Joy B Redman

Cystic fibrosis screening using the College panel: Platform comparison and lessons learned from the first 20,000 samples

Purpose: To determine the accuracy of two commercially available kits for cystic fibrosis (CF) genotyping and determine allele frequencies for the ACMG/ACOG recommended mutations.Methods: A total of 1,040 consecutive analyses using Roche CF Gold Strips and the ABI CF Genotyper were performed. Subsequently we performed analyses of 20,103 samples.Results: Both kits accurately determined CF genotypes. The I148T mutation was found >100 times more frequently in carrier screening than in CF patients. Asymptomatic patients were identified who are compound heterozygotes for delta F508 and I148T. Four of 13 patients heterozygous for delta F508 and the IVS8-5T polymorphism had some symptoms of CF.Conclusion: Accurate and timely analysis can be performed for the ACMG CF panel. I148T is a low penetrance CF allele.

Extensive sequencing of the cystic fibrosis transmembrane regulator gene: Assay validation and unexpected benefits of developing a comprehensive test

Purpose: To develop a sequencing assay for the CFTR gene to identify mutations in patients with cystic fibrosis (CF).Methods: An automated assay format was developed to sequence all exons and splice junctional sequences, the promotor region, and parts of introns 11 and 19.Results: After validating the assay using 20 known samples, DNA of seven patients, four of whom were heterozygous for a known CF mutation, was sequenced. Known CF mutations were detected in seven of the eight chromosomes, and a novel missense mutation was detected in the eighth. In addition, this assay allowed 14 ambiguous results obtained using the Roche CF gold strips to be resolved. Three false-positive diagnoses were prevented; a different mutation at the same codon was identified in two patients and confirmation was provided in the remaining nine cases.Conclusions: Sequencing of the CFTR gene provides important information for CF patients and is a valuable adjunct to a carrier screening program to resolve ambiguities in panel testing.

Molecular testing for Fragile X Syndrome: Lessons learned from 119,232 tests performed in a clinical laboratory

Purpose: To examine the data from over 119,000 Fragile X Syndrome tests and 307 prenatal tests to detect unsuspected findings and obtain clinical data when indicated to optimize genetic counseling.Methods: A proprietary database containing 119,232 consecutive postnatal and 307 prenatal FXS tests performed between November 2, 1992 and June 1, 2006 was queried.Results: The distribution of normal FMR1 alleles was a bimodal distribution with a major peak at 30 repeats and a minor peak at 21 repeats. Of 59,707 tests performed for males, 1.4% had a fully expanded and methylated FMR1 allele. Of 59,525 tests performed for females, 0.61% had an affected FMR1 allele, and 1.7% had a premutation FMR1 allele for a total carrier frequency of 1.3%. When fetuses inherited an expanded maternal allele, the risk of expansion to a full affected allele was 0%, 5%, 30% and 100% for allele sizes of <50, 50–75, 76–100 and >100 repeats, respectively.Conclusions: These figures can be used for genetic counseling of patients presenting for carrier detection and prenatal diagnosis for Fragile X Syndrome.

Novel and recurrent rearrangements in the CFTR gene: clinical and laboratory implications for cystic fibrosis screening

Because standard techniques used to detect mutations in the cystic fibrosis transmembrane conductance regulator (CFTR) gene do not detect single or multiple exonic rearrangements, the importance of such rearrangements may be underestimated. Using an in-house developed, single-tube, semi-quantitative fluorescent PCR (SQF PCR) assay, we analyzed 36 DNA samples submitted for extensive CFTR sequencing and identified ten samples with rearrangements. Of 36 patients with classic CF, 10 (28%) harbored various deletions in the CFTR gene, accounting for 14% of CF chromosomes. A deletion encompassing the CFTR promoter and exons 1 and 2 was detected in a sample from one proband, and in the maternal DNA as well. In another family, a deletion of the promoter and exon 1 was detected in three siblings. In both of these cases, the families were African American and the 3120+1G>A splice site mutation was also identified. These promoter deletions have not been previously described. In a third case, a deletion of exons 17a, 17b, and 18 was identified in a Caucasian female and the same mutation was detected in the paternal DNA. In the other seven cases, we identified the following deletions: exons 2 and 3 (n=2); exons 4, 5, and 6a; exons 17a and 17b; exons 22 and 23; and exons 22, 23, and 24 (n=2). In our series, the frequency of CFTR rearrangements in classic CF patients, when only one mutation was identified by extensive DNA sequencing, was >60% (10/16). Screening for exon deletions and duplications in the CFTR gene would be beneficial in classic CF cases, especially when only one mutation is identified by standard methodologies.

