A transcription cofactor required for the heat‐shock response

The Stress-responsive activator of p300 (Strap) is a transcription cofactor that has an important role in the control of DNA damage response through its ability to regulate p53 activity. Here, we report that Strap is inducible by heat shock and stimulates the transcription of heat-shock genes. A chromatin-associated complex involving heat-shock factor 1 (HSF1), Strap and the p300 coactivator assembles on the heat-shock protein 70 (hsp70) promoter, and Strap augments HSF1 binding and chromatin acetylation in Hsp genes, most probably through the p300 histone acetyltransferase. Cells depleted of Strap do not survive under heat-shock conditions. These results indicate that Strap is an essential cofactor that acts at the level of chromatin control to regulate heat-shock-responsive transcription

The HDAC inhibitor zabadinostat is a systemic regulator of adaptive immunity

Protein acetylation plays a key role in regulating cellular processes and is subject to aberrant control in diverse pathologies. Although histone deacetylase (HDAC) inhibitors are approved drugs for certain cancers, it is not known whether they can be deployed in other therapeutic contexts. We have explored the clinical HDAC inhibitor, zabadinostat/CXD101, and found that it is a stand-alone regulator of the adaptive immune response. Zabadinostat treatment increased expression of MHC class I and II genes in a variety of cells, including dendritic cells (DCs) and healthy tissue. Remarkably, zabadinostat enhanced the activity of DCs, and CD4 and CD8 T lymphocytes. Using an antigenic peptide presented to the immune system by MHC class I, zabadinostat caused an increase in antigen-specific CD8 T lymphocytes. Further, mice immunised with covid19 spike protein and treated with zabadinostat exhibit enhanced covid19 neutralising antibodies and an increased level of T lymphocytes. The enhanced humoral response reflected increased activity of T follicular helper (Tfh) cells and germinal centre (GC) B cells. Our results argue strongly that zabadinostat has potential to augment diverse therapeutic agents that act through the immune system

Long non-coding RNA-derived peptides are immunogenic and drive a potent anti-tumour response

Protein arginine methyltransferase (PRMT) 5 is over-expressed in a variety of cancers and the master transcription regulator E2F1 is an important methylation target. We have explored the role of PRMT5 and E2F1 in regulating the non-coding genome and report here a striking effect on long non-coding (lnc) RNA gene expression. Moreover, many MHC class I protein-associated peptides were derived from small open reading frames in the lncRNA genes. Pharmacological inhibition of PRMT5 or adjusting E2F1 levels qualitatively altered the repertoire of lncRNA-derived peptide antigens displayed by tumour cells. When presented to the immune system as either ex vivo-loaded dendritic cells or expressed from a viral vector, lncRNA-derived peptides drove a potent antigen-specific CD8 T lymphocyte response, which translated into a significant delay in tumour growth. Thus, lncRNA genes encode immunogenic peptides that can be deployed as a cancer vaccine

Long non-coding RNA-derived peptides are immunogenic and drive a potent anti-tumour response

Protein arginine methyltransferase (PRMT) 5 is over-expressed in a variety of cancers and the master transcription regulator E2F1 is an important methylation target. We have explored the role of PRMT5 and E2F1 in regulating the non-coding genome and report here a striking effect on long non-coding (lnc) RNA gene expression. Moreover, many MHC class I protein-associated peptides were derived from small open reading frames in the lncRNA genes. Pharmacological inhibition of PRMT5 or adjusting E2F1 levels qualitatively altered the repertoire of lncRNA-derived peptide antigens displayed by tumour cells. When presented to the immune system as either ex vivo-loaded dendritic cells or expressed from a viral vector, lncRNA-derived peptides drove a potent antigen-specific CD8 T lymphocyte response, which translated into a significant delay in tumour growth. Thus, lncRNA genes encode immunogenic peptides that can be deployed as a cancer vaccine

The emerging role of E2F-1 in the DNA damage response and checkpoint control.

Genotoxic stress triggers a myriad of cellular responses including cell cycle arrest, stimulation of {DNA} repair and apoptosis. A central role for the E2F-1 transcription factor in the {DNA} damage response pathway is gaining support. E2F-1 is phosphorylated by {DNA} damage responsive protein kinases, which leads to E2F-1 accumulation and the induction of apoptosis. In addition, emerging information suggests that E2F-1 may play a role in the detection and subsequent repair of damaged DNA

A New Role for E2F-1 in Checkpoint Control

In response to DNA damage, E2F-1 is induced and phosphorylated. Phosphorylated E2F-1 can reside in discrete nuclear structures and induce apoptosis, suggesting a unique role for E2F-1 in DNA repair and checkpoint functions

E2F and cell cycle control: a double-edged sword

The E2F family of transcription factors plays a central role in regulating cellular proliferation by controlling the expression of both the genes required for cell cycle progression, particularly DNA synthesis, and the genes involved with apoptosis. E2F is regulated in a cell cycle-dependent manner, principally through its temporal association with pocket protein family members, the prototype member being the retinoblastoma tumor suppressor protein. Pocket proteins are, in turn, regulated through phosphorylation by cyclin-dependent kinase (cdk). The kinase activity of cyclin/cdk complexes is negatively regulated by cdk inhibitors, and thus both positive and negative growth regulatory signals impinge on E2F activity. Different E2F family members exhibit distinct cell cycle and apoptotic activities. Thus, E2F appears to play a pivotal role in coordinating events connected with proliferation, cell cycle arrest, and apoptosis

HR23B, a biomarker for HDAC inhibitors

As our understanding of cancer biology increases and novel therapies are developed, an increasing number of predictive biomarkers are becoming clinically available. Aberrant acetylation has been strongly linked to tumourigenesis and the modulation of acetylation through targeting histone deacetylase (HDAC) has led to the introduction of many HDAC inhibitors. To date, two have had regulatory approval for the treatment of cutaneous T cell lymphoma (CTCL). Modifications in chromatin control underpin the mechanism of action of HDAC inhibitors. A genome wide loss-of-function screen identified HR23B as a gene that governs sensitivity to HDAC inhibitors. HR23B shuttles ubiquitinated cargo proteins to the proteasome and elevated levels may contribute to cell death mediated by this pathway. It also governs cell sensitivity to drugs that act directly on the proteasome. HDAC inhibitors influence proteasome activity and there may be a synergistic interaction with proteasome inhibitors. HR23B and HDAC6 interact and HDAC6 may be a negative regulator of apoptosis and a positive regulator of autophagy and through its ability to down-regulate HR23B, may impact on the cellular outcome of HDAC inhibitor treatment. Expression of HR23B has been correlated with clinical response to HDAC inhibitors in a retrospective analysis of CTCL patients. The tissue expression of HR23B and the autophagy marker LC3 has been investigated and there may be a reciprocal relationship in their expression in some tumours which may provide prognostic information and patients with low HR23B expression but high levels of autophagy appear to have a particularly poor prognosis. Well designed, biomarker-driven prospective clinical trials are needed to clarify the predictive and prognostic roles of HR23B.This thesis is not currently available in ORA