Increased base change mutations at G:C pairs in Escherichia coli deficient in endonuclease III and VIII

Various types of mutation induced by oxidative DNA damage, induced by hydrogen peroxide and riboflavin photosensitization, were determined in Escherichia coli (E. coli) mutants deficient in endonuclease III (endo III) and endonuclease VIII (endo VIII). The majority of hydrogen peroxide-induced and spontaneous mutations consisted of G:C to A:T and to T:A base changes, shown on the mutation assay system by a reversion at a specific site of the lacZ gene. Base changes were also localized at G:C pairs in the mutation of the supF gene, induced by riboflavin photosensitization, which specifically yields 7,8-dihydro-8-oxoguanine (8-oxoG). G:C to T:A and to C:G transversions dominated in both mutants. These results suggest that endo III and endo VIII are involved in the repair of oxidative lesions of guanine.

Alternative excision repair pathway of UV-damaged DNA in Schizosaccharomyces pombe operates both in nucleus and in mitochondria

The fission yeast, Schizosaccharomyces pombe, possesses a UV-damaged DNA endonuclease-dependent excision repair (UVER) pathway in addition to nucleotide excision repair pathway for UV-induced DNA damage. We examined cyclobutane pyrimidine dimer removal from the myo2 locus on the nuclear genome and the coI locus on the mitochondrial genome by the two repair pathways. While nucleotide excision repair repairs damage only on the nuclear genome, UVER efficiently removes cyclobutane pyrimidine dimers on both nuclear and mitochondrial genomes. The ectopically expressed wild type UV-damaged DNA endonuclease was localized to both nucleus and mitochondria, while modifications of N-terminal methionine codons restricted its localization to either of two organelles, suggesting an alternative usage of multiple translation initiation sites for targeting the protein to different organelles. By introducing the same mutations into the chromosomal copy of the uvde(+) gene, we selectively inactivated UVER in either the nucleus or the mitochondria. The results of UV survival experiments indicate that although UVER efficiently removes damage on the mitochondrial genome, UVER in the mitochondria hardly contributes to UV resistance of S. pombe cells. We suggest a possible UVER function in mitochondria as a backup system for other UV damage tolerance mechanisms.

Transcription dependence and the roles of two excision repair pathways for UV damage in fission yeast Schizosaccharomyces pombe

Fission yeasts Schizosaccharomyces pombe possess two types of excision repair systems for UV-induced DNA damage, nucleotide excision repair (NER) and UV-damaged DNA endonuclease (UVDE)-dependent excision repair (UVER). Despite its high efficiency in damage removal, UVER defects have less effect on UV survival than NER defects. To understand the differential roles of two pathways, we examined strand-specific damage removal at the myo2 and rpb2 loci. Although NER removes cyclobutane pyrimidine dimers from the transcribed strand more rapidly than from the nontranscribed strand, UVER repairs cyclobutane pyrimidine dimers equally on both strands and at a much higher rate than NER. The low rate of damage removal from the nontranscribed strand in the absence of UVER indicates inefficient global genome repair (GGR) in this organism and a possible function of UVER as an alternative to GGR. Disruption of rhp26, the S. pombe homolog of CSB/RAD26, eliminated the strand bias of NER almost completely and resulted in a significant increase of UV sensitivity of cells in a uvdeDelta background. We suggest that the combination of transcription-coupled repair of NER and rapid UVER contributes to UV survival in growing S. pombe cells, which is accomplished by transcription-coupled repair and GGR in other organisms.

Phylogenetic affinities of Diplonema within the Euglenozoa as inferred from the SSU rRNA gene and partial COI protein sequences

In order to shed light on the phylogenetic position of diplonemids within the phylum Euglenozoa, we have sequenced small subunit rRNA (SSU rRNA) genes from Diplonema (syn. Isonema) papillatum and Diplonema sp. We have also analyzed a partial sequence of the mitochondrial gene for cytochrome c oxidase subunit I from D. papillatum. With both markers, the maximum likelihood method favored a closer grouping of diplonemids with kinetoplastids, while the parsimony and distance suggested a closer relationship of diplonemids with euglenoids. In each case, the differences between the best tree and the alternative trees were small. The frequency of codon usage in the partial D. papillatum COI was different from both related groups; however, as is the case in kinetoplastids but not in Euglena, both the non-canonical UGA codon and the canonical UGG codon were used to encode tryptophan in Diplonema.

Phylogenetic affinity of mitochondria of Euglena gracilis and kinetoplastids using cytochrome oxidase I and hsp60

The mitochondrial DNA-encoded cytochrome oxidase subunit I (COI) gene and the nuclear DNA-encoded hsp60 gene from the euglenoid protozoan Euglena gracilis were cloned and sequenced. The COI sequence represents the first example of a mitochondrial genome-encoded gene from this organism. This gene contains seven TGG tryptophan codons and no TGA tryptophan codons, suggesting the use of the universal genetic code. This differs from the situation in the mitochondrion of the related kinetoplastid protozoa, in which TGA codes for tryptophan. In addition, a complete absence of CGN triplets may imply the lack of the corresponding tRNA species. COI cDNAs from E. gracilis possess short 5' and 3' untranslated transcribed sequences and lack a 3' poly[A] tail. The COI gene does not require uridine insertion/ deletion RNA editing, as occurs in kinetoplastid mitochondria, to be functional, and no short guide RNA-like molecules could be visualized by labeling total mitochondrial RNA with [alpha-32P]GTP and guanylyl transferase. In spite of the differences in codon usage and the 3' end structures of mRNAs, phylogenetic analysis using the COI and hsp60 protein sequences suggests a monophyletic relationship between the mitochondrial genomes of E. gracilis and of the kinetoplastids, which is consistent with the phylogenetic relationship of these groups previously obtained using nuclear ribosomal RNA sequences.

