danio rerio 5'UTRs of spermine synthase highlights conserved sequences potentially involved in regulation. Interestingly, pseudogenes of this gene that are present in the human and mouse genomes seem to be absent in the compact F. rubripes genome. Analysis of a D. rerio PAC clone containing spermine synthase shows an intermediate genomic size in this fish. Sequence analysis of this PAC clone did not reveal other known genes: neither the RYRI gene, nor the HE6 gene, nor other human Xp22 genes were identified.     

Identification and comparative analysis of the RpL14 gene from Takifugu rubripes

The ribosomal protein RpL14 gene has been characterized in several species, including, human, rat and fruit fly. Haploinsufficiency for the gene causes the Minute phenotype in Drosophila, and it has been proposed as a regulator in the tumorigenic pathway in human. Several features concerning the gene structure have been studied, and some of these differ between human/rat and Drosophila. To address functional and evolutionary questions about these differences we have isolated and sequenced a cDNA and a genomic clone covering the RpL14 gene from the pufferfish Takifugu rubripes (Fugu). The Fugu RpL14 gene is approximately 2 Kb, with 5 introns, and encodes a protein of 137 amino acids. The protein contains a KOW-motif and a nuclear localization signal, which are conserved among a wide range of RPL14 proteins. On the other hand, a variable amino acid (alanine) repeat observed in human is missing in Takifugu rubripes, and the protein is shorter than its mammalian counterparts. Compared with human, the RpL14 gene in Fugu contains introns localized at identical positions in the gene, and most of them are shorter. A comparison of the RpL14 gene structure from a broad range of organisms indicates that both loss and gain of introns have occurred during the evolution of the gene.     

Fugu and human sequence comparison identifies novel human genes and conserved non-coding sequences

The compact genome of the pufferfish, Fugu rubripes, has been proposed as a 'reference' genome to aid in annotating and analysing the human genome. We have annotated and compared 85 kb of Fugu sequence containing 17 genes with its homologous loci in the human draft genome and identified three 'novel' human genes that were missed or incompletely predicted by the previous gene prediction methods. Two of the novel genes contain zinc finger domains and are designated ZNF366 and ZNF367. They map to human chromosomes 5q13.2 and 9q22.32, respectively. The third novel gene, designated C9orf21, maps to chromosome 9q22.32. This gene is unique to vertebrates, and the protein encoded by it does not contain any known domains. We could not find human homologs for two Fugu genes, a novel chemokine gene and a kinase gene. These genes are either specific to teleosts or lost in the human lineage. The Fugu-human comparison identified several conserved non-coding sequences in the promoter and intronic regions. These sequences, conserved during 450 million years of vertebrate evolution, are likely to be involved in gene regulation. The 85 kb Fugu locus is dispersed over four human loci, occupying about 1.5 Mb. Contiguity is conserved in the human genome between six out of 16 Fugu gene pairs. These contiguous chromosomal segments should share a common evolutionary history dating back to the common ancestor of mammals and teleosts. We propose contiguity as strong evidence to identify orthologous genes in distant organisms. This study confirms the utility of the Fugu as a supplementary tool to uncover and confirm novel genes and putative gene regulatory regions in the human genome.