Mismatch repair deficient human cells: spontaneous and MNNG-induced mutational spectra in the HPRT gene.

We have determined both the spontaneous and N-methyl-N'-nitro-N-nitrosoguanidine (MNNG)-induced mutational spectra in the HPRT gene of human cells (MT1) defective in the mismatch repair gene hMSH6 (GTBP). Eight of nine exons and nine of sixteen intronic flanking sequences were scanned, encompassing >900 bp of the HPRT gene. Mutant hotspots were detected and separated by differences in their melting temperatures using constant denaturant capillary electrophoresis (CDCE) or denaturing gradient gel electrophoresis (DGGE).A key finding of this work is that a high proportion of all HPRT inactivating mutations is represented by a small number of hotspots distributed over the exons and mRNA splice sites. Thirteen spontaneous hotspots and sixteen MNNG-induced hotspots accounted for 55% and 48% of all 6TG(R) point mutations, respectively. MNNG-induced hotspots were predominantly G:C-->A:T transitions. The spontaneous spectrum of cells deficient in hMSH6 contained transversions (A:T-->T:A, G:C-->T:A, A:T-->C:G), transitions (A:T-->G:C), a plus-one insertion, and a minus-one deletion. Curiously, G:C-->A:T transitions, which dominate human germinal and somatic point mutations were absent from the spontaneous hMSH6 spectra.

Molecular analysis of complex human cell populations: mutational spectra of MNNG and ICR-191.

We describe a method to identify and enumerate mutants at the nucleotide level in complex cell populations. Several thousand different mutants were induced at the HPRT locus in human lymphoblastoid cultures by either MNNG, an alkylating agent, or by ICR-191, a substituted acridine. HPRT mutants were selected en masse by resistance to 6-thioguanine. The most frequent mutations (hotspots) in HPRT exon 3 were determined by a combination of denaturing gradient gel electrophoresis and polymerase chain reaction. MNNG predominantly produced GC----AT transitions at nucleotides in a GGGGGG sequence, while ICR-191 produced both +1 frameshifts in the same GGGGGG sequence and +1 frameshifts in a CCC sequence.

Direct measurement of mutational spectra in humans.

By combining high fidelity in vitro DNA amplification and mutant DNA sequence separation by denaturing gradient gel electrophoresis, we are able to directly observe mutational hotspots in human genomic DNA. Our technological development has progressed through the stage of identifying mutant sequences in independently derived, 6-thioguanine-resistant human B cells. We are now analyzing uncloned, complex populations derived from several thousand 6-thioguanine-resistant cells and report preliminary data concerning the mutational spectra of benzo[a]pyrene diol epoxide and ultraviolet light in exon 3 of the hypoxanthine-guanine phosphoribosyltransferase gene. In addition, the approach appears to be general for any gene sequence for which a means to select mutants exists. The more global need to eliminate phenotypic selection is, however, our primary impetus. Our analysis leads us to conclude that no known in vitro DNA polymerase has sufficient fidelity to permit direct observation of unselected mutants. Therefore, an additional change in technology will be necessary to observe nonselected mutant DNA sequences at the low frequencies found in human tissues.

Resolution of a missense mutant in human genomic DNA by denaturing gradient gel electrophoresis and direct sequencing using in vitro DNA amplification: HPRT Munich.

The combination of denaturing gradient gel electrophoresis (DGGE) and in vitro DNA amplification has allowed us to (1) localize a DNA mutation to a given 100-bp region of the human genome and (2) rapidly sequence the DNA without cloning. DGGE showed that a mutation had occurred, but the technique revealed little about the nature or position of that mutation. The region of the genome containing the mutation was amplified by the polymerase chain-reaction technique, providing DNA of sufficient quality and quantity for direct sequencing. Amplification was performed with a 32P end-labeled primer that allowed direct Maxam-Gilbert sequencing of the amplified product without cloning. HPRTMunich was found to contain a single-base-pair substitution, a C-to-A transversion at base-pair position 397. We report the generation of a 169-bp, wild-type DNA probe that encompasses most of exon 3 of the human hypoxanthine guanine phosphoribosyltransferase (HPRT) gene and contains a low-temperature melting domain of approximately 100 bp. HPRTMunich, an HPRT mutant isolated from a patient with gout, has a single amino acid substitution; the corresponding DNA sequence alteration must lie within the low-temperature melting domain of exon 3. We report the separation of HPRTMunich from the wild-type sequence using DGGE. In addition to base-pair substitutions, DGGE is also sensitive to the methylation state of the molecule. The cDNA for HPRT was cloned into a vector and propagated in Escherichia coli dam+ and dam- strains; thus, methylated and unmethylated HPRT cDNA was obtained.(ABSTRACT TRUNCATED AT 250 WORDS)

DNA amplification in vitro using T4 DNA polymerase.

We have evaluated in vitro DNA amplification by polymerase chain reaction using either T4 DNA polymerase or Klenow fragment of Escherichia coli DNA polymerase I. Both polymerases under optimal salt conditions permit efficient amplification of exon 3 of the hypoxanthine guanine phosphoribosyltransferase (HPRT) gene from human genomic DNA and from plasmid containing the HPRT cDNA. DNA sequences amplified from human genomic DNA, using two 20-nucleotide primers flanking the ends of the exon, showed a marked difference between the two polymerases. T4 DNA polymerase yielded only the expected amplified DNA fragment, whereas Klenow fragment produced many lower-molecular-weight bands in addition to the expected DNA fragment. On the basis of the reported fidelity of in vitro DNA synthesis using Klenow fragment and T4 DNA polymerase, it is expected that the latter will create substantially fewer errors during the amplification process. For these reasons, T4 DNA polymerase should be particularly valuable for amplification of sequences present at a very low frequency requiring many cycles of amplification to be detected.