Faculty Bibliography

ATP-sensitive K(+) (K(ATP)) channels, composed of inward rectifier K(+) (Kir)6.x and sulfonylurea receptor (SUR)x subunits, are expressed on cellular plasma membranes. We demonstrate an essential role for SUR2 subunits in trafficking K(ATP) channels to an intracellular vesicular compartment. Transfection of Kir6.x/SUR2 subunits into a variety of cell lines (including h9c2 cardiac cells and human coronary artery smooth muscle cells) resulted in trafficking to endosomal/lysosomal compartments, as assessed by immunofluorescence microscopy. By contrast, SUR1/Kir6.x channels efficiently localized to the plasmalemma. The channel turnover rate was similar with SUR1 or SUR2, suggesting that the expression of Kir6/SUR2 proteins in lysosomes is not associated with increased degradation. Surface labeling of hemagglutinin-tagged channels demonstrated that SUR2-containing channels dynamically cycle between endosomal and plasmalemmal compartments. In addition, Kir6.2 and SUR2 subunits were found in both endosomal and sarcolemmal membrane fractions isolated from rat hearts. The balance of these K(ATP) channel subunits shifted to the sarcolemmal membrane fraction after the induction of ischemia. The K(ATP) channel current density was also increased in rat ventricular myocytes isolated from hearts rendered ischemic before cell isolation without corresponding changes in subunit mRNA expression. We conclude that an intracellular pool of SUR2-containing K(ATP) channels exists that is derived by endocytosis from the plasma membrane. In cardiac myocytes, this pool can potentially play a cardioprotective role by serving as a reservoir for modulating surface K(ATP) channel density under stress conditions, such as myocardial ischemia.

Endothelial cells (ECs) are constantly exposed to blood flow-induced shear forces in the vessels and this is a major determinant of endothelial function. Ion channels have a major role in endothelial function and in the control of vascular tone. We hypothesized that shear force is a general regulator of ion channel expression, which will have profound effects on endothelial function. We examined this hypothesis using large-scale quantitative real-time RT-PCR. Human coronary artery ECs were exposed to two levels of flow-induced shear stress for 24 h, while control cells were grown under static conditions. The expression of ion channel subunits was compared between control and flow-adapted cells. We used primers against 55 ion channel and exchanger subunits and were able to detect 54 subunits. Five dyn/cm(2) of shear induced downregulation of 1 (NCX1) and upregulation of 18 subunits, including K(Ca)2.2, K(Ca)2.3, CX37, K(v)1.5 and HCN2. Fifteen dyn/cm(2) of shear stress induced the expression of 30 ion channel subunits, including K(Ca)2.3, K(Ca)2.2, CX37, K(ir)2.3 and K(Ca)3.1. Our data demonstrate that substantial remodeling of endothelial ion channel subunit expression occurs with flow adaptation and suggest that altered ion channel expression may significantly contribute to vascular pathology associated with flow-induced alterations

Formins dynamically regulate actin microfilament assembly, influencing processes such as cell division, signal transduction, migration, and cell-cell contact formation. The actin cytoskeleton affects ion channel activity and formation of mechanical cell-cell junctions. As in vitro differentiation of embryonic stem cells (ESC) results in phenotypical immature cardiomyocytes, differences in formin expression might reflect alterations to the actin cytoskeleton of adult cardiomyocytes. Objective: To compare formin expression during heart development to the profile of in vitro differentiated cardiomyocytes. Methods: Samples: ESC and cardiac tissue from embryonic day 14.5, neonatal day 2 or 2 month old mice of the 129P2 strain (heart development); spontaneously contracting cardiomyocytes differentiated from 129P2 ESC (in vitro differentiation). Transcript analysis performed by qRT-PCR analysis (15 mouse formin genes, 2 stemness genes, 4 cardiomyocyte differentiation genes). Expression of candidate formin proteins was analyzed using commercially available Diap1 and Fhod1 antibodies. Results: qRT-PCR analysis revealed significant changes in formin expression for 9 of 15 formins during heart development. Four patterns of transcript changes were observed: formins expressed in ESC and decreasing during development (Diap1, Diap3); transcripts peeking during fetal heart development (Fhod1, Fmnl1, Grid2ip); transcripts altered during heart development compared to ESC and adult heart (Daam1, Daam2, Fmnl2, Fmnl3); transcript increasing during development (Fhod3). In vitro differentiated cardiomyocytes revealed significant increases in expression of embryonic formins (Grid2ip, Fhod1, Fmnl2) and formins otherwise not differentially expressed during heart development (Diap2, Fmn1, Fmn2, Inf2). Expression of Fhod1 and Diap1 protein was studied in ESC, neonatal cardiomyocytes and in vitro differentiated cardiomyocytes, verifying the observed changes in transcript expression. Conclusion: Formins are dynamically regulated during cardiac development. Modifying formin expression of in vitro differentiated cardiomyocytes could improve functional maturity and therefore their potential use in cell replacement therapy for cardiac repair

