Optimization of PCR and electrophoresis conditions enhances mutation analysis of the BRCA1 gene

Gel-based nonradioactive single-strand conformational polymorphism and mutation detection: limitations and solutions

Single-strand conformation polymorphism (SSCP) for screening mutations/single-nucleotide polymorphisms (SNPs) is a simple, cost-effective technique, saving an expensive exercise of sequencing each and every polymerase chain reaction product and assisting in choosing only the amplicons of interest with expected mutations. The principle of detection of small changes in DNA sequences is based on changes in single-strand DNA conformations. The changes in electrophoretic mobility that SSCP detects are sequence dependent. The limitations faced in SSCP range from routine polyacrylamide gel electrophoresis (PAGE) problems to the problems of resolving mutant DNA bands. Both these problems can be solved by controlling PAGE conditions and by varying physical and environmental conditions such as pH, temperature, voltage, gel type and percentage, addition of additives or denaturants, and others. Despite much upgrading of the technology for mutation detection, SSCP remains the method of choice to analyze mutations and SNPs in order to understand genomic variations, both spontaneous and induced, and the genetic basis of diseases.

Association of an exonic LDHA polymorphism with altered respiratory response in probands at high risk for panic disorder

Panic disorder (PD) is a clinical syndrome characterized by recurrent discrete episodes of fear accompanied by a variety of physiological and psychological symptoms, often with prominent respiratory components. A series of clinical observations has led some investigators to hypothesize that subtle alterations in ventilatory regulation are integral to at least a subtype of PD. In order to identify genetic factors that might predispose individuals to these alterations in ventilatory response, we conducted single stranded conformation polymorphism analysis across the exons of the lactate dehydrogenase A and B genes (LDHA and LDHB) using DNA prepared from 86 subjects previously characterized by respiratory response to a CO(2) challenge with a variable genetic loading for PD. Remarkably, a single conserved LDHA exon 5 haplotype conferred increased risk for a paradoxical ventilatory response pattern to CO(2) inhalation which robustly separated well subjects at high risk for PD from low-risk control subjects. But, comparison of LDHA exon 5 genotypes in PD probands (n = 25) to that of random newborn controls (n = 182) did not demonstrate any significant differences. Given the pivotal role of LDH in the metabolism of lactate, a known inducer of panic attacks, and the dependence of LDH activity on cell pH, we suggest that LDHA polymorphisms may contribute to the variability to CO(2) respiratory challenge.

Restriction endonuclease fingerprinting enhanced conformation sensitive gel electrophoresis (REF-CSGE) in the analysis of BRCA1 exon 11 mutations in a high-risk breast cancer cohort

Efficient genetic analysis of large exonic regions containing heterozygous mutations and common polymorphisms can be difficult. We have analyzed 30 patients for inherited susceptibility mutations (ISM) within exon 11 of the BRCA1 gene as part of an ongoing genetic epidemiological study of high-risk breast cancer (HRBC). A novel combination of restriction endonuclease fingerprinting (REF) and conformation sensitive gel electrophoresis (CSGE) was developed for rapid and efficient screening of mutations. This method (REF-CSGE) was compared side-by-side with standard CSGE and evaluated for both efficiency and sensitivity of detection. REF-CSGE detected 100% of the alterations found by CSGE. However, one variant was only detectable by REF-CSGE. All samples with variant bands were sequenced to confirm the nature of the alteration. In total, two small deletions (frameshifts) and 62 point mutations (60 known polymorphisms and two variants of unknown significance) were found in our cohort. The majority of the exon 11 polymorphisms detected are inherited as a linked haplotype. Point mutations that comprise these haplotypes could be simultaneously detected on a single gel by REF-CSGE, thereby decreasing the number of sequencing reactions necessary to elucidate heteroduplex patterns seen on CSGE gels. An analysis of the overall efficiency of both techniques revealed that REF-CSGE required 67% fewer confirmatory sequencing reactions, resulting in savings in both reagents and technician time.

Ovarian cancer BRCA1 mutation detection: Protein truncation test (PTT) outperforms single strand conformation polymorphism analysis (SSCP)

