Chick embryos exposed to trichloroethylene in an ex ovo culture model show selective defects in early endocardial cushion tissue formation

BACKGROUND

Formation of the primitive heart is a critical step for establishing a competent circulatory system necessary for continued morphogenesis, and as such has significant potential as a target for environmental insult. The goal of this study was to identify the initial cellular events that precede more superficially observable abnormalities resulting from exposing early chick embryos to trichloroethylene (TCE).

METHODS

A whole embryo culture method was used to assess the susceptibility of endocardial epithelial-mesenchymal transformation in the early chick heart to TCE. This method has the benefits of maintaining the anatomical relationships of developing tissues and organs, instantaneously exposing precisely staged embryos to quantifiable levels of TCE in a protein-free medium, and the ability to directly monitor developmental morphology.

RESULTS

A minority of embryos (Hamburger and Hamilton [HH] stage 13-14) exposed to TCE (10-80 ppm) were not viable after 24 hr in culture and exhibited a variety of gross malformations in a dose-dependent fashion. However, the majority of treated embryos remained viable and developed into HH stage 17 embryos that were superficially indistinguishable from vehicle-treated controls. Further analysis of the hearts of these superficially normal embryos by whole-mount confocal microscopy revealed selective reduction in the number of atrioventricular canal mesenchymal cells. Additionally, those mesenchymal cells that did develop migrated abnormally as long thin cords of adherent cells.

CONCLUSIONS

The regional selectivity of these effects in the chick heart suggests a critical window of susceptibility to TCE in the epithelial-mesenchymal transformation of atrioventricular canal endocardium.

Leukemia inhibitory factor induces endothelial differentiation in cardiac stem cells

The importance of interleukin 6 (IL-6)-related cytokines in cardiac homeostasis has been studied extensively; however, little is known about their biological significance in cardiac stem cells. Here we describe that leukemia inhibitory factor (LIF), a member of IL-6-related cytokines, activated STAT3 and ERK1/2 in cardiac Sca-1+ stem cells. LIF stimulation resulted in the induction of endothelial cell-specific genes, including VE-cadherin, Flk-1, and CD31, whereas neither smooth muscle nor cardiac muscle marker genes such as GATA4, GATA6, Nkx-2.5, and calponin were up-regulated. Immunocytochemical examination showed that about 25% of total cells were positively stained with anti-CD31 antibody 14 days after LIF stimulation. Immunofluorescent microscopic analyses identified the Sca-1+ cells that were also positively stained with anti-von Willebrand factor antibody, indicating the differentiating process of Sca-1+ cells into the endothelial cells. IL-6, which did not activate STAT3 and ERK1/2, failed to induce the differentiation of cardiac stem cells into the endothelial cells. In cardiac stem cells, the transduction with dominant negative STAT3 abrogated the LIF-induced endothelial differentiation. And the inhibition of ERK1/2 with the MEK1/2 inhibitor U0126 also prevented the differentiation of Sca-1+ cells into endothelial cells. Thus, both STAT3 and ERK1/2 are required for LIF-mediated endothelial differentiation in cardiac stem cells. Collectively, it is proposed that LIF regulates the commitment of cardiac stem cells into the endothelial cell lineage, contributing to neovascularization in the process of tissue remodeling and/or regeneration.

Mode and determination of the initial contraction stage in the mouse embryo heart

The developing mammalian heart initiates spontaneous contractions shortly after the myocardium differentiates from the splanchnic mesoderm. The precise timing and mode of the onset of heartbeat, however, have not been statistically described in mice. We analyzed the patterns of contractive activity in video-recorded heart regions ranging from the pre-somite stage to day 10.5 (E10.5). The first sign was detected at the 3-somite stage (E8.25), when a few cardiac myocytes constituted small contracting groups on both sides of the heart tube. Fluctuations of the basal [Ca2+]i level were detected in dormant 3-somite-stage hearts, indicating the initiation of electrical activity before visible contractions. After weak and irregular contractions at the 3-somite stage, the contractions were almost coordinated as early as the 4-somite stage. Unidirectional blood flow through the atrioventricular canal was established around the 20-somite stage at E9.25, correlated with the development of the endocardial cushion. We propose that not only the endocardial cushion but also coordinated contractions are essential for unidirectional flow, because induced bradycardia due to short exposure at room temperature caused regurgitation at E10.5 when otherwise highly organized flow was observed. These findings complement and extend earlier observations on functional heart development, providing a reference for fundamental research on mammalian cardiogenesis.