Validation and Clinical Application of a Locus- Specific Polymerase Chain Reaction- and Minisequencing-Based Assay for Congenital Adrenal Hyperplasia (21-Hydroxylase Deficiency)

Congenital adrenal hyperplasia is an autosomal recessive disorder caused by defective adrenal steroid biosynthesis, resulting in reduced glucocorticoid and increased androgen production. The majority of cases are due to inactivation of the 21-hydroxylase gene (CYP21A2), most commonly caused by genomic rearrangements with the adjacent, highly homologous pseudogene CYP21A. The most common deletions and gene conversion events have been defined and are typically detected by Southern hybridization detection of CYP21 rearrangements and/or polymerase chain reaction (PCR). However, Southern hybridization is laborious, and allele-specific PCR results may be difficult to interpret. We have therefore developed a locus-specific, PCR-based, minisequencing method for detecting the 12 most common CYP21A2 mutations. We validated the assay using a panel of 20 previously genotyped samples obtained from individuals who collectively have a broad spectrum of mutations causing 21-hydroxylase deficiency. We also used 19 control samples having no CYP21 mutations. All validation samples were correctly typed, and we identified haplotypes that may be useful for clinical diagnosis. Results from 102 clinical samples demonstrate that this assay is a rapid, reliable, and robust method for locus-specific identification of mutations and is suitable for routine clinical use and prenatal diagnosis.

Cystic fibrosis testing 8 years on: lessons learned from carrier screening and sequencing analysis.

Purpose: This study reviews data from our cystic fibrosis testing program to evaluate the performance of population-based carrier screening and compare observed detection rates with predicted results of the American College of Medical Genetics/American College of Obstetricians and Gynecologists recommended panel of 23 mutations.Methods: We queried our proprietary databases containing approximately 3 million cystic fibrosis screening tests, 1300 prenatal diagnostic tests, and 2400 cystic fibrosis sequencing analyses.Results: We observed an overall cystic fibrosis carrier frequency of 1:37.6 individuals in the pan-ethnic tested population. This represents a detection rate of 77%, given an estimated US pan-ethnic carrier frequency of 1:29. For patients self-identified as white or Ashkenazi Jewish, a carrier frequency of 1:29 and 1:27 were observed, respectively. A combined frequency of 1:28, representing close to 90% of carriers, was identified in these two highest risk populations. In total, 119 affected fetuses were identified by prenatal diagnoses, a ratio of 1 affected fetus per 25,000 carrier screens. Of 62 newborns with positive immunoreactive trypsinogen and positive sweat tests, almost all of whom had been tested using the American College of Medical Genetics/American College of Obstetricians and Gynecologists panel, only two individuals would have been identified using an expanded mutation panel.Conclusion: The American College of Medical Genetics/American College of Obstetricians and Gynecologists panel of 23 mutations is performing as predicted in detecting cystic fibrosis carriers in the United States among all ethnic groups. No recurrent mutations have been detected in sufficient numbers to justify including any additional mutations to the existing panel. An expanded American College of Medical Genetics/American College of Obstetricians and Gynecologists panel would have a minimal impact on the prevention of births of children affected with cystic fibrosis.

Cystic fibrosis screening: lessons learned from the first 320,000 patients.

Purpose: To examine the data from >335,000 Cystic fibrosis (CF) tests to detect unsuspected findings and obtain clinical data when indicated to optimize genetic counseling.Methods: A proprietary database containing 335,204 consecutive CF DNA tests and 445 CF prenatal diagnostic tests was queried. Clinical information was obtained for prenatal and selected nonprenatal cases by telephone contact with physician offices.Results: The mutation 1078delT was found in much lower frequency than expected with rates of only 1:55,867 tests and 0.06% of CF mutations. This level is below the threshold set by the American College of Medical Genetics. Homozygosity was observed for 2789+5G>A in a 29-year-old women and compound heterozygosity with delta F408 in a 40-year-old woman with isolated chronic sinusitis. Many patients elected prenatal diagnosis when not at a 1:4 risk due to echogenic bowel or IVS-8 5T issues.Conclusions: With the exception of 1078delT, all CF mutations in the ACMG panel were detected with a frequency of > 0.1% of CF chromosomes. When ACMG guidelines are strictly adhered to, population-based CF carrier screening will accurately identify couples at risk for having children with CF.

