Mecanosensores en el cambio de fenotipo de la musculatura lisa vascular / Mechanosensors and phenotype changes in vascular smooth muscle

Resumen: Introducción: Las células de la musculatura lisa vascular (CMLV) se caracterizan por mantener cierto grado de desdiferenciación, variando su fenotipo entre el contráctil y el secretor, de acuerdo con las necesidades del tejido, y el contráctil predominante en condiciones fisiológicas. Cualquier alteración del estímulo mecánico, ya sea en el flujo sanguíneo o la tensión mecánica ejercida sobre las CMLV, conducen a cambios de su fenotipo y remodelamiento de la vasculatura, lo que puede constituir el punto de inflexión de varias patologías relevantes en la salud pública como, por ejemplo, la hipertensión arterial. Objetivo: Realizar una revisión sobre los mecanosensores y las vías transduccionales conocidas e implicadas en el cambio de fenotipo de las CMLV. Metodología: Se realizó una búsqueda sistemática en las bases de datos PubMed, Scopus, Google Académico y Scielo sobre la mantención y cambio de fenotipo de las células de la musculatura lisa vascular asociado principalmente a el estrés mecánico, la participación de los mecanosensores más relevantes y las vías de señalización involucrados en este proceso. Conclusión: Los mecanosensores implicados en el cambio de fenotipo de las CMLV contemplan principalmente receptores acoplados a proteína G, moléculas de adhesión y canales iónicos activados por estiramiento. Los estudios se han concentrado en la activación o inhibición de vías como las proteínas quinasas activadas por mitógenos (MAPK), la vía AKT, mTOR y factores transcripcionales que regulan la expresión de genes de diferenciación y/o desdiferenciación, como las miocardinas. Existen además otros receptores involucrados en la respuesta al estrés mecánico, como los receptores tirosina quinasas. A pesar de la importancia que reviste el conocimiento de los mecanosensores y las vías implicadas en el cambio de fenotipo de las CMLV, así como el papel que cumplen en el establecimiento de patologías vasculares, es aún escaso el conocimiento que se tiene sobre los mismos.

Abstract: Introduction: Vascular smooth muscle cells (VS- MCs) are characterized by maintaining a certain de- gree of dedifferentiation. VSMCs may vary their phenotype between contractile and secretory according to tissue needs. Under physiological conditions, the predominant phenotype is contractile. Any alteration of the mechanical stimulus, either in the blood flow or the mechanical stress exerted on the VSMCs, leads to changes in their phenotype and remodeling of the vasculature. These changes can constitute the turning point in several hypertension and other diseases relevant in public health. Objective: To review the main mechanosensor and transduction pathways involved changes in VSMCs phenotype. Methods: A systematic search of PubMed, Scopus, Google Scholar and Scielo databases was carried out to ascertain the state of the art regarding the maintenance and change of VSMCs phenotype mainly associated with mechanical stress. Additionally, the participation of the most relevant mechanosensors and the signaling pathways involved in this process are discussed. Conclusion: The mechanosensors involved in the change in VSMCs phenotype mainly contempla- te G-protein-coupled receptors, adhesion molecules, and stretch-activated ion channels. Studies have been focused on the activation or inhibition of MAPK, AKT, mTOR, pathways and transcriptional factors that regulate the expression of differentiation and/or des differentiation genes such as Myocardins. There are also other receptors involved in the response to mechanical stress such as the tyrosine kinases receptor. Although the importance of understanding mechanosensors, the signaling pathways involved in VSMC phenotype switching and their role in the establishment of vascular pathologies, knowledge about them is limited.

Chikungunya: un reto para los servicios de salud de la República Dominicana / Chikungunya: a challenge for the Dominican Republic's health services

