Induction of T-type Calcium Channel Gene Expression by Chronic Hypoxia

Toro, R.; Levitsky, Konstantín L.; López‐Barneo, José; Chiara, María‐Dolores

doi:10.1074/jbc.m212576200

Cited by 108 publications

(69 citation statements)

References 60 publications

(86 reference statements)

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“…Altogether, these results support the view that reduced expression of the maxi-K ϩ channel ␤ 1 -subunit contributes to vascular pathophysiology in hypoxia. However, it is important to keep in mind that we have studied downregulation of the maxi-K ϩ channel ␤ 1 -subunit within the first 24 to 48 hours of exposure to hypoxia (a protocol normally used for the study of hypoxia-regulated genes [25][26][27] ), whereas the establishment of chronic hypertension in humans results from exposures to hypoxia lasting weeks or months.…”

Section: Discussionmentioning

confidence: 99%

“…We assayed the effect of dimethyloxalylglycine (DMOG), a competitive inhibitor of prolyl hydroxylases that stabilizes HIF in normoxia. 5,26,27 DMOG induced HO-1 by approximately 2.5-fold but did not alter the mRNA levels of the ␤ 1 -subunit. However, downregulation of the ␤ 1 -subunit was more pronounced in cells exposed sequentially to hypoxia (6 hours, 1% O 2 ), reoxygenation (18 hours, 20% O 2 ), and hypoxia (6 hours, 1% O 2 ) compared with those exposed to sustained hypoxia (30 hours, 1% O 2 ) (Figure 2).…”

Section: Channel ␤ 1 -Subunit Mrna In Arterial Myocytesmentioning

confidence: 99%

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Decreased Expression of Maxi-K ⁺ Channel β ₁ -Subunit and Altered Vasoregulation in Hypoxia

et al. 2005

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Background-Hypertension, a major cause of cardiovascular morbidity and mortality, can result from chronic hypoxia; however, the pathogenesis of this disorder is unknown. We hypothesized that downregulation of the maxi-K ϩ channel ␤ 1 -subunit by hypoxia decreases the ability of these channels to hyperpolarize arterial smooth muscle cells, thus favoring vasoconstriction and hypertension. Methods and Results-Lowering O 2 tension produced a decrease of maxi-K ϩ ␤ 1 -subunit mRNA levels in rat (aortic and basilar) and human (mammary) arterial myocytes. This was paralleled by a reduction of the ␤ 1 -subunit protein level as determined by immunocytochemistry and flow cytometry. Exposure to hypoxia also produced a decrease of open probability, mean open time, and sensitivity to the xenoestrogen tamoxifen of single maxi-K ϩ channels recorded from patch-clamped dispersed myocytes. The number of channels per patch and the single-channel conductance were not altered. The vasorelaxing force of maxi-K ϩ channels was diminished in rat and human arterial rings exposed to low oxygen tension. Conclusions-These

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Section: Discussionmentioning

confidence: 99%

Section: Channel ␤ 1 -Subunit Mrna In Arterial Myocytesmentioning

confidence: 99%

Decreased Expression of Maxi-K ⁺ Channel β ₁ -Subunit and Altered Vasoregulation in Hypoxia

et al. 2005

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“…Based on the analysis of the rate of mRNA production and stability, these authors concluded that posttranslational mechanisms contribute to the upregulation of the ␤-subunit. Using a clonal cell line (PC12 cells), del Toro et al (2003) examined the effects of chronic hypoxia on T-type Ca 2ϩ channel expression. They observed robust upregulation of the ␣ 1H subunit of the T-type Ca 2ϩ channel and increased current density of this channel in response to prolonged hypoxia.…”

Section: Effects Of Chronic Hypoxia On Sensory Transductionmentioning

confidence: 99%

Cellular and Molecular Mechanisms Associated with Carotid Body Adaptations to Chronic Hypoxia

Prabhakar

Jacono

2005

High Altitude Medicine & Biology

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Chronic hypoxia leads to adaptations in the respiratory system manifested as a persistent increase in resting ventilation, termed ventilatory acclimatization to hypoxia (VAH). Increased afferent nerve activity from carotid bodies and the ensuing reflex activation of ventilation are critical for eliciting VAH. In this review we highlight recent information on the cellular and molecular mechanisms associated with chronic hypoxia-induced functional and structural changes in the carotid body. Chronic hypoxia leads to hypersensitivity of the carotid bodies and induces morphological changes, including enlargement of the organ, hyperplasia of glomus cells, and neovascularization. Enhanced hypoxic sensitivity is due to alterations in ion current densities, as well as changes in neurotransmitter dynamics and recruitment of additional neuromodulators (endothelin- 1, ET-1) in glomus cells. Morphological alterations are in part due to upregulation of growth factors (e.g., VEGF). VAH is markedly attenuated in mice partially deficient in HIF-1 transcription factor, which regulates several downstream genes, including VEGF, ET-1, and Ca(2+) channels. The finding that VAH is also blunted in mice deficient in the fosB gene led to the suggestion that the magnitude and time course of VAH depend on complex interactions between more than one transcription factor, resulting in coordinated regulation of several downstream genes and their protein products.

