Restriction endonuclease mapping of Co1E2-P9 and Co1E3-CA38 plasmids

Using single and double restriction-endonuclease digestions, 16 and 17 cleavage sites have been mapped for the ColE2-P9 and ColE3-CA38 plasmids, respectively. One or more sites for AvaI, BglI, EcoRI, HincII, PvuI, PvuII, SmaI and XhoI endonucleases were found in both plasmids, two BglII sites were found only in ColE2-P9, and one KpnI site was unique to ColE3-CA38. ColE2-P9 was found to be slightly smaller than ColE3-CA38,4.4 Md compared to 4.6 Md. Eleven restriction sites are common to both plasmids in that they are identically placed relative to each other. These sites define a continuous DNA segment equal to over 60% of each plasmid. The remaining portions of the plasmids, which contain the non-homologous regions identified by Inselburg and Johns (1975) have no restriction sites in common, and differ in size by about 0.2 Md.     

The construction of a versatile plasmid vector that allows direct selection of fragments cloned into six unique sites of the cI gene of coliphage 434

A new plasmid vector, pNSI, is described that allows positive selection for bacterial transformants carrying recombinant plasmids. It is a derivative of pBR327, and it includes a regulatory region from the lambdoid phage 434. The expression of the Tc^R gene of pNS1 is under the control of the o_Rp_R operator-promoter of phage 434, which is regulated by the represser gene c1. The cloning sites of pNSI (StuI, NdeI, HpaI, HindIII, AsuII and EcoRI) are situated within cI; hence insertion of foreign DNA into these sites causes derepressed expression of the Tc^R gene from p_R thus conferring the Tc^R phenotype on the harboring Escherichia coli strain. The use ofpNS1 is facilitated by the presence of another selectable marker, Ap^R its small size, and its known nucleotide sequence; no special host strain is required.     

Localized breakdown in linkage disequilibrium does not always predict sperm crossover hot spots in the human MHC class II region

To investigate the relationship between meiotic crossover hot spots and block-like linkage disequilibrium (LD), we have extended our high-resolution studies of the human MHC class II region to a 90-kb segment upstream of the HLA-DOA gene. LD blocks in this region are not as well defined as in the neighboring 210-kb DNA segment but do show two regions of LD breakdown in which coalescent analysis indicates substantial historical recombination. Sperm crossover analysis of one region revealed a novel localized hot spot similar in intensity and morphology to most other MHC hot spots. Crossovers at this hot spot are not obviously affected by a large insertion/deletion polymorphism near the hot spot. The second region of LD breakdown, within the DPB1 gene, shows an extremely low level of sperm crossover activity and does not contain a sperm crossover hot spot. These results highlight the complexity of LD patterns and the importance of experimentally verifying crossover hot spots.     

‘ATG vectors’ for regulated high-level expression of cloned genes in Escherichia coli

A plasmid cloning vector system has been constructed that allows for the production of large quantities of foreign proteins or fragments thereof, in an unfused state. These vectors provide strong regulated trp-lac fusion promoters and the lacZ ribosome-binding site (RBS) followed by an ATG translation initiation codon at an appropriate distance from the RBS. The ATG codon is located within a unique NcoI restriction site (CCATGG). Digestion with NcoI exposes the ATG for fusion. Gene fragments lacking a prokaryotic RBS and/or ATG start codons can be inserted in several ways. Expression experiments using a truncated cI gene of bacteriophage A or a large portion of the coding region of the Herpes simplex virus type l glycoprotein D gene have been performed. The results of these studies show that the vectors are useful for the high-level expression of prokaryotic and eukaryotic genes in Escherichia coli.     

Relationship between cellular RecA protein concentration and untargeted mutagenesis in Escherichia coli

We measured the production of untargeted mutations in the cI and cII genes of untreated λ phage undergoing a lytic cycle in UV-irradiated bacterial hosts. As previously shown, treatment with 4 μg/ml of rifampicin during post-irradiation incubation inhibited amplification of the RecA protein in these cells. In addition, we observed a decreased mutation rate compared to the untreated, irradiated bacteria. Treatment with 4 μg/ml or 8 μg/ml rifampicin did not prevent the UV induction of the umuDC operon, as judged by assay of β-galactosidase activity in a umuC-lacZ fusion strain. In contrast, the UV-induction of β-galactosidase in the sulA-lacZ fusion strain was decreased by 4 μg/ml rifampicin. The inhibition of untargeted mutagenesis by this drug treatment was also observed in a strain constitutive for SOS functions (lexA (Def)) as well as ina RecA-overproducing plasmid strain, that blocks induction of heat-shock proteins, factor(s) in wild-type recA⁺ cells. An htpR165-carrying strain, that blocks induction of heat-shock proteins, exhibited normal UV-promoted mutagenesis. A correlation was observed between the cellular concentration of RecA protein, increased spontaneously by a temperature shift in a lexA(Ts) strain, and the extent of UV-promoted untargeted mutagenesis. These results suggest a mechanistic role of RecA protein in this process.     

