Advances in Biophysics最新文献

The isolation of the NBS1 gene revealed the molecular mechanisms of DSB repair. In response to DNA damage, histone H2AX in the vicinity of DSBs is phosphorylated by ATM. NBS1 then targets the MRE11/RAD50 complex to the sites of DSBs through interaction of the FHA/BRCT domain with gamma-H2AX. NBS1 complex binds to damaged-DNA directly, and HR repair is initiated. To collaborate DSB repair, ATM also regulates cell cycle checkpoints at G1, G2, and intra-S phases via phosphorylation of SMC, CHK2 and FANCD2. The phosphorylation of these proteins require NBS1 complex. Thus, NBS1 has at least two important roles in genome maintenance, as a DNA repair protein in HR pathway and as a signal modifier in intra-S phase checkpoints. NBS1 is also known to be involved in maintenance of telomeres, which have DSB-like structures and defects here can cause telomeric fusion. Therefore, NBS1 should be a multifunctional protein for the maintenance of genomic integrity. Further studies on NBS1 will provide insights into the mechanisms of DNA damage response and the network of these factors involved in genomic stability.

Human genome is continuously exposed to various DNA damaging agents including reactive oxygen species. Of various forms of DNA damage, double-strand breaks (DSBs) in DNA are the most detrimental because of the mutagenicity and cytotoxicity. To combat the serious threats posed by DSBs, cells evolved various homologous and non-homologous recombination repair mechanisms. However, some repair mechanisms appear to be involved in the induction of genome rearrangements such as deletions. To analyze the deletion mutations in a whole body system, gpt delta mice were established. In this mouse model, deletions in lambda DNA integrated in the chromosome are preferentially selected as Spi- phages, which can then be subjected for molecular analysis. Here, we reported the sequence characteristics of deletions induced by ionizing radiations in the liver, ultraviolet light B in the epidermis, mitomycin C in the bone marrow and heterocyclic amine PhIP in the colon. To our knowledge, this is the first report in which in vivo deletion mutations are systematically analyzed at the molecular level. About half of the large deletions occur between short direct-repeat sequences and the remainder had flush ends, suggesting that they are generated during the repair of DSBs in DNA. The results also suggest that mutation induction and repair mechanisms may vary depending on the type of organs/tissues examined, i.e., germ cells versus somatic cells or highly proliferating cells versus slowly proliferating cells. Possible mechanisms of intrachromosomal deletion mutations are discussed.

In Saccharomyces cerevisiae, VMA1 intein encodes a homing endonuclease termed VDE which is produced by an autocatalytic protein splicing reaction. VDE introduces a DSB at its recognition sequence on intein-minus allele, resulting in the lateral transfer of VMA1 intein. In this review, we summarize a decade of in vitro study on VDE and describe our recent study on the in vivo behavior of both VDE and host proteins involved in intein mobility. Meiotic DSBs caused by VDE are repaired in the similar pathway to that working in meiotic recombination induced by Spo11p-mediated DSBs. Meiosis-specific DNA cleavage and homing is shown to be guaranteed by the two distinct mechanisms, the subcellular localization of VDE and a requirement of premeiotic DNA replication. Based on these lines of evidence, we present the whole picture of molecular mechanism of VDE-initiated homing in yeast cells.

Human genome is continuously exposed to various DNA damaging agents including reactive oxygen species. Of various forms of DNA damage, double-strand breaks (DSBs) in DNA are the most detrimental because of the mutagenicity and cytotoxicity. To combat the serious threats posed by DSBs, cells evolved various homologous and non-homologous recombination repair mechanisms. However, some repair mechanisms appear to be involved in the induction of genome rearrangements such as deletions. To analyze the deletion mutations in a whole body system, gpt delta mice were established. In this mouse model, deletions in lambda, DNA integrated in the chromosome are preferentially selected as Spi(-) phages, which can then be subjected for molecular analysis. Here, we reported the sequence characteristics of deletions induced by ionizing radiations in the liver, ultraviolet light beta in the epidermis, mitomycin C in the bone marrow and heterocyclic amine PhIP in the colon. To our knowledge, this is the first report in which in vivo deletion mutations are systematically analyzed at the molecular level. About half of the large deletions occur between short direct-repeat sequences and the remainder had flush ends, suggesting that they are generated during the repair of DSBs in DNA. The results also suggest that mutation induction and repair mechanisms may vary depending on the type of organs/tissues examined, i.e., germ cells versus somatic cells or highly proliferating cells versus slowly proliferating cells. Possible mechanisms of intrachromosomal deletion mutations are discussed.

Among the genus Ipomoea, three morning glories, I. nil the Japanese morning glory), I. purpurea (the common morning glory), and I. tricolor, were domesticated well for floricultural plants, and many spontaneous mutants displaying various flower pigmentation patterns were isolated. Most of these spontaneous mutations were found to be caused by the insertion of DNA transposable elements in the genes for the anthocyanin pigmentation in flowers, and many of them exhibited variegated flowers, such as white flowers with pigmented spots and sectors. Here, we describe the historical background of the mutants displaying variegated flowers and review the genetic and epigenetic regulation in flower pigmentation associated with transposable elements of these morning glories. The flecked, speckled, r-1, and purple mutations in I. nil were caused by insertions of Tpnl and its relatives in the En/Spm superfamily, Tpn2, Tpn3, and Tpn4, into the genes for anthocyanin coloration in flowers,i.e., DFR-B, CHI, CHS-D, and InNHXI, respectively. Similarly, the flaked and pink mutants of I. purpurea have distantly related elements, Tip100 and Tip201, in the Ac/Ds superfamily inserted into the CHS-D and F3'H genes, respectively. The flower variegation patterns can be determined by the frequency and timing of the excision of these transposons, and their stable insertions produce plain color flowers without generating pigmented spots or sectors; furthermore, both genetic and epigenetic regulation appeared to play important roles in determining the frequency and timing of the excision of the transposons. However, flower variegation is not always associated with the excision of an integrated DNA transposon from one of the genes for anthocyanin pigmentation. The mutant Flying Saucers of I. tricolor displaying variegated flowers was found to have the transposon ItMULE inserted into the DFR-B promoter region, but no excision of ITMULEL from the DFR-B could be detected in the variegated flower lines. The instable pearly-vrg allele in cv. Flying Saucers is likely to be an epiallele because the DNA methylation in the DFR-B promoter appeared to be associated with flower pigmentation.

