DNA fragments differing by single base-pair substitutions are separated in denaturing gradient gels: correspondence with melting theory

Constant denaturant gel electrophoresis as a rapid screening technique for p53 mutations

At present, mutation of the p53 gene appears to be the most common genetic alteration found in human cancers. These mutations can occur within many different regions of the gene. We have developed a modification of denaturing gradient gel electrophoresis termed "constant denaturant gel electrophoresis" (CDGE), which provides a rapid and sensitive method to screen the four conserved regions within the p53 gene where the majority of p53 mutations have been reported. The sensitivity of CDGE was first tested with known p53 mutations in all four conserved regions. The CDGE technique was then used to screen 32 breast carcinomas that had been analyzed by immunohistochemical methods for altered p53 protein levels and whose DNA had already been shown to have loss of heterozygosity for a chromosome 17p marker. By immunostaining techniques, only 6 of the 32 tumors had elevated p53 expression. However, CDGE detected p53 mutations in 11 of the 32 tumors. DNA sequence analysis was performed to determine the nucleotide positions of these mutations in all 11 samples. Loss of heterozygosity for the pYNZ22 or p144D6 markers did not associate with either the loss of heterozygosity at the p53 locus or the mutations detected by CDGE. We conclude that CDGE is a rapid and effective technique to screen for p53 mutations.

Molecular characterization of mild-to-moderate hemophilia A: detection of the mutation in 25 of 29 patients by denaturing gradient gel electrophoresis

To date it has been difficult to characterize completely a genetic disorder, such as hemophilia A, in which the involved gene is large and unrelated affected individuals have different mutations, most of which are point mutations. Toward this end, we analyzed the DNA of 29 patients with mild-to-moderate hemophilia A in which the causative mutation is likely to be a missense mutation. Using computer analysis, we determined the melting properties of factor VIII gene sequences to design primer sets for PCR amplification and subsequent denaturing gradient gel electrophoresis (DGGE). A total of 45 primer sets was chosen to amplify 99% of the coding region of the gene and 41 of 50 splice junctions. To facilitate detection of point mutations, we mixed DNA from two male patients, and both homoduplexes and heteroduplexes were analyzed. With these 45 primer sets, 26 DNAs containing previously identified point mutations in the factor VIII gene were studied, and all 26 mutations were easily distinguishable from normal. After analyzing the 29 patients with unknown mutations, we identified the disease-producing mutation in 25 (86%). Two polymorphisms and two rare normal variants were also found. Therefore, DGGE after computer analysis is a powerful method for nearly complete characterization of disease-producing mutations and polymorphisms in large genes such as that for factor VIII.

Identification of a germ-line mutation in the p53 gene in a patient with an intracranial ependymoma

We detected a germ-line mutation of the p53 gene in a patient with a malignant ependymoma of the posterior fossa. This mutation, which was found at codon 242, resulted in an amino acid substitution in a highly conserved site of exon 7 of the p53 gene; the same mutation was found in both the germ-line and the tumor tissue. This is the most common region of previously described somatic p53 mutations in tumor specimens and of the germ-line p53 mutations in patients with the Li-Fraumeni cancer syndrome. Evaluation of the patient's family revealed several direct maternal and paternal relatives who had died at a young age from different types of cancer. The association of a germ-line p53 mutation with an intracranial malignancy and a strong family history of cancer suggests that p53 gene mutations predispose a person to malignancy and, like retinoblastoma mutations, may be inherited.

Developmental function of Elf-1: an essential transcription factor during embryogenesis in Drosophila

The Drosophila transcription factor Elf-1 binds to a cis-acting element that is essential for neuronal expression of the Dopa decarboxylase gene (Ddc). Elf-1 also stimulates transcription from the Ddc and Ultrabithorax promoters in vitro. To investigate the function of this factor in vivo we have screened for mutations and identified the Elf-1 gene as grainyhead (grh), a previously known embryonic lethal locus. Elf-1/grh mutations cause late embryonic lethality accompanied by multiple defects in the cuticle and head skeleton. Using Ddc-lacZ gene fusions, we show that these mutations affect Ddc expression in the embryo. Surprisingly, however, epidermal expression is disrupted, whereas neuronal expression remains unaffected. Analysis of the mutant phenotype indicates that Elf-1 coordinately regulates multiple genes involved in the differentiation of epidermal structures. The results highlight the importance of genetic analysis in the study of proteins required for developmental regulation of gene expression.

