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Rapamycin Attenuates Cardiac Fibrosis In Experimental Uremic Cardiomyopathy By Reducing Marinobufagenin Levels And Inhibiting Downstream Pro-Fibrotic Signaling, Steven T. Haller Phd, Yanling Yan Phd, Christopher A. Drummond Phd, Joe Xie Md, Jiang Tian Phd, David J. Kennedy Phd, Victoria Y. Shilova Phd, Zijian Xie Phd, Jiang Liu Phd, Christopher J. Cooper Md, Deepak Malhotra Md, Phd, Joseph I. Shapiro Md, Olga V. Fedorova Phd, Alexei Y. Bagrov Md, Phd
Rapamycin Attenuates Cardiac Fibrosis In Experimental Uremic Cardiomyopathy By Reducing Marinobufagenin Levels And Inhibiting Downstream Pro-Fibrotic Signaling, Steven T. Haller Phd, Yanling Yan Phd, Christopher A. Drummond Phd, Joe Xie Md, Jiang Tian Phd, David J. Kennedy Phd, Victoria Y. Shilova Phd, Zijian Xie Phd, Jiang Liu Phd, Christopher J. Cooper Md, Deepak Malhotra Md, Phd, Joseph I. Shapiro Md, Olga V. Fedorova Phd, Alexei Y. Bagrov Md, Phd
Jiang Liu
Background: Experimental uremic cardiomyopathy causes cardiac fibrosis and is causally related to the increased circulating levels of the cardiotonic steroid, marinobufagenin (MBG), which signals through Na/K‐ATPase. Rapamycin is an inhibitor of the serine/threonine kinase mammalian target of rapamycin (mTOR) implicated in the progression of many different forms of renal disease. Given that Na/K‐ATPase signaling is known to stimulate the mTOR system, we speculated that the ameliorative effects of rapamycin might influence this pathway.
Methods and Results: Biosynthesis of MBG by cultured human JEG‐3 cells is initiated by CYP27A1, which is also a target for rapamycin. It was demonstrated that 1 …
Attenuation Of Na/K-Atpase Mediated Oxidant Amplification With Pnaktide Ameliorates Experimental Uremic Cardiomyopathy, Jiang Liu, Jiang Tian, Muhammad Chaudhry, Kyle Maxwell, Yanling Yan, Xiaoliang Wang, Preeya T. Shah, Asad A. Khawaja, Rebecca Martin, Tylor J. Robinette, Adee El-Hamdani, Michael W. Dodrill, Komal Sodhi, Christopher A. Drummond, Steven T. Haller, David J. Keenedy, Nader G. Abraham, Zijian Xie, Joseph I. Shapiro Md
Attenuation Of Na/K-Atpase Mediated Oxidant Amplification With Pnaktide Ameliorates Experimental Uremic Cardiomyopathy, Jiang Liu, Jiang Tian, Muhammad Chaudhry, Kyle Maxwell, Yanling Yan, Xiaoliang Wang, Preeya T. Shah, Asad A. Khawaja, Rebecca Martin, Tylor J. Robinette, Adee El-Hamdani, Michael W. Dodrill, Komal Sodhi, Christopher A. Drummond, Steven T. Haller, David J. Keenedy, Nader G. Abraham, Zijian Xie, Joseph I. Shapiro Md
Jiang Liu
We have previously reported that the sodium potassium adenosine triphosphatase (Na/K-ATPase) can effect the amplification of reactive oxygen species. In this study, we examined whether attenuation of oxidant stress by antagonism of Na/K-ATPase oxidant amplification might ameliorate experimental uremic cardiomyopathy induced by partial nephrectomy (PNx). PNx induced the development of cardiac morphological and biochemical changes consistent with human uremic cardiomyopathy. Both inhibition of Na/K-ATPase oxidant amplification with pNaKtide and induction of heme oxygenase-1 (HO-1) with cobalt protoporphyrin (CoPP) markedly attenuated the development of phenotypical features of uremic cardiomyopathy. In a reversal study, administration of pNaKtide after the induction of uremic …
Protein Carbonylation Of An Amino Acid Residue Of The Na/K‐Atpase Α1 Subunit Determines Na/K‐Atpase Signaling And Sodium Transport In Renal Proximal Tubular Cells, Yanling Yan, Anna P. Shapiro, Brahma R. Mopidevi, Muhammad Chaudhry, Kyle Maxwell, Steven T. Haller, Christopher A. Drummond, David J. Keendey, Jiang Tian, Deepak Malhorta, Zijian Xie, Joseph I. Shapiro Md, Jiang Liu
Protein Carbonylation Of An Amino Acid Residue Of The Na/K‐Atpase Α1 Subunit Determines Na/K‐Atpase Signaling And Sodium Transport In Renal Proximal Tubular Cells, Yanling Yan, Anna P. Shapiro, Brahma R. Mopidevi, Muhammad Chaudhry, Kyle Maxwell, Steven T. Haller, Christopher A. Drummond, David J. Keendey, Jiang Tian, Deepak Malhorta, Zijian Xie, Joseph I. Shapiro Md, Jiang Liu
Jiang Liu
Background We have demonstrated that cardiotonic steroids, such as ouabain, signaling through the Na/K‐ATPase, regulate sodium reabsorption in the renal proximal tubule. By direct carbonylation modification of the Pro222 residue in the actuator (A) domain of pig Na/K‐ATPase α1 subunit, reactive oxygen species are required for ouabain‐stimulated Na/K‐ATPase/c‐Src signaling and subsequent regulation of active transepithelial 22Na+ transport. In the present study we sought to determine the functional role of Pro222 carbonylation in Na/K‐ATPase signaling and sodium handling.
Methods and Results Stable pig α1 knockdown LLC‐PK1‐originated PY‐17 cells were rescued by expressing wild‐type rat α1 and rat α1 with …
Carbonylationmodificationregulatesna/K-Atpasesignalingandsaltsensitivity:Areviewandahypothesis, Preeya Shah Phd, Rebecca Martin, Yanling Yan, Joseph I. Shapiro Md, Jiang Liu
Carbonylationmodificationregulatesna/K-Atpasesignalingandsaltsensitivity:Areviewandahypothesis, Preeya Shah Phd, Rebecca Martin, Yanling Yan, Joseph I. Shapiro Md, Jiang Liu
Jiang Liu
Na/K-ATPase signaling has been implicated in different physiological and pathophysiological conditions. Accumulating evidence indicates that oxidative stress not only regulates the Na/K-ATPase enzymatic activity, but also regulates its signaling and other functions. While cardiotonic steroids (CTS)-induced increase in reactive oxygen species (ROS) generation is an intermediate step in CTS-mediated Na/K-ATPase signaling, increase in ROS alone also stimulates Na/K-ATPase signaling. Based on literature and our observations, we hypothesize that ROS have biphasic effects on Na/K-ATPase signaling, transcellular sodium transport, and urinary sodium excretion. Oxidative modulation, in particular site specific carbonylation of the Na/K-ATPase α1 subunit, is a critical step in proximal …