Comprehensive detection of single base changes in human genomic DNA using denaturing gradient gel electrophoresis and a GC clamp

We present a simple, efficient extension of denaturing gradient gel electrophoresis that allows the detection of nearly any sequence change in a defined fragment of DNA. The fragment can be obtained either by means of the polymerase chain reaction or by restriction digestion of genomic DNA. With restriction fragments of genomic DNA, sequence information is not required, and covalent modifications in genomic DNA that are lost in a PCR, such as methylation, are detectable. We describe how a GC clamp (an arbitrary, G+C-rich sequence of 30 to 60 bp) can be attached to a selected restriction fragment present in a digest of genomic DNA. The GC clamp alters the melting properties of the fragment; this change greatly increases the fraction of possible mutations that is detectable. In a 272-bp HaeIII fragment from the human beta-globin gene, we were able to detect 13 of 13 mutations tested in human genomic DNA. Four additional mutations in cloned plasmids were analyzed. The data agree with a simple theoretical model for DGGE, which predicts how two fragments, differing at a single (specified) base pair, are resolved in a gradient gel as a function of running time for the gel. The calculation assists in the design of probes and gel conditions that aid in the detection of sequence changes.     

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

Summary 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.     

A comparison of solution and membrane-bound DNA × DNA hybridization,as used to infer phylogeny

A new method of membrane-bound DNA × DNA hybridization was devised to accommodate the study of small quantities of DNA obtained from museum specimens for phylogeny reconstruction. Membranebound, single-stranded target genomic DNAs were competitively hybridized with a total genomic DNA probe to form hybrid duplexes required for the DNA dissociation experiments. We compared the thermal elution profiles derived from dissociating duplexes made with probes of whole genomic, single-copy, and repetitive DNA, as well as solution DNA × DNA hybridization using sc tracer. Quantitatively, pairwise indices of genetic distance derived from duplexes made with genomic probes depended entirely on hybridization of repetitive sequences, but a parallel set of experiments using repetitive and sc probes produced qualitatively similar results. The indices of genetic distance generated by the membrane-bound hybrids form an internally consistent, resolved tree which is in agreement with the solution DNA × DNA hybridization trials and traditional views of the phylogeny of the taxa under study.Correspondence to: P. Houde     

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.     

Use of matrix-immobilised recombinant plasmids to purify chain-specific rabbit globin complementary DNAs.

The cloning of DNA sequences in plasmid recombinants has made it possible to amplify specific sequences to an extent that they can be used for preparative purposes. We describe the use of rabbit globin DNA sequences cloned in the plasmid pCR1 and covalently bound to Sepharose 4B for the purification of chain-specific rabbit alpha- and beta-globin cDNAs. These purified probes were then used to estimate the length of the alpha- and beta-globin DNA sequences inserted into the recombinant plasmid. The technique should allow the rapid isolation of sequence-specific cDNA, RNA and genomic DNA.     

Characterization and detection of a newly described Asian taeniid using cloned ribosomal DNA fragments and sequence amplification by the polymerase chain reaction.

DNA isolated from a newly described taeniid from Taiwan which shows adult characters indistinguishable from those of Taenia saginata was compared to DNA from T. saginata and nine other cestodes by restriction endonuclease digestion of genomic DNA and Southern blot analysis using 32P-labeled total cestode RNA and cloned ribosomal RNA gene fragments as probes. Hybridization patterns of Taiwan Taenia DNA revealed distinct variations from that of T. saginata and Taenia solium as well as all other cestode DNAs examined; however, similarities in restriction maps and sequence data between cloned ribosomal gene fragments from Taiwan Taenia (pTTr 3.1) and T. saginata (pTSgr 3.1 and PTSgr 2.4, respectively) suggest close evolutionary relatedness between these two taeniids. DNA sequence amplification from genomic DNA using oligonucleotide primers homologous to regions on both the 2.4- and 3.1-kb fragments was able to delineate between Taiwan Taenia and T. saginata by generating 1.0- and 0.29-kb fragments, respectively. Results demonstrated that Taiwan Taenia is not exclusive to Taiwan but exists in other parts of Eastern Asia and that adult morphology is insufficient for its detection in other locations. Results further support biological data indicating that Taiwan Taenia and T. saginata, although similar morphologically, are distinct genotypes.     