Molecular characterization of severe hemophilia A suggests that about half the mutations are not within the coding regions and splice junctions of the factor VIII gene

Hemophilia A is an X chromosome-linked disorder resulting from deficiency of factor VIII, an important protein in blood coagulation. A large number of disease-producing mutations have been reported in the factor VIII gene. However, a comprehensive analysis of the mutations has been difficult because of the large gene size, its many scattered exons, and the high frequency of de novo mutations. Recently, we have shown that nearly all mutations resulting in mild-to-moderate hemophilia A can be detected by PCR and denaturing gradient gel electrophoresis (DGGE). In this study, we attempted to discover the mutations causing severe hemophilia A by analyzing 47 unselected patients, 30 of whom had severe hemophilia and 17 of whom had mild-to-moderate disease. Using DGGE as a screening method, we analyzed 99% of the coding region, 94% of the splice junctions, the promoter region, and the polyadenylylation site of the gene. We found the mutation in 16 of 17 (94%) patients with mild-to-moderate disease but in only 16 of 30 (53%) patients with severe hemophilia A. Since DGGE after computer analysis appears to detect all mutations in a given fragment, the lower-than-expected yield of mutations in patients with severe disease is likely not due to failure of the detection method; it is probably due to the presence of mutations in DNA sequences outside the regions studied. Such sequences may include locus-controlling regions, other sequences within introns or outside the gene that are important for its expression, or another gene involved in factor VIII expression that is very closely linked to the factor VIII gene.

Incomplete kinase labelling of PCR primers yields 'doublet' artifacts in denaturing gradient gels

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Two dimensional single-strand conformation polymorphism analysis: a useful tool for the detection of mutations in long DNA fragments

A new two-dimensional gel system for the analysis of single strand conformational polymorphisms has been developed to identify point mutations, deletions and insertions in long DNA fragments (e.g. 2.7 kb) generated by the polymerase chain reaction. In this procedure, such DNA fragments are first restricted with frequent-cutter enzymes. The resulting small fragments are then separated in the first dimension according to their size by electrophoresis under denaturing conditions; these single stranded DNA fragments are subsequently fractionated in the second dimension by electrophoresis on a non denaturing slab gel based on their fold-back conformation which is completely sequence-dependent. The method was tested on three previously characterized pH 4.5 resistant mutants of HRV14 and was then used to determine changes in three further mutants.

Mutation detection in phenylketonuria by using chemical cleavage of mismatch: importance of using probes from both normal and patient samples

mRNA from a postmortem liver sample of a patient with classical phenylketonuria was examined using the chemical cleavage of mismatch (CCM) method to search for mutations in phenylalanine hydroxylase. Initial screening identified a heterozygous alteration in exon 2 which changed the encoded amino acid from phenylalanine (TTC) to leucine (TTG) at codon 39 and a polymorphism at codon 430 where the change from CTG to CTC did not alter the encoded leucine. Use of the CCM technique also revealed that the control reference clone differed from the published sequence by having a substitution of isoleucine (ATT) for methionine (ATG) at codon 276 and CAA rather than CAG as the codon for glutamine 232. By using the mRNA from the patient instead of the control as the source for the radiolabeled probe for the CCM technique, a second previously undetected alteration was identified in exon 10 where the change from TCA to CCA at codon 349 altered the amino acid from serine to arginine. Judicious choice of probes gives the CCM method the potential to detect close to 100% of single base mutations.

Unexpected behavior of H2Kb mutant DNAs in denaturing gradient gel electrophoresis

Denaturing gradient gel electrophoresis (DGGE) is based upon the different melting behaviors of DNA molecules in a chemical denaturant gradient according to their sequences. This technique has recently become a widespread tool to detect mutations. The introduction of a GC-clamp enables the detection of most single base differences between two DNA molecules. As a test system we have applied the polymerase chain reaction (PCR) in combination with DGGE to detect a number of mutations in the mouse H2Kb DNA sequence. A wide variety of spontaneous in vivo mutations of this haplotype have been reported in the C57BL/6J mouse strain and are clustered in the alpha 1 and alpha 2 domains. The combination of PCR and DGGE revealed almost all base changes present in the H2Kb mutants used. However, most of the PCR products of these mutants showed melting behavior which is not easily predicted. We suggest that in addition to current simple theory, which considers that the migration of a DNA molecule in a denaturing gradient depends primarily on its initial melting behavior, additional factors such as secondary structure in partially melted molecules may play a role and can be used to detect mutations.

Identification of polymorphisms by genomic denaturing gradient gel electrophoresis: application to the proximal region of human chromosome 21

Genomic Denaturing Gradient Gel Electrophoresis (gDGGE) provides an alternative to the standard method of restriction fragment length polymorphism (RFLP) analysis for identifying polymorphic sequence variation in genomic DNA. For gDGGE, genomic DNA is cleaved by restriction enzymes, separated in a polyacrylamide gel containing a gradient of DNA denaturants, and then transferred by electroblotting to nylon membranes. Unlike other applications of DGGE, gDGGE is not limited by the size of the probe and does not require probe sequence information. gDGGE can be used in conjunction with any unique DNA probe. Here we use gDGGE with probes from the proximal region of the long arm of human chromosome 21 to identify polymorphic DNA sequence variation in this segment of the chromosome. Our screening panel consisted of DNA from nine individuals, which was cleaved with five restriction enzymes and submitted to electrophoresis in two denaturing gradient conditions. We detected at least one potential polymorphism for nine of eleven probes that were tested. Two polymorphisms, one at D21S4 and one at D21S90, were characterized in detail. Our study demonstrates that gDGGE is a fast and efficient method for identifying polymorphisms that are useful for genetic linkage analysis.

