延伸因子2及二磷酸腺苷核糖基化延伸因子2对转位的作用。
Effect of elongation factor 2 and of adenosine diphosphate-ribosylated elongation factor 2 on translocation.
作者信息
Montanaro L, Sperti S, Testoni G, Mattioli A
出版信息
Biochem J. 1976 Apr 15;156(1):15-23. doi: 10.1042/bj1560015.
Abstract
- The effect of elongation factor 2 (EF 2) and of adenosine diphosphate-ribosylated elongation factor 2 (ADP-ribosyl-EF 2) on the shift of endogenous peptidyl-tRNA from the A to the P site of rat liver ribosomes (measured by the peptidyl-puromycin reaction) and on the release of deacylated tRNA (measured by aminoacylation) was investigated. 2. Limiting amounts of EF2, pre-bound or added to ribosomes, catalyse the shift of peptidyl-tRNA in the presence of GPT; when the enzyme is added in substrate amounts GMP-P(CH2)P [guanosine (beta, gamma-methylene)triphosphate] can partially replace GTP. ADP-ribosyl-EF 2 has no effect on the shift of peptidyl-tRNA when present in catalytic amounts, but becomes almost as effective as EF 2 when added in substrate amounts together with GTP; GMP-P(CH2)P cannot replace GTP. 3. The release of deacylated tRNA is induced only by substrate amounts of added EF 2 and also occurs in the absence of guanine nucleotides. In this reaction ADP-ribosyl-EF 2 is only 25% as effective as EF 2 in the absence of added nucleotide, but becomes 60-80% as effective in the presence of GTP or GMP-P(CH2)P. 4. The results obtained on protein-synthesizing systems are consistent with the hypothesis that ADP-ribosyl-EF 2 can operate a single round of translocation followed by binding of aminoacyl-tRNA and peptide-bond formation. 5. From the data obtained with the native enzyme it is concluded that the two moments of translocation require different conditions of interaction of EF 2 with ribosomes; it is suggested that the shift of peptidyl-tRNA is catalysed by EF 2 pre-bound to ribosomes, and that the release of tRNA is induced by a second molecule of interacting EF 2. The hydrolysis of GTP would be required for the release of pre-bound EF 2 from ribosomes. 5. The inhibition of the utilization of limiting amounts of EF 2 on ADP-ribosylation is very likely the consequence of a concomitant decrease in the rate of association and dissociation of the enzyme from ribosomes.
摘要
- 研究了延伸因子2(EF 2)和二磷酸腺苷核糖基化延伸因子2(ADP - 核糖基 - EF 2)对大鼠肝脏核糖体上内源性肽基 - tRNA从A位点转移至P位点(通过肽基 - 嘌呤霉素反应测定)以及对脱酰基tRNA释放(通过氨酰化测定)的影响。2. 有限量的预先结合或添加到核糖体上的EF2,在GPT存在下催化肽基 - tRNA的转移;当以底物量添加该酶时,鸟苷(β,γ - 亚甲基)三磷酸(GMP - P(CH2)P)可部分替代GTP。催化量的ADP - 核糖基 - EF 2对肽基 - tRNA的转移无影响,但与GTP一起以底物量添加时,其效果几乎与EF 2相同;GMP - P(CH2)P不能替代GTP。3. 脱酰基tRNA的释放仅由添加的底物量的EF 2诱导,且在不存在鸟嘌呤核苷酸时也会发生。在该反应中,在未添加核苷酸的情况下,ADP - 核糖基 - EF 2的效果仅为EF 2的25%,但在GTP或GMP - P(CH2)P存在时,其效果可达60 - 80%。4. 在蛋白质合成系统上获得的结果与以下假设一致:ADP - 核糖基 - EF 2可进行一轮转位,随后结合氨酰 - tRNA并形成肽键。5. 根据用天然酶获得的数据得出结论,转位的两个阶段需要EF 2与核糖体相互作用的不同条件;建议肽基 - tRNA的转移由预先结合到核糖体上的EF 2催化,而tRNA的释放由相互作用的第二个EF 2分子诱导。从核糖体释放预先结合的EF 2需要GTP的水解。5. ADP - 核糖基化对有限量EF 2利用的抑制很可能是该酶与核糖体结合和解离速率同时降低的结果。
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