Desde diciembre de 2013, la Región de las Américas se enfrenta por primera vez a una epidemia de chikungunya. Los casos iniciales se registraron en el Caribe francés y, debido al comercio y la movilización de personas, esta epidemia no tardó en llegar a la República Dominicana, cuya población es de 10 millones de habitantes y comparte con Haití la isla La Española. En este artículo se difunde información extraída de diversos artículos y documentos oficiales sobre el virus, la infección y la epidemia de chikungunya, que han sido de gran ayuda para orientar la respuesta en la República Dominicana y pueden ser útiles para mejorar tanto el conocimiento como las actuaciones frente a la epidemia de los trabajadores del sector salud de la Región. Se destaca la importancia que revisten las investigaciones realizadas en países y territorios afectados del océano Índico, como la isla de Reunión, durante la epidemia declarada entre 2005 y 2007, cuando se registró una tasa de ataque mayor de 30%, se identificaron los grupos de riesgo, las formas graves y atípicas de la infección, la transmisión vertical del virus, las formas crónicas, que pueden provocar dolores recurrentes durante tres años, y las defunciones directa o indirectamente relacionadas con el virus chikungunya. Por su alta tasa de ataque, el virus chikungunya se convierte en un reto sin precedentes para los ministerios de salud, que exige una adecuada organización de los servicios de salud, la priorización de la atención a los grupos de riesgo y a los pacientes con formas graves de la enfermedad, así como una adecuada comunicación social y respuesta intersectorial.

The Region of the Americas has been affected since December 2013 by a chikungunya epidemic for the first time. Although the first cases were recorded in the French Caribbean, the epidemic quickly spread to the Dominican Republic due to trade and people movements. The Dominican Republic, which shares the island of Hispaniola with Haiti, has a population of 10 million. This article contains information from a range of different publications and official documents about the chikungunya virus infection and epidemic. These papers were extremely helpful for guiding the response to the epidemic in the Dominican Republic and may also be useful for enhancing knowledge of the virus and responses among health workers elsewhere in the region. Particular attention is drawn to the important research undertaken in countries and territories affected by the epidemic in the Indian Ocean area. This is the case, for example, of the island of La Réunion, where the epidemic had an attack rate of more than 30% between 2005 and 2007. Researchers were able to identify risk groups, severe and atypical forms of the infection, cases of vertical transmission, chronic disease causing recurrent pain over three years, and directly- or indirectly-related deaths from the virus. Given its high attack rate, the chikungunya virus has emerged as an exceptional challenge for health ministries and calls for appropriate organized responses from the health services, prioritization of care for risk groups and patients exhibiting severe forms of the disease, and effective social communication and intersectoral actions.

Vascular O-GlcNAcylation augments reactivity to constrictor stimuli by prolonging phosphorylated levels of the myosin light chain

O-GlcNAcylation is a modification that alters the function of numerous proteins. We hypothesized that augmented O-GlcNAcylation levels enhance myosin light chain kinase (MLCK) and reduce myosin light chain phosphatase (MLCP) activity, leading to increased vascular contractile responsiveness. The vascular responses were measured by isometric force displacement. Thoracic aorta and vascular smooth muscle cells (VSMCs) from rats were incubated with vehicle or with PugNAc, which increases O-GlcNAcylation. In addition, we determined whether proteins that play an important role in the regulation of MLCK and MLCP activity are directly affected by O-GlcNAcylation. PugNAc enhanced phenylephrine (PE) responses in rat aortas (maximal effect, 14.2±2 vs 7.9±1 mN for vehicle, n=7). Treatment with an MLCP inhibitor (calyculin A) augmented vascular responses to PE (13.4±2 mN) and abolished the differences in PE-response between the groups. The effect of PugNAc was not observed when vessels were preincubated with ML-9, an MLCK inhibitor (7.3±2 vs 7.5±2 mN for vehicle, n=5). Furthermore, our data showed that differences in the PE-induced contractile response between the groups were abolished by the activator of AMP-activated protein kinase (AICAR; 6.1±2 vs 7.4±2 mN for vehicle, n=5). PugNAc increased phosphorylation of myosin phosphatase target subunit 1 (MYPT-1) and protein kinase C-potentiated inhibitor protein of 17 kDa (CPI-17), which are involved in RhoA/Rho-kinase-mediated inhibition of myosin phosphatase activity. PugNAc incubation produced a time-dependent increase in vascular phosphorylation of myosin light chain and decreased phosphorylation levels of AMP-activated protein kinase, which decreased the affinity of MLCK for Ca2+/calmodulin. Our data suggest that proteins that play an important role in the regulation of MLCK and MLCP activity are directly affected by O-GlcNAcylation, favoring vascular contraction.

