Department of Biological Chemistry, University of Michigan Medical School, Ann Arbor, Michigan 48109, United States.
Biochemistry. 2011 Dec 20;50(50):10929-40. doi: 10.1021/bi201410x. Epub 2011 Nov 22.
Glutamine synthetase (GS) activity in Escherichia coli is regulated by reversible adenylylation, brought about by a bicyclic system comprised of uridylyltransferase/uridylyl-removing enzyme (UTase/UR), its substrate, PII, adenylyltransferase (ATase), and its substrate, GS. The modified and unmodified forms of PII produced by the upstream UTase/UR-PII cycle regulate the downstream ATase-GS cycle. A reconstituted UTase/UR-PII-ATase-GS bicyclic system has been shown to produce a highly ultrasensitive response of GS adenylylation state to the glutamine concentration, but its composite UTase/UR-PII and ATase-GS cycles displayed moderate glutamine sensitivities when examined separately. Glutamine sensitivity of the bicyclic system was significantly reduced when the trimeric PII protein was replaced by a heterotrimeric form of PII that was functionally monomeric, and coupling between the two cycles was different in systems containing wild-type or heterotrimeric PII. Thus, the trimeric nature of PII played a role in the glutamine response of the bicyclic system. We therefore examined regulation of the individual AT (adenylylation) and AR (deadenylylation) activities of ATase by PII preparations with various levels of uridylylation. AR activity was affected in a linear fashion by PII uridylylation, but partially modified wild-type PII activated the AT much less than expected based on the extent of PII modification. Partially modified wild-type PII also bound to ATase less than expected based upon the fraction of modified subunits. Our results suggest that the AT activity is only bound and activated by completely unmodified PII and that this design is largely responsible for ultrasensitivity of the bicyclic system.
大肠杆菌中的谷氨酰胺合成酶(GS)活性受可逆腺苷酰化调节,这是由一个双环系统实现的,该系统由尿苷酰转移酶/尿苷酰酶(UTase/UR)、其底物 PII、腺苷酰转移酶(ATase)及其底物 GS 组成。上游 UTase/UR-PII 循环产生的修饰和未修饰形式的 PII 调节下游 ATase-GS 循环。已证明,重组的 UTase/UR-PII-ATase-GS 双环系统对 GS 腺苷酰化状态对谷氨酰胺浓度具有高度超敏反应,但当单独检查时,其复合 UTase/UR-PII 和 ATase-GS 循环显示出中等的谷氨酰胺敏感性。当三聚体 PII 蛋白被功能上为单体的三聚体 PII 的异三聚体形式取代时,双环系统的谷氨酰胺敏感性显著降低,并且在含有野生型或异三聚体 PII 的系统中,两个循环之间的耦合不同。因此,PII 的三聚体性质在双环系统的谷氨酰胺反应中起作用。因此,我们检查了不同尿苷酰化水平的 PII 制剂对 ATase 的单个 AT(腺苷酰化)和 AR(脱腺苷酰化)活性的调节。AR 活性以线性方式受 PII 尿苷酰化的影响,但部分修饰的野生型 PII 的激活作用远低于基于 PII 修饰程度的预期。部分修饰的野生型 PII 与 ATase 的结合也少于基于修饰亚基分数的预期。我们的结果表明,AT 活性仅由完全未修饰的 PII 结合和激活,并且这种设计在很大程度上负责双环系统的超敏性。