Recent studies have shown that the BRCA1 tumor suppressor gene plays a role in the development of both hereditary and sporadic ovarian cancer. Since several different mechanisms may give rise to tumor gene defects, a better understanding of these mechanisms may identify BRCA1 as an attractive therapeutic target in ovarian cancer. Sequencing this large gene is not practical on a population-wide basis. The optimal screening strategy is yet to be determined. The purpose of our study is to compare two common screening techniques: the protein truncation test (PTT) and single strand conformational polymorphism analysis (SSCP). Ninety-four patients with epithelial ovarian cancer and available snap-frozen tissue were screened for BRCA1 mutations by both PTT (five individual PCR reactions with complete translation of the product in the TNT System (Promega, Madison, WI)) and SSCP (41 individual PCR reactions covering the entire coding sequence). All abnormal results were confirmed by sequencing. A paired peripheral blood DNA sample was utilized to determine if the sequence abnormality was a germline mutation. Twenty-three mutations in BRCA1 were found in 22 patients (14 germline, eight somatic, one unknown) including four novel mutations: E489X, 3558delT, 3871delGTCT, del exon 7-10. Although the predictive value of a negative test was close for the two methods (PTT 99.1%, SSCP 99.8%), the comparison of positive predictive value overwhelmingly favored PTT (100.0%, vs. 26.4%, respectively). The specificity for PTT was 100.0% while the sensitivity was 82.6%. While for SSCP, the specificity was 99.0% and the sensitivity was only 60.9%. The concordance rate for the two screening tests was 88.9%. Only SSCP can detect missense mutations. PTT is a superior screening test for truncating BRCA1 mutations that are expected to be of clinical significance.

Mutation analysis of the EMX2 gene in Kallmann's syndrome

OBJECTIVE

To investigate the possibility that a mutation in the human EMX2 gene may be involved in Kallmann's syndrome.

DESIGN

In vitro experiment.

SETTING

Academic Medical Center.

PATIENTS

One hundred and twenty patients with Kallman's syndrome or idiopathic hypogonadotrophic hypogonadism (IHH).

INTERVENTION

Peripheral blood leukocytes were used to obtain DNA.

MAIN OUTCOMES MEASURES

Single-stranded conformational polymorphism (SSCP) analysis was used to identify possible mutations of the EMX2 gene.

RESULTS

One hundred and twenty patients with Kallmann's syndrome or IHH, had no mutations noted in this gene.

CONCLUSION

It is unlikely that EMX2 mutations are a clinically significant cause of IHH or Kallman's syndrome.

BRCA1 mutations in familial ovarian cancer

BRCA1 mutation research in ovarian and breast cancer 17q21-linked families has yielded a large number of germline sequence variations. Somatic mutations have been uncommonly reported. We screened 81 probands with primary ovarian, peritoneal, or fallopian tube carcinoma for BRCA1 mutations. The study group was intentionally biased by the inclusion of 29 probands with a family history of ovarian and/or breast carcinoma, 13 probands diagnosed on or before age 45, seven individuals with a metachronous breast cancer and 51 tumors with BRCA1 LOH. Tumor and/or germline DNA was screened by modified techniques of single-strand confirmation polymorphism analysis, and abnormal banding patterns were sequenced to confirm mutations. Twenty-one (25.9%) BRCA1 sequence variations were identified. Eight mutations were somatic including seven null mutations. Apart from classical hereditary ovarian/breast cancer, a family history of ovarian/breast cancer defines a subset of ovarian cancer individuals with a significant likelihood of either a germline or a somatic BRCA1 gene sequence variation.

Association between nonrandom X-chromosome inactivation and BRCA1 mutation in germline DNA of patients with ovarian cancer

BACKGROUND

Most human female cells contain two X chromosomes, only one of which is active. The process of X-chromosome inactivation, which occurs early in development, is usually random, producing tissues with equal mixtures of cells having active X chromosomes of either maternal or paternal origin. However, nonrandom inactivation may occur in a subset of females. If a tumor suppressor gene were located on the X chromosome and if females with a germline mutation in one copy of that suppressor gene experienced nonrandom X-chromosome inactivation, then some or all of the tissues of such women might lack the wild-type suppressor gene function. This scenario could represent a previously unrecognized mechanism for development of hereditary cancers. We investigated whether such a mechanism might contribute to the development of hereditary ovarian cancers.

METHODS

Patterns of X-chromosome inactivation were determined by means of polymerase chain reaction amplification of the CAG-nucleotide repeat of the androgen receptor (AR) gene after methylation-sensitive restriction endonuclease digestion of blood mononuclear cell DNA from patients with invasive (n = 213) or borderline (n = 44) ovarian cancer and control subjects without a personal or family history of cancer (n = 50). BRCA1 gene status was determined by means of single-strand conformational polymorphism analysis and DNA sequencing. All statistical tests were two-sided.

RESULTS AND CONCLUSIONS

Among individuals informative for the AR locus, nonrandom X-chromosome inactivation was found in the DNA of 53% of those with invasive cancer versus 28% of those with borderline cancer (P = .005) and 33% of healthy control subjects (P = .016). Nonrandom X-chromosome inactivation can be a heritable trait. Nine of 11 AR-informative carriers of germline BRCA1 mutations demonstrated nonrandom X-chromosome inactivation (.0002 < P < .008, for simultaneous occurrence of both).

IMPLICATIONS

Nonrandom X-chromosome inactivation may be a predisposing factor for the development of invasive, but not borderline, ovarian cancer.