Guide RNAs and guide RNA genes in the cryptobiid kinetoplastid protozoan, Trypanoplasma borreli

Trypanoplasma borreli belongs to the bodonid/cryptobiid group of kinetoplastid protozoa, which represents a sister group to the trypanosomatids. RNA transcripts from several mitochondrial genes in this organism undergo the trypanosomatid type of uridine addition/deletion RNA editing. A guide RNA (gRNA) cDNA library was constructed and five gRNAs were identified, one for editing the ribosomal protein S12 mRNA, three for editing the cytochrome oxidase subunit I mRNA, and one for editing the cytochrome b mRNA. All of the gRNAs contained nonencoded oligo[U] sequences at the 3' end, as is common with gRNAs in trypanosomatids, but also contained nonencoded oligo[U] sequences at the 5' end. The mechanism for addition of the 5' nonencoded oligo[U] sequence and the function of this sequence are unknown. The T. borreli gRNAs were shorter (25-35 nt, excluding the 5' oligo[U]) than gRNAs in trypanosomatids (45-50 nt), indicating a smaller size of editing blocks in this organism. Genomic sequences for two gRNAs were cloned and sequenced. These two gRNA-encoding sequences were shown to originate from the 180-kb Component I molecules, which represent a possible homologue of minicircle DNA in trypanosomatids, and not from the 80-kb Component II molecules, which contain the structural genes and cryptogenes.

Minicircle-encoded guide RNAs from Crithidia fasciculata

Although the mitochondrial uridine insertion/deletion, guide RNA (gRNA)-mediated type of RNA editing has been described in Crithidia fasciculata, no evidence for the encoding of gRNAs in the kinetoplast minicircle DNA has been presented. There has also been a question as to the capacity of the minicircle DNA in this species to encode the required variety of gRNAs, because the kinetoplast DNA from the C1 strain has been reported as essentially containing a single minicircle sequence class. To address this problem, the genomic and mature edited sequences of the MURF4 and RPS12 cryptogenes were determined and a gRNA library was constructed from mitochondrial RNA. Five specific gRNAs were identified, two of which edit blocks within the MURF4 mRNA, and three of which edit blocks within the RPS12 mRNA. The genes for these gRNAs are all localized with identical polarity within one of the two variable regions of specific minicircle molecules, approximately 60 bp from the "bend" region. These minicircles were found to represent minor sequence classes representing approximately 2% of the minicircle DNA population in the network. The major minicircle sequence class also encodes a gRNA at the same relative genomic location, but the editing role of this gRNA was not determined. These results confirm that kinetoplast minicircle DNA molecules in this species encode gRNAs, as is the case in other trypanosomatids, and suggest that the copy number of specific minicircle sequence classes can vary dramatically without an overall effect on the RNA editing system.

A eukaryotic gene encoding an endonuclease that specifically repairs DNA damaged by ultraviolet light

Many eukaryotic organisms, including humans, remove ultraviolet (UV) damage from their genomes by the nucleotide excision repair pathway, which requires more than 10 separate protein factors. However, no nucleotide excision repair pathway has been found in the filamentous fungus Neurospora crassa. We have isolated a new eukaryotic DNA repair gene from N.crassa by its ability to complement UV-sensitive Escherichia coli cells. The gene is altered in a N.crassa mus-18 mutant and responsible for the exclusive sensitivity to UV of the mutant. Introduction of the wild-type mus-18 gene complements not only the mus-18 DNA repair defect of N.crassa, but also confers UV-resistance on various DNA repair-deficient mutants of Saccharomyces cerevisiae and a human xeroderma pigmentosum cell line. The cDNA encodes a protein of 74 kDa with no sequence similarity to other known repair enzymes. Recombinant mus-18 protein was purified from E.coli and found to be an endonuclease for UV-irradiated DNA. Both cyclobutane pyrimidine dimers and (6-4)photoproducts are cleaved at the sites immediately 5' to the damaged dipyrimidines in a magnesium-dependent, ATP-independent reaction. This mechanism, requiring a single polypeptide designated UV-induced dimer endonuclease for incision, is a substitute for the role of nucleotide excision repair of UV damage in N.crassa.

