Effects of regulatory light chain phosphorylation on mutant and wild-type cardiac muscle myosin mechanochemistry

Karabina, Anastasia Smaro

03 November 2015

Cardiac muscle contraction is responsible for pumping blood throughout the body. The cyclical, ATP-hydrolysis dependent interaction of the myosin motor protein with filamentous actin drives muscle contraction. During this process the α-helical neck region of myosin acts as a lever arm, transmitting contractile force between thick and thin filaments by amplifying small conformational changes in the myosin motor domain. The resulting relative displacement of thick and thin filaments causes muscle shortening. The regulatory light chain (RLC) of myosin mechanically supports the lever arm by binding to the myosin heavy chain neck region; this is a crucial interaction in maintaining myosin's ability to produce force and motion. We investigated the role of N-terminal modifications of the RLC in modulating actomyosin contractility at the molecular level. Phosphorylation of the RLC is a naturally occurring post-translational modification of the RLC N-terminus that is important for cardiac function and has been shown to enhance contractility at the cellular level. In contrast, genetic mutations of the RLC that lead to familial hypertrophic cardiomyopathy (FHC) disrupt cardiac function and trigger remodeling of the cardiac muscle structure. We studied two FHC-linked mutations, N47K and R58Q, located in the N-terminus of the RLC in close proximity to the phosphorylation site. Using in vitro motility assays we examined how RLC modifications affect the mechanochemical properties of cardiac β-myosin. We found that the FHC mutations reduced myosin force and power generation, in contrast to RLC phosphorylation which increased myosin force and power for WT and mutant myosins. Phosphorylation of mutant RLC resulted in a restoration of the mutation-induced decreases in contractility to WT dephosphorylated levels. These results point to RLC phosphorylation as a general mechanism to increase force production of the individual myosin motor and as a potential target to ameliorate the fundamental contractile FHC-induced phenotype.

Biophysics

Phosphorylation

Cardiac myosin

Hypertrophic cardiomyopathy

In Vitro motility

Load dependence

Regulatory light chain

Ecocardiografia tecidual em gatos da raça Maine Coon geneticamente testados para a cardiomipatia hipertrófica / Tissue Doppler echocardiography in Maine Coon cats genetically tested for hypertrophic cardiomyopathy

