Molecular analysis of zebrafish photolyase/cryptochrome family: two types of cryptochromes present in zebrafish.

BACKGROUND: Cryptochromes (CRY), members of the DNA photolyase/cryptochrome protein family, regulate the circadian clock in animals and plants. Two types of animal CRYs are known, mammalian CRY and Drosophila CRY. Both CRYs participate in the regulation of circadian rhythm, but they have different light dependencies for their reactions and have different effects on the negative feedback loop which generates a circadian oscillation of gene expression. Mammalian CRYs act as a potent inhibitor of transcriptional activator whose reactions do not depend on light, but Drosophila CRY functions as a light-dependent suppressor of transcriptional inhibitor. RESULTS: We cloned seven zebrafish genes that carry members of the DNA photolyase/cryptochrome protein family; one (6-4)photolyase and six cry genes. A sequence analysis and determination of their in vitro functions showed that these zebrafish cry genes constitute two groups. One has a high sequence similarity to mammalian cry genes and inhibits CLOCK:BMAL1 mediated transcription. The other, which has a higher sequence similarity to the Drosophila cry gene rather than the mammalian cry genes, does not carry transcription inhibitor activity. The expressions of these cry genes oscillate in a circadian manner, but their patterns differ. CONCLUSIONS: These findings suggest that functionally diverse cry genes are present in zebrafish and each gene has different role in the molecular clock.

Three distinct classes of the alpha-subunit of the nuclear pore-targeting complex (importin-alpha) are differentially expressed in adult mouse tissues.

The process of active nuclear protein transport is mediated by the nuclear localization signal (NLS). An NLS-containing karyophile forms a stable complex, termed the nuclear pore-targeting complex, to target nuclear pores. The alpha-subunit of the complex (importin-alpha) binds to the NLS and the beta-subunit (importin-beta) carries the alpha-subunit, bound to the NLS substrate, into the nucleus. To date, five mouse alpha-subunits have been identified and classified into three subfamilies (alpha-P, alpha-Q, and alpha-S). The expression of these alpha-subunits and the beta-subunit in various adult mouse tissues was examined by immunoblotting and immunohistochemistry using antibodies specific for each subfamily of the alpha-subunit or the beta-subunit. The beta-subunit was found to be ubiquitously expressed, whereas each subfamily of the alpha-subunit showed a unique expression pattern in various tissues, especially in brain and testis. In brain, the expression of alpha-P was not observed, whereas alpha-S was significantly expressed in Purkinje cells, and pyramidal cells of the hippocampus and cerebral cortex. In testis, alpha-P was expressed predominantly in primary spermatocytes, whereas alpha-Q was found mainly in Leydig cells. Expression of alpha-S was detected in almost all cells in convoluted seminiferous tubules and Leydig cells to a similar extent. These results suggest that nuclear protein import may be controlled in a tissue-specific manner by alpha-subunit family proteins.

High incidence of ultraviolet-B-or chemical-carcinogen-induced skin tumours in mice lacking the xeroderma pigmentosum group A gene.

Xeroderma pigmentosum (XP) is an autosomal recessive disorder characterized by a high frequency of skin cancer on sun-exposed areas, and neurological complications. XP has a defect in the early step(s) of nucleotide-excision repair (NER) and consists of eight different genetic complementation groups (groups A-G and a variant). We established XPA (group-A XP) gene-deficient mice by gene targeting of mouse embryonic stem (ES) cells. The XPA-deficient mice showed neither obvious physical abnormalities nor pathological alterations, but were defective in NER and highly susceptible to ultraviolet-B- or 9,10-dimethyl-1,2-benz[a]anthracene-induced skin carcinogenesis. These findings provide in vivo evidence that the XPA protein protects mice from carcinogenesis initiated by ultraviolet or chemical carcinogen. The XPA-deficient mice may provide a good in vivo model to study the high incidence of skin carcinogenesis in group A XP patients.

Identification of splicing mutations of the last nucleotides of exons, a nonsense mutation, and a missense mutation of the XPAC gene as causes of group A xeroderma pigmentosum.

Four mutations of the XPAC gene were identified as molecular bases of different UV-sensitive subgroups of xeroderma pigmentosum (XP) group A. One was a G to C transversion at the last nucleotide of exon 4 in GM1630/GM2062, a little less hypersensitive subgroup than the most sensitive XP2OS/XP12RO. The second mutation was a G to A transition at the last nucleotide of exon 3 in GM2033/GM2090, an intermediate subgroup. Both mutations caused almost complete inactivation of the canonical 5' splice donor site and aberrant RNA splicing. The third mutation was a nucleotide transition altering the Arg-211 codon (CGA) to a nonsense codon (TGA) in another allele of GM2062. The fourth mutation was a nucleotide transversion altering the His-244 codon (CAT) to an Arg codon (CGT) in XP8LO, an intermediate subgroup. Our results strongly suggest that the clinical heterogeneity in XP-A is due to different mutations in the XPAC gene.

Rat DNA polymerase beta gene can join in excision repair of Escherichia coli.

Though DNA polymerase I (poll) of Escherichia (E.) coli is understood to play a role in repair synthesis of excision repair, it is still obscure whether DNA polymerase beta (pol beta) plays a similar role in eukaryotic cells. To estimate the role of pol beta in excision repair processes, we inserted the rat pol beta gene into several mutant E. coli defective in a diverse set of enzymatic activities of poll. UV resistance was seen only when the 5'----3' exonuclease (exo) activity of poll molecules remained. Therefore it is suggested that 5'----3' exo activity as well as pol beta activity are essential for repair synthesis of excision repair in eukaryotic cells.