Functional expression of kinin B1 and B2 receptors in mouse abdominal aorta

Previous studies have shown that the vascular reactivity of the mouse aorta differs substantially from that of the rat aorta in response to several agonists such as angiotensin II, endothelin-1 and isoproterenol. However, no information is available about the agonists bradykinin (BK) and DesArg9BK (DBK). Our aim was to determine the potential expression of kinin B1 and B2 receptors in the abdominal mouse aorta isolated from C57BL/6 mice. Contraction and relaxation responses to BK and DBK were investigated using isometric recordings. The kinins were unable to induce relaxation but concentration-contraction response curves were obtained by applying increasing concentrations of the agonists BK and DBK. These effects were blocked by the antagonists Icatibant and R-715, respectively. The potency (pD2) calculated from the curves was 7.0 ± 0.1 for BK and 7.3 ± 0.2 for DBK. The efficacy was 51 ± 2 percent for BK and 30 ± 1 percent for DBK when compared to 1 æM norepinephrine. The concentration-dependent responses of BK and DBK were markedly inhibited by the arachidonic acid inhibitor indomethacin (1 æM), suggesting a mediation by the cyclooxygenase pathway. These contractile responses were not potentiated in the presence of the NOS inhibitor L-NAME (1 mM) or endothelium-denuded aorta, indicating that the NO pathway is not involved. We conclude that the mouse aorta constitutively contains B1 and B2 subtypes of kinin receptors and that stimulation with BK and DBK induces contractile effect mediated by endothelium-independent vasoconstrictor prostanoids.

The role of vascular smooth muscle cells on the pathogenesis of atherosclerosis.

Atherosclerosis is the leading cause of death and disability. The lesions of atherosclerosis represent a series of highly specific cellular and molecular responses. The earliest changes that precede the formation of lesions of atherosclerosis take place in the endothelium (EC), with resultant endothelial dysfunction. The EC-induced injury can result in increased lipid permeability, macrophage recruitment, formation of foam cells, and recruitment of T-lymphocytes and platelet. After intimal injury, different cell types,including ECs, platelets, and inflammatory cells release mediators, such as growth factors and cytokines that induce multiple effects including phenotype change of vascular smooth muscle cells (VSMC) from the quiescent "contractile" phenotype state to the active "synthetic" state, that can migrate and proliferate from media to the intima. The inflammatory response simulates migration and proliferation of VSMC that become intermixed with the area of inflammation to form an intermediate lesion. These responses continue uninhibited and is accompanied by accumulation of new extra cellular matrix (ECM). The migratory and proliferative activities of VSMC are regulated by growth promoters such as platelet derived growth factors (PGF), endothelin-1 (ET-1), thrombin, fibroblast growth factor (FGF), interleukin-1 (IL-1) and inhibitors such as, heparin sulfates , nitric oxide (NO), transforming growth factor (TGF)-beta. The matrix metallo proteinases (MMPs) could also participate in the process of VSMC migration. MMPs could catalyze and remove the basement membrane around VSMC and facilitate contacts with the interstitial matrix. This could promote a change from quiescent, contractile VSMC to cells capable of migrating and proliferating to mediate repair. The VSMC regulation is a very complex process, VSMC are stimulated to proliferate and migrate by some kind of cytokines, growth factors, angiotensin II (Ang-II). Together with apoptosis, proliferation and migration of VSMC are vital to the pathogenesis of atherosclerosis and plaque rupture. Rupture of the plaque is associated with increased fibrous cap macrophage, increased VSMC apoptosis, and reduced fibrous cap VSMC. VSMC are the only cells with plaques capable of synthesizing structurally important collagen isoforms, and the apoptosis of VSMC might promote plaque rupture.

Role of Ca++ gradient in functional dilatation in the microvessels of rat skeletal muscle.