Principal causes of hot spots for cytosine to thymine mutations at sites of cytosine methylation in growing cells. A model, its experimental support and implications.

In Escherichia coli and human cells, many sites of cytosine methylation in DNA are hot spots for C to T mutations. It is generally believed that T.G mismatches created by the hydrolytic deamination of 5-methylcytosines (5meC) are intermediates in the mutagenic pathway. A number of hypotheses have been proposed regarding the source of the mispaired thymine and how the cells deal with the mispairs. We have constructed a genetic reversion assay that utilizes a gene on a mini-F to compare the frequency of occurrence of C to T mutations in different genetic backgrounds in exponentially growing E. coli. The results identify at least two causes for the hot spot at a 5meC: (1) the higher rate of deamination of 5meC compared to C generates more T.G than uracil.G (U.G) mismatches, and (2) inefficient repair of T.G mismatches by the very short-patch (VSP) repair system compared to the repair of U. G mismatches by the uracil-DNA glycosylase (Ung). This combination of increased DNA damage when the cytosines are methylated coupled with the relative inefficiency in the post-replicative repair of T.G mismatches can be quantitatively modeled to explain the occurrence of the hot spot at 5meC. This model has implications for mutational hot and cold spots in all organisms.     

An automated decision-tree approach to predicting protein interaction hot spots

Protein-protein interactions can be altered by mutating one or more "hot spots," the subset of residues that account for most of the interface's binding free energy. The identification of hot spots requires a significant experimental effort, highlighting the practical value of hot spot predictions. We present two knowledge-based models that improve the ability to predict hot spots: K-FADE uses shape specificity features calculated by the Fast Atomic Density Evaluation (FADE) program, and K-CON uses biochemical contact features. The combined K-FADE/CON (KFC) model displays better overall predictive accuracy than computational alanine scanning (Robetta-Ala). In addition, because these methods predict different subsets of known hot spots, a large and significant increase in accuracy is achieved by combining KFC and Robetta-Ala. The KFC analysis is applied to the calmodulin (CaM)/smooth muscle myosin light chain kinase (smMLCK) interface, and to the bone morphogenetic protein-2 (BMP-2)/BMP receptor-type I (BMPR-IA) interface. The results indicate a strong correlation between KFC hot spot predictions and mutations that significantly reduce the binding affinity of the interface.     

Spectrum of spontaneous frameshift mutations. Sequences of bacteriophage T4 rII gene frameshifts

The DNA sequences of 185 independent spontaneous frameshift mutations in the rIIB gene of bacteriophage T4 are described. Approximately half of the frameshifts, including those at hot spot sites, are fully consistent with classical proposals that frameshift mutations are produced by a mechanism involving the misaligned pairing of repeated DNA sequences. However, the remaining frameshifts are inconsistent with this model. Correlations between the positions of two base-pair frameshifts and the bases of DNA hairpins suggest that local DNA topology might influence frameshift mutation. Warm spots for larger deletions share the property of having endpoints adjacent to DNA sequences whose complementarity to sequences a few base-pairs away suggest that non-classical DNA misalignments may participate in deletion mutation. A model for duplication mutation as a consequence of strand displacement synthesis is discussed. In all, 15 frameshifts were complex combinations of frameshifts and base substitutions. Three of these were identical, and have extended homology to a sequence 256 base-pairs away that is likely to participate in the mutational event; the remainder are unique combinations of frameshifts and transversions. The frequency and diversity of complex mutants suggest a challenge to the assumption that the molecular evolution of DNA must depend primarily upon the accumulation of single nucleotide changes.     

