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Homologous recombination (HR) and nonhomologous end joining (NHEJ) are two distinct DNA double-stranded break (DSB) repair pathways. Here, we report that DNA-dependent protein kinase (DNA-PK), the core component of NHEJ, partnering with DNA-damage checkpoint kinases ataxia telangiectasia mutated (ATM) and ATM- and Rad3-related (ATR), regulates HR repair of DSBs. The regulation was accomplished through modulation of the p53 and replication protein A (RPA) interaction. We show that upon DNA damage, p53 and RPA were freed from a p53-RPA complex by simultaneous phosphorylations of RPA at the N-terminus of RPA32 subunit by DNA-PK and of p53 at Ser37 and Ser46 in a Chk1/Chk2-independent manner by ATR and ATM, respectively. Neither the phosphorylation of RPA nor of p53 alone could dissociate p53 and RPA. Furthermore, disruption of the release significantly compromised HR repair of DSBs. Our results reveal a mechanism for the crosstalk between HR repair and NHEJ through the co-regulation of p53-RPA interaction by DNA-PK, ATM and ATR.

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AIMS: To investigate the prevalence of Helicobacter pylori in the saliva of patients infected with this bacterium. METHODS: A novel polymerase chain reaction (PCR) assay was developed to detect H pylori in saliva and gastric biopsy specimens from patients undergoing endoscopy. RESULTS: Our PCR assay amplified a 417 base pair fragment of DNA from all 21 DNAs derived from H pylori clinical isolates but did not amplify DNA from 23 non-H pylori strains. Sixty three frozen gastric biopsy and 56 saliva specimens were tested. H pylori specific DNA was detected by PCR in all 39 culture positive biopsy specimens and was also identified from another seven biopsy specimens which were negative by culture but positive by histology. H pylori specific DNA was identified by PCR in saliva specimens from 30 (75%) of 40 patients with H pylori infection demonstrated by culture or histological examination, or both, and in three patients without H pylori infection in the stomach. CONCLUSION: The results indicate that the oral cavity harbours H pylori and may be the source of infection and transmission.

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A temperature-sensitive, protein synthesis-defective mutant of Escherichia coli exhibiting an altered ribosomal protein L22 has been investigated. The temperature-sensitive mutation was mapped to the rplV gene for protein L22. The genes from the wild type and mutant strains were amplified by the polymerase chain reaction and the products were sequenced. A cytosine to thymine transition at position 22 of the coding sequence was found in the mutant DNA, predicting an arginine to cysteine alteration in the protein. A single cysteine residue was found in the isolated mutant protein. This amino acid change accounts for the altered mobility of the mutant protein in two-dimensional gels and during reversed-phase HPLC. The temperature-sensitive phenotype was fully complemented by a plasmid carrying the wild type L22 gene. Ribosomes from the complemented cells showed only wild type protein L22 by two dimensional gel analysis and were as heat-resistant as control ribosomes in a translation assay. The point mutation in the L22 gene is uniquely responsible for the temperature-sensitivity of this strain.

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A hot alkaline lysis procedure for plasmid DNA isolation is described for the preparation of high-quality substrates for automated DNA sequence analysis. This miniprep procedure employs routine laboratory chemicals while avoiding the use of enzymes and organic solvents to produce plasmid DNA free of RNA contamination. The method is inexpensive, relatively quick and can yield over 20 micrograms plasmid DNA from a 5-ml overnight culture. Automated sequencing has a success rate of > or = 96% with plasmid substrates prepared by this method. In addition, the plasmid DNAs can be used successfully in all types of molecular biology manipulations.

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A recently isolated human alphoid DNA (in plasmid pHH550) has been sequenced and found to have an exceptionally high degree of similarity to the human alphoid consensus sequence, while its component monomers are unusually heterogeneous in sequence. In contrast to other alphoid DNAs, this DNA is found in all primates tested. Thus this may be an evolutionarily old sequence similar to the one from which other human alphoid DNAs diverged. The pHH550 sequences are found on a number of human chromosomes, including 21 and 22. On chromosome 21 most members of this new sequence group are located distal to other alphoid DNAs.