The molecular basis of hemophilia A

Due to new, sensitive methodologies, the rate at which factor VIII gene mutations are found is increasing rapidly. The next five years should lead to the discovery of a wide range of defects as well as potential new hot-spots for mutations. Advances in understanding the protein will also provide new insights into the effects of particular mutations. Tremendous strides have been made in carrier detection and prenatal diagnosis. Already diagnosis is possible in 70% of cases with the factor VIII intragenic polymorphisms. Although there is still room for improvement in availability, speed, and cost of the test, many families in the United States and Europe are benefiting from this sensitive detection method.

Genome scanning by two-dimensional DNA typing: the use of repetitive DNA sequences for rapid mapping of genetic traits

The existence of repetitive DNA sequences offers the possibility to assess the mammalian genome for individual variation in its entirety rather than at one or only a few sites. In order to fully explore the various sets of mammalian repeat sequences for this purpose, analytical tools are required which allow many if not all individual members of sets of repetitive elements to be resolved and identified in terms of location and allelic variation. We have applied and further developed an electrophoretic system, two-dimensional DNA typing, which may fulfill these requirements. The two-dimensional system combines separation of DNA fragments by size in a neutral gel, with separation by sequence composition in a denaturing gradient gel. By hybridization with minisatellite- and simple-sequence core probes and by inter-repeat polymerase chain reaction techniques, it is possible to obtain individual--and even chromosome-specific separation patterns that consist of hundreds of spots. Computerized image analysis and matching of such spot patterns allows the rapid assessment of multiple polymorphisms, spread over the genome, to monitor genetic variability in populations. When coupled to databases of polymorphic DNA markers with a known genomic location, two-dimensional DNA typing can greatly accelerate the mapping of genetic traits in humans, animals, and plants.

Amplification of nucleic acids by polymerase chain reaction (PCR) and other methods and their applications

The in vitro replication of DNA, principally using the polymerase chain reaction (PCR), permits the amplification of defined sequences of DNA. By exponentially amplifying a target sequence, PCR significantly enhances the probability of detecting target gene sequences in complex mixtures of DNA. It also facilitates the cloning and sequencing of genes. Amplification of DNA by PCR and other newly developed methods has been applied in many areas of biological research, including molecular biology, biotechnology, and medicine, permitting studies that were not possible before. Nucleic acid amplification has added a new and revolutionary dimension to molecular biology. This review examines PCR and other in vitro nucleic acid amplification methodologies--examining the critical parameters and variations and their widespread applications--giving the strengths and limitations of these methodologies.

Restriction fragment length polymorphism in plants and its implications

In the last decade RFLP analysis has evolved from an idea that seemed promising to a well-established tool that has led to fundamental advances in several fields. Construction of genetic maps has now become feasible in many organisms where it would previously have been impractical. Since genetic maps are of general utility for many sorts of biological research, they cannot fail to have a significant impact in the immediate future. As genetic maps become reconciled with physical maps in several plants, it will become possible to clone virtually any gene. For a plant breeder this will have the effect of broadening the gene pool available for plant improvement to include virtually all organisms, including animals and microorganisms. Much remains to be done, however. We need basic studies of the biochemistry, physiology, and genetics of plants and the insects and pathogens infesting them to be able to identify target genes for cloning. We need basic studies of transformation and gene expression to be able to have introduced genes expressed in transformed plants in the proper amounts and in the desired tissues. It must also be kept in mind that the best of our present technologies only suffice to clone and transform single genes. We will have to make another large jump in capabilities to be able to transfer QTL between plants. Since the most important agronomic traits are controlled by QTL, this effort will have to be undertaken. However, the future looks promising for plant breeding and RFLP analysis. The molecular genetic revolution now has every indication of being transferrable to practical problems such as plant breeding, and the first steps in this transferral have already occurred through the medium of RFLP analysis.

Two-dimensional DNA-fingerprinting in animals

DNA-fingerprinting has become, during the last five years, an important method of genetic analysis in medicine, veterinary medicine and other disciplines. The power of this technique, especially for genetic linkage analysis, may be enhanced in humans by using the two dimensional DNA-fingerprinting method. Here we show that this procedure can successfully be applied to different animal species, e.g. pig, dog and mouse. Optimal conditions, however, have to be determined for each species tested. With the use of marker systems as well as computer programs it will be possible to evaluate complex two-dimensional spot patterns in a short time and with high reliability.

