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Query: UMLS:C0020538 (
hypertension
)
170,190
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Intracellular Mg2+ depletion has been implicated in vascular dysfunction in
hypertension
. We demonstrated that transient receptor potential melastatin 7 (TRPM7) cation channels mediate Mg2+ influx in VSMCs. Whether this plays a role in [Mg2+]i deficiency in
hypertension
is unclear. Here, we tested the hypothesis that downregulation of TRPM7 and its homologue
TRPM6
is associated with reduced [Mg2+]i and that ANG II negatively regulates
TRPM6
/7 in vascular smooth muscle cells (VSMCs) from spontaneously hypertensive rats (SHR). Cultured VSMCs from Wistar Kyoto (WKY) and SHR were studied. mRNA and protein expression of
TRPM6
and TRPM7 were assessed by RT-PCR and immunoblotting, respectively. Translocation of annexin-1, specific TRPM7 substrate, was measured as an index of TRPM7 activation. [Mg2+]i was determined using mag fura-2. VSMCs from WKY and SHR express
TRPM6
and TRPM7. Basal
TRPM6
expression was similar in WKY and SHR, but basal TRPM7 content was lower in VSMCs from SHR vs. WKY. This was associated with significantly reduced [Mg2+]i in SHR cells (P < 0.01). ANG II time-dependently increased
TRPM6
expression, with similar responses in WKY and SHR. ANG II significantly increased TRPM7 expression in WKY (P < 0.05), but not in SHR. Annexin-1 translocation was reduced 1.5-2-fold in SHR vs. WKY. Our findings demonstrate that
TRPM6
and TRPM7 are differentially regulated in VSMCs from SHR and WKY. Whereas
TRPM6
is unaltered in SHR, expression of TRPM7 is blunted. This was associated with attenuated annexin-1 translocation and decreased VSMC [Mg2+]i in SHR. Downregulation of TRPM7, but not
TRPM6
, may play a role in altered Mg2+ homeostasis in VSMCs from SHR.
...
PMID:Differential regulation of transient receptor potential melastatin 6 and 7 cation channels by ANG II in vascular smooth muscle cells from spontaneously hypertensive rats. 1610 4
Epidemiological, clinical and experimental evidence indicates an inverse association between Mg(2+) levels (serum and tissue) and blood pressure. Magnesium may influence blood pressure by modulating vascular tone and structure through its effects on numerous biochemical reactions that control vascular contraction/dilation, growth/apoptosis, differentiation and inflammation. Magnesium acts as a calcium channel antagonist, it stimulates production of vasodilator prostacyclins and nitric oxide and it alters vascular responses to vasoactive agonists. Mammalian cells regulate Mg(2+) concentration through specialized influx and efflux transport systems that have only recently been characterized. Magnesium efflux occurs via Na(2+)-dependent and Na(2+)-independent pathways. Mg(2+) influx is controlled by recently cloned transporters including Mrs2p, SLC41A1, SLC41A1, ACDP2, MagT1,
TRPM6
and TRPM7. Alterations in some of these systems may contribute to hypomagnesemia and intracellular Mg(2+) deficiency in
hypertension
. In particular increased Mg(2+) efflux through altered regulation of the vascular Na(+)/Mg(2+) exchanger and decreased Mg(2+) influx due to defective vascular and renal
TRPM6
/7 expression/activity may be important. This review discusses the role of Mg(2+) in vascular biology and implications in
hypertension
and focuses on the putative transport systems that control vascular magnesium homeostasis. Much research is still needed to clarify the exact mechanisms of Mg(2+) regulation in the cardiovascular system and the implications of aberrant transcellular Mg(2+) transport in the pathogenesis of cardiovascular disease.
...
