Contritution of correction to genetic recombination in T4 phage measured by the effect of map contraction

Marker-dependence of the fine structure map contraction in T4 phage is studied in two-factor crosses between rIIB mutants separated by indicator distances. The genetic intervals, which were short as compared with mean length of the heteroduplex region in hybrid DNA molecules but which exceeded the length of the DNA strand involved in a single correction event, were selected as indicator ones. On the basis of a deviation of measured frequencies from additivity (map contraction) the marker-specific frequencies of wild type recombinants arising as a result of correction to the wild type (kappa (- leads to +)) were calculated. For the most of the marker studied both of the base substitution and frame shift type the frequencies kappa (- leads to +) have the values below 2.10(-4). In the case of three most highly corrected frame shift markers with kappa (- leads to +) being 14.10(-4)--17.10(-4), about ten percent of all mismatched regions are corrected to the wild type.     

The interaction of p53 with 3'-terminal mismatched DNA

The diversity of p53 functions involves its interaction with sequence-specific, non-sequence-specific and various damaged sites in DNA. The preferential excision of misincorporated over correct nucleotides by the 3′→5′ exonuclease activity of p53 provides a molecular basis for p53 involvement in the correction of the DNA replication errors. However, p53 exhibits variations in its comparative efficiency to excise different 3'-terminal mismatched nucleotides. To determine the importance of the binding capacity of the protein to various 3'-terminal damaged sites, we have examined the interaction of p53 with linear dsDNAs containing various 3'-terminal mismatches, employing a gel retardation assay. The data demonstrate the intrinsic 3'-terminal mismatched DNA binding capacity of p53. Since p53 binds directly to various 3'-terminal purine:pyrimidine and purine:purine mispairs to an equal extent, p53 can be considered as a general 3'-mismatched DNA binding protein. Apparently, 3'-terminal mismatched bases are structural element to which p53 can bind, that extends the spectrum of damage sites to which p53 may respond. The formation of the p53-mismatched DNA complex is independent of the sequence context. Thus, the dissimilarities in mispair excision efficiency are probably due to an inherent property of the p53 in excision of 3'-mismatched nucleotides by a bound protein. The results establish a framework for understanding the mechanism of cooperative interaction between p53 and exonuclease-deficient DNA polymerase (e.g. HIV-1 RT). Within the context of error-correction events, p53 by recognition and excision of 3'-mismatched nucleotides from DNA, may be involved in DNA repair, thus increasing the accuracy of DNA synthesis by DNA polymerases.     

A general method for identifying correct solutions in the quantitative analysis of gene conversion data

Past attempts to obtain values for meiotic parameters relating to hybrid DNA formation and the correction of mismatched bases in hybrid DNA have not given unique solutions unless various simplifying assumptions were made. A method is given for identifying correct sets of solutions after calculating the frequency of hybrid DNA formation at a heterozygous site and using the fact that closely linked sites within a locus have very similar hybrid DNA formation frequencies. The method is illustrated with simulated data and Sordaria fimicola data; it can also show up incorrect assumptions in analysis. A method is suggested for assessing the importance of double-strand gaps in producing conversions.     

Properties of the 3' to 5' exonuclease associated with calf DNA polymerase delta

The 3' to 5' exonuclease of calf thymus DNA polymerase delta has properties expected of a proofreading nuclease. It digests either single-stranded DNA or the single-stranded nucleotides of a mismatched primer on a DNA template by a nonprocessive mechanism. The distribution of oligonucleotide products suggests that a significant portion of the enzyme dissociates after the removal of one nucleotide. This mechanism is expected if the substrate in vivo is an incorrect nucleotide added by the polymerase. Digestion of single-stranded DNA does not proceed to completion, producing final products six to seven nucleotides long. Digestion of a long mismatched terminus accelerates when the mismatched region is reduced to less than six nucleotides. At the point of complementation, the digestion rate is greatly reduced. These results suggest that short mismatched regions are a preferred substrate. The use of a mismatched primer-template analogue, lacking the template single strand, greatly lowers digestion efficiency at the single-stranded 3'-terminus, suggesting that the template strand is important for substrate recognition. When oligonucleotides were examined for effectiveness as exonuclease inhibitors, (dG)8 was found to be the most potent inhibitor of single-stranded DNA digestion. (dG)8 was less effective at inhibiting digestion of mismatched primer termini, again suggesting that this DNA is a preferred substrate. Overall, these results indicate that the exonuclease of DNA polymerase delta efficiently removes short mismatched DNA, a structure formed from misincorporation during DNA synthesis.     

