Constant denaturant gel electrophoresis, a modification of denaturing gradient gel electrophoresis, in mutation detection

Mutation screening of the TP53 gene by temporal temperature gel electrophoresis (TTGE)

A protocol for detection of mutations in the TP53 gene using temporal temperature gradient electrophoresis (TTGE) is described. TTGE is a mutation detection technique that separates DNA fragments differing by single base pairs according to their melting properties in a denaturing gel. It is based on constant denaturing conditions in the gel combined with a temperature gradient during the electrophoretic run. This method combines some of the advantages of the related techniques, denaturing gradient gel electrophoresis and constant denaturant gel electrophoresis, and eliminates some of the problems. The result is a rapid and sensitive screening technique which is robust and easily set up in smaller laboratory environments.

Analysis of mutational spectra by denaturing capillary electrophoresis

The point mutational spectrum over nearly any 75- to 250-bp DNA sequence isolated from cells, tissues or large populations may be discovered using denaturing capillary electrophoresis (DCE). A modification of the standard DCE method that uses cycling temperature (e.g., +/-5 degrees C), CyDCE, permits optimal resolution of mutant sequences using computer-defined target sequences without preliminary optimization experiments. The protocol consists of three steps: computer design of target sequence including polymerase chain reaction (PCR) primers, high-fidelity DNA amplification by PCR and mutant sequence separation by CyDCE and takes about 6 h. DCE and CyDCE have been used to define quantitative point mutational spectra relating to errors of DNA polymerases, human cells in development and carcinogenesis, common gene-disease associations and microbial populations. Detection limits are about 5 x 10(-3) (mutants copies/total copies) but can be as low as 10(-6) (mutants copies/total copies) when DCE is used in combination with fraction collection for mutant enrichment. No other technological approach for unknown mutant detection and enumeration offers the sensitivity, generality and efficiency of the approach described herein.

The human genomic melting map

In a living cell, the antiparallel double-stranded helix of DNA is a dynamically changing structure. The structure relates to interactions between and within the DNA strands, and the array of other macromolecules that constitutes functional chromatin. It is only through its changing conformations that DNA can organize and structure a large number of cellular functions. In particular, DNA must locally uncoil, or melt, and become single-stranded for DNA replication, repair, recombination, and transcription to occur. It has previously been shown that this melting occurs cooperatively, whereby several base pairs act in concert to generate melting bubbles, and in this way constitute a domain that behaves as a unit with respect to local DNA single-strandedness. We have applied a melting map calculation to the complete human genome, which provides information about the propensities of forming local bubbles determined from the whole sequence, and present a first report on its basic features, the extent of cooperativity, and correlations to various physical and biological features of the human genome. Globally, the melting map covaries very strongly with GC content. Most importantly, however, cooperativity of DNA denaturation causes this correlation to be weaker at resolutions fewer than 500 bps. This is also the resolution level at which most structural and biological processes occur, signifying the importance of the informational content inherent in the genomic melting map. The human DNA melting map may be further explored at http://meltmap.uio.no.

Cell cycle checkpoint signaling involved in histone deacetylase inhibition and radiation-induced cell death

In breast cancer, radiation has a central role in the treatment of brain metastasis, although tumor sensitivity might be limited. The tumor cell defense response to ionizing radiation involves activation of cell cycle checkpoint signaling. Histone deacetylase (HDAC) inhibitors, agents that cause hyperacetylation of histone proteins and thereby aberrations in the chromatin structure, may also override the DNA damage defense response and facilitate the radiation-induced mitotic cell death. In experimental metastasis models, the human breast carcinoma cell line MA-11 invariably disseminates to the central nervous system. We compared profiles of in vitro MA-11 cell cycle response to ionizing radiation and HDAC inhibition. After radiation exposure, the G2-M phase accumulation and the preceding repression of the G2 phase regulatory factors Polo-like kinase-1 and cyclin B1 required intact G2 checkpoint signaling through the checkpoint kinase CHK1, whereas the similar phenotypic changes observed with HDAC inhibition did not. MA-11 cells did not show radiation-induced expression of the G1 cell cycle inhibitor p21, indicative of a defective G1 checkpoint and consistent with a point mutation detected in the tumor suppressor TP53 gene. Increase in the p21 level, however, was observed with HDAC inhibition. Following pretreatment with the HDAC inhibitor, the efficiency of clonogenic regrowth after irradiation was reduced, which is in accordance with the concept of increased probability of mitotic cell death when the chromatin structure is disrupted. Among molecular cell cycle-targeted drugs currently in the pipeline for testing in early-phase clinical trials, HDAC inhibitors may have therapeutic potential as radiosensitizers.

DHPLC is superior to SSCP in screening p53 mutations in esophageal cancer tissues

Mutations of the p53 tumor-suppressor gene universally occur on exons 5-8 in human cancer. We analyzed these mutations in esophageal cancer tissue from 207 patients in China using 2 methods, single-strand conformation polymorphism (SSCP), one of the most frequently used methods, and the recently developed denaturing high-performance liquid chromatography (DHPLC), and compared their sensitivity and efficiency. Exons 5-8 of p53 were amplified from esophageal cancer tissue genomes, screened for fragments of mutations and polymorphisms by SSCP and DHPLC in a blind study and confirmed by direct sequencing to detect the mutations and polymorphisms. The numbers detected by DHPLC were greater than those detected by SSCP, though the rate of mutations and polymorphisms was lower in SSCP than in DHPLC, which appeared to detect smaller mutations (substitutions and 1 bp insertions/deletions). Of the mutations with substitutions detected by DHPLC but not by SSCP, 50% substituted adenosine for other nucleotides, suggesting that these mutations are often missed when SSCP is used. According to these data, the sensitivity of SSCP and DHPLC was 81% and 97%, respectively, and the specificity was 97% and 85%, respectively. Our results suggest that DHPLC may be recommended over SSCP when screening gene mutations. Thus, rates of p53 mutations and polymorphisms in esophageal cancer tissue in Chinese patients were 49% and 41% by DHPLC and SSCP, respectively.

