Genetic Testing in Inherited Arrhythmias: Approach,Limitations, and Challenges

Genetic testing is playing an ever-expanding role in cardiovascular care and is becoming part of the “toolkit” for the cardiovascular clinician. In patients with inherited arrhythmias, genetic testing can confirm a suspected diagnosis, establish a diagnosis in unexplained cases, and help facilitate cascade family screening. Many inherited arrhythmia syndromes are monogenic diseases arising from a single pathogenic variant involved in the structure and function of cardiac ion channels or structural proteins. As such, “arrhythmia gene panels” will often cast a wide net for such heritable diseases. However, challenges may arise when genetic testing results are ambiguous, or when genetic testing results (genotype) and clinical phenotypes do not match. In cases of “genotype-phenotype matching,” genetic results complement the clinical phenotype and genetic testing can be used in diagnosis, family screening, and occasionally prognostication. It becomes more challenging when genetic results are negative or noncontributory and “contradict” the clinical phenotype. “Genotype mismatches” can also occur when genotype-positive patients have no clinical phenotype, or when genetic testing results point towards a completely different disease than the clinical phenotype. We discuss an approach to genetic testing and review the challenges that may arise when interpreting genetic testing results. Genetic testing has opened a wealth of opportunities in the diagnosis, management, and cascade screening of inherited arrhythmia syndromes, but has also opened a “Pandora’s box” of challenges. Genetic results should be interpreted with caution and in a multidisciplinary clinic, with support from genetic counsellors and an expert with a focused interest in cardiovascular genetics.     

Genetic testing and genetic counseling in cardiovascular genetic medicine: overview and preliminary recommendations

In this emerging era of cardiovascular genetic medicine, increasing responsibility will be placed on cardiovascular practitioners to be aware of the latest clinical genetic testing methods and the knowledge base needed to interpret genetic test results. Some cardiovascular specialists will develop the expertise within the field to order genetic testing and interpret results, while other practitioners will refer patients to centers of excellence in cardiovascular genetic medicine. A previous article in the Cardiovascular Genetic Medicine: Clinical Perspectives and Future Applications series(1) highlighted an increasing recognition of the cardiomyopathies (hypertrophic [HCM], dilated [DCM], arrhythmogenic right ventricular dysplasia [ARVD]) and channelopathies (long QT syndrome [LQTS] and others) as genetic diseases, and focused on the importance of a targeted family history as a critical part of patient evaluation. The goal of this article, second in the series, is to provide a general framework for understanding the principles of genetic testing and genetic counseling. We review the growing number of genetic tests currently available to cardiac specialists, the selection of an appropriate test, and the numerous genetic counseling issues raised by the testing process. We also provide our preliminary recommendations for genetic testing in cardiovascular genetic medicine.     

Genetic epidemiology and public health: hope, hype, and future prospects

Genetic epidemiology is a rapidly expanding research field, but the implications of findings from such studies for individual or population health are unclear. The use of molecular genetic screening currently has some legitimacy in certain monogenic conditions, but no established value with respect to common complex diseases. Personalised medical care based on molecular genetic testing is also as yet undeveloped for common diseases. Genetic epidemiology can contribute to establishing the causal nature of environmentally modifiable risk factors, through the application of mendelian randomisation approaches and thus contribute to appropriate preventive strategies. Technological and other advances will allow the potential of genetic epidemiology to be revealed over the next few years, and the establishment of large population-based resources for such studies (biobanks) should contribute to this endeavour.     

Family history: an essential tool for cardiovascular genetic medicine

We are pleased to provide a new section devoted to topics in cardiovascular genetic medicine. An emerging field, cardiovascular genetic medicine is devoted to the identification and understanding of cardiac conditions resulting from genetic mechanisms and to the development and validation of treatment algorithms and guidelines. Cardiovascular genetic medicine is rapidly enlarging, and we anticipate a broad range of comprehensive reviews. We will first focus on the most tractable diagnoses to apply the principles of cardiovascular genetic medicine: the cardiomyopathies such as dilated, hypertrophic, arrhythmogenic right ventricular dysplasia/cardiomyopathy and the channelopathies such as long QT syndrome and related disorders. These conditions follow classical or Mendelian genetics, otherwise known as the single gene disorders. As greater numbers of disease genes and their specific mutations are identified, and as large clinical cohorts of affected probands and their at-risk family members become available for study, clinical recommendations, and then guidelines, will follow. Progress is also evident for those conditions considered to be complex or multigenic diseases, such as coronary disease and hypertension, which affect large segments of the population. Risk alleles are now being identified that may rapidly lead to genetic testing to assess risk for these conditions. Cardiovascular genetic medicine must also be responsive to public concerns regarding confidentiality, and it must also demonstrate clinical integrity and utility for genetic testing. Our first topic features the role of family history in cardiovascular genetic medicine. Assisted by my clinical and research group -- genetic counselors and nursing personnel devoted to the field -- we have provided a glossary with explanations of genetic terminology, as illustrated in this first article, and will continue to do so for the series. We will prepare additional topics and others will be solicited from experts in the field. I also invite any potential contributors to propose and submit topics that are both of interest to you and relevant to the field. Please also give us your feedback, especially to improve the clarity, diversity, and timeliness of the genetic concepts presented. So, away we go.     

