Sharie B. Parks

Lamin A/C mutation analysis in a cohort of 324 unrelated patients with idiopathic or familial dilated cardiomyopathy

BACKGROUND Lamin A/C mutations are a well-established cause of dilated cardiomyopathy (DCM), although their frequency has not been examined in a large cohort of patients. We sought to examine the frequency of mutations in LMNA, the gene encoding lamin A/C, in patients with idiopathic (IDC) or familial dilated cardiomyopathy (FDC). METHODS Clinical cardiovascular data, family histories, and blood samples were collected from 324 unrelated IDC probands, of whom 187 had FDC. DNA samples were sequenced for nucleotide alterations in LMNA. Likely protein-altering mutations were followed up by evaluating additional family members, when possible. RESULTS We identified 18 protein-altering LMNA variants in 19 probands or 5.9% of all cases (7.5% of FDC; 3.6% of IDC). Of the 18 alterations, 11 were missense (one present in 2 kindreds), 3 were nonsense, 3 were insertion/deletions, and 1 was a splice site alteration. Conduction system disease and DCM were common in carriers of LMNA variants. Unexpectedly, in 6 of the 19 kindreds with a protein-altering LMNA variant (32%), at least one affected family member was negative for the LMNA variant. CONCLUSIONS Lamin A/C variants were observed with a frequency of 5.9% in probands with DCM. The novel observation of FDC pedigrees in which not all affected individuals carry the putative disease-causing LMNA mutation suggests that some protein-altering LMNA variants are not causative or that some proportion of FDC may be because of multiple causative factors. These findings warrant increased caution in FDC research and molecular diagnostics.

Mutations of Presenilin Genes in Dilated Cardiomyopathy and Heart Failure

Two common disorders of the elderly are heart failure and Alzheimer disease (AD). Heart failure usually results from dilated cardiomyopathy (DCM). DCM of unknown cause in families has recently been shown to result from genetic disease, highlighting newly discovered disease mechanisms. AD is the most frequent neurodegenerative disease of older Americans. Familial AD is caused most commonly by presenilin 1 (PSEN1) or presenilin 2 (PSEN2) mutations, a discovery that has greatly advanced the field. The presenilins are also expressed in the heart and are critical to cardiac development. We hypothesized that mutations in presenilins may also be associated with DCM and that their discovery could provide new insight into the pathogenesis of DCM and heart failure. A total of 315 index patients with DCM were evaluated for sequence variation in PSEN1 and PSEN2. Families positive for mutations underwent additional clinical, genetic, and functional studies. A novel PSEN1 missense mutation (Asp333Gly) was identified in one family, and a single PSEN2 missense mutation (Ser130Leu) was found in two other families. Both mutations segregated with DCM and heart failure. The PSEN1 mutation was associated with complete penetrance and progressive disease that resulted in the necessity of cardiac transplantation or in death. The PSEN2 mutation showed partial penetrance, milder disease, and a more favorable prognosis. Calcium signaling was altered in cultured skin fibroblasts from PSEN1 and PSEN2 mutation carriers. These data indicate that PSEN1 and PSEN2 mutations are associated with DCM and heart failure and implicate novel mechanisms of myocardial disease.

Clinical and functional Characterization of TNNT2 mutations identified in patients with dilated cardiomyopathy

Background—A key issue for cardiovascular genetic medicine is ascertaining if a putative mutation indeed causes dilated cardiomyopathy (DCM). This is critically important as genetic DCM, usually presenting with advanced, life-threatening disease, may be preventable with early intervention in relatives known to carry the mutation. Methods and Results—We recently undertook bidirectional resequencing of TNNT2, the cardiac troponin T gene, in 313 probands with DCM. We identified 6 TNNT2 protein-altering variants in 9 probands, all who had early onset, aggressive disease. Additional family members of mutation carriers were then studied when available. Four of the 9 probands had DCM without a family history, and 5 probands had familial DCM. Only 1 mutation (Lys210del) could be attributed as definitively causative from previous reports. Four of the 5 missense mutations were novel (Arg134Gly, Arg151Cys, Arg159Gln, and Arg205Trp), and one was previously reported with hypertrophic cardiomyopathy (Glu244Asp). Based on the clinical, pedigree, and molecular genetic data, these 5 mutations were considered possibly or likely disease causing. To further clarify their potential pathophysiologic impact, we undertook functional studies of these mutations in cardiac myocytes reconstituted with mutant troponin T proteins. We observed decreased Ca2+ sensitivity of force development, a hallmark of DCM, in support of the conclusion that these mutations are disease causing. Conclusions—We conclude that the combination of clinical, pedigree, molecular genetic, and functional data strengthen the interpretation of TNNT2 mutations in DCM.

Real-Time Polymerase Chain Reaction With Fluorescent Hybridization Probes for the Detection of Prevalent Mutations Causing Common Thrombophilic and Iron Overload Phenotypes

We evaluated more than 450 patients with thrombophilia or iron overload for the presence of a factor V Leiden (R506Q), prothrombin G20210A, or HFE C282Y mutation using a standard method (polymerase chain reaction [PCR]-restriction fragment length polymorphism) and a comparative real-time PCR fluorescent resonance energy transfer (FRET) hybridization probe melting curve method. There was 100% concordance between the genotypes ascertained by the 2 methods (at each loci). In addition, phenotypic biochemical laboratory parameters measured on a subset of referred patients correlated with their respective genotypes. In the iron overload cohort, HFE C282Y homozygotes (n = 74) had significantly higher (P < .0001) transferrin saturation levels (74% +/- 25%) than did nonhomozygotes (n = 340; 51.4% +/- 28%), suggesting a genotype-dependent increase in body iron loads. In the thrombophilic cohort, the degree of activated protein C resistance (APCR), measured by a clotting time-based test, was associated significantly with the presence of 0 (n = 255; APCR = 2.59 +/- 0.26), 1 (n = 84; APCR = 1.61 +/- 0.13), or 2 (n = 5; APCR = 1.16 +/- 0.04) copies of the mutant factor V Leiden allele. As the fluorescent genotyping method required no postamplification manipulation, genotypes could be determined more quickly and with minimized risk of handling errors or amplicon contamination. In addition to these practical advantages, the FRET method is diagnostically accurate and clinically predictive of phenotypic, disease-associated manifestations.

Diagnostic Molecular Pathology

I I I . DNA Diagnostic Methodologies .......... 1-3 Southern Blot Assay .......................................... 1-3 Polymerase Chain Reaction Assay .................... 1-3 PCR-Restriction Fragment Length Polymorphism (PCR-RFLP) Assay .............. 1-4 PCR-Fluorescence Resonance Energy Transfer (PCR-FRET) ...................... 1-5 PCR-Denaturing High Pressure Liquid Chromatography (HPLC) Screening Assay ............................................ 1-6 Real-time Quantitative Reverse Transcription PCR ........................................ 1-6 DNA Sequencing .............................................. 1-6