Gross R A, Huggenvik J, Massa E, Allen R G, Uhler M D
Department of Neurology, University of Minnesota Medical School, Minneapolis 55455.
Mol Endocrinol. 1994 Aug;8(8):970-82. doi: 10.1210/mend.8.8.7997238.
The role of the cAMP-dependent kinase (AK) in neurotransmission was investigated by genetic alteration of AK subunit expression in AtT-20 clonal pituitary cells. We characterized and compared wild-type [AK(wt)] cells and two clones with different AK activities. The first stably expresses a gene for a mutant AK regulatory subunit (RI) that does not bind cAMP [AK(-)]; the second stably expresses a gene for the catalytic subunit (C) of AK [AK(+)]. Western blot analysis of RI and C subunit expression showed increased expression of both subunits in AK(+) and AK(-) cells relative to AK(wt), with the transfection-induced expression of one subunit producing a compensatory increase in the expression of the other. The basal AK activities varied among the cell types, with AK(+) cells possessing 3-fold higher basal AK activity than AK(wt) cells, and AK(-) cells possessing half the AK activity of AK(wt) cells. Preincubation of cultures with 300 microM 8-(4-chlorophenylthio)-cAMP increased AK activity approximately 4-fold in AK(wt) and AK(+) cells, but was without effect in AK(-) cells. Subsequent addition of 1 microM cAMP in vitro increased AK activity an additional 2- to 3-fold in all cell types. The higher basal AK activity found in AK(wt) and AK(+) cells was associated with larger whole cell calcium currents (approximately 43% and approximately 75% larger than in AK(-) cells, respectively) and faster rates of current rundown. The currents from each cell line had similar voltage-dependent and pharmacological properties, however, and [3H]PN200-110 binding was similar among the cell types. Maximal currents were evoked at clamp potentials of 0-10 mV; currents were inactivated approximately 30% in the steady state at holding potentials of -40 mV compared to -80 mV, and currents were reduced approximately 45% in the presence of nifedipine at -40 mV, but were insensitive to omega-conotoxin GVIA. AK(wt) and AK(+) cells also had higher basal and cAMP-stimulated release of beta-endorphin; control rates were approximately 50% greater, but stimulated rates were approximately 400% greater compared to those in AK(-) cells. We conclude that a greater number of calcium channels were activated by depolarization in the phosphorylated state, that current rundown was largely due to dephosphorylation, and that activation of calcium channels was coupled to the release of beta-endorphin.(ABSTRACT TRUNCATED AT 400 WORDS)
通过改变AtT - 20克隆垂体细胞中AK亚基的表达,研究了环磷酸腺苷依赖性激酶(AK)在神经传递中的作用。我们对野生型[AK(wt)]细胞以及两个具有不同AK活性的克隆进行了表征和比较。第一个克隆稳定表达一种不结合环磷酸腺苷的突变型AK调节亚基(RI)的基因[AK(-)];第二个克隆稳定表达AK催化亚基(C)的基因[AK(+)]。对RI和C亚基表达的蛋白质印迹分析表明,相对于AK(wt),AK(+)和AK(-)细胞中两个亚基的表达均增加,一个亚基的转染诱导表达会使另一个亚基的表达产生代偿性增加。基础AK活性在不同细胞类型中有所不同,AK(+)细胞的基础AK活性比AK(wt)细胞高3倍,而AK(-)细胞的AK活性是AK(wt)细胞的一半。用300微摩尔8 - (4 - 氯苯基硫代) - 环磷酸腺苷预孵育培养物后,AK(wt)和AK(+)细胞中的AK活性增加约4倍,但对AK(-)细胞无影响。随后在体外添加1微摩尔环磷酸腺苷,所有细胞类型中的AK活性又额外增加2至3倍。在AK(wt)和AK(+)细胞中发现的较高基础AK活性与更大的全细胞钙电流相关(分别比AK(-)细胞大43%和约75%)以及更快的电流衰减速率。然而,每个细胞系的电流具有相似的电压依赖性和药理学特性,并且[3H]PN200 - 110结合在不同细胞类型中相似。在钳制电位为0 - 10毫伏时诱发最大电流;在 - 40毫伏的保持电位下,稳态时电流失活约30%,而在 - 80毫伏时为 - 40毫伏时相比,在硝苯地平存在下电流在 - 40毫伏时降低约45%,但对ω - 芋螺毒素GVIA不敏感。AK(wt)和AK(+)细胞还具有更高的基础和环磷酸腺苷刺激的β - 内啡肽释放;对照速率大约高50%,但刺激速率比AK(-)细胞高约400%。我们得出结论,在磷酸化状态下,更多的钙通道被去极化激活,电流衰减主要是由于去磷酸化,并且钙通道的激活与β - 内啡肽的释放相关。(摘要截断于400字)
