Phosphoproteomics guides low dose drug combination of cisplatin and silmitasertib against concurrent chemoradiation resistant cervical cancer†

IF 3 4区生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY Molecular omics Pub Date : 2024-11-27 DOI:10.1039/D4MO00147H

Irene A. George, Janani Sambath, R. E. Dhawale, Manisha Singh, Vinita Trivedi, R. Venkataramanan, Richa Chauhan and Prashant Kumar

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Abstract

Cisplatin-based concurrent chemoradiotherapy (CCRT) is the standard treatment for cervical patients with locally advanced disease. Despite the improved survival rates and prognosis observed in patients undergoing CCRT, over 30–40% do not achieve complete response and are at risk of locoregional recurrence. Targeting crucial molecules that confer resistance may improve the clinical outcomes of the treatment resistant patient cohort. Herein, we employed a liquid chromatography-tandem mass spectrometry (LC-MS/MS)-based phosphoproteomic approach to identify the altered phosphophorylation events, activated kinases and dysregulated pathways involved in treatment resistance. We quantified 2531 unique phosphopeptides mapping to 1099 proteins of which 74 proteins were differentially phosphorylated between the cohorts. Pathway analysis revealed dysregulation of the DNA repair pathway and the proteins involved in DNA repair in the non-responder cohort. Additionally, we identified kinase signature associated with CCRT resistance. Kinases such as CSNK2A1, PRKDC, PLK-1, NEK2, ATM and CDK1 are predicted to be activated in non-responders. In particular, we showed that CSNK2A1 is involved in oncogenesis of cervical cancer and pharmacological inhibition led to reduced cell proliferation, migration and colony formation. Moreover, the combination of the CSNK2A1 inhibitor, silmitasertib with cisplatin demonstrated synergism (combination index < 1) and yielded a beneficial reduction in dosage. The dose reduced combination potentially reduced the proliferative, migratory and colony formation ability in vitro. Our findings highlight the potential of phosphoproteomics to identify clinically significant targets and pathways implicated in CCRT resistance. Our study also indicates that combination therapy could serve as an effective treatment strategy to improve the efficacy of patients undergoing CCRT.

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磷蛋白质组学指导顺铂和silmitasertib低剂量联合治疗同步放化疗耐药宫颈癌。

以顺铂为基础的同步放化疗（CCRT）是局部晚期宫颈患者的标准治疗方法。尽管在接受CCRT的患者中观察到生存率和预后的改善，但超过30-40%的患者没有达到完全缓解，并且存在局部复发的风险。靶向产生耐药性的关键分子可能会改善耐药患者群体的临床结果。在此，我们采用液相色谱-串联质谱（LC-MS/MS）为基础的磷酸化蛋白质组学方法来鉴定与治疗抗性相关的磷酸化事件、活化激酶和失调通路的改变。我们量化了2531个独特的磷酸化肽，映射到1099个蛋白质，其中74个蛋白质在队列中磷酸化差异。途径分析显示，在无应答队列中，DNA修复途径和参与DNA修复的蛋白质出现了失调。此外，我们还发现了与CCRT耐药相关的激酶信号。预计CSNK2A1、PRKDC、PLK-1、NEK2、ATM和CDK1等激酶在无应答者中被激活。特别是，我们发现CSNK2A1参与宫颈癌的肿瘤发生，药理抑制导致细胞增殖、迁移和集落形成减少。此外，CSNK2A1抑制剂silmitasertib与顺铂联用显示出协同作用（联合指数< 1），并产生有益的剂量减少。剂量降低组合可能降低体外增殖、迁移和集落形成能力。我们的研究结果强调了磷酸蛋白组学在鉴别与CCRT耐药相关的临床重要靶点和途径方面的潜力。我们的研究也表明，联合治疗可以作为一种有效的治疗策略来提高CCRT患者的疗效。

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来源期刊

Molecular omics Biochemistry, Genetics and Molecular Biology-Biochemistry

CiteScore

5.40

自引率

3.40%

发文量

期刊介绍： Molecular Omics publishes high-quality research from across the -omics sciences. Topics include, but are not limited to: -omics studies to gain mechanistic insight into biological processes – for example, determining the mode of action of a drug or the basis of a particular phenotype, such as drought tolerance -omics studies for clinical applications with validation, such as finding biomarkers for diagnostics or potential new drug targets -omics studies looking at the sub-cellular make-up of cells – for example, the subcellular localisation of certain proteins or post-translational modifications or new imaging techniques -studies presenting new methods and tools to support omics studies, including new spectroscopic/chromatographic techniques, chip-based/array technologies and new classification/data analysis techniques. New methods should be proven and demonstrate an advance in the field. Molecular Omics only accepts articles of high importance and interest that provide significant new insight into important chemical or biological problems. This could be fundamental research that significantly increases understanding or research that demonstrates clear functional benefits. Papers reporting new results that could be routinely predicted, do not show a significant improvement over known research, or are of interest only to the specialist in the area are not suitable for publication in Molecular Omics.