Pellegrino, Arine

28 January 2011

A cardiomiopatia hipertrófica (CMH) é a principal cardiopatia dos felinos e é caracterizada por hipertrofia miocárdica concêntrica, sem dilatação ventricular. Disfunções miocárdicas ocorrem em gatos com CMH, mas pouco se conhece a respeito destas alterações nos estágios iniciais da afecção. Em gatos da raça Maine Coon, a mutação no gene MyBPC-A31P está relacionada com a CMH de origem familial, porém, a correlação exata entre o genótipo e o fenótipo ainda é inconclusiva. A ecocardiografia tecidual é uma modalidade não invasiva que permite avaliação da função miocárdica e é mais sensível que a ecocardiografia convencional. Para avaliar a função sistólica e diastólica, antes ou após a ocorrência de hipertrofia ventricular, gatos da raça Maine Coon (n=57), geneticamente testados para a mutação, foram avaliados por meio de ecocardiografia convencional e tecidual (nas modalidades Doppler tecidual pulsado, Doppler tecidual colorido e strain). Posteriormente, foram fenotipicamente classificados em: normais (n=45), suspeitos (n=7) e acometidos pela CMH (n=5); e genotipicamente classificados em: negativos (n=28), heterozigotos (n=26) e homozigotos para a mutação (n=3). Valores de velocidades miocárdicas (Doppler tecidual pulsado e colorido) e valores de strain, medidos na região basal e média do septo interventricular (SIV), da parede livre do ventrículo esquerdo (PVE), da parede anterior do ventrículo esquerdo (PAVE), da parede posterior do ventrículo esquerdo (PPVE) e do segmento radial da PVE, foram comparados nos diferentes grupos. Observou-se que as velocidades longitudinais Em (Doppler tecidual pulsado) na região média da PVE foram menores nos gatos com CMH quando comparados com suspeitos e normais. Os valores de Em/Am (Doppler tecidual colorido), na região basal do SIV, foram inferiores nos gatos com CMH quando comparados com suspeitos e normais. A relação E/Em (Doppler tecidual colorido), na região basal do SIV, foi maior nos gatos com CMH em relação aos suspeitos e normais. E os valores de Sm (Doppler tecidual colorido), em região basal da PVE, foram menores nos gatos heterozigotos em relação aos negativos, ambos sem hipertrofia ventricular. Observou-se correlação positiva entre a ocorrência de fusão das ondas Em e Am e a frequência cardíaca; e correlação positiva entre valores de Sm e Em e a frequência cardíaca (Doppler tecidual pulsado e colorido). Enquanto à ecocardiografia convencional observou-se um estado de contratilidade aparentemente normal, os valores de strain (em região média do SIV) nos gatos com CMH foram inferiores aos dos gatos normais. Valores de strain (em região basal da PAVE) também foram menores nos gatos heterozigotos em relação aos negativos, antes mesmo da hipertrofia ventricular. Observou-se correlação negativa entre valores de strain e espessura miocárdica. A ecocardiografia tecidual é uma nova modalidade ecocardiográfica reprodutível em gatos que, isoladamente, não permite a identificação de gatos com mutação antes do desenvolvimento de hipertrofia. O strain possibilita a detecção de anormalidades sistólicas em gatos da raça Maine Coon, apesar da aparente normalidade à ecocardiografia convencional. Apesar da expectativa em relação ao uso da ecocardiografia tecidual para a identificação precoce de indivíduos portadores da CMH, ainda há necessidade de estudos mais extensos e com maior número de indivíduos. / Hypertrophic cardiomyopathy (HCM) is the most common feline heart disease and is characterized by increased cardiac mass with a hypertrophied nondilated left ventricle. Myocardial dysfunction occurs in cats with HCM but less is known about dysfunctions in initial stages of HCM. A mutation in MYBPC-A31P gene has been identified in a colony of Maine Coon cats with HCM. However, the close correlation between genotype and phenotype still be inconclusive. Myocardial analysis by tissue Doppler imaging (TDI) is a noninvasive echocardiographic method to assess systolic and diastolic function that is more sensitive than conventional echocardiography. To evaluate diastolic and systolic function in cats with mutation, with or without ventricular hypertrophy, Maine Coon cats (n=57) were screened for mutation and examined with both echocardiography and TDI (pulsed tissue Doppler, color tissue Doppler and Strain methods). Then, were phenotypically classified in: normal (n=45), suspects (n=7) and HCM group (n=5); and genotypically classified in: negative (n=28), heterozygous (n=26) and homozygous group (n=3). Myocardial velocities (by pulsed and color tissue Doppler imaging) and peak myocardial strain, measured in the basal and mildventricular segment of the interventricular septal wall (IVS), left ventricular free wall (LVW), left ventricular anterior wall (LVAW), left ventricular posterior wall (LVPW) and radial segment of LVW, was compared among different groups. A decreased longitudinal Em velocities (pulsed tissue Doppler) at the mildventricular segment of LVW was observed in HCM cats compared with suspects and normal cats. A decreased longitudinal Em/Am (color tissue Doppler) at the basal segment of IVS was observed in HCM cats compared with suspects and normal cats. A significant increased longitudinal E/Em (color tissue Doppler) at the basal segment of IVS was observed in HCM cats compared with suspects and normal cats. And a significant decreased longitudinal Sm (color tissue Doppler) at the basal segment of the LVW was observed in heterozygous cats compared with negative cats, both without hypertrophy. There was a positive correlation between summated early and late diastolic velocities (EmAm) and heart rate; and a positive correlation between Sm and Em velocities and heart rate, both in pulsed and in color TDI. Whereas conventional echocardiography demonstrated an apparently normal contractile state, myocardial strain (at mildventricular segment of IVS) in HCM cats was decreased compared with normal group. Myocardial strain (at basal segment of LVAW) also was decreased in heterozygous cats compared with negative group; and was decreased in heterozygous cats compared with negative group, both without ventricular hypertrophy. And there was a negative correlation between strain values and wall thickness. TDI analyses are a new, valuable and reproducible method in cats that alone is not able to identify cats with mutation before myocardial hypertrophy. Strain method allows noninvasive detection of abnormal systolic deformation in Maine Coons cats with HCM mutation despite apparently normal left ventricular systolic function. Despite high expectations regarding the use of TDI for early identification of individuals with HCM, there is still need for larger studies with greater numbers of individuals.