When should genetic testing be obtained in a patient with phaeochromocytoma or paraganglioma?

About 30% of phaeochromocytoma and paraganglioma patients harbour a germline mutation in one of the known susceptibility genes and in more than one-third of these patients there is no family history for these tumours. The genetic classification, risk assessment and specific management of the patients and at risk family members play an important role in preventive medicine. Distinct diagnostic or therapeutic approaches related to the genetic testing results are and will be even more relevant in the future for the detection of mutation carriers. In addition to a positive family history, other clinical features such as young age at time of manifestation, multifocal tumours and specific tumour location are highly associated with the presence of a germline mutation – genetic testing in these cases should be mandatory. Since several genes are involved in the genetics of phaeochromocytoma and paraganglioma, prioritizing which gene(s) to be tested first by using simple clinical information can reduce the efforts and costs of this analysis. The clinicians offering and performing the genetic testing should provide or make available adequate counselling as well as access to preventive and surveillance options to patients. Collaboration with referral centres and research groups in this field can help to coordinate the management of these patients.     

Genetic testing in cardiovascular disease

Genetic testing is increasingly becoming possible for diagnosis, susceptibility testing, and prognostication in cardiovascular medicine. The practicing cardiologist, therefore, needs to be familiar with the clinical utilities and limitations of genetic testing. This review explores the major approaches to genetic testing and issues in test interpretation. Specific applications to cardiovascular diseases, including coronary artery disease, cardiomyopathies, cardiac arrhythmias, and pulmonary arterial hypertension are discussed.     

Genetic testing in cardiovascular disease.

Genetic testing is increasingly becoming possible for diagnosis, susceptibility testing, and prognostication in cardiovascular medicine. The practicing cardiologist, therefore, needs to be familiar with the clinical utilities and limitations of genetic testing. This review explores the major approaches to genetic testing and issues in test interpretation. Specific applications to cardiovascular diseases, including coronary artery disease, cardiomyopathies, cardiac arrhythmias, and pulmonary arterial hypertension are discussed.     

Pr?vention durch Bewegung

Regular physical activity is now recognized as an important and very effective step to prevent many diseases, especially those of the cardiovascular system. Many studies within the last 20?years have also shown that exercise capacity or fitness is an important prognostic factor in healthy subjects and patients with cardiovascular diseases for both mortality and morbidity. Physical fitness, which is mainly determined by regular physical activity or training, can be analyzed by maximal exercise testing using the treadmill or cycle ergometry. In addition, fitness is also based on genetic factors. There are some methodological criticisms concerning self-reported questionnaires of physical activity, MET (metabolic equivalent) calculations and exhaustion during maximal voluntary stress testing. However, the results of both approaches are valid and reliable for daily use. Accordingly, every physician regardless of his or her discipline should encourage all patients at every visit to follow a healthy lifestyle, including regular exercise and physical activity. This also applies to older patients, who especially benefit from exercise and physical activity.     

Novel molecular therapeutic approach to cardiovascular disease based on hepatocyte growth factor.