Antenatal diagnosis of beta-thalassemia in Sardinia

This paper reviews the characteristics and the results of 15 years of experience with a preventive program, based on carrier screening and prenatal diagnosis, designed to control thalassemia major in the Sardinian population. The education of the population about thalassemia and the modalities for its prevention was accomplished via the mass media. Carrier screening was carried out voluntarily on couples of child-bearing age. Prenatal diagnosis was initially carried out by fetal blood analysis; since 1983, it has been done by DNA analysis on non-amplified or amplified DNA. Different chorionic villous sampling procedures have been used. Nowadays, we have adopted the transabdominal approach because, in our experience, it seems to be associated with a low risk (2%) of fetal mortality. At the present time, the beta-thalassemia mutations are detected directly by dot-blot analysis of amplified DNA with 32P- or horseradish peroxidase-labeled allele-specific oligonucleotide probes. Two oligonucleotide probes, one complementary to the codon-39 nonsense mutation, which accounts for 95.7% of the beta-thalassemia chromosomes in the Sardinian population, and the other complementary to the frameshift at codon 6, which is the second most common mutation in our population (2.1%), allow us to make prenatal diagnosis in the large majority of cases. Notwithstanding a careful dissection of maternal decidua from chorionic villi, co-amplification of maternal sequence was detected in 4 out of 425 cases tested by this procedure. In order to avoid this pitfall, the simultaneous amplification of highly polymorphic VNTR (variable number of tandem repeats) segments could be used. On the whole we have so far carried out 2711 prenatal tests: 1130 by fetal blood analysis, 1156 by oligonucleotide hybridization on electrophoretically separated DNA fragments, and 425 by dot-blot analysis on amplified DNA with allele-specific oligonucleotide probes. Two errors occurred by fetal blood analysis and none by DNA analysis. The incidence of thalassemia major declined from 1:250 live births in the absence of prevention to 1:1000 after the establishment of this program, indicating that carrier screening and prenatal diagnosis are effective means for preventing thalassemia major at the population level.

A chemical mismatch cleavage method useful for the detection of point mutations in the p53 gene in lung cancer

Point mutations in genes can be etiologic of pulmonary diseases, as in the case of the inherited disorders alpha-1-antitrypsin deficiency and cystic fibrosis or in the context of dominant and recessive oncogenes in lung cancer. Various methodologies have been developed to screen for single-base mutations. These techniques include direct DNA sequencing, RNase protection, denaturing gradient gel electrophoresis, and chemical mismatch cleavage. The latter method offers the advantages of rapid and efficient analysis of genomic or cDNA and is thus ideally suited to screening applications. Furthermore, all possible single-base changes can theoretically be detected. In the present work, chemical mismatch cleavage was utilized to detect mutations in the p53 gene in small cell and non-small cell lung cancer. This technique was modified by using a two-step, hemi-nested PCR procedure for preparation of target genomic DNAs permitting an expanded target size for analysis. Evaluation by chemical mismatch cleavage of eight p53 cDNAs derived from lung tumors shown to have different mutations by DNA sequencing correctly detected the presence of a point mutation in all instances. Analysis of six additional tumor genomic DNAs with defined mutations in the corresponding p53 cDNAs accurately confirmed the mutation at the level of the genome. The technique also identified codon 72 and intron 6 polymorphisms. Using the intron 6 polymorphism, loss of heterozygosity at the p53 locus in tumor DNA was readily detected by chemical mismatch cleavage. Finally, utilizing this technique for scanning analysis of the p53 gene of uncharacterized lung tumor DNAs, additional mutations were identified in a prospective manner which were confirmed by sequence analysis.(ABSTRACT TRUNCATED AT 250 WORDS)

Detection by denaturing gradient gel electrophoresis of a new polymorphism in the apolipoprotein B gene

The apolipoprotein B gene is subject to mutations that may be important in coronary heart diseases. We have used polymerase chain reaction and denaturing gradient gel electrophoresis to characterize a single nucleotide substitution in the apolipoprotein B gene. This mutation affects amino acid 4311 of the protein and converts asparagine to serine. It was found in 24% of the 81 unrelated individuals analyzed. Moreover, another mutation was detected by sequencing in a single individual.

Rapid, nonradioactive detection of clonal T-cell receptor gene rearrangements in lymphoid neoplasms

Southern blot hybridization analysis of clonal antigen receptor gene rearrangements has proved to be a valuable adjunct to conventional methods for diagnosing lymphoid neoplasia. However, Southern blot analysis suffers from a number of technical disadvantages, including the time necessary to obtain results, the use of radioactivity, and the susceptibility of the method to various artifacts. We have investigated an alternative approach for assessing the clonality of antigen receptor gene rearrangements in lymphoid tissue biopsy specimens. This approach involves the amplification of rearranged gamma T-cell receptor genes by the polymerase chain reaction and analysis of the polymerase chain reaction products by denaturing gradient gel electrophoresis. By use of this approach, clonal rearrangements from neoplastic lymphocytes constituting as little as 0.1-1% of the total cells in the tissue are detected as discrete bands in the denaturing gel after the gel is stained with ethidium bromide and viewed under ultraviolet light. In contrast, polyclonal rearrangements from reactive lymphocytes appear as a diffuse smear along the length of the gel. Our findings suggest that polymerase chain reaction combined with denaturing gradient gel electrophoresis may offer a rapid, nonradioactive, and sensitive alternative to Southern blot analysis for the diagnostic evaluation of lymphoid tissue biopsy specimens.

