Regulation of pressure and local blood flow occurs at the level of resistance arteries and arterioles. Under physiological conditions, these small vessels exist in a state of partial constriction, termed myogenic tone. Myogenic tone is considered to be an intrinsic property of arteriolar smooth muscle cells, which membranes depolarize in response to increase in the intraluminal pressure. Oscillations of membrane potential in smooth muscles are mediated by the activity of voltage-gated L-type Ca2+ channels, which provide an influx of Ca2+ to activate various voltage-gated and Ca2+-sensitive channels of smooth muscle cells and to initiate endothelial Ca2+ signaling needed for vasodilation. Although a relationship between change in membrane potential and myogenic response is considered to be universal throughout various smooth muscle tissues, it may be regulated differently based on autoregulatory responses and channels expression. Here we review electrophysiological signature of arteriolar smooth muscle in various tissues, with an emphases and specific examples of the excitability of 4th order arterioles isolated from skeletal muscle.
- arteriolar smooth muscle
- voltage-gated Ca2+ and Na+ channels
Regulation of pressure and local blood flow occurs at the level of resistance arteries and arterioles. Once blood exits the heart, it first flows into large elastic arteries, followed by smaller distributing arteries, which branch further into small resistance arteries and, finally, arterioles. The branching and reduction in vessel diameter actually results in the increase in total cross-sectional area of circulation. Because of their small diameter, resistance arteries and arterioles are the place of the largest pressure drop.
2. Myogenic tone
Resistance arteries and arterioles typically exhibit a state of partial constriction termed myogenic tone . Myogenic tone is related to the level of the intraluminal pressure and provides a level of tone that vasodilators can act upon . When the intraluminal pressure increases, resistance arteries and arterioles first dilate due to their elastic properties and then constrict to the new steady-state level. Myogenic tone is an intrinsic property of arteriolar smooth muscle cells and does not require endothelium [3, 4]. Resistance to blood flow is actively controlled by contraction or relaxation of arteriolar smooth muscle cells wrapped around the vessel so that their tone regulates the vessel diameter . Arterial walls are made up of three layers: the tunica intima, tunica media and tunica adventitia. While the tunica intima contains endothelial cells and a thin layer of connective tissue, the tunica media supplies mechanical strength and contractile power. It is composed of several layers of spindle-shaped smooth muscle cells arranged helically in a matrix of elastin and collagen fibers. In some places, endothelial cells make contacts with smooth muscle cells to transmit signals between the intima and media. The tunica adventitia is mostly a connective tissue sheath with no distinct outer border. Its role is to tether the vessel loosely to the surrounding tissue . Arterioles, the smallest resistance arteries placed right before capillaries, have a single layer of spindle-shaped smooth muscle cells . Endothelial cells frame the lumen of arterioles. The shape and orientation within the vessels help to distinguish between these two distinct cells types (Figure 1).
Development of the tone is associated with depolarization of smooth muscle cells. While the mechanisms underlying depolarization are not completely understood, it is known that development of myogenic tone depends on extracellular Ca2+. At 0 Ca2+, pressurized resistance arteries and arterioles are fully dilated. Adding Ca2+ up to ≈ 2 mM to the extracellular space causes maximal tone . In addition to the development of basal tone, the myogenic mechanism is believed to underlie the response to acute changes in pressure and contribute to spontaneous vasomotor activity .
Myogenic tone is controlled by intrinsic as well as extrinsic mechanisms. Intrinsic mechanisms include constriction of arterioles in response to pressure increase (Bayliss effect), endothelial secretions (nitric oxide, EDHF, prostacyclin, endothelin), vasoactive metabolites (e.g. adenosine in exercising muscle), autacoids (local vasoactive paracrine secretions such as histamine), and temperature. Important physiological responses mediated entirely by intrinsic regulation include the autoregulation of flow, and functional and reactive hyperemia. Intrinsic regulation also contributes to pathological responses such as inflammation and arterial vasospasm. Extrinsic regulation is brought about by factors originating outside the organ, namely the vasomotor nerves (sympathetic, parasympathetic and others) and circulating hormones such as adrenaline, vasopressin and insulin (for review, see ).