Lysozyme binding to endocardial endothelium mediates myocardial depression by the nitric oxide guanosine 3',5' monophosphate pathway in sepsis

Inflammatory mediators have been implicated as a cause of reversible myocardial depression in septic shock. We previously reported that the release of lysozyme-c (Lmz-S) from leukocytes from the spleen or other organs contributes to myocardial dysfunction in Escherichia coli septic shock in dogs by binding to a cardiac membrane glycoprotein. However, the mechanism by which Lzm-S causes this depression has not been elucidated. In the present study, we tested the hypothesis that the binding of Lzm-S to a membrane glycoprotein causes myocardial depression by the formation of nitric oxide (NO). NO generation then activates soluble guanylyl cyclase and increases cyclic guanosine monophosphate (cGMP), which in turn triggers contractile impairment via activation of cGMP-dependent protein kinase (PKG). We examined these possibilities in a right ventricular trabecular preparation in which isometric contraction was used to measure cardiac contractility. We found that Lzm-S's depressant effect could be prevented by the non-specific NO synthase (NOS) inhibitor N(G)-monomethyl-l-arginine (l-NMMA). A guanylyl cyclase inhibitor (ODQ) and a PKG inhibitor (Rp-8-Br-cGMP) also attenuated Lzm-S's depressant effect as did chemical denudation of the endocardial endothelium (EE) with Triton X-100 (0.5%). In EE tissue, we further showed that Lzm-S caused NO release with use of 4,5 diaminofluorescein, a fluorescent dye that binds to NO. The present study shows that the binding of Lzm-S to EE generates NO, and that NO then activates the myocardial guanosine 3',5' monophosphate pathway leading to cardiac depression in sepsis.

In situ Ca2+ dynamics of Purkinje fibers and its interconnection with subjacent ventricular myocytes

Purkinje fibers play essential roles in impulse propagation to the ventricles, and their functional impairment can become arrhythmogenic. However, little is known about precise spatiotemporal pattern(s) of interconnection between Purkinje-fiber network and the underlying ventricular myocardium within the heart. To address this issue, we simultaneously visualized intracellular Ca(2+) dynamics at Purkinje fibers and subjacent ventricular myocytes in Langendorff-perfused rat hearts using multi-pinhole type, rapid-scanning confocal microscopy. Under recording of electrocardiogram at room temperature spatiotemporal changes in fluo3-fluorescence intensity were visualized on the subendocardial region of the right-ventricular septum. Staining of the heart with either fluo3, acetylthiocholine iodide (ATCHI), or di-4-ANEPPS revealed characteristic structures of Purkinje fibers. During sinus rhythm (about 60 bpm) or atrial pacing (up to 3 Hz) each Purkinje-fiber exhibited spatiotemporally synchronous Ca(2+) transients nearly simultaneously to ventricular excitation. Ca(2+) transients in individual fibers were still synchronized within the Purkinje-fiber network not only under high-K(+) (8 mM) perfusion-induced Purkinje-to-ventricular (P-V) conduction delay, but also under unidirectional, orthodromic P-V block produced by 10-mM K(+) perfusion. While spontaneous, asynchronous intracellular Ca(2+) waves were identified in injured fibers of Purkinje network locally, surrounding fibers still exhibited Ca(2+) transients synchronously to ventricular excitation. In summary, these results are the first demonstration of intracellular Ca(2+) dynamics in the Purkinje-fiber network in situ. The synchronous Ca(2+) transients, preserved even under P-V conduction disturbances or under emergence of Ca(2+) waves, imply a syncytial role of Purkinje fibers as a specialized conduction system, whereas unidirectional block at P-V junctions indicates a substrate for reentrant arrhythmias.

