Electrophysiological Characterization of an Alternatively Processed ERG K + Channel in Mouse and Human Hearts
Mutants of HERG, the human form of ERG (the ether-a-go-go-related K+ channel gene), are responsible for some forms of the long-QT syndrome, an abnormality of cardiac repolarization. HERG was cloned from brain and has properties similar but not identical to the rapidly activating component of the native cardiac K+ channel current (Ikr). We identified in the mouse an alternatively processed form of ERG (MERG B) that is expressed abundantly in heart but only in trace amounts in brain. MERG B has a unique 36-amino acid NH2-terminal domain that is strongly basic and considerably shorter than the 376-amino acid NH2-terminal domain of HERG. When expressed in Xenopus oocytes, the kinetics of activation and deactivation of the MERG B current were best fit by a biexponential function, with the fast components dominant over the slow components. The fast component of activation had a mean tau value of 163 +/- 16 ms at -20 mV and 8 +/- 4 ms at +20 mV (n = 4). The fast component of deactivation had a mean tau value of 145 +/- 29 ms at -20 mV and 12 +/- 4 ms at -90 mV (n = 4). The MERG B current was blocked by the selective IKr blocker, dofetilide, with an IC50 of 54 nmol/L. In addition, we isolated HERG B, the human homologue of MERG B, which has electrophysiological characteristics qualitatively similar to those of MERG B. We have identified ERG B, an alternatively processed isoform of the ERG gene, expressed selectively in heart and with electrophysiological characteristics similar to those of native cardiac IKr.
Expression of cardiac transient outward current and inwardly rectifying K+ current is age dependent. However, little is known about age-related changes in cardiac delayed rectifier K+ current (IK, with rapidly and slowly activating components, IKr and IKs, respectively). Accordingly, the purpose of the present study was to assess developmental changes in IK channels in fetal, neonatal, and adult mouse ventricles. Three techniques were used: conventional microelectrode to measure the action potential, voltage clamp to record macroscopic currents of IK, and radioligand assay to examine [3H]dofetilide binding sites. The extent of prolongation of action potential duration at 95% repolarization (APD95) by a selective IKr blocker, dofetilide (1 mumol/L), dramatically decreased from fetal (137% +/- 18%) to day-1 (75% +/- 29%) and day-3 (20% +/- 15%) neonatal mouse ventricular tissues (P < .01). Dofetilide did not prolong APD95 in adult myocardium. IKr is the sole component of IK in day-18 fetal mouse ventricular myocytes. However, both IKr and IKs were observed in day-1 neonatal ventricular myocytes. With further development, IKs became the dominant component of IK in day-3 neonates. In adult mouse ventricular myocytes, neither IKr nor IKs was observed. Correspondingly, a high-affinity binding site for [3H]dofetilide was present in fetal mouse ventricles but was absent in adult ventricles. The complementary data from microelectrode, voltage-clamp, and [3H]dofetilide binding studies demonstrate that expression of the IK channel is developmentally regulated in the mouse heart.
Osteoarthritis (OA) is a multifactorial, often progressive, painful disease. OA often progresses with an apparent irreversible loss of articular cartilage, exposing underlying bone, resulting in pain and loss of mobility. This cartilage loss is thought to be permanent due to ineffective repair and apparent lack of stem/progenitor cells in that tissue. However, the adjacent synovial lining and synovial fluid are abundant with mesenchymal progenitor/stem cells (synovial mesenchymal progenitor cells [sMPCs]) capable of differentiating into cartilage both in vitro and in vivo. Previous studies have demonstrated that MPCs can home to factors such as monocyte chemotactic protein 1 (MCP‐1/CCL2) expressed after injury. While MCP‐1 (and its corresponding receptors) appears to play a role in recruiting stem cells to the site of injury, in this study, we have demonstrated that MCP‐1 is upregulated in OA synovial fluid and that exposure to MCP‐1 activates sMPCs, while concurrently inhibiting these cells from undergoing chondrogenesis in vitro. Furthermore, exposure to physiological (OA knee joint synovial fluid) levels of MCP‐1 triggers changes in the transcriptome of sMPCs and prolonged exposure to the chemokine induces the expression of MCP‐1 in sMPCs, resulting in a positive feedback loop from which sMPCs cannot apparently escape. Therefore, we propose a model where MCP‐1 (normally expressed after joint injury) recruits sMPCs to the area of injury, but concurrently triggers changes in sMPC transcriptional regulation, leading to a blockage in the chondrogenic program. These results may open up new avenues of research into the lack of endogenous repair observed after articular cartilage injury and/or arthritis. Stem Cells 2013;31:2253–2265
