Mechanisms underlying angiotensin II-induced calcium oscillations

Edwards, Aurélie; Pallone, Thomas L.

doi:10.1152/ajprenal.00107.2008

Cited by 13 publications

(20 citation statements)

References 59 publications

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“…Not shown are KCa, Kir, KATP, and Kv channels. (13) As shown by Lee et al (34), there is a good correlation between this fraction and the contractile force in arterial smooth muscle. Interpolation of the data shown in their Fig.…”

Section: Mlck-dependent Phosphorylation Of Myosinmentioning

confidence: 76%

“…The other equations of the model, those that yield the K ϩ , Na ϩ , Cl Ϫ , and Ca 2ϩ currents, as well as transmembrane electrical potential differences, were described in detail in our previous work and are summarized in the appendix of reference (13).…”

Section: Model Descriptionmentioning

confidence: 99%

“…The affinity of SERCA for Ca 2ϩ in the absence of cGMP (K mf * ) is taken as 0.59 M so that the affinity (Kmf) equals 0.31 M under resting conditions (21). The parameters Kmr and H are respectively taken as 1.7 mM and 2 (13).…”

Section: Effects Of Cgmp On Ca 2ϩ Signaling and Vasocontractilitymentioning

confidence: 99%

“…The value of K PMCA M, cGMP is taken as 1 M, and the maximum current in the absence of cGMP (I PMCA, max * ) is taken as 2.9 pA so that the maximum current (IPMCA, max) equals 12 pA under resting conditions (13).…”

Section: Effects Of Cgmp On Ca 2ϩ Signaling and Vasocontractilitymentioning

confidence: 99%

“…1, the model accounts for plasma membrane (PM) and sarcoplasmic reticulum (SR) pumps, exchangers and ion channels, cytosolic and store Ca 2ϩ buffering, and the existence of subplasmalemmal microdomain spaces in which Na ϩ /Ca 2ϩ exchangers and the ␣ 2 isoform of the Na ϩ -K ϩ -ATPase are exclusively expressed (30,39). We recently examined two configurations for ryanodine receptors (RyR) and IP 3 receptors (IP 3 R), and concluded that oscillatory behavior is most consistently reproduced if they reside on separate SR stores in DVR pericytes (13), hence our assumption of separate RyR and IP 3 R store compartments here.…”

mentioning

confidence: 99%

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Cellular mechanisms underlying nitric oxide-induced vasodilation of descending vasa recta

Edwards

Cao

Pallone

2011

American Journal of Physiology-Renal Physiology

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signaling and MLC phosphorylation. At concentrations above 1 nM, O 2 Ϫ is predicted to modulate [Cacyt] and MCLP activity mostly by reducing NO bioavailability. The DVR vasoconstriction that is induced by high concentrations of H 2O2 can be explained by H2O2-mediated downregulation of MLCP and SERCA activity. We conclude that intrinsic generation of NO by the DVR wall may be sufficient to inhibit vasoconstriction by maintaining suppression of MLC phosphorylation. calcium signaling; hydrogen peroxide; superoxide; vascular smooth muscle NITRIC OXIDE (NO) acts as a local vasodilator in the renal medulla and plays an important role in the maintenance of medullary perfusion, medullary oxygenation, and blood pressure. Chronic inhibition of nitric oxide synthase (NOS) reduces medullary blood flow (MBF) and is associated with sodium retention and the development of hypertension (8, 41). Whereas NO increases MBF by promoting the vasodilation of descending vasa recta (DVR) or juxtamedullary arterioles, superoxide (O 2 Ϫ ) and hydrogen peroxide (H 2 O 2 ) act to reduce MBF by mechanisms that remain to be fully elucidated (17,37). In addition, NO inhibits, whereas O 2 Ϫ enhances, thick ascending limb sodium reabsorption (23). Hence, interactions between NO and O 2 Ϫ likely contribute to the long-term control of blood pressure; when the balance between these two radicals is shifted in favor of O 2 Ϫ (such as in diabetes and atherosclerosis, conditions that promote oxidative stress), renal vasoconstriction and tubular reabsorption increase, favoring hypertension (17).In a recent microperfusion study of DVR (4), we showed that intrinsic production of NO and reactive oxygen species (ROS) affects DVR vasoactivity. To elucidate the cellular pathways by which NO, O 2 Ϫ , and H 2 O 2 modulate DVR contraction, in the present study we expanded our mathematical model of Ca 2ϩ signaling in DVR pericytes to account for the effects of NO and ROS and to predict the degree of vessel contraction.Smooth muscle contraction is initiated by an increase in cytosolic Ca 2ϩ concentration ([Ca] cyt ). Increased binding of Ca 2ϩ to calmodulin (CaM) activates myosin light chain kinase (MLCK), which then phosphorylates myosin light chains (MLC) in the presence of ATP, thereby increasing the cycling rate of actin-myosin cross-bridge formation and generating the active force needed for muscle contraction. Most of the vasodilatory effects of NO on smooth muscle cells appear to be mediated by cGMP. Activity of the NO/cGMP pathway favors reduction in the fraction of phosphorylated myosin, via two different mechanisms: 1) an increase in the activity of myosin light chain phosphatase (MLCP), and 2) modulation of Ca 2ϩ transport that lowers [Ca] cyt , decreases Ca 2ϩ binding to CaM, and thereby reduces MLCK activity.We incorporated these and other signaling pathways in our mathematical model of DVR pericytes as described in MODEL DESCRIPTION. The data on which this and prior versions of the model are based have been largely derived from studies of DVR peric...

