Effect of α-domain substitution on the structure, property and function of human neuronal growth inhibitory factor

Human metallothionein-3 (hMT3), also named human neuronal growth inhibitory factor (hGIF), is attractive due to its distinct neuronal growth inhibitory activity, which is not shown by other human MT isoforms. It has been reported that the neuronal growth inhibitory activity arises from the N-terminal β-domain rather than its C-terminal α-domain. However, previous bioassay results have shown that the single β-domain is less effective at inhibiting the neuron growth than that in intact hMT3 on a molar basis, which suggests that the α-domain is indispensable to the neuronal growth inhibitory activity of hMT3. In order to confirm this assumption, we constructed two domain-hybrid mutants, the β(MT3)–β(MT3) mutant and the β(MT3)–α(MT1) mutant, and investigated their structural and metal binding properties by UV-vis spectroscopy, CD spectroscopy, pH titration, DTNB reaction, EDTA reaction, etc. The results showed that stability of the Cd₃S₉ cluster of the β(MT3)–β(MT3) mutant decreased significantly while the Cd₃S₉ cluster of the β(MT3)–α(MT1) mutant had a similar stability and solvent accessibility to that of hMT3. Interestingly, the bioassay results showed that the neuronal growth inhibitory activity of the β(MT3)–β(MT3) mutant decreased significantly, while the β(MT3)–α(MT1) mutant showed similar inhibitory activity to hMT3. Based on these results, we conclude that the α-domain is indispensable and plays an important role in modulating the stability of the metal cluster in the β-domain by domain–domain interactions, thus influencing the bioactivity of hMT3. Z.-C. Ding and Q. Zheng contributed equally to this work.     

Important roles of the conserved linker-KKS in human neuronal growth inhibitory factor

Metallothinein-3 (MT3), also named neuronal growth inhibitory factor (GIF), is attractive by its distinct neuronal growth inhibitory activity, which is not shared by other MT isoforms. The polypeptide chain of GIF is folded into two individual domains, which are connected by a highly conserved linker, KKS. In order to figure out the significance of the conserved segment, we constructed several mutants of human GIF (hGIF), including the K31/32A mutant, the K31/32E mutant and the KKS-SP mutant by site-directed mutagenesis. pH titration and DTNB reaction exhibited that all the three mutations made the β-domain lower in stability and looser. More significantly, change of KKS to SP also altered the general backbone conformation and metal–thiolate cluster geometry. Notably, bioassay results showed that the bioactivity of the K31/32A mutant and the K31/32E mutant decreased obviously, while the KKS-SP mutant lost inhibitory activity completely. Based on these results, we proposed that the KKS linker was a crucial factor in modulating the stability and the solvent accessibility of the Cd₃S₉ cluster in the β-domain through domain–domain interactions, thus was indispensable to the biological activity of hGIF.     

Mutation at Glu23 eliminates the neuron growth inhibitory activity of human metallothionein-3

Human metallothionein-3 (hMT3), first isolated and identified as a neuronal growth inhibitory factor (GIF), is a metalloprotein expressed predominantly in brain. However, until now, the exact mechanism of the bioactivity of hMT3 is still unknown. In order to study the influence of acid-base catalysis on S-nitrosylation of hMT3, we constructed the E23K mutant of hMT3. During the course of bioassay, we found out unexpectedly that mutation at E23 of hMT3 eliminates the neuronal growth inhibitory activity completely. To the best of our knowledge, it is the first report that other residues, besides the TCPCP motif, in the beta-domain can alter the bioactivity of hMT3. In order to figure out the causes for the loss of bioactivity of the E23K mutant, the biochemical properties were characterized by UV-vis spectroscopy, CD spectroscopy, pH titration, DTNB reaction, EDTA reaction, and SNOC reaction. All data demonstrated that stability of the metal-thiolate cluster and overall structure of the E23K mutant were not altered too much. However, the reaction of the E23K mutant with SNOC exhibited biphasic kinetics and the mutant protein released zinc ions much faster than hMT3 in the initial step, while hMT3 exhibited single kinetic process. The 2D [1H-15N] HSQC was also employed to characterize structural changes during the reaction of hMT3 with varying mounts of nitric oxide. It was shown that the resonance of Glu23 disappeared at a molar ratio of NO to protein of 4. Based on these results, we suggest that mutation at Glu23 may alter the NO metabolism and/or affect zinc homeostasis in brain, thus altering the neuronal growth inhibitory activity.     