Hydrogen sulfide (H(2)S) is a colorless, water soluble, flammable gas that has the characteristic smell of rotten eggs. Like other members of the gasotransmitter family (nitric oxide and carbon monoxide), H(2)S has traditionally been considered to be a highly toxic gas and environmental hazard. However, much like for nitric oxide and carbon monoxide, the initial negative perception of H(2)S has evolved with the discovery that H(2)S is produced enzymatically in mammals under normal conditions. As a result of this discovery, there has been a great deal of work to elucidate the physiological role of H(2)S. H(2)S is now recognized to be cytoprotective in various models of cellular injury. Specifically, it has been demonstrated that the acute administration of H(2)S, either prior to ischemia or at reperfusion, significantly ameliorates in vitro or in vivo myocardial and hepatic ischemia-reperfusion injury. These studies have also demonstrated a cardioprotective role for endogenous H(2)S. This review article summarizes the current body of evidence demonstrating the cytoprotective effects of H(2)S with an emphasis on the cardioprotective effects. This review also provides a detailed description of the current signaling mechanisms shown to be responsible for these cardioprotective actions

Metabolic processes that regulate muscle energy use are major determinants of bodily energy balance. Here, we find that sarcolemmal ATP-sensitive K(+) (K(ATP)) channels, which couple membrane excitability with cellular metabolic pathways, set muscle energy expenditure under physiological stimuli. Disruption of K(ATP) channel function provoked, under conditions of unaltered locomotor activity and blood substrate availability, an extra energy cost of cardiac and skeletal muscle performance. Inefficient fuel metabolism in K(ATP) channel-deficient striated muscles reduced glycogen and fat body depots, promoting a lean phenotype. The propensity to lesser body weight imposed by K(ATP) channel deficit persisted under a high-fat diet, yet obesity restriction was achieved at the cost of compromised physical endurance. Thus, sarcolemmal K(ATP) channels govern muscle energy economy, and their downregulation in a tissue-specific manner could present an antiobesity strategy by rendering muscle increasingly thermogenic at rest and less fuel efficient during exercise

A comprehensive number of epidemiological and animal studies suggest that prenatal and early life events are important determinants for disorders later in life. Among them, prenatal stress (i.e. stress experienced by the pregnant mother with impact on the fetal ontogeny) has clear programming effects on the cardiovascular system. A fetus developing in adverse conditions becomes an adult who is susceptible to disease, which may include hypertension, insulin resistance, altered blood lipid levels and cardiovascular disease. Recent evidence demonstrates that maternal programming can occur in the absence of other adverse environmental factors. Obesity, which is becoming a problem of large proportions in Western countries, is a possible cause of programming. With over 30% of the population of the USA currently obese, many mothers suffer from obesity during their child-bearing years (in fact, these conditions are often aggravated during pregnancy). One of the targets of programming is the cardiovascular system, and reported consequences include hypertension, endothelial dysfunction and vascular abnormalities. The overall goal of our study was to investigate the susceptibility of the heart to ischaemia-reperfusion in an animal model of maternal obesity. Our data demonstrate that normal (non-mutant) offspring from obese agouti mouse dams had an increased susceptibility to ischaemia-reperfusion injury. These data may provide insights into the long-term cardiovascular consequences of programming.

SRp38 is an atypical SR protein splicing regulator. To define the functions of SRp38 in vivo, we generated SRp38 null mice. The majority of homozygous mutants survived only until E15.5 and displayed multiple cardiac defects. Evaluation of gene expression profiles in the SRp38(-/-) embryonic heart revealed a defect in processing of the pre-mRNA encoding cardiac triadin, a protein that functions in regulation of Ca(2+) release from the sarcoplasmic reticulum during excitation-contraction coupling. This defect resulted in significantly reduced levels of triadin, as well as those of the interacting protein calsequestrin 2. Purified SRp38 was shown to bind specifically to the regulated exon and to modulate triadin splicing in vitro. Extending these results, isolated SRp38(-/-) embryonic cardiomyocytes displayed defects in Ca(2+) handling compared with wild-type controls. Taken together, our results demonstrate that SRp38 regulates cardiac-specific alternative splicing of triadin pre-mRNA and, reflecting this, is essential for proper Ca(2+) handling during embryonic heart development.

K(ATP) channels are generally cardioprotective under conditions of metabolic impairment, consisting of pore-forming (Kir6.1 and/or Kir6.2) and sulphonylurea-binding, modulatory subunits [sulfonylurea receptor (SUR) 1, 2A, or 2B]. Cardiovascular K(ATP) channels are generally thought to consist of Kir6.2/SUR2A subunits (in the case of heart muscle) or Kir6.1/SUR2B subunits (smooth muscle), whereas SUR1-containing channels have well-documented roles in pancreatic insulin release. Recent data, however, demonstrated the presence of SUR1 subunits in mouse cardiac tissue (particularly in atria) and a surprising protection from myocardial ischemia/reperfusion in SUR1-null mice. Here, we review some of the extra-pancreatic roles assigned to SUR1 subunits and consider whether these might be involved in the sequelae of ischemia/reperfusion