Investigating the inhibitor and substrate diversity of the JmjC histone demethylases

Schiller, Rachel Shamo

January 2016

Epigenetic control of gene expression by histone post-translational modifications (PTMs) is a complex process regulated by proteins that can 'read', 'write' or 'erase' these PTMs. The histone lysine demethylase (KDM) family of epigenetic enzymes remove methyl modifications from lysines on histone tails. The Jumonji C domain (JmjC) family is the largest family of KDMs. Investigating the scope and mechanisms of the JmjC KDMs is of interest for understanding the diverse functions of the JmjC KDMs in vivo, as well as for the application of the basic science to medicinal chemistry design. The work described in this thesis aimed to biochemically investigate the inhibitor and substrate diversity of the JmjC KDMs, it led to the identification of new inhibitors and substrates and revealed a potential combinatorial dependence between adjacent histone PTMs. Structure-activity relationship studies gave rise to an n-octyl ester form of IOX1 with improved cellular potency and selectivity towards the KDM4 subfamily. This compound should find utility as a basis for the development of JmjC inhibitors and as a tool compound for biological studies. The rest of this thesis focused on the biochemical investigations of potential substrates and inhibitors for KDM3A, a JmjC demethylase with varied physiological functions. Kinetic characterisation of reported KDM3A substrates was used as the basis for evaluations of novel substrates and inhibitors. Further studies found TCA cycle intermediates to be moderate co-substrate competitive inhibitors of KDM3A. Biochemical investigations were carried out to study potential protein-protein interactions of KDM3A with intraflagellar transport proteins (IFTs), non-histone proteins involved in the formation of sperm flagellum. Work then addressed the exploration of novel in vitro substrates for KDM3 (KDM3A and JMJD1C) mediated catalysis, including: methylated arginines, lysine analogues, acetylated and formylated lysines. KDM3A, and other JmjC KDMs, were found to catalyse novel arginine demethylation reaction in vitro. Knowledge gained from studies with unnatural lysine analogues was utilised to search for additional novel PTM substrates for KDM3A. These results constitute the first evidence of JmjC KDM catalysed hydroxylation of an Nε-acetyllysine residue. The H3 K4me3 position seems to be required for acetyllysine substrate recognition, implying a combinatorial effect between PTMs. Preliminary results provide evidence that JMJD1C, a KDM3 protein previously reported to be inactive, may catalyse deacetylation in vitro. An additional novel reaction, observed with both KDM3A and JMJD1C, is deformylation of N^ε-formyllysine residues on histone H3 fragment peptides. Interestingly, H3 K4 methylation was also observed to enhance the apparent deformylation of both KDM3A and JMJD1C catalysed reactions. Overall, findings in this thesis suggest that the catalytic activity of JmjC KDMs extends beyond lysine demethylation. In a cellular context, members of the KDM3 subfamily might provide a regulatory link between methylation and acylation marks. Such a link will further highlight the complex relationships between histone PTMs and the epigenetic enzymes that regulate them. The observed dependency of H3 K9 catalysis on H3 K4 methylation adds another layer of complexity to the epigenetic regulation by histone PTMs.

PHARMACOLOGICAL TARGETING OF FGFR IN METASTATIC BREAST CANCER IS AUGMENTED BY DNMT1 INHIBITION

Mitchell G Ayers (18990533)

02 August 2024

<p dir="ltr">Metastatic breast cancer (BC) remains a dauting therapeutic challenge due to the heterogeneity and cellular plasticity that exists. Because of these, BC resistance to targeted therapies and immune checkpoint blockade (ICB) present major challenges in the clinical setting. As a result, incomplete clearance of BC during a therapeutic regimen can lead to the persistence of minimal residual disease (MRD) which greatly contributes to tumor relapse. Here we develop a powerful in vivo model of lung metastasis in which we can achieve robust pulmonary tumor regression in response to the fibroblast growth factor receptor (FGFR) inhibitor, pemigatinib.</p><p dir="ltr">To enhance the efficacy of ICB, tumors must first be converted from an immune “cold” environment to an immune “hot” environment. Using our in vivo model of lung metastasis, we demonstrated that pemigatinib can significantly increase the presence of infiltrating T-cells into the lungs while suppressing the presence of MDSCs both locally in the lungs and systemically. Taken together, pemigatinib is an ideal candidate to prime these immune “cold” tumors for combination with ICB.</p><p dir="ltr">Upon establishment of MRD by pemigatinib in our in vivo model we observe upregulation of an alternate growth factor receptor, platelet-derived growth factor receptor (PDGFR). Functionally, upon FGFR inhibition, there is increased response to pulmonary fibroblast derived PDGF ligand, fueling survival of MRD. We demonstrated that knockdown of PDGFR significantly delayed tumor growth reinitiation in an in vitro 3D culture following pemigatinib as well as delayed tumor relapse in our pulmonary metastasis model.</p><p dir="ltr">To limit cellular plasticity and reduce survival of MRD, we propose a novel dual-targeted approach utilizing pemigatinib, in conjunction with inhibition of DNMT1 using the reversible inhibitor GSK3484862. We used our in vivo model of lung metastasis after treatment with pemigatinib as a model of cellular plasticity to targeted therapy. This combination therapy prevented growth factor plasticity and delayed tumor recurrence. Through prevention of PDGFR upregulation induced by pemigatinib.</p><p dir="ltr">In the present dissertation works, our study demonstrates pemigatinib’s robust ability to increase infiltrating T-cells in addition to its strong antitumor effects on pulmonary tumors. Despite the robust effects of pemigatinib, acquired mechanism of resistance through upregulation of PDGFR allows survival of MRD and are supported by PDGF secreting fibroblasts. Using an approach of limiting cellular plasticity through DNA methylation inhibition combined with pemigatinib, we achieved a more durable therapeutic response. Our findings underscore the significance of understanding adaptive responses to targeted therapies and provide a tangible therapeutic strategy to prolong treatment response in metastatic breast cancer.</p>

Tumour immunology

Cancer cell biology

Breast Cancer biology

FGFR signaling

FGFR1 inhibitor

tumor immunology.

pharmacology

Drug Resistance

immune checkpoint inhibitor (ICKi)

Epigenetic inhibitor

Cancer associated fibroblasts (CAFs)

DNMT 1 methyltransferase