31P NMR revealed that the complex of p21ras with the GTP analog GppNHp.Mg2+ exists in two conformational states, states 1 and 2. In wild-type p21ras the equilibrium constant K1(12) between the two states is 1.09. The population of these states is different for various mutants but independent of temperature. The activation enthalpy delta H ++ and activation entropy delta S ++ for the conformational transitions were determined by full-exchange matrix analysis for wild-type p21ras and p21ras(S65P). For the wild-type protein one obtains delta H ++ = 89 +/- 2 kJ mol-1 and delta S ++ = 102 +/- 20 J mol-1 K-1 and for the mutant protein delta H ++ = 93 +/- 7 kJ mol-1 and delta S ++ = 138 +/- 30 J mol-1 K-1. The study of various p21ras mutants suggests that the two states correspond to different conformations of loop L2, with Tyr-32 in two different positions relative to the bound nucleotide. High-field EPR at 95 GHz suggest that the observed conformational transition does not directly influence the coordination sphere of the protein-bound metal ion. The influence of this transition on loop L4 was studied by 1H NMR with mutants E62H and E63H. There was no indication that L4 takes part in the transition described in L2, although a reversible conformational change could be induced by decreasing the pH value. The exchange between the two states is slow on the NMR time scale (< 10 s-1): at approximately pH 5 the population of the two states is equal. The interaction of p21ras-triphosphate complexes with the Ras-binding domain (RBD) of the effector protein c-Raf-1, Raf-RBD, and with the GTPase activating protein GAP was studied by 31P NMR spectroscopy. In complex with Raf-RBD the second conformation of p21ras (state 2) is stabilized. In this conformation Tyr-32 is located in close proximity to the phosphate groups of the nucleotide, and the beta-phosphate resonance is shifted upfield by 0.7 ppm. Spectra obtained in the presence of GAP suggest that in the ground state GAP does not interact directly with the nucleotide bound to p21ras and does not induce larger conformational changes in the neighborhood of the nucleotide. The experimental data are consistent with a picture where GAP accelerates the exchange process between the two states and simultaneously increases the population of state 1 at higher temperature.
The guanine nucleotide-binding protein Ras occurs in solution in two different states, state 1 and state 2, when the GTP analogue GppNHp is bound to the active center as detected by (31)P NMR spectroscopy. Here we show that Ras(wt).Mg(2+).GppCH(2)p also exists in two conformational states in dynamic equilibrium. The activation enthalpy DeltaH(++)(12) and the activation entropy DeltaS(++)(12) for the transition from state 1 to state 2 are 70 kJ mol(-1) and 102 J mol(-1) K(-1), within the limits of error identical to those determined for the Ras(wt).Mg(2+).GppNHp complex. The same is true for the equilibrium constants K(12) = [2]/[1] of 2.0 and the corresponding DeltaG(12) of -1.7 kJ mol(-1) at 278 K. This excludes a suggested specific effect of the NH group of GppNHp on the equilibrium. The assignment of the phosphorus resonance lines of the bound analogues has been done by two-dimensional (31)P-(31)P NOESY experiments which lead to a correction of the already reported assignments of bound GppNHp. Mutation of Thr35 in Ras.Mg(2+).GppCH(2)p to serine leads to a shift of the conformational equilibrium toward state 1. Interaction of the Ras binding domain (RBD) of Raf kinase or RalGDS with Ras(wt) or Ras(T35S) shifts the equilibrium completely to state 2. The (31)P NMR experiments suggest that, besides the type of the side chain of residue 35, a main contribution to the conformational equilibrium in Ras complexes with GTP and GTP analogues is the effective acidity of the gamma-phosphate group of the bound nucleotide. A reaction scheme for the Ras-effector interaction is presented which includes the existence of two conformations of the effector loop and a weak binding state.
The active GTP-bound form of p21ras is converted to the biologically inactive GDP-bound form by enzymatic hydrolysis and this function serves to regulate the wild-type ras protein. The side chain of the amino acid at position 61 may play a key role in this hydrolysis of GTP by p21. Experimental studies that define properties of the Q61E mutant of p21H-ras are presented along with supporting molecular dynamics simulations. We find that under saturating concentrations of GTP the Q61E mutant of p21H-ras has a 20-fold greater rate of intrinsic hydrolysis (kcat = 0.57 min-1) than the wild type. The affinity of the Q61E variant for GTP (Kd = 115 microM) is much lower than that of the wild type. GTPase activating protein does not activate the variant. From molecular dynamics simulations, we find that both the wild type and Q61E mutant have the residue 61 side chain in transient contact with a water molecule that is well-positioned for hydrolytic attack on the gamma phosphate. Thr-35 also is found to form a transient hydrogen bond with this critical water. These elements may define the catalytic complex for hydrolysis of the GTP [Pai et al. (1990) EMBO J. 9, 2351]. Similarly, the G12P mutant, which also has an intrinsic hydrolysis rate similar to the wild type, is found to form the same complex in simulation. In contrast, molecular dynamics analysis of the mutants G12R, G12V, and Q61L, which have much lower intrinsic rates than the wild-type p21, do not show this complex.(ABSTRACT TRUNCATED AT 250 WORDS)
Abstract. Little is known about the signal transduction mechanisms involved in the response to neurotrophins and other neurotrophic factors in neurons, beyond the activation of the tyrosine kinase activity of the neurotrophin receptors belonging to the trk family. We have previously shown that the introduction of the oncogene product ras p21 into the cytoplasm of chick embryonic neurons can reproduce the survival and neurite-outgrowth promoting effects of the neurotrophins nerve growth factor (NGF) and brain-derived neurotrophic factor (BDNF), and of ciliary neurotrophic factor (CNTF). To assess the potential signaltransducing role of endogenous ras p21, we introduced function-blocking anti-ras antibodies or their Fab fragments into cultured chick embryonic neurons. The BDNF-induced neurite outgrowth in El2 nodose ganglion neurons was reduced to below control levels, and the NGF-induced survival of E9 dorsal root ganglion (DRG) neurons was inhibited in a specific and dose-dependent fashion. Both effects could be reversed by saturating the epitope-binding sites with biologically inactive ras p21 before microinjection. Surprisingly, ras p21 did not promote the survival of NGFo dependent El2 chick sympathetic neurons, and the NGF-induced survival in these cells was not inhibited by the Fab-fragments. The survival effect of CNTF on ras-responsive ciliary neurons could not be blocked by anti-ras Fab fragments. These results indicate an involvement of ras p21 in the signal transduction of neurotrophic factors in sensory, but not sympathetic or ciliary neurons, pointing to the existence of different signaling pathways not only in CNTF-responsive, but also in neurotrophin-responsive neuronal populations.
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