The Positive Enantiomer of a Novel Chiral DNA Alkylating Agent Exhibits Nanomolar Potency in Hematologic Cancers

LP-184, or (-)-hydroxyurea methylacylfulvene, is a potent DNA alkylating agent that effectively kills solid tumors. It belongs to the acylfulvene compound family known to induce DNA lesions repaired by the Transcription-Coupled Nucleotide Excision Repair (TC-NER) pathway. Here, we show that LP-284, the synthetic positive enantiomer of LP-184, exhibited the greatest and broadest hematologic cancer antiproliferative activities among the 6 acylfulvenes, including illudin S, illudin M, Irofulven (LP-100), the semisynthetic racemic LP-184, the synthetic negative enantiomer LP-184, and LP-284. The distinct pharmacological activities of LP-284 may be due to differences in metabolic activation, transport, or affinity to cellular macromolecules. To determine whether metabolic activation plays a role, we compared the correlation between the expression of Prostaglandin Reductase 1 (PTGR1), the NADPH-dependent oxidoreductase known to convert Irofulven into its active metabolite, and the IC50 of LP-184, Irofulven, and LP-284. We found that the expression level of PTGR1 is highly correlated with LP-184 (r=0.88, p=8.4e-20) and Irofulven (r=0.71, p=4.7e-10) sensitivity, but not with LP-284 (r=-0.01, p=0.93). We also found that the average expression level of PTGR1 is significantly lower in hematologic cancer cell lines (n=180) than in solid tumor cell lines (n=856), indicating the existence of an alternative LP-284 activator in hematologic cells. Next, we checked mutation status, RNA expression, protein expression, and DNA methylation of 489 oxidoreductases, but none of the enzymes was highly correlated with LP-284 activity. To further explore the potential clinical application of LP-284 in hematologic cancers, we conducted cell viability assays in 18 hematologic cancer cell lines and found that LP-284 exhibited nanomolar potency in acute lymphocytic leukemia (average IC50: 351 nM), chronic myeloid leukemia (average IC50: 360 nM), B-cell lymphoma (average IC50: 366 nM), and Multiple Myeloma (MM, IC50: 334 nM). We also investigated the therapeutic potential of LP-284 in combination with spironolactone in treating MM. Spironolactone, an FDA approved drug for hypertension, degrades one of the key TC-NER players ERCC3 in MM, which in turn makes cells more vulnerable to helix-distorting DNA lesions likely caused by LP-284. While Spironolactone alone didn't cause cytotoxicity to the MM cell line RPMI8226, it reduced LP-284 IC50 by 2.4 fold. Taken together, we have demonstrated the importance of stereochemistry in acylfulvene activity. LP-284, likely to be activated through a different route, is a unique and potent acylfulvene for hematologic cancers. Additionally, pharmacological inhibition of the TC-NER pathway greatly promoted LP-284 cytotoxicity. We hypothesize that LP-284 induces DNA lesions, which may be lethal to TC-NER deficient cells and may block transcription of short-lived fusion genes that are essential for cancer cell survival until repaired. Therefore, our discovery of the novel enantiomer LP-284 may provide a targeted therapy option for hematologic cancers with compromised DNA repair. Disclosures Zhou: Lantern Pharma: Current Employment. Biyani: Lantern Pharma: Current Employment. Kathad: Lantern Pharma: Current Employment, Current equity holder in publicly-traded company. Kulkarni: Lantern Pharma: Current Employment. McDermott: Lantern Pharma: Current Employment. Bhatia: Lantern Pharma: Current Employment.

ATR-Chk1 activation mitigates replication stress caused by mismatch repair-dependent processing of DNA damage

The mismatch repair pathway (MMR) is essential for removing DNA polymerase errors, thereby maintaining genomic stability. Loss of MMR function increases mutation frequency and is associated with tumorigenesis. However, how MMR is executed at active DNA replication forks is unclear. This has important implications for understanding how MMR repairs O6-methylguanine/thymidine (MeG/T) mismatches created upon exposure to DNA alkylating agents. If MeG/T lesion recognition by MMR initiates mismatch excision, the reinsertion of a mismatched thymidine during resynthesis could initiate futile repair cycles. One consequence of futile repair cycles might be a disruption of overall DNA replication in the affected cell. Herein, we show that in MMR-proficient HeLa cancer cells, treatment with a DNA alkylating agent slows S phase progression, yet cells still progress into the next cell cycle. In the first S phase following treatment, they activate ataxia telangiectasia and Rad3-related (ATR)-Checkpoint Kinase 1 (Chk1) signaling, which limits DNA damage, while inhibition of ATR kinase activity accelerates DNA damage accumulation and sensitivity to the DNA alkylating agent. We also observed that exposure of human embryonic stem cells to alkylation damage severely compromised DNA replication in a MMR-dependent manner. These cells fail to activate the ATR-Chk1 signaling axis, which may limit their ability to handle replication stress. Accordingly, they accumulate double-strand breaks and undergo immediate apoptosis. Our findings implicate the MMR-directed response to alkylation damage as a replication stress inducer, suggesting that repeated MMR processing of mismatches may occur that can disrupt S phase progression.

Negative hyperconjugation effect on the reactivity of phosphoramide mustard derivatives as a DNA alkylating agent: theoretical and experimental insights

In this work we suggest new factors affecting the reactivity of compounds similar to cyclophosphamide; as their reactivity mainly relies on the frontier molecular orbitals, the factors causing changes in the frontier molecular orbitals, alter the reactivity of these compounds too.