A new class of DNA photolyases present in various organisms including aplacental mammals

DNA photolyase specifically repairs UV light-induced cyclobutane-type pyrimidine dimers in DNA through a light-dependent reaction mechanism. We have obtained photolyase genes from Drosophila melanogaster (fruit fly), Oryzias latipes (killifish) and the marsupial Potorous tridactylis (rat kangaroo), the first photolyase gene cloned from a mammalian species. The deduced amino acid sequences of these higher eukaryote genes show only limited homology with microbial photolyase genes. Together with the previously cloned Carassius auratus (goldfish) gene they form a separate group of photolyase genes. A new classification for photolyases comprising two distantly related groups is proposed. For functional analysis P.tridactylis photolyase was expressed and purified as glutathione S-transferase fusion protein from Escherichia coli cells. The biologically active protein contained FAD as light-absorbing cofactor, a property in common with the microbial class photolyases. Furthermore, we found in the archaebacterium Methanobacterium thermoautotrophicum a gene similar to the higher eukaryote photolyase genes, but we could not obtain evidence for the presence of a homologous gene in the human genome. Our results suggest a divergence of photolyase genes in early evolution.

Visible light-inducible photolyase gene from the goldfish Carassius auratus

By introducing and expressing a cDNA library constructed from mRNA of the cultured goldfish Carassius auratus cells in Escherichia coli, a gene encoding photolyase of the vertebrate was isolated, the first example from metazoa. The amino acid sequence deduced from the nucleotide sequence differs significantly from those of microorganisms. Five out of 6 tryptophan residues strictly conserved in photolyases from microorganisms and thought to play important roles in DNA and chromophore binding of the enzyme are substituted by other residues of different characteristics. By Northern analysis the expression of the photolyase gene was found to be induced more than 10 times by exposure of the cells to visible light. These results indicate a unique evolution of the photolyase gene and a novel mechanism of gene regulation, in which visible light triggers the production of the light-dependent enzyme for repair of DNA damages induced by harmful ultraviolet part of sunlight.

Enhancement of photorepair of ultraviolet-induced pyrimidine dimers by preillumination with fluorescent light in the goldfish cell line. The relationship between survival and yield of pyrimidine dimers

The enhancement of photorepair of UV-induced pyrimidine dimers by preillumination with fluorescent light, previously reported with RBCF-1 cells derived from caudal fin of a goldfish, was studied in terms of clonogenic ability and yields of dimers. In the logarithmic growth phase, the ability of photorepair increased with the time after preillumination, reached a maximum at 8 h, and gradually declined. At 8 h, the dose decrement with the photorepair-treatment for 20 min at 7.5 J/m2 UV increased by preillumination for 1 h from 1.6 to 3.1 J/m2 in terms of restoration of survival and from 1.2 to 4.3 J/m2 in terms of the disappearance of dimers. Incubation of the preilluminated cells in the medium containing cycloheximide (0.5 microgram/mL) after preillumination until UV-irradiation diminished their enhancement of photorepair. In the density-inhibited state, the ability of photorepair was higher than in the log phase, and it was hardly enhanced by preillumination.

Enhancement of repair of UV-irradiated plasmids in cultured fish cells by fluorescent light preillumination and growth arrest

The UV-irradiated plasmid pBSCATSV, which could express chloramphenicol acetyltransferase (CAT) in the presence of SV40 early promoter, was transfected into RBCF-1 cells derived from the goldfish (Carassius auratus). The cells were incubated in the dark for 24 h and then the CAT activity was measured. CAT expression relative to non-irradiated control was calculated. The CAT expression of the exponentially growing cells transfected with UV-irradiated plasmid was enhanced by fluorescent light (FL) preillumination of the cells 8 h before transfection. The efficiency of photorepair (PR) measured by CAT expression was also enhanced by the same FL preillumination. This suggests that FL preillumination enhances both photorepair and dark repair of RBCF-1 cells for UV-damaged plasmid transfected into the cells. The enhancement of repair of UV damage by FL preillumination was also observed in survival assays. When the UV-irradiated pBSCATSV was transfected into growth-arrested cells in confluent culture, CAT expression was less sensitive to UV irradiation, and FL preillumination was much less effective in enhancing photorepair and dark repair.

Enhancement of photorepair of ultraviolet-damage by preillumination with fluorescent light in cultured fish cells

Fluorescent light (FL) illumination of RBCF-1 cells, derived from a goldfish, prior to 254 nm UV-irradiation enhanced their ability to photorepair. The cells were illuminated with FL for 1 h (29 W/M2) and incubated for 8 h in the dark before being irradiated with 10 J/m2 UV. The surviving fraction of FL-treated cells after UV-irradiation rose about 7-fold (from 3 to 20%) by 20 min photorepair treatment with the same FL source, whereas 4-fold (from 1.6 to 6%) in the FL non-treated cells. Flow cytometric analysis showed that FL treatment did not affect the distribution of cell cycle phase at the time of UV-irradiation (8 h after FL treatment). Pyrimidine dimers induced by UV were measured by the use of UV endonuclease of Micrococcus luteus and alkaline agarose gel electrophoresis. Initial yields of dimers after exposure to 10 J/m2 UV were almost the same (about 0.11 dimer/kb) between FL treated and non-treated cells. But after 20 min photorepair treatment, about 70% of dimers were removed in the FL treated samples, while less than 20% were removed in the non FL-treated ones.