Cardiomiopatia hipertrófica

Cats

Doppler tecidual

Echocardiography

Ecocardiografia

Gatos

Hypertrophic cardiomyopathy

Maine Coon

Maine Coon

Tissue Doppler

Family communication of genetic risk for sudden cardiac death

Shah, Lisa Lynn

01 May 2017

Background: Hypertrophic Cardiomyopathy (HCM) and Long QT Syndrome (LQTS) are genetic cardiovascular diseases that cause sudden cardiac death. When an individual is diagnosed with an inherited disease such as HCM/LQTS it is critical that their biological relatives are notified of their increased risk. Newly diagnosed individuals in turn notify other at-risk family members through a successive process called cascade screening. This facilitates screening of at-risk biological relatives through genetic testing and/or clinical testing, and treatment for HCM/LQTS prior to development of life-threatening complications. However, for cascade screening to detect all potential cases the disease risk must be effectively communicated to all at-risk relatives. The responsibility for notifying family members of this risk largely falls to the first person diagnosed in the family (proband). Empiric evidence suggests that around half of at-risk relatives are not screened in accordance with cascade screening recommendations, potentially due to information about HCM/LQTS risk not being communicated effectively in their families. Factors have been identified that influence communication about genetic risk in families with non-cardiac disease; however, it is not known if or how these factors apply in families with genetic cardiac disease. These include network factors, which describe characteristics of relationships between family members and non-network factors, which describe characteristics of individuals including individual factors, disease factors, and sociocultural factors. There is a critical need to understand communication in families with HCM/LQTS in order to facilitate effective genetic risk communication in families, improve adherence to cascade screening recommendations, and prevent death and complications from cardiovascular diseases. Objectives: The purpose of this study was to improve our understanding of the relationships among network and non-network factors and communication of genetic risk for HCM/LQTS between probands and their relatives. I proposed the following aims: Aim 1: Describe family social network structures and communication paths about risk for HCM/LQTS from probands to their relatives. Aim 2: Identify which network and non-network factors are associated with who is told about risk for HCM/LQTS. Methods: The sample for this study included individuals with HCM or LQTS recruited through the University of Iowa Cardiology Clinics (UI) and the University of Wisconsin Inherited Arrhythmia Clinic (UW). Data were collected using a structured interview, family pedigree, and survey. Analysis included egocentric social network analysis, descriptive, bivariate, and multilevel logit regression modeling. Results: Participants in this study had an average of 24 living at-risk relatives in their families. Overall, just over half (52%) of these at-risk relatives had been reported to have been told about their risk. However, within families, the percentage of relatives told about their risk ranged from 0%-100%. Ninety percent of first-degree relatives were told about their risk, 61% of second-degree relatives were told and 33% of third-degree relatives were told. Recruitment site affiliation was determined to be a confounder and so analyses were calculated separately for UI and UW. In both the UI and UW samples, network factors including closer geographic distance, increased emotional closeness, increased relationship quality, increased frequency of communication, higher betweenness centrality, and closer degree of biological relation were independently associated with increased odds of communication of risk. In the UI sample, non-network factors that were independently associated with increased odds of communication of risk included younger age at diagnosis; having LQTS; having positive genetic test results; having an ICD; younger current age; being female; having increased role limitations due to physical functioning; feeling anxious about telling family members about risk; feeling communication was a burden; feeling that communication was a responsibility or duty; being happy to be able to share important information; and identifying financial issues, pregnancies, or upcoming marriages as playing a role in communication. In a multivariate model, increased frequency of communication, closer degree of biological relation, having an ICD, and identifying financial issues and pregnancies as contributors to communication were significantly associated with communication of genetic risk information. In the UW sample, non-network factors that were independently associated with increased odds of communication of risk included younger age, decreased emotional wellbeing, increased role limitations due to emotional wellbeing, and decreased energy and fatigue. In a multivariate model, increased frequency of communication and closer degree of biological relation were significantly associated with communication. Although over half of at-risk relatives were told about their risk, just over half of those (53.8%) were reported to have screened for disease, which represents 27% of all at-risk relatives. Of those tested, 35% were reported as diagnosed with HCM/LQTS. Conclusion: Communication of genetic risk for HCM/LQTS in families is inadequate and contributes to the problem of relatives not being screened for disease. Insight on the factors that influence communication in families at risk of sudden cardiac death can guide development of interventions, policies, and future research aimed at improving genetic risk communication and cascade screening, and preventing death and complications from inherited cardiac diseases. This research is applicable for genetic conditions where population based screening methods are not effective and rely on families to communicate risk and need for screening.

cascade screening

hypertrophic cardiomyopathy

inherited cardiac conditions

long QT syndrome

risk communication

Nursing

Methods for comprehensive transcriptome analysis using next-generation sequencing and application in hypertrophic cardiomyopathy

Christodoulou, Danos C.