During skeletal muscle contraction functional dilatation (FD) is a well established phenomenon, which is usually linked to the accumulation of various vasodilator metabolites. The present study aimed to establish the role of calcium ions (Ca++) in the functional dilatation of skeletal muscle microvessels especially during single & few twitches. The FD was studied in urethane anaesthetized rats whose spinotrapezius muscle was prepared for intravital microscopy. After stimulating the muscle with few twitch (1 & 3 Hz) and tetanic frequency (40 Hz), muscle contracted and showed dilatation. However the dilator response was quickest (1 Hz : 10 +/- 0.40, 3 Hz : 02 +/- 0.47 sec and 40 Hz : 02 +/- 0.10 sec) and maximum in magnitude (1 Hz : 25 +/- 0.30%, 3 Hz : 35 +/- 0.49% and 40 Hz : 55 +/- 0.39%) in terminal arteriole and with tetanic frequency. Calcium channel blockade by Diltiazem abolished the FD response except for tetanic stimulation contraction. Findings suggested possible involvement of Ca++ movement in functional dilatation which was initiated by passive efflux of Ca++ from smooth muscle of vessel and then maintained during higher frequency stimulation by release of local metabolities.

Mecanismos da contratação do músculo liso vascular / Vascular smooth muscle contraction mechanisms

A transmissão do sinal originado na membrana plasmática, para promover a ligação entre a excitação e a contração, é feita através de acoplamento eletromecânico ou farmacomecânico, ambos levando ao aumento do cálcio intracelular. O primeiro é devido à despolarização da membrana, ativando canais de cálcio dependentes de voltagem; e o segundo resulta da interação de agonistas com receptores ligados à proteína G, ativando as fosfolipases e liberando o inositol 1,4,5 trisfosfato (lP3) e o diacilglicerol (DAG). O IP31ibera cálcio do retículo sarcoplasmático e o DAG ativa a proteína quinase C, aumentando a condutância dos canais de cálcio transmembranais. O cálcio intracelular, ao ligar-se à calmodulina, altera a sua conformação, permitindo sua interação com a quinase da cadeia leve da miosina (MLCK), deslocando a seqüência auto inibitória da MLCK que fosforila a miosina. A exposição dos sítios ativos promove a ligação cíclica da porção globular da miosina com actina, seguida pela mudança do ângulo de orientação do complexo actomiosina, o que promove o deslizamento de um filamento sobre o outro. O desenvolvimento da tensão do músculo depende da ativação da miosina pela fosforilação direta e da ativação da actina, pela saída do complexo tropomiosina/caldesmon, induzida pela cálcio/calmodulina. A energia deste processo é devida ao ATp, liberado pela miosina ATPase após sua interação com a actina. As contrações do músculo liso vascular são do tipo tônico, desenvolvendo-se lentamente e mantendo um tônus constante. O tônus basal do músculo liso vascular é responsável pela manutenção da resistência periférica

P2X1 receptors and the endothelium

Adenosine triphosphate (ATP) is now established as a principle vaso-active mediator in the vasculature. Its actions on arteries are complex, and are mediated by the P2X and P2Y receptor families. It is generally accepted that ATP induces a bi-phasic response in arteries, inducing contraction via the P2X and P2Y receptors on the smooth muscle cells, and vasodilation via the actions of P2Y receptors located on the endothelium. However, a number of recent studies have placed P2X1 receptors on the endothelium of some arteries. The use of a specific P2X1 receptor ligand, alpha, beta methylene ATP has demonstrated that P2X1 receptors also have a bi-functional role. The actions of ATP on P2X1 receptors is therefore dependant on its location, inducing contraction when located on the smooth muscle cells, and dilation when expressed on the endothelium, comparable to that of P2Y receptors.

17/β-Estradiol modulates effects of insulin-induced changes in vascular contractility / El 17/β-estradiol modula los efectos de los cambios de la contractilidad vascular producidos por la insulina

The protective role of estrogens against peripheral vascular and coronary disease in women is well documented; however, it is not present in diabetic women. Estrogens reduce tension development through non-genomic mechanisms that include changes in calcium concentrations in endothelial and smooth muscle cells, and regulation of nitric oxide synthase (NOS) in endothelial cells. Insulin increases endothelin-1 (ET-1) release from endothelial cells modulating smooth muscle calcium levels and elevating force generated by femoral and coronary arteries. This paper examines whether 17/β-estradiol (E2β) modulates changes in femoral and coronary artery contractility induced by insulin. Femoral and coronary arteries were obtained from male Wistar rats, placed in isolated tissue baths for in vitro studies, perfused with different solutions, and the contractile response to KCl 40 mmol/L was measured. Insulin increased arterial contraction induced by KCl. This increase was not present when the endothelium was removed. In the presence of E2β, we observed a dose dependent reduction in the tension developed and this effect disappeared when the endothelium was removed. The insulin-induced contraction was significantly reduced in presence of E2β. These data indicate that the effect of insulin on femoral and coronary vascular contractility is modulated by E2β.