Two strands of DNA are not equivalent as probes in hybridizations at low stringency

Only one of the two complementary strands of a restriction fragment hybridizes under low stringency conditions to a cloned Arabidopsis thaliana genomic DNA fragment. We propose that this effect is caused by the energetic nonequivalence of the two possible mismatched duplexes, resulting from the accumulation of mismatches and extrahelical bases. These mismatches will differ between the two duplexes. The choice of probe strand may therefore be important for the success of heterologous hybridizations utilizing single-stranded probes.     

Genomic RFLP Analysis of Meloidogyne arenaria Race 2 Populations

Traditional morphological methods of Meloidogyne identification have been unsuccessful in distinguishing three South Carolina, USA Meloidogyne arenaria race 2 populations—Govan, Pelion, and Florence. These populations differ greatly in reproductive rate and aggressiveness on soybean hosts. Total genomic DNA from eggs of each population was digested with the restriction endonuclease Eco RI and Southern hybridization analyses were performed with single-copy and interspersed multi-copy cloned probes. Probes were isolated from a genomic library of Eco RI, M. arenaria DNA fragments cloned into pUC8. One probe, designated pE1.6A, when hybridized to Southern blots of M. arenaria genomic DNAs, displayed an interspersed repetitive pattern, and the RFLPs distinguished the Govan population from the Pelion and Florence populations. Another clone, pE6.0A, carrying moderately repeated sequences, distinguished the Pelion and Florence isolates. This communication demonstrates the utility of genomic RFLP analysis for distinguishing populations of the same race within the same species. To test the possible utility of these moderately repeated sequence probes for detecting the presence of nematode DNA in DNA samples from roots inoculated with varying numbers of nematodes, dot blot hybridization analyses were performed. It is possible to detect as few as 30 nematodes per root sample with these cloned probes.     

Asymmetric transcription of mouse mammary tumor virus genes in vivo and in vitro

Mouse mammary tumor virus (MMTV) DNA fragments were cloned into M13 bacteriophage, and the single-stranded recombinant phage DNAs were used as strand-specific nucleic acid hybridization probes to measure synthesis of plus (genomic) and minus strands of MMTV RNA in cultured cell lines and in cell-free preparations of nuclei. Pulse-labeling studies showed that synthesis of MMTV RNA in three different cell lines was highly asymmetric. In nuclear preparations from a cloned line of MMTV-infected rat hepatoma cells, elongation of nascent MMTV RNA chains and initiation of new MMTV RNA chains with nucleoside (beta-S)triphosphates were also highly asymmetric.     

The analysis of some new Drosophila repetitive DNA sequences isolated and cloned from two-dimensional agarose gels

Drosophila melanogaster DNA (Dm) was sequentially cleaved by BamHI and EcoRI and separated by two-dimensional gel electrophoresis. Six different prominent bands, which are derived primarily from the cleavage of long sequences that are repeated 20-100 times per genome, were recovered from the gel and cloned in pBR322. Hybridization and restriction analysis of the cloned Dm segments showed that three of these bands are mainly derived from the ribosomal and histone gene repeating units. Segments cloned from the other three bands are not homologous to any known repeating elements that we have tested. They represent long repetitive sequences of moderate multiplicity that appear not to have been hitherto described. These segments have been restriction-mapped and hybridized to cDNA prepared from poly(A)RNA from adult flies. While two minority segments did hybridize to this probe, the majority failed to hybridize. The arrangement of genomic sequences homologous to each plasmid was tested by restriction analysis and Southern hybridization. The results indicate that the repetitive element is largely conserved intact although occupying numerous different positions in the genome. The DNAs from four different strains of D. melanogaster and two of D. simulans produced restriction patterns having some segment lengths in common and some showing clear differences, a fact that indicates that these sequences can move about to occupy different genomic locations in different strains.     

Sensitive detection of RNA using strand-specific M13 probes

We have extended the method of Hu and Messing (Gene 17 (1982) 271-277) to prepare highly radioactive M13 probes suitable for use in RNA-DNA hybridization experiments. Single strands of M13 DNA carrying cloned sequences are rendered partially double-stranded by primed synthesis using a synthetic oligonucleotide primer complementary to a region 5' to the cloning site. The newly synthesized radioactive complementary strand is then covalently cross-linked to the M13 phage DNA by UV irradiation in the presence of 4,5,8-trimethylpsoralen (trioxsalen). Since the cross-linked probe is stable to heat denaturation, and the region of cloned sequence is kept single-stranded, these complexes may be used as strand-specific hybridization probes to detect RNA sequences under conditions which would denature DNA-DNA duplexes.     