08 October 2013

Characterization of the RNA transcriptome by next-generation sequencing can produce an unprecedented yield of information that provides novel biologic insights. I describe four approaches for sequencing different aspects of the transcriptome and provide computational tools to analyze the resulting data. Methods that query the dynamic range of gene expression, low expressing transcripts, micro RNA levels, and start-site usage of transcripts are described.

Genetics

fhl1

genetic modifier

hypertrophic cardiomyopathy

inherited cardiomyopathies

next-generation sequencing

rna-seq

Expanding techniques and indications for multisite pacing in heart failure

Rogers, Dominic Piers Scott

January 2013

No description available.

610

Ecocardiografia tecidual em gatos da raça Maine Coon geneticamente testados para a cardiomipatia hipertrófica / Tissue Doppler echocardiography in Maine Coon cats genetically tested for hypertrophic cardiomyopathy

Arine Pellegrino

28 January 2011

A cardiomiopatia hipertrófica (CMH) é a principal cardiopatia dos felinos e é caracterizada por hipertrofia miocárdica concêntrica, sem dilatação ventricular. Disfunções miocárdicas ocorrem em gatos com CMH, mas pouco se conhece a respeito destas alterações nos estágios iniciais da afecção. Em gatos da raça Maine Coon, a mutação no gene MyBPC-A31P está relacionada com a CMH de origem familial, porém, a correlação exata entre o genótipo e o fenótipo ainda é inconclusiva. A ecocardiografia tecidual é uma modalidade não invasiva que permite avaliação da função miocárdica e é mais sensível que a ecocardiografia convencional. Para avaliar a função sistólica e diastólica, antes ou após a ocorrência de hipertrofia ventricular, gatos da raça Maine Coon (n=57), geneticamente testados para a mutação, foram avaliados por meio de ecocardiografia convencional e tecidual (nas modalidades Doppler tecidual pulsado, Doppler tecidual colorido e strain). Posteriormente, foram fenotipicamente classificados em: normais (n=45), suspeitos (n=7) e acometidos pela CMH (n=5); e genotipicamente classificados em: negativos (n=28), heterozigotos (n=26) e homozigotos para a mutação (n=3). Valores de velocidades miocárdicas (Doppler tecidual pulsado e colorido) e valores de strain, medidos na região basal e média do septo interventricular (SIV), da parede livre do ventrículo esquerdo (PVE), da parede anterior do ventrículo esquerdo (PAVE), da parede posterior do ventrículo esquerdo (PPVE) e do segmento radial da PVE, foram comparados nos diferentes grupos. Observou-se que as velocidades longitudinais Em (Doppler tecidual pulsado) na região média da PVE foram menores nos gatos com CMH quando comparados com suspeitos e normais. Os valores de Em/Am (Doppler tecidual colorido), na região basal do SIV, foram inferiores nos gatos com CMH quando comparados com suspeitos e normais. A relação E/Em (Doppler tecidual colorido), na região basal do SIV, foi maior nos gatos com CMH em relação aos suspeitos e normais. E os valores de Sm (Doppler tecidual colorido), em região basal da PVE, foram menores nos gatos heterozigotos em relação aos negativos, ambos sem hipertrofia ventricular. Observou-se correlação positiva entre a ocorrência de fusão das ondas Em e Am e a frequência cardíaca; e correlação positiva entre valores de Sm e Em e a frequência cardíaca (Doppler tecidual pulsado e colorido). Enquanto à ecocardiografia convencional observou-se um estado de contratilidade aparentemente normal, os valores de strain (em região média do SIV) nos gatos com CMH foram inferiores aos dos gatos normais. Valores de strain (em região basal da PAVE) também foram menores nos gatos heterozigotos em relação aos negativos, antes mesmo da hipertrofia ventricular. Observou-se correlação negativa entre valores de strain e espessura miocárdica. A ecocardiografia tecidual é uma nova