Hemant S. Thatte

Receptor-regulated Translocation of Endothelial Nitric-oxide Synthase

The endothelial nitric-oxide synthase (eNOS) is activated by transient increases in intracellular Ca2+ elicited by stimulation of diverse receptors, including bradykinin B2 receptors on endothelial cells. eNOS and B2 receptors are targeted to specialized signal-transducing domains in the plasma membrane termed plasmalemmal caveolae. Targeting to caveolae facilitates eNOS activation following receptor stimulation, but in resting cells, eNOS is tonically inhibited by its interactions with caveolin, the scaffolding protein in caveolae. We used a quantitative approach exploiting immunofluorescence microscopy to investigate regulation of the subcellular distribution of eNOS in endothelial cells by bradykinin and Ca2+. In resting cells, most of the eNOS is localized at the cell membrane. However, within 5 min following addition of bradykinin, nearly all the eNOS translocates to structures in the cell cytosol; following more protracted incubations with bradykinin, most of the cytosolic enzyme subsequently translocates back to the cell membrane. The bradykinin-induced internalization of eNOS is completely abrogated by the intracellular Ca2+ chelator BAPTA; conversely, Ca2+-mobilizing drugs and agonists promote eNOS translocation. These results establish that eNOS targeting to the membrane is labile and is subject to receptor-regulated Ca2+-dependent reversible translocation, providing another point for regulation of NO-dependent signaling in the vascular endothelium.

Transmembrane calcium influx induced by ac electric fields

Exogenous electric fields induce cellular responses including redistribution of integral membrane proteins, reorganization of microfilament structures, and changes in intracellular calcium ion concentration ([Ca2+]i). Although increases in [Ca2+]i caused by application of direct current electric fields have been documented, quantitative measurements of the effects of alternating current (ac) electric fields on [Ca2+]i are lacking and the Ca2+ pathways that mediate such effects remain to be identified. Using epifluorescence microscopy, we have examined in a model cell type the [Ca2+]i response to ac electric fields. Application of a 1 or 10 Hz electric field to human hepatoma (Hep3B) cells induces a fourfold increase in [Ca2+]i (from 50 nM to 200 nM) within 30 min of continuous field exposure. Depletion of Ca2+ in the extracellular medium prevents the electric field‐induced increase in [Ca2+]i, suggesting that Ca2+ influx across the plasma membrane is responsible for the [Ca2+]i increase. Incubation of cells with the phospholipase C inhibitor U73122 does not inhibit ac electric field‐induced increases in [Ca2+]i, suggesting that receptor‐regulated release of intracellular Ca2+ is not important for this effect. Treatment of cells with either the stretch‐activated cation channel inhibitor GdCl3 or the nonspecific calcium channel blocker CoCl2 partially inhibits the [Ca2+]i increase induced by ac electric fields, and concomitant treatment with both GdCl3 and CoCl2 completely inhibits the field‐induced [Ca2+]i increase. Since neither Gd3+ nor Co2+ is efficiently transported across the plasma membrane, these data suggest that the increase in [Ca2+]i induced by ac electric fields depends entirely on Ca2+ influx from the extracellular medium.—Cho, M. R., Thatte, H. S., Silvia, M. T., Golan, D. E. Transmembrane calcium influx induced by ac electric fields. FASEB J. 13, 677–683 (1999)

The coronary artery bypass conduit: I. Intraoperative endothelial injury and its implication on graft patency.

Prevention of intraoperative injury to the vascular endothelium is of primary importance in maintaining viability and patency of the aorto-coronary saphenous vein graft. Surgical manipulation, ischemia, storage conditions, and distension before anastomosis can abnormally alter the antithrombogenic property of the endothelium leading to vasospasms, thrombogenesis, occlusive intimal hyperplasia, and stenosis. Endothelial injury can also form an initiation site for the formation of later-stage atheromas and graft failure. A multifactorial strategy aimed at prevention of endothelial injury and graft failure should include improved surgical techniques, optimal preservation conditions, avoidance of nonphysiologic distension pressures, and use of specific pharmacologic agents as the primary form of intervention. The successful application of this strategy, and the development of newer and more efficacious strategies that may impact on long-term graft patency, can now be aided by assessment of the structural and functional integrity of bypass conduits using multiphoton imaging techniques.