Los estrógenos protegen a la mujer contra enfermedades vasculares periféricas y centrales; sin embargo, su papel se pierde con la diabetes. Los estrógenos reducen la tensión en las arterias mediante cambios en el calcio intracelular en células endoteliales y musculares lisas y la regulación de la óxido nítrico sintasa en células endoteliales. La insulina incrementa la liberación de endotelina-1 (ET-1) en células endoteliales aumentando la fuerza generada por las arterias. En este estudio se examina si el 17/β-estradiol (E2β) modula los cambios en la contractilidad inducidos por insulina en las arterias femorales y coronarias. Las arterias se obtuvieron de ratas Wistar macho y se colocaron en cámaras para tejido aislado para perfundirse in vitro con distintas concentraciones de insulina y estrógenos estimulando la contracción con KCl 40 mmol/L. La insulina elevó la fuerza de la contracción inducida por KCl. Este incremento desapareció cuando se eliminó el endotelio. El E2β disminuyó la tensión desarrollada por las arterias conforme se aumentó la dosis y el efecto desapareció al quitar el endotelio. El incremento en la tensión por insulina disminuyó con E2β. En conclusión el efecto de la insulina sobre las arterias femorales y coronarias se encuentra modulado por el E2β.(Arch Cardiol Mex 2003; 73:254-260).

Effects of changes in PH the contractility of vascular smooth muscle

Hydrogen ion concentration [H+] is an important regulator of many cellular functions including contractility of the vascular smooth muscle cells. In many physiological and pathological states, changes in pH may have profound effects on the contractility of blood vessels and thus on the peripheral vascular resistance and blood pressure. Therefore, it is necessary to understand the likely outcome of the situations in the conditions, where pH changes are frequent. In this review, the mechanisms involved in the contractile responses of vascular tissues to pH changes are discussed

Experimental evidence for a non-renin mediated pathway during TAME-esterase induced contractions in rat aorta in vitro.

Possible pharmacological effects of N-alpha-tosyl L-arginine methyl ester [TAME] were studied on rat aorta strips in vitro. Results showed that [TAME]-esterase was an endothelium dependent component that involved a nitric oxide cyclic-GMP mediated pathway. Furthermore, during activation of Kinin-Kallikrein system, TAME-esterase induced contractions involve degradation of kinins by kininases.

Aspectos estructurales y funcionales de la vena safena humana utilizada como puente aorto-coronario en la cirugia de revascularización miocárdica / Structural and functional aspects of the human saphenous vein used as aorto-coronary graft in myocardial revascularization

La vena safena humana (VSH) se utiliza como puente en la cirugía de revascularización coronaria y de otros lechos arteriales, especialmente de miembros inferiores. Dado que los puentes de VSH presentan un porcentaje considerable de obliteración, numerosos estudios han investigado los factores que promoverían la producción de la estenosis en los mismos. Este artículo describe resultados sobre las condiciones estructurales y funcionales que confluyen para producir la obstrucción de los puentes de VSH. Se analiza la reactividad de la VSH a agonistas fisiológicos, incluídos los factores contrayentes y relajantes derivados del endotelio, por su importancia en determinar el vasoespasmo y en modificar la expresión de factores de crecimiento tisular y/o promotores de procesos trombóticos y ateromatosos. Se describen mecanismos involucrados en la regulación del estado contráctil de los miocitos lisos, en particular la actividad de canales de K+ de la membrana

Gap junctions in the cardiovascular and immune systems

Gap junctions are clusters of intercellular channels directly connecting the cytoplasm of adjacent cells. These channels are formed by proteins named connexins and are present in all metazoan organisms where they serve diverse functions ranging from control of cell growth and differentiation to electric conduction in excitable tissues. In this overview we describe the presence of connexins in the cardiovascular and lympho-hematopoietic systems giving the reader a summary of the topics to be covered throughout this edition and a historical perspective of the discovery of gap junctions in the immune system

