Kang H, Sayner S L, Gross K L, Russell L C, Chinkers M
Department of Pharmacology, University of South Alabama, Mobile, Alabama 36688, USA.
Biochemistry. 2001 Sep 4;40(35):10485-90. doi: 10.1021/bi010999i.
Protein phosphatase 5 (PP5) exhibits low basal activity due to the autoinhibitory properties of its N-terminal and C-terminal domains but can be activated approximately 40-fold in vitro by polyunsaturated fatty acids. To identify residues involved in regulating PP5 activity, we performed scanning mutagenesis of its N-terminal tetratricopeptide repeat (TPR) domain and deletion mutagenesis of its C-terminal domain. Mutating residues in a groove of the TPR domain that binds to heat shock protein 90 had no effect on basal phosphatase activity. Mutation of Glu-76, however, whose side chain projects away from this groove, resulted in a 10-fold elevation of basal activity without affecting arachidonic acid-stimulated activity. Thus, the interface of the TPR domain involved in PP5 autoinhibition appears to be different from that involved in heat shock protein 90 binding. We also observed a 10-fold elevation of basal phosphatase activity upon removing the C-terminal 13 amino acids of PP5, with a concomitant 50% decrease in arachidonic acid-stimulated activity. These two effects were accounted for by two distinct amino acid deletions: deleting the four C-terminal residues (496-499) of PP5 had no effect on its activity, but removing Gln-495 elevated basal activity 10-fold. Removal of a further three amino acids had no additional effect, but deleting Asn-491 resulted in a 50% reduction in arachidonic acid-stimulated activity. Thus, Glu-76 in the TPR domain and Gln-495 at the C-terminus were implicated in maintaining the low basal activity of PP5. While the TPR domain alone has been thought to mediate fatty acid activation of PP5, our data suggest that Asn-491, near its C-terminus, may also be involved in this process.
蛋白磷酸酶5(PP5)由于其N端和C端结构域的自抑制特性而表现出较低的基础活性,但在体外可被多不饱和脂肪酸激活约40倍。为了鉴定参与调节PP5活性的残基,我们对其N端四肽重复序列(TPR)结构域进行了扫描诱变,并对其C端结构域进行了缺失诱变。在TPR结构域中与热休克蛋白90结合的凹槽中的残基发生突变,对基础磷酸酶活性没有影响。然而,Glu-76的突变,其侧链从该凹槽伸出,导致基础活性提高了10倍,而不影响花生四烯酸刺激的活性。因此,参与PP5自抑制的TPR结构域界面似乎与参与热休克蛋白90结合的界面不同。我们还观察到,去除PP5的C端13个氨基酸后,基础磷酸酶活性提高了10倍,同时花生四烯酸刺激的活性降低了50%。这两种效应由两个不同的氨基酸缺失引起:删除PP5的四个C端残基(496-499)对其活性没有影响,但去除Gln-495使基础活性提高了10倍。再去除另外三个氨基酸没有额外影响,但删除Asn-491导致花生四烯酸刺激的活性降低了50%。因此,TPR结构域中的Glu-76和C端的Gln-495与维持PP5的低基础活性有关。虽然一直认为单独的TPR结构域介导PP5的脂肪酸激活,但我们的数据表明,靠近其C端的Asn-491也可能参与这一过程。