G蛋白Rab3a协同神经生长抑制因子(GIF)抑制神经元的生长

为了研究G蛋白Rab3a与神经生长抑制因子 (growthinhibitoryfactor,GIF ,原称金属硫蛋白 3,MT 3)相互作用对神经元细胞生长的影响 ,以嗜铬细胞瘤株 (pheochromocytoma)PC1 2充当神经元模型 .将hMT 3(humanMT 3)和Rab3a基因分别克隆至真核表达载体pFlag CMV 2和pSV HA中 ,质粒共同转染PC1 2细胞 ,观察转染后细胞的生长状态 .以共转染pFlag CMV 2 hMT 1和pSV HA Rab3a的细胞组作为对照 ,验证hMT 3与Rab3a相互作用对PC1 2影响的特异性 .结果发现 ,共转染pFlag CMV 2 hMT 3和pSV HA Rab3a的PC1 2细胞生长明显受到抑制 ,细胞生长抑制率与GIF在脑提取物存在F的神经元生长抑制作用接近 ,但转染两基因中的任何单个基因以及共转染pFlag CMV 2 hMT 1和pSV HA Rab3a对PC1 2细胞生长无影响 .进一步构建重组表达质粒pGEX 4T 1 Rab3a和pGEX 4T 1 hMT 3,转化大肠杆菌BL2 1 ,经谷胱甘肽 Sepharose 4B亲和层析、凝血酶酶切和SephacrylS 1 0 0纯化 ,得到纯度 95 %以上的Rab3a和hMT 3蛋白 .体外细胞生物学活性检测表明 ,表达的Rab3a蛋白与重组hMT 3蛋白共培养PC1 2 ,对细胞的生长产生了明显的特异性协同抑制作用 ,抑制曲线与GIF在脑提取物存在下的神经元生长抑制曲线极为相似     

The effect of the EAAEAE insert on the property of human metallothionein-3

MT3 shows apparently different properties and function from MT1 even though they have 70% sequence homology. Possibly the two inserts, Thr5 and a negatively charged hexapeptide at position-55 in MT3, play important roles. A series of MT3 variants around the EAAEAE hexapeptide have been prepared by site-directed mutagenesis and their properties and reactivity towards pH, EDTA and DTNB have been studied. Our detailed studies revealed that the EAAEAE insert is essential to the property of MT3. It is the hexapeptide insert, to some extent, making the MT3 alpha-domain looser and lower stability of the metal-thiolate cluster, which could be accessed more easily.     

生长抑制因子(GIF)与G蛋白Rab3a直接相互作用

生长抑制因子(growth inhibitory factor, GIF), 又称金属硫蛋白-3, 为68个氨基酸组成的脑特异性金属硫蛋白, 具有广泛的生理功能; GIF可能与阿尔茨海默氏症(Alzheimer's)病理相关, 在Alzheimer's脑提取物存在下, 还对神经细胞具有特异的生长抑制活性.然而, 对其发挥生长抑制作用的分子机制并不清楚.运用酵母双杂交系统从人脑cDNA文库中筛选与GIF相互作用因子,从4.1×10⁶个人脑cDNA文库转化子中,首次筛选到Ras家族G蛋白Rab3a C端,包含87个氨基酸的片段能与GIF相互作用;用PCR自人胎盘总cDNA中获得包含完整Rab3a编码序列的cDNA;通过酵母双杂交实验表明,全长Rab3a蛋白亦能与GIF相互作用.免疫共沉淀和蛋白质印迹实验进一步验证了GIF与Rab3a在哺乳动物细胞中可以相互作用; 而且, Rab3a是以GTP结合形式(GTP-Rab3a)与GIF发生相互作用.     

Structural prediction of the beta-domain of metallothionein-3 by molecular dynamics simulation