Potential involvement of vascular endothelial growth factor in pathophysiology of Turner syndrome

Vascular endothelial growth factor (VEGF) is a specific growth factor for endothelium but plays also a role in the signaling involved in embryonic endocardial-to-mesenchymal transformation of the endocardial cushions. Furthermore, VEGF is the major vascular permeability factor in both fetal and postnatal life. Overexpression of VEGF during fetal life is associated with fetal hydrops and abnormal endocardial cushion development and therefore with congenital heart defects. Cases of prenatal cervical hygroma like in Turner syndrome show both hydrops and cardiac defects. We hypothesize that excess VEGF formed in the wall of the distended jugular sacs (cervical hygroma's) results in other abnormal features characteristic for Turner syndrome such as short stature and gonadal dysgenesis. This implicates that if excess VEGF could be limited prenatally, the phenotypical expression of Turner syndrome can possibly be reduced.

Convergent proliferative response and divergent morphogenic pathways induced by epicardial and endocardial signaling in fetal heart development

Heart development requires cardiomyocyte proliferation, coupled with morphogenic differentiation of the inner trabecular myocardium and the outer compact zone myocardium. In mouse embryos lacking the retinoic acid receptor RXRalpha, proliferation and morphogenesis of the compact zone fails. We demonstrated previously that epicardial cells, in response to retinoic acid, secrete an activity that promotes cell proliferation. In this study, we have investigated downstream signaling pathways that are elicited in response to this factor. We find that cells treated in culture activate PI3 kinase and Erk pathways, and that these are required for a proliferative response. In vivo, phosphorylation of Akt and GSK3beta (PI3K pathway) and of Erk1/2 and p90rsk (Erk pathway) is substantially reduced in RXRalpha-deficient heart tissue. Neuregulin, a mitogen secreted from the endocardium which promotes cardiomyocyte proliferation and trabecular differentiation, also activates proliferation via PI3K and Erk pathways. However, the epicardial factor is not neuregulin, and does not function via the neuregulin receptor. Gene markers known to be selectively expressed in trabecular or compact myocardium in vivo are differentially activated in cell culture by treatment with neuregulin or epicardial factor, and are misexpressed in RXRalpha(-/-) heart tissue. We therefore conclude that epicardial and endocardial signals converge on common proliferative components, but diverge in downstream pathways that lead to compact vs. trabecular morphogenic differentiation.

Selective down-regulation of sub-endocardial ryanodine receptor expression in a rabbit model of left ventricular dysfunction

Defective sarcoplasmic reticulum (SR) Ca2+ handling is evident in cardiomyopathy and may be mediated by selective dysregulation of SR Ca2+ handling proteins. To assess whether regulation of SR Ca2+ release may vary regionally within the normal and diseased heart, left ventricular transmural expression and activity of the ryanodine receptor (RyR2) was studied in a rabbit coronary artery ligation model of left ventricular dysfunction (LVD). Tissue/cells were isolated from both the sub-endocardial and subepicardial layers of the left ventricular free wall from sham-operated and coronary artery ligated rabbit hearts. Three independent methods were used to study alterations in RyR2 mRNA (real-time quantitative PCR (RT-PCR)) and protein expression (quantitative immunoblotting and [3H] ryanodine binding). These biochemical data were compared with functional measurements of fractional SR Ca2+ release from both of these regions. Data from RT-PCR revealed lower RyR2 mRNA levels in the sub-endocardium compared with subepicardium in both experimental groups with the reduction being significantly lower in the sub-endocardium from the LVD group. Quantitative analysis of RyR2 protein levels revealed the same expression patterns. Calsequestrin mRNA and protein levels showed no significant changes. This study demonstrates a lower expression level of RyR2 in the sub-endocardium of the left ventricle of rabbit hearts and is the first to show a further specific reduction in LVD. There is a corresponding decrease in fractional SR Ca2+ release in cells isolated from the sub-endocardium of hearts from the LVD group, relating these selective biochemical alterations to changes in function.

Transmural heterogeneity of Na+-Ca2+ exchange: evidence for differential expression in normal and failing hearts