Detection of heteroduplex DNA molecules among the products of Saccharomyces cerevisiae meiosis

We have used denaturant-gel electrophoresis to provide a physical demonstration of heteroduplex DNA in the products of yeast meiosis. We examined heteroduplex formation at arg4-nsp, a G.C----C.G transversion that displays a moderately high level of postmeiotic segregation. Of the two possible arg4-nsp/ARG4 mismatches (G.G and C.C), only C.C was detected in spores from mismatch repair-competent (Pms1+) diploids. In contrast, C.C and G.G were present at nearly equal levels in spores from Pms1- diploids. These results confirm previous suggestions that postmeiotic segregation spores contain heteroduplex DNA at the site of the marker in question, that C.C is repaired less frequently than is G.G, and that the PMS1 gene product plays a role in mismatch correction. Combined with the observation that Pms1+ ARG4/arg4-nsp diploids produce 3 times more 3+:5m (wildtype:mutant) tetrads (+, +, +/m, m) than 5+:3m tetrads (+, +/m, m, m), these results indicate that, during meiosis, formation of heteroduplex DNA at ARG4 involves preferential transfer of the sense (nontranscribed) strand of the DNA duplex.

Detection of single-base mutations by reaction of DNA heteroduplexes with a water-soluble carbodiimide followed by primer extension: application to products from the polymerase chain reaction

A new method was developed for the detection of single-base mutations in DNA. The polymerase chain reaction was used to prepare DNA fragments of up to 1 kb. Fragments that differed by a single-base were combined, denatured and renatured to generate heteroduplexes. The heteroduplexes were reacted with a water-soluble carbodiimide under conditions in which the carbodiimide modified Gs and Ts that were not base paired. The DNA was then used as a template for primer extension with Taq DNA polymerase under conditions in which extension terminated at the site of the carbodiimide-modified base and generated a 32P-labeled fragment that was identified by polyacrylamide gel electrophoresis as a fragment smaller than the full length product. The procedure detected all four general classes of single-base mutations in several different sequence contexts. The site of the mutation was located to within about 15 bp. Extension with both a 5'- and a 3'-primer made it possible to confirm the site of the mutation in most DNA samples or detect a mutation in heteroduplexes even if a G or T in one strand was unreactive because of its sequence context. The procedure appears to have several advantages over previously published techniques.

Denaturing gradient gel electrophoresis identifies genomic DNA polymorphism with high frequency in maize

We have used denaturing gradient gel electrophoresis (DGGE) to identify genomic DNA polymorphism in maize (Zea mays L.). DGGE probes detect polymorphism in maize at a frequency comparable to the incidence of restriction fragment length polymorphism (RFLP). Probes identifying polymorphism were mapped to maize chromosome arms by utilizing DGGE and maize lines carrying B-A chromosomal translocations. The methods for library construction, probe screening, and genome analysis, described here for maize, can also be applied to the genomic analysis of other organisms.

Detecting base pair substitutions in DNA fragments by temperature-gradient gel electrophoresis

A vertical gel electrophoresis apparatus is described which can distinguish DNA fragments differing by single base pair substitutions. The system employs a homogenous polyacrylamide gel containing urea-formamide and a temperature gradient which runs either perpendicular or parallel to the direction of electrophoresis. The temperature-gradient system simplifies several features of the denaturant-gradient system (1) and is relatively inexpensive to construct. Eight homologous 373 bp DNAs differing by one, two, or nine base pair substitutions were examined. DNA electrophoretic mobility changed abruptly with the temperature induced unwinding of DNA domains. GC to AT substitutions at different locations within the first melting domain, as well as an AT to TA transversion were separated with temperature gradients parallel to the electrophoretic direction. The relative stabilities of the DNAs observed in the gels were compared to predictions of DNA melting theory. General agreement was observed however complete correspondence was not obtained.

Mutations and a polymorphism in the factor VIII gene discovered by denaturing gradient gel electrophoresis

Hemophilia A results from mutations in the gene coding for coagulation factor VIII. We used denaturing gradient gel electrophoresis to screen for mutations in the region of the factor VIII gene coding for the first acidic domain. Amplification primers were designed employing the MELTMAP computer program to optimize the ability to detect mutations. Screening of amplified DNA from 228 unselected hemophilia A patients revealed two mutations and one polymorphism. Rescreening the same population by making heteroduplexes between amplified patient and control samples prior to electrophoresis revealed one additional mutation. The mutations include two missense and one 4-base-pair deletion, and each mutation was found in patients with severe hemophilia. The polymorphism, located adjacent to the adenine branch site in intron 7, is useful for genetic prediction in some cases where the Bcl I and Xba I polymorphisms are uninformative. These results suggest that DNA amplification and denaturing gradient gel electrophoresis should be an excellent strategy for identifying mutations and polymorphisms in defined regions of the factor VIII gene and other large genes.

Identification of the multiple beta-thalassemia mutations by denaturing gradient gel electrophoresis

We used denaturing gradient gel electrophoresis to detect the beta-thalassemia mutations in the Chinese population. By amplifying the beta-globin gene in four separate fragments and electrophoresing the amplified DNA in two gels, we were able to distinguish all the 12 known mutations on the basis of the mobility of the homoduplexes and heteroduplexes. We conclude that denaturing gradient gel electrophoresis offers a nonradioactive means of detecting multiple mutations in genetic disorders.