Structural factors determining DNA length limitations in conformation-sensitive mutation detection methods

Numerous mutations and polymorphisms in human genes remain to be identified using reliable methods. Of the available mutation scanning methods those dependent on structural change-induced mobility shifts are highly effective. Their efficiency is, however, DNA length-sensitive and the reasons for that are poorly understood. In this study, we explain why scanning genes for mutations is less effective in longer DNA fragments, and reveal the factors which are behind this effect. We have performed a systematic analysis of the same sequence variants of exon 11 of the BRCA1 gene in DNA fragments of three different lengths using the combined single-strand conformation polymorphism (SSCP) and heteroduplex analysis (DA) by capillary electrophoresis (CE). There are two major structural factors responsible for the reduced mutation detection rate in long amplicons. The first is increased contribution from other secondary structure modules and domains in longer fragments, which mask the structural change induced by the mutation. The second is higher frequency of single-nucleotide polymorphisms (SNPs) including common polymorphisms in longer fragments. This makes it necessary to distinguish the structural effect of the mutation from that of each polymorphic variant, which is often difficult to achieve. Taking these factors into account, an efficient scanning of genes for sequence variants by conformation-sensitive methods may be performed.

Approach to analysis of single nucleotide polymorphisms by automated constant denaturant capillary electrophoresis

Melting gel techniques have proven to be amenable and powerful tools in point mutation and single nucleotide polymorphism (SNP) analysis. With the introduction of commercially available capillary electrophoresis instruments, a partly automated platform for denaturant capillary electrophoresis with potential for routine screening of selected target sequences has been established. The aim of this article is to demonstrate the use of automated constant denaturant capillary electrophoresis (ACDCE) in single nucleotide polymorphism analysis of various target sequences. Optimal analysis conditions for different single nucleotide polymorphisms on ACDCE are evaluated with the Poland algorithm. Laboratory procedures include only PCR and electrophoresis. For direct genotyping of individual SNPs, the samples are analyzed with an internal standard and the alleles are identified by co-migration of sample and standard peaks. In conclusion, SNPs suitable for melting gel analysis based on theoretical thermodynamics were separated by ACDCE under appropriate conditions. With this instrumentation (ABI 310 Genetic Analyzer), 48 samples could be analyzed without any intervention. Several institutions have capillary instrumentation in-house, thus making this SNP analysis method accessible to large groups of researchers without any need for instrument modification.

Identification of parental origin of cognate dsRNA genome segment(s) of rotavirus reassortants by constant denaturant gel electrophoresis

Rotaviruses are the single most important etiologic agents of severe diarrhea in infants and young children worldwide. They possess a triple capsid morphology and a genome of 11 segments of double-stranded (ds) RNA. During the course of the development of various live, attenuated reassortant rotavirus vaccines, we often experienced difficulty in identifying the parental origin of certain genome segment(s) of a reassortant vaccine candidate. Various assays have been utilized for determination of the parental origin of reassortant virus genes, including polyacrylamide gel electrophoresis (PAGE), DNA and/or RNA hybridization assays and gene sequence analysis. The traditional PAGE is simple and easy to perform, however, it is common to find that certain cognate dsRNA segment(s) cannot be differentiated by this assay due to a high degree of sequence homology among different rotavirus strains. Constant denaturant gel electrophoresis (CDGE) is one of several methods that have been used to screen DNA fragments for small sequence changes or point mutations. By using the CDGE, we were successful in partially denaturing rotavirus dsRNA thereby changing the physical properties of the genome segment(s) in the gel and thus differentiating the cognate genome segment(s) of rotavirus reassortants. The CDGE provides a simple and reliable assay system for identification of parental gene origins of a rotavirus reassortant.

High-efficiency DNA ligation for clamp attachment without polymerase chain reaction

We coupled ligation with mass action to achieve high-efficiency clamp attachment without polymerase chain reaction (PCR). Using a 10-fold molar excess of a GC-rich clamp of synthesized and hybridized oligonucleotides, we achieved the maximum clamp-ligation efficiency in which the clamp was ligated to >95% of 10(10)-10(12) restriction ends of a PCR-amplified fragment. The maximum efficiency was confirmed by ligating the clamp to 10(11)-10(12) restriction ends of human genomic DNA. Our approach can be added to a constant denaturant capillary electrophoresis (CDCE)-based method of analyzing rare point mutants at fractions as low as 10(-6); such mutants appear as small copy numbers in the initial samples. This CDCE-based method alone is applicable to only those DNA sequences juxtaposed with an internally occurring clamp of a higher melting temperature in genomic DNA. Since such sequences represent 9% of the human genome, the addition of clamp ligation significantly increases the scanning range for the human genome without reducing the initial mutant copy numbers. Furthermore, clamp ligation/attachment without PCR prevents PCR-created mutants from interfering with rare mutational analysis. In addition to those applications seeking high-efficiency DNA ligation, our approach can be generally applied to ligation of restriction ends.

BioMEMS using electrophoresis for the analysis of genetic mutations

Biomedical microelectromechanical systems (BioMEMS) are rapidly emerging in many areas of genetic analysis. These devices demonstrate potential for rapid analysis using modular components capable of sample purification, amplification, mutation discrimination and detection on small, portable point-of-care instruments. Here, various approaches to genetic mutation detection and the modern analysis platform, capillary electrophoresis, will be briefly reviewed. Microfluidic devices will be discussed in relation to fabrication techniques, mutation detection using simple electrophoretic separations, multiplexed designs and modular functionalities, as well as challenges and issues surrounding this technology.

