大鼠阻力动脉中的氯离子和碳酸氢根转运
Chloride and bicarbonate transport in rat resistance arteries.
作者信息
Aalkjaer C, Hughes A
机构信息
Danish Biomembrane Research Centre, University of Aarhus, Denmark.
出版信息
J Physiol. 1991 May;436:57-73. doi: 10.1113/jphysiol.1991.sp018539.
Abstract
- The role of chloride and bicarbonate in the control of intracellular pH (pHi) was assessed in segments of rat mesenteric resistance arteries (internal diameter about 200 microns) by measurements of chloride efflux with 36Cl-, of pHi with the pH-sensitive dye 2',7'-bis-(2-carboxyethyl)-5 (and-6)-carboxyfluorescein (BCECF) and of membrane potential with intracellular electrodes. 2. The main questions addressed were whether the previously demonstrated sodium-coupled uptake of bicarbonate in these arteries was also coupled to chloride efflux, and whether sodium-independent Cl(-)-HCO3- exchange was present and played a role in regulation of pHi. 3. The 36Cl- efflux was unaffected by acidification induced by an NH4Cl pre-pulse in the presence as well as in the absence of bicarbonate. This was also true in sodium-free media and in vessels depolarized by high potassium. 4. The membrane potential was unaffected by the acidification associated with wash-out of NH4Cl, and the net acid extrusion during recovery of pHi from the acidification was not affected significantly by depolarization. 5. In the absence of bicarbonate, omission of extracellular chloride caused no change in pHi, but reduced 36Cl- efflux. By contrast, in the presence of bicarbonate, omission of chloride caused an increase in pHi but no change in 36Cl- efflux. Furthermore, the anion transport inhibitor 4,4'-diisothiocyanatostilbene-2,2'-disulphonic acid (DIDS) inhibited the increase in pHi seen in the presence of bicarbonate and reduced the 36Cl- efflux in the presence of bicarbonate. 6. The presence of bicarbonate had no significant effect on the rate of recovery of pHi or the rate of increase of intracellular acid equivalents after an NH4Cl induced alkalinization; also the buffering power was not significantly different in the absence and presence of bicarbonate. Moreover these parameters were not significantly affected by DIDS, although DIDS as previously demonstrated reduced the rate of recovery of pHi from acidification. 7. The membrane potential was not significantly affected by the alkalinization associated with addition of NH4Cl and the rate of recovery of pHi from the alkalinization was not affected by depolarization. 8. The effects of NH4Cl and PCO2 on 36Cl- efflux were complex and could not easily be explained by the changes in pHi.(ABSTRACT TRUNCATED AT 400 WORDS)
摘要
- 通过用³⁶Cl⁻测量氯离子外流、用pH敏感染料2',7'-双-(2-羧乙基)-5(和-6)-羧基荧光素(BCECF)测量细胞内pH(pHi)以及用细胞内电极测量膜电位,评估了氯离子和碳酸氢根在大鼠肠系膜阻力动脉段(内径约200微米)中对细胞内pH控制的作用。2. 所探讨的主要问题是,这些动脉中先前证明的与钠偶联的碳酸氢根摄取是否也与氯离子外流偶联,以及是否存在不依赖钠的Cl⁻-HCO₃⁻交换并在pHi调节中起作用。3. 在有和没有碳酸氢根的情况下,³⁶Cl⁻外流不受氯化铵预脉冲诱导的酸化影响。在无钠培养基和高钾去极化的血管中也是如此。4. 膜电位不受氯化铵洗脱相关酸化的影响,并且在pHi从酸化恢复过程中的净酸排出不受去极化的显著影响。5. 在没有碳酸氢根的情况下,去除细胞外氯离子不会导致pHi改变,但会降低³⁶Cl⁻外流。相比之下,在有碳酸氢根的情况下,去除氯离子会导致pHi升高,但³⁶Cl⁻外流没有变化。此外,阴离子转运抑制剂4,4'-二异硫氰酸根合芪-2,2'-二磺酸(DIDS)抑制了在有碳酸氢根时观察到的pHi升高,并降低了有碳酸氢根时的³⁶Cl⁻外流。6. 碳酸氢根的存在对氯化铵诱导碱化后pHi的恢复速率或细胞内酸当量的增加速率没有显著影响;在没有和有碳酸氢根的情况下缓冲能力也没有显著差异。此外,尽管如先前所示DIDS降低了pHi从酸化恢复的速率,但这些参数不受DIDS的显著影响。7. 膜电位不受氯化铵添加相关碱化的显著影响,并且pHi从碱化恢复的速率不受去极化的影响。8. 氯化铵和二氧化碳分压对³⁶Cl⁻外流的影响很复杂,难以用pHi的变化轻易解释。(摘要截断于400字)
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