A spatiotemporal characterization of the effect of p53 phosphorylation on its interaction with MDM2

The interaction of p53 and MDM2 is modulated by the phosphorylation of p53. This mechanism is key to activating p53, yet its molecular determinants are not fully understood. To study the spatiotemporal characteristics of this molecular process we carried out Brownian dynamics simulations of the interactions of the MDM2 protein with a p53 peptide in its wild type state and when phosphorylated at Thr18 (pThr18) and Ser20 (pSer20). We found that p53 phosphorylation results in concerted changes in the topology of the interaction landscape in the diffusively bound encounter complex domain. These changes hinder phosphorylated p53 peptides from binding to MDM2 well before reaching the binding site. The underlying mechanism appears to involve shift of the peptide away from the vicinity of the MDM2 protein, peptide reorientation, and reduction in peptide residence time relative to wild-type p53 peptide. pThr18 and pSr20 p53 peptides experience reduction in residence times by factors of 13.6 and 37.5 respectively relative to the wild-type p53 peptide, indicating a greater role for Ser20 phosphorylation in abrogating p53 MDM2 interactions. These detailed insights into the effect of phosphorylation on molecular interactions are not available from conventional experimental and theoretical approaches and open up new avenues that incorporate molecular interaction dynamics, for stabilizing p53 against MDM2, which is a major focus of anticancer drug lead development.     

MDA5 participates in the detection of paramyxovirus infection and is essential for the early activation of dendritic cells in response to Sendai Virus defective interfering particles

Defective interfering (DI) particles are byproducts of virus replication that potently enhance dendritic cell (DC) maturation by virus infection. DI particles have been reported for many different viruses and are strong inducers of type I IFNs. The cellular mechanisms involved in the response to DI particles are not known. In this study, we show that 1) DI particles are recognized by more than one viral sensor independently of TLRs and type I IFN signaling; 2) The helicase MDA5 participates in the detection of DI genomes as MDA5-deficient DCs respond inefficiently to Sendai virus stocks containing DI particles; 3) DI particles stimulate the expression of IRF3-responsive genes by a uniquely potent mechanism when compared with other prototypic viral stimulus; and 4) the efficient detection of DI particles overcomes virus immune antagonism. These data highlight the outstanding adjuvant capacity of DI particles in stimulating mouse and human DCs. They also offer biological relevance to the previously reported inhibition of MDA5 by different paramyxovirus V proteins. The unique mechanism by which DI particles trigger the maturation of DCs represents a novel strategy that could be further exploited for the development of potent adjuvant molecules.