Conservative site-specific recombination plays key roles in creating biological diversity in prokaryotes. Most site-specific inversion systems consist of two recombination sites and a recombinase gene. In contrast, the shufflon multiple inversion system of plasmid R64 consists of seven sfx recombination sites, which separate four invertible DNA segments, and the rci gene encoding a site-specific recombinase of the integrase family. The rci product mediates recombination between any two inverted sfx sites, resulting in the inversion of four DNA segments independently or in groups. Random shufflon inversions construct seven pilV genes encoding constant N-terminal segment with different C-terminal segments. The pilV products are tip-located adhesins of the type IV pilus, called the thin pilus, of R64 and recognize lipopolysaccharides of recipient bacterial cells during R64 liquid matings. Thus, the shufflon determines the recipient specificity of liquid matings. Rci protein of R64 was overexpressed, purified, and used for in vitro recombination reactions. The cleavage and rejoining of DNA strands in shufflon recombinations were found to take place in the form of a 5' protruding 7-bp staggered cut within sfx sequences. Thus, the sfx sequence is asymmetric: only the 7-bp spacer sequence and the right arm sequence are conserved among various R64 sfxs, whereas the sfx left arm sequences are not conserved. Rci protein was shown to bind to entire sfx sequences, suggesting that it binds to the right arms of the sfx sequences in a sequence-specific manner and to their left arms in a non-sequence-specific manner. The sfx left arm sequences greatly affected the shufflon inversion frequency. The artificial symmetric sfx sequence, in which the sfx left arm was changed to the inverted repeat sequence of the right arm, exhibited the highest inversion frequency. Rci-dependent deletion of a DNA segment flanked by two symmetric sfx sequences in direct orientation was observed, suggesting that the asymmetry of sfx sequences may prevent recombination between sfx sequences in direct orientation in the R64 shufflon. The Rci C-terminal domain was not required for recombination using the symmetric sfx sequence. A model, where the C-terminal domain of Rci protein plays a key role in the sequence-specific and non-specific binding of Rci to asymmetric sfx sites, was proposed. Site-specific recombination in the temperate phage Mx8 of M. xanthus was also described. The Mx8 attP site is located within the coding sequence of the Mx8 intP gene. Therefore, the integration of Mx8 into the M. xanthus chromosome results in the conversion of the intP gene into a new gene, intR. As a result of this conversion, the 112-amino-acid C-terminal sequence of the intP product is replaced with a 13-amino acid sequence of the intR product. The C-terminal domain of Mx8 IntP recombinase is only required for integration and not for excision.

Conservative site-specific recombination plays key roles in creating biological diversity in prokaryotes. Most site-specific inversion systems consist of two recombination sites and a recombinase gene. In contrast, the shufflon multiple inversion system of plasmid R64 consists of seven sfx recombination sites, which separate four invertible DNA segments, and the rci gene encoding a site-specific recombinase of the integrase family. The rci product mediates recombination between any two inverted sfx sites, resulting in the inversion of four DNA segments independently or in groups. Random shufflon inversions construct seven pilV genes encoding constant N-terminal segment with different C-terminal segments. The pilV products are tip-located adhesins of the type IV pilus, called the thin pilus, of R64 and recognize lipopolysaccharides of recipient bacterial cells during R64 liquid matings. Thus, the shufflon determines the recipient specificity of liquid matings. Rci protein of R64 was overexpressed, purified, and used for in vitro recombination reactions. The cleavage and rejoining of DNA strands in shufflon recombinations were found to take place in the form of a 5' protruding 7-hp staggered cut within sfx sequences. Thus, the sfx sequence is asymmetric: only the 7-bp spacer sequence and the right arm sequence are conserved among various R64 sfxs, whereas the sfx left arm sequences are not conserved. Rci protein was shown to bind to entire sfx sequences, suggesting that it binds to the right arms of the sfx sequences in a sequence-specific manner and to their left arms in a non-sequence-specific manner. The sfx left arm sequences greatly affected the shufflon inversion frequency. The artificial symmetric sfx sequence, in which the sfx left arm was changed to the inverted repeat sequence of the right arm, exhibited the highest inversion frequency. Rci-dependent deletion of a DNA segment flanked by two symmetric sfx sequences in direct orientation was observed, suggesting that the asymmetry of sfx sequences may prevent recombination between sfx sequences in direct orientation in the R64 shufflon. The Rci C-terminal domain was not required for recombination using the symmetric sfx sequence. A model, where the C-terminal domain of Rci protein plays a key role in the sequence-specific and non-specific binding of Rci to asymmetric sfx sites, was proposed. Site-specific recombination in the temperate phage Mx8 of M. xanthus was also described. The Mx8 attP site is located within the coding sequence of the Mx8 intP gene. Therefore, the integration of Mx8 into the M. xanthus chromosome results in the conversion of the intP gene into a new gene, intP. As a result of this conversion, the 112-amino-acid C-terminal sequence of the intP product is replaced with a 13-amino acid sequence of the intR product. The C-terminal domain of Mx8 IntP recombinase is only required for integration and not for excision.