PMID:Magnesium transport in hypertension. 1802 56
Magnesium, an essential intracellular cation, is critically involved in many biochemical reactions involved in the regulation of vascular tone and integrity. Decreased magnesium concentration has been implicated in altered vascular reactivity, endothelial dysfunction, vascular inflammation, and structural remodeling, processes important in vascular changes and target organ damage associated with
hypertension
. Until recently, very little was known about mechanisms regulating cellular magnesium homeostasis, and processes controlling transmembrane magnesium transport had been demonstrated only at the functional level. Two cation channels of the transient receptor potential melastatin (TRPM) cation channel family have now been identified as magnesium transporters,
TRPM6
and TRPM7. These unique proteins, termed chanzymes because they possess a channel and a kinase domain, are differentially expressed, with
TRPM6
being found primarily in epithelial cells and TRPM7 occurring ubiquitously. Vascular TRPM7 is modulated by vasoactive agents, pressure, stretch, and osmotic changes and may be a novel mechanotransducer. In addition to its magnesium transporter function, TRPM7 has been implicated as a signaling kinase involved in vascular smooth muscle cell growth, apoptosis, adhesion, contraction, cytoskeletal organization, and migration, important processes involved in vascular remodeling associated with
hypertension
and other vascular diseases. Emerging evidence suggests that vascular TRPM7 function may be altered in
hypertension
. This review discusses the importance of magnesium in vascular biology and implications in
hypertension
and highlights the transport systems, particularly
TRPM6
and TRPM7, which may play a role in the control of vascular magnesium homeostasis. Since the recent identification and characterization of Mg2+-selective transporters, there has been enormous interest in the field. However, there is still a paucity of information, and much research is needed to clarify the exact mechanisms of magnesium regulation in the cardiovascular system and the implications of aberrant transmembrane magnesium transport in the pathogenesis of
hypertension
and other vascular diseases.
...
PMID:Transient receptor potential melastatin 6 and 7 channels, magnesium transport, and vascular biology: implications in hypertension. 1819 17
Hyperaldosteronism is associated with
hypertension
, cardiovascular fibrosis, and electrolyte disturbances, including hypomagnesemia. Mechanisms underlying aldosterone-mediated Mg(2+) changes are unclear, but the novel Mg(2+) transporters
TRPM6
and TRPM7 may be important. We examined whether aldosterone influences renal
TRPM6
/7 and the TRPM7 downstream target annexin-1 and tested the hypothesis that Mg(2+) administration ameliorates aldosterone-induced cardiovascular and renal injury and prevents aldosterone-associated
hypertension
. C57B6 mice were studied (12 weeks, n=8 to 9/group); (1) control group (0.2% dietary Mg(2+)), (2) Mg(2+) group (0.75% dietary Mg(2+)), (3) aldosterone group (Aldo, 400 microg/kg/min and 0.9% NaCl drinking water), and (4) Aldo+Mg(2+) group. Blood pressure was unaltered by aldosterone and was similar in all groups throughout the experiment. Serum Na(+) was increased and serum K(+) and Mg(2+) decreased in the Aldo group. Aldo mice had hypomagnesuria and proteinuria, and renal, cardiac, and aortic fibrosis, which were normalized by Mg(2+) supplementation. Renal and cardiovascular expression of interleukin-6, VCAM1 and COX2 was increased in the Aldo group. Magnesium attenuated renal and cardiac interleukin-6 content and decreased renal VCAM1 and cardiac COX2 expression (P<0.05). Aldosterone decreased expression of renal TRPM7 and the downstream target annexin-1 (P<0.05) without effect on
TRPM6
. Whereas Mg(2+) increased mRNA expression of
TRPM6
and TRPM7, it had no effect on TRPM7 and annexin-1 protein content. Our data demonstrate that aldosterone mediates blood pressure-independent renal and cardiovascular fibrosis and inflammation through Mg(2+)-sensitive pathways. We suggest that altered Mg(2+) metabolism in hyperaldosteronism may relate to TRPM7 downregulation and that Mg(2+) protects against cardiovascular and renal damaging actions of aldosterone.
Hypertension
2008 Apr
PMID:Downregulation of renal TRPM7 and increased inflammation and fibrosis in aldosterone-infused mice: effects of magnesium. 1826 39
Decreased Mg(2+) concentration has been implicated in altered vascular reactivity, endothelial dysfunction and structural remodeling, processes important in vascular changes and target organ damage associated with
hypertension
. Unlike our knowledge of other major cations, mechanisms regulating cellular Mg(2+) handling are poorly understood. Until recently little was known about protein transporters controlling transmembrane Mg(2+) influx. However, new research has uncovered a number of genes and proteins identified as transmembrane Mg(2+) transporters, particularly transient receptor potential melastatin (TRPM) cation channels,
TRPM6
and TRPM7. Whereas
TRPM6
is found primarily in epithelial cells, TRPM7 is ubiquitously expressed. Vascular TRPM7 has been implicated as a signaling kinase involved in vascular smooth muscle cell growth, apoptosis, adhesion, contraction, cytoskeletal organization and migration, and is modulated by vasoactive agents, pressure, stretch and osmotic changes. Emerging evidence suggests that vascular TRPM7 function might be altered in
hypertension
. The present review discusses the importance of Mg(2+) in vascular biology in
hypertension
and focuses on transport systems, mainly TRPM7, that might play a role in the control of vascular Mg(2+) homeostasis. Elucidation of the relationship between the complex systems responsible for regulation of Mg(2+) homeostasis, the role of TRPM7 in vascular signaling, and the cardiovascular impact will be important for understanding the clinical implications of hypomagnesemia in cardiovascular disease.