Spatial electrical heterogeneity has a profound effect on normal cardiac electrophysiology and genesis of cardiac arrhythmias in diseased hearts. The Na+-Ca2+ exchanger (NCX) is a key linker, through Ca2+ signaling, between contractility and arrhythmias. Here we characterize the differential transmural expression of NCX in normal and rapid pacing-induced failing canine hearts. Significant transmural heterogeneity of NCX was present in normal hearts, as NCX current density measured at +80 mV was significantly (P<0.05) greater in epicardial (EPI) (5.49 pA/pF) than mid-myocardial (MID) (2.84 pA/pF) and endocardial (ENDO) (2.21 pA/pF) cells. Interestingly, heart failure caused a selective increase in NCX current density (P<0.05) limited to ENDO (by 202%) and MID (by 76%) but not EPI myocytes (P=not significant). The differences in functional expression were associated with changes in both mRNA and protein levels. The normal EPI layer exhibited the greatest NCX mRNA and protein levels compared with MID and ENDO layers, whereas the ENDO layer underwent the most pronounced increase in mRNA (by 185%) and protein (by 207%) levels in heart failure. The transmural NCX gradient, from EPI (greatest) to ENDO (least), is disrupted in heart failure. A selective upregulation of NCX expression in MID and ENDO in heart failure markedly redirects the orientation of the transmural functional gradient of NCX and may lead to enhanced vulnerability to cardiac arrhythmias.

Release of endothelin-1 from human endocardium after radiofrequency catheter ablation and coronary angioplasty: comparative results

BACKGROUND

Plasma levels of endothelin-1 (ET-1) increase after coronary angioplasty (PTCA) due to endothelial injury during the procedure. ET-1 has been found in human endocardial and myocardial cells. It is not known whether ET-1 increases after thermal injury induced by radiofrequency catheter ablation (RFA).

METHODS

We determined plasma ET-1 levels at baseline, immediately after, and at 2 and 6 h post-procedure in 31 patients undergoing PTCA and 16 patients undergoing RFA. Patients subjected to diagnostic coronary angiography (n=15) or electrophysiology study (n=13) served as controls.

RESULTS

Compared to baseline, ET-1 levels increased significantly immediately post-PTCA (55.1+/-20.1 vs. 42.7+/-14.9 pg/ml, p<0.01) and at 2 h post-RFA (98.0+/-11.7 vs. 53.0+/-17.4 pg/ml, p<0.01) and returned to baseline measurements at 2 h post-PTCA and 6 h post-RFA. There was no change of ET-1 levels in the control groups. ET-1 kinetics curve was significantly higher post-RFA compared to post-PTCA (p<0.001). ET-1 immediately post-PTCA correlated with total pressure-time product applied for balloon inflation during the procedure (r=0.56, p<0.01). There was no correlation between ET-1 levels and the number of RFA applications. No patient developed ischemia post-PTCA. There were no complications or arrhythmia recurrences post-RFA.

CONCLUSION

Endocardial thermal injury incurred during RFA is another mechanism of endothelin increase apart from mechanical injury of the coronary endothelium during PTCA and represents further evidence for the existence of the peptide in human endocardial endothelial and myocardial cells. ET-1 increase is delayed and more pronounced post-RFA compared to post-PTCA. Despite that, it does not seem to have any clinical impact in the immediate post-RFA period.

NO modulation of myocardial performance in fish hearts

In the mammalian heart, intracardiac nitric oxide (NO) regulates in an autocrine-paracrine manner cardiac function in the beat-to-beat response (Starling's law of the heart), short-term response (phasic control, e.g. excitation-contraction coupling, responses to neurotransmitters and endocrines) and long-term response (tonic control by altering gene expression). This trio of NO temporal-dependent actions has a long evolutionary history, as we have documented in the prototypic vertebrate heart, the teleost heart. This heart shares a common structural and functional scenario with higher vertebrate hearts exhibiting, at the same time, differences in myoarchitecture (trabecular vs. compact type), blood supply (lacunary vs. vascular) and pumping performance (sensitivity to filling pressure), thus providing challenging opportunities for revealing aspects of unity and diversity of cardiac NO in vertebrates. Using in vitro working teleost heart preparations we have shown that, under basal conditions, NO through a cGMP-mediated mechanism modulates ventricular performance (negative inotropism) and remarkably increases the sensitivity to filling pressure (i.e. the Frank-Starling response). NO-cGMP mechanism also influences the short-term response elicited by inotropic agents such as acetylcholine and angiotensin II. A role of NO in long-term cardiac adaptation is illustrated by morphologic evidence (e.g. NOS immuno-localization in phylogenetically distant species) which emphasizes the importance of NO in reshaping the angio-myoarchitecture of the fish heart ventricle (i.e. compensation for regional heterogeneity). Finally, by studying the avascular hearts of teleosts and amphibians that lack vascular endothelium, a relevant role of endocardial endothelium-NO signalling in intracavitary regulation of myocardial performance has been firmly established, thus revealing its early evolutionary role in non-mammalian vertebrates.