Mutation detection in KRAS Exon 1 by constant denaturant capillary electrophoresis in 96 parallel capillaries

Mutations in KRAS exon 1 oncogene are frequently found in colon carcinomas. A correlation between the mutated KRAS and the prognosis and outcome of treatment of colon cancer patients was reported in the literature. The object of our work was to establish a high-throughput method with high sensitivity to enable screening of tumor mutation status of KRAS exon 1 in large groups of colon cancer patients. KRAS exon 1 sequences from DNA isolated from 191 sporadic colon cancers were PCR amplified using one primer labeled with fluorescein and a second primer extended by a GC-clamp. After PCR amplification samples were subjected to automated 96-array constant denaturant capillary electrophoresis using a modified MegaBACE 1000 sequencing instrument. Mutant samples were identified by characteristic peak patterns. The sensitivity of detection of a mutant allele in a background of the wild-type alleles was 0.3%. Using the 96-array instrument a typical screening of 191 samples for KRAS mutation status could be performed within 2 h. A KRAS exon 1 mutation was found in 66 of 191 (34.6%) of the samples. The 96-array constant denaturant capillary electrophoresis provides an opportunity for the high-sensitivity screening of large cancer populations for KRAS exon 1 mutations.

17Beta-estradiol is carcinogenic in human breast epithelial cells

The association found between breast cancer development and prolonged exposure to estrogen suggests that this hormone is of etiologic importance in the causation of this disease. In order to prove this postulate, we treated the immortalized human breast epithelial cells (HBEC) MCF-10F with 17beta-estradiol (E(2)) for testing whether they express colony formation in agar methocel, or colony efficiency (CE), and loss of ductulogenesis in collagen matrix, phenotypes also induced by the carcinogen benz[a]pyrene (BP). MCF-10F cells were treated with 0.0, 0.007, 70nM, or 0.25mM of E(2) twice a week for 2 weeks. CE increased from 0 in controls to 6.1, 9.2, and 8.7 with increasing E(2) doses. Ductulogenesis was 75 +/- 4.9 in control cells; it decreased to 63.7 +/- 28.8, 41.3 +/- 12.4, and 17.8 +/- 5.0 in E(2)-treated cells, which also formed solid masses or spherical formations lined by a multilayer epithelium, whose numbers increased from 0 in controls to 18.5 +/- 6.7, 107 +/- 11.8 and 130 +/- 10.0 for each E(2) dose. MCF-10F cells were also treated with 3.7 microM of progesterone (P) and the CE was 3.39 +/- 4.05. At difference of E(2), P does not impaired the ductulogenic capacity. Genomic analysis revealed that E(2)-treated cells exhibited loss of heterozigosity in chromosome 11, as detected using the markers D11S29 and D11S912 mapped to 11q23.3 and 11q24.2-25, respectively These results also indicate that E(2), like the chemical carcinogen BP, induces in HBEC phenotypes indicative of neoplastic transformation.

Carcinogenicity of estrogens in human breast epithelial cells

Epidemiological and clinical evidences indicate that breast cancer risk is associated with prolonged ovarian function that results in elevated circulating levels of steroid hormones. Principal among these is estrogen, which is associated with two important risk factors, early onset of menarche and late menopause. However, up to now there is no direct experimental evidence that estrogens are responsible of the initiation of human breast cancer. We postulate that if estrogens are causative agents of this disease, they should elicit in human breast epithelial cells (HBEC) genomic alterations similar to those exhibited by human breast cancers, such as DNA amplification and loss of genetic material representing tumor suppressor genes. These effects could result from binding of the hormone to its nuclear receptors (ER) or from its metabolic activation to reactive metabolites. This hypothesis was tested by treating with the natural estrogen 17beta-estradiol (E2) and the synthetic steroid diethylstilbestrol (DES) MCF-10F cells, a HBEC line that is negative for ER. Cells treated with the chemical carcinogen benzo (a) pyrene (BP) served as a positive control of cell transformation. BP-, E2-, and DES-treated MCF-10F cells showed increases in survival efficiency and colony efficiency in agar methocel, and loss of ductulogenic capacity in collagen gel. The largest colonies were formed by BP-treated cells, becoming progressively smaller in DES- and E2-treated cells. The loss of ductulogenic capacity was maximal in BP-, and less prominent in E2- and DES-treated cells. Genomic analysis revealed that E2- and DES-treated cells exhibited loss of heterozygosity in chromosomes 3 and 11, at 3p21, 3p21-21.2, 3p21.1-14.2, and 3p14.2 14.1, and at 11q23.3 and 11q23.1-25 regions, respectively. It is noteworthy that these loci are also affected in breast lesions, such as ductal hyperplasia, carcinoma in situ, and invasive carcinoma. Our data are the first ones to demonstrate that estrogens induce in HBEC phenotypic changes indicative of cell transformation and that those changes are associated with significant genomic alterations that might unravel new pathways in the initiation of breast cancer.

Identification of in vivo mutations in exon 5 of the human HPRT gene in a set of pooled T-cell mutants by constant denaturant capillary electrophoresis (CDCE)

Constant denaturant capillary electrophoresis (CDCE), based on co-operative DNA melting equilibria, has the resolving power to separate single nucleotide mutants from wild type sequences. We used this technique to study mutations in a 70-bp isomelting domain of the human HPRT gene, which included the entire exon 5 and its flanking splice donor and acceptor sites. Pooled samples of 6-thioguanine selected T-cell clones from 51 healthy donors representing a total of approximately 1000 individual HPRT mutants were analysed. Slow moving peaks from the heteroduplex part of the CDCE electropherograph were collected and subjected to a second round of PCR and CDCE analysis, followed by DNA sequencing. Five independent mutations were detected. Four were splicing errors; one insertion of CC and two G-->A transitions in the splice donor site of intron 5, and one G-->C transversion in the splice acceptor site of intron 4. The fifth mutation was a missense transversion, T389>G. A reconstruction experiment, in which DNA with known mutation was mixed with wild type DNA, showed the sensitivity of mutation detection to be better than 1:100 under the conditions used in this study. These results demonstrate the high sensitivity of the CDCE-method for mutation screening.