3. Skeletal muscle vasculature
Skeletal muscle is the largest organ in the body that receives about 20% of cardiac output at rest and up to 80% during exercise. In skeletal muscle, the local blood flow is regulated over a 20× range to meet the demands of exercise. Therefore, vascular resistance of skeletal muscle is a critical determinant of total peripheral resistance and blood pressure. Arterioles of skeletal muscle have a high myogenic tone at rest as they are subject to major hyperemia (increased blood flow) during exercise . In case of orthostatic hypotension, a potential contributor to cardiovascular adaptation to prolonged periods of bed rest or microgravity, skeletal muscle arterioles may develop functional or structural adaptations. Despite the physiological importance of skeletal muscle arterioles, little is known about ionic mechanisms underlying their excitability. Even within the same skeletal muscle, arterioles might respond differently to pressure changes. For instance, the first-order arterioles isolated from fast-twitch (e.g., white gastrocnemius) skeletal muscle fiber demonstrated both functional and structural changes such as reduced myogenic tone, decreased contractile responsiveness, and reduced wall thickness with no change in luminal diameter [9, 10]. In contrast, arterioles isolated from slow-twitch (e.g., soleus) fibers show no difference in myogenic tone or contractile responsiveness but rather a structural remodeling resulting in a decreased arteriole diameter .
4. Excitability of vascular smooth muscle
After development of isolated vessel techniques, the electrophysiology of smooth muscle cells was extensively studied in small arteries isolated from various vascular beds .
4.1 Membrane potential of vascular smooth muscle
Both slow changes (myogenic tone) and fast spikes in the membrane potential have been observed in arteriolar smooth muscle cells. Arteriolar smooth muscle cells can generate rhythmical contractions (vasomotion) over an extended period of time. Vasomotion occurs spontaneously or in response to vasoactive stimulation with a frequency of 3–20 per minute. The exact physiological role of vasomotion is not clear. In cases of ischemia and hypertension, it serves as a protective mechanism. Vasomotion is not a consequence of heartbeat, respiration, or neuronal input. It is generated within arteriolar smooth muscle cells by an endogenous pacemaker mechanism driven by a cytosolic Ca2+ oscillator. The cytosolic Ca2+ oscillator depends on Ca2+ entry and is regulated by transmitters and hormones, which increase the formation of InsP3 and diacylglycerol (DAG) and promote oscillatory activity (for review, see ).
From the early studies, it has been appreciated that an increase in intraluminal pressure leads to depolarization and consequent contraction of vascular smooth muscle cell (electromechanical coupling). Mechanisms of depolarization are still not well understood. Depolarization increases Ca2+ concentration inside the cell, which leads to activation of myosin light chain kinase by Ca2+/calmodulin and consequent contraction. Propagation of depolarization is achieved through gap junctions between neighboring smooth muscle cells. The signaling between endothelial and smooth muscle cells via gap junctions is essential for normal vascular function. Gap junctions in arteriolar smooth muscle cells and endothelial cells are formed by connexins Cx37, Cx40, and Cx43. Coupling between arteriolar smooth muscle cells appears to be essential for the maintenance of oscillations in membrane potential, the intracellular [Ca2+], and vasomotion.
The exact signaling mechanisms that underlie detection of the mechanical stimulus and membrane depolarization are not completely understood (for review, see [7, 14]). Depolarization of vascular smooth muscle’s membrane activates various voltage-gated ion channels, pumps and exchangers, including voltage-gated Ca2+ and K+ channels, Ca2+-activated BKCa and ClCa channels, Na+/Ca2+ exchanger, Ca2+-ATP pump and N+/K+-ATPase, ATP-sensitive P2X receptor, and transient receptor potential (TRP) ion channels. Voltage-gated L-type Ca2+ channels are activated upon depolarization and increase Ca2+ concentration inside the cell. BKCa K+ channels hyperpolarize smooth muscle cell back to its resting potential [15, 16]. Some vascular myocytes, particularly in large vessels, contract via pathways that appear to be unrelated to significant changes in the membrane potential (pharmacomechanical coupling).