modalidade ecocardiográfica reprodutível em gatos que, isoladamente, não permite a identificação de gatos com mutação antes do desenvolvimento de hipertrofia. O strain possibilita a detecção de anormalidades sistólicas em gatos da raça Maine Coon, apesar da aparente normalidade à ecocardiografia convencional. Apesar da expectativa em relação ao uso da ecocardiografia tecidual para a identificação precoce de indivíduos portadores da CMH, ainda há necessidade de estudos mais extensos e com maior número de indivíduos. / Hypertrophic cardiomyopathy (HCM) is the most common feline heart disease and is characterized by increased cardiac mass with a hypertrophied nondilated left ventricle. Myocardial dysfunction occurs in cats with HCM but less is known about dysfunctions in initial stages of HCM. A mutation in MYBPC-A31P gene has been identified in a colony of Maine Coon cats with HCM. However, the close correlation between genotype and phenotype still be inconclusive. Myocardial analysis by tissue Doppler imaging (TDI) is a noninvasive echocardiographic method to assess systolic and diastolic function that is more sensitive than conventional echocardiography. To evaluate diastolic and systolic function in cats with mutation, with or without ventricular hypertrophy, Maine Coon cats (n=57) were screened for mutation and examined with both echocardiography and TDI (pulsed tissue Doppler, color tissue Doppler and Strain methods). Then, were phenotypically classified in: normal (n=45), suspects (n=7) and HCM group (n=5); and genotypically classified in: negative (n=28), heterozygous (n=26) and homozygous group (n=3). Myocardial velocities (by pulsed and color tissue Doppler imaging) and peak myocardial strain, measured in the basal and mildventricular segment of the interventricular septal wall (IVS), left ventricular free wall (LVW), left ventricular anterior wall (LVAW), left ventricular posterior wall (LVPW) and radial segment of LVW, was compared among different groups. A decreased longitudinal Em velocities (pulsed tissue Doppler) at the mildventricular segment of LVW was observed in HCM cats compared with suspects and normal cats. A decreased longitudinal Em/Am (color tissue Doppler) at the basal segment of IVS was observed in HCM cats compared with suspects and normal cats. A significant increased longitudinal E/Em (color tissue Doppler) at the basal segment of IVS was observed in HCM cats compared with suspects and normal cats. And a significant decreased longitudinal Sm (color tissue Doppler) at the basal segment of the LVW was observed in heterozygous cats compared with negative cats, both without hypertrophy. There was a positive correlation between summated early and late diastolic velocities (EmAm) and heart rate; and a positive correlation between Sm and Em velocities and heart rate, both in pulsed and in color TDI. Whereas conventional echocardiography demonstrated an apparently normal contractile state, myocardial strain (at mildventricular segment of IVS) in HCM cats was decreased compared with normal group. Myocardial strain (at basal segment of LVAW) also was decreased in heterozygous cats compared with negative group; and was decreased in heterozygous cats compared with negative group, both without ventricular hypertrophy. And there was a negative correlation between strain values and wall thickness. TDI analyses are a new, valuable and reproducible method in cats that alone is not able to identify cats with mutation before myocardial hypertrophy. Strain method allows noninvasive detection of abnormal systolic deformation in Maine Coons cats with HCM mutation despite apparently normal left ventricular systolic function. Despite high expectations regarding the use of TDI for early identification of individuals with HCM, there is still need for larger studies with greater numbers of individuals.

