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

PCR primers based on different portions of insertion elements can assist genetic relatedness studies, strain fingerprinting and species identification in rhizobia

Using the sequence of an insertion element originally found in Rhizobium sullae, the nitrogen-fixing bacterial symbiont of the legume Hedysarum coronarium, we devised three primer pairs (inbound, outbound and internal primers) for the following applications: (a) tracing genetic relatedness within rhizobia using a method independent of ribosomal inheritance, based on the presence and conservation of IS elements; (b) achieve sensitive and reproducible bacterial fingerprinting; (c) enable a fast and unambiguous detection of rhizobia at the species level. In terms of taxonomy, while in line with part of the 16S rRNA gene- and glutamine synthetase I-based clustering, the tools appeared nonetheless more coherent with the actual geographical ranges of origin of rhizobial species, strengthening the European-Mediterranean connections and discerning them from the asian and american taxa. The fingerprinting performance of the outward-pointing primers, designed upon the inverted repeats, was shown to be at least as sensitive as BOX PCR, and to be functional on a universal basis with all 13 bacterial species tested. The primers designed on the internal part of the transposase gene instead proved highly species-specific for R. sullae, enabling selective distinction from its most related species, and testing positive on every R. sullae strain examined, fulfilling the need of PCR-mediated species identification. A general use of other IS elements for a combined approach to rhizobial taxonomy and ecology is proposed.

Use of denaturing gradient electrophoresis to determine the distributions of polymorphisms in entire genes in natural populations

We show here that the method of genomic denaturing gradient electrophoresis (gDGGE) can be used to examine any gene that has been previously cloned and sequenced, and to detect and approximately localize within the gene the majority of its polymorphisms. By using pooled-DNA gDGGE, many different samples can be scanned on a single gel. Further, the patterns on the gels and results from sequencing of some of the alleles shows that a variety of different kinds of polymorphism, ranging from single base changes to more substantial allelic differences, can be distinguished. The extramacrochaetae (emc) gene of Drosophila melanogaster exhibits no polymorphism in its ORF that can be detected by this method, although a rearrangement polymorphism was detected in the 3' downstream region of the gene. The suppressor-of-hairless (Su(H)) gene of D. melanogaster, however, exhibits a variety of polymorphisms in its ORF. Some are small deletions or insertions in a glutamine-rich part of the gene product that would not have been detectable by ordinary screening methods. Many of the polymorphisms detected in this preliminary survey are likely to have an impact on the function of the Su(H) gene product.

Perspectives on molecular assays for measuring mutation in humans and rodents

The original idea for this article was to examine the new molecular techniques for detection of mutation directly at the DNA level in exposed individuals or their offspring and to assess their relative advantages and disadvantages for mutation monitoring in humans and rodents. However, an examination of the articles and a comparison of the technology indicated that our constant quests for methods improvement were leading to some loss of insight into the important health-related questions that should be guiding these endeavors. As a result, individual methods are not covered here in great technical detail. Instead, a few molecular methods are presented in a general overview, along with some of the biological issues related to the detection of induced mutations within individuals and populations. Some hypothetical scenarios are also presented because molecular approaches will continue to change rapidly, and we must continually adjust our thinking to combine the useful attributes of each current and future technical approach with the most appropriate biological questions.

Mutation detection by denaturing gradient gel electrophoresis (DGGE)

The molecular analysis of genetic diseases relies on several technical approaches which allow genetic and physical mapping, characterization of the gene structure, expression studies, and identification of disease-causing mutations. Denaturing gradient gel electrophoresis (DGGE) allows the rapid screening for single base changes in enzymatically amplified DNA. The technique is based on the migration of double-stranded DNA molecules through polyacrylamide gels containing linearly increasing concentrations of a denaturing agent. In this review DGGE and the several modifications of the original protocol are presented. Moreover, its applications in human molecular genetics are summarized together with a preliminary comparison with other mutation detection technologies such as chemical cleavage, RNase protection, and single-strand conformation polymorphism.

Genome mapping by arbitrary amplification of yeast artificial chromosomes

Several methods have been described for using the polymerase chain reaction (PCR) to isolate fragments of DNA for genome mapping. We have developed an approach for isolating discrete fragments by amplifying DNA with single oligonucleotides (10-mers) with arbitrarily selected sequences. The method is rapid and technically simple. We isolated fragments from a contig of three yeast artificial chromosomes (YACs) from the human Xq28 chromosomal region. We purified YACs yWXD37, yWXD348, and yWXD705 from a preparative pulsed field gel. Amplifications of each YAC were performed with single 10-mers as the PCR primers and the products were visualized on agarose gels. These fragments have been successfully used as hybridization probes against Southern blots containing the YACs and against blots containing human genomic DNA and somatic cell hybrids containing Xq28 as their only human constituent. The results have been concordant with the known order of the YACs. We have also successfully combined 10-mers with primers derived from vector arm sequences to isolate YAC ends. We discuss several uses of this method in comparative mapping and in filling in gaps in physical and genetic maps.

Pedigree assessment using RAPD-DGGE in cereal crop species

The introduction of molecular biology methodologies to plant improvement programs offers an invaluable opportunity for extensive germplasm characterization. However, the detection of adequate DNA polymorphism in self-pollinating species remains on obstacle. We have optimized a denaturing-gradient-gel electrophoresis (DGGE) system which, when used in combination with random amplified polymorphic DNA (RAPD) analysis, greatly facilitates the detection of reproducible DNA polymorphism among closely related plant lines. We have used this approach to estimate pedigree relationships among a spectrum of plant materials in wheat, barley and oat. Based on analysis with one or two primers, we were able to distinguish soft from hard winter wheat, and 2-rowed from 6-rowed barley. Further analysis with additional primers allowed resolution of polymorpisms even among closely related lines in highly selected populations. We placed 17 cultivars of oat into two distinct clusters that differed significantly from previous oat pedigree assessments. We believe that DGGE-RAPD is a superior method for detecting DNA polymorphism when compared to RFLP, agarose-RAPD, or polyacrylamide-RAPD methods.

Variations among Japanese of the factor IX gene (F9) detected by PCR-denaturing gradient gel electrophoresis

In the course of feasibility studies to examine the efficiencies and practicalities of various techniques for screening for genetic variations, the human coagulation factor IX (F9) genes of 63 Japanese families were examined by PCR-denaturing gradient gel electrophoresis (PCR-DGGE). Four target sequences with lengths of 983-2,891 bp from the F9 genes of 126 unrelated individuals from Hiroshima and their 100 children were amplified by PCR, digested with restriction enzymes to approximately 500-bp fragments, and examined by DGGE--a total of 6,724 bp being examined per individual. GC-rich sequences (GC-clamps) of 40 bp were attached to both ends of the target sequences, as far as was feasible. Eleven types of new nucleotide substitutions were detected in the population, none of which produced RFLPs or caused hemophilia B. By examining two target sequences in a single lane, approximately 8,000 bp in a diploid individual could be examined. This approach is very effective for the detection of variations in DNA and is applicable to large-scale population studies.

TaqI RFLP at D21S137

Images

Detection of the common alpha-1-antitrypsin variants by denaturing gradient gel electrophoresis

The well-characterized and highly polymorphic human alpha-1-antitrypsin (AAT) gene was used as a test locus to evaluate the general applicability of denaturing gradient gel electrophoresis (DGGE) for the detection of single base change polymorphisms. We report the resolution of all the major alleles, M1Ala, M1Val, M2, M3, S and Z and the identification of substantial genetic polymorphism in intron 3-4 by this technique. DGGE was found to be a quick and efficient method for the screening of multiple samples for the presence of genetic variation.