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Section: Mlck-dependent Phosphorylation Of Myosinmentioning

confidence: 76%

Section: Model Descriptionmentioning

confidence: 99%

Section: Effects Of Cgmp On Ca 2ϩ Signaling and Vasocontractilitymentioning

confidence: 99%

Section: Effects Of Cgmp On Ca 2ϩ Signaling and Vasocontractilitymentioning

confidence: 99%

mentioning

confidence: 99%

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Cellular mechanisms underlying nitric oxide-induced vasodilation of descending vasa recta

Edwards

Cao

Pallone

2011

American Journal of Physiology-Renal Physiology

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Renal Medullary Circulation

Pallone

Edwards

Mattson

2012

Comprehensive Physiology

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The renal medullary microcirculation is a distinctive arrangement of blood vessels that serve multiple functions in the renal medulla. This article begins with a description of the unique anatomy of this vascular bed and the role it plays in transport and countercurrent exchange in the medulla. A segment of the review is then devoted to the important role mathematical modeling has played in the understanding of this vascular bed's function. Succeeding sections focus upon the hematocrit in the vasa recta capillaries and methods utilized to assess blood flow in the renal medulla. An extensive portion of the article is then devoted to the regulation of the medullary circulation, from ion channel architecture to neurohormonal signaling. Finally, we discuss the importance of the renal medullary circulation in the regulation of fluid and electrolyte homeostasis and arterial blood pressure regulation.

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Cardiac Hegemony of Senescence

Siddiqi

Sussman

2013

Curr Transl Geriatr and Exp Gerontol Rep

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Cardiac senescence and age-related disease development have gained general attention and recognition in the past decades due to increased accessibility and quality of health care. The advancement in global civilization is complementary to concerns regarding population aging and development of chronic degenerative diseases. Cardiac degeneration has been rigorously studied. The molecular mechanisms of cardiac senescence are on multiple cellular levels and hold a multilayer complexity level, thereby hampering development of unambiguous treatment protocols. In particular, the synergistic exchange of the senescence phenotype through a senescence secretome between myocytes and stem cells appears complicated and is of great future therapeutic value. The current review article will highlight hallmarks of senescence, cardiac myocyte and stem cell senescence, and the mutual exchange of senescent secretome. Future cardiac cell therapy approaches require a comprehensive understanding of myocardial senescence to improve therapeutic efficiency as well as efficacy.

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Mechanisms underlying angiotensin II-induced calcium oscillations

Cited by 13 publications

References 59 publications

Cellular mechanisms underlying nitric oxide-induced vasodilation of descending vasa recta

Cellular mechanisms underlying nitric oxide-induced vasodilation of descending vasa recta

Renal Medullary Circulation

Cardiac Hegemony of Senescence

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