Peroxyl radical mediated oxidative DNA base damage: implications for lipid peroxidation induced mutagenesis

Endogenous DNA damage induced by lipid peroxidation is believed to play a critical role in carcinogenesis. Lipid peroxidation generates free radical intermediates (primarily peroxyl radicals, ROO(*)) and electrophilic aldehydes as the principal genotoxicants. Although detailed information is available on the role of aldehyde base adducts in mutagenesis and carcinogenesis, the contribution of peroxyl radical mediated DNA base damage is less well understood. In the present study we have mapped oxidative base damage induced by peroxyl radicals in the supF tRNA gene and correlated this information with peroxidation-induced mutations in several human fibroblast cell lines. Nearly identical patterns of oxidative base damage were obtained from reaction of DNA with either peroxidizing arachidonic acid (20:4omega6) or peroxyl radicals generated by thermolysis of ABIP in the presence of oxygen. Oxidative base damage primarily occurred at G and C. Transversions at GC base pairs in the supF gene were the major base substitution detected in all cell lines. Peroxyl radical induced tandem mutations were also observed. Many mutation hot spots coincided with sites of mapped oxidative lesions, although in some cases hot spots occurred adjacent to the damaged base. Evidence is presented for the involvement of 8-oxodG in the oxidation of DNA by ROO(*). These results are used to interpret some key features of previously published mutation spectra induced by lipid peroxidation in human cells.     

Site-specific tamoxifen-DNA adduct formation: lack of correlation with mutational ability in Escherichia coli.

We have mapped sites of tamoxifen adduct formation, in the lacI gene using the polymerase STOP assay, following reaction in vitro with alpha-acetoxytamoxifen and horseradish peroxidase (HRP)/H(2)O(2) activated 4-hydroxytamoxifen. For both compounds, most adduct formation occurred on guanines. However, one adenine, within a run of guanines, generated a strong polymerase STOP site with activated 4-hydroxytamoxifen, and a weaker STOP site with alpha-acetoxytamoxifen at the same location. In Escherichia coli the lac I gene reacted with 4-hydroxytamoxifen was more likely to be mutated (2 orders of magnitude) than when reacted with alpha-acetoxytamoxifen, despite the greater DNA adduct formation by alpha-acetoxytamoxifen. This correlates with the greater predicted ability of activated 4-hydroxytamoxifen adducts to disrupt DNA structure than alpha-acetoxytamoxifen adducts. For lac I reacted with activated 4-hydroxytamoxifen, a hot spot of base mutation was located in the region of the only adenosine adduct. No mutational hot spots were observed with alpha-acetoxytamoxifen. Our data clearly shows a lack of correlation between gross adduct number, as assayed by (32)P-postlabeling and mutagenic potential. These data indicate the importance of minor adduct formation in mutagenic potential and further that conclusions regarding the mutagenicity of a chemical may not be reliably derived from the gross determination of adduct formation.     

Mutations in the Trp53 gene of UV-irradiated Xpc mutant mice suggest a novel Xpc-dependent DNA repair process

Mutational hot spots in the human p53 gene are well established in tumors in the human population and are frequently negative prognosticators of the clinical outcome. We previously developed a mouse model of skin cancer with mutations in the xeroderma pigmentosum group C gene (Xpc). UVB radiation-induced skin cancer is significantly enhanced in these mice when they also carry a mutation in one copy of the Trp53 gene (Xpc-/-Trp53+/-). Skin tumors in these mice often contain inactivating mutations in the remaining Trp53 allele and we have previously reported a novel mutational hot spot at a non-dipyrimidine site (ACG) in codon 122 of the Trp53 gene in the tumors. Here we show that this mutation is not a hot spot in Xpa or Csa mutant mice. Furthermore, the mutation in codon T122 can be identified in mouse skin DNA from (Xpc-/-Trp53+/-) mice as early as 2 weeks after exposure to UVB radiation, well before histological evidence of dysplastic or neoplastic changes. Since this mutational hot spot is not at a dipyrimidine site and is apparently Xpc-specific, we suggest that some form of non-dipyrimidine base damage is normally repaired in a manner that is distinct from conventional nucleotide excision repair, but that requires XPC protein.     

Hot Spots of Recombination in Fission Yeast: Inactivation of the M26 Hot Spot by Deletion of the Ade6 Promoter and the Novel Hotspot Ura4-Aim

