Karla R. Bowles

Detection of viruses in myocardial tissues by polymerase chain reaction : evidence of adenovirus as a common cause of myocarditis in children and adults

OBJECTIVES The purpose of this study was to analyze cardiac tissue and blood for viral genomes using polymerase chain reaction (PCR) to define the common viral etiologies of myocarditis by age group. BACKGROUND Enteroviruses are considered the most common cause of myocarditis at all ages. Diagnosis relies on viral cultures, serology, and cardiac histology, which lack sensitivity, as well as PCR. However, in many cases enteroviruses are not detected. METHODS Cardiac samples were obtained for PCR analysis from patients with myocarditis (n = 624) and dilated cardiomyopathy (DCM) (n = 149). Patients were analyzed by age group, including neonates (n = 116), infants (n = 191), toddlers (n = 87), children (n = 110), adolescents (n = 92), and adults (n = 177). After nucleic acids had been extracted from an endomyocardial biopsy, an explant, or autopsy samples, PCR and reverse transcription PCR were performed to detect the genomic sequences of enterovirus, adenovirus, cytomegalovirus (CMV), herpes simplex virus (HSV), Epstein-Barr virus (EBV), parvovirus, respiratory syncytial virus (RSV), and influenza A virus. RESULTS Viral genome was amplified (adenovirus = 142, enterovirus = 85, CMV = 18, parvovirus = 6, influenza A = 5, HSV = 5, EBV = 3, RSV = 1) from 239 (38%) of the 624 samples from myocarditis patients, including 26 patient samples in which dual infection was found. Virus was detected in 30 (20%) of 149 DCM patient samples; only adenovirus (n = 18) and enterovirus (n = 12) were detected. CONCLUSIONS Polymerase chain reaction identified adenovirus as the most common virus in the myocardium of children and adults with myocarditis and DCM. Although enteroviruses are also found in these patients, they appear to be a less common cause of myocarditis than adenovirus.

Novel Gene Mutations in Patients With Left Ventricular Noncompaction or Barth Syndrome

Background — Mutations in the gene G4.5 result in a wide spectrum of severe infantile cardiomyopathic phenotypes, including isolated left ventricular noncompaction (LVNC), as well as Barth syndrome (BTHS) with dilated cardiomyopathy (DCM). The purpose of this study was to investigate patients with LVNC or BTHS for mutations in G4.5 or other novel genes. Methods and Results — DNA was isolated from 2 families and 3 individuals with isolated LVNC or LVNC with congenital heart disease (CHD), as well as 4 families with BTHS associated with LVNC or DCM, and screened for mutations by single-strand DNA conformation polymorphism analysis and DNA sequencing. In 1 family with LVNC and CHD, a C→T mutation was identified at nucleotide 362 of &agr;-dystrobrevin, changing a proline to leucine (P121L). Mutations in G4.5 were identified in 2 families with isolated LVNC: a missense mutation in exon 4 (C118R) in 1 and a splice donor mutation (IVS10+2T→A) in intron 10 in the other. In a family with cardiomyopathies ranging from BTHS or fatal infantile cardiomyopathy to asymptomatic DCM, a splice acceptor mutation in exon 2 of G4.5 (398-2 A→G) was identified, and a 1-bp deletion in exon 2 of G4.5, resulting in a stop codon after amino acid 41, was identified in a sporadic case of BTHS. Conclusions — These data demonstrate genetic heterogeneity in LVNC, with mutation of a novel gene, &agr;-dystrobrevin, identified in LVNC associated with CHD. In addition, these results confirm that mutations in G4.5 result in a wide phenotypic spectrum of cardiomyopathies.

Mutations in the human δ-sarcoglycan gene in familial and sporadic dilated cardiomyopathy

Dilated cardiomyopathy (DCM) is a major cause of morbidity and mortality. Two genes have been identified for the X-linked forms (dystrophin and tafazzin), whereas three other genes (actin, lamin A/C, and desmin) cause autosomal dominant DCM; seven other loci for autosomal dominant DCM have been mapped but the genes have not been identified. Hypothesizing that DCM is a disease of the cytoskeleton and sarcolemma, we have focused on candidate genes whose products are found in these structures. Here we report the screening of the human δ-sarcoglycan gene, a member of the dystrophin-associated protein complex, by single-stranded DNA conformation polymorphism analysis and by DNA sequencing in patients with DCM. Mutations affecting the secondary structure were identified in one family and two sporadic cases, whereas immunofluorescence analysis of myocardium from one of these patients demonstrated significant reduction in δ-sarcoglycan staining. No skeletal muscle disease occurred in any of these patients. These data suggest that δ-sarcoglycan is a disease-causing gene responsible for familial and idiopathic DCM and lend support to our “final common pathway” hypothesis that DCM is a cytoskeletalopathy.