Sequence analysis of a PM2-DNA anti-Z-IgG-binding region

An anti-Z-antibody-binding region between PM2-DNA map units 0.05 and 0.18, containing approx. 25% of the bound PM2 antibody molecules (1,2) has been sequenced. Analysis of this PM2 DNA sequence from map units 0.00 to 0.175 demonstrates that alternating purine/pyrimidine tracts capable of adopting the left-handed conformation are present within this antibody-binding region. Longer (GC)n-rich tracts are clustered together and comprise seven alternating purine/pyrimidine-rich areas (48%–84%) ranging from 19 to 142 nucleotides in length. The DNA located between these alternating purine/pyrimidine-rich areas exhibit a low level (0%–19%) of this sequence arrangement. There is a very strong correlation between the alternating purine/pyrimidine-rich areas and the anti-Z-DNA-IgG-binding sites. Nucleotides 1461–1583 of the PM2-DNA genome encode the bacteriophage capsid protein IV. One of the PM2 left-handed sites is located within this protein-coding sequence; a B-to-Z transition within this site may be involved in protein-IV gene regulation in vivo.     

Effect of base-pair stability of nearest-neighbor nucleotides on the fidelity of deoxyribonucleic acid synthesis

The influence of the stability of base pairs formed by nearest-neighbor nucleotides on misincorporation frequency has been studied with the large fragment of DNA polymerase I, the alternating DNA copolymers, poly(dI-dC) and poly-(dG-dC), as template-primers, and dGTP, dITP, and dCTP as substrates. We have utilized the difference in thermodynamic stability between the doubly H-bonded I X C base pair and triply H-bonded G X C base pair to examine the effects of base-pair stability of both the "preceding" and the "following" nucleotides on the frequency of insertion of a mismatched nucleotide, as well as on its stable incorporation into polynucleotide. The present studies demonstrate that the stability of the base pairs formed by nearest-neighbor nucleotides affects the frequency of incorporation of noncomplementary nucleotides. Misincorporation frequency is increased when the nearest-neighbor nucleotides form more stable base pairs with the corresponding nucleotides in the template and is decreased when they form less stable base pairs. The stability of the base pair formed by a nucleotide either preceding (5' to) or following (3' to) a misincorporated nucleotide influences misincorporation frequency, but by different mechanisms. The stability of base pairs formed by preceding nucleotides affects the rate of insertion of mismatched nucleotide but does not protect the mismatched nucleotide from removal by the 3' to 5' exonuclease activity. In contrast, the stability of a base pair formed by a following nucleotide determines whether a misincorporated nucleotide is extended or excised by affecting the ability of the enzyme to edit errors of incorporation.     

Gene conversion in Escherichia coli: the recF pathway for resolution of heteroduplex DNA.

The independent repair of mismatched nucleotides present in heteroduplex DNA has been used to explain gene conversion and map expansion after general genetic recombination. We have constructed and purified heteroduplex plasmid DNAs that contain heteroallelic 10-base-pair insertion-deletion mismatches. These DNA substrates are similar in structure to the heteroduplex DNA intermediates that have been proposed to be produced during the genetic recombination of plasmids. These DNA substrates were transformed into wild-type and mutant Escherichia coli strains, and the fate of the heteroduplex DNA was determined by both restriction mapping and genetic tests. Independent repair events that yielded a wild-type Tetr gene were observed at a frequency of approximately 1% in both wild-type and recB recC sbcB mutant E. coli strains. The independent repair of small insertion-deletion-type mismatches separated by 1,243 base pairs was found to be reduced by recF, recJ, and ssb single mutations in an otherwise wild-type genetic background and reduced by recF, recJ, and recO mutations in a recB recC sbcB genetic background (the ssb mutation was not tested in the latter background). Independent repair of small insertion-deletion-type mismatched nucleotides that were as close as 312 nucleotides apart was observed. There was no apparent bias in favor of the insertion or deletion of mutant sequences.     