The M26 mutation in the ade6 gene of Schizosaccharomyces pombe creates a hot spot of meiotic recombination. A single base substitution, the M26 mutation is situated within the open reading frame, near the 5' end. It has previously been shown that the heptanucleotide sequence 5' ATGACGT 3', which includes the M26 mutation, is required for hot spot activity. The 510-bp ade6-delXB deletion encompasses the promoter and the first 23 bp of the open reading frame, ending 112 bp upstream of M26. Deletion of the promoter in cis to M26 abolishes hot spot activity, while deletion in trans to M26 has no effect. Homozygous deletion of the promoter also eliminates M26 hot spot activity, indicating that the heterology created through deletion of the promoter per se is not responsible for the loss of hot spot activity. Thus, DNA sequences other than the heptanucleotide 5' ATGACGT 3', which must be located at the 5' end of the ade6 gene, appear to be required for hot spot activity. While the M26 hotspot stimulates crossovers associated with M26 conversion, it does not affect the crossover frequency in the intervals adjacent to ade6. The flanking marker ura4-aim, a heterology created by insertion of the ura4(+) gene upstream of ade6, turned out to be a hot spot itself. It shows disparity of conversion with preferential loss of the insertion. The frequency of conversion at ura4-aim is reduced when the M26 hot spot is active 15 kb away, indicating competition for recombination factors by hot spots in close proximity.     

Binding of 9-aminoacridine to bulged-base DNA oligomers from a frame-shift hot spot

Complexes of 9-aminoacridine and two derivatives with oligomers based on the sequence of a hot spot for frame-shift mutations, 5'dGATGGGGCAG, are investigated by proton NMR and equilibrium dialysis. Competition dialysis experiments show that the drug binds bulge-containing oligomers more strongly than regular duplexes of similar sequence and length, with one apparent strong site. A duplex containing an extra cytidine in a run of C's has the highest affinity for 9-aminoacridine among the sequences tested. An oligomer containing five consecutive G.C pairs shows cooperative drug binding, indicating that G tracts of this length may have an altered helical structure. Complexes of a regular 8-mer and a 9-mer containing a bulged guanosine are examined in detail by two-dimensional NMR techniques. 9-Aminoacridine preferentially binds at TpG sites in the 8-mer but binds primarily at the bulged guanosine in the G-bulge 9-mer. Drug-DNA NOE's in the 8-mer complex are compared with the crystal structure of 9-aminoacridine and 5-iodo-CpG [Sakore et al. (1979) J. Mol. Biol. 135, 763-785]. The NMR data suggest that the drug intercalates across the base pairs of both strands with the amino group projecting into the minor groove.     

Conversion of the FokI endonuclease to a universal restriction enzyme: cleavage of phage M13mp7 DNA at predetermined sites

Endonuclease FokI belongs to class IIS of restriction enzymes, for which the DNA cut points lie outside the enzyme-recognition sites. This permitted conferring new cleavage specificities by combining FokI with tailored oligodeoxynucleotide adapters. Such adapters carry a single-stranded (ss) target-recognition domain, complementary to the selected ss target DNA, and a double-stranded (ds) enzyme-recognition site. Neither enzyme nor adapter alone has endonucleolytic activity toward phage M13mp7 ss DNA, whereas the enzymeadapter complex cleaves this ss target DNA at the particular sites foreordained by the sequence of the ss domain of the adapter. Two kinds of adapters (32 and 34 nucleotides long), with opposing orientations of the asymmetric FokI recognition site, were constructed and shown to direct specific cleavage under a variety of conditions. In addition to FokI, other class IIS enzymes, HphI, MboII and BbvI, which alone do not cleave ss DNA, are suitable for construction of tailored enzyme-adapter complexes with predictable cleavage specificities.

This report provides a preliminary experimental confirmation for the proposal of Szybalski [Gene 40 (1985) 169-173] for the design of adapter-enzyme complexes with novel and predictable specificities. Theoretically, using this approach any sequence could be precisely cleaved at a predetermined point.     

Geometrically centered region: A “wet” model of protein binding hot spots not excluding water molecules

A protein interface can be as “wet” as a protein surface in terms of the number of immobilized water molecules. This important water information has not been explicitly taken by computational methods to model and identify protein binding hot spots, overlooking the water role in forming interface hydrogen bonds and in filing cavities. Hot spot residues are usually clustered at the core of the protein binding interfaces. However, traditional machine learning methods often identify the hot spot residues individually, breaking the cooperativity of the energetic contribution. Our idea in this work is to explore the role of immobilized water and meanwhile to capture two essential properties of hot spots: the compactness in contact and the far distance from bulk solvent. Our model is named geometrically centered region (GCR). The detection of GCRs is based on novel tripartite graphs, and atom burial levels which are a concept more intuitive than SASA. Applying to a data set containing 355 mutations, we achieved an F measure of 0.6414 when ΔΔG ≥ 1.0 kcal/mol was used to define hot spots. This performance is better than Robetta, a benchmark method in the field. We found that all but only one of the GCRs contain water to a certain degree, and most of the outstanding hot spot residues have water‐mediated contacts. If the water is excluded, the burial level values are poorly related to the ΔΔG, and the model loses its performance remarkably. We also presented a definition for the O‐ring of a GCR as the set of immediate neighbors of the residues in the GCR. Comparative analysis between the O‐rings and GCRs reveals that the newly defined O‐ring is indeed energetically less important than the GCR hot spot, confirming a long‐standing hypothesis. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