Molecular screening for diseases frequent in Ashkenazi Jews: lessons learned from more than 100,000 tests performed in a commercial laboratory.

Purpose: To determine the frequency of carriers of Ashkenazi Jewish (AJ) genetic diseases in the US population and compare these numbers with previously published frequencies reported in smaller more isolated cohorts.Methods: A database containing more than 100,000 genotyping assays was queried. Assays for 10 separate AJ genetic diseases where comparisons were made with published data.Results: As expected, we observed lower carrier frequencies in a general, US population than those reported in literature. In 2427 patients tested for a panel of 8 AJ diseases, 20 (1:121) were carriers of two diseases and 331 (1:7) were carriers of a single disease. Fifty-three of 7184 (1:306) individuals tested for Gaucher disease had 2 Gaucher Disease mutations indicating a potentially affected phenotype.Conclusions: As the number of AJ diseases increases, progressively more individuals will be identified as carriers of at least one disease.

Extensive sequencing of the CFTR gene: lessons learned from the first 157 patient samples.

Cystic fibrosis (CF) is one of the most common monogenic diseases affecting Caucasians and has an incidence of approximately 1:3,300 births. Currently recommended screening panels for mutations in the responsible gene (CF transmembrane regulator gene, CFTR) do not detect all disease-associated mutations. Our laboratory offers extensive sequencing of the CFTR (ABCC7) gene (including the promoter, all exons and splice junction sites, and regions of selected introns) as a clinical test to detect mutations which are not found with conventional screening. The objective of this report is to summarize the findings of extensive CFTR sequencing from our first 157 consecutive patient samples. In most patients with classic CF symptoms (18/24, 75%), extensive CFTR sequencing confirmed the diagnosis by finding two disease-associated mutations. In contrast, only 5 of 75 (7%) patients with atypical CF had been identified with two CFTR mutations. A diagnosis of CF was confirmed in 10 of 17 (58%) newborns with either positive sweat chloride readings or positive immunoreactive trypsinogen (IRT) screen results. We ascertained ten novel sequence variants that are potentially disease-associated: two deletions (c.1641AG>T, c.2949_2853delTACTC), seven missense mutations (p.S158T, p.G451V, p.K481E, p.C491S, p.H949L, p.T1036N, p.F1099L), and one complex allele ([p.356_A357del; p.358I]). We ascertained three other apparently novel complex alleles. Finally, several patients were found to carry partial CFTR gene deletions. In summary, extensive CFTR gene sequencing can detect rare mutations which are not found with other screening and diagnostic tests, and can thus establish a definitive diagnosis in symptomatic patients with previously negative results. This enables carrier detection and prenatal diagnosis in additional family members.

Genotype-phenotype correlation and frequency of the 3199del6 cystic fibrosis mutation among I148T carriers: results from a collaborative study.

Purpose: We expect that the mutation panel currently recommended for preconception/prenatal CF carrier screening will be modified as new information is learned regarding the phenotype associated with specific mutations and allele frequencies in various populations. One such example is the I148T mutation, originally described as a severe CF mutation. After implementation of CF population-based carrier screening, we learned that I148T exists as a complex allele with 3199del6 in patients with clinical CF, whereas asymptomatic compound heterozygotes for I148T and a second severe CF mutation were negative for 3199del6.Methods: We performed reflex testing for 3199del6 on 663 unrelated specimens, including I148T heterozygotes, compound heterozygotes, and a homozygous individual.Results: Less than 1% of I148T carriers were also positive for 3199del6. Excluding subjects tested because of a suspected or known CF diagnosis or positive family history, 0.6% of I148T-positive individuals were also positive for 3199del6. We identified 1 I148T homozygote and 6 unrelated compound heterozygous individuals with I148T and a second CF variant (2 of whom also carried 3199del6). In addition, one fetus with echogenic bowel and one infertile male were heterozygous for I148T (3199del6 negative).Conclusions: Reflex testing for 3199del6 should be considered whenever I148T is identified. Reflex testing is of particular importance for any symptomatic patient or whenever one member of a couple carries a deleterious CF mutation and the other member is an I148T heterozygote. Further population data are required to determine if I148T, in the absence of 3199del6, is associated with mild or atypical CF or male infertility.