Recent clinical trials using immunotherapy demonstrate its potential to control cancer by disinhibiting the immune system. Immune checkpoint blocking (ICB) antibodies such as anti-cytotoxic T-lymphocyte-associated protein 4 (anti-CTLA-4) or anti-Programmed cell death protein 1/anti-Programmed death-ligand 1 (anti-PD-1/anti-PD-L1)1 have demonstrated durable clinical responses in various cancers. Although these new immunotherapies have significant impact on cancer treatment, multiple mechanisms of immune resistance exist in tumors. Among the key mechanisms, myeloid cells play a major role in limiting effective tumor immunity. 2–4 Growing evidence suggests that high infiltration of immune-suppressive myeloid cells correlates with poor prognosis and ICB resistance. 5,6 These observations suggest a need for a precision medicine approach where the design of the immunotherapeutic combinations are tailored based on tumor immune landscape to overcome such resistance mechanisms. Herein we employ a preclinical model system and show that resistance to ICB is directly mediated by the suppressive activity of infiltrating myeloid cells in various tumors. Furthermore, selective pharmacologic targeting of the gamma isoform of phosphoinositide 3-kinase (PI3K-γ), highly expressed in myeloid cells, restores sensitivity to ICB. We demonstrate that targeting PI3K–γ, with a selective inhibitor, currently being evaluated in a phase 1 clinical trial (NCT02637531), can reshape the tumor immune microenvironment and promote cytotoxic T cell-mediated tumor regression without targeting cancer cells directly. Our results introduce opportunities for new combination strategies using a selective small molecule PI3K-γ inhibitor, such as IPI-549, to overcome resistance to ICB in patients with high levels of suppressive myeloid cell infiltration in tumors.
17-Allylamino-17-demethoxygeldanamycin (17-AAG)1 is a semisynthetic inhibitor of the 90 kDa heat shock protein (Hsp90) currently in clinical trials for the treatment of cancer. However, 17-AAG faces challenging formulation issues due to its poor solubility. Here we report the synthesis and evaluation of a highly soluble hydroquinone hydrochloride derivative of 17-AAG, 1a (IPI-504), and several of the physiological metabolites. These compounds show comparable binding affinity to human Hsp90 and its endoplasmic reticulum (ER) homologue, the 94 kDa glucose regulated protein (Grp94). Furthermore, the compounds inhibit the growth of the human cancer cell lines SKBR3 and SKOV3, which overexpress Hsp90 client protein Her2, and cause down-regulation of Her2 as well as induction of Hsp70 consistent with Hsp90 inhibition. There is a clear correlation between the measured binding affinity of the compounds and their cellular activities. Upon the basis of its potent activity against Hsp90 and a significant improvement in solubility, 1a is currently under evaluation in Phase I clinical trials for cancer.
Optimization of isoquinolinone PI3K inhibitors led to the discovery of a potent inhibitor of PI3K-γ (26 or IPI-549) with >100-fold selectivity over other lipid and protein kinases. IPI-549 demonstrates favorable pharmacokinetic properties and robust inhibition of PI3K-γ mediated neutrophil migration in vivo and is currently in Phase 1 clinical evaluation in subjects with advanced solid tumors.
Duvelisib, an oral dual inhibitor of PI3K-δ and PI3K-γ, is in phase III trials for the treatment of chronic lymphocytic leukemia (CLL) and indolent non-Hodgkin’s lymphoma (iNHL). In CLL, duvelisib monotherapy is associated with high iwCLL and nodal response rates, but complete remissions are rare. To characterize the molecular effect of duvelisib, we obtained samples from CLL patients on the duvelisib phase I trial. Gene-expression studies (RNA seq, Nanostring, Affymetrix array, and real time RT-PCR) demonstrated increased expression of BCL2 along with several BH3-only pro-apoptotic genes. In concert with induction of transcript levels, reverse phase protein arrays and immunoblots confirmed increase at the protein level. The BCL2 inhibitor venetoclax induced greater apoptosis in ex-vivo cultured CLL cells obtained from patients on duvelisib compared to pre-treatment CLL cells from the same patients. In vitro combination of duvelisib and venetoclax resulted in enhanced apoptosis even in CLL cells cultured under conditions that simulate the tumor microenvironment. These data provide a mechanistic rationale for testing the combination of duvelisib and venetoclax in the clinic. Such combination regimen (NCT02640833) is being evaluated for patients with B-cell malignancies including CLL.
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