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Mouse mast cell chymases are granule-associated serine proteinases with chymotrypsin-like substrate specificities. cDNAs for two new chymases were isolated from a cDNA library constructed using mRNA from ABFTL-6 mouse mast cells by screening with a rat mast cell proteinase cDNA. The deduced amino acid sequence of mouse chymase 1 consists of a 226 amino acid catalytic portion and a 21 amino acid preprosequence. Chymase 1 is unusual in that an Asn occurs in the substrate binding pocket, a feature that has not been observed in any other serine proteinase. Also, chymase 1 is expected to have a large positive charge (+13) at physiological pH. A partial cDNA for chymase 2 encodes 177 residues of the carboxy terminal portion of a second proteinase distinct from chymase 1. Chymase 2 cDNA contains a highly conserved intron/exon junction, a high positive charge (+17) and a novel, second potential N-glycosylation site. Transcripts for both chymases are found in ABFTL-6 mast cells, but only chymase 2 mRNA is in mouse connective tissue mast cells. These data suggest that these chymases have distinct enzymatic properties and tissue-specific patterns of gene expression.

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Intact chromosomal DNAs are routinely prepared by embedding cells in agarose plugs before lysis. The large sizes of the genomic DNAs cause their retention while other macromolecules diffuse into and out of the gel matrix during lysis, washing and restriction cleavage incubations. However, in an analysis of agarose-embedded chromosomal DNAs cleaved with restriction enzymes, fragments larger than 30 kilobases were found to have eluted from the gel plugs. Since loss of fragments from gel plugs may affect qualitative and quantitative interpretations of electrophoretic patterns, an analysis of the diffusion of DNA segments from agarose plugs was performed. The two variables monitored were the time dependence and the DNA fragment size dependence of the diffusion process. The results indicate that small fragments (less than or equal to 2 kilobases) are quickly lost from 1% agarose gel plugs; moreover, significant amounts of large DNA segments (i.e., the 48.5-kilobase lambda phage chromosome) are also lost. In addition to urging caution in the analysis of restriction cleavage data, these observations suggest that intact small organelle genomes and extrachromosomal DNAs also may be lost from genomic DNAs prepared in agarose gel plugs.

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Treating proteins with low concentrations of sodium dodecyl sulfate (SDS) and boiling for 2-3 min increased the linear range and total amount of protein that could be bound to nitrocellulose. Human serum albumin (HSA) and cathepsin G (Cat G) were both optimally bound at an SDS concentration of 10 micrograms/ml, while bronchial leukocyte proteinase inhibitor (BLPI) required 50 micrograms/ml SDS for optimum binding, corresponding to SDS-to-protein weight ratios of 0.5 and 2.5, respectively. Ionic strength and pH of the blotting buffers had a greater effect on the binding of SDS-treated proteins than on native proteins, with the linear binding range and total capacity for SDS-treated proteins being increased. Boiling SDS-treated human leukocyte extracts inactivated endogenous peroxidases, eliminating their interference with peroxidase-linked secondary antibodies in immunoassays. The nonionic detergents, Tween 20 and Nonidet P-40, were shown to rapidly wash both native and SDS-treated HSA off the filters, but these HSA samples were stable to washing with SDS. Although SDS-treated Cat G was more stable with nonionic detergents than was native Cat G, it was less resistant to washing with SDS. The substitution of SDS for nonionic detergents improved the response of immunoassays with native and SDS-treated proteins. Affinity-purified antibodies to human mast cell tryptase cross-reacted with native Cat G, but not with SDS-treated Cat G, indicating that SDS treatment can improve the specificity of immunoassays employing polyclonal antisera. These effects appear to be the result of partial denaturation and increases in the hydrophobicity of SDS-treated relative to native proteins.