Cloning and characterization of the ribosomal genes of the sea-urchin Paracentrotus lividus. Heterogeneity of the multigene family

A Paracentrotus lividus genomic library was constructed using sperm DNA prepared from a single animal. The DNA was fragmented by partial digestion with DNase II, sized on a preparative agarose gel and inserted in the Pst I site of pBR 322 by the dG X dC tailing method. Recombinant plasmids containing ribosomal DNA were isolated, a restriction map of the gene was determined and the 18S and 26S transcribed sequences were located by S1 protection mapping. The organization of the ribosomal genes in genomic DNA of individual animals and of a pool of animals was studied by blot-hybridization of the restriction fragments, using as probes nick-translated 32P-labelled cloned ribosomal DNA fragments or 18S and 26S sea-urchin ribosomal RNA. The repeat length of the ribosomal unit was about 10.5 X 10(3) bases. A comparison of the restriction patterns of DNA from different animals showed a marked sequence heterogeneity in the spacer region of these genes. Variations of about 200 base pairs were detectable in the length of the spacer of some individuals.     

Characterization of a spontaneous mutation to a beta-thalassemia allele.

We have studied a nuclear family containing a single child with severe beta-thalassemia intermedia, a Greek-Cypriot mother with hematological findings of beta-thalassemia trait, and a Polish father who is hematologically normal. Since both the child and her father were heterozygous for a DNA polymorphism within the beta-globin gene, it was possible to clone and sequence the beta-globin gene identical by descent from both the child and her father. A nonsense mutation in codon 121 (GAA----TAA) was found in the beta-globin gene of the child, while the same gene from her father lacked this mutation and was normal. This mutation has not been previously observed among over 200 beta-thalassemia genes characterized in Caucasians. Since the mutation eliminates an EcoRI site in the beta-globin gene, we could show that the mutation is not present in genomic DNA of the father. To rule out germinal mosaicism, sperm DNA of the father was also digested with EcoRI, and the mutant EcoRI fragment was not observed under conditions that would detect the mutation if it were present in at least 2% of sperm cells. Routine HLA and blood group testing supported stated paternity. In addition, studies with 17 DNA probes that detect multiple allele polymorphisms increased the probability of stated paternity to at least 10(8):1. These data provide evidence that the G----T change in codon 121 of the beta-globin gene in the child is the result of a spontaneous mutation that occurred during spermatogenesis in a paternal germ cell.     

Discrimination among the human beta A, beta S, and beta C-globin genes using allele-specific oligonucleotide hybridization probes.

Synthetic nonadecanucleotides complementary to the human beta A-, beta S-, or beta C-globin sequences were used as hybridization probes to screen human genomic DNA samples for these genes. The oligonucleotides were 32P-labeled and used as probes to genotype restriction endonuclease digests of human genomic DNA. The data obtained show that hybridization with oligonucleotide probes, unlike restriction fragment length polymorphism (RFLP) analysis or direct restriction enzyme digestion, can be used to directly distinguish among the three alleles of beta-globin, beta A, beta S, and beta C, when present either in one (heterozygous) or two copies.     

Detection of DNA sequence polymorphisms in human genomic DNA by using denaturing gradient gel blots.

Denaturing gradient gel electrophoresis can detect sequence differences outside restriction-enzyme recognition sites. DNA sequence polymorphisms can be detected as restriction-fragment melting polymorphisms (RFMPs) in genomic DNA by using blots made from denaturing gradient gels. In contrast to the use of Southern blots to find sequence differences, denaturing gradient gel blots can detect differences almost anywhere, not just at 4-6-bp restriction-enzyme recognition sites. Human genomic DNA was digested with one of several randomly selected 4-bp recognition-site restriction enzymes, electrophoresed in denaturing gradient gels, and transferred to nylon membranes. The blots were hybridized with radioactive probes prepared from the factor VIII, type II collagen, insulin receptor, beta 2-adrenergic receptor, and 21-hydroxylase genes; in unrelated individuals, several RFMPs were found in fragments from every locus tested. No restriction map or sequence information was used to detect RFMPs. RFMPs can be used as genetic markers, because their alleles segregate in a Mendelian manner. Unlike most other methods for detecting DNA sequence polymorphisms, a genomic DNA blot made from one gel can be hybridized consecutively with many (30 or more) different probes.     

Amplification and characterization of a beta-globin gene synthesized in vitro.