Membrane potential of arteriolar smooth muscle cells is difficult to measure because of the changes in the intraluminal pressure and active vasomotor responses. Resting membrane potentials range from approximately
4.2 Excitability of vascular smooth muscle
Most of the arteriolar smooth muscle cells are quiescent. In some cases, a drop in the intraluminal pressure (during trauma to a vessel) that leads to hyperpolarization and dilation generates membrane action potentials. Physiological role of membrane action potentials in arteriolar smooth muscle is unclear, as relatively small changes in the membrane potential (between −55 and − 35 mV) are sufficient to control Ca2+ entry and to initiate contraction in response to stimulation by mechanical stress of the blood flow . Spontaneous action potentials could be associated either with rhythmic vasomotor activity ; follow K+-induced hyperpolarization and dilation , or precede injury-induced constriction .
Only a few recordings of action potentials in skeletal muscle arterioles were made so far [6, 23, 25, 27]. Spontaneous action potential spikes could be observed in pressurized small arteries [23, 25], as well as in un-pressurized arterioles as shown in Figure 3 [6, 21].
4.3 Voltage-gated channels of arterial smooth muscle
Unlike in many other excitable tissues, action potentials in smooth muscle cells of arteries  and arterioles  are thought to be independent of voltage-gated Na+ channels, as they could not be blocked by the application of voltage-gated Na+ channel blocker tetrodotoxin (TTX). Depolarization of smooth muscle cells induced by the change in intraluminal pressure and/or tissue-stretch produces an increase in the intracellular [Ca2+], consequent myosin light chain phosphorylation and contraction (for review, see ). Since specific blockers of L-type voltage-gated Ca2+ channels suppress both the upstroke and the after-depolarizing components of action potentials, these channels are thought to be the main pathway for the depolarizing current. Nevertheless, several groups have demonstrated that voltage-gated Na+ channels are present in arterial beds and are activated upon membrane depolarization [6, 29].
4.3.1 Voltage-gated Ca2+ channels
Voltage-gated Ca2+ channels mediate influx of Ca2+ ions in response to membrane depolarization and regulate intracellular processes such as contraction, secretion, neurotransmission, and gene expression in many different cell types. Their activity is essential to couple electrical signals in the cell surface to physiological events in cells. Voltage-gated Ca2+ channels are comprised of the pore-forming α1 subunit in complex with auxiliary subunits. A transmembrane disulfide-linked α2δ, an intracellular β, and a γ subunit are components of most types of calcium channels. The α1 subunit contains four repeats of a domain with six transmembrane segments, the fourth of which is the voltage-sensing S4 segment. The pore loop between transmembrane segments S5 and S6 in each domain determines ion conductance and selectivity (for review, see ). Ten distinct genes encode mammalian α1 subunits of three subfamilies of voltage-gated Ca2+ channels. The amino acid sequences of these α1 subunits are more than 70% identical within a subfamily but less than 40% identical among subfamilies. Voltage-gated Ca2+ channels are named using the chemical symbol of the principal permeating ion with the principal physiological regulator (voltage) indicated as a subscript according to the nomenclature developed for voltage-gated K+ channels . The CaV1 subfamily (CaV1.1–CaV1.4) represents high-voltage activated L-type Ca2+ channels, the CaV2 subfamily (CaV2.1–CaV2.3) represents neuronal N-, P/Q-, and R-types Ca2+ channels, and CaV3 subfamily (CaV3.1–CaV3.3) represents low-voltage activated T-type Ca2+ channels.
