Epigenetic vulnerabilities of leukemia harboring inactivating EZH2 mutations.

Epigenetic regulators, such as the polycomb repressive complex 2 (PRC2), play a critical role in both normal development and carcinogenesis. Mutations and functional dysregulation of PRC2 complex components, such as EZH2, are implicated in various forms of cancer and associated with poor prognosis. This study investigated the epigenetic vulnerabilities of acute myeloid leukemia (AML) and myelodysplastic/myeloproliferative disorders (MDS/MPN) by performing a chemical probe screen in patient cells. Paradoxically, we observed increased sensitivity to EZH2 and embryonic ectoderm development (EED) inhibitors in AML and MDS/MPN patient cells harboring EZH2 mutations. Expression analysis indicated that EZH2 inhibition elicited upregulation of pathways responsible for cell death and growth arrest, specifically in patient cells with mutant EZH2. The identified EZH2 mutations had drastically reduced catalytic activity, resulting in lower cellular H3K27me3 levels, and were associated with decreased EZH2 and PRC2 component EED protein levels. Overall, this study provides an important understanding of the role of EZH2 dysregulation in blood cancers and may indicate disease etiology for these poor prognosis AML and MDS/MPN cases.

The Proton Responsiveness in the Extracellular Domain of GLIC Differs in the Presence of the ELIC Transmembrane Domain.

Prokaryotic homologues of Cys-loop receptors have proven to be useful in understanding their eukaryotic counterparts, but even the best studied of these, Gloeobacter ligand-gated ion channel (GLIC), is still not yet fully understood. GLIC is activated by protons with a pH50 between 5 and 6, implicating a histidine residue in its activation, but although a histidine residue (His11') in the pore-forming α-helix (M2) is known to be involved in gating, the His in the extracellular domain (ECD), His127, is not. Nevertheless, there is evidence from a GLIC-glycine chimera for a proton sensitive residue or region in the GLIC extracellular domain. Here we create a novel chimeric receptor with the ECD of GLIC and the transmembrane domain of ELIC (GELIC). Expression of this receptor in oocytes reveals proton activation, although the pH50 (6.7) differs from that of GLIC (5.4). Exploration of protonatable residues in the ECD reveals that the pKas of five Asp residues (31, 49, 91, 136, and 178) differ between the open and closed states of GLIC. Substitution of these residues with Ala or Asn shows somewhat similar effects for GLIC and GELIC in Asp91 mutants, but different effects for the others. Overall, the data suggest that protonation of residues in the ECD is a requirement for channel opening in GELIC but plays only a minor role in GLIC, where gating may be largely driven via protonation of the His residue in its pore.

Crotonic Acid Blocks the Gloeobacter Ligand-Gated Ion Channel (GLIC) via the Extracellular Domain.

Cys-loop receptors play important roles in signal transduction in multicellular organisms, but similar proteins exist in prokaryotes, the best studied of which is the Gloeobacter ligand-gated ion channel (GLIC). GLIC is activated by protons with 50% activation (pH50) at pH 5.5, and while a histidine residue in its pore-forming α-helix (M2) is known to be involved in gating, there is also evidence of a proton-sensitive region in the extracellular domain. However, this proton-sensitive region does not appear to be located in the region of GLIC equivalent to the agonist binding site in related proteins. Here we explore functional effects of a range of compounds that could bind to this site and show that some GABA analogues, the most potent of which is crotonic acid, inhibit GLIC function. Mutagenesis and docking studies suggest crotonic acid can bind to this region of the protein and, when bound, can allosterically inhibit GLIC function. These data therefore suggest that there is a transduction pathway from the orthosteric binding site to the pore in GLIC, as exists in related eukaryotic ligand-gated ion channels, and thus provide further evidence that this prokaryotic receptor is a good model for understanding this family of proteins.

Probing residues in the pore-forming (M2) domain of the Cys-loop receptor homologue GLIC reveals some unusual features.

Cys-loop receptors play important roles in signal transduction. The Gloeobacter ligand-gated ion channel (GLIC) pore binds similar compounds to Cys-loop receptor pores, but has the advantage of known structures in open and closed states. GLIC is activated by protons with a pEC50 of 5.4, and has a histidine residue (His 11') in its pore-forming α-helix (M2) which is involved in gating. Here we explore the role of this His and other M2 residues using two-electrode voltage clamp of mutant receptors expressed in oocytes. We show that 11'His is very sensitive to substitution; replacement with a range of amino acids ablates function. Similarly altering its location in M2 to the 8', 9', 10', 12', 13' or 14' positions ablated function. Most substitutions of Ser6' or Ile9' were also non-functional, although not Ile9'Leu and Ile9'Val. Unexpectedly, an Ile9'His substitution was constitutively active at pH 7, but closed as [H+] increased, with a pIC50 of 5.8. Substitution at 2', 5' and 7' had little effect on pEC50. Overall the data show Ser6' and His11' are critical for the function of the receptor, and thus distinguish the roles of these M2 residues from those of Cys-loop receptors, where substitutions are mostly well tolerated. These data suggest modellers should be aware of these atypical features when using the GLIC pore as a model for Cys-loop receptor pores.