Constant denaturant gel electrophoresis (CDGE) in BRCA1 mutation screening

Screening for mutations in the breast and ovarian cancer susceptibility gene, BRCA1, is complicated by the wide spectrum of mutations found in this large gene. In the present study a constant denaturant gel electrophoresis (CDGE) mutation screening strategy was established for approximately 80% of the genomic coding sequence (exons 2, 11, 13-16, 20, 24). This strategy was applied to screen genomic DNA from 50 familial breast and/or ovarian cancer patients who had previously been examined for BRCA1 mutations by SSCP. A total of 14 carriers of 12 distinct disease-associated mutations and 7 carriers of 6 distinct rare substitutions leading to amino acid substitutions were identified. The SSCP failed to detect 40% of the different deletions/insertions (4/10) and 75% (6/8) of the different base substitutions leading to terminating codons or rare amino acid changes. SSCP did, however, identify one rare base substitution that could not be detected in the CDGE screening. To evaluate the CDGE mutation screening strategy further, 25 unrelated patients from Norwegian breast and/or ovarian cancer families were examined for BRCA1 mutations using a combined genomic DNA/cDNA approach covering the entire coding sequence of the gene. A total of six mutation carriers were detected, all of whom had cases of ovarian cancer in their families. Three patients from independent families carried an 1135insA mutation in exon 11, two others had a Gly484ter and an 1675delA mutation, respectively, and the sixth carried a splice mutation (5194-2 a-->c) causing deletion of exon 18. CDGE may become an efficient tool in diagnostic and population based screening for BRCA1 mutations.

Sequence-based analysis of enzymatically amplified DNA fragments by mutation detection techniques

The accurate analysis of molecular variation is important in a range of disciplines of parasitology. Although conventional DNA techniques have overcome some of the limitations of traditional approaches, some can be relatively expensive and/or cumbersome to use when large sample sizes require analysis, and some cannot accurately resolve or define nucleotide variation. Using selected examples of applications to parasites, Robin Gasser and Xingquan Zhu discuss some PCR-based mutation detection techniques and their advantages over conventional analytical methods.

Optimal Temperature Selection for Mutation Detection by Denaturing HPLC and Comparison to Single-Stranded Conformation Polymorphism and Heteroduplex Analysis

Background: Denaturing HPLC (DHPLC) is a semi-automated method for detecting unknown DNA sequence variants. The sensitivity of the method is dependent on the temperature at which the analysis is undertaken, the selection of which is dependent on operator experience. To circumvent this, software has been developed for predicting the optimal temperature for DHPLC analysis. We examined the utility of this software.

Methods: To maximize the relevance of our data for other investigators, we have screened 42 different amplimers from CFTR, TSC1, and TSC2. The samples consisted of 103 unique sequence heterozygotes and 126 wild-type homozygous controls.

Results: At the temperature recommended by the software, 96% (99 of 103) of heterozygotes and all of the wild-type controls were correctly classified. This compares favorably with sensitivities of 85% for single-stranded conformation polymorphism and 82% for gel-based heteroduplex analyses of the same fragments.

Conclusions: Software-optimized DHPLC is a highly sensitive method for mutation detection. However, where sensitivity >96% is required, our data suggest that in addition to the recommended temperature, fragments should also be run at the recommended temperature plus 2 °C.

Improved mutation detection in GC-rich DNA fragments by combined DGGE and CDGE

Denaturing gradient gel electrophoresis (DGGE) has proven to be a powerful pre-screening method for the detection of DNA variants. If such variants occur, however, in DNA fragments that are very rich in G and C, they may escape detection. To overcome this limitation, we tested a novel gel system which combines DGGE and constant denaturant gel electrophoresis (CDGE), as it might have the advantages of both methods. Indeed, this combination had the advantages of both methods, good separation of hetero-duplex molecules and prevention of total strand dissociation, and it proved successful in the detection of DNA variants in several GC-rich fragments.

Applications of constant denaturant capillary electrophoresis/high-fidelity polymerase chain reaction to human genetic analysis

Constant denaturant capillary electrophoresis (CDCE) permits high-resolution separation of single-base variations occurring in an approximately 100 bp isomelting DNA sequence based on their differential melting temperatures. By coupling CDCE for highly efficient enrichment of mutants with high-fidelity polymerase chain reaction (hifi PCR), we have developed an analytical approach to detecting point mutations at frequencies equal to or greater than 10(-6) in human genomic DNA. In this article, we present several applications of this approach in human genetic studies. We have measured the point mutational spectra of a 100 bp mitochondrial DNA sequence in human tissues and cultured cells. The observations have led to the conclusion that the primary causes of mutation in human mitochondrial DNA are spontaneous in origin. In the course of studying the mitochondrial somatic mutations, we have also identified several nuclear pseudogenes homologous to the analyzed mitochondrial DNA fragment. Recently, through developments of the means to isolate the desired target sequences from bulk genomic DNA and to increase the loading capacity of CDCE, we have extended the CDCE/hifi PCR approach to study a chemically induced mutational spectrum in a single-copy nuclear sequence. Future applications of the CDCE/hifi PCR approach to human genetic analysis include studies of somatic mitochondrial mutations with respect to aging, measurement of mutational spectra of nuclear genes in healthy human tissues and population screening for disease-associated single nucleotide polymorphisms (SNPs) in large pooled samples.

Application of constant denaturant capillary electrophoresis (CDCE) to mutation detection in humans

Constant denaturant electrophoresis is a DNA separation technique based on the principle of cooperative melting equilibrium. DNA sequences with distinct high and low melting domains can be utilized to separate and identify molecules differing by only one base pair in the lower melting domain. Combined with capillary gel electrophoresis and when coupled with high fidelity DNA amplification, this approach can detect mutants at a fraction of 10(-6). Modifications to the capillary electrophoretic system have also increased DNA loading capacity which allows for analysis of rare mutations in a large, heterogeneous population such as DNA samples derived from human tissues. Employment of this technology has determined the first mutational spectrum in human cells and tissues in a mitochondrial sequence without phenotypic selection of mutants.

