黏膜谷胱甘肽在色素沉着兔结膜中的特殊保护作用。

Gukasyan Hovhannes J, Kim Kwang-Jin, Kannan Ram, Farley Robert A, Lee Vincent H L

Departments of Pharmaceutical Sciences, University of Southern California, Los Angeles, California 90089, USA.

Invest Ophthalmol Vis Sci. 2003 Oct;44(10):4427-38. doi: 10.1167/iovs.03-0437.

PURPOSE

To investigate mechanisms of H(2)O(2)-induced reduction in rates of active ion transport (I(sc)) across the pigmented rabbit conjunctival tissue and the protective role afforded by mucosal glutathione (GSH).

METHODS

Changes in I(sc) and specific binding properties of ouabain were evaluated in a modified Ussing chamber setup, using conjunctival tissues freshly excised from pigmented rabbits. Effective concentrations of H(2)O(2) at which 50% of I(sc) was inhibited (IC(50)) were determined for the mucosal and serosal instillation of the agent. The rate of exogenous H(2)O(2) consumption in the mucosal and serosal bathing fluids was estimated. Mucosal 8-Br cAMP at 3 mM, serosal bumetanide at 0.5 mM, and both mucosal and serosal bathing of the conjunctiva with Na(+)-free bicarbonated Ringer's solution (BRS) were used to estimate contributions of conjunctival ion transport mechanisms in I(sc) changes elicited by mucosal H(2)O(2) at IC(50). Specific binding of (3)H-ouabain to the serosal side of the conjunctiva was estimated in the presence of mucosal or serosal H(2)O(2) to assess the role of functional Na(+)/K(+)-ATPase pumps in H(2)O(2) injury. The effect of mucosally instilled GSH and other reductive and nonreductive agents on possible restoration of oxidant-induced decrease in conjunctival I(sc) was also determined.

RESULTS

Mucosal and serosal H(2)O(2) decreased conjunctival I(sc) gradually in a dose-dependent manner. The mucosal IC(50) of H(2)O(2)was 1.49 +/- 0.20 mM, whereas the serosal IC(50) was estimated at 10.6 +/- 2.0 micro M. The rate of H(2)O(2) consumption from mucosal fluid was six times faster than that from serosal fluid. Conjunctival tissues pretreated with mucosal H(2)O(2) at IC(50) retained approximately 50% of their maximum 8-Br cAMP-dependent increases in I(sc). Serosal bumetanide did not further reduce the I(sc) beyond the initial 70% decrease caused by mucosal H(2)O(2). When conjunctiva was bathed with Na(+)-free BRS on both the mucosal and serosal sides, before or after addition of mucosal H(2)O(2), the combined effects were additive, decreasing I(sc) by up to 95% to 99%. Mucosal, but not serosal, GSH or reduced L-glutathione mono-ethyl ester (GSH-MEE) superfusion of conjunctival tissues pre-exposed to mucosal H(2)O(2) at IC(50) recovered to 60% to 80% of the initial pre-H(2)O(2) I(sc) after approximately 100 minutes. The specific binding of (3)H-ouabain to the serosal side of the tissue was inhibited by 85% in the presence of mucosal or serosal treatment with H(2)O(2) at their respective IC(50) values. Pretreatment for 60 minutes with either 5 mM GSH, 2 mM GSH-MEE, or 0.1 mM ebselen, when instilled into the mucosal fluid, resulted in 30%, 45%, or 55% reductions, respectively, in ouabain binding after exposure to mucosal H(2)O(2) at IC(50). Furthermore, mucosal posttreatment with 10 mM GSH or 5 mM GSH-MEE of conjunctival tissues pre-exposed to mucosal H(2)O(2) resulted in a 30% recovery of the ouabain-binding level above that observed in tissues exposed to 1.5 mM H(2)O(2) alone on the mucosal side. By contrast, the decrease in conjunctival I(sc) or in the ouabain-binding level elicited by serosal H(2)O(2) at IC(50) was irreversible.