The beta-domain of metallothionein-3 (MT3) has been reported to be crucial to the neuron growth inhibitory bioactivity. Little detailed three-dimensional structural information is available to present a reliable basis for elucidation on structure-property-function relationships of this unique protein by experimental techniques. So, molecular dynamics simulation is adopted to study the structure of beta-domain of MT3. In this article, a 3D structural model of beta-domain of MT3 was generated. The molecular simulations provide detailed protein structural information of MT3. As compared with MT2, we found a characteristic conformation formed in the fragment (residue 1-13) at the N-terminus of MT3 owing to the constraint induced by 5TCPCP9, in which Pro7 and Pro9 residues are on the same side of the protein, both facing outward and the two 5-member rings of prolines are arranged almost in parallel, while Thr5 is on the opposite side. Thr5 in MT3 is also found to make the first four residues relatively far from the fragment (residue 23-26) as compared with MT2. The simulated structure of beta-domain of MT3 is looser than that of MT2. The higher energy of MT3 than that of MT2 calculated supports these conclusions. Simulation on the four isomer arising from the cis- or trans-configuration of 6CPCP9 show that the trans-/trans-isomer is energetic favorable. The partially unfolding structure of beta-domain of MT3 is also simulated and the results show the influence of 6CPCP9 sequence on the correct folding of this domain. The correlations between the bioactivity of MT3 and the simulated structure as well as the folding of beta-domain of MT3 are discussed based on our simulation and previous results.     

神经生长抑制因子相互作用蛋白的分子克隆、鉴定及其生物学特性

为了探讨神经生长抑制因子(Neuronal growth inhibitory factor,GIF)与Alzheimer’s病(Alzheimer’s disease,AD)的关系,将GIF的cDNA全基因克隆到载体pHyblex中,运用酵母双杂交系统从Alzheimer’s病人脑cDNA文库中筛选出与GIF相互作用蛋白的cDNA克隆。免疫共沉淀和蛋白质印迹实验进一步验证了该蛋白在体内与GIF相互作用的特异性。克隆并鉴定了其中1个与GIF特异性结合的蛋白,与人细胞核dUTP焦磷酸酶(DUT)同源。进一步构建了重组表达质粒pGEX-4T-1／DUT,转化大肠杆菌BL21,经谷胱甘肽-Sepharose 4B亲和层析、凝血酶酶切和Sephacryl S100纯化,得到纯度95％以上的dUTPase蛋白。体外生物学活性检测表明,表达的dUTPase蛋白可以与GIF共同作用嗜铬细胞瘤株(pheochromocytoma)PC12,对细胞的生长产生抑制作用。     

The Properties of the Metal–Thiolate Clusters in Recombinant Mouse Metallothionein-4

Metallothioneins (MTs) are metal-binding proteins with low molecular weight and conservative cysteine residues. Metallothionein-4 (MT-4), one of MT isoforms, is first reported to be distributed in a tissue-specific manner, mainly in stratified squamous epithelia. Here, we compare the properties of metal–thiolate clusters in MT-4 to those in MT-1 and MT-3, including the stabilities toward both pH change and EDTA, as well as the exposure of thiolates to solvent. The metal–thiolate clusters in MT-3 show different property and activity to the reactions compared with MT-4 and MT-1. The structure of metal–thiolate clusters in MT-4 is similar to that of MT-1 from the UV and CD spectra. During pH titration and DTNB reaction, MT-4 and MT-1 exhibit comparable behavior. But while reacting with EDTA, the metal–thiolate clusters in MT-4 are more stable than those of MT-1. We suppose the negative charge of the β-domain of MT-4 prevents the EDTA attack to MT-4.     

Activity of human dihydrolipoamide dehydrogenase is reduced by mutation at threonine-44 of FAD-binding region to valine

Dihydrolipoamide dehydrogenase (E3) is a member of the pyridine nucleotide-disulfide oxidoreductase family. Thr residues are highly conserved. They are at the active site disulfide-bond regions of most E3s and other oxidoreductases. The crystal structure of Azotobacter vinelandii E3 suggests that the hydroxyl group of Thr that are involved in the FAD binding interact with the adenosine phosphate of FAD. However, several prokaryotic E3s have Val instead of Thr. To investigate the meaning and importance of the Thr conservation in many E3s, the corresponding residue, Thr-44, in human E3 was substituted to Val by site-directed mutagenesis. The mutant's E3 activity showed about a 2.2-fold decrease. Its UV-visible and fluorescence spectra indicated that the mutant might have a slightly different microenvironment at the FAD-binding region.     