Tissue engineering a blood vessel substitute: the role of biomechanics

The engineering of a functional blood vessel substitute has for a quarter of a century been a "holy grail" within the cardiovascular research community. Such a substitute must exhibit long term patency, and the critical issues in this area in many ways are influenced by biomechanics. One of the requirements is that it must be non-thrombogenic, which requires an "endothelial-like" inner lining. It also must have mechanical strength, i.e. a burst pressure, sufficient to operate at arterial pressures. Ideally, however, it must be more than this. It also must have viscoelastic properties that match those of the native vessel being replaced. Finally, if it is to be able to adapt to changing blood flow conditions, it must exhibit vasoactivity, a function which in and of itself can be viewed as biomechanical in nature. To achieve this requires having, as part of the construct, vascular smooth muscle cells, which are contractile in nature and oriented in a circumferential direction. Only if an engineered blood vessel substitute possesses all of these functional characteristics, can one say that the functionality exhibited by a native vessel is being mimicked.

In vitro model of atherosclerosis using coculture of arterial wall cells and macrophage

In order to determine the precise mechanism of the interactions between different types of cells, which are common phenomena in tissues and organs, the importance of coculture techniques are becoming increasingly important. In the area of cardiology, artificial arteries have been developed, based on the understanding of physiological communication of the arterial smooth muscle cells (SMC), endothelial cells (EC), and the extracellular matrix (ECM). In the study of atherosclerosis, the modification of low-density lipoprotein (LDL), which result in the recruitment and accumulation of white blood cells, especially, monocytes/macrophages, and foam cell formation, are hypothesized. Although there are well known animal models, an in vitro model of atherogenesis with a precisely known atherogenesis mechanism has not yet been developed. In this paper, an arterial wall reconstruction model using rabbit primary cultivated aortic SMCs and ECs, was shown. In addition, human peripheral monocytes were used and the transmigration of monocytes was observed by scanning electron and laser confocal microscopy. Monocyte differentiation into macrophages was shown by immunohistochemistry and comprehensive gene expression analysis. With the modified form of LDL, the macrophages were observed to accumulate lipids with a foamy appearance and differentiate into the foam cells in the ECM between the ECs and SMCs in the area of our coculture model.

Membrane stretch increases the activity of Ca(2+)-activated K+ channels in rabbit coronary vascular smooth muscles

It has been proposed that Ca(2+)-activated K+ channels play an essential role in maintaining vascular tone during stretch of blood vessel. However, the underlying mechanism of stretch-induced change of Ca(2+)-activated K+ channel activities are still unknown. The present experiment was designed to investigate the effect of membrane stretch on these channels whose activity was measured from rabbit coronary smooth muscle cells using a patch clamp technique. Ca(2+)-activated K+ channel were identified by their Ca2+ and voltage dependencies and its large conductances as in other preparations. Perfusion of cells with a hypotonic solution, which mimics stretching the cell membrane by making a cell swelling, produced an increase in channel activity in cell-attached patch mode. The similar increase was observed when negative pressure was applied into the patch pipette for stretching the cell membrane within a patch area. In inside-out patch, stretch still increased channel activity even under the conditions which exclude the possible involvement of secondary messengers, or of transmembrane Ca2+ influx via stretch-activated cation channels. Pretreatment of arachidonic acid or albumin showed no effect on stretch-induced channel activation, excluding the possibility of fatty acids mediated channel activation during membrane stretch. These results indicate that the stretch may directly increase the activity of Ca(2+)-activated K+ channels in our experimental condition.

