A Novel 2-Carbon-Linked Dimeric Artemisinin With Potent Antileukemic Activity and Favorable Pharmacology

Acute myeloid leukemia (AML) remains a devastating disease, with low cure rates despite intensive standard chemotherapy regimens. In the past decade, targeted antileukemic drugs have emerged from research efforts. Nevertheless, targeted therapies are often effective for only a subset of patients whose leukemias harbor a distinct mutational or gene expression profile and provide only transient antileukemic responses as monotherapies. We previously presented single agent and combination preclinical data for a novel 3-carbon-linked artemisinin-derived dimer (3C-ART), diphenylphosphate analog 838 (ART838), that indicates a promising approach to treat AML, given its demonstrated synergy with targeted antileukemic drugs and large therapeutic window. We now report new data from our initial evaluation of a structurally distinct class of 2-carbon-linked dimeric artemisinin-derived analogs (2C-ARTs) with prior documented in vivo antimalarial activity. These 2C-ARTs have antileukemic activity at low (nM) concentrations, have similar cooperativity with other antineoplastic drugs and comparable physicochemical properties to ART838, and provide a viable path to clinical development.

Insights into Asparaginase from Endophytic Fungus Lasiodiplodia theobromae: Purification, Characterization and Antileukemic Activity

Endobiotic fungi are considered as a reservoir of numerous active metabolites. Asparaginase is used as an antileukemic drug specially to treat acute lymphoblastic leukaemia. The presented study aims to optimize the media conditions, purify, characterize, and test the antileukemic activity of the asparaginase induced from Lasiodiplodia theobromae. The culture medium was optimized using an experiment designed by The Taguchi model with an activity ranging from 10 to 175 IU/mL. Asparaginase was induced with an activity of 315 IU/mL. Asparaginase was purified with a specific activity of 468.03 U/mg and total activity of 84.4 IU/mL. The purified asparaginase showed an approximate size of 70 kDa. The purified asparaginase showed an optimum temperature of 37 °C and an optimum pH of 6. SDS reduced the activity of asparaginase to 0.65 U/mL while the used ionic surfactants enhanced the enzyme activity up to 151.92 IU/mL. The purified asparaginase showed a Km of 9.37 µM and Vmax of 127.00 µM/mL/min. The purified asparaginase showed an IC50 of 35.2 ± 0.7 IU/mL with leukemic M-NFS-60 cell lines and CC50 of 79.4 ± 1.9 IU/mL with the normal WI-38 cell line. The presented study suggests the use of endophytic fungi as a sustainable source for metabolites such as asparaginase, provides an opportunity to develop a facile, eco-friendly, cost-effective, and rapid synthesis of antileukemic drugs, which have the potential to be used as alternative and reliable sources for potent anticancer agents.

CRCM5484: A BET- BDII Selective Compound With Differential Anti-Leukemic Drug Potentiation

Differentially screening the Fr-PPIChem chemical library on the BET BRD4-BDII versus -BDI bromodomains led to the discovery of a BDII selective tetrahydropyridothienopyrimidinone (THPTP)-based compound. Structure-activity relationship (SAR) and hit-to-lead approaches allowed us to develop CRCM5484, a highly potent inhibitor of BET proteins with a preferential and 475-fold selectivity for the second bromodomain of the BRD3 protein (BRD3-BDII) over its first bromodomain (BRD3-BDI). Its very low activity was demonstrated in various cell-based assays, corresponding with recent data describing other selective BDII compounds. However, screening on a drug sensitivity and resistance-profiling platform revealed its ability to potentiate the antileukemic activity in combination with various FDA-approved and/or in-development drugs in a cell- and context-dependent differential manner. Altogether, the results confirm the originality of the THPTP molecular mode of action in the BD cavity and its potential as chemical platform for the development of potent and selective bromodomain inhibitors.