Cardiomiopatia hipertrófica

Doppler tecidual

Ecocardiografia

Gatos

Maine Coon

Cats

Echocardiography

Hypertrophic cardiomyopathy

Maine Coon

Tissue Doppler

Avaliação genética de gatos da raça Persa: mapeamento da mutação relacionada à cardiomiopatia hipertrófica de origem familial / Genetic evaluation of Persian cats: screening of hypertrophic cardiomyopathy mutation.

Arine Pellegrino

05 November 2014

A cardiomiopatia hipertrófica (CMH) é a principal cardiopatia dos felinos, caracterizada por hipertrofia ventricular esquerda, sem dilatação. A prevalência em humanos é de um a cada 500 indivíduos e, em pelo menos 60% dos casos, a doença é de origem familial. Há mais de 1400 mutações em mais de 11 genes que codificam proteínas do sarcômero relacionadas à CMH. Em algumas famílias de gatos, a CMH é transmitida de forma autossômica dominante sendo muito similar à humana. No Maine Coon, redução na miomesina e mutação no gene que codifica a proteína C miosina ligante (MYBPC3) são alterações encontradas nos acometidos pela CMH. No Ragdoll, a CMH está relacionada com mutação no mesmo gene, porém em um códon diferente e altamente conservado na espécie. Em outras raças como Persa, British Shorthair, Norwegian Forest também há evidências da CMH familial, porém não há comprovação do tipo de herança envolvida. No presente estudo, uma população de 100 gatos da raça Persa foi avaliada por meio de exames ecocardiográfico, eletrocardiográfico, laboratoriais, mesuração da pressão arterial e pesquisa da mutação relacionada à doença renal policística (PKD), prevalente em gatis de Persas. Os animais foram classificados quanto à presença ou não da CMH e, após seleção dos grupos experimentais (20 gatos sem CMH e 22 gatos com CMH), amostras de sangue foram submetidas à extração do DNA, genotipagem pela técnica de PCR e sequenciamento dos genes da alfa-actina cardíaca (exon 5 do gene ACTC1) e da proteína C miosina ligante (exon 27 do gene MYBPC3), com posterior correlação das mutações com a presença da afecção. À avaliação da população total, a CMH foi mais prevalente em gatos machos e de maior faixa etária; ocorreu em 22 animais; e a forma assimétrica com hipertrofia miocárdica em região septal basal foi a mais comum na raça. A presença de mutação relacionda à PKD foi mais comum nos gatos com hipertrofia ventricular, apesar dos mesmos apresentarem pressão arterial e função renal normais. Foi identificado um polimorfismo de nucleotídeo único (SNP) na posição 890 do exon 5 do gene ACTC1 e três SNP no intron 5-6 do mesmo gene. Nenhum polimorfismo, adição ou deleção foi observado em outras regiões do gene ACTC1 ou no gene MYBPC3. Apesar dos SNP observados no estudo, os mesmos não se enquadram nos critérios de mutação causal da CMH porque não provocam mudança em aminoácidos e não ocorreram exclusivamente em animais com CMH. Desta forma, a mutação causal da CMH em gatos da raça Persa não foi elucidada e mutações nestes dois exons de genes cardíacos não parecem ser a causa da cardiomiopatia na referida raça. Avaliações de genes cardíacos adicionais são necessárias para a identificação da causa molecular desta cardiopatia no Persa. Em relação aos resultados encontrados nos gatos PKD positivos, há necessidade de mais estudos para avaliar a relação causal (PKD e hipertrofia) ou associação genética entre ambas. Faz-se necessária a avaliação cardiológica de gatos PKD positivos, bem como é necessário incluir a PDK como diagnóstico diferencial da CMH no Persa. / Hypertrophic cardiomyopathy (HCM) is the most important feline heart disease and it is characterized by ventricular hypertrophy in absence of dilated left ventricle. In humans, the prevalence is 1 to 500 individuals and the familial HCM occurs in at least 60% of cases. There are more than 1400 mutations in more than 11 sarcomeres genes related to HCM. In some families of cats, HCM is an autosomal dominant genetic disease very similar to the human HCM. Reduction in miomesine and a mutation in myosin binding protein C gene (MYBPC3) are observed in Maine Coon cats with HCM. In Ragdoll cats, HCM is associated with a mutation in the same gene, but in a different codon highly conserved in feline species. In other breeds such as Persian, British Shorthair and Norwegian Forest there is also evidence of familial HCM, but the type of genetic inheritance is unknown. In this study, a population of 100 Persian cats was assessed by: echocardiography, electrocardiography, laboratorial tests, blood pressure determination and genetic test for the presence of the polycystic kidney disease (PKD) mutation, common in Persians. The animals were classified according to the presence or not of HCM. Blood samples from experimental groups (20 cats without HCM and 22 cats with HCM) were subjected to DNA extraction, genotyping by PCR and sequencing of cardiac alpha-actin gene (exon 5 of ACTC1) and myosin binding protein C gene (exon 27 of MYBPC3) with subsequent correlation with the presence of mutations and HCM. In the evaluated population, HCM was more prevalent in older and male cats; it occurred in 22 animals; and the asymmetric hypertrophy at basal region of septum was the most common. The PKD mutation was more common in cats with left ventricular hypertrophy, despite they presenting normal blood pressure and renal function. One single nucleotide polymorphism (SNP) at position 890 of exon 5 of the gene ACTC1 and three SNP in intron 5-6 of the same gene were identified. No polymorphism, addition or deletion was observed in other regions of the gene ACTC1 or MYBPC3 gene. Despite the SNP observed in the study, they do not fit the criteria of HCM causal mutation because they do not cause changes in amino acids and do not occurred exclusively in animals with HCM. Thus, a causal mutation of HCM in Persians cat has not been elucidated and mutations in these two exons of cardiac genes do not seem to be the cause of HCM in this breed. Additional screening of cardiac genes is necessary to identify the molecular cause of this feline disease in Persian cats. Regarding the results founded in PKD positive cats, it is important for further studies to evaluate the genetic association or causal relationship (PKD and hypertrophy). The cardiologic evaluation of PKD positive cats is necessary, and the PDK must be included as a differential diagnosis of HCM in Persian.