Gene therapy techniques are being developed as potential treatments for cardiovascular diseases. During the past decade, many gene transfer methods including viral transfer techniques have been developed, and some are being applied clinically in human gene therapy studies. Recently, we have developed a novel gene transfer method mediated by Hemagglutinating Virus of Japan (HVJ) liposome, with which we have already reported several cases of successful gene transfer in vivo. Since the virus is inactivated by ultraviolet light, there is little potential for biological hazard with this method as compared to other viral gene transfer approaches. We also developed a novel strategy of gene therapy for cardiovascular diseases utilizing hepatocyte growth factor (HGF) which is an endothelial cell specific growth factor and an angiogenic growth factor. Based on these facts, we hypothesized that HGF may prevent restenosis after angioplasty through re endothelialization and myocardial infarction through induction of angiogenesis. The present results provide evidence of the efficacy of supplemental therapy with HGF by gene transfer in cardiovascular diseases. These data suggest the efficacy of novel molecular therapeutic approaches as gene therapy for cardiovascular diseases such as restenosis and myocardial infarction.     

Medicina personalizada: diagnóstico genético de cardiopatías/canalopatías hereditarias

Major advances in the field of molecular genetics have expanded our ability to identify genetic substrates underlying the pathogenesis of various disorders that follow Mendelian inheritance patterns. Included among these disorders are the potentially lethal and heritable channelopathies and cardiomyopathies for which the underlying genetic basis has been identified and is now better understood. Clinical and genetic heterogeneity are hallmark features of these disorders, with thousands of gene mutations being implicated within these divergent cardiovascular diseases. Genetic testing for several of these heritable channelopathies and cardiomyopathies has matured from discovery to research-based genetic testing to clinically/commercially available diagnostic tests. The purpose of this review is to provide the reader with a basic understanding of human medical genetics and genetic testing in the context of cardiovascular diseases of the heart. We review the state of clinical genetic testing for the more common channelopathies and cardiomyopathies, discuss some of the pertinent issues that arise from genetic testing, and discuss the future of personalized medicine in cardiovascular disease.     

Clopidogrel and genetic testing: is it necessary for everyone?

Clopidogrel is a widely used antiplatelet agent to treat and prevent a variety of atherothrombotic diseases. More than a decade after its initial Food and Drug Administration approval, studies have emerged raising concerns regarding its possible reduced efficacy in patients who have impaired conversion of clopidogrel to its active metabolite (ie, poor metabolizers). Research has implicated genetic variations in the CYP2C19 isozyme as at least partly responsible for the variable antiplatelet response seen with clopidogrel. Studies have shown that patients possessing genetic variants of the CYP2C19 isozyme may be at increased risk of adverse cardiovascular events due to impaired clopidogrel efficacy, although this has not been definitively demonstrated. The Food and Drug Administration has issued a boxed warning regarding this concern. However, specific recommendations on genetic testing and alternative therapeutic strategies are not currently available. Genetic testing is commercially available to test patients for variability in the CYP2C19 isozyme, but altering antiplatelet therapy based on the results of this testing has not been adequately studied, and it is therefore not clear how to adjust therapy based on the results of this genetic testing. In addition, there are many other factors that may contribute to the variability in antiplatelet effect seen with clopidogrel besides CYP2C19 genetic polymorphisms. Ongoing trials dealing with adjusting antiplatelet therapy based on genetic testing will hopefully provide more useful information on how to appropriately integrate pharmacogenomics with the care of patients with atherothrombotic disease.     

Genetic variation in the natriuretic peptide system and heart failure

Heart failure (HF) is a modern epidemic and is one of the few cardiovascular diseases which is increasing in prevalence. The growing importance of the Natriuretic Peptide (NP) system in HF is well recognized. Laboratory tests for B-type Natriuretic Peptide (BNP) have proven value as diagnostic and prognostic tools in HF and are now part of routine clinical care. Furthermore, recombinant atrial natriuretic peptide (ANP) (carperitide) and BNP (nesiritide) and are approved HF therapies in Japan and the US, respectively and additional natriuretic peptides (e.g., CNP, urodilatin, and designer NPs) are under investigation for use in HF. Common genetic sequence variants are increasingly being recognized as determinants of disease risk or drug response and may help explain a portion of the inter-individual variation in the human NP system. This review describes current knowledge of NP system genetic variation as it pertains to HF as well as ongoing studies and where the field is expected to progress in the near future. To briefly summarize, NP system genetic variants have been associated with alterations in gene expression, NP levels, and cardiovascular disease. The next step forward will include specific investigations into how this genetic variation can advance ‘Personalized Medicine’, such as whether they impact the utility of diagnostic BNP testing or effectiveness of therapeutic NP infusion. This is already in progress, with pharmacogenetic studies of nesiritide currently underway. We expect that within 5 years there should be a reasonable idea of whether NP system genetic variation will have important clinical implications.     

Molecular biology and gene therapy in gastroenterology and hepatology.

