Concurrent inhibition of FLT3 and sphingosine kinase-1 triggers synergistic cytotoxicity in midostaurin resistant FLT3-ITD positive acute myeloid leukemia cells via blocking FLT3/STAT5A signaling to induce apoptosis.

IF 1.8 4区医学 Q3 INFECTIOUS DISEASES Journal of Chemotherapy Pub Date : 2025-03-21 DOI:10.1080/1120009X.2025.2478340

Melisa Tecik, Aysun Adan

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Abstract

The FMS-like tyrosine kinase 3-internal tandem duplication (FLT3-ITD) is one of the most frequent mutations observed in acute myeloid leukemia (AML) which contributes to disease progression and unfavorable prognosis. Midostaurin, a small FLT3 inhibitor (FLT3I), is clinically approved. However, patients generally possess acquired resistance when midostaurin used alone. Shifting the balance in the sphingolipid rheostat toward anti-apoptotic sphingosine kinase-1 (SK-1) or glucosylceramide synthase (GCS) is related to therapy resistance in cancer, however, their role in midostaurin resistant FLT3-ITD positive AML has not been previously investigated. We generated midostaurin resistant MV4-11 and MOLM-13 cell lines which showed increased IC₅₀ values compared to their sensitive partner cells. SK-1 is overexpressed in resistant cells while GCS remains unchanged. Subsequent pharmacological targeting of SK-1 in resistant cells decreased SK-1 protein level, inhibited cell proliferation and showed additive or synergistic effect on cell growth, as confirmed by the Chou-Talalay combination index, and induced G0/G1 arrest (PI staining by flow cytometry). Cotreatment (SKI-II plus midostaurin) triggered apoptosis via phosphatidylserine exposure (annexin V/PI double staining). Mechanistically, induction of the intrinsic pathway of apoptosis was confirmed as increased activating cleavages of caspase-3 and PARP and increased Bax/Bcl-2 ratios. Activating phosphorylations of FLT3 (at tyrosine residue 591) and STAT5A (at tyrosine residue 694) dramatically inhibited in resistant cells treated with the combination. In conclusion, midostaurin resistance could be reversed by dual SK-1 and FLT3 inhibition in midostaurin resistant AML cell lines, providing the first evidence of a novel treatment approach to re-sensitize FLT3-ITD positive AML.

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通过阻断FLT3/STAT5A信号通路诱导细胞凋亡，同时抑制FLT3和鞘氨醇激酶-1可触发midoatin耐药FLT3- itd阳性急性髓系白血病细胞的协同细胞毒性。

FMS样酪氨酸激酶3-内部串联重复（FLT3-ITD）是急性髓性白血病（AML）中最常见的突变之一，导致疾病进展和预后不良。Midostaurin 是一种小型 FLT3 抑制剂（FLT3I），已获得临床批准。然而，单独使用米哚妥林时，患者通常会产生耐药性。鞘脂流变的平衡转向抗凋亡的鞘氨醇激酶-1（SK-1）或葡萄糖醛酸合成酶（GCS）与癌症的耐药性有关，但它们在米哚妥林耐药的 FLT3-ITD 阳性 AML 中的作用以前尚未研究过。我们生成了耐米哚妥林的 MV4-11 和 MOLM-13 细胞系，与它们的敏感伙伴细胞相比，这些细胞系的 IC50 值有所增加。耐药细胞中 SK-1 过表达，而 GCS 保持不变。随后在耐药细胞中以 SK-1 为药理靶点，可降低 SK-1 蛋白水平，抑制细胞增殖，对细胞生长产生相加或协同效应（Chou-Talalay 综合指数证实了这一点），并诱导 G0/G1 停滞（流式细胞仪进行 PI 染色）。共处理（SKI-II 加米哚妥林）通过磷脂酰丝氨酸暴露（annexin V/PI 双染色）引发细胞凋亡。从机理上讲，凋亡内在途径的诱导被证实为 caspase-3 和 PARP 的活化裂解增加以及 Bax/Bcl-2 比率增加。用该组合治疗的耐药细胞中，FLT3（在酪氨酸残基 591 处）和 STAT5A（在酪氨酸残基 694 处）的活化磷酸化显著抑制。总之，在米哚妥林耐药的 AML 细胞系中，SK-1 和 FLT3 的双重抑制可以逆转米哚妥林的耐药性，首次证明了一种新的治疗方法可以使 FLT3-ITD 阳性的 AML 再敏感化。

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来源期刊

Journal of Chemotherapy 医学-药学

CiteScore

3.70

自引率

0.00%

发文量

144

审稿时长

6-12 weeks

期刊介绍： The Journal of Chemotherapy is an international multidisciplinary journal committed to the rapid publication of high quality, peer-reviewed, original research on all aspects of antimicrobial and antitumor chemotherapy. The Journal publishes original experimental and clinical research articles, state-of-the-art reviews, brief communications and letters on all aspects of chemotherapy, providing coverage of the pathogenesis, diagnosis, treatment, and control of infection, as well as the use of anticancer and immunomodulating drugs. Specific areas of focus include, but are not limited to: · Antibacterial, antiviral, antifungal, antiparasitic, and antiprotozoal agents; · Anticancer classical and targeted chemotherapeutic agents, biological agents, hormonal drugs, immunomodulatory drugs, cell therapy and gene therapy; · Pharmacokinetic and pharmacodynamic properties of antimicrobial and anticancer agents; · The efficacy, safety and toxicology profiles of antimicrobial and anticancer drugs; · Drug interactions in single or combined applications; · Drug resistance to antimicrobial and anticancer drugs; · Research and development of novel antimicrobial and anticancer drugs, including preclinical, translational and clinical research; · Biomarkers of sensitivity and/or resistance for antimicrobial and anticancer drugs; · Pharmacogenetics and pharmacogenomics; · Precision medicine in infectious disease therapy and in cancer therapy; · Pharmacoeconomics of antimicrobial and anticancer therapies and the implications to patients, health services, and the pharmaceutical industry.