SHP2 inhibitors maintain TGFß signalling through SMURF2 inhibition.

Despite the promising antitumor activity of SHP2 inhibitors in RAS-dependent tumours, overall responses have been limited by their narrow therapeutic window. Like with all MAPK pathway inhibitors, this is likely the result of compensatory pathway activation mechanisms. However, the underlying mechanisms of resistance to SHP2 inhibition remain unknown. The E3 ligase SMURF2 limits TGFß activity by ubiquitinating and targeting the TGFß receptor for proteosome degradation. Using a functional RNAi screen targeting all known phosphatases, we identify that the tyrosine phosphatase SHP2 is a critical regulator of TGFß activity. Specifically, SHP2 dephosphorylates two key residues on SMURF2, resulting in activation of the enzyme. Conversely, SHP2 depletion maintains SMURF2 in an inactive state, resulting in the maintenance of TGFß activity. Furthermore, we demonstrate that depleting SHP2 has significant implications on TGFß-mediated migration, senescence, and cell survival. These effects can be overcome through the use of TGFß-targeted therapies. Consequently, our findings provide a rationale for combining SHP2 and TGFß inhibitors to enhance tumour responses leading to improved patient outcomes.

USP1-trapping lesions as a source of DNA replication stress and genomic instability.

The deubiquitinase USP1 is a critical regulator of genome integrity through the deubiquitylation of Fanconi Anemia proteins and the DNA replication processivity factor, proliferating cell nuclear antigen (PCNA). Uniquely, following UV irradiation, USP1 self-inactivates through autocleavage, which enables its own degradation and in turn, upregulates PCNA monoubiquitylation. However, the functional role for this autocleavage event during physiological conditions remains elusive. Herein, we discover that cells harboring an autocleavage-defective USP1 mutant, while still able to robustly deubiquitylate PCNA, experience more replication fork-stalling and premature fork termination events. Using super-resolution microscopy and live-cell single-molecule tracking, we show that these defects are related to the inability of this USP1 mutant to be properly recycled from sites of active DNA synthesis, resulting in replication-associated lesions. Furthermore, we find that the removal of USP1 molecules from DNA is facilitated by the DNA-dependent metalloprotease Spartan to counteract the cytotoxicity caused by "USP1-trapping". We propose a utility of USP1 inhibitors in cancer therapy based on their ability to induce USP1-trapping lesions and consequent replication stress and genomic instability in cancer cells, similar to how non-covalent DNA-protein crosslinks cause cytotoxicity by imposing steric hindrances upon proteins involved in DNA transactions.

OTUD4 enhances TGFß signalling through regulation of the TGFß receptor complex.

Systematic control of the transforming growth factor-ß (TGFß) pathway is essential to keep the amplitude and the intensity of downstream signalling at appropriate levels. Ubiquitination plays a crucial role in the general regulation of this pathway. Here we identify the deubiquitinating enzyme OTUD4 as a transcriptional target of the TGFß pathway that functions through a positive feedback loop to enhance overall TGFß activity. Interestingly we demonstrate that OTUD4 functions through both catalytically dependent and independent mechanisms to regulate TGFß activity. Specifically, we find that OTUD4 enhances TGFß signalling by promoting the membrane presence of TGFß receptor I. Furthermore, we demonstrate that OTUD4 inactivates the TGFß negative regulator SMURF2 suggesting that OTUD4 regulates multiple nodes of the TGFß pathway to enhance TGFß activity.

Author Correction: c-Met activation leads to the establishment of a TGFß-receptor regulatory network in bladder cancer progression.

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

c-Met activation leads to the establishment of a TGFß-receptor regulatory network in bladder cancer progression.

Treatment of muscle-invasive bladder cancer remains a major clinical challenge. Aberrant HGF/c-MET upregulation and activation is frequently observed in bladder cancer correlating with cancer progression and invasion. However, the mechanisms underlying HGF/c-MET-mediated invasion in bladder cancer remains unknown. As part of a negative feedback loop SMAD7 binds to SMURF2 targeting the TGFß receptor for degradation. Under these conditions, SMAD7 acts as a SMURF2 agonist by disrupting the intramolecular interactions within SMURF2. We demonstrate that HGF stimulates TGFß signalling through c-SRC-mediated phosphorylation of SMURF2 resulting in loss of SMAD7 binding and enhanced SMURF2 C2-HECT interaction, inhibiting SMURF2 and enhancing TGFß receptor stabilisation. This upregulation of the TGFß pathway by HGF leads to TGFß-mediated EMT and invasion. In vivo we show that TGFß receptor inhibition prevents bladder cancer invasion. Furthermore, we make a rationale for the use of combinatorial TGFß and MEK inhibitors for treatment of high-grade non-muscle-invasive bladder cancers.