Anil Singapuri

Prevention and reversal of cardiac hypertrophy by soluble epoxide hydrolase inhibitors

Sustained cardiac hypertrophy represents one of the most common causes leading to cardiac failure. There is emerging evidence to implicate the involvement of NF-κB in the development of cardiac hypertrophy. However, several critical questions remain unanswered. We tested the use of soluble epoxide hydrolase (sEH) inhibitors as a means to enhance the biological activities of epoxyeicosatrienoic acids (EETs) to treat cardiac hypertrophy. sEH catalyzes the conversion of EETs to form the corresponding dihydroxyeicosatrienoic acids. Previous data have suggested that EETs may inhibit the activation of NF-κB-mediated gene transcription. We directly demonstrate the beneficial effects of several potent sEH inhibitors (sEHIs) in cardiac hypertrophy. Specifically, we show that sEHIs can prevent the development of cardiac hypertrophy using a murine model of pressure-induced cardiac hypertrophy. In addition, sEHIs reverse the preestablished cardiac hypertrophy caused by chronic pressure overload. We further demonstrate that these compounds potently block the NF-κB activation in cardiac myocytes. Moreover, by using in vivo electrophysiologic recordings, our study shows a beneficial effect of the compounds in the prevention of cardiac arrhythmias that occur in association with cardiac hypertrophy. We conclude that the use of sEHIs to increase the level of the endogenous lipid epoxides such as EETs may represent a viable and completely unexplored avenue to reduce cardiac hypertrophy by blocking NF-κB activation.

Ablation of a Ca2+‐activated K+ channel (SK2 channel) results in action potential prolongation in atrial myocytes and atrial fibrillation

Small conductance Ca2+‐activated K+ channels (SK channels) have been reported in excitable cells, where they aid in integrating changes in intracellular Ca2+(Ca2+i) with membrane potential. We have recently reported the functional existence of SK2 channels in human and mouse cardiac myocytes. Moreover, we have found that the channel is predominantly expressed in atria compared to the ventricular myocytes. We hypothesize that knockout of SK2 channels may be sufficient to disrupt the intricate balance of the inward and outward currents during repolarization in atrial myocytes. We further predict that knockout of SK2 channels may predispose the atria to tachy‐arrhythmias due to the fact that the late phase of the cardiac action potential is highly susceptible to aberrant excitation. We take advantage of a mouse model with genetic knockout of the SK2 channel gene. In vivo and in vitro electrophysiological studies were performed to probe the functional roles of SK2 channels in the heart. Whole‐cell patch‐clamp techniques show a significant prolongation of the action potential duration prominently in late cardiac repolarization in atrial myocytes from the heterozygous and homozygous null mutant animals. Morover, in vivo electrophysiological recordings show inducible atrial fibrillation in the null mutant mice but not wild‐type animals. No ventricular arrhythmias are detected in the null mutant mice or wild‐type animals. In summary, our data support the important functional roles of SK2 channels in cardiac repolarization in atrial myocytes. Genetic knockout of the SK2 channels results in the delay in cardiac repolarization and atrial arrhythmias.

Functional Roles of a Ca2+-Activated K+ Channel in Atrioventricular Nodes

Since the first description of the anatomical atrioventricular nodes (AVNs), a large number of studies have provided insights into the heterogeneity of the structure as well as a repertoire of ion channel proteins that govern this complex conduction pathway between the atria and ventricles. These studies have revealed the intricate organization of multiple nodal and nodal-like myocytes contributing to the unique electrophysiology of the AVN in health and diseases. On the other hand, information regarding the contribution of specific ion channels to the function of the AVN remains incomplete. We reason that the identification of AVN-specific ion channels may provide a more direct and rational design of therapeutic target in the control of AVN conduction in atrial flutter/fibrillation, one of the most common arrhythmias seen clinically. In this study, we took advantage of 2 genetically altered mouse models with overexpression or null mutation of 1 of a small conductance Ca2+-activated K+ channel isoform, SK2 channel, and demonstrated robust phenotypes of AVN dysfunction in these experimental models. Overexpression of SK2 channels results in the shortening of the spontaneous action potentials of the AVN cells and an increase in the firing frequency. On the other hand, ablation of the SK2 channel results in the opposite effects on the spontaneous action potentials of the AVN. Furthermore, we directly documented the expression of SK2 channel in mouse AVN using multiple techniques. The new insights may have important implications in providing novel drug targets for the modification of AVN conduction in the treatment of atrial arrhythmias.