Mapping the gene for juvenile myoclonic epilepsy

The practice of epileptology at a molecular level, where gene products are identified by gene mapping, will soon be possible for a growing number of epilepsies. Juvenile myoclonic epilepsy (JME) is the first of such epilepsies to be mapped to a chromosome, namely chromosome 6p21.3. Family studies of 68 JME probands from California revealed 50% of all families reported seizures in first- or second-degree relatives. Twelve percent of all family members other than the proband had epileptic seizures. Eighty percent of symptomatic siblings and 6% of asymptomatic siblings had diffuse 4- to 6-Hz multispike-wave complexes. Twelve percent of asymptomatic parents had diffuse, nonspecific slow waves mixed with spikes or sharp waves. JME is tightly linked to the Bf-HLA loci in chromosome 6. No matter what mode of inheritance is assumed, linkage to the clinical manifestations of JME and its associated EEG traits is indicated by lod scores over 3.0, as long as "EEG affected" but clinically asymptomatic family members are counted as affected during LIPED analysis. Studies are now being done to further localize the JME site. At the same time, further linkage studies should decide if JME is heterogeneous within itself and whether the same JME site in 6p21.3 underlies absence and grand mal epilepsies.

Fidelity of DNA polymerases in DNA amplification

Denaturing gradient gel electrophoresis (DGGE) was used to separate and isolate the products of DNA amplification by polymerase chain reaction (PCR). The strategy permitted direct enumeration and identification of point mutations created by T4, modified T7, Klenow fragment of polymerase I, and Thermus aquaticus (Taq) DNA polymerases. Incorrectly synthesized sequences were separated from the wild type by DGGE as mutant/wild-type heteroduplexes and the heteroduplex fraction was used to calculate the average error rate (mutations per base duplication). The error rate induced in the 104-base-pair low-temperature melting domain of exon 3 of the human hypoxanthine/guanine phosphoribosyltransferase (HPRT) gene was approximately 3.4 x 10(-5) for modified T7, 1.3 x 10(-4) for Klenow fragment, and 2.1 x 10(-4) for Taq polymerases after a 10(6)-fold amplification. The error rate for T4 DNA polymerase was not more than 3 x 10(-6) error per base duplication. The predominant mutations were sequenced and found to be transitions of G.C to A.T for T4 and modified T7 DNA polymerases, and A.T to G.C for Taq polymerase. Klenow fragment induced both possible transitions and deletions of 2 and 4 base pairs.

Ancient roots for polymorphism at the HLA-DQ alpha locus in primates

The genes encoding the human histocompatibility antigens (HLA) exhibit a remarkable degree of polymorphism as revealed by immunologic and molecular analyses. This extensive sequence polymorphism either may have been generated during the lifetime of the human species or could have arisen before speciation and been maintained in the contemporary human population by selection or, possibly, by genetic drift. These two hypotheses were examined using the polymerase chain reaction method to amplify polymorphic sequences from the DQ alpha locus, as well as the DX alpha locus, an homologous but nonexpressed locus, in a series of primates that diverged at known times. In general, the amino acid sequence of a specific human DQ alpha allelic type is more closely related to its chimpanzee or gorilla counterpart than to other human DQ alpha alleles. Phylogenetic analysis of the silent nucleotide position changes shows that the similarity of allelic types between species is due to common ancestry rather than convergent evolution. Thus, most of the polymorphism at the DQ alpha locus in the human species was already present at least 5 million years ago in the ancestral species that gave rise to the chimpanzee, gorilla, and human lineages. However, one of the DQ alpha alleles may have arisen after speciation by recombination between two ancestral alleles.

Polymerase chain reaction

The PCR, like recombinant DNA technology, has had an enormous impact in both basic and diagnostic aspects of molecular biology because it can produce large amounts of a specific DNA fragment from small amounts of a complex template. Recombinant DNA techniques create molecular clones by conferring on a specific sequence the ability to replicate by inserting it into a vector and introducing the vector into a host cell. PCR represents a form of "in vitro cloning" that can generate, as well as modify, DNA fragments of defined length and sequence in a simple automated reaction. In addition to its many applications in basic molecular biological research, PCR promises to play a critical role in the identification of medically important sequences as well as an important diagnostic one in their detection.

Mutation detection using nucleotide analogs that alter electrophoretic mobility

A simple primer extension assay has been developed to distinguish homologous DNA segments differing by as little as a single nucleotide. DNA strands are synthesized with one of the four natural nucleotides replaced with an analog that affects electrophoretic mobility. DNAs that are the same length but differ in the number of analog molecules per strand exhibit different mobilities on a sequencing gel. In combination with the polymerase chain reaction (PCR; 1, 2), this method has been used to distinguish mutant and normal alleles of the human insulin receptor gene that differ by a single-base substitution. The method appears to be generally applicable to the detection of any nucleotide polymorphism in any segment of DNA.

Perspectives on UV light mutagenesis: investigation of the CHO aprt gene carried on a retroviral shuttle vector

The extent to which the cellular processing of shuttle vector-carried genes reflects that of endogenous chromosomal loci has been a subject of considerable controversy. In order to address this issue, we have developed a retroviral-based shuttle vector carrying the Chinese hamster ovary (CHO) adenine phosphoribosyltransferase (aprt) gene stably integrated into the genome to be used for studying mutational specificity in mammalian cells. Initially, we have characterized a collection of UV-induced mutants in a CHO cell background. We have therefore been able to directly compare this shuttle vector data to that previously obtained for UV-induced mutation at the endogenous CHO (aprt) locus. Although some potential differences between the two spectra have been noted, there appears to be a remarkable similarity in the distribution and site specificity of UV-induced mutations. These similarities extend to extrachromosomal shuttle vectors as well and consolidate the role of shuttle vectors as powerful analytical tools for studying mechanisms of point mutagenesis in mammalian cells.

