Manish K. Gupta

Determination of the critical residues responsible for cardiac myosin binding protein C's interactions

Despite early demonstrations of myosin binding protein Cs (MyBP-C) interaction with actin, different investigators have reached different conclusions regarding the relevant and necessary domains mediating this binding. Establishing the detailed structure-function relationships is needed to fully understand cMyBP-Cs ability to impact on myofilament contraction as mutations in different domains are causative for familial hypertrophic cardiomyopathy. We defined cMyBP-Cs N-terminal structural domains that are necessary or sufficient to mediate interactions with actin and/or the head region of the myosin heavy chain (S2-MyHC). Using a combination of genetics and functional assays, we defined the actin binding site(s) present in cMyBP-C. We confirmed that cMyBP-Cs C1 and m domains productively interact with actin, while S2-MyHC interactions are restricted to the m domain. Using residue-specific mutagenesis, we identified the critical actin binding residues and distinguished them from the residues that were critical for S2-MyHC binding. To validate the structural and functional significance of these residues, we silenced the endogenous cMyBP-C in neonatal rat cardiomyocytes (NRC) using cMyBP-C siRNA, and replaced the endogenous cMyBP-C with normal or actin binding-ablated cMyBP-C. Replacement with actin binding-ablated cMyBP-C showed that the mutated protein did not incorporate into the sarcomere normally. Residues responsible for actin and S2-MyHC binding are partially present in overlapping domains but are unique. Expression of an actin binding-deficient cMyBP-C resulted in abnormal cytosolic distribution of the protein, indicating that interaction with actin is essential for the formation and/or maintenance of normal cMyBP-C sarcomeric distribution.

Sumo E2 Enzyme UBC9 Is Required for Efficient Protein Quality Control in Cardiomyocytes

Rationale: Impairment of proteasomal function is pathogenic in several cardiac proteinopathies and can eventually lead to heart failure. Loss of proteasomal activity often results in the accumulation of large protein aggregates. The ubiquitin proteasome system (UPS) is primarily responsible for cellular protein degradation, and although the role of ubiquitination in this process is well studied, the function of an ancillary post-translational modification, SUMOylation, in protein quality control is not fully understood. Objective: To determine the role of ubiquitin-conjugating enzyme 9 (UBC9), a small ubiquitin-like modifier–conjugating enzyme, in cardiomyocyte protein quality control. Methods and Results: Gain- and loss-of-function approaches were used to determine the importance of UBC9. Overexpression of UBC9 enhanced UPS function in cardiomyocytes, whereas knockdown of UBC9 by small interfering RNA caused significant accumulations of aggregated protein. UPS function and relative activity was analyzed using a UPS reporter protein consisting of a short degron, CL1, fused to the COOH-terminus of green fluorescent protein (GFPu). Subsequently, the effects of UBC9 on UPS function were tested in a proteotoxic model of desmin-related cardiomyopathy, caused by cardiomyocyte-specific expression of a mutated &agr;B crystallin, CryABR120G. CryABR120G expression leads to aggregate formation and decreased proteasomal function. Coinfection of UBC9-adenovirus with CryABR120G virus reduced the proteotoxic sequelae, decreasing overall aggregate concentrations. Conversely, knockdown of UBC9 significantly decreased UPS function in the model and resulted in increased aggregate levels. Conclusions: UBC9 plays a significant role in cardiomyocyte protein quality control, and its activity can be exploited to reduce toxic levels of misfolded or aggregated proteins in cardiomyopathy.

An Endogenously Produced Fragment of Cardiac Myosin-Binding Protein C Is Pathogenic and Can Lead to Heart Failure

Rationale: A stable 40-kDa fragment is produced from cardiac myosin-binding protein C when the heart is stressed using a stimulus, such as ischemia-reperfusion injury. Elevated levels of the fragment can be detected in the diseased mouse and human heart, but its ability to interfere with normal cardiac function in the intact animal is unexplored. Objective: To understand the potential pathogenicity of the 40-kDa fragment in vivo and to investigate the molecular pathways that could be targeted for potential therapeutic intervention. Methods and Results: We generated cardiac myocyte–specific transgenic mice using a Tet-Off inducible system to permit controlled expression of the 40-kDa fragment in cardiomyocytes. When expression of the 40-kDa protein is induced by crossing the responder animals with tetracycline transactivator mice under conditions in which substantial quantities approximating those observed in diseased hearts are reached, the double-transgenic mice subsequently experience development of sarcomere dysgenesis and altered cardiac geometry, and the heart fails between 12 and 17 weeks of age. The induced double-transgenic mice had development of cardiac hypertrophy with myofibrillar disarray and fibrosis, in addition to activation of pathogenic MEK–ERK pathways. Inhibition of MEK–ERK signaling was achieved by injection of the mitogen-activated protein kinase (MAPK)/ERK inhibitor U0126. The drug effectively improved cardiac function, normalized heart size, and increased probability of survival. Conclusions: These results suggest that the 40-kDa cardiac myosin-binding protein C fragment, which is produced at elevated levels during human cardiac disease, is a pathogenic fragment that is sufficient to cause hypertrophic cardiomyopathy and heart failure.