Growth modulation of human tumor cells by a growth-inhibiting activity derived from tumorigenic V79 chinese hamster cells

Summary A growth-inhibiting activity was identified in supernatants of the neoplastic V79 Chinese hamster cell line based on its ability to inhibit the proliferation of the same cell line. The partially purified activity, provisionally termed “growth inhibiting factor” (GIF) activity, inhibited the growth of a wide variety of human tumor cells, but not various normal human fibroblasts. This species-nonspecific activity was reversible, saturable, and highly potent in tumorigenic cell lines, and was noted in both monolayer culture and in soft agar. The inhibitory activity CIF was also exhibited in a chemically defined serum-free medium supplemented with insulin and transferrin. GIF activity was stable to acid, heat, trypsin, and dithiothreitol but sensitive to alpha-chymotrypsin. The pattern of growth modulation by GIF on V79 cells was apparently different from those exhibited by bifunctional peptides such as transforming growth factor-beta, tumor necrosis factor-alpha, and interleukin-1-alpha. In addition, GIF activity cannot be ascribed to these cytokines based on the physicochemical and immunologic properties. Although GIF has yet to be purified to homogeneity, these data suggest that GIF might be a novel growth regulator which has a critical role in regulating growth of V79 cells. The growth modulation of tumor cells by this tumor-derived growth inhibiting activity suggested the presence of an autocrine growth regulatory mechanism even in tumor cells.     

Growth inhibitory factor prevents neurite extension and the death of cortical neurons caused by high oxygen exposure through hydroxyl radical scavenging

Growth inhibitory factor (GIF), a brain-specific member of the metallothionein family (MT-III), has been characterized as a inhibitory substance for neurotrophic factors in Alzheimer's disease brains. However, the function of GIF, other than the inhibition of neurotrophic factors, remains unknown. We demonstrate here that exogenous GIF prevents neurite extension of cortical neurons in the early period of differentiation and the death of differentiated neurons caused by high oxygen exposure. Down-regulation of GIF in cortical neurons with antisense S-oligonucleotides promoted neuronal death under high oxygen conditions. ESR spin-trapping studies demonstrated that GIF at 2-6 microm scavenged hydroxyl radicals generated by a Fenton-type reaction or the photolysis of hydrogen peroxide much more effectively than the same concentration of metallothionein I+II. GIF did not scavenge either superoxide produced by the xanthine/xanthine oxidase reaction or NO generated from 1-hydroxy-2-oxo-3-(N-methyl-3-aminopropyl)-3-methyl-1-triazene. Moreover, GIF at 40-80 microm inhibited tyrosine nitration by peroxynitrite as efficiently as metallothionein I+II at the same concentration. These results indicate that GIF prevents neurite extension of neurons in the early period of differentiation and supports the survival of differentiated neurons by scavenging hydroxyl radicals.     

人神经生长抑制因子β结构域的高效表达及性质研究

神经生长抑制因子（ Ｇ Ｉ Ｆ）是一种特异存在于哺乳动物脑中的金属硫蛋白（ｍ ｅｔａｌｌｏｔｈｉｏｎｅｉｎ, Ｍ Ｔ）类似物,又称 Ｍ Ｔ Ⅲ．它与 Ｍ Ｔ 有相同的结合 Ｚｎ（Ⅱ）, Ｃｄ（Ⅱ）, Ｃｕ（Ⅰ）等金属的能力,但与 Ｍ Ｔ 不同的是它能够抑制神经细胞的生长,并发现在患 Ａｌｚｈｅｉｍ ｅｒ ｄｉｓｅａｓｅ（ Ａ Ｄ 症）病人的大脑中 Ｇ Ｉ Ｆ蛋白量和ｍ Ｒ Ｎ Ａ 的量均显著下降,研究证明 Ｇ Ｉ Ｆ对神经细胞的抑制活性主要存在于其 β结构域中．为进一步研究 β结构域结构和功能的关系,将 β结构域的 ｃ Ｄ Ｎ Ａ 克隆入融合表达载体ｐ Ｇ Ｅ Ｘ ４ Ｔ １ 中, Ｉ Ｐ Ｔ Ｇ 诱导并高效表达了 β结构域蛋白,通过氨基酸组成和质谱的测定,证明得到了目的蛋白．利用金属重组的方法,分别得到了结合 Ｃｄ 和 Ｚｎ 的 Ｇ Ｉ Ｆ 的 β结构域,并测定了其巯基和金属含量对蛋白量的比值,证明所得 Ｇ Ｉ Ｆ β与 Ｍ Ｔ β在结合金属能力上十分相似．用紫外光谱学的研究表明, Ｃｄ Ｍ Ｔ 的 β结构域在２５０ ｎｍ 处比 Ｃｄ Ｇ Ｉ Ｆ 的 β结构域有一明显肩峰,从而表明二者的金属—巯基结合簇的结构有明显不同,而这种结构上的差异有可能导致二者在功能上的不同．     

