Neuronal activity regulates the nuclear proteome to promote activity-dependent transcription

The formation and plasticity of neuronal circuits relies on dynamic activity-dependent gene expression. Although recent work has revealed the identity of important transcriptional regulators and of genes that are transcribed and translated in response to activity, relatively little is known about the cell biological mechanisms by which activity alters the nuclear proteome of neurons to link neuronal stimulation to transcription. Using nucleus-specific proteomic mapping in silenced and stimulated neurons, we uncovered an understudied mechanism of nuclear proteome regulation: activity-dependent proteasome-mediated degradation. We found that the tumor suppressor protein PDCD4 undergoes rapid stimulus-induced degradation in the nucleus of neurons. We demonstrate that degradation of PDCD4 is required for normal activity-dependent transcription and that PDCD4 target genes include those encoding proteins critical for synapse formation, remodeling, and transmission. Our findings highlight the importance of the nuclear proteasome in regulating the activity-dependent nuclear proteome and point to a specific role for PDCD4 as a regulator of activity-dependent transcription in neurons.

The ORF45 protein of Kaposi Sarcoma-associated Herpesvirus (KSHV) is an inhibitor of p53 signaling during viral reactivation

Kaposi Sarcoma-associated herpesvirus (KSHV) is a carcinogenic double-stranded DNA virus and the etiological agent of Kaposi’s Sarcoma (KS), primary effusion lymphoma (PEL), and multicentric Castleman’s Disease (MCD). To prevent premature apoptosis and support its replication cycle, KSHV expresses a series of open reading frames (ORFs) that regulate signaling by the p53 tumor suppressor protein. Here we describe a novel viral inhibitor of p53 encoded by KSHV ORF45 and identify its mechanism of action. ORF45 binds to p53 and prevents its interactions with USP7, a p53 deubiquitinase. This results in decreased accumulation, localization of p53 to the cytoplasm, and diminished transcriptional activity. IMPORTANCE Unlike in other cancers, the tumor suppressor protein p53 is rarely mutated in Kaposi Sarcoma (KS). Rather, Kaposi Sarcoma-associated herpesvirus (KSHV) inactivates p53 through multiple viral proteins. One possible therapeutic approach to KS is the activation of p53, which would result in apoptosis and tumor regression. In this regard, it is important to understand all the mechanisms used by KSHV to modulate p53 signaling. This work describes a novel inhibitor of p53 signaling and a potential drug target, ORF45, and identifies the mechanisms of its action.

Impact of Reactive Oxygen and Nitrogen Species Produced by Plasma on Mdm2–p53 Complex

The study of protein–protein interactions is of great interest. Several early studies focused on the murine double minute 2 (Mdm2)–tumor suppressor protein p53 interactions. However, the effect of plasma treatment on Mdm2 and p53 is still absent from the literature. This study investigated the structural changes in Mdm2, p53, and the Mdm2–p53 complex before and after possible plasma oxidation through molecular dynamic (MD) simulations. MD calculation revealed that the oxidized Mdm2 bounded or unbounded showed high flexibility that might increase the availability of tumor suppressor protein p53 in plasma-treated cells. This study provides insight into Mdm2 and p53 for a better understanding of plasma oncology.

Nanobodies restore stability to cancer-associated mutants of tumor suppressor protein p16INK4a

We describe the generation and characterization of camelid single-domain antibodies (nanobodies) raised against tumor suppressor protein p16INK4a (p16). p16 plays a critical role in the cell cycle by inhibiting cyclin-dependent kinases CDK4 and CDK6, and it is inactivated in sporadic and familial cancers. The majority of the p16 missense mutations cause loss of function by destabilizing the protein structure. We show that the nanobodies bind p16 with nanomolar affinities and restore the stability of a range of different cancer-associated p16 mutations located at sites throughout the protein. The nanobodies also bind and stabilize p16 in a cellular setting. The crystal structure of a nanobody-p16 complex reveals that the nanobody binds to the opposite face of p16 to the CDK-binding interface permitting formation of a ternary complex. These findings indicate that nanobodies could be used as pharmacological chaperones to determine the consequences of restoring the function of p16 in the cell.