Apoptosis and expression of Bax, Bcl-x, and Bcl-2 apoptotic regulatory proteins in colorectal carcinomas, and association with p53 genotype/phenotype

AIMS

Spontaneous apoptosis and expression of the apoptotic regulatory proteins Bax, Bcl-x, and Bcl-2 were investigated in 50 colorectal carcinomas. The p53 genotypes/phenotypes and BAX genotypes were also determined, and possible associations of these with apoptosis and/or with expression of the different apoptotic regulatory proteins were studied.

METHODS

Terminal deoxynucleotidyl transferase (TdT) mediated dUTP labelling of DNA fragments was used to detect apoptotic tumour cells in sections and peroxidase immunohistochemistry was used to assess protein expression. p53 genotype/phenotype was determined using constant denaturant gel electrophoresis/immunoblotting and bax genotype was determined using polymerase chain reaction based methods.

RESULTS

The distribution of tumour apoptotic indices was bimodal with a natural cut off at 1.0% (range, 0.0-5.4%); the median fraction of apoptotic tumour cells was 0.8%. Tumour apoptosis was not associated significantly with tumour DNA ploidy status. Normal mucosal tissue had less than 0.1% apoptotic cells. Staining intensities for Bax, Bcl-x, and Bcl-2 were strong; that is, equivalent to or greater than positive normal mucosal cells, in 11 of 50, 20 of 49, and 20 of 48 carcinomas. Frameshift mutations in the bax gene were detected in three of 42 tumours analysed, all of which were DNA diploid, and Bax protein expression in these tumours was absent or very low. Bax, Bcl-x, and Bcl-2 protein expression were not correlated with tumour apoptosis or tumour DNA ploidy status. p53 was expressed in 34 of 50 tumours and p53 gene mutations were detected in 22 of 29 p53 positive tumours analysed. Apoptosis was significantly lower in a greater number of p53 positive tumours than p53 negative tumours. In addition, Bcl-2 protein expression was significantly higher in a greater number of p53 positive tumours compared with p53 negative tumours. Bax and Bcl-x protein expression were not significantly associated with p53 phenotype/genotype.

CONCLUSIONS

The results indicate that acquisition of a p53 phenotype is associated with lower spontaneous apoptosis and higher expression of Bcl-2. The results also suggest that p53 is not a major determinant for Bax expression in colorectal carcinomas in vivo.

Strategies and applications of DNA level diagnosis in genetic diseases: past experiences and future directions

The development of technologies towards the detection of mutations represents one of the most important areas of molecular biology. It has played a pivotal role in the tremendous success of the elucidation of complex biological problems, including genetic diseases. Today, these proven and emerging technologies have become the basis of successful biological investigations. More importantly, they are expected to play a central role in medicine, particularly the diagnosis and prognosis of genetic diseases including genetic predispositions, the assessment of treatments including transplants and decisions on reproductive choices. In addition, these technologies hold the key to future breakthroughs. This review provides an up-to-date examination of the principles of genetic diseases, the theories behind current methods of genetic diagnosis and detection of mutations including strategies for modification and the development of future technologies as they impact on the practice of medicine and on society as a whole.

Association of p53 accumulation with TP53 mutations, loss of heterozygosity at 17p13, and DNA ploidy status in 273 colorectal carcinomas

The aim of this study was to establish an experimentally based cutoff level for assessing p53 immunoreactivity in colorectal tumors. The accumulation of p53 protein in 273 colorectal tumors was correlated with previously obtained data on TP53 mutation and loss of heterozygosity at two 17p13 loci in the same tumors. The monoclonal antibody PAb 1801 was used for p53 staining, and the results obtained by immunohistochemistry and immunoblotting were similar. Mutation analyses of exons 5-8 were performed using constant denaturant gel electrophoresis followed by sequencing. There were no statistically significant differences for any measured TP53 gene alteration between the group of tumors without p53-positive nuclei (n = 83) and the group with <5% positive nuclei (n = 58). The majority of mutations within these groups were deletions/insertions and nonsense mutations without p53 accumulation. Therefore, we assume that 5% p53-positive nuclei is the relevant cutoff level to assess TP53 damage in colorectal tumors. A prerequisite for this recommendation is optimal conditions for p53 protein detection. The parameters for p53 dysfunction were correlated to DNA aneuploidy measured by flow cytometry. TP53 mutations were significantly associated with DNA aneuploidy (P < 0.00001), and a nonrandom distribution of TP53 gene alterations among diploid (DI = 1), hyperdiploid (1.0 < DI < 1.3), and highly aneuploid (DI > 1.3) tumors indicates that DNA hyperdiploid tumors constitute a separate developmental entity different from tumors with gross aneuploidy.

Mutation analyses of KRAS exon 1 comparing three different techniques: temporal temperature gradient electrophoresis, constant denaturant capillary electrophoresis and allele specific polymerase chain reaction

Mutations in the KRAS gene is a key event in the carcinogenesis of many human cancers and may serve as a diagnostic marker and a target for therapeutic intervention. In this study we have applied three different techniques for mutation detection of KRAS exon 1 mutations: Allele specific polymerase chain reaction (AS-PCR), temporal temperature gradient electrophoresis (TTGE) and constant denaturant capillary electrophoresis (CDCE). Samples from 191 sporadic colon carcinomas were analyzed. AS-PCR were performed with oligonucleotides specific for know mutations in codon 12 and 13 of the KRAS gene. In TTGE analyses, linear ramping of the temperature were performed during electrophoresis in a constant denaturant gel. CDCE analyses were performed using fluorescin labeled PCR-products. Separation was achieved under constant denaturing conditions using high temperature in a gel-filled capillary followed by laser detection. A mutated KRAS gene was found in 42/191 (22.0%) of the samples using AS-PCR, in 62/191 (32.5%) using TTGE and in 66/191 (34.6%) of the samples using CDCE. In the TTGE and CDCE analyses the sequence of the mutant were determined by comparing the electrophoretic pattern to that of known mutations or by mixing the sample with known mutations prior to reanalysis. In a titration experiment mixing mutant and wild-type alleles prior to PCR, the sensitivity for mutation detection was shown to be 10(-2) for TTGE and under optimized conditions 10(-3) for CDCE.