Evidence for the Role of BAG3 in Mitochondrial Quality Control in Cardiomyocytes.

Mitochondrial abnormalities impact the development of myofibrillar myopathies. Therefore, understanding the mechanisms underlying the removal of dysfunctional mitochondria from cells is of great importance toward understanding the molecular events involved in the genesis of cardiomyopathy. Earlier studies have ascribed a role for BAG3 in the development of cardiomyopathy in experimental animals leading to the identification of BAG3 mutations in patients with heart failure which may play a part in the onset of disease development and progression. BAG3 is co‐chaperone of heat shock protein 70 (HSP70), which has been shown to modulate apoptosis and autophagy, in several cell models. In this study, we explore the potential role of BAG3 in mitochondrial quality control. We demonstrate that siRNA mediated suppression of BAG3 production in neonatal rat ventricular cardiomyocytes (NRVCs) significantly elevates the level of Parkin, a key component of mitophagy. We found that both BAG3 and Parkin are recruited to depolarized mitochondria and promote mitophagy. Suppression of BAG3 in NRVCs significantly reduces autophagy flux and eliminates clearance of Tom20, an essential import receptor for mitochondria proteins, after induction of mitophagy. These observations suggest that BAG3 is critical for the maintenance of mitochondrial homeostasis under stress conditions, and disruptions in BAG3 expression impact cardiomyocyte function. J. Cell. Physiol. 232: 797–805, 2017.

UBC9-Mediated Sumoylation Favorably Impacts Cardiac Function in Compromised Hearts

RATIONALE SUMOylation plays an important role in cardiac function and can be protective against cardiac stress. Recent studies show that SUMOylation is an integral part of the ubiquitin proteasome system, and expression of the small ubiquitin-like modifier (SUMO) E2 enzyme UBC9 improves cardiac protein quality control. However, the precise role of SUMOylation on other protein degradation pathways, particularly autophagy, remains undefined in the heart. OBJECTIVE To determine whether SUMOylation affects cardiac autophagy and whether this effect is protective in a mouse model of proteotoxic cardiac stress. METHODS AND RESULTS We modulated expression of UBC9, a SUMO E2 ligase, using gain- and loss-of-function in neonatal rat ventricular cardiomyocytes. UBC9 expression seemed to directly alter autophagic flux. To confirm this effect in vivo, we generated transgenic mice overexpressing UBC9 in cardiomyocytes. These mice have an increased level of SUMOylation at baseline and, in confirmation of the data obtained from neonatal rat ventricular cardiomyocytes, demonstrated increased autophagy, suggesting that increased UBC9-mediated SUMOylation is sufficient to upregulate cardiac autophagy. Finally, we tested the protective role of SUMOylation-mediated autophagy by expressing UBC9 in a model of cardiac proteotoxicity, induced by cardiomyocyte-specific expression of a mutant α-B-crystallin, mutant CryAB (CryAB(R120G)), which shows impaired autophagy. UBC9 overexpression reduced aggregate formation, decreased fibrosis, reduced hypertrophy, and improved cardiac function and survival. CONCLUSIONS The data showed that increased UBC9-mediated SUMOylation is sufficient to induce relatively high levels of autophagy and may represent a novel strategy for increasing autophagic flux and ameliorating morbidity in proteotoxic cardiac disease.

GRP78 Interacting Partner Bag5 Responds to ER Stress and Protects Cardiomyocytes From ER Stress‐Induced Apoptosis

Bag5 is a member of the BAG family of molecular chaperone regulators and is unusual in that it consists of five BAG domains, which function as modulators of chaperone activity. Bag family proteins play a key role in cellular as well as in cardiac function and their differential expression is reported in heart failure. In this study, we examined the importance of a Bag family member protein, Bag5, in cardiomyocytes during endoplasmic reticulum (ER) stress. We found that expression of Bag5 in cardiomyocytes is significantly increased with the induction of ER stress in a time dependent manner. We have taken gain‐in and loss‐of functional approaches to characterize Bag5 protein function in cardiomyocytes. Adenoviral mediated expression of Bag5 significantly decreased cell death as well as improved cellular viability in ER stress. Along with this, ER stress‐induced CHOP protein expression is significantly decreased in cells that overexpress Bag5. Conversely, we found that siRNA‐mediated knockdown of Bag5 caused cell death, increased cytotoxicity, and decreased cellular viability in cardiomyocytes. Mechanistically, we found that Bag5 protein expression is significantly increased in the ER during ER stress and that this in turn modulates GRP78 protein stability and reduces ER stress. This study suggests that Bag5 is an important regulator of ER function and so could be exploited as a tool to improve cardiomyocyte function under stress conditions. J. Cell. Biochem. 117: 1813–1821, 2016.