Cardiac Small Conductance Ca2+-Activated K+ Channel Subunits Form Heteromultimers via the Coiled-Coil Domains in the C Termini of the Channels

Rationale: Ca2+-activated K+ channels are present in a wide variety of cells. We have previously reported the presence of small conductance Ca2+-activated K+ (SK or KCa) channels in human and mouse cardiac myocytes that contribute functionally toward the shape and duration of cardiac action potentials. Three isoforms of SK channel subunits (SK1, SK2, and SK3) are found to be expressed. Moreover, there is differential expression with more abundant SK channels in the atria and pacemaking tissues compared with the ventricles. SK channels are proposed to be assembled as tetramers similar to other K+ channels, but the molecular determinants driving their subunit interaction and assembly are not defined in cardiac tissues. Objective: To investigate the heteromultimeric formation and the domain necessary for the assembly of 3 SK channel subunits (SK1, SK2, and SK3) into complexes in human and mouse hearts. Methods and Results: Here, we provide evidence to support the formation of heteromultimeric complexes among different SK channel subunits in native cardiac tissues. SK1, SK2, and SK3 subunits contain coiled-coil domains (CCDs) in the C termini. In vitro interaction assay supports the direct interaction between CCDs of the channel subunits. Moreover, specific inhibitory peptides derived from CCDs block the Ca2+-activated K+ current in atrial myocytes, which is important for cardiac repolarization. Conclusions: The data provide evidence for the formation of heteromultimeric complexes among different SK channel subunits in atrial myocytes. Because SK channels are predominantly expressed in atrial myocytes, specific ligands of the different isoforms of SK channel subunits may offer a unique therapeutic opportunity to directly modify atrial cells without interfering with ventricular myocytes.

α-Actinin2 cytoskeletal protein is required for the functional membrane localization of a Ca2+-activated K+ channel (SK2 channel)

The importance of proper ion channel trafficking is underpinned by a number of channel-linked genetic diseases whose defect is associated with failure to reach the cell surface. Conceptually, it is reasonable to suggest that the function of ion channels depends critically on the precise subcellular localization and the number of channel proteins on the cell surface membrane, which is determined jointly by the secretory and endocytic pathways. Yet the precise mechanisms of the entire ion channel trafficking pathway remain unknown. Here, we directly demonstrate that proper membrane localization of a small-conductance Ca2+-activated K+ channel (SK2 or KCa2.2) is dependent on its interacting protein, α-actinin2, a major F-actin crosslinking protein. SK2 channel localization on the cell-surface membrane is dynamically regulated, and one of the critical steps includes the process of cytoskeletal anchoring of SK2 channel by its interacting protein, α-actinin2, as well as endocytic recycling via early endosome back to the cell membrane. Consequently, alteration of these components of SK2 channel recycling results in profound changes in channel surface expression. The importance of our findings may transcend the area of K+ channels, given that similar cytoskeletal interaction and anchoring may be critical for the membrane localization of other ion channels in neurons and other excitable cells.

Adenylyl cyclase subtype-specific compartmentalization: differential regulation of L-type Ca2+ current in ventricular myocytes.

