Evolutionary breakpoints are co-localized with fragile sites and intrachromosomal telomeric sequences in primates.

The concentration of evolutionary breakpoints in primate karyotypes in some particular regions or chromosome bands suggests that these chromosome regions are more prone to breakage. This is the first extensive comparative study which investigates a possible relationship of two genetic markers (intrachromosomal telomeric sequences [TTAGGG]n, [ITSs] and fragile sites [FSs]), which are implicated in the evolutionary process as well as in chromosome rearrangements. For this purpose, we have analyzed: (a) the cytogenetic expression of aphidicolin-induced FSs in Cebus apella and Cebus nigrivittatus (F. Cebidae, Platyrrhini) and Mandrillus sphinx (F. Cercopithecidae, Catarrhini), and (b) the intrachromosomal position of telomeric-like sequences by FISH with a synthetic (TTAGGG)n probe in C. apella chromosomes. The multinomial FSM statistical model allowed us to determinate 53 FSs in C. apella, 16 FSs in C. nigrivittatus and 50 FSs in M. sphinx. As expected, all telomeres hybridized with the probe, and 55 intrachromosomal loci were also detected in the Cebus apella karyotype. The chi(2) test indicates that the coincidence of the location of Cebus and Mandrillus FSs with the location of human FSs is significant (P < 0.005). Based on a comparative cytogenetic study among different primate species we have identified (or described) the chromosome bands in the karyotypes of Papionini and Cebus species implicated in evolutionary reorganizations. More than 80% of these evolutionary breakpoints are located in chromosome bands that express FSs and/or contain ITSs.

Intrachromosomal telomeric repeats and stabilization of truncated chromosomes in V79 Chinese hamster cells.

(TTAGGG)n sequences have been localized on the chromosomes of the Chinese hamster V79 cell line. A correlation between telomeric-like repeats and chromosome breakage has been found. Moreover, the analysis of the truncated chromosomes, typical of this cell line, has suggested that intrachromosomal (TTAGGG)n DNA may be important in the stabilization of the new telomeres.

Two extended arrays of a satellite DNA sequence at the centromere and at the short-arm telomere of Chinese hamster chromosome 5.

We have cloned a Chinese hamster chromosome-specific repeated sequence (SatCH5). This satellite is composed of a 33-bp unit organized in two extended tandem arrays. It is localized at the centromere and at the short-arm subtelomere of chromosome 5. Altogether, SatCH5 covers about 1-2 Mb per diploid genome and is not present in other species, including the Syrian hamster and mouse. Since it is known in the Chinese hamster and numerous other vertebrate species that telomeric (TTAGGG)n repeats are localized at the centromeres of several chromosomes, we studied the localization of SatCH5 relative to (TTAGGG)n sequences. Using two-color fluorescence in situ hybridization on stretched chromosomes and on DNA fibers, we have shown that at the centromere of chromosome 5 SatCH5 and the (TTAGGG)n arrays are contiguous. SatCH5 is the first chromosome-specific repetitive sequence located at both the pericentromeric and subtelomeric regions of the same chromosome.

Telomeric and nontelomeric (TTAGGG)n sequences in gene amplification and chromosome stability.

We have isolated eight PALA-resistant mutants from CHO-PV cells and have shown that the CAD gene was amplified. We then localized the CAD genes with fluorescence in situ hybridization followed by G-banding and identified 10 different marker chromosomes carrying amplified DNA. TTAGGG repetitions, which normally map to the telomeres and centromeres, have also been localized on the 10 marker chromosomes. The organization of amplified genes and of TTAGGG sequences suggests that dicentrics were formed during amplification and that breakage-fusion-bridge cycles may have generated 7 marker chromosomes. One isochromosome was probably derived from abnormal centromere segregation at anaphase. The most striking observation was that TTAGGG sequences of centromeric origin surrounded the amplified regions and were always localized at the telomeres of the chromosome arms carrying amplified DNA. These results indicate that the recombination events that accompanied gene amplification frequently involved centromeric DNA. Moreover, breakage within centromeric TTAGGG repeats may produce telomere-like structures that stabilize the ends of rearranged chromosomes.

Localization of the Chinese hamster CAD gene reveals homology between human chromosome 2p and Chinese hamster 7q.