The pharmacology and biophysics of Ca2+ channels subfamilies are quite distinct. L-type Ca2+ calcium channels typically require a strong depolarization for activation and do not inactivate at positive potentials. They are the main pathway for Ca2+ currents recorded in muscle cells, where they initiate contraction and secretion. The CaV1 subfamily is the molecular target of the organic Ca2+ channel blockers used widely in the therapy of cardiovascular diseases. L-type Ca2+ channels are blocked by the organic antagonists, including dihydropyridines (e.g., nifedipine), phenylalkylamines, and benzothiazepines. Dihydropyridines can be channel activators or inhibitors and therefore are thought to act allosterically to shift the channel toward the open or closed state rather than by occluding the pore. T-type Ca2+ channels are activated by weak depolarization and are transient at sustained depolarization. They are expressed in a wide variety of cell types, where they are involved in shaping the action potential and controlling patterns of repetitive firing. The CaV3 subfamily of voltage-gated Ca2+ channels is insensitive to both the dihydropyridines that block CaV1 channels and the spider and cone snail toxins that block the CaV2 channels. There are no widely useful pharmacological agents that block T-type Ca2+ currents specifically. Mibefradil blocks both T-type Ca2+ channels and with less potency L-type Ca2+ channels. Currents through expressed CaV3.2 channels could be selectively blocked by application of 40 μM of Ni2+ .
Currents through dihydropyridine-sensitive Ca2+ channels were recorded in arteries of various vascular beds [21, 33, 34, 35, 36], including from smooth muscle cells of skeletal muscle arterioles (Figure 4, left panel). CaV1.2 considered to be the principal sub-type of voltage-gated Ca2+ channels involved in excitation-contraction coupling of vascular smooth muscle cells . Since L-type Ca2+ blocker nifedipine did not eliminate basal tone in skeletal muscle arterioles, other Ca2+ entry mechanisms are believed to contribute to myogenic tone along with L-type Ca2+ channels . In addition to L-type, vascular smooth muscle cells also express T-type Ca2+ channels (for review, see [30, 39]). Currents through T-type Ca2+ channels have been found in smooth muscle cells of arteries and arterioles of cerebral , mesenteric , renal , coronary , and skeletal  vascular beds as shown in Figure 4 (right panel). Although the messenger RNAs for both, CaV3.1 and CaV3.2 T-type Ca2+ channels were found in rat cremaster arterioles , only L-type Ca2+ currents were recorded in single smooth muscle cells isolated from resistance arteries of hamster cremaster muscle . The pressure/stretch stimulus initiates a depolarization that causes Ca2+ influx through voltage-gated L-type Ca2+ channels and initiates Ca2+ sparklets [44, 45, 46]. Both, Ca2+ sparklets and Ca2+ sparks (Ca2+ release from intracellular stores) signaling events, activate negative feedback mechanisms via Ca2+-dependent K+ currents thus preventing unrestrained depolarization [47, 48, 49]. While Ca2+ influx through L-type Ca2+ channels are believed to be involved in contraction of vascular smooth muscle, T-type Ca2+ channels, particularly CaV3.2 appear to be mostly involved in relaxation of coronary arteries, acting through activation of BKCa channels [40, 41, 42, 43, 50, 51].
4.3.2 Voltage-gated Na+ channels
In addition to voltage-gated Ca2+ channels, significant TTX-sensitive Na+ currents were found in smooth muscle cells from rabbit main pulmonary artery , human aorta , murine mesenteric arteries , and skeletal muscle arterioles  as shown in Figure 5. The above observations suggest that more complex mechanisms are likely to generate action potential in vascular smooth muscle cells. When voltage-gated Ca2+ and Na+ channels coexist in the same cell, Na+ conductance is thought to be responsible for generation and propagation of action potential in excitable cells such as neurons, striated muscle, and neuroendocrine cells. It has lower threshold and faster rise time than Ca2+ conductance. After Na+ channels rapidly inactivate, L-type voltage-gated Ca2+ channels open and further depolarize the cell, thus prolonging the plateau of an action potential. In contrast, T-type voltage-gated Ca2+ channels may open at resting potential and produce depolarizing current that brings the cell to threshold for Na+ spike [54, 55].