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Several human DNAs digested with Kpn I restriction endonuclease released a 0.6-kilobase (kb) segment that varied in its intensity among human samples. A recombinant DNA clone (N6.4) of these 0.6-kb Kpn I segments was isolated and used to probe the genomic content and restriction cleavage pattern of homologous sequences. The hybridization patterns revealed a previously undescribed, moderately repetitive long interspersed (LINE) sequence family, which we have termed L2Hs (second LINE family in Homo sapiens). This LINE family exhibits both quantitative and qualitative polymorphisms in the human population. The content of L2Hs sequences in human genomes varies over a 5-fold range. Relative to the value for a human placental DNA, sequences homologous to the L2Hs family occur in lower amounts in gorilla DNA (approximately 20%) and even less in DNA from chimpanzees and other primates (less than 1%). Thus, the L2Hs sequences appear to have emerged only recently as a moderately repetitive sequence family in primate evolution. The observed restriction fragment length polymorphism of the L2Hs family members may reflect patterns of sequence rearrangements, amplifications, and/or deletions in human genomes.

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Analysis of rhesus monkey alphoid DNA suggests that it arose by tandem duplication of an ancestral monomer unit followed by independent variation within two adjacent monomers (one becoming more divergent than the other) before their amplification as a dimer unit to produce tandem arrays. The rhesus monkey alphoid DNA is a tandemly repeated, 343-bp dimer; the consensus dimer is over 98% homologous to the alphoid dimers reported for baboon and bonnet monkey, 81% homologous to the African green monkey alpha monomer, and less than 70% homologous to the more divergent human alphoid DNAs. The consensus dimer consists of two wings (I and II, 172 and 171 bp, respectively) that are only 70% homologous to each other, but share seven regions of exact homology. These same regions are highly conserved among the consensus sequences of the other cercopithecid alphoid DNAs. The three alpha-protein binding sites reported for African green monkey alpha DNA by F. Strauss and A. Varshavsky (Cell 37: 889-901, 1984) occur in wings I and II, but with one site altered in wing I. Two cloned dimer segments are 98% homologous to the consensus, each containing 8 single-base-pair differences within the 343-bp segment. Surprisingly, 37% of these differences occur in regions that are evolutionarily conserved in the alphoid consensus sequences, including the alpha-protein binding sites. Sequence variation in this highly repetitive DNA family may produce unique nucleosomal architectures for different members of an alphoid array. These unique architectures may modulate the evolution of these repetitive DNAs and may produce unique centromeric characteristics in primate chromosomes.

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Various pretreatments of metaphase spreads were examined to obtain optimal DNA labelling patterns while maintaining chromosome integrity during in situ hybridization procedures. Preparations of African green monkey (AGM) chromosomes fixed in methanol-acetic acid (CV-1 cell line) were treated by coating with Denhardt's solution, dilute gelatin-chrome alum, nonfat instant dry milk dissolved in saline-citrate solution (SSC) and/or acetylation prior to denaturation of chromosomal DNA in 70% formamide-2 X SSC for 2 min at 70 degrees C. A 3H-labelled, cloned DNA fragment of the highly repetitive AGM component alpha DNA was hybridized to the chromosomes by incubation at 45 degrees C for 16 h. Treatment with gelatin-chrome alum prior to denaturation greatly improved chromosome morphology and decreased background, but reduced pericentromeric labelling. Sequential treatment with 5 X Denhardt's solution followed by gelatin-chrome alum resulted in enhanced specificity of labelling and excellent chromosome morphology, as well as reduced levels of background. Acetylation had little effect after pretreatment with gelatin-chrome alum, but reduced background levels after pretreatment with Denhardt's solution. Chromosomes treated with Denhardt's solution plus gelatin-chrome alum can be routinely G-banded using trypsin after in situ hybridization.