A Novel Isoflavone, ME-344, Enhances Venetoclax Antileukemic Activity Against AML Via Suppression of Oxidative Phosphorylation and Purine Biosynthesis

The 5-year survival rate for adult patients with acute myeloid leukemia (AML) treated with cytarabine-based chemotherapy remains less than 30%, due to drug resistance and disease relapse. Recently, a selective inhibitor of anti-apoptotic Bcl-2, venetoclax, was approved by the FDA in combination with low dose cytarabine or hypomethylating agents for treating newly diagnosed AML patients who are 75 years of age or older or for those who are unfit for standard chemotherapy, providing more treatment options for this group of patients. Although the response rate to these newly approved combination therapies is reported to be 70%, the median overall survival is only 10-18 months showing that the duration of response is limited. Therefore, novel therapeutic agents are in demand to enhance venetoclax activity against AML and to combat AML resistant to cytarabine-based chemotherapy. Cytarabine-resistant AML cells lead to relapse and rely on oxidative phosphorylation (OXPHOS) for survival. In addition, it has been reported that targeting OXPHOS can enhance venetoclax activity against preclinical models of AML. Thus, we hypothesize that OXPHOS suppressing agents would be good candidates to combine with and enhance venetoclax antileukemic activity against newly diagnosed AML and those with resistance to cytarabine. A novel isoflavone, ME-344, has been shown to suppress OXPHOS in cell lines derived from solid tumors by inhibiting Complex I of the electron transport chain. We hypothesized that combining ME-344 with venetoclax would result in synergistic antileukemic activity against AML. Consistent with our hypothesis, combining ME-344 with venetoclax resulted in synergistic induction of apoptosis in AML cell lines, including those with acquired cytarabine resistance. The combination of these two agents also resulted in synergistic antileukemic activity in one primary AML patient sample, as determined by MTT assay. The combination of ME-344 and venetoclax prolonged the median survival of MV4-11 leukemia- bearing NSGS mice by 37% (median survival of 48 days compared to 35 days for vehicle control treated mice, n=5 per arm, p<0.0001). This is in contrast to the venetoclax combination with cytarabine, which prolonged median survival of the same xenograft model by 7.5% (Luedtke et al., Signal Transduction and Targeted Therapy, 2020; 5:17). ME-344 alone (9-hour treatment) reduced basal mitochondrial respiration in AML cells by 10% prior to induction of apoptosis. When treated with ME-344 for 8-hours followed by combined ME-344 and venetoclax for an additional 1-hour, basal mitochondrial respiration was reduced by 18% (again prior to detection of apoptosis initiation). This sequential combination regimen also decreased the mitochondrial membrane potential (by JC-1 staining and flow cytometry analysis) when compared to untreated control and single treatment. Additionally, apoptosis induction by the combination of ME-344 and venetoclax or ME-344 alone was significantly enhanced when AML cells were forced to utilize OXPHOS by replacing glucose with galactose in the culture medium. Further investigation revealed that apoptosis induced by ME-344 was partially attenuated when Mcl-1 was overexpressed, Bak was knocked down, or caspase activation was inhibited. This suggests a mechanism that involves components of the intrinsic apoptosis pathway. Targeted metabolomics analyses of MV4-11 cells treated with ME-344 for 8 h revealed a significant reduction of essential metabolites involved in the de novo purine biosynthesis pathway, specifically AICAR (p=0.001) and IMP (p=0.004). Given the critical role of purine in cell proliferation and survival, suppression of purine biosynthesis by ME-344 may represent a novel mechanism underlying its enhancement on the antileukemic activity of venetoclax against AML. Interestingly, inhibition of this pathway by the purine biosynthesis inhibitor lometrexol, also synergistically enhanced apoptosis in AML cells induced by venetoclax. Taken together, these results suggest that ME-344 suppresses OXPHOS and the purine biosynthesis pathway to enhance the antileukemic activity of venetoclax against AML. Further in-depth mechanistic studies into the suppression of purine biosynthesis and OXPHOS, as well as studies of ME-344 and venetoclax against cytarabine-resistant AML in a mouse model are warranted. Disclosures Wiley: MEIPharma: Current Employment.

