Single Ion Pair Is Essential for Stabilizing SHP2's Open Conformation.

Src-homology-2-domain-containing PTP-2 (SHP2) is a widely expressed signaling enzyme whose misregulation is associated with multiple human pathologies. SHP2's enzymatic activity is controlled by a conformational equilibrium between its autoinhibited ("closed") state and its activated ("open") state. Although SHP2's closed state has been extensively characterized, the putative structure of its open form has only been revealed in the context of a highly activated mutant (E76K), and no systematic studies of the biochemical determinants of SHP2's open-state stabilization have been reported. To identify amino-acid interactions that are critical for stabilizing SHP2's active state, we carried out a mutagenic study of residues that lie at potentially important interdomain interfaces of the open conformation. The open/closed equilibria of the mutants were evaluated, and we identified several interactions that contribute to the stabilization of SHP2's open state. In particular, our findings establish that an ion pair between glutamate 249 on SHP2's PTP domain and arginine 111 on an interdomain loop is the key determinant of SHP2's open-state stabilization. Mutations that disrupt the R111/E249 ion pair substantially shift SHP2's open/closed equilibrium to the closed state, even compared to wild-type SHP2's basal-state equilibrium, which strongly favors the closed state. To the best of our knowledge, the ion-pair variants uncovered in this study are the first known SHP2 mutants in which autoinhibition is augmented with respect to the wild-type protein. Such "hyperinhibited" mutants may provide useful tools for signaling studies that investigate the connections between SHP2 inhibition and the suppression of human disease progression.

Ccm1 is required for arterial morphogenesis: implications for the etiology of human cavernous malformations.

Hemorrhagic stroke is a significant cause of morbidity and mortality in children, and is frequently associated with intracranial vascular malformations. One prevalent form of these vascular malformations, cerebral cavernous malformation, is characterized by thin-walled vascular cavities that hemorrhage and has been linked to loss-of-function mutations in CCM1. The neural and epithelial expression of CCM1 in adulthood suggests that cavernous malformations may be the result of primary neural defects. In this study, we generated mice lacking Ccm1 and demonstrate that Ccm1 is ubiquitously expressed early in embryogenesis and is essential for vascular development. Homozygous mutant embryos die in mid-gestation and the first detectable defects are exclusively vascular in nature. The precursor vessels of the brain become dilated starting at E8.5, reminiscent of the intracranial vascular defects observed in the human disease. In addition, there is marked enlargement and increased endothelial proliferation of the caudal dorsal aorta, as well as variable narrowing of the branchial arch arteries and proximal dorsal aorta. These vascular defects are not secondary to primary neural defects, as neural morphology and marker expression are normal even subsequent to the onset of vascular pathology. The defects in the vascular structure of embryos lacking Ccm1 are associated with early downregulation of artery-specific markers, including the Efnb2- and Notch-related genes. Finally, consistent with the murine data, we found that there is an analogous reduction in Notch gene expression in arterioles from humans with mutations in CCM1. Our studies suggest that cavernous malformations result from primary vascular rather than neural defects.