Detection of simple mutations and polymorphisms in large genomic regions.

We have developed a novel technology that makes it possible to detect simple nucleotide polymorphisms directly within a sample of total genomic DNA. It allows, in a single Southern blot experiment, the determination of sequence identity of genomic regions with a combined length of hundreds of kilobases. This technology does not require PCR amplification of the target DNA regions, but exploits preparative size-fractionation of restriction-digested genomic DNA and a newly discovered property of the mismatch-specific endonuclease CEL I to cleave heteroduplex DNA with a very high specificity and sensitivity. We have used this technique to detect various simple mutations directly in the genomic DNA of isogenic pairs of recombinant Pseudomonas aeruginosa, Escherichia coli and Salmonella isolates. Also, by using a cosmid DNA library and genomic fractions as hybridization probes, we have compared total genomic DNA of two clinical P.aeruginosa clones isolated from the same patient, but exhibiting divergent phenotypes. The mutation scan correctly detected a GA insertion in the quorum-sensing regulator gene rhlR and, in addition, identified a novel intragenomic polymorphism in rrn operons, indicating very high stability of the bacterial genomes under natural non-mutator conditions.

Purification, cloning, and characterization of the CEL I nuclease.

CEL I, isolated from celery, is the first eukaryotic nuclease known that cleaves DNA with high specificity at sites of base-substitution mismatch and DNA distortion. The enzyme requires Mg(2+) and Zn(2+) for activity, with a pH optimum at neutral pH. We have purified CEL I 33 000-fold to apparent homogeneity. A key improvement is the use of alpha-methyl-mannoside in the purification buffers to overcome the aggregation of glycoproteins with endogenous lectins. The SDS gel electrophoresis band for the homogeneous CEL I, with and without the removal of its carbohydrate moieties, was extracted, renatured, and shown to have mismatch cutting specificity. After determination of the amino acid sequence of 28% of the CEL I polypeptide, we cloned the CEL I cDNA. Potential orthologs are nucleases putatively encoded by the genes BFN1 of Arabidopsis, ZEN1 of Zinnia, and DSA6 of daylily. Homologies of CEL I with S1 and P1 nucleases are much lower. We propose that CEL I exemplifies a new family of neutral pH optimum, magnesium-stimulated, mismatch duplex-recognizing nucleases, within the S1 superfamily.

Incision at nucleotide insertions/deletions and base pair mismatches by the SP nuclease of spinach.

Spinach leaves contain a highly active nuclease called SP. The purified enzyme incises single-stranded DNA, RNA, and double-stranded DNA that has been destabilized by A-T-rich regions and DNA lesions [Strickland et al. (1991) Biochemistry 30, 9749-9756]. This broad range of activity has suggested that SP may be similar to a family of nucleases represented by S1, P1, and the mung bean nuclease. However, unlike these single-stranded nucleases that require acidic pH and low ionic strength conditions, SP has a neutral pH optimum and is active over a wide range of salt concentrations. We have extended these findings and showed that an outstanding substrate for SP is a mismatched DNA duplex. For base-substitution mismatches, SP incises at all mismatches except those containing a guanine residue. SP also cuts at insertion/deletions of one or more nucleotides. Where the extrahelical DNA loop contains one nucleotide, the preference of extrahelical nucleotide is A >> T approximately C but undetectable at G. The inability of SP to cut at guanine residues and the favoring of A-T-rich regions distinguish SP from the CEL I family of neutral pH mismatch endonucleases recently discovered in celery and other plants [Oleykowski et al. (1998) Nucleic Acids Res. 26, 4597-4602]. SP, like CEL I, does not turn over after incision at a mismatched site in vitro. Similar to CEL I, the presence of a DNA polymerase or a DNA ligase allows SP to turn over and stimulate its activity in vitro by about 20-fold. The possibility that the SP nuclease may be a natural variant of the CEL I family of mismatch endonucleases is discussed.

Mutation detection using a novel plant endonuclease.

We have discovered a useful new reagent for mutation detection, a novel nuclease CEL I from celery. It is specific for DNA distortions and mismatches from pH 6 to 9. Incision is on the 3'-side of the mismatch site in one of the two DNA strands in a heteroduplex. CEL I-like nucleases are found in many plants. We report here that a simple method of enzyme mutation detection using CEL I can efficiently identify mutations and polymorphisms. To illustrate the efficacy of this approach, the exons of the BRCA1 gene were amplified by PCR using primers 5'-labeled with fluorescent dyes of two colors. The PCR products were annealed to form heteroduplexes and subjected to CEL I incision. In GeneScan analyses with a PE Applied Biosystems automated DNA sequencer, two independent incision events, one in each strand, produce truncated fragments of two colors that complement each other to confirm the position of the mismatch. CEL I can detect 100% of the sequence variants present, including deletions, insertions and missense alterations. Our results indicate that CEL I mutation detection is a highly sensitive method for detecting both polymorphisms and disease-causing mutations in DNA fragments as long as 1120 bp in length.

Repair of aflatoxin B1 DNA adducts by the UvrABC endonuclease of Escherichia coli.

The repair by UvrABC endonuclease of two major adducts formed by aflatoxin B1 in DNA was found to be similar. Aflatoxin epoxide was used to generate the aflatoxin B1.N7-guanine adduct which can convert to aflatoxin B1-formamidopyrimidine adduct. The reaction of the aflatoxin B1 epoxide with DNA follows pseudo-first order kinetics. The DNA sequence-specific relative reactivity of the epoxide is the same as previously observed for aflatoxin B1 activated by liver microsomes, therefore strongly reinforcing the notion that aflatoxin B1 reacts with DNA through the epoxide intermediate. For the majority of lesion sites, a high affinity protein-DNA complex was formed from the UvrA and the UvrB proteins with similar efficiency to both adducts, and to pyrimidine dimers, and then nicks the DNA when UvrC was added. The two incisions are at the eighth phosphodiester moiety 5' and the sixth phosphodiester moiety 3' of a modified guanine nucleotide. Both incisions appeared to be concerted. For some sites, the DNA sequence can alter the relative incision efficiency up to 15-fold. However, the majority of these AFB1 lesion structures in most DNA sequences are similar with respect to recognition by this nucleotide excision repair enzyme. Therefore the observation that the aflatoxin B1.N7-guanine lesion is removed rapidly, while the aflatoxin B1-formamidopyrimidine lesion persists in the mammalian cell may have other mechanistic explanations.