Detecting single base substitutions, mismatches and bulges in DNA by temperature gradient gel electrophoresis and related methods

Temperature gradient gel electrophoresis (TGGE) and related methods can separate DNA fragments that differ by a single base pair or defect. This article describes the basic features of TGGE, and reviews the theoretical model of DNA unwinding and its ability to predict DNA mobility in a temperature gradient gel. Recent applications of TGGE and related methods that were directed at detecting point mutations, and evaluating the effects of single site defects are also reported.

Detection of sequence variation in parasite ribosomal DNA by electrophoresis in agarose gels supplemented with a DNA-intercalating agent

This study evaluated the use of a commercially available DNA intercalating agent (Resolver Gold) in agarose gels for the direct detection of sequence variation in ribosomal DNA (rDNA). This agent binds preferentially to AT sequence motifs in DNA. Regions of nuclear rDNA, known to provide genetic markers for the identification of species of parasitic ascarid nematodes (order Ascaridida), were amplified by polymerase chain reaction (PCR) and subjected to electrophoresis in standard agarose gels versus gels supplemented with Resolver Gold. Individual taxa examined could not be distinguished reliably based on the size of their amplicons in standard agarose gels, whereas they could be readily delineated based on mobility using Resolver Gold-supplemented gels. The latter was achieved because of differences (approximately 0.1-8.2%) in the AT content of the fragments among different taxa, which were associated with significant interspecific differences (approximately 11-39%) in the rDNA sequences employed. There was a tendency for fragments with higher AT content to migrate slower in supplemented agarose gels compared with those of lower AT content. The results indicate the usefulness of this electrophoretic approach to rapidly screen for sequence variability within or among PCR-amplified rDNA fragments of similar sizes but differing AT contents. Although evaluated on rDNA of parasites, the approach has potential to be applied to a range of genes of different groups of infectious organisms.

Ki-ras mutations and prognosis in colorectal cancer

A total of 191 colorectal adenocarcinomas, obtained from consecutive patients with a median follow-up of 6 years, were studied in order to evaluate the possible association of Ki-ras mutations with tumour stage, tumour differentiation and survival time. Resected full-cross tumour samples were screened for Ki-ras mutations in codons 12 and 13 using temporal temperature gradient gel electrophoresis (TTGE). Ki-ras mutations were detected in 62 (32%) of the samples. The most frequent mutation, observed in 21 samples, was from GGT to GAT changing glycine to aspartic acid in codon 12. The study did not show any association between Ki-ras mutations and Dukes' stage or tumour differentiation. Patients with Ki-ras mutations had a marginally shorter survival time (median 50 months) compared with patients without (median 59 months), but the difference was not statistically significant. The results indicate that Ki-ras gene mutations have no relevant prognostic importance in this cohort of colorectal cancer patients.

Different genetic pathways to proximal and distal colorectal cancer influenced by sex-related factors

Mutations in the k-ras and TP53 genes, as well as microsatellite instability (MIN), are frequent genetic alterations in colorectal carcinomas and represent 3 different mechanisms in the carcinogenic process. Both the incidence of colorectal cancer and the frequency of genetic alterations in such tumours have been related to different clinico-pathological variables, including age and gender of the patient and location of the tumour. A number of studies have also reported associations between different types of genetic alterations. We therefore wanted to explore the relationship between these genetic and clinico-pathological variables using multivariate analysis on material from 282 colorectal carcinomas. Three logistic regression models were constructed: 1) the presence of K-ras mutations was dependent on MIN and age and gender of patient, with an especially low frequency among younger males and in tumours with MIN (overall p = 0.0003); 2) the presence of TP53 mutations was only dependent on tumour location, with a positive association to cancers occurring distally (p = 0.002); and 3) the presence of MIN was dependent on age, gender and K-ras and TP53 mutations, as well as on tumour location. MIN was most frequent among younger male and older female patients, was rare in tumours with K-ras or TP53 mutations and was found almost exclusively in the proximal colon (overall p < 0.0001). Our data confirm that different genetic pathways to colorectal cancer dominate in the proximal and distal segments of the bowel and suggest that the K-ras- and MIN-dependent pathways are influenced by different sex-related factors.

Mitochondrial mutational spectra in human cells and tissues

We have found that human organs such as colon, lung, and muscle, as well as their derived tumors, share nearly all mitochondrial hotspot point mutations. Seventeen hotspots, primarily G --> A and A --> G transitions, have been identified in the mitochondrial sequence of base pairs 10,030-10,130. Mutant fractions increase with the number of cell generations in a human B cell line, TK6, indicating that they are heritable changes. The mitochondrial point mutation rate appears to be more than two orders of magnitude higher than the nuclear point mutation rate in TK6 cells and in human tissues. The similarity of the hotspot sets in vivo and in vitro leads us to conclude that human mitochondrial point mutations in the sequence studied are primarily spontaneous in origin and arise either from DNA replication error or reactions of DNA with endogenous metabolites. The predominance of transition mutations and the high number of hotspots in this short sequence resembles spectra produced by DNA polymerases in vitro.

Mutation scanning methods for the analysis of parasite genes

Molecular variation is widespread in parasite populations, and its analysis has important implications for studying aspects relating to the function and organisation of genes, and the taxonomy, phylogeny and population genetics of parasites. This article reviews some PCR-based mutation scanning techniques that have advantages over currently used DNA methods for the analysis of genetic variation in parasites. The review is technical and describes briefly the principles of relevant techniques, examines some of their advantages and disadvantages and gives several examples for possible applications.