Construction of frameshift mutation hot spots within the tetracycline resistance gene of pBR322

The chemical carcinogen, N-2-acetylaminofluorene (AAF) when bound covalently to DNA induces a majority (greater than 90%) of frameshift mutations. The mutations occur with high frequencies at defined sequences (i.e. mutation hot spots). Two classes of mutation hot spots were found: at repetitive sequences and at specific non-repetitive sequences. Mutations at the repetitive sequences depend upon a functional umuC gene whereas mutations at specific non-repetitive sequences are umuC-independent. The first discovered sequence of this class is the NarI restriction enzyme recognition sequence (5'GGCGCC3'). In an attempt to define a family of such sequences we constructed a related sequence 5'GCGCGC3' within the tetracycline resistance gene of pBR322. This sequence was also found to be an--AAF induced--2 frameshift mutation hot spot in both wild type and umuC strains.     

Natural meiotic recombination hot spots in the Schizosaccharomyces pombe genome successfully predicted from the simple sequence motif M26

The M26 hot spot of meiotic recombination in Schizosaccharomyces pombe is the eukaryotic hot spot most thoroughly investigated at the nucleotide level. The minimum sequence required for M26 activity was previously determined to be 5'-ATGACGT-3'. Originally identified by a mutant allele, ade6-M26, the M26 heptamer sequence occurs in the wild-type S. pombe genome approximately 300 times, but it has been unclear whether any of these are active hot spots. Recently, we showed that the M26 heptamer forms part of a larger consensus sequence, which is significantly more active than the heptamer alone. We used this expanded sequence as a guide to identify a smaller number of sites most likely to be active hot spots. Ten of the 15 sites tested showed meiotic DNA breaks, a hallmark of recombination hot spots, within 1 kb of the M26 sequence. Among those 10 sites, one occurred within a gene, cds1(+), and hot spot activity of this site was confirmed genetically. These results are, to our knowledge, the first demonstration in any organism of a simple, defined nucleotide sequence accurately predicting the locations of natural meiotic recombination hot spots. M26 may be the first example among a diverse group of simple sequences that determine the distribution, and hence predictability, of meiotic recombination hot spots in eukaryotic genomes.     

Exploration of pairing constraints identifies a 9 base-pair core within box C/D snoRNA-rRNA duplexes

2'-O-ribose methylation of eukaryotic ribosomal RNAs is guided by RNA duplexes consisting of rRNA and box C/D small nucleolar (sno)RNA sequences, the methylated sites invariably mapping five positions apart from the D box. Here we have analyzed the RNA duplex pairing constraints by investigating the features of 415 duplexes from the fungus, plant and animal kingdoms, and the evolution of those duplexes within the 124 sets they group into. The D-box upstream 1st and >or=15th positions consist of Watson-Crick base-pairs, G:U base-pairs and mismatched bases with ratios close to random assortments; these positions display single base differences in >60% of the RNA duplex sets. The D-box upstream 2nd to 11th positions have >90% Watson-Crick base-pairs; they display single base mutations with a U-shaped distribution of lower values of 0% and 1.6% at the methylated site 5th and 4th positions, and double compensatory mutations leading to new Watson-Crick base-pairs with an inverted U-shaped distribution of higher values at the 8th to 11th positions. Half of the single mutations at the 3rd to 11th positions resulted in G:U base-pairing, mainly through A-->G mutations in the rRNA strands and C-->T mutations in the snoRNA strands. Double compensatory mutations at the 3rd to 11th positions are extremely frequent, representing 36% of all mutations; they frequently arose from an A-->G mutation in the rRNA strands followed by a T-->C mutation in the snoRNA strands. Differences in the mutational pathways through which the rRNA and snoRNA strand evolved must be related to differences in the rRNA and snoRNA copy number and gene organization. Altogether these data identify the D-box upstream 3rd to 11th positions as box C/D snoRNA-rRNA duplex cores. The impact of the pairing constraints on the evolution of the 9 base-pair RNA duplex cores is discussed.