Sleep deprivation, shift work, and jet lag all disrupt normal biological rhythms and have major impacts on health; however, circadian disorganization has never been shown as a causal risk factor in organ disease. We now demonstrate devastating effects of rhythm disorganization on cardiovascular and renal integrity and that interventions based on circadian principles prevent disease pathology caused by a short-period mutation (tau) of the circadian system in hamsters. The point mutation in the circadian regulatory gene, casein kinase-1epsilon, produces early onset circadian entrainment with fragmented patterns of behavior in +/tau heterozygotes. Animals die at a younger age with cardiomyopathy, extensive fibrosis, and severely impaired contractility; they also have severe renal disease with proteinuria, tubular dilation, and cellular apoptosis. On light cycles appropriate for their genotype (22 h), cyclic behavioral patterns are normalized, cardiorenal phenotype is reversed, and hearts and kidneys show normal structure and function. Moreover, hypertrophy does not develop in animals whose suprachiasmatic nucleus was ablated as young adults. Circadian organization therefore is critical for normal health and longevity, whereas chronic global asynchrony is implicated in the etiology of cardiac and renal disease.
Abstract-In vascular smooth muscle cells (SMCs), several mechanisms act in concert to regulate the intracellular calcium concentration [Ca 2ϩ ] i , which may in turn affect vascular tone. One such mechanism is the extrusion of Ca 2ϩ by the plasma membrane calcium ATPase (PMCA). To address, in particular, the role of the neuronal nitric oxide synthase (nNOS)-associating isoform PMCA4b in regulating vascular tone, a doxycycline-responsive transgene for human PMCA4b was overexpressed in arterial SMCs of mice. Overexpression of hPMCA4b resulted in a 2-fold increase in total aortic PMCA4 protein expression and significant real-time RT-PCR-documented differences in the levels of endogenous mouse PMCA1, PMCA4, SERCA2, and IP3R1 gene expression in arterial SMCs. Whereas no significant difference in basal [Ca 2ϩ ] i or Ca 2ϩ sensitivity was observed in vascular SMCs or mesenteric arteries, respectively, from hPMCA4b-overexpressing versus control mice, hPMCA4b-overexpressing mice revealed a reduced set-point and increased extent of myogenic response and heightened sensitivity to vasoconstrictors. Treatment of arteries with an nNOS inhibitor resulted in a reduced set-point and increased extent of the myogenic response in control but not hPMCA4b-overexpressing mice. Moreover, aortic SMCs from hPMCA4b-overexpressing mice exhibited reduced levels of cGMP under both basal and phenylephrine-stimulated conditions. These changes were associated with significant doxycycline-reversible elevations in blood pressure. Taken together, these data show that overexpression of hPMCA4b in arterial SMCs increases vascular reactivity and blood pressure, an effect that may be mediated in part by negative regulation of nNOS. Key Words: transgenic mice Ⅲ blood pressure Ⅲ nitric oxide synthase Ⅲ intracellular calcium Ⅲ myogenic tone H ypertension is a polygenic disease responsive to environmental factors. Although more than 50 genes have been implicated in the regulation of blood pressure, 1 the complexity of hypertension has been additionally revealed by studies suggesting that insertion or deletion of single genes can lead to either reduced or elevated blood pressure. 2 One hallmark of hypertension is increased peripheral resistance attributable to both structural and functional changes in resistance arteries. 3 On a functional level, peripheral resistance is a balance between vasodilator and vasoconstrictor mechanisms of vascular smooth muscle cells (SMCs), in turn dependent on the intracellular calcium concentration ([Ca 2ϩ ] i ) and the Ca 2ϩ sensitivity of the contractile apparatus. Homeostasis of Ca 2ϩ involves several distinct mechanisms, including the extrusion of Ca 2ϩ by plasma membrane calcium ATPase (PMCA). These high-affinity calmodulin-responsive Ca 2ϩ efflux pumps are P-type transport proteins encoded for by a family of 4 genes (PMCA1 through PMCA4). Both PMCA1 and PMCA4 are ubiquitously expressed, whereas PMCA2 and PMCA3 show cell-specific patterns of expression. 4 From these 4 genes, more than 20 distinct isoforms of PMCA ...
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