Multifunctional nanoparticle-mediated SHARP1 knockdown in MLL-AF6 acute myeloid leukemia

Acute myeloid leukemia (AML) has an extremely poor prognosis and high relapse and fatality rates. We targeted SHARP1 using multifunctional small interfering RNA (siRNA) and bortezomib (BTZ)-loaded cRGD-guided PEGylated cationic liposomal nanoparticles to monitor their antileukemic activity in MLL-AF6 AML cells. Efficient siRNA/BTZ co-delivery by the nanoparticles significantly inhibited cell viability, decreasing clonogenic growth of AML cells and stimulating robust apoptosis. We hypothesized that SHARP1 downregulation induced nonfunctional MLL-AF6, DOT1L, MEN1, and LEDGF fusion protein accumulation, preventing MLL-AF complex formation and downregulating RAS-GTP and Bcl-2, consequently triggering autophagy and apoptosis. The BTZ combination substantially augmented therapeutic synergy leading to enhanced autophagic and apoptotic events. Our findings demonstrate a state-of-the-art biodegradable nanoplatform for siRNA/BTZ co-delivery with targeted SHARP1 knockdown, demonstrating a potential therapeutic option for MLL-AF6 AML.

Antileukemic Activity and Molecular Docking Study of a Polyphenolic Extract from Coriander Seeds

Leukemia is a group of hematological neoplastic disorders linked to high mortality rates worldwide, but increasing resistance has led to the therapeutic failure of conventional chemotherapy. This study aimed to evaluate in vitro the antileukemic activity and potential mechanism of action of a polyphenolic extract obtained from the seeds of Coriandrum sativum L. (CSP). A methylthiazoletetrazolium assay was performed to assess the CSP cytotoxicity on chronic (K562) and acute (HL60) myeloid leukemia cell lines and on normal Vero cell line. CSP toxicity was also evaluated in vivo using the OECD 423 acute toxicity model on Swiss albino mice. The results demonstrated a remarkable antitumoral activity against K562 and HL60 cell lines (IC50 = 16.86 µM and 11.75 µM, respectively) although no cytotoxicity was observed for the Vero cells or mice. A silico study was performed on the following receptors that are highly implicated in the development of leukemia: ABL kinase, ABL1, BCL2, and FLT3. The molecular docking demonstrated a high affinity interaction between the principal CSP components and the receptors. Our findings demonstrated that CSP extract has remarkable antileukemic activity, which is mainly mediated by the flavonoids, catechins, and rutin, all of which showed the highest binding affinity for the targeted receptors. This study revealed a promising active compound alternative research-oriented biopharmacists to explore.

The combination of CUDC-907 and gilteritinib shows promising in vitro and in vivo antileukemic activity against FLT3-ITD AML

About 25% of patients with acute myeloid leukemia (AML) harbor FMS-like tyrosine kinase 3 (FLT3) internal tandem duplication (ITD) mutations and their prognosis remains poor. Gilteritinib is a FLT3 inhibitor approved by the US FDA for use in adult FLT3-mutated relapsed or refractory AML patients. Monotherapy, while efficacious, shows short-lived responses, highlighting the need for combination therapies. Here we show that gilteritinib and CUDC-907, a dual inhibitor of PI3K and histone deacetylases, synergistically induce apoptosis in FLT3-ITD AML cell lines and primary patient samples and have striking in vivo efficacy. Upregulation of FLT3 and activation of ERK are mechanisms of resistance to gilteritinib, while activation of JAK2/STAT5 is a mechanism of resistance to CUDC-907. Gilteritinib and CUDC-907 reciprocally overcome these mechanisms of resistance. In addition, the combined treatment results in cooperative downregulation of cellular metabolites and persisting antileukemic effects. CUDC-907 plus gilteritinib shows synergistic antileukemic activity against FLT3-ITD AML in vitro and in vivo, demonstrating strong translational therapeutic potential.