Freije J M, Blay P, MacDonald N J, Manrow R E, Steeg P S
Women's Cancers Section, Laboratory of Pathology, Division of Clinical Sciences, NCI, National Institutes of Health, Bethesda, Maryland 20892, USA.
J Biol Chem. 1997 Feb 28;272(9):5525-32. doi: 10.1074/jbc.272.9.5525.
We previously compared the structure and motility suppressive capacity of nm23-H1 by transfection of wild type and site-directed mutant forms into breast carcinoma cells. Wild type nm23-H1 and an nm23-H1(S44A) (serine 44 to alanine) mutant suppressed motility, whereas the nm23-H1(P96S), nm23-H1(S120G), and to a lesser extent, nm23-H1(S120A) mutant forms failed to do so. In the present study wild type and mutant recombinant Nm23-H1 proteins have been produced, purified, and assayed for phosphorylation and phosphotransfer activities. We report the first association of Nm23-H1 mutations lacking motility suppressive capacity with decreased in vitro activity in histidine-dependent protein phosphotransferase assays. Nm23-H1(P96S), a Drosophila developmental mutation homolog, exhibited normal autophosphorylation and nucleoside-diphosphate kinase (NDPK) characteristics but deficient phosphotransfer activity in three histidine protein kinase assays, using succinic thiokinase, Nm23-H2, and GST-Nm23-H1 as substrates. Nm23-H1(S120G), found in advanced human neuroblastomas, exhibited deficient activity in several histidine-dependent protein phosphotransfer reactions, including histidine autophosphorylation, downstream phosphorylation on serines, and slightly decreased histidine protein kinase activity; significant NDPK activity was observed. The Nm23-H1(S120A) mutant was deficient in only histidine-dependent serine autophosphorylation. Nm23-H1 and Nm23-H1(S44A) exhibited normal activity in all assays conducted. Based on this correlation, we hypothesize that a histidine-dependent protein phosphotransfer activity of Nm23-H1 may be responsible for its biological suppressive effects.
我们之前通过将野生型和定点突变型nm23-H1转染至乳腺癌细胞,比较了nm23-H1的结构和运动抑制能力。野生型nm23-H1和nm23-H1(S44A)(丝氨酸44突变为丙氨酸)突变体抑制了运动,而nm23-H1(P96S)、nm23-H1(S120G)以及程度较轻的nm23-H1(S120A)突变体则未能抑制运动。在本研究中,已制备、纯化了野生型和突变型重组Nm23-H1蛋白,并对其磷酸化和磷酸转移活性进行了测定。我们首次报道了缺乏运动抑制能力的Nm23-H1突变与组氨酸依赖性蛋白磷酸转移酶测定中体外活性降低之间的关联。Nm23-H1(P96S)是果蝇发育突变同源物,在使用琥珀酸硫激酶、Nm23-H2和GST-Nm23-H1作为底物的三种组氨酸蛋白激酶测定中,表现出正常的自磷酸化和核苷二磷酸激酶(NDPK)特性,但磷酸转移活性不足。在晚期人类神经母细胞瘤中发现的Nm23-H1(S120G)在几种组氨酸依赖性蛋白磷酸转移反应中表现出活性不足,包括组氨酸自磷酸化、丝氨酸下游磷酸化以及组氨酸蛋白激酶活性略有降低;观察到显著的NDPK活性。Nm23-H1(S120A)突变体仅在组氨酸依赖性丝氨酸自磷酸化方面存在缺陷。Nm23-H1和Nm23-H1(S44A)在所有进行的测定中均表现出正常活性。基于这种相关性,我们推测Nm23-H1的组氨酸依赖性蛋白磷酸转移活性可能是其生物学抑制作用的原因。