Rationale: Adenylyl cyclase (AC) represents one of the principal molecules in the &bgr;-adrenergic receptor signaling pathway, responsible for the conversion of ATP to the second messenger, cAMP. AC types 5 (ACV) and 6 (ACVI) are the 2 main isoforms in the heart. Although highly homologous in sequence, these 2 proteins play different roles during the development of heart failure. Caveolin-3 is a scaffolding protein, integrating many intracellular signaling molecules in specialized areas called caveolae. In cardiomyocytes, caveolin is located predominantly along invaginations of the cell membrane known as t-tubules. Objective: We take advantage of ACV and ACVI knockout mouse models to test the hypothesis that there is distinct compartmentalization of these isoforms in ventricular myocytes. Methods and Results: We demonstrate that ACV and ACVI isoforms exhibit distinct subcellular localization. The ACVI isoform is localized in the plasma membrane outside the t-tubular region and is responsible for &bgr;1-adrenergic receptor signaling–mediated enhancement of the L-type Ca2+ current (ICa,L) in ventricular myocytes. In contrast, the ACV isoform is localized mainly in the t-tubular region where its influence on ICa,L is restricted by phosphodiesterase. We further demonstrate that the interaction between caveolin-3 with ACV and phosphodiesterase is responsible for the compartmentalization of ACV signaling. Conclusions: Our results provide new insights into the compartmentalization of the 2 AC isoforms in the regulation of ICa,L in ventricular myocytes. Because caveolae are found in most mammalian cells, the mechanism of &bgr;- adrenergic receptor and AC compartmentalization may also be important for &bgr;-adrenergic receptor signaling in other cell types.Rationale: Adenylyl cyclase (AC) represents one of the principal molecules in the β-adrenergic receptor signaling pathway, responsible for the conversion of ATP to the second messenger, cAMP. AC types 5 (ACV) and 6 (ACVI) are the 2 main isoforms in the heart. Although highly homologous in sequence, these 2 proteins play different roles during the development of heart failure. Caveolin-3 is a scaffolding protein, integrating many intracellular signaling molecules in specialized areas called caveolae. In cardiomyocytes, caveolin is located predominantly along invaginations of the cell membrane known as t-tubules. Objective: We take advantage of AC V and AC VI knockout mouse models to test the hypothesis that there is distinct compartmentalization of these isoforms in ventricular myocytes. Methods and Results: We demonstrate that ACV and ACVI isoforms exhibit distinct subcellular localization. The ACVI isoform is localized in the plasma membrane outside the t-tubular region and is responsible for β1-adrenergic receptor signaling–mediated enhancement of the L-type Ca2+ current ( I Ca,L) in ventricular myocytes. In contrast, the ACV isoform is localized mainly in the t-tubular region where its influence on I Ca,L is restricted by phosphodiesterase. We further demonstrate that the interaction between caveolin-3 with ACV and phosphodiesterase is responsible for the compartmentalization of ACV signaling. Conclusions: Our results provide new insights into the compartmentalization of the 2 AC isoforms in the regulation of I Ca,L in ventricular myocytes. Because caveolae are found in most mammalian cells, the mechanism of β- adrenergic receptor and AC compartmentalization may also be important for β-adrenergic receptor signaling in other cell types. # Novelty and Significance {#article-title-41}

Zika Virus Tissue and Blood Compartmentalization in Acute Infection of Rhesus Macaques.

Animal models of Zika virus (ZIKV) are needed to better understand tropism and pathogenesis and to test candidate vaccines and therapies to curtail the pandemic. Humans and rhesus macaques possess similar fetal development and placental biology that is not shared between humans and rodents. We inoculated 2 non-pregnant rhesus macaques with a 2015 Brazilian ZIKV strain. Consistent with most human infections, the animals experienced no clinical disease but developed short-lived plasma viremias that cleared as neutralizing antibody developed. In 1 animal, viral RNA (vRNA) could be detected longer in whole blood than in plasma. Despite no major histopathologic changes, many adult tissues contained vRNA 14 days post-infection with highest levels in hemolymphatic tissues. These observations warrant further studies to investigate ZIKV persistence and its potential clinical implications for transmission via blood products or tissue and organ transplants.

Functional interaction with filamin A and intracellular Ca2+ enhance the surface membrane expression of a small-conductance Ca2+-activated K+ (SK2) channel

Significance The precise subcellular localization of ion channel proteins is necessary for the proper function of excitable cells. The trafficking of several ion channels is dependent on the interaction of the ion channel proteins with cytoskeletal proteins, underpinned by a number of diseases in which the defect lies with the interacting proteins. Here, we demonstrate the role of filamin A, a cytoskeletal protein, in augmenting the membrane expression of small-conductance, Ca2+-activated K+ channels (KCa2.2 or SK2) in atrial myocytes. We further demonstrate that SK2 channel trafficking is Ca2+-dependent in the presence of another cytoskeletal protein, α-actinin2, thereby establishing the role of filamin A, α-actinin2, and intracellular Ca2+ in trafficking of SK2 channels. The findings may have implications in other excitable cells. For an excitable cell to function properly, a precise number of ion channel proteins need to be trafficked to distinct locations on the cell surface membrane, through a network and anchoring activity of cytoskeletal proteins. Not surprisingly, mutations in anchoring proteins have profound effects on membrane excitability. Ca2+-activated K+ channels (KCa2 or SK) have been shown to play critical roles in shaping the cardiac atrial action potential profile. Here, we demonstrate that filamin A, a cytoskeletal protein, augments the trafficking of SK2 channels in cardiac myocytes. The trafficking of SK2 channel is Ca2+-dependent. Further, the Ca2+ dependence relies on another channel-interacting protein, α-actinin2, revealing a tight, yet intriguing, assembly of cytoskeletal proteins that orchestrate membrane expression of SK2 channels in cardiac myocytes. We assert that changes in SK channel trafficking would significantly alter atrial action potential and consequently atrial excitability. Identification of therapeutic targets to manipulate the subcellular localization of SK channels is likely to be clinically efficacious. The findings here may transcend the area of SK2 channel studies and may have implications not only in cardiac myocytes but in other types of excitable cells.

