Mechanism of constitutive phosphoinositide 3-kinase activation by oncogenic mutants of the p85 regulatory subunit

p85/p110 phosphoinositide 3-kinases regulate multiple cell functions and are frequently mutated in human cancer. The p85 regulatory subunit stabilizes and inhibits the p110 catalytic subunit. The minimal fragment of p85 capable of regulating p110 is the N-terminal SH2 domain linked to the coiled-coil iSH2 domain (referred to as p85ni). We have previously proposed that the conformationally rigid iSH2 domain tethers p110 to p85, facilitating regulatory interactions between p110 and the p85 nSH2 domain. In an oncogenic mutant of murine p85, truncation at residue 571 leads to constitutively increased phosphoinositide 3-kinase activity, which has been proposed to result from either loss of an inhibitory Ser-608 autophosphorylation site or altered interactions with cellular regulatory factors. We have examined this mutant (referred to as p65) in vitro and find that p65 binds but does not inhibit p110, leading to constitutive p110 activity. This activated phenotype is observed with recombinant proteins in the absence of cellular factors. Importantly, this effect is also produced by truncating p85ni at residue 571. Thus, the phenotype is not because of loss of the Ser-608 inhibitory autophosphorylation site, which is not present in p85ni. To determine the structural basis for the phenotype of p65, we used a broadly applicable spin label/NMR approach to define the positioning of the nSH2 domain relative to the iSH2 domain. We found that one face of the nSH2 domain packs against the 581-593 region of the iSH2 domain. The loss of this interaction in the truncated p65 would remove the orienting constraints on the nSH2 domain, leading to a loss of p110 regulation by the nSH2. Based on these findings, we propose a general model for oncogenic mutants of p85 and p110 in which disruption of nSH2-p110 regulatory contacts leads to constitutive p110 activity.     

Structure of the transmembrane dimer interface of glycophorin A in membrane bilayers

The hydrophobic transmembrane domain of glycophorin A contains a sequence motif that mediates dimerization in membrane environments. Long-range interhelical distance measurements using magic angle spinning NMR spectroscopy provide high-resolution structural constraints on the packing of the dimer interface in membrane bilayers. We show that direct packing contacts occur between glycine residues at positions 79 and 83 in the transmembrane sequence. Additional interhelical constraints between Ile76 and Gly79 and between Val80 and Gly83 restrict the rotational orientation and crossing angle of the interacting helices. These results refine our previously proposed structure of the glycophorin A dimer [Smith, S. O., and Bormann, B. J. (1995) Proc. Natl. Acad. Sci. U.S.A. 92, 488-491] which revealed that the methyl groups of Val80 and Val84 are packed against Gly79 and Gly83, respectively.     

Hydroxyproline‐rich Glycoproteins and Plant Defence

The distinguished plant cell wall component referred to as hydroxyproline‐rich glycoproteins (HRGPs) exists in two forms: soluble in the symplast and insoluble in the apoplast. Insolubilization of HRGPs in cell walls through oxidative cross‐linking which is elicited by stress represents a characteristic feature exhibited by two classes of HRGPs, namely, extensins and proline/HRGPs. Cross‐linking of these HRGPs is an important process to strengthen the cell walls that contributes to plant defence reactions. In this review, the available information on these proteins is analysed with respect to their roles in host‐pathosystems and the various techniques applied for their characterization. Future prospects on strengthening of cell walls through gene regulation and transgenic approaches are also addressed.     

Pyrrolidine ring conformations in prolyl peptides from 13C spin-lattice relaxation times

A method was developed in the framework of a bistable jump model to obtain the pyrrolidine ring conformations in proline peptides from 13C spin-lattice relaxation times. Equations are presented expressing the ring torsions in terms of the 13C spin-lattice relaxation times of the ring carbons. This method was applied to 26 pyrrolidine ring systems and acceptable conformations were obtained.