Role of the histone domain in the autoinhibition and activation of the Ras activator Son of Sevenless.

Membrane-bound Ras is activated by translocation of the Son of Sevenless (SOS) protein to the plasma membrane. SOS is inactive unless Ras is bound to an allosteric site on SOS, and the Dbl homology (DH) and Pleckstrin homology (PH) domains of SOS (the DH-PH unit) block allosteric Ras binding. We showed previously that the activity of SOS at the membrane increases with the density of PIP(2) and the local concentration of Ras-GTP, which synergize to release the DH-PH unit. Here we present a new crystal structure of SOS that contains the N-terminal histone domain in addition to the DH-PH unit and the catalytic unit (SOS(HDFC), residues 1-1049). The structure reveals that the histone domain plays a dual role in occluding the allosteric site and in stabilizing the autoinhibitory conformation of the DH-PH unit. Additional insight is provided by kinetic analysis of the activation of membrane-bound Ras by mutant forms of SOS that contain mutations in the histone and the PH domains (E108K, C441Y, and E433K) that are associated with Noonan syndrome, a disease caused by hyperactive Ras signaling. Our results indicate that the histone domain and the DH-PH unit are conformationally coupled, and that the simultaneous engagement of the membrane by a PH domain PIP(2)-binding interaction and electrostatic interactions between a conserved positively charged patch on the histone domain and the negatively charged membrane coincides with a productive reorientation of SOS at the membrane and increased accessibility of both Ras binding sites on SOS.

Differences in flexibility underlie functional differences in the Ras activators son of sevenless and Ras guanine nucleotide releasing factor 1.

The Ras-specific nucleotide exchange factor Son of sevenless (Sos) is inactive without Ras bound to a distal allosteric site. In contrast, the catalytic domain of Ras guanine nucleotide releasing factor 1 (RasGRF1) is active intrinsically. By substituting residues from RasGRF1 into Sos, we have generated mutants of Sos with basal activity, partially relieved of their dependence on allosteric activation. We have performed molecular dynamics simulations showing how Ras binding to the allosteric site leads to a bias toward the active conformation of Sos. The trajectories show that Sos fluctuates between active and inactive conformations in the absence of Ras and that the activating mutations favor conformations of Sos that are more permissive to Ras binding at the catalytic site. In contrast, unliganded RasGRF1 fluctuates primarily among active conformations. Our results support the premise that the catalytic domain of Sos has evolved an allosteric activation mechanism that extends beyond the simple process of membrane recruitment.

A Src-like inactive conformation in the abl tyrosine kinase domain.

The improper activation of the Abl tyrosine kinase results in chronic myeloid leukemia (CML). The recognition of an inactive conformation of Abl, in which a catalytically important Asp-Phe-Gly (DFG) motif is flipped by approximately 180 degrees with respect to the active conformation, underlies the specificity of the cancer drug imatinib, which is used to treat CML. The DFG motif is not flipped in crystal structures of inactive forms of the closely related Src kinases, and imatinib does not inhibit c-Src. We present a structure of the kinase domain of Abl, determined in complex with an ATP-peptide conjugate, in which the protein adopts an inactive conformation that resembles closely that of the Src kinases. An interesting aspect of the Src-like inactive structure, suggested by molecular dynamics simulations and additional crystal structures, is the presence of features that might facilitate the flip of the DFG motif by providing room for the phenylalanine to move and by coordinating the aspartate side chain as it leaves the active site. One class of mutations in BCR-Abl that confers resistance to imatinib appears more likely to destabilize the inactive Src-like conformation than the active or imatinib-bound conformations. Our results suggest that interconversion between distinctly different inactive conformations is a characteristic feature of the Abl kinase domain.

Toward engineering the stability and hemin-binding properties of microsomal cytochromes b5 into rat outer mitochondrial membrane cytochrome b5: examining the influence of residues 25 and 71.

As part of a larger effort to engineer the stability and hemin-binding properties of microsomal (Mc) cytochromes b(5) into rat liver outer mitochondrial membrane (OM) cytochrome (cyt) b(5), several mutants of rat OM cyt b(5) were prepared to study the effect of gradual and complete elimination of two extended hydrophobic networks, which are present in the structure of the mitochondrial protein and are absent in the structure of mammalian Mc cytochromes b(5). One of the hydrophobic networks, identified in a previous study [Altuve, A., Silchenko, S., Lee, K.-H., Kuczera, K., Terzyan, S., Zhang, X., Benson, D. R., and Rivera, M. (2001) Biochemistry 40, 9469-9483], encompasses the side chains of Ala-18, Ile-32, Leu-36, and Leu-47, whereas a second hydrophobic network, identified as part of this work, encompasses the side chains of Ile-25, Phe-58, Leu-71, and the heme. The X-ray structure of the A18S/I25L/I32L/L47R/L71S quintuple mutant of rat OM cyt b(5) demonstrates that both hydrophobic networks have been eliminated and that the corresponding structural elements of the Mc isoform have been introduced. The stability of the rat OM mutant proteins studied was found to decrease in the order wild type > I25L > A18S/I32L/L47R > L71S > A18S/I32L/L47R/L71S > 18S/I25L/I32L/L47R/L71S, indicating that the two hydrophobic networks do indeed contribute to the high stability of rat OM cyt b(5) relative to the bovine Mc isoform. Surprisingly, the quintuple mutant of rat OM cyt b(5) is less stable than bovine Mc cyt b(5), even though the former exhibits significantly slower rates of hemin release and hemin reorientation at pH 7.0. However, at pH 5.0 the bovine Mc and rat OM quintuple mutant proteins release hemin at comparable rates, suggesting that one or both of the His axial ligands in the rat OM protein are more resistant to protonation under physiological conditions. Results obtained from chemical denaturation experiments conducted with the apoproteins demonstrated that mutants containing L71S are significantly less stable than bovine Mc apocyt b(5), strongly suggesting that Leu-71 plays a pivotal role in the stabilization of rat OM apocyt b(5), presumably via hydrophobic interactions with Ile-25 and Phe-58. Because comparable interactions are absent in bovine Mc apocyt b(5), which contains Ser at position 71, it must resort to different interactions to stabilize its fold, thus highlighting yet another difference between rat OM and bovine Mc cyt b(5). During the course of these investigations we also discovered that rat OM cyt b(5) can be made to strongly favor hemin orientational isomer A (I32L) or isomer B (L71S) with a single point mutation and that release of hemin orientational isomers A and B can be kinetically resolved in certain rat OM mutants.