Saphenous Vein Conduits Harvested by Endoscopic Technique Exhibit Structural and Functional Damage

BACKGROUND Injury to the saphenous vein endothelium during harvest impacts patency after coronary artery bypass graft surgery. Many centers are adopting endoscopic saphenous vein harvest (ESVH) instead of using the traditional open saphenous vein harvest (OSVH) technique. Our objective was to compare the effects of ESVH and OSVH on the structural and functional viability of saphenous vein endothelium using multiphoton imaging, immunofluorescence, and biochemical techniques. METHODS Ten patients scheduled for coronary artery bypass graft surgery were prospectively identified. Each underwent ESVH for one portion and OSVH for another portion of the saphenous vein. A 1-cm segment from each portion was immediately transported to the laboratory for processing. The vessel segments were labeled with fluorescent markers to quantify cell viability (esterase activity), calcium mobilization, and generation of nitric oxide. Samples were also labeled with immunofluorescent antibodies to visualize caveolin, endothelial nitric oxide synthase, von Willebrand factor, and cadherin, and extracted to identify these proteins using Western blot techniques. All labeling, imaging, and image analysis was done in a blinded fashion. RESULTS Esterase activity was significantly higher in the OSVH group (p < 0.0001). Similarly, calcium mobilization and nitric oxide production were significantly greater in the OSVH group (p = 0.0209, p < 0.0001, respectively). Immunofluoresence and Western blot techniques demonstrated an abnormal alteration in distribution of caveolin and endothelial nitric oxide synthase in the ESVH group. CONCLUSIONS Our study indicates that ESVH has a detrimental effect on the saphenous vein endothelium, which may lead to decreased graft patency and worse patient outcomes.

Role of HERG-like K(+) currents in opossum esophageal circular smooth muscle.

An inwardly rectifying K+ conductance closely resembling the human ether-a-go-go-related gene (HERG) current was identified in single smooth muscle cells of opossum esophageal circular muscle. When cells were voltage clamped at 0 mV, in isotonic K+ solution (140 mM), step hyperpolarizations to -120 mV in 10-mV increments resulted in large inward currents that activated rapidly and then declined slowly (inactivated) during the test pulse in a time- and voltage- dependent fashion. The HERG K+ channel blockers E-4031 (1 μM), cisapride (1 μM), and La3+ (100 μM) strongly inhibited these currents as did millimolar concentrations of Ba2+. Immunoflourescence staining with anti-HERG antibody in single cells resulted in punctate staining at the sarcolemma. At membrane potentials near the resting membrane potential (-50 to -70 mV), this K+ conductance did not inactivate completely. In conventional microelectrode recordings, both E-4031 and cisapride depolarized tissue strips by 10 mV and also induced phasic contractions. In combination, these results provide direct experimental evidence for expression of HERG-like K+ currents in gastrointestinal smooth muscle cells and suggest that HERG plays an important role in modulating the resting membrane potential.

Reorganization of microfilament structure induced by ac electric fields.

AC electric fields induce redistribu‐tion of integral membrane proteins. Cell‐surface re‐ceptor redistribution does not consistently follow electric field lines and depends critically on the frequency of the applied ac electric fields, suggesting that mechanisms other than electroosmosis are involved. We hypothesized that cytoskeletal reorganization is responsible for electric field‐induced cell‐surface receptor redistribution, and used fluorescence video microscopy to study the reorganization of microfilaments in human hepatoma (Hep3B) cells exposed to low‐frequency electric fields ranging in strength from 25 mV/cm to 20 V/cm (peak to peak). The frequency of the applied electric field was varied from 1 to 120 Hz and the field exposure duration from 1 to 60 min. In control cells, cytoplas‐mic microfilaments were aligned in the form of continuous parallel cables along the longitudinal axis of the cell. Exposure of cells to ac electric fields induced alterations in microfilament structure in a manner that depended on the frequency of the applied field. A 1 or 10 Hz ac field caused microfilament reorganization from continuous, aligned cable structures to discontinuous globular patches. In contrast, the structure of microfilaments in cells exposed to 20‐120 Hz electric fields did not differ from that in control cells. The extent of microfilament reor‐ganization increased nonlinearly with the electric field strength. The characteristic time for microfila‐ment reorganization in cells exposed to a 1 Hz, 20 V/cm electric field was ~5 min. Applied ac electric fields could initiate signal transduction cascades, which in turn cause reorganization of cytoskeletal structures.—Cho, M. R., Thatte, H. S., Lee, R. C., Golan, D. E. Reorganization of microfilament struc‐ture induced by ac electric fields. FASEB J. 10, 1552‐1558 (1996)

Induced redistribution of cell surface receptors by alternating current electric fields.