All-trans-retinoic acid attenuates neointima formation with acceleration of reendothelialization in balloon-injured rat aorta

Retinoic acids may inhibit vascular smooth muscle cell proliferation, but may promote endothelial cell proliferation in cell culture. However, little data are available about the effects of all-trans-retinoic acid (ATRA) on endothelial regeneration and functional recovery in an experimental model of vascular injury. Accordingly, we investigated whether ATRA may attenuate neointima formation and accelerate endothelial regeneration with functional recovery in balloon-injured rat aorta. Twelve-week-old male Sprague-Dawley rats underwent endothelial denudation of the thoracic aorta by balloon injury. Fourteen rats were fed a standard rat pellet diet. Another 14 rats were fed ATRA (1.5 mg/day) for 2 weeks. The animals were killed on day 14 for organ chamber study and morphometric analysis. Rats in the ATRA group had a significantly improved acetylcholine-induced relaxation response than those in control group. However, endothelial independent response was not significantly different between the two groups. The extent of reendothelialization was markedly superior in the ATRA group compared with control group (p>0.05). Furthermore, neointima area and the ratio of neointima to medial area were significantly less in ATRA group than in control group (p>0.05). In conclusion, ATRA may accelerate endothelial regeneration with functional recovery, and attenuate neointima formation in balloon-injured rat aorta.

Calcium handling by vascular myocytes in hypertension

Calcium ions (Ca2+) trigger the contraction of vascular myocytes and the level of free intracellular Ca2+ within the myocyte is precisely regulated by sequestration and extrusion mechanisms. Extensive evidence indicates that a defect in the regulation of intracellular Ca2+ plays a role in the augmented vascular reactivity characteristic of clinical and experimental hypertension. For example, arteries from spontaneously hypertensive rats (SHR) have an increased contractile sensitivity to extracellular Ca2+ and intracellular Ca2+ levels are elevated in aortic smooth muscle cells of SHR. We hypothesize that these changes are due to an increase in membrane Ca2+ channel density and possibly function in vascular myocytes from hypertensive animals. Several observations using various experimental approaches support this hypothesis: 1) the contractile activity in response to depolarizing stimuli is increased in arteries from hypertensive animals demonstrating increased voltage-dependent Ca2+ channel activity in hypertension; 2) Ca2+ channel agonists such as Bay K 8644 produce contractions in isolated arterial segments from hypertensive rats and minimal contraction in those from normotensive rats; 3) intracellular Ca2+ concentration is abnormally increased in vascular myocytes from hypertensive animals following treatment with Ca2+ channel agonists and depolarizing interventions, and 4) using the voltage-clamp technique, the inward Ca2+ current in arterial myocytes from hypertensive rats is nearly twice as large as that from myocytes of normotensive rats. We suggest that an alteration in Ca2+ channel function and/or an increase in Ca2+ channel density, resulting from increased channel synthesis or reduced turnover, underlies the increased vascular reactivity characteristic of hypertension.

Efecto de N-Nitro-L-Arginina sobre la contracción y relajación en músculo liso vascular / Effect of N-Nitro-L-Arginine on the concentration and relaxation of vascular smooth muscle

La contractilidad del músculo liso arterial esta regulado por la concentración de calcio libre intracelular y por la estimulación de receptores adrenérgicos (alpha 1 y alpha 2 (norepinefrina (NE), fenilefrina (PHE) y clonidina) inducen contracciones, aumentando la tensión vascular e incrementando la concentración de calcio intracelular. Esta respuesta aumenta en ausencia de endotelio. Por otro lado, la relajación de arterias aisladas inducidas por acetilcolina (ACh) es dependiente de endotelio y modulada por EDRF. Nosotros estudiamos el efecto de la preincubación N-nitro-L-arginina (L-NA) sobre la contracción alpha-adrenérgica inducida y la relajación inducida por ACh respectivamente en aorta torácica aislada de rata en comparación con el efecto producido por KCl 70mM, la cual es tomada como control. Los resultados muestran una diferencia significativa (p<0.001) en presencia de L-NA en la contracción producida por FE comparada a la ausencia de L-NA. En las tres concentraciones de ACh usadas, la presencia de L-NA indujo una relajación inferior al 20 por ciento. La ausencia de L-NA indujo 100 por ciento de relajación, retorno a la línea base. L-NA induce un aumento en la entrada de calcio através de canales modulados por receptor y porque la inhibición de la síntesis de EDRF produce un aumento de la tensión vascular. De la misma forma, la relajación se explicada por la liberación de EDRF estimulada por ACh, la cual es inhibida por L-NA. Considerando el endotelio vascular como un órgano paracrino, es importante e interesante estudiar la farmacomodulación de los efectos de NO/EDRF y por misma razón considerar al L-NA en el arsenal farmacológico.