Biernbaum M S, Bownds M D
J Gen Physiol. 1979 Dec;74(6):649-69. doi: 10.1085/jgp.74.6.649.
Frog rod outer segments contain approximately 0.25 mol of GTP and 0.25 mol of ATP per mol of rhodopsin 3 min after their isolation from the retina. UTP and CTP are present at 10-fold and 100-fold lower levels, respectively. Concentrations of GTP and ATP decline in parallel over the next 4 min to reach relatively stable levels of 0.1 mol per mol of rhodopsin. Illumination reduces the concentration of endogenous GTP but not ATP. This light-induced decrease in GTP can be as large as 70% and has a half-time of 7 s. GTP is reduced to steady intermediate levels during extended illumination of intermediate intensity, but partially returns to its dark-adapted level after brief illumination. The magnitude of the decrease increases as a linear function of the logarithm of continuous light intensity at levels which bleach between 5 X 10(2) and 5 X 10(6) rhodopsin molecules/outer segment per second. This exceeds the range of intensities over which illumination causes decreases in the cyclic GMP content and permeability of isolated outer segments (Woodruff and Bownds. 1979. J. Gen. Physiol. 73:629-653). Thus, over 4 log units of light intensity, a sensitivity control mechanism functions to make extended illumination less effective in stimulating a GTP decrease. GTP levels in dark-adapted outer segments are sensitive to changes in calcium concentration in the suspending medium. If the external calcium concentration is reduced to 10(-8) M, GTP concentration is lowered to the same level caused by saturating illumination, and the GTP remaining is no longer light-sensitive. Lowering calcium concentration to intermediate levels between 10(-6) and 10(-8) M reduces GTP to stable intermediate levels, and the GTP remaining can be reduced by light. Restoration of millimolar calcium drives synthesis of GTP, but not of ATP, and GTP lability towards illumination is again observed. These calcium-induced changes in GTP are diminished by the addition of the divalent cation ionophore A23187. Lowering or raising magnesium levels does not influence the GTP concentration. These data raise the possibility that light activates either a calcium transport mechanism driven by the hydrolysis of GTP, or some other calcium-sensitive GTPase activity of unknown function. Known light-dependent reactions involving cyclic nucleotide transformations and rhodopsin phosphorylation appear to account for only a small fraction of the light-induced GTP decrease.
从视网膜分离3分钟后,蛙视杆细胞外段每摩尔视紫红质含有约0.25摩尔的GTP和0.25摩尔的ATP。UTP和CTP的含量分别比其低10倍和100倍。在接下来的4分钟内,GTP和ATP的浓度平行下降,达到每摩尔视紫红质相对稳定的0.1摩尔水平。光照会降低内源性GTP的浓度,但不会降低ATP的浓度。这种光诱导的GTP减少幅度可达70%,半衰期为7秒。在中等强度的持续光照下,GTP会降至稳定的中间水平,但在短暂光照后会部分恢复到暗适应水平。在每秒使5×10²至5×10⁶个视紫红质分子/外段发生漂白的光照强度水平下,减少幅度随连续光照强度对数呈线性增加。这超出了光照导致分离的外段中环状GMP含量和通透性降低的强度范围(伍德拉夫和鲍恩兹,1979年,《普通生理学杂志》73:629 - 653)。因此,在4个对数单位的光照强度范围内,一种敏感性控制机制发挥作用,使持续光照在刺激GTP减少方面效果降低。暗适应外段中的GTP水平对悬浮介质中钙浓度的变化敏感。如果外部钙浓度降至10⁻⁸ M,GTP浓度会降至饱和光照所导致的相同水平,剩余的GTP不再对光敏感。将钙浓度降至10⁻⁶至10⁻⁸ M之间的中间水平会使GTP降至稳定的中间水平,剩余的GTP可被光进一步降低。毫摩尔浓度钙的恢复会驱动GTP的合成,但不会驱动ATP的合成,并且再次观察到GTP对光照的不稳定性。添加二价阳离子载体A23187会减弱这些钙诱导的GTP变化。降低或升高镁水平不会影响GTP浓度。这些数据增加了一种可能性,即光激活了由GTP水解驱动的钙转运机制,或者激活了某种功能未知的其他钙敏感GTP酶活性。已知的涉及环状核苷酸转化和视紫红质磷酸化的光依赖反应似乎仅占光诱导GTP减少的一小部分。