Voltage-gated Na+ channels consist of the subunit associated with auxiliary subunits. The pore-forming subunit is sufficient for functional expression, but the kinetics and voltage dependence of channel gating are modified by the subunits. These auxiliary subunits are involved in channel localization and interaction with cell adhesion molecules, extracellular matrix, and intracellular cytoskeleton. Similar to the voltage-gated Ca2+ channels, the subunits of Na+ channels are organized in four homologous domains, each composed of six transmembrane segments. S4 segment is a voltage sensor, and a pore loop located between the S5 and S6 segments determines ion conductance and selectivity (for review, see ). According to the nomenclature, the NaV1 superfamily (NaV1.1–NaV1.9) represents voltage-gated Na+ channels. Unlike the different classes of voltage-gated Ca2+ channels, the functional properties of Na+ channels are relatively similar. Amino acid sequences of the nine mammalian Na+ channel isoforms are more than 50% identical to each other, but separate families are difficult to define. By this criterion, nine isoforms are considered to be members of one NaV1 gene subfamily. Some voltage-gated Na+ channels (NaV1.1, NaV1.2, NaV1.3, NaV1.4, NaV1.6, and NaV1.7) could be blocked by tetrodotoxin that binds to the extracellular side of the pore.
Several isoforms of TTX-sensitive voltage-gated channels have been found previously smooth muscle cells of in vasa recta (NaV1.3), portal vein (NaV1.6 and NaV1.8), and vas deference (NaV1.6) [57, 58, 59]. The activity of these voltage-gated Na+ channels may be tightly controlled by elevations of intracellular Ca2+, potentially suppressing activity of Na+ channels . For instance, Ca2+/CaM binding was shown to down-regulates skeletal muscle isoform NaV1.4 by shifting its steady-state inactivation curve in the hyperpolarizing direction . NaV1.3 channels in descending vasa recta are suppressed by calmodulin inhibitors, while elevation of the intracellular [Ca2+] shifts the voltage-dependence of their activation to more positive voltages . In addition, Ca2+-dependent down-regulation of Na+ channels can also occur via the PKC pathway since activation of PKC decreases peak sodium currents through brain NaV1.2 and skeletal muscle NaV1.4 channels by up to 80% [61, 62].
L-type voltage-gated Ca2+ channels are involved in excitation-contraction coupling of vascular smooth muscle cells. In addition, T-type Ca2+ channels were detected in arteriolar smooth muscle cells. These two types of voltage-gated Ca2+ channels together play an important role in the constriction/relaxation of smooth muscle cells by regulating Ca2+ signaling during myogenic tone. However, there are indications that other type of voltage-gated channels, specifically Na+ channels are present in various vascular beds. While the role of voltage-gated Ca2+ channels is well established, contribution of voltage-gated Na+ channel remains to be determined.
I would like to thank Dr. Roman E. Shirokov for invaluable discussion related to this work.
Conflict of interest
The author declares no conflict of interest.