system suitable for recordings from Langendorff-perfused rat hearts using the voltage-sensitive dye 4-[-[2-(di-n-butylamino)-6-naphthyl]vinyl]pyridinium (di-4-ANEPPS) has been developed. Conduction velocity was measured under hyper-and hypokalemic conditions, as well as at physiological and reduced temperature. Elevation of extracellular [K ϩ ] to 9 mM from 5.9 mM caused a slowing of conduction velocity from 0.66 Ϯ 0.08 to 0.43 Ϯ 0.07 mm/ms (35%), and reduction of the temperature to 32°C from 37°C caused a slowing from 0.64 Ϯ 0.07 to 0.46 Ϯ 0.05 mm/ms (28%). Ventricular activation patterns in sinus rhythm showed areas of early activation (breakthrough) in both the right and left ventricle, with breakthrough at a site near the apex of the right ventricle usually occurring first. The effects of mechanically immobilizing the preparation to reduce motion artifact were also characterized. Activation patterns in epicardially paced rhythm were insensitive to this procedure over the range of applied force tested. In sinus rhythm, however, a relatively large immobilizing force caused prolonged PQ intervals as well as altered ventricular activation patterns. The time-dependent effects of the dye on the rat heart were characterized and include 1) a transient vasodilation at the onset of dye perfusion and 2) a long-lasting prolongation of the PQ interval of the electrocardiogram, frequently resulting in brief episodes of atrioventricular block. fluorescent dyes; rat heart ventricular activation; imaging techniques MAPPING OF CARDIAC ELECTRICAL ACTIVITY using voltagesensitive dyes has proven to be a valuable complement to extracellular electrode-based mapping. Recently, this approach has yielded important new information on normal and abnormal activation patterns in hearts from a variety of species (1,10,27,39,40). The voltagesensitive dye approach offers the possibility of obtaining very high spatial resolution without the methodological complications involved in fabricating large high-resolution electrode arrays (12,21). This is a particular advantage for recordings in small preparations, such as the hearts of rodents. In addition, this approach provides a direct measurement of the transmembrane voltage rather than extracellular potentials.The increasing use of genetically engineered murine models in cardiovascular studies has resulted in a significant need for quantitative, reproducible techniques for evaluating the electrophysiological properties of the mouse heart. Voltage-sensitive dye mapping has proven to be a very useful tool in this context (1,26,27,36). Although at present the mouse is the predominant experimental animal for genetically engineered models, there is an increasing interest in utilizing larger animals such as the rabbit (22) and the rat (8, 29). Voltage-sensitive dye mapping has been applied to cultured monolayers of rat cardiac cells (7, 30); however, it has not been applied to the rat heart in vitro. The rat heart is a widely used model in cardiac electrophysiological and hemodynamic studies. Rapid...
The effects of C-type natriuretic peptide (CNP) on heart rate and ionic currents were demonstrated by recording the ECG from adult mice and performing voltage-clamp experiments on single sinoatrial (SA) node cells isolated from mouse heart. The selective natriuretic peptide type C receptor (NPR-C) agonist cANF (10(-7) M) significantly decreased heart rate in the presence of isoproterenol (5 x 10(-9) M), as indicated by an increase in the R-R interval of ECGs obtained from Langendorff-perfused hearts. Voltage-clamp measurements in enzymatically isolated single pacemaker myocytes revealed that CNP (10(-8) M) and cANF (10(-8) M) significantly inhibited L-type Ca2+ current [ICa(L)]. These findings suggest that the CNP effect on this current is mediated by NPR-C. Further support for an NPR-C-mediated inhibition of ICa(L) in SA node myocytes was obtained by altering the functional coupling between the G protein Gi and NPR-C. In these experiments, a "Gi-activator peptide," which consists of a 17-amino acid segment of NPR-C containing a specific Gi protein-activator sequence, was dialyzed into SA node myocytes. This peptide decreased ICa(L) significantly, suggesting that NPR-C activation can result in a reduction in ICa(L) when CNP is bound and the Gi protein pathway is activated. This effect of CNP appears to be selective for ICa(L), because the hyperpolarization-activated current was unaffected by CNP or cANF. These results provide the first demonstration that CNP has a negative chronotropic effect on heart rate and suggest that this effect is mediated by selectively activating NPR-C and reducing ICa(L) through coupling to Gi protein.
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