Genotypic selection methods for the direct analysis of point mutations

Genotypic selection enriches a particular DNA sequence relative to another closely-related DNA sequence based only on a change of one or a few bases. This review is a survey of the genotypic selection methods that have the sensitivity to detect rare point mutations. These methods are primarily being used to study mutations caused by environmental mutagens; however, the ability to detect and measure very minor DNA sequence populations is likely to further research efforts in many fields. The approaches for allele-selection have intrinsic strengths and weaknesses, and vary greatly in sensitivity. The most sensitive method is Restriction Fragment Length Polymorphism/Polymerase Chain Reaction (RFLP/PCR) by which mutant fractions as low as 1 mutant allele in 10(8) wild-type alleles can be detected. The RFLP/PCR approach is presented as a prototype genotypic selection method. Genotypic selection methods are categorized in terms of those that (1) selectively destroy the abundant or wild-type allele, (2) selectively amplify the rare or mutant allele, or (3) spatially separate the alleles. Issues relevant to the further development of genotypic selection methods include initial DNA pool size, strategies to eliminate the bulk of extraneous DNA, the use of an internal copy number standard in quantitative PCR, the fidelity of thermostable DNA polymerases, and the effective use of PCR in linking two or more genotypic selection techniques. We conclude that proficient genotypic selection requires more than one allele-enrichment technique with at least one of these preceding a high-fidelity PCR amplification step.

Mutational spectrometry without phenotypic selection: human mitochondrial DNA

By first separating mutant from nonmutant DNA sequences on the basis of their melting temperatures and then increasing the number of copies by high-fidelity DNA amplification, we have developed a method that allows observation of point mutations in biological samples at fractions at or above 10-6. Using this method, we have observed the hotspot point mutations that lie in 100 base pairs of the mitochondrial genome in samples of cultured cells and human tissues. To date, 19 mutants have been isolated, their fractions ranging from 4x10-4 down to the limit of detection. We performed specific tests to determine if the observed signals were artefacts arising from contamination, polymerase errors during PCR or DNA adducts created during the procedure. We also tested the possibilities that DNA replication mismatch intermediates, or endogenous DNA adducts that were originally present in the cells, were included with true mutants in our separation steps and converted to mutants during PCR. We show that while most of the mutants behave as double-stranded point mutants in the cells, some appear to arise at least in part from mismatch intermediates or cellular DNA adducts. This technology is therefore sufficient for the observation of the spectrum of point mutations in human mitochondrial DNA and is a tool for discovering the primary causes of these mutations.

TP53 protein accumulation and gene mutation in relation to overexpression of MDM2 protein in ovarian borderline tumours and stage I carcinomas

Three hundred and seventy-four early-stage ovarian tumours, including 27 borderline tumours and 347 stage I carcinomas, were investigated immunohistochemically for overexpression of the TP53 and MDM2 proteins. TP53 (p53) and MDM2 alterations were detected in 15 and 4 per cent of borderline tumours, and in 50 and 13 per cent of stage I carcinomas, respectively. Mutations in the TP53 gene (exons 5-8) were demonstrated in 29 of the 50 stage I carcinomas studied, using denaturing gel electrophoresis followed by direct sequencing. TP53 overexpression was seen less often in tumours of mucinous and endometrioid type than in tumours of other histological types and more often in moderately and poorly differentiated than in well differentiated tumours. MDM2 protein overexpression was seen more often in clear cell carcinoma than in tumours of other histological types. These results indicate that TP53 abnormalities play a crucial role, and MDM2 abnormalities a minor role, in the development of early-stage ovarian carcinoma. There was no significant association between TP53 or MDM2 alterations and survival in multivariate analysis.

Benign and malignant thyroid lesions show instability at microsatellite loci

Forty-six benign and malignant tumours and tumour-like lesions of the thyroid were analysed for microsatellite instability (MI) at eight loci, mapping to four different chromosomes, 7 lesions (15%) displayed MI at one or more loci, including 2/13 nodular goitres, 2/15 follicular adenomas, 2/12 papillary carcinomas and 1/4 follicular carcinomas. Two benign and one malignant lesion among the seven unstable cases exhibited this phenotype at three or more loci. We found no mutations in the mismatch repair gene, hMSH2, in the seven affected cases, after screening all the exons by CDGE mutation analysis. At variance with the data on record, these results indicate that, despite being relatively infrequent, MI does occur not only in thyroid carcinomas but also in benign lesions (goitres and follicular adenomas of the thyroid).

Efficiency of separation of DNA mutations by constant denaturant capillary electrophoresis is controlled by the kinetics of DNA melting equilibrium

Constant denaturant capillary electrophoresis (CDCE) separation takes place in the heated portion of the capillary where faster-moving, unmelted DNA fragments are in equilibrium with slower-moving, partially melted forms. Within a certain temperature range, the position of the melting equilibrium and thus the average electrophoretic mobility of each mutant is different. The resulting differences in mobility allow sequences containing single base pair point mutations to be separated from each other. We report the results of experiments in which we explored the rules defining separation efficiency by varying the parameters of CDCE. We discovered an unusual peak broadening mechanism. In contrast to most other DNA electrophoresis systems, peak width in CDCE steadily decreases with the square root of the separation speed. Moreover, the peak width displays a sharp maximum at a specific temperature. To account for these observations, we use a model which describes CDCE separation as a random walk. According to this model, peaks in CDCE are broad because the kinetics of the melting equilibrium are slow and therefore the number of random walk steps represented by melting/renaturation transitions is relatively small. In addition to providing a satisfactory interpretation of the data, the model also predicts that separation efficiency will increase as the ionic strength of the running buffer is increased and as the concentration of denaturant in the buffer is decreased. These predictions were verified and were used to establish conditions for high-resolution CDCE suitable for separating complex mixtures of single base pair mutants.