Mutations in the muscle LIM protein and α-actinin-2 genes in dilated cardiomyopathy and endocardial fibroelastosis

Dilated cardiomyopathy (DCM) is a major cause of morbidity and mortality. Two genes have been identified for the X-linked forms (dystrophin and tafazzin), while mutations in multiple genes cause autosomal dominant DCM. Muscle LIM protein (MLP) is a member of the cysteine-rich protein (CRP) family and has been implicated in both myogenesis and sarcomere assembly. In the latter role, it binds zyxin and alpha-actinin, both of which are involved in actin organization. An MLP-deficient mouse has been described; these mice develop dilated cardiomyopathy and heart failure. Based upon these data, and the recent descriptions of mutations in MLP in patients with DCM or hypertrophic cardiomyopathy, we screened patients for mutations in the MLP and alpha-actinin-2 genes. We identified a patient with DCM and EFE, having a mutation in MLP with the residue lysine 69 substituted by arginine (K69R). This is within a highly conserved region adjacent to the first LIM domain involved in alpha-actinin binding. Analysis in cell culture systems demonstrated that the mutation abolishes the interaction between MLP and alpha-actinin-2 and the cellular localization of MLP was altered. In another individual with DCM, a W4R mutation was identified. However, this mutation did not segregate with disease in this family. In another patient with DCM, a Q9R mutation was identified in alpha-actinin-2. This mutation also disrupted the interaction with MLP and appeared to inhibit alpha-actinin function in cultured cells, in respect to the nuclear localization of actinin and the initiation of cellular differentiation.

Frequency of mutations in individuals with breast cancer referred for BRCA1 and BRCA2 testing using next‐generation sequencing with a 25‐gene panel

Next‐generation sequencing (NGS) allows for simultaneous sequencing of multiple cancer susceptibility genes and, for an individual, may be more efficient and less expensive than sequential testing. The authors assessed the frequency of deleterious germline mutations among individuals with breast cancer who were referred for BRCA1 and BRCA2 (BRCA1/2) gene testing using a panel of 25 genes associated with inherited cancer predisposition.

The “Final Common Pathway” Hypothesis and Inherited Cardiovascular Disease The Role of Cytoskeletal Proteins in Dilated Cardiomyopathy

The genetic basis of a number of inherited cardiovascular diseases has been elucidated over the last few years, including the long QT syndromes, hypertrophic cardiomyopathy and dilated cardiomyopathy. While genetic heterogeneity has been demonstrated in most of these diseases, a pattern has emerged, specifically that genes encoding proteins with similar functions or involved in the same pathway are responsible for a particular disease or syndrome. Based on this observation we proposed the “final common pathway” hypothesis. In the case of the arrhythmogenic disorders, the long QT syndromes and Brugada syndrome, mutations have been described in a number of ion channel proteins, including cardiac potassium (KVLQT1, HERG and minK) and sodium (SCN5A) channels. Thus, using the “final common pathway” hypothesis we have proposed these diseases to be “ion channelopathies”. Hypertrophic cardiomyopathy appears to be a disease of the sarcomere (“sarcomyopathy”) since all the disease-causing mutations have been identified in the gene encoding many of the sarcomeric proteins, including β-myosin heavy chain, α-tropomyosin, troponin I and troponin T, as well as in actin, close to the β-myosin heavy chain binding site. The genes responsible for familial dilated cardiomyopathy have been less well characterized. For X-linked dilated cardiomyopathy, mutations in the dystrophin and G4.5 genes have been reported. In addition, mutations in actin (close to the dystrophin binding domain) and desmin, a component of the intermediate filaments, have been reported. However, the genes at a further 6 loci associated with autosomal dominant dilated cardiomyopathy (associated with conduction disease in 2 cases) remain unidentified.Due to the mutations in dystrophin, actin and desmin, we have proposed that dilated cardiomyopathy is a “cytoskeletalopathy”, and we are currently investigating the involvement of these genes in patients.ZusammenfassungDie genetischen Ursachen einer Reihe von vererbten kardiovaskulären Erkrankungen, wie den “Long QT”-Syndromen und der hypertrophischen und dilatativen Kardiomyopathie, wurden in den letzten Jahren aufgeklärt. Obwohl eine genetische Heterogenität bei den meisten dieser Krankheiten vorhanden ist, lassen sich Krankheitsmuster oder Syndrome von defekten Genen ableiten, die Proteine mit ähnlicher Funktion kodieren. Wir schlugen daher die Hypothese des “Final Common Pathway” (gemeinsame Endstrecke) vor.Bei arrhythmogenen Störungen, den “Long QT”-Syndromen und dem Brugada-Syndrom, wurden Mutationen bei mehreren Kanalproteinen wie den kardialen Kalium-(KVLQT1, HERG und minK) und Natriumkanälen (SCN5A) beschrieben. Auf der Grundlage der “Final Common Pathway”-Hypothese bezeichneten wir diese Krankheit als “Ionenkanalopathien”. Die hypertrophische Kardiomyopathie scheint eine Erkrankung des Sarkomers (“Sarkomyopathie”) zu sein, da die krankheitsverursachenden Mutationen in Genen gefunden wurden, die Proteine des Sarkomers, wie schwere Kette des β-Myosins (β-MHC), α-Tropomyosin, Troponin I und Troponin T und Aktin (benachbart zur β-MHC-Bindungsstelle), kodieren. Die Gene, die zu einer familiären dilatativen Kardiomyopathie führen, sind weniger gut untersucht. Für die X-chromosomal vererbte dilatative Kardiomyopathie wurden Mutationen bei Dystrophin, G4.5, Aktin (in der Nähe der Dystrophinbindungsdomäne) und Desmin (eine Komponente der intermediären Filamente) beobachtet. Es sind zum jetzigen Zeitpunkt die Gene bei weiteren sechs Loci, die mit autosomaler dilatativer Kardiomyopathie (und in zwei Fällen mit Störungen der Erregungsleitung) assoziiert sind, unbekannt.Wegen der Mutationen bei Dystrophin, Aktin und Desmin schlugen wir, auch auf der Grundlage laufender eigener Untersuchgungen, für die dilatative Kardiomyopathie die Bezeichnung “Zytoskeletopathie” vor.

