Novel Drug to Target HK2 Overcomes Therapeutic Resistance in Preclinical B-Cell Lymphoma Models

Background: The Warburg's effect is a hallmark in cancer. Hexokinase II (HK2) is a glycolic kinase to phosphorylate glucose to glucose-6-phosphate, which can be utilized as the energy source for cells. HK2 is predominantly overexpressed in cancer cells and has been associated with poor clinical outcomes in cancer patients. Previously, we demonstrated that HK2 mRNA and protein levels were increased in diffuse large B-cell lymphoma patients, and were significantly associated with inferior progression free survival (PFS) and overall survival (OS). In our rituximab and chemotherapy-resistant cell lines (TRCL), we demonstrated an upregulation of HK2 expression level is association with voltage-dependent anion channel (VDAC) resulting in a) repress mitochondrial potential and b) global therapy resistance. Knocking out HK2 overcame the chemo-resistance phenotype observed in TRCL. Here, we designed a novel specific inhibitor of HK2 and tested its activity in lymphoma pre-clinical models.

Material and Methods: A HK2 specific inhibitor (HK2-001) was designed and generated according to antisense peptide technology, CABS-docking system and ROSWTTA analyzing. A panel of B-cell lymphoma cell lines including rituximab/chemo-sensitive and resistant cell lines (Raji, Raji 4RH, RL and RL 4RH), diffuse large B-cell lymphoma (DLBCL) (DHL4, DOHH2, TMD8 and U2932) and mantle cell lymphoma (MCL) (HBL2, Granta, Mino and Z138) were used. In addition, primary tumor cells isolated from chronic lymphocytic lymphoma (CLL) or other B-cell lymphoma patients were used. Briefly, cell lines or primary tumor cells were exposed to escalating doses of HK2-001 alone or in combination with different chemotherapy agents (doxorubicin, dexamethasone), targeted agents (i.e. burton tyrosine kinase inhibitors, BH3 mimetics) or monoclonal anti-CD20 antibodies. Cell viability was evaluated using the Presto Blue assay in experiments testing pharmacological interactions between HK2-001 and chemotherapy or targeted agents. All experiments were performed in triplicates in three separate experiments. The coefficient of synergy was calculated using CalcuSyn.

Results: In vitro exposure of lymphoma cell lines to HK2-001 induced cell death in a panel of B-cell lymphoma cell lines representing rituximab/chemo-sensitive and resistant lymphoma. In addition, synergistic activity was observed between HK2-001 and doxorubicin, ibrutinib, and Venetoclax. These effects were also observed in primary tumor cells isolated from B-cell lymphoma patients. In addition, HK2-001 potentiated the anti-tumor activity of Rituximab and Obinutuzumab ex vivo.

Conclusion: We developed a novel peptide targeting HK2. Pre-clinical studies suggested anti-tumor activity as a single agent. More importantly, HK2-001 enhanced the anti-tumor activity of chemotherapy agents, BTK inhibitors, BH3 mimetics and monoclonal antibodies targeting CD20. HK2-001 is a promising novel therapeutic strategy for against B-cell lymphoma, especially in refractory or relapsed patients. Future studies aimed to evaluate the effects of HKII-001 drug combinations in lymphoma animal models are planned and to evaluate its effects on Chimeric antigen receptor T-cells (CART) or bi-specific antibodies.