Cardiomiopatia hipertrófica

Ecocardiografia

Gatos

Genética

Persa

Sequenciamento

Cats

Echocardiography

Genetic

Hypertrophic cardiomyopathy

Persian

Sequence

The Tell–Tale Cardiac Thin Filament Model: An Investigation into the Dynamics of Contraction and Relaxation

Williams, Michael Ryan, Williams, Michael Ryan

January 2017

The correct function of cardiac sarcomeric proteins allow for people to maintain quality of life. However, mutations of the cardiac sarcomeric proteins can result in remodeling of the heart which typically results in death. I present a full atomistic cardiac thin filament model that I have developed and three studies that I conducted while at the University of Arizona, while pursuing my doctoral degree in chemistry The goal was to develop the model to be able to study the effects of the mutations on the thin filament proteins. First, I present the long process of developing the model that is still evolving as new information is available. Second, I present the study of two mutants, the troponin T R92L mutant and the tropomyosin D230N mutant. Molecular dynamics was used to simulate the wild–type and mutant versions of the model which resulted in a visualization of the change of interaction between the tropomyosin and troponin, specifically at the overlap region. Third, I present the study of calcium release which is the "gatekeeper" to cardiac contraction. Steered molecular dynamics was utilized to find a previously unseen molecular mechanism that alters the rate of calcium release depending on the mutant. Fourth, I present the study of the mechanism of the tropomyosin transition across the actin filament, in which a longitudinal transition is favored. The studies helped to provide an atomistic level understanding of the cardiac thin filament as well as the methodology to which the mutations disrupt the natural functions of the sarcomeric proteins. The new results of the research can provide new insight into how the effects of the disease causing mutations can be mitigated, potentially extending the life of people with the conditions.

Calcium Regulation

Cardiac Thin Filament

Enhanced Sampling Techniques

Familial hypertrophic cardiomyopathy

High Performance Computing

Molecular Dynamics

Hypertrophie ventriculaire gauche physiologique ou pathologique : Intérêt d’une approche multiparamétrique / Physiological or pathological left ventricular hypertrophy : interest of a multi-parametric approach