...
PMID:Transient receptor potential melastatin 7 (TRPM7) cation channels, magnesium and the vascular system in hypertension. 2115 Jan 27
Magnesium may influence blood pressure by modulating vascular tone and structure through its effects on myriad biochemical reactions that control vascular contraction/dilation, growth/apoptosis, differentiation and inflammation. Magnesium acts as a calcium channel antagonist, it stimulates production of vasodilator prostacyclins and nitric oxide and it alters vascular responses to vasoconstrictor agents. Mammalian cells regulate Mg2+ concentration through special transport systems that have only recently been characterized. Magnesium efflux occurs via Na2+-dependent and Na2+-independent pathways. Mg2+ influx is controlled by recently cloned transporters including Mrs2p, SLC41A1, SLC41A2, ACDP2, MagT1,
TRPM6
and TRPM7. Alterations in some of these systems may contribute to hypomagnesemia and intracellular Mg2+ deficiency in
hypertension
and other cardiovascular pathologies. In particular, increased Mg2+ efflux through dysregulation of the vascular Na+/Mg2+ exchanger and decreased Mg2+ influx due to defective vascular and renal
TRPM6
/7 expression/activity may be important in altered vasomotor tone and consequently in blood pressure regulation. The present review discusses the role of Mg2+ in vascular biology and implications in
hypertension
and focuses on the putative transport systems that control magnesium homeostasis in the vascular system. Much research is still needed to clarify the exact mechanisms of cardiovascular Mg2+ regulation and the implications of aberrant cellular Mg2+ transport and altered cation status in the pathogenesis of
hypertension
and other cardiovascular diseases.
...
PMID:Vascular biology of magnesium and its transporters in hypertension. 2119 86
Recent data indicate that transient receptor potential (TRP) cation channels play an important role in
hypertension
. Now, we tested the hypothesis that TRP expression is altered in human cerebral vascular tissue in patients who had experienced hypertensive intracerebral hemorrhage. TRPC1, TRPC3, TRPC5, TRPC6, TRPM4,
TRPM6
, and TRPM7 channels were detected in cerebral vascular tissue by quantitative real-time RT-PCR. Control cerebral vascular tissue was obtained from normotensive patients who underwent neurosurgical operation because of brain tumor. To examine a possible relation between the expression of TRP expression and hypoxic conditions caused by the intracerebral bleeding, we examined the expression of hypoxia inducible factor 1a (HIF1a). Transcripts of TRPC3, TRPC5,
TRPM6
, and HIF1a were significantly reduced in cerebral vascular tissue from patients after hypertensive intracerebral hemorrhage compared to controls. TRPC3 mRNA correlated well with the expression of HIF1a mRNA (r(2) = 0.59; p = 0.01). TRPC3 expression is associated with
hypertension
and hypoxic conditions in human cerebral vascular tissue.
...
PMID:Decreased expression of transient receptor potential channels in cerebral vascular tissue from patients after hypertensive intracerebral hemorrhage. 2195 71
In comparison with calcium, magnesium is an "orphan nutrient" that has been studied considerably less heavily. Low magnesium intakes and blood levels have been associated with type 2 diabetes, metabolic syndrome, elevated C-reactive protein,
hypertension
, atherosclerotic vascular disease, sudden cardiac death, osteoporosis, migraine headache, asthma, and colon cancer. Almost half (48%) of the US population consumed less than the required amount of magnesium from food in 2005-2006, and the figure was down from 56% in 2001-2002. Surveys conducted over 30 years indicate rising calcium-to-magnesium food-intake ratios among adults and the elderly in the United States, excluding intake from supplements, which favor calcium over magnesium. The prevalence and incidence of type 2 diabetes in the United States increased sharply between 1994 and 2001 as the ratio of calcium-to-magnesium intake from food rose from <3.0 to >3.0. Dietary Reference Intakes determined by balance studies may be misleading if subjects have chronic latent magnesium deficiency but are assumed to be healthy. Cellular magnesium deficit, perhaps involving
TRPM6
/7 channels, elicits calcium-activated inflammatory cascades independent of injury or pathogens. Refining the magnesium requirements and understanding how low magnesium status and rising calcium-to-magnesium ratios influence the incidence of type 2 diabetes, metabolic syndrome, osteoporosis, and other inflammation-related disorders are research priorities.