Bayliss N. On the local reactions of the arterial wall to changes of internal pressure. The Journal of Physiology. 1902; 28:220-231
Mellander S, Johansson B. Control of resistance, exchange, and capacitance functions in the peropheral circulation. Pharmacological Reviews. 1968; 20(3):117-196
Kuo L, Chilian WM, Davis MJ. Coronary arteriolar myogenic response is independent of endothelium. Circulation Research. 1990; 66(3):860-866
Falcone JC, Davis MJ, Meininger GA. Endothelial independence of myogenic response in isolated skeletal muscle arterioles. American Journal of Physiology. Heart and Circulatory Physiology. 1991; 260(1):H130-H135
Greensmith JE, Duling BR. Morphology of the constricted arteriolar wall: Physiological implications. American Journal of Physiology. Heart and Circulatory Physiology. 1984; 247(5):H687-HH98
Ulyanova AV, Shirokov RE. Voltage-dependent inward currents in smooth muscle cells of skeletal muscle arterioles. PLoS One. 2018; 13(4):e0194980
Davis MJ, Hill MA. Signaling mechanisms underlying the vascular myogenic response. Physiological Reviews. 1999; 79(2):387-423
Herring N, Paterson DJ. Levick’s Introduction to Cardiovascular Physiology. 6th Ed. Boca Raton, FL: CRC Press; 2018
Delp MD, Colleran PN, Wilkerson MK, McCurdy MR, Muller-Delp J. Structural and functional remodeling of skeletal muscle microvasculature is induced by simulated microgravity. American Journal of Physiology. Heart and Circulatory Physiology. 2000; 278(6):H1866-H1873
Delp MD. Myogenic and vasoconstrictor responsiveness of skeletal muscle arterioles is diminished by hindlimb unloading. Journal of Applied Physiology. 1999; 86(4):1178-1184
Heaps CL, Bowles DK. Nonuniform changes in arteriolar myogenic tone within skeletal muscle following hindlimb unweighting. Journal of Applied Physiology. 2002; 92(3):1145-1151
Duling BR, Gore RW, Dacey RG Jr, Damon DN. Methods for isolation, cannulation, and in vitro study of single microvessels. American Journal of Physiology. Heart and Circulatory Physiology. 1981; 241(1):H108-H116
Berridge MJ. Smooth muscle cell calcium activation mechanisms. The Journal of Physiology. 2008; 586(21):5047-5061
Hill MA, Davis MJ, Meininger GA, Potocnik SJ, Murphy TV. Arteriolar myogenic signalling mechanisms: Implications for local vascular function. Clinical Hemorheology and Microcirculation. 2006; 34(1):67-79
Brayden J, Nelson M. Regulation of arterial tone by activation of calcium-dependent potassium channels. Science. 1992; 256(5056):532-535
Jaggar JH, Porter VA, Lederer WJ, Nelson MT. Calcium sparks in smooth muscle. American Journal of Physiology. Cell Physiology. 2000; 278(2):C235-C256
Hirst GD, Edwards FR. Sympathetic neuroeffector transmission in arteries and arterioles. Physiological Reviews. 1989; 69(2):546-604
Nelson MT, Patlak JB, Worley JF, Standen NB. Calcium channels, potassium channels, and voltage dependence of arterial smooth muscle tone. American Journal of Physiology. Cell Physiology. 1990; 259(1):C3-C18
Kuriyama H, Suzuki H. Adrenergic transmissions in the guinea-pig mesenteric artery and their cholinergic modulations. The Journal of Physiology. 1981; 317:383-396
Hirst GD, van Helden DF. Ionic basis of the resting potential of submucosal arterioles in the ileum of the guinea-pig. The Journal of Physiology. 1982; 333:53-67
Hirst GD, Silverberg GD, van Helden DF. The action potential and underlying ionic currents in proximal rat middle cerebral arterioles. The Journal of Physiology. 1986; 371:289-304
Knot HJ, Nelson MT. Regulation of arterial diameter and wall [Ca2+] in cerebral arteries of rat by membrane potential and intravascular pressure. The Journal of Physiology. 1998; 508(Pt 1):199-209