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The KpnI sequences constitute the dominant, long, interspersed repetitive DNA families in primate genomes. These families contain related, but nonidentical sequence subsets, some of which border functional gene domains and are transcribed into RNA. To test whether these sequences perform an organizational function in the nucleus, their association with the nuclear matrix has been examined in African green monkey cells. DNase I treatment depleted the residual matrix of most of the KpnI 1.2- and 1.5-kilobase pair family sequences although significant amounts of each family remained in the loop attachment DNA fragments. Hybridization analysis of the KpnI and RsaI cleavage patterns of matrix loop attachment DNA indicate that some sequence subsets of these KpnI families are relatively less depleted than others. The nuclear matrix association of subpopulations of KpnI 1.2- and 1.5-kilobase pair families was also shown by metrizamide gradient centrifugation of nuclear matrix complexes cleaved by KpnI endonuclease. The gradients demonstrate that some KpnI segments are differentially associated with nuclear matrix proteins. Moreover, the procedures permit the preparative isolation and purification of the DNA-protein complexes containing these KpnI 1.2- and 1.5-kilobase pair sequence families. Speculations on the relationship between the matrix association of these KpnI family sequences and their possible roles in gene organization and expression are presented and discussed.

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The micrococcal nuclease cleavage of intact nuclear chromatin from African green monkey cells and of the completely deproteinized sequences was studied by using high-resolution analytical and DNA sequencing gels and secondary restriction enzyme analysis. When deproteinized component alpha DNA was used as substrate, not all phosphodiester bonds in the 172-base-pair repeat units were cleaved with equal frequency by the nuclease. A distinct preference for the cleavage of A-T rather than G-C bonds was observed; however, A + T-richness in itself did not confer susceptibility to cleavage by micrococcal nuclease. The results suggested that, in deproteinized DNA, nuclease cleavage at particular dinucleotides may be influenced more by the effect of adjacent sequences than by the composition of the dinucleotide. In contrast to complex cleavage patterns of the deproteinized component alpha DNA which arose because of multiple cleavage sites in the repeat unit, micrococcal nuclease cleaved component alpha nuclear chromatin at one site per nucleosome repeat, near position 126 in the nucleotide sequence. This simple chromatin cleavage pattern is consistent with the discrete nucleosomal structure of component alpha in chromatin and a direct phase relationship between the component alpha DNA sequence repeats and the nucleosome protein structural repeats.

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Families of related, but nonidentical repetitive DNA sequences, termed the alphoid DNAs, have been identified and characterized in representative species from seven major primate Families. The sequences appear as old as the primate Order itself: they are found in a prosimian (lemur), in a New World monkey, and in all Old World primates examined, including man. The alphoid DNAs are uniquely primate sequences and they may represent the most abundant repetitive DNAs in the primate genome. - A classification scheme for two major families of alphoid DNAs is proposed that is based upon restriction enzyme analysis and Southern blotting with radioactive probes prepared from component alpha DNA (Maio, 1971) and from the human EcoRI dimer sequences (Manuelidis, 1976). The family of alphoid DNAs that hybridizes readily with component alpha is termed the HindIII family of alphoid DNAs. This family shows an almost universal distribution among present-day primates. The family of DNA sequences that hybridizes readily with the human EcoRI dimer probe is termed the EcoRI dimer family of alphoid DNAs. This family may be restricted to the great apes and man. The two probes permitted the discrimination of different, but related alphoid families in present-day primates. Multiple alphoid sequence families are found within the genomes of individual primates and the major primate taxa can be characterized by the representations of the various alphoid DNAs within their genomes. - An Appendix is presented (Brown et al., 1981) indicating that competition hybridization effects may influence the autoradiographic banding patterns, and hence, the interpretations of Southern filter-transfer hybridizations when dealing with related repetitive sequences such as the alphoid DNAs that are present in abundance in eukaryotic genomes.