Gene mapping of familial autosomal dominant dilated cardiomyopathy to chromosome 10q21-23.

Dilated cardiomyopathy (DCM) is the most common form of primary myocardial disorder, accounting for 60% of all cardiomyopathies. In 20-30% of cases, familial inheritance can be demonstrated; an autosomal dominant transmission is the usual type of inheritance pattern identified. Previously, genetic heterogeneity was demonstrated in familial autosomal dominant dilated cardiomyopathy (FDCM). Gene localization to chromosome 1 (1p1-1q1 and 1q32), chromosome 3 (3p25-3p22), and chromosome 9 (9q13-9q22) has recently been identified. We report one family with 26 members (12 affected) with familial autosomal dominant dilated cardiomyopathy in which linkage to chromosome 10 at the 10q21-q23 locus is identified. Using short tandem repeat polymorphism (STR) markers with heterozygosity > 70%, 169 markers (50% of the genome) were used before linkage was found to markers D10S605 and D10S201 with a pairwise LOD score = 3.91, theta = 0, penetrance = 100% for both markers. Linkage to 1p1-1q1, 1q32, 3p25-3p22, and 9q13-9q22 was excluded. We conclude that a new locus for pure autosomal dominant FDCM exists, and that this gene is localized to a 9 cM region of 10q21-10q23. The search for the disease causing gene and the responsible mutation(s) is ongoing.

Danon disease as an underrecognized cause of hypertrophic cardiomyopathy in children

Background—Some patients with hypertrophic cardiomyopathy (HCM) or left ventricular hypertrophy also present with skeletal myopathy and Wolff-Parkinson-White (WPW) syndrome; mutations in the gene encoding the lysosome-associated protein-2 (LAMP-2) have been identified in these patients, suggesting that some of these patients have Danon disease. In this study we investigated the frequency of LAMP2 mutations in an unselected pediatric HCM population. Methods and Results—LAMP2 was amplified from genomic DNA isolated from peripheral lymphocytes of 50 patients diagnosed with HCM and analyzed by direct DNA sequencing. In 2 of the 50 probands (4%), nonsense mutations were identified. In 1 family the proband initially presented with HCM as a teenager, which progressed to dilated cardiomyopathy (DCM) and heart failure. Skeletal myopathy and WPW were also noted. The teenage sister of the proband is a carrier of the same LAMP2 mutation and has HCM without skeletal myopathy or WPW. The other proband presented with HCM, WPW, and skeletal myopathy as a teenager, whereas his carrier mother developed DCM during her 40s. Skeletal and cardiac muscle sections revealed the absence of LAMP-2 on immunohistochemical staining. Conclusions—LAMP2 mutations may account for a significant proportion of cases of HCM in children, especially when skeletal myopathy and/or WPW is present, suggesting that Danon disease is an underrecognized entity in the pediatric cardiology community.

Mutation analysis of the G4.5 gene in patients with isolated left ventricular noncompaction.

Mutations in the gene G4.5, originally associated with Barth syndrome, have been reported to result in a wide spectrum of severe infantile X-linked cardiomyopathies. The purpose of this study was to investigate patients with isolated left ventricular noncompaction (LVNC) for disease-causing mutations in G4.5. In 27 patients including 10 families with isolated LVNC, mutation analysis of G4.5 was performed using single-strand DNA conformation polymorphism (SSCP) analysis and DNA sequencing. A novel splice acceptor site mutation of intron 8 of G4.5 was identified in a family with severe infantile X-linked LVNC without the usual findings of Barth syndrome. This mutation results in deletion of exon 9 from the mRNA, and is predicted to significantly disrupt the protein product. Genotype-phenotype correlation of G4.5 mutations in all 38 cases reported in the literature to date revealed that there was no correlation between location or type of mutation and either cardiac phenotype or disease severity. We suggest that males presenting with cardiomyopathy, particularly during infancy, even in the absence of the typical signs of Barth syndrome, should be evaluated for mutations in G4.5.

Etiologies of cardiomyopathy and heart failure.

Evidence for a final common pathway for disorders of the myocardium (pages 246 and 320–330).