Schnell, Frédéric

17 November 2015

Introduction : Le diagnostic de cardiomyopathie hypertrophique (CMH) est difficile chez l’athlète. En effet, le remodelage physiologique induit par l’entraînement physique intense entraîne des modifications électriques et morphologiques qui peuvent mimer une cardiomyopathie. Or il est indispensable de poser le diagnostic de cardiomyopathie avec certitude chez un athlète. Ne pas contre-indiquer un athlète avec une cardiomyopathie l’expose à un risque de mort subite, mais poser un diagnostic par excès l’expose à de lourdes répercussions tant professionnelles que sociales. Méthodes : (1) Nous avons cherché à améliorer les critères ECG actuels de détection de cardiomyopathie chez l’athlète à partir d’une cohorte multicentrique d’athlètes et de CMH. (2) Nous avons cherché à déterminer quel bilan complémentaire réaliser en cas d’anomalie ECG par un suivi longitudinal d’athlètes avec ondes T négatives. (3) Nous avons essayé de mieux caractériser le phénotype des athlètes atteints de CMH par rapport aux CMH sédentaires dans une cohorte multicentrique. (4) Nous avons tenté de déterminer si l’utilisation des nouvelles techniques d’imagerie de déformation myocardique permettait d’améliorer la pertinence diagnostique et pronostique en cas de CMH dans une cohorte de CMH et d’athlètes rennais. Résultats : Nous avons proposé une nouvelle classification ECG permettant de mieux identifier les athlètes avec modifications ECG non pathologiques sans diminuer pour autant la capacité à détecter les CMH. En cas d’ondes T négatives chez l’athlète, nous avons démontré qu’il était indispensable de réaliser une IRM myocardique. En effet l’échocardiographie peut être prise en défaut dans près de 35% des cas. Néanmoins, les critères diagnostiques actuels de CMH peuvent être pris en défaut; en effet les athlètes avec une CMH ont un phénotype différent des CMH sédentaires avec une meilleure fonction systolique, notamment longitudinale, et diastolique. L’évaluation de la fonction longitudinale à l’effort et l’évaluation de la dispersion mécanique sont des paramètres qui semblent prometteurs en terme de diagnostic. En effet l’altération la fonction longitudinale semble être en lien avec la fibrose myocardique. L’échocardiographie d’effort, notamment la présence d’une insuffisance mitrale à l’effort, semble être un facteur pronostic important dans les CMH. Conclusions : les travaux réalisés ont permis de développer des outils pour mieux différencier une hypertrophie ventriculaire gauche (HVG) pathologique d’une HVG physiologique mais également pour mieux caractériser cette HVG et déterminer avec plus de précision le pronostic des CMH . / Introduction: the diagnosis of hypertrophic cardiomyopathy (HCM) in athlete is difficult. Indeed, intense sports practice induces an electrical and morphological physiological remodeling which can be difficult to differentiate from the changes induced in pathology. However, it is essential to diagnose an athlete with a cardiomyopathy. Indeed, in case of underlying cardiomyopathy the athlete will be at risk of sudden cardiac death, but an excessive over diagnosis has strong professional and social consequences. Methods: (1) we have tried to improve the ECG criteria’s, which enable the differentiation between ECG changes induced by exercise and the ECG changes induced by an underlying cardiomyopathy. (2) We tried to define the best investigation algorithm in case of abnormal ECG changes in athletes. (3) We tried to improve the characterization of the phenotype of athletes with HCM as compared to sedentary HCM. (4) We tried to investigate if the use of new imaging technics, i.e. speckle tracking, might improve the diagnostic accuracy and enable a better prognostic evaluation in HCM. Results: We have proposed a new classification of ECG in athletes enabling to decrease the rate of false positive ECG in athletes without decreasing its diagnostic accuracy in HCM. In case of pathological T wave inversion (PTWI) in athletes, we demonstrated that a CMR is mandatory, as echocardiography missed a diagnosis of pathology in 35% of PTWI athletes. Nevertheless, the diagnosis of HCM with current criteria’s of HCM can be challenging. Indeed, HCM athletes have a different phenotype from HCM sedentary, with a better systolic and diastolic function; they also have a better longitudinal function. The assessment of longitudinal function during exercise and mechanical dispersion are promising tool for the diagnosis of HCM in athletes. Indeed, the alteration of longitudinal strain is related to myocardial fibrosis. Exercise echocardiography, i.e. exercise mitral insufficiency, seems to be a prognostic factor in HCM patients. Conclusions: Ours results enabled to develop tools which might help to better differentiate pathological and physiological left ventricular hypertrophy (LVH); but also to better characterize LVH and the prognosis in HCM patients.

Athlète

Hypertrophie ventriculaire

Cardiopathie hypertrophique

Déformation myocardique

Athlete

Left ventricular hypertrophy

Hypertrophic cardiomyopathy

Speckle tracking

Modeling Hypertrophic Cardiomyopathy Using Genome-Edited Human Induced Pluripotent Stem Cell-Derived Cardiomyocytes in Response to Dynamic Mechanotransduction

Strimaityte, Dovile

05 1900

Familial hypertrophic cardiomyopathy (HCM) is a genetic disease largely caused by a mutation in myosin binding protein C (MYBPC3) and it affects about 1:500 population leading to arrhythmic sudden death, heart failure, and atrial fibrillation. MYBPC3 activates calcium-induced actin-myosin filament sliding within the cardiac sarcomere, creating the force necessary for heart contraction. The underlying molecular mechanisms causing HCM phenotype remain elusive, therefore, there is an urgent need for a reliable in vitro human HCM model to investigate the pathogenesis of HCM. This study utilized isogenic human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) with MYBPC3 gene mutation (wildtype, heterozygous, homozygous) and further micropatterned them into fiber-like structures on polyacrylamide hydrogels of physiological and fibrotic-like stiffnesses. Cells were cultured for an extended culture time up to 60 days and their morphology/attachment, contractility, and calcium transient were extensively and carefully evaluated. It was found that MYBPC3 knockout cells maintained the highest contraction amplitude, but had increased contraction, and relaxation durations, decreased calcium transient amplitude, as well as time to peak and decay times over the culture period in comparison to the isogenic wildtype. Overall, this study demonstrates that hiPSC-CMs can be successfully patterned and cultured for an extended time on hydrogels forming end-to-end connections, which can be served as a simple yet effective in vitro human model for studying mechanical dysfunction of HCM.

Hypertrophic Cardiomyopathy

hiPSCs

hiPSC-CMs

MYBPC3

Cardiomyocytes

Contractility

Calcium Transient

Mechanotransduction

Hydrogel

HCM Modeling

Micropatterning