Molecular analyses have become an integral part of biomedical research as well as clinical medicine. The definition of the molecular and genetic basis of many human diseases has led to a better understanding of their pathogenesis and has in addition offered new perspectives for their diagnosis, therapy and prevention. Genetically, human diseases can be classified as monogenetic, complex genetic and acquired genetic diseases. Based on this classification, gene therapy is based on four concepts: gene substitution, gene augmentation, block of gene expression or function as well as DNA vaccination. While recent developments are promising, various delivery, targeting and safety issues need to be addressed before gene therapy will enter clinical practice. In the future, molecular diagnosis and gene therapy of gastrointestinal and liver diseases will be part of our patient management and complement existing diagnostic, therapeutic and preventive strategies.     

The Application of Induced Pluripotent Stem Cells in Cardiac Disease Modeling and Drug Testing

In recent decades, cardiovascular diseases have become the greatest health threat to human beings, and thus it is particularly important to explore the subtle underlying pathogenesis of cardiovascular diseases. Although many molecular pathways have been explored to be essential in the development of cardiovascular diseases, their clinical significances are still uncertain. With the emergence of induced pluripotent stem cells (iPSCs), a unique platform for cardiovascular diseases has been established to model cardiovascular diseases on specific genetic background in vitro. This review summarizes current progresses of iPSCs in cardiovascular disease modeling and drug testing. This review highlighted iPSC-based cardiovascular disease modeling and drug testing. The technical advances in iPSC-based researches and various clinically relevant applications are discussed. With further intensive research, iPSC technology will shape the future of clinical translational research in cardiovascular diseases.     

Coronary artery disease from a perspective of genomic risk score, ethical approaches and suggestions

As a leading cause of mortality, coronary artery disease is on the focus of genetic research as a complex trait. Although predictive genetic testing for cardiovascular diseases is on the counter, it is still hard to aggregate information from multiple genetic variants, environmental factors and family history into a single score. Every susceptibility allele provides small contribution to disease formation. Biomarkers play a role in various metabolic pathways. Genetic information and data depend heavily on probabilities. This should be clearly explained by genetic counselor to the patient and relatives who are looking for certain answers. Presence of susceptibility alleles can be a source of anxiety and it may result as a reduced self-confidence in ability to change health behavior. Complex diseases set a new stage to study novel techniques that can elucidate interactions among genetic, environmental and ethnic factors. The cookbook approach to treat a complex disease can often be misleading. Future studies may provide personalized information, which can improve the outcome of standardized treatments. As knowing one's own genetic risk is becoming a task for the responsible individual, it surely will add new challenges to ethical framework. Publicly marketing genetic tests for complex diseases raises ethical concerns. To avoid discriminatory use of genetic information; genetic risk scoring, therapeutic process, ethical policies must have a multifaceted progress. In this review, we summarized the attempts to resolve ethical issues related to genetic testing in complex diseases to resolve patient autonomy with individual responsibility and to aim the patient beneficence and confidentiality.     

Mitochondrial medicine: to a new era of gene therapy for mitochondrial DNA mutations

Mitochondrial disorders can no longer be ignored in most medical disciplines. Such disorders include specific and widespread organ involvement, with tissue degeneration or tumor formation. Primary or secondary actors, mitochondrial dysfunctions also play a role in the aging process. Despite progresses made in identification of their molecular bases, nearly everything remains to be done as regards therapy. Research dealing with mitochondrial physiology and pathology has >20 years of history around the world. We are involved, as are many other laboratories, in the challenge of finding ways to fight these diseases. However, our main limitation is the scarcety of animal models required for both understanding the molecular mechanisms underlying the diseases and evaluating therapeutic strategies. This is especially true for diseases due to mutations in mitochondrial DNA (mtDNA), since an authentic genetic model of mtDNA mutations is technically a very difficult task due to both the inability of manipulating the mitochondrial genome of living mammalian cells and to its multicopy nature. This has led researchers in the field to consider the prospect of gene therapy approaches that can roughly be divided into three groups: (1) import of wild-type copies or relevant sections of DNA or RNA into mitochondria, (2) manipulation of mitochondrial genetic content, and (3) rescue of a defect by expression of an engineered gene product from the nucleus (allotopic or xenotropic expression). We briefly introduce these concepts and indicate where promising progress has been made in the last decade.     