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KpnI restriction of anthropoid primate DNAs, from a New World monkey to man, releases a series of segments that are remarkable among all of the alphoid DNAs in the constancy of their relative amounts in the various primate genomes, in their long-range organization, and in their internal sequence structure. These segments are labeled the KpnI A, B, C and D segments. Cross-hybridization analysis by Southern filter-transfer hybridization indicates that the KpnI segments represent separate and distinct families of alphoid DNAs. These families are termed the KpnI A, B, C and D families of alphoid sequences, of which only the KpnI A and B families were studied in detail here. - Evidence is presented suggesting that the KpnI segments do not exist as long, tandemly repeated sequences in the primate genome: rather, they may occur interspersed among other, perhaps nonalphoid sequences. From the stained gel patterns and from Southern filter-transfer hybridization experiments, the KpnI families appear to be absent from the genomes of the two prosimians studied - the galago and the black lemur. The KpnI A and B families are found among all of the anthropoid primates, including the New World capuchin monkey. The KpnI C family was detected in the genomes of the Old World anthropoid primates whereas the KpnI D family was detected only among the great apes and man. - The results are in accord with the observation (Musich et al., 1980) that with the continued evolutionary development of the primate Order, there has been a parallel trend toward an increased number and variety of alphoid DNA sequences. The properties of the KpnI families suggest that these sequences, unique among the alphoid DNAs, have been conservatively maintained throughout primate phylogeny and that they are among the most ancient of all primate DNAs.

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The genomes of Old-World, New-World, and prosimian primates contain members of a large class of highly repetitive DNAs that are related to one another and to component alpha DNA of the African green monkey by their sequence homologies and restriction site periodicities. The members of this class of highly repetitive DNAs are termed the alphoid DNAs, after the prototypical member, component alpha of the African green monkey which was the first such DNA to be identified (Maio, 1971) and sequenced (Rosenberg et al., 1978). The alphoid DNAs appear to be uniquely primate sequences.--From the restriction enzyme cleavage patterns and Southern blot hybridizations under different stringency conditions, the alphoid DNAs comprise multiple sequence families exhibiting varying degrees of homology to component alpha DNA. They also share common elements in their restriction site periodicities (172 . n base-pairs), in the long-range organization of their repeating units, and in their banding behavior in CsCl and Cs2SO4 bouyant density gradients, in which they band within the bulk DNA as cryptic repetitive components.--In the three species from the Family Cercopithecidae examined, the alphoid DNAs represent the most abundant, tandemly repetitive sequence components, comprising about 24% of the African green monkey genome and 8 to 10% of the Rhesus monkey and baboon genomes. In restriction digests, the bulk of the alphoid DNAs among the Cercopithecidae appeared quantitatively reduced to a simple series of arithmetic segments based on a 172 base-pair (bp) repeat. In contrast with these simple restriction patterns, complex patterns were observed when human alphoid DNAs were cleaved with restriction enzymes. Detailed analysis revealed that the human genome contains multiple alphoid sequence families which differ from one another both in their repeat sequence organization and in their degree of homology to the African green monkey component alpha DNA.--The finding of alphoid sequences in other Old-World primate families, in a New-World monkey, and in a prosimian primate attests to the antiquity of these sequences in primate evolution and to the sequence conservatism of a large class of mammalian highly repetitive DNA. In addition, the relative conservatism exhibited by these sequences may distinguish the alphoid DNAs from more recently evolved highly repetitive components and satellite DNAs which have a more restricted taxonomical distribution.

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Component alpha DNA is a highly repetitive sequence that comprises nearly a quarter of the African green monkey (Cercopithecus aethiops) genome. A previous microbial restriction enzyme analysis showed that the repeat structure of component alpha DNA is based upon a monomeric unit of 176 +/- 4 base-pairs. An endonuclease, provisionally termed Case I, has been isolated from African green monkey testes that cleaves component alpha DNA into multimeric segments based upon the same repeat periodicity as that revealed by microbial restriction enzymes. The primary sites of Cae I cleavage in the component alpha sequence appear to be 120 +/- 6 base-pairs distant from the Hind III sites and 73 +/- 6 base-pairs distant from the Eco RI* sites. Cae I has been partially characterized with special reference to the effects of ATP and S-adenosylmethionine on the cleavage of component alpha DNA. Cae I may be a member of a class of similar site-specific nucleases present in mammalian cells. Cae I also cleaves mouse satellite DNA into a multimeric series of discrete segments: the periodicity of this series is shorter than that revealed by Eco RII retriction analysis of mouse satellite DNA.

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