Functional analysis of Survivin in spindle assembly in Xenopus egg extracts

Survivin is a member of the inhibitor of apoptosis (IAP) protein family that serves critical roles in mitosis and cytokinesis. Many studies have suggested Survivin's involvement in spindle regulation, but direct biochemical evidence for this has been lacking. Using the cell-free system of Xenopus egg extracts, we tested whether Survivin was necessary for the assembly of metaphase spindles. Removal or inhibition of Xenopus Survivin causes the disruption in the formation of metaphase spindles. In particular, we observe the generation of microtubule (MT) asters or poorly formed shortened spindle structures. In the latter phenotype the spindle structures display a decrease pole-to-pole length and a reduction of MTs around the chromatin indicating that Survivin may promote the stabilization of MT-chromatin interactions. In addition, function analysis of Survivin's conserved phosphorylation site Thr34 (Thr43 in Xenopus) and tubulin-binding domain was also assessed in regulating spindle assembly. Treatment of Xenopus egg extracts with a recombinant Survivin mutant that contained an alanine residue substitution at Thr43 (SURT43A mutant) or that was missing the C-terminal tubulin-binding domain (SURCL mutant) produced an increased frequency of MT asters and shorten abnormal spindle structures in Xenopus egg extracts. Interestingly, a phosphomimetic mutation made at residue Thr43 of Survivin (SURT43E mutant) generated a high frequency of MT asters implying that premature 'activation' of Survivin may interfere with an early stage of spindle assembly. Taken together, we propose that Survivin is a necessary component of the mitotic spindle and its phosphorylation at residue Thr43 is important for Survivin function in spindle assembly.     

Incorporation of a glycine within the conserved TCPCP motif of human neuronal growth inhibitory factor significantly reduces its bioactivity

It has been reported that the ⁶CPCP⁹ motif near the N-terminus is pivotal to the inhibitory activity of human neuronal growth inhibitory factor (hGIF). In order to better understand the biological significance of this region on the structure, property and function of hGIF, we introduced a highly flexible residue, Gly, either in front of the ⁶CPCP⁹ motif (the IG6 mutant, TGCPCP) or in the middle of it (the IG8 mutant, TCPGCP) and investigated their structural and metal binding properties in detail. The results showed that the overall structure and the stability of the metal-thiolate clusters of the two mutants were comparable to that of hGIF. However, the bioassay results showed that the bioactivity of the IG6 mutant decreased significantly, while the bioactivity of the IG8 mutant was almost abolished. Molecular dynamics simulation results showed that the backbone of the IG6 mutant exhibited high similarity to that of hGIF, and the two prolines could still induce structural constraints on the ⁶CPCP⁹ tetrapeptide and form a similar conformation with that of hGIF, however, the conformation of the first five amino acid residues in the N-terminus was quite different. In hGIF, the five residues are twisted and form a restricted conformation, while in the IG6 mutant this peptide extends more naturally and smoothly, which is similar to that of MT2. As to the IG8 mutant, the Gly insertion broke the ⁶CPCP⁹ motif, thus probably abolishing the interactions with other molecules and eliminating its inhibitory activity. Based on these results, we suggested that although the structure adopted by the ⁶CPCP⁹ motif is the determinant factor of the inhibitory bioactivity of hGIF, other residues within the N-terminal fragment (residue 1-13) may also influence the peptide conformation and contribute to the protein’s bioactivity.     

Isolation of GIF from porcine brain and studies of its zinc transfer kinetics with apo-carbonic anhydrase

Neuronal growth inhibitory factor (GIF) of porcine brain, was isolated and purified by a similar procedure which was used on the isolation of human and bovine GIF. The native porcine protein with stoichiometry of 4Cu⁺, 3Zn²⁺ was obtained for the first time. The kinetics of zinc transfer from Cu₄Zn₃MT-3 to apo-carbonic anhydrase were studied, and zinc transfer rate constants and thermodynamic parameters were obtained. It is found that like other MTs, porcine Cu₄Zn₃MT-3 can also transfer its zinc atom to apoCA, even much easier than other MTs. A possible association mechanism has been proposed, the formation of Cu₄Zn₃MT3-apoCA complex may be the rate-determining step. The obtained data indicate besides its neuronal growth inhibitory function, GIF might play a role in cellular Zn homeostasis in brain.     