A novel minisatellite repeat expansion identified at FRA16B in a Japanese carrier

Previously, the allelic expansion of a 33-bp AT-rich minisatellite repeat has been reported to cause FRA16B, a distamycin A-inducible fragile site. Here, we identified a novel 35-bp minisatellite repeat at FRA16B in a Japanese carrier. The nucleotide sequence of the 35-bp minisatellite was highly AT-rich and nearly identical to the 33-bp one but with insertion of two nucleotides, thymine and adenine. The copy number of the AT-rich minisatellite was 21 in total in the carrier, while only a few copies of the 33-bp minisatellite were present in a non-carrier Japanese subject. These results suggest that the molecular mechanism involved in the allelic expansion of the minisatellite repeat in FRA16B recognizes both minisatellites, the 33-bp one and the 35-bp one, as an amplicon. These observations were different from the ones at folate-sensitive fragile sites, where the CCG triplet repeat was commonly involved in the allelic expansion. Although a slight reduction in AT content (95% > 90%) in the region of minisatellite expansion in the carrier subject was observed, both AT-content and length of the highly AT-rich region seem to play important roles in the cytogenetic expression of the distamycin A-inducible fragile site. In another normal subject, without fragile site expression, allelic expansion involving the 33-bp minisatellite was observed, and the length of the AT-rich DNA region was increased up to approximately 1000 bp. Since the length of the AT-rich minisatellite region was increased up to approximately 1,100-bp in the carrier subject, the threshold length for the cytogenetic expression of the AT-rich DNA region may be between about 1,000-bp and 1,100-bp.     

Mapping of restriction sites in the argF gene of Escherichia coli by partial endonuclease digestion of end-labeled DNA.

A detailed physical map depicting the cleavage sites generated by ten different restriction endonucleases was prepared for the argF region of the Escherichia coli K-12 genome carried on a 1650 base pair fragment capable of directing the in vitro synthesis of ornithine transcarbamylase (OTCase; ec 2.1.3.3) under the control of arginine holorepressor. The method employed was originally developed by Smith and Birnstiel (1976), and involved the electrophoretic sizing of partial endonuclease digestion products of DNA radiolabeled at one end. This novel technique proved to be rapid, simple, amenable to the simultaneous mapping of numerous cleavage sites, and provided the essential information for determining the map order of restriction fragments. A facile method which involved magnesium phosphate as the DNA-binding agent was presented for the isolation of DNA fragments. The discovery of a 117 base pair leader sequence in the argF gene is also discussed.     

Studies on the biochemical basis of spontaneous mutation. III. Rate model for DNA polymerase-effected nucleotide misincorporation

We propose a model to investigate the relation between insertion and excision activities of polymerases involved in DNA synthesis, and the frequency of errors resulting from substituting either mismatched bases or base analogues into a DNA molecule. An analytical equation is derived which expresses the error frequency as a function of nucleotide insertion and removal rates. For the general case, given arbitrary rates of insertion and removal, and allowing the enzyme to peel back by excising previously incorporated nucleotides, we have developed a computer simulation for the synthesis of a DNA molecule. In the special case, where insertion and removal frequencies are within the biologically interesting range for spontaneous mutations, the effect of “peelback” on error correction can be obtained analytically. Our results suggest that the magnitude of the removal frequency (3′-exonuclease activity) is the parameter that exerts the greatest influence on error correction capability; the frequency of errors is less sensitive to either the specificity for removal of mismatched relative to correctly matched bases, or to peelback.     