Activin receptor-like kinase 2 and Smad6 regulate epithelial-mesenchymal transformation during cardiac valve formation

Epithelial-mesenchymal transformation (EMT) occurs during both development and tumorigenesis. Transforming growth factor beta (TGFbeta) ligands signal EMT in the atrioventricular (AV) cushion of the developing heart, a critical step in valve formation. TGFbeta signals through a complex of type I and type II receptors. Several type I receptors exist although activin receptor-like kinase (ALK) 5 mediates the majority of TGFbeta signaling. Here, we demonstrate that ALK2 is sufficient to induce EMT in the heart. Both ALK2 and ALK5 are expressed throughout the heart with ALK2 expressed abundantly in endocardial cells of the outflow tract (OFT), ventricle, and AV cushion. Misexpression of constitutively active (ca) ALK2 in non-transforming ventricular endocardial cells induced EMT, while caALK5 did not, thus demonstrating that ALK2 activity alone is sufficient to stimulate EMT. Smad6, an inhibitor of Smad signaling downstream of ALK2, but not ALK5, inhibited EMT in AV cushion endocardial cells. These data suggest that ALK2 activation may stimulate EMT in the AV cushion and that Smad6 may act downstream of ALK2 to negatively regulate EMT.

TRANSENDOCARDIAL AND TRANSEPICARDIAL INTRAMYOCARDIAL FIBROBLAST GROWTH FACTOR-2 ADMINISTRATION: MYOCARDIAL AND TISSUE DISTRIBUTION

Effective local delivery to the heart remains an obstacle to successful therapeutic application of a number of drugs and biological agents. This study was designed to study and optimize the delivery characteristics of transendocardial intramyocardial (IM) administration, determine myocardial deposition and retention over time, and compare it to transepicardial IM injection. Thirty-nine pigs were used for the study (15 for catheter optimization, 15 for transendocardial IM delivery, and 9 for transepicardial IM delivery). (125)I-Fibroblast growth factor-2 (FGF2) (25 microCi) was used as the prototype molecule. Tissue and myocardial distribution was determined at 1 and 24 h and 7 days. Using 1-h (125)I-FGF2 myocardial deposition as a parameter for delivery efficiency, the optimal needle length and delivery volume for transendocardial based delivery were determined to be 6 mm and 0.1 ml, respectively. Using these parameters for endocardial delivery, (125)I-FGF2 cardiac activity was 18.01 +/- 3.84% of delivered activity at 1 h, 11.65 +/- 5.17% at 24 h, and 2.32 +/- 0.87% at 7 days in ischemic animals. Studies in nonischemic animals produced similar results. For transepicardial delivery, (125)I-FGF2 cardiac-specific activity was 23.14 +/- 12.67% for the 6-mm needle, declining to 12.32 +/- 8.50% at 24 h, and did not significantly differ from values obtained following transendocardial delivery. Thus, optimized transendocardial intramyocardial delivery using Biosense guidance results in efficient delivery of FGF2 to the target myocardium that is comparable with transepicardial delivery, both providing markedly higher myocardial deposition and retention and lower systemic recirculation of FGF2 than intracoronary, intrapericardial, or intravenous delivery. However, myocardial distribution is limited to injection sites.

Primary Endocardial Malignant Spindle-cell Sarcoma in the Right Atrium of a Dog resembling a Malignant Peripheral Nerve Sheath Tumour

An unusual malignant spindle-cell sarcoma in the right atrium of a 7-year-old male hunting terrier is described. The neoplasm arose from the endocardium, protruded into the lumen of the right atrium, was covered with endothelium, and showed local invasive growth into the atrial wall. The tumour was composed of interlacing bundles of spindle cells, sometimes arranged in whorls resembling the Antoni type A pattern. The extracellular matrix showed abundant reticulin fibres. Immunohistochemistry revealed an intense labelling of tumour cells for vimentin, and a partial labelling for neuron-specific enolase, S100 protein, and Melan-A. The morphology of the tumour indicated a primary malignant peripheral nerve sheath tumour, resembling a neoplasm described in rats.

