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雄性大鼠吸入硫化氢和低氧的代谢和心脏信号作用。

Metabolic and cardiac signaling effects of inhaled hydrogen sulfide and low oxygen in male rats.

机构信息

Department of Environmental Health Sciences, University of Alabama at Birmingham, Birmingham, Alabama 35294, USA.

出版信息

J Appl Physiol (1985). 2012 May;112(10):1659-69. doi: 10.1152/japplphysiol.01598.2011. Epub 2012 Mar 8.

DOI:10.1152/japplphysiol.01598.2011
PMID:22403348
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3365405/
Abstract

Low concentrations of inhaled hydrogen sulfide (H(2)S) induce hypometabolism in mice. Biological effects of H(2)S in in vitro systems are augmented by lowering O(2) tension. Based on this, we hypothesized that reduced O(2) tension would increase H(2)S-mediated hypometabolism in vivo. To test this, male Sprague-Dawley rats were exposed to 80 ppm H(2)S at 21% O(2) or 10.5% O(2) for 6 h followed by 1 h recovery at room air. Rats exposed to H(2)S in 10.5% O(2) had significantly decreased body temperature and respiration compared with preexposure levels. Heart rate was decreased by H(2)S administered under both O(2) levels and did not return to preexposure levels after 1 h recovery. Inhaled H(2)S caused epithelial exfoliation in the lungs and increased plasma creatine kinase-MB activity. The effect of inhaled H(2)S on prosurvival signaling was also measured in heart and liver. H(2)S in 21% O(2) increased Akt-P(Ser473) and GSK-3β-P(Ser9) in the heart whereas phosphorylation was decreased by H(2)S in 10.5% O(2), indicating O(2) dependence in regulating cardiac signaling pathways. Inhaled H(2)S and low O(2) had no effect on liver Akt. In summary, we found that lower O(2) was needed for H(2)S-dependent hypometabolism in rats compared with previous findings in mice. This highlights the possibility of species differences in physiological responses to H(2)S. Inhaled H(2)S exposure also caused tissue injury to the lung and heart, which raises concerns about the therapeutic safety of inhaled H(2)S. In conclusion, these findings demonstrate the importance of O(2) in influencing physiological and signaling effects of H(2)S in mammalian systems.

摘要

低浓度的吸入硫化氢(H2S)可诱导小鼠代谢降低。在体外系统中,H2S 的生物学效应通过降低氧张力得到增强。基于此,我们假设降低氧张力会增加体内 H2S 介导的代谢降低。为了验证这一点,雄性 Sprague-Dawley 大鼠在 21% O2 或 10.5% O2 中暴露于 80 ppm H2S 6 小时,然后在室温空气中恢复 1 小时。与暴露前水平相比,暴露于 10.5% O2 中的 H2S 的大鼠体温和呼吸明显下降。在两种氧水平下,H2S 给药都会降低心率,并且在 1 小时恢复后心率不会恢复到暴露前水平。吸入 H2S 会导致肺部上皮细胞脱落,并增加血浆肌酸激酶-MB 活性。还测量了吸入 H2S 对心脏和肝脏中生存信号的影响。在心脏中,21% O2 中的 H2S 增加了 Akt-P(Ser473)和 GSK-3β-P(Ser9),而在 10.5% O2 中的 H2S 则降低了磷酸化,表明心脏信号通路的调节需要氧。吸入 H2S 和低氧对肝脏 Akt 没有影响。总之,我们发现与以前在小鼠中发现的情况相比,大鼠中需要更低的 O2 来实现 H2S 依赖性代谢降低。这突出了物种对 H2S 生理反应的差异的可能性。吸入 H2S 暴露还会导致肺部和心脏组织损伤,这引发了对吸入 H2S 治疗安全性的担忧。总之,这些发现表明 O2 在影响哺乳动物系统中 H2S 的生理和信号效应方面的重要性。

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