The trifunctional enzyme CAD catalyzes the first three steps of pyrimidine biosynthesis. By using fluorescence in situ hybridization we have localized the Chinese hamster CAD gene on chromosome 7q11-q13 of diploid fibroblasts. Other genes previously assigned to chromosome 7 include acid phosphatase-1, the M2 subunit of ribonucleotide reductase and ornithine decarboxylase. These genes are also syntenic with CAD on human chromosome 2p. We have then mapped CAD on the pericentromeric region of two different rearranged chromosomes (Z8p and R2q) in a cell line derived from Chinese hamster ovary. The presence of CAD on Z8 and R2 indicates that they derive from rearrangements involving chromosome 7.

BHK cell lines with increased rates of gene amplification are hypersensitive to ultraviolet light.

Four cell lines (MP1, -4, -5, -7), isolated from baby hamster kidney cells after simultaneous selection with N-(phosphonacetyl)-L-aspartate and methotrexate, have previously been shown to amplify their DNA at an increased rate. We now show that all four lines are hypersensitive to killing by UV light and mitomycin C. At high doses of UV light or mitomycin C, the MP lines survived less than 10% or less than 5% as well as parental cells, respectively. After UV irradiation, inhibition of DNA and RNA synthesis was greater in MP than in parental cells, and recovery was slower or absent. A 2- to 3.5-fold increase in the frequency of UV-induced sister chromatid exchange was also seen in the four cell lines. In MP5, unscheduled DNA replication after treatment with UV light was only approximately 70% as great as in parental cells and the other MP lines. In MP4 and MP7 cells S phase was elongated. Although their individual properties confirm that the four cell lines are independent, their common properties suggest a relationship between tolerance of DNA damage and gene amplification.

Bacillus subtilis deoxyribonuclease activity specific for single-stranded deoxyribonucleic acid: cellular site and variations during germination and sporulation.

The endonuclease of Bacillus subtilis specific for single-stranded deoxyribonucleic acid is absent in spores, appears during germination only after the start of deoxyribonucleic acid synthesis, and is located almost exclusively in the periplasm.

DNA repair in nuclei isolated from HeLa cells.

We have studied the DNA repair synthesis in HeLa cell isolated nuclei in presence of aphidicolin, which selectively inhibits DNA polymerase alpha but not DNA polymerases beta and gamma. The drug strongly depresses the DNA synthesis rate both in vivo and in the subcellular system but seems not to interfere with DNA repair. The enhancement in nucleotide incorporation by isolated nuclei after UV-irradiation is observed only in the presence of ATP.

Properties of the high-molecular-weight deoxyribonuclease of Bacillus subtilis degrading single-stranded DNA.

We have studied the properties of the high-Mr DNAse degrading single-stranded DNA which is present in extracts of Bacillus subtilis. This enzyme is a heterogeneous aggregate of identical subunits with an Mr of 36 000, as measured in dodecylsulfate/polyacrylamide electrophoresis. The aggregate can be disassembled by the presence of Triton X-100, but reforms spontaneously following removal of the detergent. A mild proteolytic treatment of the aggregate causes the irreversible and nearly quantitative conversion into the free subunit. The modified subunit has identical properties (in terms of size, chromatographic adsorption and catalytic activity) as the small DNAse previously described by Ciarrocchi et al. [Eur. J. Biochem. 61, 487 (1976)], i.e. an endonuclease highly specific for single-stranded DNA and producing 5'-P and 3'-OH ends.

Modulation of deoxyribonucleic acid polymerase III level during the life cycle of Bacillus subtilis.

Deoxyribonucleic acid (DNA) polymerase III is not detectable in Bacillus subtilis spores; the enzyme activity appears 20 to 30 min after spore activation and rapidly increases just before the onset of the first round of DNA replication (30 min later); the level of polymerase III further increases and reaches its maximum (on a per-genome basis) when the cells enter the vegetative phase of growth; this level is six- to eightfold higher than the one observed during germination. In the stationary phase, the polymerase III drops to levels comparable to those found in germinating spores at the first round of replication. On the contrary, DNA polymerase I is present at appreciable levels in the dormant spore; it increases during vegetative growth by a factor of three and, during the stationary phase, reaches its maximum level which is sixfold higher than that observed in the spores. The block of protein synthesis during vegetative growth does not cause an appreciable reduction of the two enzymes (in absolute terms), showing that the regulation of their levels is probably not due to a balance between synthesis and breakdown. These results indicate that polymerase III is probably one of the factors controlling the initiation of DNA synthesis during spore germination.