Molecular analysis of recombination events in Drosophila

The locations of crossover junctions and gene conversion tracts, isolated in the rosy gene of Drosophila melanogaster, were determined using DNA sequencing and denaturing gradient gel electrophoresis. Frequent DNA sequence polymorphisms between the parental genes served as unselected genetic markers. All conversion tracts were continuous, and half of the reciprocal crossover events had conversion tracts at the crossover junction. These experiments have also identified the sequence polymorphisms responsible for altered gene expression in two naturally occurring rosy variants.

The role of mitochondrial DNA in Huntington's disease

Huntington's disease is generally considered to be a late-onset neurodegenerative disorder, which follows a protracted course of deteriorating motor control and cognitive impairment. However, in a minority of cases, the onset of symptoms occurs early in life. A preponderance of the juvenile-onset HD victims have inherited the genetic defect from their fathers. This variation in age of onset, based on the sex of the affected parent, has suggested that maternally inherited genes may influence expression of the disorder. We describe a portion of a large Venezuelan HD pedigree in which both the mother and father of three juvenile-onset HD patients share a common maternal lineage. Scanning of mtDNA from members of this family with 43 restriction endonucleases failed to reveal any differences in the mitochondrial genotype that could account for the difference in age of onset between the affected father and his progeny. Members of a related family with an affected father but no juvenile-onset progeny also appeared to share the same mitochondrial genotype. In addition, the mitochondrial gene products from lymphoblast cell lines of these family members were analyzed on polyacrylamide gels after incubation of cells with [35S]methionine, but no detectable alterations were seen. Taken together, these data suggest that the maternally inherited mitochondrial genome does not play a crucial role in determining in age of onset in HD.

Direct detection of point mutations by mismatch analysis: application to haemophilia B

Rapid detection of point mutations in genomic DNA has been achieved by chemical mismatch analysis of heteroduplexes formed between amplified wild-type and target sequences in the human factor IX gene. Amplification and mismatch detection (AMD) analysis of DNA from relatives of haemophilia B patients permitted carrier diagnosis by direct identification of the presence or absence of the mutation in all cases, thus eliminating the need for the informative segregation of polymorphic markers. This extends diagnostic capability to virtually all haemophilia B families. AMD analysis permits detection of all sequence variations in genomic DNA and is therefore applicable to direct diagnosis of X-linked and autosomal diseases and for identification of new polymorphisms for genetic mapping.

The use of denaturing gradient gel electrophoresis to screen for DNA sequence polymorphisms in the human factor VIII gene

We describe the use of denaturing gradient gel electrophoresis to screen for DNA sequence polymorphisms in the human factor VIII gene. DNA fragments that differ in sequence by only a single base pair can be separated on denaturing gradient gels due to changes in their melting behavior. Previous studies have demonstrated the use of denaturing gradient gels to detect sequence changes in human genomic DNA, including mutations in the beta globin gene and polymorphisms on chromosome 20. We have begun to use denaturing gradient gels to look for polymorphisms within the human factor VIII gene. The DNA sequences of seven cloned fragments from introns in the human factor VIII gene were determined and used to predict a melting map for each fragment. The melting behavior of each cloned fragment was evaluated by electrophoresis into denaturing gradient gels. Appropriate fragments were then used as radioactive probes for hybridization to human DNA samples that had been digested with restriction enzymes. Heteroduplexes formed between the probe and genomic DNA samples were electrophoresed into denaturing gradient gels. The final positions of heteroduplex bands were determined by autoradiography. We describe a general approach for using denaturing gradient gel electrophoresis to find DNA polymorphisms, with particular emphasis on the predictive value of DNA sequence data. We compare the efficiency of polymorphism detection by denaturing gradient gel electrophoresis with detection by restriction fragment length polymorphism (RFLP) analysis. The factor VIII gene appears to have a low level of DNA sequence polymorphism.(ABSTRACT TRUNCATED AT 250 WORDS)

Two-dimensional DNA fingerprinting of human individuals

The limiting factor in the presently available techniques for the detection of DNA sequence variation in the human genome is the low resolution of Southern blot analysis. To increase the analytical power of this technique, we applied size fractionation of genomic DNA restriction fragments in conjunction with their sequence-dependent separation in denaturing gradient gels; the two-dimensional separation patterns obtained were subsequently transferred to nylon membranes. Hybridization analysis using minisatellite core sequences as probes resulted in two-dimensional genomic DNA fingerprints with a resolution of up to 625 separated spots per probe per human individual; by conventional Southern blot analysis, only 20-30 bands can be resolved. Using the two-dimensional DNA fingerprinting technique, we demonstrate in a small human pedigree the simultaneous transmission of 37 polymorphic fragments (out of 365 spots) for probe 33.15 and 105 polymorphic fragments (out of 625 spots) for probe 33.6. In addition, a mutation was detected in this pedigree by probe 33.6. We anticipate that this method will be of great use in studies aimed at (i) measuring human mutation frequencies, (ii) associating genetic variation with disease, (iii) analyzing genomic instability in relation to cancer and aging, and (iv) linkage analysis and mapping of disease genes.

