Wang X, Li L, Peracchia L L, Peracchia C
Department of Physiology, University of Rochester School of Medicine and Dentistry, 601 Elmwood Avenue, Rochester, NY 14642-8642, USA.
Pflugers Arch. 1996 Apr;431(6):844-52. doi: 10.1007/s004240050076.
Gap junction channels are regulated by gates that close upon exposure to 100% CO2, probably via an increase in intracellular Ca2+ concentration, [Ca2+]i. For defining connexin (Cx) domain(s) involved in gating, we have studied chemical and voltage gating sensitivities of channels made of Cx38, Cx32 or chimeras of the above, expressed in Xenopus oocytes. Cx38 channels are more sensitive to CO2 and voltage than those of Cx32. A 3-min exposure to 100% CO2 reduces Cx38 junctional conductance (Gj) to 0% of initial values at a maximum rate of 25%/min, whereas even a 15-min exposure to 100% CO2 reduces Cx32 Gj by approximately 50% at the slow rate of 9%/min. Of the various Cx32 mutants and Cx32/38 chimeras constructed, two chimeras (Cx32/38I and Cx32/38N) expressed functional channels. Upon exposure to CO2, channels made of Cx32/38I (Cx32 inner loop replaced with that of Cx38) reproduced precisely the uncoupling behavior of Cx38 channels in uncoupling magnitude and in both uncoupling and recoupling rates, whereas channels made of Cx32/38N (N-terminus replaced) behaved closer to Cx32 than to Cx38 channels. Cx38 channels were more voltage sensitive than those of Cx32, with V0, i.e., the transjunctional voltage at which voltage-sensitive conductance is half maximal = 35.3 and 59.5 mV, and n, i.e., equivalent gating charge = 3.3 and 2.1, respectively. Of the two chimeras, Cx32/38I channels were similar to Cx38 channels, with V0 = 40.6 mV, Gj min, i.e., the theoretical minimal normalized junctional conductance = 0.35 and n = 3.0, whereas Cx32/38 N channels displayed very low voltage sensitivity, with V0 = 84.8 mV, Gj min = 0.5 and n = 1.1. The data suggest that the inner loop plays a major role in pH and voltage gating sensitivity, but whether other domains also participate in the gating mechanism cannot be excluded.
缝隙连接通道由门控调节,暴露于100%二氧化碳时门会关闭,可能是通过细胞内钙离子浓度[Ca2+]i的增加来实现。为了确定参与门控的连接蛋白(Cx)结构域,我们研究了由Cx38、Cx32或上述两者的嵌合体组成的通道在非洲爪蟾卵母细胞中表达时的化学门控和电压门控敏感性。Cx38通道比Cx32通道对二氧化碳和电压更敏感。暴露于100%二氧化碳3分钟可使Cx38连接电导(Gj)以最大25%/分钟的速率降至初始值的0%,而即使暴露于100%二氧化碳15分钟,Cx32的Gj也仅以9%/分钟的缓慢速率降低约50%。在构建的各种Cx32突变体和Cx32/38嵌合体中,有两个嵌合体(Cx32/38I和Cx32/38N)表达了功能性通道。暴露于二氧化碳时,由Cx32/38I(Cx32内环被Cx38的内环取代)组成的通道在解偶联幅度以及解偶联和重新偶联速率方面精确再现了Cx38通道的解偶联行为,而由Cx32/38N(N端被取代)组成的通道表现得更接近Cx32通道而非Cx38通道。Cx38通道比Cx32通道对电压更敏感,其V0(即电压敏感电导为最大值一半时的跨连接电压)分别为35.3和59.5 mV,n(即等效门控电荷)分别为3.3和2.1。在这两个嵌合体中,Cx32/38I通道与Cx38通道相似,V0 = 40.6 mV,Gj min(即理论最小标准化连接电导) = 0.35,n = 3.0,而Cx32/38 N通道表现出非常低的电压敏感性,V0 = 84.8 mV,Gj min = 0.5,n = 1.1。数据表明内环在pH和电压门控敏感性中起主要作用,但不能排除其他结构域也参与门控机制的可能性。