Influence of DNA structure on DNA polymerase beta active site function: extension of mutagenic DNA intermediates

In the ternary substrate complex of DNA polymerase (pol) beta, the nascent base pair (templating and incoming nucleotides) is sandwiched between the duplex DNA terminus and polymerase. To probe molecular interactions in the dNTP-binding pocket, we analyzed the kinetic behavior of wild-type pol beta on modified DNA substrates that alter the structure of the DNA terminus and represent mutagenic intermediates. The DNA substrates were modified to 1) alter the sequence of the duplex terminus (matched and mismatched), 2) introduce abasic sites near the nascent base pair, and 3) insert extra bases in the primer or template strands to mimic frameshift intermediates. The results indicate that the nucleotide insertion efficiency (k(cat)/K(m), dGTP-dC) is highly dependent on the sequence identity of the matched (i.e. Watson-Crick base pair) DNA terminus (template/primer, G/C approximately A/T > T/A approximately C/G). Mismatches at the primer terminus strongly diminish correct nucleotide insertion efficiency but do not affect DNA binding affinity. Transition intermediates are generally extended more easily than transversions. Most mismatched primer termini decrease the rate of insertion and binding affinity of the incoming nucleotide. In contrast, the loss of catalytic efficiency with homopurine mismatches at the duplex DNA terminus is entirely due to the inability to insert the incoming nucleotide, since K(d)((dGTP)) is not affected. Abasic sites and extra nucleotides in and around the duplex terminus decrease catalytic efficiency and are more detrimental to the nascent base pair binding pocket when situated in the primer strand than the equivalent position in the template strand.     

Multiple mRNAs are generated from the chicken lysozyme gene

We have determined the DNA sequence of a 770 by Pst I fragment containing 450 nucleotides of the 5′ flanking region of the chicken lysozyme gene. S1-nuclease mapping was performed to localize the 5′ end of nuclear RNA containing lysozyme-specific sequences and of the mRNA. We present evidence that the 5′ noncoding region of the chicken lysozyme mRNA is heterogeneous in length. The 5′ termini of the different mRNAs map 29, 31 and 53 nucleotides upstream from their common initiation codon. The 5′ ends of lysozyme-specific nuclear RNAs map at positions similar to that of the mRNA. AT-rich regions and sequences similar to the E. coli RNA polymerase recognition sequence are found around 30 and 70 nucleotides upstream from each of these 5′ termini. The AT-rich regions differ, however, from the canonical Goldberg-Hogness box in that they do not contain the extremely conserved TATA sequence motif. Sequence comparison at the 5′ end of the lysozyme, conalbumin and ovalbumin genes reveals only one region of partial homology, 140 nucleotides upstream from the mRNA start sites.     

DNA合成的忠实性机制

DNA的忠实性合成对于基因组稳定和物种延续至关重要,否则可能会产生严重的后果。DNA合成具有极高的忠实性,这主要基于3个步骤:(1)基于氢键、碱基对构象或其他因素的核苷酸选择;(2)基于3′→5′外切酶活性的校对,方式有顺式校对和反式校对,可以去除错误掺入的核苷酸;(3)基于错配修复、切除修复、同源重组修复和跨损伤DNA合成的修复过程,可以纠正逃过校对的错误核苷酸。由于DNA聚合酶不仅可以作为抗病毒或抗癌药物的靶标,而且其忠实性还与抗药性或药物副作用有关,所以深入研究DNA合成的忠实性具有非常重要的意义。文章主要论述了DNA合成的忠实性机制,并对DNA聚合酶的应用前景做了展望。     

A nonuniform distribution of excision repair synthesis in nucleosome core DNA

We have investigated the distribution in nucleosome core DNA of nucleotides incorporated by excision repair synthesis occurring immediately after UV irradiation in human cells. We show that the differences previously observed for whole nuclei between the DNase I digestion profiles of repaired DNA (following its refolding into a nucleosome structure) and bulk DNA are obtained for isolated nucleosome core particles. Analysis of the differences obtained indicates that they could reflect a significant difference in the level of repair-incorporated nucleotides at different sites within the core DNA region. To test this possibility directly, we have used exonuclease III digestion of very homogeneous sized core particle DNA to "map" the distribution of repair synthesis in these regions. Our results indicate that in a significant fraction of the nucleosomes the 5' and 3' ends of the core DNA are markedly enhanced in repair-incorporated nucleotides relative to the central region of the core particle. A best fit analysis indicates that a good approximation of the data is obtained for a distribution where the core DNA is uniformly labeled from the 5' end to position 62 and from position 114 to the 3' end, with the 52-base central region being devoid of repair-incorporated nucleotides. This distribution accounts for all of the quantitative differences observed previously between repaired DNA and bulk DNA following the rapid phase of nucleosome rearrangement when it is assumed that linker DNA and the core DNA ends are repaired with equal efficiency and the nucleosome structure of newly repaired DNA is identical with that of bulk chromatin. Furthermore, the 52-base central region that is devoid of repair synthesis contains the lowest frequency cutting sites for DNase I in vitro, as well as the only "internal" locations where two (rather than one) histones interact with a 10-base segment of each DNA strand.     

