Kandror O, Sherman M, Moerschell R, Goldberg A L
Department of Cell Biology, Harvard Medical School, Boston, Massachusetts 02115, USA.
J Biol Chem. 1997 Jan 17;272(3):1730-4. doi: 10.1074/jbc.272.3.1730.
Trigger factor (TF) is a putative molecular chaperone recently found to function together with GroEL in the degradation of the fusion protein, CRAG. TF overproduction enhanced the ability of GroEL to form complexes with CRAG, as well as fetuin or histone. To define further this effect on GroEL binding, affinity columns containing a variety of denatured proteins were used. When cell extracts were applied onto a fetuin column, both TF and GroEL bound but not GroES. Upon ATP addition, TF and GroEL were eluted together and remained tightly associated (even in presence of GroES) in complexes containing one TF per GroEL 14-mer. Overproduction of TF enhanced the capacity of GroEL to bind to many denatured proteins. Moreover, GroEL-TF complexes isolated from such cells showed much greater binding capacity than GroEL from TF-deficient cells. Furthermore, the addition of pure TF to pure GroEL also enhanced markedly its binding capacity. The affinity of GroEL for CRAG also rises during heat shock due to GroEL phosphorylation. TF expression, however, did not promote GroEL phosphorylation. Moreover, heat shock and TF overproduction affected GroEL binding to other denatured polypeptides in distinct ways; only TF promoted binding to certain polypeptides, whereas only phosphorylation increased binding to others. Thus, association with TF and phosphorylation are independent regulators of GroEL function. This enhanced affinity of TF-GroEL complexes for unfolded proteins may also be important in protein folding, because TF has prolyl isomerase activity and associates with nascent polypeptides.
触发因子(TF)是一种推测的分子伴侣,最近发现它与GroEL共同作用于融合蛋白CRAG的降解过程。TF的过量表达增强了GroEL与CRAG以及胎球蛋白或组蛋白形成复合物的能力。为了进一步确定这种对GroEL结合的影响,使用了含有多种变性蛋白的亲和柱。当将细胞提取物应用于胎球蛋白柱时,TF和GroEL都能结合,但GroES不能。加入ATP后,TF和GroEL一起被洗脱,并在每个GroEL十四聚体含有一个TF的复合物中紧密结合(即使存在GroES)。TF的过量表达增强了GroEL与许多变性蛋白结合的能力。此外,从此类细胞中分离出的GroEL-TF复合物比来自TF缺陷细胞的GroEL显示出更大的结合能力。此外,向纯GroEL中加入纯TF也显著增强了其结合能力。由于GroEL磷酸化,在热休克期间GroEL对CRAG的亲和力也会增加。然而,TF的表达并没有促进GroEL的磷酸化。此外,热休克和TF过量表达以不同方式影响GroEL与其他变性多肽的结合;只有TF促进与某些多肽的结合,而只有磷酸化增加与其他多肽的结合。因此,与TF的结合和磷酸化是GroEL功能的独立调节因子。TF-GroEL复合物对未折叠蛋白增强的亲和力在蛋白质折叠中可能也很重要,因为TF具有脯氨酰异构酶活性并与新生多肽结合。