Denaturing gradient gel analysis of single-base substitutions at a mouse adenine phosphoribosyltransferase splice acceptor site

Denaturing gradient gel electrophoresis (DGGE) can detect single-base changes in DNA. We used site-directed mutagenesis to produce all six possible single-base substitutions at a splice acceptor consensus AG dinucleotide within the mouse adenine phosphoribosyltransferase (aprt) gene. Studies of mouse and Chinese hamster cell aprt indicate a high level of both spontaneous and induced mutations in this region. We systematically evaluated each of the six mutations by DGGE. Five of the six mutant sequences could be distinguished from wildtype by DGGE analysis of a 560-bp fragment containing the mutation. However, one mutant could not be distinguished from wild-type, and some of the mutant constructs could not be distinguished from each other. Analysis of DNA heteroduplexes consisting of wild-type and mutant strands or two different mutant strands enabled all mutant constructs to be distinguished from wild-type and from each other. The pairwise mixtures resulted in 24 different heteroduplexes, all of which were less stable than the parental homoduplexes. End labeling of DNA prior to heteroduplex formation and subsequent DGGE analysis enabled us to determine the relative destabilization caused by different types of single-base mismatches.

Attachment of a 40-base-pair G + C-rich sequence (GC-clamp) to genomic DNA fragments by the polymerase chain reaction results in improved detection of single-base changes

Denaturing gradient gel electrophoresis (DGGE) can be used to distinguish two DNA molecules that differ by as little as a single-base substitution. This method detects approximately 50% of all possible single-base changes in DNA fragments ranging from 50 to approximately 1000 base pairs. To increase the number of single-base changes that can be distinguished by DGGE, we used the polymerase chain reaction to attach a 40-base-pair G + C-rich sequence, designated a GC-clamp, to one end of amplified DNA fragments that encompass regions of the mouse and human beta-globin genes. We show that this GC-clamp allows the detection of mutations, including the hemoglobin sickle (HbS) and hemoglobin C (HbC) mutations within the human beta-globin gene, that were previously indistinguishable by DGGE. In addition to providing an easy way to attach a GC-clamp to genomic DNA fragments, the polymerase chain reaction technique greatly increases the sensitivity of DGGE. With this approach, DNA fragments derived from less than 5 ng of human genomic DNA can be detected by ethidium bromide staining of the gel, obviating the need for radioactive probes. These improvements extend the applicability of DGGE for the detection of polymorphisms and mutations in genomic and cloned DNA.

Generation of single-stranded DNA by the polymerase chain reaction and its application to direct sequencing of the HLA-DQA locus

Single-copy sequences can be enzymatically amplified from genomic DNA by the polymerase chain reaction. By using unequal molar amounts of the two amplification primers, it is possible in a single step to amplify a single-copy gene and produce an excess of single-stranded DNA of a chosen strand for direct sequencing or for use as a hybridization probe. Further, individual alleles in a heterozygote can be sequenced directly by using allele-specific oligonucleotides either in the amplification reaction or as sequencing primers. By using these methods, we have studied the allelic diversity at the HLA-DQA locus and its association with the serologically defined HLA-DR and -DQ types. This analysis has revealed a total of eight alleles and three additional haplotypes. This procedure has wide applications in screening for mutations in human genes and facilitates the linking of enzymatic amplification of genes to automated sequencing.

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)

Double-stranded cucumovirus associated RNA 5: which sequence variations may be detected by optical melting and temperature-gradient gel electrophoresis?

Sequence variants of the double-stranded form of satellite RNAs of cucumber mosaic virus (dsCARNA 5) were analyzed for the possibility to experimentally detect minor nucleotide sequence changes. Denaturation maps (helix-probability versus position of the nucleotide in the sequence versus temperature) were calculated applying the Poland algorithm. Optical denaturation curves and temperature-gradient gel mobility curves were simulated using the denaturation maps and were compared with experimental results from optical melting and temperature-gradient gel electrophoresis (Tien Po et al., accompanying paper). Melting of the dsRNAs starts from both ends of the molecule in two transitions of low co-operativity, continues in the right part in a highly co-operative transition, and is finished in another highly co-operative transition including strand-separation. Whereas all parts of the molecule contribute uniformly to the optical melting curve, opening of the ends predominates in the retardation transition in gel electrophoresis. Detailed discussion of the influence of base pair changes in the sequence shows that a single base pair change may be detected by temperature-gradient gel electrophoresis, if it is located in certain favorable locations, whereas its detection in optical melting curves is possible only in very special cases. The systematic differences found in the accompanying paper between necrogenic and non-necrogenic dsCARNA 5 could be interpreted on the basis of such nucleotide sequence differences.