Transmural dispersion of repolarization as a key factor of arrhythmogenicity in a novel intact heart model of LQT3

BACKGROUND

Congenital and acquired long QT syndrome (LQTS) are caused by abnormalities of ionic currents underlying ventricular repolarization. For a better understanding of the mechanisms by which functional electrical instability at the level of the whole heart leads to torsade de pointes (TdP), a novel model of LQT3 was developed and the role of transmural dispersion of repolarization for the development of proarrhythmia was evaluated.

METHODS AND RESULTS

In 11 Langendorff-perfused rabbit hearts, veratridine (0.1-0.5 microM), an inhibitor of sodium channel inactivation, led to a concentration-dependent increase in QT-interval and simultaneously recorded monophasic ventricular action potentials (MAPs) (p<0.05) and thereby mimicked LQT3. Veratridine reproducibly induced early afterdepolarizations (EADs) and TdP after lowering potassium concentration. In bradycardic (AV-blocked) hearts, the increase in MAP duration showed marked regional differences. It was significantly more pronounced on the left endocardium as compared to left or right epicardium. This resulted in a significant increase in dispersion of repolarization (24% at 0.1 microM, 92% at 0.25 microM, 208% at 0.5 microM; p<0.01). Left ventricular transmural dispersion of repolarization increased significantly more than interventricular dispersion (104 to 33 ms at 0.5 microM veratridine; p<0.05).

CONCLUSION

By inhibition of sodium channel inactivation, veratridine mimics LQT3 in this intact heart model. In bradycardic, hypokalemic hearts, it reproducibly induced EADs and TdP in the setting of significantly increased left ventricular transmural dispersion of repolarization. Based on these experimental data, reduction of transmural dispersion of repolarization may be considered an important target for the prevention of TdP in patients with LQT3.

Cellular mechanism of calcium-mediated triggered activity in the heart

Calcium overload due to enhanced calcium entry is a mechanism for spontaneous calcium release (SCR) from the sarcoplasmic reticulum, delayed-afterdepolarizations (DAD), and triggered activity. However, the exact mechanistic relationship between elevated intracellular calcium levels and triggered activity originating from a specific location remains unclear. We hypothesize that under conditions of enhanced calcium entry, elevation of intracellular calcium will result in multiple calcium release events of which only one is more likely to initiate a triggered beat. We used optical mapping of action potentials and ratiometric calcium transients in an electromechanically-uncoupled canine wedge model of enhanced calcium entry, using I(Ks) blockade with beta-adrenergic stimulation. Under conditions of enhanced calcium entry, the rate of calcium uptake was faster compared with control conditions; however, during rapid pacing, cytoplasmic calcium elevation at the endocardium was significantly increased (15+/-4%) compared with control (10+/-3, P<0.04). Rapid pacing induced multiple simultaneous SCR events with largest amplitude and earliest onset near the endocardium compared with the epicardium. Furthermore, SCR events with largest amplitude and earliest onset served as a focus for DAD-mediated triggered activity. Interestingly, polymorphic VT occurred in some experiments when multiple SCR events occurred. In conclusion, multiple, simultaneous SCR events occur over a broad region of relatively slower calcium uptake and elevated diastolic calcium levels. However, SCR events closer to the endocardium have the largest amplitude and earliest onset and are, thereby, more likely to initiate DAD-mediated triggered activity. Finally, multiple SCR events may be a mechanism of polymorphic VT under calcium overload conditions.

Isolation of arterial-specific genes by subtractive hybridization reveals molecular heterogeneity among arterial endothelial cells

Arteries are distinguished from veins by differences in gene expression, as well as in their anatomy and physiology. The characterization of arterial- and venous-specific genes may improve our understanding of cardiovascular development and disease. Here we report the results of a subtractive hybridization screen for arterial-specific genes, and describe in detail the expression of a novel arterial-specific gene, Depp (decidual protein induced by progesterone), using a GFP-Cre knock-in that permits a comparison of both instantaneous and cumulative expression patterns in situ. Several features of Depp expression are noteworthy. First, Depp is expressed in endothelial cells of peripheral tissues, but not in atrial or ventricular endocardial cells of the heart. Very few genes have been reported to discriminate between these two cell types, and therefore this specificity may be useful in generating conditional mutations in other genes implicated in cardiovascular development. Second, Depp reveals an unexpected degree of molecular heterogeneity among arterial endothelial cells. Third, Depp is up-regulated in subsets of endothelial cells, in settings of adult neo-vascularization, including tumor angiogenesis. Taken together, these data reveal unanticipated temporal and spatial heterogeneity among arterial endothelial cells of various tissues and organs, raising new questions regarding the functional significance of this diversity.