CONCLUSIONS

A higher mucosal IC(50) of [H(2)O(2)] on conjunctival I(sc) corresponds to the faster consumption of exogenous H(2)O(2) from mucosal bathing fluid. In addition, actively secreted GSH by conjunctival epithelial cells may help reduce the injury by mucosally applied H(2)O(2). Injury by H(2)O(2) may directly affect vital membrane components (e.g., Na(+),K(+)-ATPase) involved in active ion transport across conjunctiva. Mucosal protection by GSH (or its analogues) of active conjunctival ion transport may be useful in maintaining the physiological functions of conjunctiva under oxidative stress.

目的

研究过氧化氢（H₂O₂）诱导色素沉着兔结膜组织主动离子转运速率（Isc）降低的机制以及黏膜谷胱甘肽（GSH）所起的保护作用。

方法

在改良的Ussing室装置中，使用从色素沉着兔新鲜切除的结膜组织，评估Isc的变化和哇巴因的特异性结合特性。确定该试剂经黏膜和浆膜滴注时抑制50% Isc的有效浓度（IC₅₀）。估计黏膜和浆膜浴液中外源性H₂O₂的消耗速率。使用3 mM的黏膜8-溴环磷酸腺苷（8-Br cAMP）、0.5 mM的浆膜布美他尼以及用无钠碳酸氢林格液（BRS）对结膜进行黏膜和浆膜浴，以评估结膜离子转运机制在IC₅₀时黏膜H₂O₂引起的Isc变化中的作用。在黏膜或浆膜存在H₂O₂的情况下，估计³H-哇巴因与结膜浆膜侧的特异性结合，以评估功能性钠/钾-ATP酶泵在H₂O₂损伤中的作用。还确定了黏膜滴注GSH以及其他还原性和非还原性试剂对氧化剂诱导的结膜Isc降低的可能恢复作用。

结果

黏膜和浆膜H₂O₂均以剂量依赖性方式逐渐降低结膜Isc。H₂O₂的黏膜IC₅₀为1.49±0.20 mM，而浆膜IC₅₀估计为10.6±2.0 μM。黏膜液中H₂O₂的消耗速率比浆膜液快6倍。用IC₅₀的黏膜H₂O₂预处理的结膜组织在其最大8-Br cAMP依赖性Isc增加中保留了约50%。浆膜布美他尼在黏膜H₂O₂引起的最初70%降低基础上并未进一步降低Isc。当在添加黏膜H₂O₂之前或之后，用无钠BRS对结膜的黏膜和浆膜两侧进行浴洗时，联合作用是相加的，使Isc降低高达95%至99%。用IC₅₀的黏膜H₂O₂预先处理的结膜组织，经黏膜而非浆膜灌注GSH或还原型L-谷胱甘肽单乙酯（GSH-MEE）后约100分钟，Isc恢复到H₂O₂处理前初始值的60%至80%。在黏膜或浆膜用各自IC₅₀值的H₂O₂处理的情况下，³H-哇巴因与组织浆膜侧的特异性结合被抑制85%。当滴注到黏膜液中时，用5 mM GSH、2 mM GSH-MEE或0.1 mM依布硒啉预处理60分钟，在暴露于IC₅₀的黏膜H₂O₂后，哇巴因结合分别降低30%、45%或55%。此外，用10 mM GSH或5 mM GSH-MEE对预先暴露于黏膜H₂O₂ 的结膜组织进行黏膜后处理，使哇巴因结合水平比仅在黏膜侧暴露于1.5 mM H₂O₂的组织中观察到的水平恢复30%。相比之下，IC₅₀时浆膜H₂O₂引起的结膜Isc降低或哇巴因结合水平降低是不可逆的。

结论

结膜Isc上[H₂O₂]的较高黏膜IC₅₀与黏膜浴液中外源性H₂O₂的更快消耗相对应。此外，结膜上皮细胞主动分泌的GSH可能有助于减轻黏膜应用H₂O₂造成的损伤。H₂O₂损伤可能直接影响参与结膜主动离子转运的重要膜成分（如钠、钾-ATP酶）。GSH（或其类似物）对结膜主动离子转运的黏膜保护作用可能有助于在氧化应激下维持结膜的生理功能。