The molecular mechanisms that underlie the biological effects of low frequency sinusoidal electric fields may involve induced changes in the physical state of charged cell surface receptors. We have used intensified fluorescence video microscopy to study the redistribution of cell surface receptors, including transferrin receptors (TFR) and low density lipoprotein receptors (LDL‐R), in response to externally applied alternating current electric fields in the 3 to 23 V/cm range (peak to peak). Redistribution of both TFR and LDL‐R was prominent at frequencies of 1 and 10 Hz but negligible at frequencies of 60 and 120 Hz. Application of a 1 Hz, 23 V/cm field for 15 min caused a twofold change in local TFR surface density, whereas application of a 60 Hz, 23 V/cm field resulted in no significant TFR redistribution. The extent of TFR redistribution induced by a 1 Hz field changed by only 20% over the field strength range from 3.5 to 23 V/cm. AC field‐induced cell surface receptor migration did not consistently follow electric field lines, suggesting that mechanisms more complex than classical electrophoresis and electroosmosis mediate receptor redistribution. Joule heating and plasma membrane calcium channel activation were shown not to be involved in the mechanism of receptor redistribution. Applied external electric fields may reorganize cytoskeletal and plasma membrane structures, providing pathways for cell surface receptors to migrate anharmonically.— Cho, M. R., Thatte, H. S., Lee, R. C., Golan, D. E. Induced redistribution of cell surface receptors by alternating current electric fields. FASEB J. 8: 771‐776; 1994.

Integrin-dependent human macrophage migration induced by oscillatory electrical stimulation.

Electrical stimulation has been used to promote wound healing. The mechanisms by which such stimulation could interact with biological systems to accelerate healing have not been elucidated. One potential mechanism could involve stimulation of macrophage migration to the site of a wound. Here we report that oscillatory electric fields induce human macrophage migration. Macrophages exposed to a 1 Hz, 2 V/cm field show an induced migration velocity of 5.2±0.4 ×10-2 μm/min and a random motility coefficient of 4.8±1.4 ×10-2 μm2/min on a glass substrate. Electric field exposure induces reorganization of microfilaments from ring-like structures at the cell periphery to podosomes that are confined to the contact sites between cell and substrate, suggesting that the cells are crawling on glass. Treatment of cells with monoclonal antibodies directed against β 2-integrins prior to field exposure prevents cell migration, indicating that integrin-dependent signaling pathways are involved. Electric fields cause macrophage migration on laminin or fibronectin coated substrates without inducing podosome formation or changes in cellular morphology. The migration velocity is not significantly altered but the random movement is suppressed, suggesting that cell movements on a laminin- or fibronectin-coated surface are not mediated by cell crawling. It is suggested that electric field-induced macrophage migration utilizes several modes of cell movement, including cell crawling and possibly cell rolling. ©

Multi-photon microscopic evaluation of saphenous vein endothelium and its preservation with a new solution, GALA

BACKGROUND Injury to endothelium can compromise the patency of bypass grafts harvested during coronary artery bypass graft (CABG) surgery. Maintaining structural and functional viability of endothelium in grafts may lead to improved long-term patency. The information gained from the application of multi-photon microscopy in transmission and epifluorescence mode was used to assess the structural and functional integrity of human saphenous vein segments stored in multiple preservation solutions, and to design a superior storage solution. METHODS Multi-photon microscopy was used to image deep within saphenous vein tissue harvested from patients undergoing CABG for analysis of endothelial structure and function. Endothelial cell structural viability, calcium mobilization, and nitric oxide generation were determined using specific fluorescence markers. RESULTS Within 60 minutes of harvest and storage in standard preservation solutions, calcium mobilization and nitric oxide generation were markedly diminished with more than 90% of endothelial cells no longer viable in the vein. In contrast, veins could be stored for 24 hours without substantial loss in cell viability in a newly formulated heparinized physiologic buffered salt solution containing glutathione, ascorbic acid, and L-arginine (GALA). CONCLUSIONS Standard solutions in clinical use today led to a profound decline in saphenous vein endothelial cell viability, whereas the newly designed physiologic salt solution (GALA) maintained endothelial function and structural viability for up to 24 hours. The improvements seen from using GALA as a vessel storage medium may lead to greater long-term vein graft patency following CABG surgery.

Control of band 3 lateral and rotational mobility by band 4.2 in intact erythrocytes: release of band 3 oligomers from low-affinity binding sites

Band 4.2 is a human erythrocyte membrane protein of incompletely characterized structure and function. Erythrocytes deficient in band 4.2 protein were used to examine the functional role of band 4.2 in intact erythrocyte membranes. Both the lateral and the rotational mobilities of band 3 were increased in band 4.2-deficient erythrocytes compared to control cells. In contrast, the lateral mobility of neither glycophorins nor a fluorescent phospholipid analog was altered in band 4.2-deficient cells. Compared to controls, band 4.2-deficient erythrocytes manifested a decreased ratio of band 3 to spectrin, and band 4.2-deficient membrane skeletons had decreased extractability of band 3 under low-salt conditions. Normal band 4.2 was found to bind to spectrin in solution and to promote the binding of spectrin to ankyrin-stripped inside-out vesicles. We conclude that band 4.2 provides low-affinity binding sites for both band 3 oligomers and spectrin dimers on the human erythrocyte membrane. Band 4.2 may serve as an accessory linking protein between the membrane skeleton and the overlying lipid bilayer.