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“…Chronic hypoxia induces a decrease in GLUT1 expression in the adult rat brain but an increase in the fetal as well as in the developing brain (73). Chronic hypoxia also raises the mRNA and channel currents of T-type voltage-gated Ca 2ϩ channels but not of other types of Ca ϩϩ channels in pheochromocytoma-derived PC12 cells (21).…”

Section: Effect Of Hypoxia On the Expression Of Bicarbonate Transportersmentioning

confidence: 99%

Chronic continuous hypoxia decreases the expression of SLC4A7 (NBCn1) and SLC4A10 (NCBE) in mouse brain

Chen¹,

Choi²,

Haddad³

et al. 2007

American Journal of Physiology-Regulatory, Integrative and Comp

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Chen L-M, Choi I, Haddad GG, Boron WF. Chronic continuous hypoxia decreases the expression of SLC4A7 (NBCn1) and SLC4A10 (NCBE) in mouse brain. Am J Physiol Regul Integr Comp Physiol 293: R2412-R2420, 2007. First published October 10, 2007; doi:10.1152/ajpregu.00497.2007.-In the mammalian CNS, hypoxia causes a wide range of physiological effects, and these effects often depend on the stage of development. Among the effects are alterations in pH homeostasis. Na ϩ -coupled HCO 3 Ϫ transporters can play critical roles in intracellular pH regulation and several, such as NCBE and NBCn1, are expressed abundantly in the central nervous system. In the present study, we examined the effect of chronic continuous hypoxia on the expression of two electroneutral Na-coupled HCO 3 Ϫ transporters, SLC4a7 (NBCn1) and SLC4a10 (NCBE), in mouse brain, the first such study on any acid-base transporter. We placed the mice in normobaric chambers and either maintained normoxia (21% inspired O 2) or imposed continuous chronic hypoxia (11% O2) for a duration of either 14 days or 28 days, starting from ages of either postnatal age 2 days (P2) or P90. We assessed protein abundance by Western blot analysis, loading equal amounts of total protein for each condition. In most cases, hypoxia reduced NBCn1 levels by 20 -50%, and NCBE levels by 15-40% in cerebral cortex, subcortex, cerebellum, and hippocampus, both after 14 and 28 days, and in both pups and adults. We hypothesize that these decreases, which are out of proportion to the expected overall decreases in brain protein levels, may especially be important for reducing energy consumption. electroneutral; bicarbonate transporter; SLC4; central nervous system HYPOXIA, A LOW-OXYGEN LEVEL in tissue, may be either continuous or intermittent. Chronic continuous hypoxia (CCH) may occur during normal events, such as embryonic development and ascent to altitude, and in pathological states, such as pulmonary disease (i.e., decreased O 2 uptake), anemia (i.e., decreased O 2 content in blood), ischemia (i.e., decreased blood flow to tissues), and cancer (i.e., increased O 2 utilization by tissues). Chronic intermittent hypoxia (CIH) occurs during obstructive sleep apnea. Due to its very high energy demands, the mammalian brain is particularly sensitive to hypoxia.Mammals immediately respond to hypoxemia by increasing first alveolar ventilation and then heart rate. The central nervous system (CNS) also rapidly responds with several metabolic adaptations (3,39,40,44,54,74,78). Over a longer period of time, the acclimation to hypoxemia includes both functional and structural changes in many tissues, including the CNS (for reviews, see Refs. 35,39,and 74). Structural changes in response to chronic hypoxia include a decrease in body mass and an increase in capillary density, which in the brain can amount to a doubling over a period of ϳ4 wk (7, 41) (for reviews, see Refs. 39 and 74). The angiogenic response is under the control of hypoxia-inducible factor-1 (for reviews, see Refs. 29, 33, and 64) and an...

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Induction of T-type Calcium Channel Gene Expression by Chronic Hypoxia

Cited by 108 publications

References 60 publications

Decreased Expression of Maxi-K ⁺ Channel β ₁ -Subunit and Altered Vasoregulation in Hypoxia

Decreased Expression of Maxi-K ⁺ Channel β ₁ -Subunit and Altered Vasoregulation in Hypoxia

Cellular and Molecular Mechanisms Associated with Carotid Body Adaptations to Chronic Hypoxia

Chronic continuous hypoxia decreases the expression of SLC4A7 (NBCn1) and SLC4A10 (NCBE) in mouse brain

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Induction of T-type Calcium Channel Gene Expression by Chronic Hypoxia

Cited by 108 publications

References 60 publications

Decreased Expression of Maxi-K + Channel β 1 -Subunit and Altered Vasoregulation in Hypoxia

Decreased Expression of Maxi-K + Channel β 1 -Subunit and Altered Vasoregulation in Hypoxia

Cellular and Molecular Mechanisms Associated with Carotid Body Adaptations to Chronic Hypoxia

Chronic continuous hypoxia decreases the expression of SLC4A7 (NBCn1) and SLC4A10 (NCBE) in mouse brain

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Decreased Expression of Maxi-K ⁺ Channel β ₁ -Subunit and Altered Vasoregulation in Hypoxia

Decreased Expression of Maxi-K ⁺ Channel β ₁ -Subunit and Altered Vasoregulation in Hypoxia