Immunolocalization of chick periostin protein in the developing heart

The process that cardiac cushions undergo to form the mature septa and valves of the adult heart is poorly understood. Periostin is an extracellular molecule that is expressed during cushion mesenchyme formation and throughout valvulogenesis. Once thought to be an osteoblast-specific factor, studies have shown this molecule is antiosteogenic. We have produced an antibody to chicken periostin and examined periostin's localization in the developing avian heart. This antibody recognized proteins from chick heart lysates around 90 kD molecular weight as predicted from the chick periostin mRNA and other periostin orthologs. Periostin immunolocalization was first evident as fibrous strands in the cushion mesenchyme. At HH25, periostin was detected on the basal surface of the trabecular endothelium and also on the endocardial epithelium of the atrioventricular cushion. We hypothesize that periostin may function in the organization of extracellular matrix molecules, providing cues necessary for attachment and spreading during the epithelial-to-mesenchymal transitions of the endocardial epithelium. Enhanced secretion of periostin in the region of delamination may directly or indirectly promote change in the myocardium that precedes or mediates delamination of the leaflet. At later stages of development (HH34-38), periostin was seen predominantly in the fibrous regions of the heart, such as the left atrioventricular valve (LAV), annulus, cardiac skeleton, and adventitia. We propose that periostin is induced by sheer stress and may be an essential molecular component for structures of the heart that undergo mechanical stress or tension during the cardiac cycle.

The Effects of Halothane, Isoflurane, and Sevoflurane on Ca2+ Current and Transient Outward K+ Current in Subendocardial and Subepicardial Myocytes from the Rat Left Ventricle

Halothane, isoflurane, and sevoflurane abbreviate ventricular action potential duration (APD), and for halothane this effect is greater in the subendocardium than in the subepicardium. In this study we investigated mechanisms underlying the regional effects of these anesthetics on APD. The effect of 0.6 mM halothane, isoflurane, and sevoflurane on the action potential, L-type Ca(2+) current, transient outward K(+) current (I(to)), and steady-state current was recorded in rat left ventricular subendocardial and subepicardial myocytes. Halothane and isoflurane (but not sevoflurane) reduced APD significantly (P < 0.05), more in subendocardial than subepicardial myocytes. Peak L-type Ca(2+) current did not differ between regions and, compared with control, was reduced significantly in both regions by 40% (P < 0.001), 20% (P < 0.001), and 12% (P < 0.01) by halothane, isoflurane, and sevoflurane, respectively. I(to) was greater in subepicardial (3.95 +/- 0.29 nA) than subendocardial (1.12 +/- 0.05 nA) myocytes. In subepicardial myocytes, peak I(to) was reduced significantly by halothane (P < 0.01) and isoflurane (P < 0.05) (by 8% and 7%, respectively) but was unaffected by sevoflurane. No significant reduction of I(to) was observed in subendocardial myocytes with the three anesthetics. The steady-state current was increased significantly (P < 0.05), but the extent of this increase did not differ between the two regions or among the three anesthetics. Therefore, greater inhibition of I(to) in subepicardial than subendocardial myocytes by halothane and isoflurane could underlie their transmural effects on APD.

Foxp1 regulates cardiac outflow tract, endocardial cushion morphogenesis and myocyte proliferation and maturation

We have recently described a new subfamily of Fox genes, Foxp1/2/4, which are transcriptional repressors and are thought to regulate important aspects of development in several tissues, including the lung, brain, thymus and heart. Here, we show that Foxp1 is expressed in the myocardium as well as the endocardium of the developing heart. To further explore the role of Foxp1 in cardiac development, we inactivated Foxp1 through gene targeting in embryonic stem cells. Foxp1 mutant embryos have severe defects in cardiac morphogenesis, including outflow tract septation and cushion defects, a thin ventricular myocardial compact zone caused by defects in myocyte maturation and proliferation, and lack of proper ventricular septation. These defects lead to embryonic death at E14.5 and are similar to those observed in other mouse models of congenital heart disease, including Sox4 and Nfatc1 null embryos. Interestingly, expression of Sox4 in the outflow tract and cushions of Foxp1 null embryos is significantly reduced, while remodeling of the cushions is disrupted, as demonstrated by reduced apoptosis and persistent Nfatc1 expression in the cushion mesenchyme. Our results reveal a crucial role for Foxp1 in three aspects of cardiac development: (1) outflow tract development and septation, (2) tissue remodeling events required for cardiac cushion development, and (3) myocardial maturation and proliferation.