Kotecha N, Hill MA. Myogenic contraction in rat skeletal muscle arterioles: Smooth muscle membrane potential and Ca2+ signaling. American Journal of Physiology. Heart and Circulatory Physiology. 2005; 289(4):H1326
Gerstheimer FP, Mühleisen M, Nehring D, Kreye VA. A chloride-bicarbonate exchanging anion carrier in vascular smooth muscle of the rabbit. Pflügers Archiv. 1987; 409(1-2):60-66
Burns WR, Cohen KD, Jackson WF. K+-induced dilation of hamster cremasteric arterioles involves both the Na+/K+-ATPase and inward-rectifier K+ channels. Microcirculation. 2004; 11(3):279-293
Graham JM, Keatinge WR. Responses of inner and outer muscle of the sheep carotid artery to injury. The Journal of Physiology. 1975; 247(2):473-482
Bartlett IS, Crane GJ, Neild TO, Segal SS. Electrophysiological basis of arteriolar vasomotion in vivo. Journal of Vascular Research. 2000; 37(6):568-575
Keatinge WR. Sodium flux and electrical activity of arterial smooth muscle. The Journal of Physiology. 1968; 194(1):183-200
Berra-Romani R, Blaustein MP, Matteson DR. TTX-sensitive voltage-gated Na+ channels are expressed in mesenteric artery smooth muscle cells. American Journal of Physiology. Heart and Circulatory Physiology. 2005; 289(1):H137-H145
Catterall WA, Perez-Reyes E, Snutch TP, Striessnig J. International union of pharmacology. XLVIII. Nomenclature and structure-function relationships of voltage-gated calcium channels. Pharmacological Reviews. 2005; 57(4):411-425
Chandy KG, Gutman GA. Nomenclature for mammalian potassium channel genes. Trends in Pharmacological Sciences. 1993; 14(12):434
Lee J-H, Gomora JC, Cribbs LL, Perez-Reyes E. Nickel block of three cloned T-type calcium channels: Low concentrations selectively block alpha1H. Biophysical Journal. 1999; 77(6):3034-3042
Aaroson PI, Bolton TB, Lang RJ, MacKenzie I. Calcium currents in single isolated smooth muscle cells from the rabbit ear artery in normal-calcium and high-barium solutions. The Journal of Physiology. 1988; 405(1):57-75
Bean B, Sturek M, Puga A, Hermsmeyer K. Calcium channels in muscle cells isolated from rat mesenteric arteries: Modulation by dihydropyridine drugs. Circulation Research. 1986; 59(2):229-235
Ganitkevich VY, Isenberg G. Contribution of two types of calcium channels to membrane conductance of single myocytes from guinea-pig coronary artery. The Journal of Physiology. 1990; 426(1):19-42
Smirnov SV, Aaronson PI. Ca2+ currents in single myocytes from human mesenteric arteries: Evidence for a physiological role of L-type channels. The Journal of Physiology. 1992; 457(1):455-475
Koch W, Ellinor P, Schwartz A. cDNA cloning of a dihydropyridine-sensitive calcium channel from rat aorta. Evidence for the existence of alternatively spliced forms. The Journal of Biological Chemistry. 1990; 265(29):17786-17791
Hill MA, Meininger GA. Calcium entry and myogenic phenomena in skeletal muscle arterioles. American Journal of Physiology. Heart and Circulatory Physiology. 1994; 267(3):H1085-H1H92
Perez-Reyes E. Molecular physiology of low voltage-activated T-type calcium channels. Physiological Reviews. 2003; 83(1):117-161
Morita H, Cousins H, Onoue H, Ito Y, Inoue R. Predominant distribution of nifedipine-insensitive, high voltage-activated Ca2+ channels in the terminal mesenteric artery of guinea pig. Circulation Research. 1999; 85(7):596-605
Gordienko DV, Clausen C, Goligorsky MS. Ionic currents and endothelin signaling in smooth muscle cells from rat renal resistance arteries. American Journal of Physiology. Renal Physiology. 1994; 266(2):F325-F341
VanBavel E, Sorop O, Andreasen D, Pfaffendorf M, Jensen BL. Role of T-type calcium channels in myogenic tone of skeletal muscle resistance arteries. American Journal of Physiology. Heart and Circulatory Physiology. 2002; 283(6):H2239-H2H43