Full-length, double-stranded globin DNA was synthesized in vitro starting from rabbit globin mRNA. Several restriction endonuclease cleavage sites with known recognition sequences were mapped on this DNA as a means of assessing the accuracy of in vitro synthesis. By comparing this map with the nucleotide sequences known or predicted from the amino acid sequences of alpha-and beta-chain rabbit hemoglobin, it was possible to show that the synthetic globin DNA is a faithful copy of beta-globin mRNA. Amplification of the synthetic globin DNA was achieved by inserting the molecule into the plasmid PMB9 using the poly(dA)-(dT) joining procedure, and transforming E. coli with the hybrid DNA. Transformants carrying beta-globin DNA were identified by colony hybridization using purified 125I-beta-mRNA probe. Comparison of the restriction maps of the synthetic and inserted globin DNAs showed that the entire synthetic globin DNA molecule was amplified without sequence rearrangements. Both the synthetic and the cloned DNA include the entire coding sequence of the beta-globin gene plus a substantial portion of the untranslated regions flanking the structural gene.     

Hybridization of synthetic oligodeoxyribonucleotides to phi chi 174 DNA: the effect of single base pair mismatch.

Oligodeoxyribonucleotides complementary to the DNA of the wild type (wt) bacteriophage phi chi 174 have been synthesized by the phosphotriester method. The oligomers, 11, 14, and 17 bases long, are complementary to the region of the DNA which accounts for the am-3 point mutation. When hybridized to am-3 DNA, the oligonucleotides form duplexes with a single base pair mismatch. The thermal stability of the duplexes formed between wt and am-3 DNAs has been measured. The am-3 DNA:oligomer duplexes dissociate at a temperature about 10 degrees C lower than the corresponding wt DNA:oligomer duplexes. This dramatic decrease in thermal stability due to a single mismatch makes it possible to eliminate the formation of the mismatched duplexes by the appropriate choice of hybridization temperature. These results are discussed with respect to the use of oligonucleotides as probes for the isolation of specific cloned DNA sequences.     

General method for cloning amplified DNA by differential screening with genomic probes.

Mutant Syrian hamster cell lines resistant to N-(phosphonacetyl)-L-aspartate, a potent and specific inhibitor of aspartate transcarbamylase, have amplified the gene coding for the multifunctional protein (CAD) that includes this activity. The average amount of DNA amplified is approximately 500 kilobases per gene copy, about 20 times the length of the CAD gene itself. A differential screening method which uses genomic DNAs as probes was developed to isolate recombinant phage containing fragments of amplified DNA. One probe was prepared by reassociating fragments of total genomic DNA from 165-28, a mutant cell line with 190 times the wild-type complement of CAD genes, until all of the sequences repeated about 200 times were annealed and then isolating the double-stranded DNA with hydroxyapatite.This DNA was highly enriched in sequences from the entire amplified region, whereas the same sequences were very rare in DNA prepared similarly from wild-type cells. After both DNAs were labeled by nick translation, highly repeated sequences were removed by hybridization to immobilized total genomic DNA from wild-type cells. A library of cloned DNA fragments from mutant 165-28 was screened with both probes, and nine independent fragments containing about 165 kilobases of amplified DNA, including the CAD gene, have been isolated so far. These cloned DNAs can be used to study the structure of the amplified region, to evaluate the nature of the amplification event, and to investigate gene expression from the amplified DNA. For example, one amplified fragment included a gene coding for a 3.8-kilobase, cytoplasmic, polyadenylated RNA which was overproduced greatly in cells resistant to N-(phosphonacetyl)-L-aspartate. The method for cloning amplified DNA is general and can be used to evaluate the possible involvement of gene amplification in phenomena such as drug resistance, transformation, or differentiation. DNA fragments corresponding to any region amplified about 10-fold or more can be cloned, even if no function for the region is known. The method for removing highly repetitive sequences from genomic DNA probes should also be of general use.     

Strategies for detecting restriction polymorphisms of Y chromosome sequences

Six cloned genomic sequences from the human Y chromosome were used for the detection of restriction polymorphisms in a panel of unrelated DNAs. Three sorts of strategies for the detection of polymorphisms were used: (a) mixing individual DNAs restricted by several endonucleases, (b) separated restrictions of the DNA library members with six different restriction enzymes, (c) individual DNA digestion with TaqI and MsqI. Results show that restriction polymorphisms are detected only rarely; this result can be explained by exemption of most of the Y chromosome from meiotic pairing and exchange.