Xu Ying, Sulaiman Pyroja, Feddersen Rod M, Liu Jian, Smith Robert G, Vardi Noga
Department of Neuroscience, University of Pennsylvania, Philadelphia, Pennsylvania 19104, USA.
J Neurosci. 2008 Sep 3;28(36):8873-84. doi: 10.1523/JNEUROSCI.0812-08.2008.
PCP2, a member of the GoLoco domain-containing family, is present exclusively in cerebellar Purkinje cells and retinal ON bipolar cells. Its function in these tissues is unknown. Biochemical and expression system studies suggest that PCP2 is a guanine nucleotide dissociation inhibitor, although a guanine nucleotide exchange factor has also been suggested. Here, we studied the function of PCP2 in ON bipolar cells because their light response depends on Galpha(o1), which is known to interact with PCP2. We identified a new splice variant of PCP2 (Ret-PCP2) and localized it to rod bipolar and ON cone bipolar cells. Electroretinogram recordings from PCP2-null mice showed a normal a-wave but a slower falling phase of the b-wave (generated by the activity of ON bipolar cells) relative to the wild type. Whole-cell recordings from rod bipolar cells showed, both under Ames medium and after blocking GABA(A/C) and glycine receptors, that PCP2-null rod bipolar cells were more depolarized than wild-type cells with greater inward current when clamped to -60 mV. Also under both conditions, the rise time of the response to intense light was slower by 28% (Ames) and 44% (inhibitory blockers) in the null cells. Under Ames medium, we also observed >30% longer decay time in the PCP2-null rod bipolar cells. We conclude that PCP2 facilitates cation channels closure in the dark, shortens the rise time of the light response directly, and accelerates the decay time indirectly via the inhibitory network. These data can most easily be explained if PCP2 serves as a guanine nucleotide exchange factor.
PCP2是含GoLoco结构域家族的成员之一,仅存在于小脑浦肯野细胞和视网膜ON双极细胞中。其在这些组织中的功能尚不清楚。生化和表达系统研究表明,PCP2是一种鸟嘌呤核苷酸解离抑制剂,不过也有人提出它是一种鸟嘌呤核苷酸交换因子。在此,我们研究了PCP2在ON双极细胞中的功能,因为它们的光反应依赖于已知与PCP2相互作用的Gα(o1)。我们鉴定出一种新的PCP2剪接变体(Ret-PCP2),并将其定位到视杆双极细胞和ON视锥双极细胞中。来自PCP2基因敲除小鼠的视网膜电图记录显示,a波正常,但相对于野生型,b波(由ON双极细胞的活动产生)的下降阶段较慢。在Ames培养基中以及阻断GABA(A/C)和甘氨酸受体后,对视杆双极细胞进行的全细胞记录表明,当钳制在-60 mV时,PCP2基因敲除的视杆双极细胞比野生型细胞更去极化,内向电流更大。同样在这两种条件下,基因敲除细胞对强光反应的上升时间在Ames培养基中慢28%,在使用抑制性阻断剂时慢44%。在Ames培养基中,我们还观察到PCP2基因敲除的视杆双极细胞的衰减时间延长了30%以上。我们得出结论,PCP2在黑暗中促进阳离子通道关闭,直接缩短光反应的上升时间,并通过抑制性网络间接加速衰减时间。如果PCP2作为鸟嘌呤核苷酸交换因子,这些数据最容易得到解释。