Biobanking in atherosclerotic disease, opportunities and pitfalls

Cardiovascular disease is the leading cause of death in Western countries and current research is still focusing on optimizing therapeutic approaches in the battle against this multifactorial disease. Concepts regarding the pathogenesis of many cardiovascular diseases originate from observations of human atherosclerotic tissue obtained from autopsies or during vascular surgery. These observations have helped us to disentangle the pathophysiology of atherosclerosis. However, identifying vulnerable patients, those prone to developing cardiovascular complications, remains difficult. The search for predictive cardiovascular biomarkers continues and large, well organized biobanks are needed to discover or validate novel biomarkers. Biobanks are an extremely valuable resource that enables us to study the influence of both genetic and environmental factors on the development of multifactorial diseases such as atherosclerosis. This review will focus on the advantages and pitfalls in atherosclerotic biobanking.     

Cardiovascular Genetic Medicine: Evolving Concepts, Rationale, and Implementation

Cardiovascular genetic medicine is devoted to the identification and understanding of cardiac conditions resulting from genetic and genomic mechanisms and to the development and validation of diagnostic and treatment algorithms and guidelines. Cardiovascular genetic medicine clinics now provide expert cardiovascular subspecialty care, genetic counseling and clinical genetic testing, and will eventually provide disease-specific gene or genetic therapies. Currently, the most tractable diagnoses for cardiovascular genetic medicine are the single-gene disorders: the cardiomyopathies, the channelopathies, and others. The recent explosion of genetic knowledge within the single-gene disorders and consequent rapid proliferation of genetic testing enables far greater numbers of individuals to directly benefit from this progress. A compelling rationale exists for this approach: cardiovascular single-gene diseases commonly present with life-threatening events (e.g., sudden cardiac death, heart failure, stroke, etc.), but identification, evaluation, and treatment of individuals with presymptomatic genetic risk has the promise to prevent or ameliorate cardiovascular morbidity and mortality. Cardiovascular genetic medicine programs also anchor training and research, thereby enabling the next generation of academic specialists in cardiovascular genetic medicine to continue to improve cardiovascular health.     

Zebrafish as a model to study cardiac development and human cardiac disease

Over the last decade, the zebrafish has entered the field of cardiovascular research as a new model organism. This is largely due to a number of highly successful small- and large-scale forward genetic screens, which have led to the identification of zebrafish mutants with cardiovascular defects. Genetic mapping and identification of the affected genes have resulted in novel insights into the molecular regulation of vertebrate cardiac development. More recently, the zebrafish has become an attractive model to study the effect of genetic variations identified in patients with cardiovascular defects by candidate gene or whole-genome-association studies. Thanks to an almost entirely sequenced genome and high conservation of gene function compared with humans, the zebrafish has proved highly informative to express and study human disease-related gene variants, providing novel insights into human cardiovascular disease mechanisms, and highlighting the suitability of the zebrafish as an excellent model to study human cardiovascular diseases. In this review, I discuss recent discoveries in the field of cardiac development and specific cases in which the zebrafish has been used to model human congenital and acquired cardiac diseases.     

Cardiovascular experiences in an Army general hospital

This report is a review of the cases of cardiovascular disease seen in an Army general hospital. To such a hospital gravitate the problem cases, the unusual conditions, cases requiring prolonged or special treament, and other cases for futher observation and disposition. Since cardiovascular diseases, by and large, fall into one or another of these categories, it is logical that a large percentage of these cases turning up in the Army eventually find their way to a general hospital. A review of such cases should be of interest in showing not only the type of cases encountered but also the problem of cardiovascular diseases in the Army.The material for this review consists of the cases admitted to the Lovell General Hospital, Fort Devens, Massachusetts, which is the Army general hospital serving the military installations in the New England states, upper New York state, and certain overseas bases. This hospital has been in operation for a little over two years and during this time has had approximately 10,000 admissions. Of this number, there were 440 cases of “organic” cardiovascular diseases and about an equal number of “functional” cardiovascular disorders. We have no information concerning the Army population from which these cases were drawn and hence can give no percentage incidence of these conditions in the Army. Further, it should be mentioned that, during the period covered by this report, the vast majority of the admissions to the hospital represented casualties of mobilization and training, few, if any, being related to actual combat.Except for a few pertinent observations, no detailed analysis of all of the data is presented, as such a presentation would be beyond the scope of this paper, which is primarily a general survey of the problem. With this in mind, the various types of diseases will be taken up and brief mention made of any salient features.