Transmural distribution of connexins in rodent hearts

INTRODUCTION

Electrophysiologic heterogeneity across the ventricular wall is a result of differential transmural expression of various ion channel proteins that underlie the different action potential waveforms observed in epicardial, midmyocardial, and endocardial regions. Cardiac connexins mediate cell-to-cell communication, are critical for normal impulse propagation, and play a role in electrophysiologic remodeling in disease states. However, little is known about the transmural distribution of cardiac gap junction proteins.

METHODS AND RESULTS

Connexin expression in epicardium, midmyocardium, and endocardium was assessed immunohistochemically in mouse and rat hearts. The total connexin protein content within different ventricular regions was measured by immunoblotting. Connexin43 is twice as abundant in midmyocardium and endocardium compared with epicardium in the mouse but not in the rat. Connexin45 is expressed equally across the left ventricular wall.

CONCLUSION

Epicardial myocytes express significantly less Cx43 and therefore may be less well coupled than midmyocardial and endocardial myocytes. A transmural gradient of connexin43 expression across the left ventricular free wall likely results in differences in the stoichiometry of connexins expressed in different regions of the heart.

Rho-associated kinases play a role in endocardial cell differentiation and migration

Development of the endocardial cushions in the heart involves cell migration and cell differentiation, which is known as epithelial-mesenchymal transformation (EMT). These processes are regulated by cell signaling systems. Yet, the roles of intracellular GTPases and their effectors on these cellular activities remain to be addressed. This study investigated the role Rho GTPase-associated kinases (ROCKs) in endocardial cushion development. Using reverse transcription (RT) and polymerase chain reaction (PCR), expression of the rock1 and rock2 genes was found in the endocardial cushions during development. To investigate the role of ROCKs in development, the ROCK inhibitor Y27632 and adenoviruses containing a dominant negative form of the rock gene were used to treat cultured endocardial cushions and cells. In monolayer cell culture and three-dimensional tissue culture, blockade of ROCK inhibited EMT development. Using three-dimensional collagen gel assays and confocal microscopy, we also observed inhibition of cell migration with ROCK inhibition. Examination of cell morphology and actin cytoskeleton revealed that inhibition of ROCK activity disturbed cytoskeletal organization and blocked the formation of lamellipodia and filopodia. Collectively, these data show that ROCKs play an essential role in endothelial cell differentiation and migration during endocardial cushion development.

HERG channel (dys)function revealed by dynamic action potential clamp technique

The human ether-a-go-go-related gene (HERG) encodes the rapid component of the cardiac delayed rectifier potassium current (I(Kr)). Per-Arnt-Sim domain mutations of the HERG channel are linked to type 2 long-QT syndrome. We studied wild-type and/or type 2 long-QT syndrome-associated mutant (R56Q) HERG current (I(HERG)) in HEK-293 cells, at both 23 and 36 degrees C. Conventional voltage-clamp analysis revealed mutation-induced changes in channel kinetics. To assess functional implication(s) of the mutation, we introduce the dynamic action potential clamp technique. In this study, we effectively replace the native I(Kr) of a ventricular cell (either a human model cell or an isolated rabbit myocyte) with I(HERG) generated in a HEK-293 cell that is voltage-clamped by the free-running action potential of the ventricular cell. Action potential characteristics of the ventricular cells were effectively reproduced with wild-type I(HERG), whereas the R56Q mutation caused a frequency-dependent increase of the action potential duration in accordance with the clinical phenotype. The dynamic action potential clamp approach also revealed a frequency-dependent transient wild-type I(HERG) component, which is absent with R56Q channels. This novel electrophysiological technique allows rapid and unambiguous determination of the effects of an ion channel mutation on the ventricular action potential and can serve as a new tool for investigating cardiac channelopathies.