A simplified procedure for the analysis of DNA polymerase III levels in Bacillus subtilis strains.

A simple and reproducible procedure is described which allows the fast and almost quantitative removal of DNA polymerases I and II from DNA polymerase III, in crude extracts of polA+ strains of Bacillus subtilis. The procedure entails streptomycin sulfate and ammonium sulfate fractionations; subsequent analysis of the partially purified preparation by G-200 chromatography, DEAE cellulose chromatography and density gradient sedimentation, shows that the ammonium sulfate fraction contains less than 5% of the total activity as DNA polymerase I and less than 2% as DNA polymerase II. The purification procedure, up to the ammonium sulfate step, was utilized for the analysis of the level of DNA polymerase III in several B. subtilis mutants, with results comparable to those obtained from the corresponding polA- strains following more cumbersome purification procedures. The M.W. of the purified form is of 227.000, somewhat greater than the published values. The early fractions of the purification have revealed the existence of a form with a M.W. of 426.000; the nature of this form, which has been observed in several instances and which is very unstable and short-lived, is under investigation.

On the identity of dnaP and dnaF genes of Bacillus subtilis.

The dnaP strains of Bacillus subtilis are altered in the initiation of DNA replication at high temperature (Riva et al., 1975). Fine mapping of the gene shows that it is located very close to the dnaF gene described by Karamata and Gross (1970) and mapped by Love et al. (1976) in the polC region. The phenotype of both mutants is indistinguishable: the DNA synthesis stops at non permissive temperature after synthesizing an amount of DNA equivalent to the completion of the rounds of replication already initiated; at permissive temperature they are abnormally sensitive to MMS and are reduced in the ability to be transformed. Both mutants are to be considered as belonging to the dnaF locus. The dnaF gene is very close to the polC gene, which specifies the DNA polymerase III of B. subtilis. The DNA polymerase III of the dnaF mutants is not temperature sensitive in vitro, however, the level of this enzyme is lower by a factor of 4 or 5 in the dnaF mutants, at the permissive temperature. Following shift of dnaF cultures to the non permissive temperature, the level of DNA polymerase III activity specifically decreases further by a factor of at least 10 in the mutant, whereas the DNA polymerase I level is unaffected. The possible roles of the dnaF gene in the control of the cellular level of the DNA polymerase III, and the possibility of a regulatory role of DNA polymerase III in the initiation of DNA replication in bacteria are discussed.

A new mutant of Bacillus subtilis altered in the initiation of chromosome replication.

We have isolated a new mutant of Bacillus subtilis temperature sensitive in DNA replication; its properties are those of an initiation mutant. When liquid cultures are shifted to 48 degrees DNA replication is the first macromolecular synthesis that stops, but only after synthesis of the amount of DNA predicted for the completion of one replication round. When spores of the mutant are germinated and shifted to 48 degrees at subsequent times, one round of DNA replication is observed only when the shift occurs between 60 and 100 min; earlier shifts do not allow replication to start, later shifts allow more than one replication. The DNA replicated after a shift to high temperature is enriched in markers close to the terminus. The reinitiation of DNA replication stopped by the high temperature, takes place following a shift to a permissive temperature only if protein synthesis is allowed. Examination of DNA replication following toluene treatment shows that the elongation of DNA chains is not affected at the non-permissive temperature. This mutant is shown by PBS-1 mapping to correspond to a new gene denominated dna P, which is located between the thy A and fur A genes and is distinct from all the mapped dna and rec genes of Bacillus subtilis. The mutation confers to the cells also a deficiency in the ability to be transformed, to be transfected with SPP1 phage DNA, and to survive treatment with methyl-methane sulfonate. These deficiencies, observed at the permissive temperature, are no more temperature dependent than in the parental strain. The ability to perform homologous and heterologous transduction with PBS-1 phage and the sensitivity to ultraviolet radiation or mitomycin C are normal.