Expression and Roles of Cav1.3 (α1D) L-Type Ca2+ Channel in Atrioventricular Node Automaticity

Atrioventricular node (AV node) is the hub where electrical input from the atria is propagated and conveyed to the ventricles. Despite its strategic position and role in governing impulse conduction between atria and ventricles, there is paucity of data regarding the contribution of specific ion channels to the function of the AV node. Here, we examined the roles of Ca(v)1.3 L-type Ca(2+) channel in AV node by taking advantage of a mouse model with null mutation of Ca(v)1.3 (Ca(v)1.3(-/-)). Ca(v)1.3 null mutant mice show evidence of AV node dysfunction with AV block, suggesting the tissue-specific function of the Ca(v)1.3 channel. In keeping with this assertion, we demonstrate that Ca(v)1.3 isoform is highly expressed in the isolated AV node cells. Furthermore, AV node isolated from Ca(v)1.3 null mutant mice show a significant decrease in the firing frequency of spontaneous action potentials suggesting that Ca(v)1.3 L-type Ca(2+) channel plays significant roles in the automaticity of the AV node. Because of the distinct voltage-dependence of Ca(v)1.2 and Ca(v)1.3 Ca(2+) channels, Ca(v)1.2 alone does not suffice to maintain normal AV node function. Ca(v)1.3 currents activate at more hyperpolarizing voltage compared to Ca(v)1.2 currents. Consequently, Ca(v)1.2 Ca(2+) channel cannot functionally substitute for Ca(v)1.3 isoform in the AV node of Ca(v)1.3 null mutant mice. Thus, our study demonstrates that the distinct biophysical properties of Ca(v)1.3 Ca(2+) channel play critical roles in the firing frequency of AV node tissues.

Cardiac Small Conductance Ca 2+ -Activated K + Channel Subunits Form Heteromultimers via the Coiled-Coil Domains in the C Termini of the Channels

Rationale: Ca2+-activated K+ channels are present in a wide variety of cells. We have previously reported the presence of small conductance Ca2+-activated K+ (SK or KCa) channels in human and mouse cardiac myocytes that contribute functionally toward the shape and duration of cardiac action potentials. Three isoforms of SK channel subunits (SK1, SK2, and SK3) are found to be expressed. Moreover, there is differential expression with more abundant SK channels in the atria and pacemaking tissues compared with the ventricles. SK channels are proposed to be assembled as tetramers similar to other K+ channels, but the molecular determinants driving their subunit interaction and assembly are not defined in cardiac tissues. Objective: To investigate the heteromultimeric formation and the domain necessary for the assembly of 3 SK channel subunits (SK1, SK2, and SK3) into complexes in human and mouse hearts. Methods and Results: Here, we provide evidence to support the formation of heteromultimeric complexes among different SK channel subunits in native cardiac tissues. SK1, SK2, and SK3 subunits contain coiled-coil domains (CCDs) in the C termini. In vitro interaction assay supports the direct interaction between CCDs of the channel subunits. Moreover, specific inhibitory peptides derived from CCDs block the Ca2+-activated K+ current in atrial myocytes, which is important for cardiac repolarization. Conclusions: The data provide evidence for the formation of heteromultimeric complexes among different SK channel subunits in atrial myocytes. Because SK channels are predominantly expressed in atrial myocytes, specific ligands of the different isoforms of SK channel subunits may offer a unique therapeutic opportunity to directly modify atrial cells without interfering with ventricular myocytes.