Blum J J
Department of Cell Biology, Duke University Medical Center, Durham, North Carolina 27710.
J Cell Physiol. 1992 Jul;152(1):111-7. doi: 10.1002/jcp.1041520115.
Promastigotes from late-log phase cultures of Leishmania donovani were washed and resuspended in Hanks' Balanced Salt Solution without glucose or phenyl red but with 20 mM (N-[2-hydroxyethyl] piperazine-N'-[2-ethanesulfonic acid]) (HEPES) (HBSS-, 305 mOsm/kg). They were then added to a solution containing 86Rb such that the final osmolality and ionic composition was as desired. Samples were taken at known times and the amount of intracellular 86Rb was measured. Similarly, experiments were performed in which 86Rb was added to the cultures about 18 hr before collection, and the amount of 86Rb released from the washed cells was measured. Under iso-osmotic conditions only about 1.3% of the intracellular 86Rb was released in 900 sec. This increased about 4-fold if the osmolality was reduced from 305-153 mOsm/kg. This is much slower than the very rapid release of alanine in response to hypo-osmotic stress, indicating that alanine release is not via a non-specific pore. Reducing the temperature from 26 degrees C to 3-4 degrees C completely inhibits 86Rb release under iso-osmotic conditions and largely inhibits it under hypo-osmotic conditions. The rate of 86Rb release was not sensitive to K+ concentration and was not altered if chloride was replaced by sulfamate. Ouabain had no effect on either 86Rb uptake or release, but carbonylcyanide P-trifluoromethoxyphenylhydrazone (FCCP) reduced the rate of 86Rb release and, after about a 300 sec exposure, completely inhibited 86Rb uptake. Amiloride partially inhibited 86Rb release, but had no effect on uptake. A decrease in pH from 7.1-5.9 had little effect on 86Rb release under iso-osmotic conditions and slightly increased the rate of release under hypo-osmotic conditions, but it decreased the rate of uptake under both iso-osmotic and hypo-osmotic conditions. Cells taken from 3-day stationary phase cultures released 86Rb more slowly under iso-osmotic conditions than cells from late log phase cultures, but were more responsive to hypo-osmotic stress than were log phase cells. These data appear to rule out an [Na-K-Cl] transporter or a [K-Cl] cotransporter as the means of K+ release, but are consistent with the possibility that a K+/H+ exchanger is present. The possibility that other carrier systems may be present is also discussed.
将来自杜氏利什曼原虫对数后期培养物的前鞭毛体洗涤后,重悬于不含葡萄糖或酚红但含有20 mM(N-[2-羟乙基]哌嗪-N'-[2-乙磺酸])(HEPES)的汉克斯平衡盐溶液(HBSS-,305 mOsm/kg)中。然后将它们加入含有86Rb的溶液中,使最终渗透压和离子组成符合要求。在已知时间取样并测量细胞内86Rb的量。同样,进行了实验,即在收集前约18小时向培养物中加入86Rb,并测量从洗涤后的细胞中释放的86Rb的量。在等渗条件下,仅约1.3%的细胞内86Rb在900秒内释放。如果渗透压从305 mOsm/kg降至153 mOsm/kg,释放量增加约4倍。这比丙氨酸在低渗应激下非常快速的释放要慢得多,表明丙氨酸的释放不是通过非特异性孔道。将温度从26℃降至3 - 4℃在等渗条件下完全抑制86Rb的释放,在低渗条件下也大大抑制其释放。86Rb的释放速率对K+浓度不敏感,并且如果用氨基磺酸盐替代氯离子,释放速率不变。哇巴因对86Rb的摄取或释放均无影响,但羰基氰化物对三氟甲氧基苯腙(FCCP)降低了86Rb的释放速率,并且在暴露约300秒后,完全抑制86Rb的摄取。氨氯吡咪部分抑制86Rb的释放,但对摄取无影响。pH从7.1降至5.9在等渗条件下对86Rb的释放影响不大,在低渗条件下略微增加释放速率,但在等渗和低渗条件下均降低摄取速率。从3天静止期培养物中获取的细胞在等渗条件下比对数后期培养物中的细胞释放86Rb更慢,但比对数期细胞对低渗应激更敏感。这些数据似乎排除了[Na-K-Cl]转运体或[K-Cl]共转运体作为K+释放的方式,但与存在K+/H+交换体的可能性一致。还讨论了可能存在其他载体系统的可能性。