...
PMID:Suboptimal magnesium status in the United States: are the health consequences underestimated? 2236 57
Magnesium ion channels and transporters regulate the cellular concentrations of Mg(2+), which must be tightly controlled as imbalances have been associated with diseases such as osteoporosis, diabetes, and
high blood pressure
in humans. The channels and transporters allow the "native" Mg(2+) to be transported against a high background concentration of its major competitor, Ca(2+). Their selectivity filters (the narrowest part of the open pore) control metal ion selectivity. As the structures of Mg(2+) channels in an open conformation with bound Mg(2+) have not yet been solved, the key determinants of Mg(2+)/Ca(2+) selectivity in Mg(2+) ion channels remain elusive. Here, using density functional theory combined with continuum dielectric methods, we evaluated how the competition between Mg(2+) and Ca(2+) in model selectivity filters depends on the degree of metal hydration, which correlates with the pore size/rigidity as well as the composition and solvent accessibility of the selectivity filter. The key determinant of the selectivity for Mg(2+) over Ca(2+) in the Mg(2+) channel selectivity filter is a pore that is sufficiently large to accommodate hexahydrated Mg ions. In such wide pores, the hexahydrated metal ions interact indirectly with the protein ligands, hence metal desolvation and ligand-ligand steric repulsion become less important than Mg(2+)-water-protein interactions. These wide pores are Mg(2+)-selective because compared to Ca(2+) or Na(+) and K(+) monocations, Mg(2+) better polarizes the bound water molecules resulting in stronger Mg(2+)-water-protein interactions. Although both tetrameric and pentameric filters with pores that can accommodate hexahydrated metal ions could select Mg(2+) over Ca(2+), a bilayered pentameric filter lined with a ring of amides and a ring of carboxylates seems to best discriminate the "native" Mg(2+) from its key rival, Ca(2+). Our results are consistent with available experimental data and help to elucidate the selectivity filters in the Mg(2+)-selective
TRPM6
and CorA channels.
...
PMID:Importance of metal hydration on the selectivity of Mg2+ versus Ca2+ in magnesium ion channels. 2408 90
Preeclampsia is a pregnancy-specific disorder characterized by de novo development of concurrent
hypertension
, proteinuria, and placental oxidative stress. During the last trimester of gestation, maternal-to-fetal transport of minerals is dramatically increased and becomes tightly mediated by ion channels that are highly permeable to various divalent cations, such as Ca(2+) , Mg(2+) , and Zn(2+) . The regulation of magnesium/inorganic phosphorus ion-channel transport in the placenta, however, is not incompletely understood. In the present study, we examined the regulation of magnesium/inorganic phosphorus channels (MPCs) in the placenta of pregnant women suffering from preeclampsia as well as in primary human placental cells subjected to oxidative stress. The expression of MPC genes (
TRPM6
, TRPM7, PiT-1, and PiT-2) was down-regulated in preeclamptic placenta tissues during preterm labor, and generally remained lower at term labor-although TRPM7 expression in the central placenta or PiT-2 expression in whole placenta was unchanged or up-regulated. Consistent with this association, expression of MPC genes in the primary placental cells was reduced under hypoxic conditions.
TRPM6
, TRPM7, and PiT-1 channels were predominantly detected in the syncytiotrophoblast layers of the placenta. In contrast, PiT-2 was abundant in the placental intravillous connective tissues. Taken together, our findings indicated that placental MPC expression is down-regulated in cases of preeclampsia and under hypoxia. This relationship may contribute to a better understanding of the interrelationship between magnesium/inorganic phosphorus imbalances and preeclampsia development during preterm or term labor.
...
PMID:Comparing the expression patterns of placental magnesium/phosphorus-transporting channels between healthy and preeclamptic pregnancies. 2515 68
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