Adeno-Associated Virus Serotype 9–Driven Expression of BAG3 Improves Left Ventricular Function in Murine Hearts With Left Ventricular Dysfunction Secondary to a Myocardial Infarction

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Dysregulation of Mitochondrial Bioenergetics and Quality Control by HIV-1 Tat in Cardiomyocytes†

Cardiovascular disease remains a leading cause of morbidity and mortality in HIV‐positive patients, even in those whose viral loads are well controlled with antiretroviral therapy. However, the underlying molecular events responsible for the development of cardiac disease in the setting of HIV remain unknown. The HIV‐encoded Tat protein plays a critical role in the activation of HIV gene expression and profoundly impacts homeostasis in both HIV‐infected cells and uninfected cells that have taken up released Tat via a bystander effect. Since cardiomyocyte function, including excitation‐contraction coupling, greatly depends on energy provided by the mitochondria, in this study, we performed a series of experiments to assess the impact of Tat on mitochondrial function and bioenergetics pathways in a primary cell culture model derived from neonatal rat ventricular cardiomyocytes (NRVCs). Our results show that the presence of Tat in cardiomyocytes is accompanied by a decrease in oxidative phosphorylation, a decline in the levels of ATP, and an accumulation of reactive oxygen species (ROS). Tat impairs the uptake of mitochondrial Ca2+ ([Ca2+]m) and the electrophysiological activity of cardiomyocytes. Tat also affects the protein clearance pathway and autophagy in cardiomyocytes under stress due to hypoxia‐reoxygenation conditions. A reduction in the level of ubiquitin along with dysregulated degradation of autophagy proteins including SQSTM1/p62 and a reduction of LC3 II were detected in cardiomyocytes harboring Tat. These results suggest that, by targeting mitochondria and protein quality control, Tat significantly impacts bioenergetics and autophagy resulting in dysregulation of cardiomyocyte health and homeostasis.

Making the connections: Autophagy and post-translational modifications in cardiomyocytes

ABSTRACT Cardiac proteins are subject to continuous stress and these intrinsic and extrinsic factors, both physiological and pathological can lead to protein misfolding. If the protein quality control (PQC) pathways are in any way compromised or their activities diminished, intracellular aggregates can form and a proteotoxic environment is generated, which contributes to cardiac disease and heart failure. We studied the role that SUMO post-translational modification plays in a proteotoxic cardiac environment. SUMOylation can have an integral role in controlling flux through the ubiquitin-proteasome system, and expression of the SUMO (small ubiquitin-like modifier) E2 enzyme UBE2I/UBC9 improves cardiac PQC. Our data focus on using gain- and loss-of-function approaches to modify UBE2I levels and measure the effects on cardiomyocyte autophagic flux. UBE2I expression does have an impact on macroautophagy/autophagy as increased SUMOylation results in increased autophagy. We show that increased SUMOylation is cardioprotective and can decrease morbidity in proteotoxic cardiac disease.

HIV-1 Nef-induced cardiotoxicity through dysregulation of autophagy

Cardiovascular disease is a leading cause of co-morbidity in HIV-1 positive patients, even those in whom plasma virus levels are well-controlled. The pathogenic mechanism of HIV-1-associated cardiomyopathy is unknown, but has been presumed to be mediated indirectly, owing to the absence of productive HIV-1 replication in cardiomyocytes. We sought to investigate the effect of the HIV-1 auxiliary protein, Nef, which is suspected of extracellular release by infected CD4+ T cells on protein quality control and autophagy in cardiomyocytes. After detection of Nef in the serum of HIV-1 positive patients and the accumulation of this protein in human and primate heart tissue from HIV-1/SIV-infected cells we employed cell and molecular biology approaches to investigate the effect of Nef on cardiomyocyte-homeostasis by concentrating on protein quality control (PQC) pathway and autophagy. We found that HIV-1 Nef-mediated inhibition of autophagy flux leads to cytotoxicity and death of cardiomyocytes. Nef compromises autophagy at the maturation stage of autophagosomes by interacting with Beclin 1/Rab7 and dysregulating TFEB localization and cellular lysosome content. These effects were reversed by rapamycin treatment. Our results indicate that HIV-1 Nef-mediated inhibition of cellular PQC is one possible mechanism involved in the development of HIV-associated cardiomyopathy.