Evidence for cooperativity between E2 binding sites in E2 trans-regulation of bovine papillomavirus type 1.

The long control region of bovine papillomavirus type 1 (BPV-1) can function in an orientation- and position-independent manner as an E2-dependent enhancer. Dissection of the long control region has revealed two E2-responsive elements, E2RE1 and E2RE2, which map, respectively, between nucleotides 7611 and 7806 and between nucleotides 7200 and 7386 of the BPV-1 genome. In this study, we have carried out a detailed analysis of E2RE1, which has previously been shown to be involved in the regulation of the BPV-1 promoters P89 and P7940. One characteristic of E2RE1 is the presence of a pair of ACCN6GGT motifs (E2 binding sites) at each end of the element. To determine the contribution of these sites, as well as other sequences within E2RE1, to enhancer function, specific mutations and deletions were generated by oligonucleotide reconstruction. The functional analysis of these mutations confirmed that a pair of E2 binding sites was essential for E2-dependent enhancer activity but also indicated that cooperativity between the motifs at each end of E2RE1 creates a highly responsive element. Isolated ACCN6GGT motif pairs could also act as E2-dependent enhancers but at a significantly reduced level in comparison to the intact element. The sequences between the E2 binding sites in E2RE1 were not required for enhancer function and could actually block the enhancer activity of an isolated pair of E2 binding sites when positioned between the binding sites and the enhancer-deleted simian virus 40 early promoter.     

Nucleotide sequence of the haptoglobin and haptoglobin-related gene pair. The haptoglobin-related gene contains a retrovirus-like element

Thirty-three kilobase pairs (kb) of human DNA containing the haptoglobin (Hp) and haptoglobin-related (Hpr) gene pair were cloned, and the nucleotide sequence of 21-kb DNA was determined. The two genes are closely linked, with Hpr being 2.2 kb downstream of Hp. Six hundred nucleotides of DNA occur between the two genes that are not found either 5' to the Hp gene or 3' to the Hpr gene. After the duplication event, the first intron of the Hpr gene acquired a 9-kb insert consisting mainly of a retrovirus-like element with a potential primer-binding site homologous to a mouse isoleucine tRNA. The element forms a repeated family in the human genome that I name RTVL-I (retrovirus-like element-isoleucine). In the coding region of the Hpr gene, there are no frameshift or nonsense mutations and its exon-intron splicing sites, 5' flanking and 3' flanking sequences do not show any obvious defects. There are 28 amino acid differences between the decoded amino acid sequences of the Hpr and Hp genes. Sixteen of these differences occur in the hpr beta chain, and all appear to be located on the surface of the molecule in places not thought to be involved in the hemoglobin binding function of haptoglobin. The structure of the Hpr gene suggests that the gene may be expressed and give rise to a functional product.     

Efficient isothermal expansion of human telomeric and minisatellite repeats by Thermococcus litoralis DNA polymerase

Repeating DNA sequences, such as telomeres, centromeres, and micro- and mini-satellites, comprise 50% of the genome and play important roles in regulatory and pathogenic mechanisms. In order to study structures and functions of such repeating sequences, it is important to have simple and efficient methods for making them in vitro. Here, we describe the efficient and convenient expansion of repetitive telomeric and minisatellite DNA sequences starting from small synthetic templates to final product lengths of several hundreds to thousands of nucleotides by the thermostable DNA polymerase from Thermococcus litoralis (Vent DNA polymerase). This enzyme was so far unknown to catalyze repeat expansion. Either single-stranded or double-stranded DNAs could be produced, depending on nucleotides present. Compared to earlier results obtained with other enzymes, the expansion reaction is highly efficient both in its yield and product length, and proceeds without thermal cycling. Moreover, the products are characterized by a narrow length distribution.