A monoclonal antibody raised to lipomodulin recognizes T suppressor factors in two independent hapten-specific suppressor networks

Five different Ag-binding suppressor factors from two types of hapten-specific Ts cell hybridomas (TsF1 inducer and TsF3 effector factors) were bound by an anti-lipomodulin mAb (141-B9), that crossreacts with rodent glycosylation inhibition factor (GIF). The Ag-specific suppressor activity in these hybridoma supernatants was bound by anti-lipomodulin columns and could be recovered by elution at acid pH. Additional evidence for the expression of lipomodulin/GIF activity on these TsF molecules was demonstrated by the ability of the eluted fractions to inhibit the glycosylation of IgE-binding peptides during their biosynthesis. The same biologic activity is associated with GIF and lipomodulin. The relationship between TsF and lipomodulin/GIF was confirmed in a serologic assay, which showed that TsF1 and TsF3 molecules, whether purified over Ag, anti-IJ or anti-TsF columns, are recognized by the mAb. 141-B9. The combined results indicate that Ag-binding Ts factors share a common antigenic determinant with phospholipase inhibitory proteins such as lipomodulin and GIF. In addition, the demonstration of glycosylation regulatory activity carried on these TsF molecules suggests a possible mode for their bioactivity.     

Studies on the epitope of neuronal growth inhibitory factor (GIF) with using of the specific antibody

Human neuronal growth inhibitory factor (GIF), a metalloprotein classified as metallothionein-3, is specifically expressed in mammal central nervous system (CNS). In these Studies the specific antibody to human GIF was prepared and used to search the epitope of human GIF by enzyme-linked immunosorbent assay (ELISA) and sequence comparison. The result of ELISA showed the epitope of human GIF may locate on a octapeptide (EAAEAEAE) in the alpha-domain of human GIF, and the result of nerve cell culture indicated that the biological activity of GIF may be affected by the specific antibody.     

Probing the role of threonine and serine residues of E. coli asparaginase II by site-specific mutagenesis.

Site-specific mutagenesis has been used to probe amino acid residues proposed to be critical in catalysis by Escherichia coli asparaginase II. Thr12 is conserved in all known asparaginases. The catalytic constant of a T12A mutant towards L-aspartic acid beta-hydroxamate was reduced to 0.04% of wild type activity, while its Km and stability against urea denaturation were unchanged. The mutant enzyme T12S exhibited almost normal activity but altered substrate specificity. Replacement of Thr119 with Ala led to a 90% decrease of activity without markedly affecting substrate binding. The mutant enzyme S122A showed normal catalytic function but impaired stability in urea solutions. These data indicate that the hydroxyl group of Thr12 is directly involved in catalysis, probably by favorably interacting with a transition state or intermediate. By contrast, Thr119 and Ser122, both putative target sites of the inactivator DONV, are functionally less important.     

Dominant inhibitory mutations in the Mg(2+)-binding site of RasH prevent its activation by GTP.

We have previously demonstrated that substitution of Asn for Ser at position 17 of RasH yields a dominant inhibitory protein whose expression in cells interferes with endogenous Ras function (L. A. Feig, and G. M. Cooper, Mol. Cell. Biol. 8:3235-3243, 1988). Subsequent structural studies have shown that the hydroxyl group of Ser-17 contributes to the binding of Mg2+ associated with bound nucleotide. In this report, we show that more subtle amino acid substitutions at this site that would be expected to interfere with complexing Mg2+, such as Cys or Ala, also generated dominant inhibitory mutants. In contrast, a Thr substitution that conserves a reactive hydroxyl group maintained normal Ras function. These results argue that the defect responsible for the inhibitory activity is improper coordination of Mg2+. Preferential affinity for GDP, observed in the original Asn-17 mutant, was found exclusively in inhibitory mutants. However, this binding specificity did not completely block the mutant proteins from binding GTP in vivo since introduction of the autophosphorylation site, Thr-59, in 17N Ras resulted in the phosphorylation of the double mutant in cells. Furthermore, inhibitory mutants failed to activate a model downstream target, yeast adenylate cyclase, even when bound to GTP. Thus, the consequence of improper complexing of Mg2+ was to lock the protein in a constitutively inactive state. A model is presented to explain how these properties could cause the mutant protein to inhibit the activation of endogenous Ras by competing for a guanine nucleotide-releasing factor.