Use of wide-bore capillaries in constant denaturant capillary electrophoresis

A serious limitation of capillary electrophoresis in separating mutant from wild-type DNA sequences is the amount of DNA which may be loaded on narrow-bore columns. Because we sought to examine mutant sequences derived from more than 10(9) human cells, we were obliged to overcome this limitation. Thus we examined the feasibility of using wide-bore capillaries of 250, 320 and 540 microns in constant denaturant capillary electrophoresis (CDCE) using conditions which successfully limited the effect of Joule heating. Excellent separations were observed using the wide-bore capillaries comparable to those obtained using a 75 microns capillary. DNA loading capacities were increased almost 100-fold as the bore of capillary increased from 75 to 540 microns.

Laboratory probing of oncogenes from human liquid and solid specimens as markers of exposure to toxicants

Recent discoveries regarding the mechanistic role of oncogenes and tumor suppressor genes in cancer development have opened a new era of molecular diagnosis. It has been observed repeatedly that genetic lesions serve as tumor markers in a broad variety of human cancers. The ras gene family, consisting of three related genes, H-ras, K-ras, and N-ras, acquires transforming activity through amplification or mutation in many tissues. If not all, then most types of human malignancies have been found to contain an altered ras gene. Because the ras oncogenes actively participate in both early and intermediate stages of cancer, several highly specific and sensitive approaches have been introduced to detect these genetic alterations as biomarkers of exposure to carcinogens. There is also mounting evidence that implicate chemical-specific alterations of the p53 tumor suppressor gene detected in most human tumors. Therefore, it seems a reliable laboratory approach to identify both altered p53 and ras genes as biomarkers of human chronic or intermittent exposure to toxicants in a variety of occupational settings.

Comparative synchronous fluorescence spectrophotometry and 32P-postlabeling analysis of PAH-DNA adducts in human lung and the relationship to TP53 mutations

Polycyclic aromatic hydrocarbon (PAH)-DNA adducts were studied in human lung from 39 lung cancer patients by synchronous fluorescence spectrophotometric (SFS) and 32P-postlabeling assays. Regression analysis of the samples failed to detect any correlation between benzo[a]pyrene-diolepoxide (BPDE)-DNA adducts detected by SFS and the BPDE co-migrating spot detected by 32P-postlabeling. We have also analyzed the relationship between adduct levels and TP53 mutations. By postlabeling diagonal radioactive zone (DRZ) adducts were detected in 37 of 39 (95%) lung tissues from lung cancer patients and the adduct level ranged from 6.81 to 108.50 adducts/10(8) nucleotide. Thirty-three of 39 (85%) had detectable levels of BPDE-DNA adducts (> 1 adduct/10(9) nucleotide). Current heavy smokers (> 20 cigarettes/day) have significantly higher DRZ adduct levels compared to individuals smoking less than 20 cigarettes/day. By SFS combined with immunoaffinity column (IAC), 11 of 39 (28%) samples had detectable adduct levels, and 6 of 11 (55%) were detectable by SFS following purification of benzo[a]pyrene (BP)-tetrols by high pressure liquid chromatography (HPLC). Six of 33 (18%) samples were positive for BPDE-DNA adducts by both postlabeling and HPLC/SFS. No correlation was observed between the SFS and 32P-postlabeling assays for the detection of BPDE-DNA adducts. However, there was a good correlation between adduct levels detected by IAC/SFS and HPLC/SFS. We found a weak association between total PAH-DNA adduct levels in lung tissue and TP53 mutations.

Somatic mutation detection in human biomonitoring

Somatic cell gene mutation arising in vivo may be considered to be a biomarker for genotoxicity. Assays detecting mutations of the haemoglobin and glycophorin A genes in red blood cells and of the hypoxanthine-guanine phosphoribosyltransferase and human leucocyte antigenes in T-lymphocytes are available in humans. This MiniReview describes these assays and their application to studies of individuals exposed to genotoxic agents. Moreover, with the implementation of techniques of molecular biology mutation spectra can now be defined in addition to the quantitation of in vivo mutant frequencies. We describe current screening methods for unknown mutations, including the denaturing gradient gel electrophoresis, single strand conformation polymorphism analysis, heteroduplex analysis, chemical modification techniques and enzymatic cleavage methods. The advantage of mutation detection as a biomarker is that it integrates exposure and sensitivity in one measurement. With the analysis of mutation spectra it may thus be possible to identify the causative genotoxic agent.

Involvement of the pRb/p16/cdk4/cyclin D1 pathway in the tumorigenesis of sporadic malignant melanomas

Biopsies from 61 sporadic metastatic malignant melanomas and five melanoma cell lines were examined for homozygous deletions and mutations in the CDKN2 gene (p16). As the p16 protein is involved in a cell cycle regulatory pathway consisting of at least pRb, cdk4 and cyclin D1, the tumours were also screened for amplifications of the last two genes. Moreover, the transcript levels of the genes were determined and the results compared with the immunohistochemically assessed expression of pRb. Altogether, homozygous deletions of CDKN2 were found in seven tumours (11%) and two of five cell lines, whereas a mutation was detected in only one biopsy, indicating that in sporadic melanomas the former mechanism is predominant for inactivating this gene. Notably, in total 59% of the metastatic lesions lacked detectable expression of p16 mRNA, whereas all the biopsies were found to express pRb. In accordance with the postulated negative feedback loop between p16 and pRb, one melanoma cell line showed overexpression of CDKN2 mRNA together with very low levels of the Rb protein. Amplification of the other two genes may not be important in the tumorigenesis of melanomas, as only one CDK4 and no CCND1 amplification was observed. However, highly elevated CDK4 mRNA levels, compared with that seen in a panel of normal tissues, were observed in 76% of the tumours, accompanied in 71% of the cases by high expression of the CCND1 cyclin activator. Although a low frequency of CDKN2 DNA aberrations was observed, the high number of tumours that lacked CDKN2 expression but showed overexpression of CDK4 and/or CCND1, suggest that functional inactivation of pRb through this pathway may be involved in the development or progression of sporadic human melanomas.