Cohen KD, Jackson WF. Hypoxia inhibits contraction but not calcium channel currents or changes in intracellular calcium in arteriolar muscle cells. Microcirculation. 2003; 10(2):133-141
Amberg GC, Navedo MF, Nieves-Cintron M, Molkentin JD, Santana LF. Calcium sparklets regulate local and global calcium in murine arterial smooth muscle. Journal of Physiology (London). 2007; 579(1):187-201
Navedo MF, Amberg GC, Nieves M, Molkentin JD, Santana LF. Mechanisms underlying heterogeneous Ca2+ sparklet activity in arterial smooth muscle. The Journal of General Physiology. 2006; 127(6):611-622
Navedo MF, Amberg GC, Votaw VS, Santana LF. Constitutively active L-type Ca2+ channels. PNAS. 2005; 102(31):11112-11117
Jaggar JH, Wellman GC, Heppner TJ, Porter VA, Perez GJ, Gollasch M, et al. Ca2+ channels, ryanodine receptors and Ca2+-activated K+ channels: A functional unit for regulating arterial tone. Acta Physiologica Scandinavica. 2008; 164(4):577-587
Ledoux J, Werner ME, Brayden JE, Nelson MT. Calcium-activated potassium channels and the regulation of vascular tone. Physiology. 2006; 21(1):69-78
Nelson MT, Cheng H, Rubart M, Santana LF, Bonev AD, Knot HJ, et al. Relaxation of arterial smooth muscle by calcium sparks. Science. 1995; 270(5236):633
Chen CC, Lamping KG, Nuno DW, Barresi R, Prouty SJ, Lavoie JL, et al. Abnormal coronary function in mice deficient in alpha1H T-type Ca2+ channels. Science. 2003; 302(5649):1416-1418
Morita H, Shi J, Ito Y, Inoue R. T-channel-like pharmacological properties of high voltage-activated, nifedipine-insensitive Ca2+ currents in the rat terminal mesenteric artery. British Journal of Pharmacology. 2002; 137(4):467-476
Okabe K, Kitamura K, Kuriyama H. The existence of a highly tetrodotoxin sensitive Na channel in freshly dispersed smooth muscle cells of the rabbit main pulmonary artery. Pflügers Archiv—European Journal of Physiology. 1988; 411(4):423-428
Cox RH, Zhou Z, Tulenko TN. Voltage-gated sodium channels in human aortic smooth muscle cells. Journal of Vascular Research. 1998; 35(5):310-317
Llinás R, Yarom Y. Electrophysiology of mammalian inferior olivary neurones in vitro. Different types of voltage-dependent ionic conductances. The Journal of Physiology. 1981; 315:549-567
Llinás R, Yarom Y. Properties and distribution of ionic conductances generating electroresponsiveness of mammalian inferior olivary neurones in vitro. The Journal of Physiology. 1981; 315:569-584
Catterall WA, Goldin AL, Waxman SG. International union of pharmacology. XLVII. Nomenclature and structure-function relationships of voltage-gated sodium channels. Pharmacological Reviews. 2005; 57(4):397
Lee-Kwon W, Goo JH, Zhang Z, Silldorff EP, Pallone TL. Vasa recta voltage-gated Na+ channel NaV1.3 is regulated by calmodulin. American Journal of Physiology. Renal Physiology. 2007; 292(1):F404-F414
Saleh S, Yeung SYM, Prestwich S, Pucovsky V, Greenwood I. Electrophysiological and molecular identification of voltage-gated sodium channels in murine vascular myocytes. The Journal of Physiology. 2005; 568(1):155-169
Zhu H-L, Shibata A, Inai T, Nomura M, Shibata Y, Brock JA, et al. Characterization of NaV1.6-mediated Na+ currents in smooth muscle cells isolated from mouse vas deferens. Journal of Cellular Physiology. 2010; 223(1):234-243
Biswas S, Deschenes I, DiSilvestre D, Tian Y, Halperin VL, Tomaselli GF. Calmodulin regulation of NaV1.4 current: Role of binding to the carboxyl terminus. The Journal of General Physiology. 2008; 131(3):197-209
Numann R, Catterall WA, Scheuer T. Functional modulation of brain sodium channels by protein kinase C phosphorylation. Science. 1991; 254(5028):115-118
Numann R, Hauschka S, Catterall W, Scheuer T. Modulation of skeletal muscle sodium channels in a satellite cell line by protein kinase C. The Journal of Neuroscience. 1994; 14(7):4226-4236