Subclonal response heterogeneity to define cancer organoid therapeutic sensitivity.

IF 3.8 2区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Scientific Reports Pub Date : 2025-04-09 DOI:10.1038/s41598-025-96204-2

Jeremy D Kratz, Shujah Rehman, Katherine A Johnson, Amani A Gillette, Aishwarya Sunil, Peter F Favreau, Cheri A Pasch, Devon Miller, Lucas C Zarling, Austin H Yeung, Linda Clipson, Samantha J Anderson, Alyssa K Steimle, Carley M Sprackling, Kayla K Lemmon, Daniel E Abbott, Mark E Burkard, Michael F Bassetti, Jens C Eickhoff, Eugene F Foley, Charles P Heise, Randall J Kimple, Elise H Lawson, Noelle K LoConte, Sam J Lubner, Daniel L Mulkerin, Kristina A Matkowskyj, Cristina B Sanger, Nataliya V Uboha, Sean J Mcilwain, Irene M Ong, Evie H Carchman, Melissa C Skala, Dustin A Deming

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Abstract

Tumor heterogeneity is predicted to confer inferior clinical outcomes with precision-based strategies, however, modeling heterogeneity in a manner that still represents the tumor of origin remains a formidable challenge. Sequencing technologies are limited in their ability to identify rare subclonal populations and predict response to treatments for patients. Patient-derived organotypic cultures have significantly improved the modeling of cancer biology by faithfully representing the molecular features of primary malignant tissues. Patient-derived cancer organoid (PCO) cultures contain subclonal populations with the potential to recapitulate heterogeneity, although treatment response assessments commonly ignore diversity in the molecular profile or treatment response. Here, we demonstrate the advantage of evaluating individual PCO heterogeneity to enhance the sensitivity of these assays for predicting clinical response. Additionally, organoid subcultures identify subclonal populations with altered treatment response. Finally, dose escalation studies of PCOs to targeted anti-EGFR therapy are utilized which reveal divergent pathway expression when compared to pretreatment cultures. Overall, these studies demonstrate the importance of population-based organoid response assessments, the use of PCOs to identify molecular heterogeneity not observed with bulk tumor sequencing, and PCO heterogeneity for understanding therapeutic resistance mechanisms.

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亚克隆反应异质性定义肿瘤类器官治疗敏感性。

肿瘤异质性被预测为基于精确的策略带来较差的临床结果，然而，以一种仍然代表肿瘤起源的方式建模异质性仍然是一个巨大的挑战。测序技术在鉴定罕见亚克隆群体和预测患者治疗反应方面的能力有限。患者来源的器官型培养通过忠实地代表原发性恶性组织的分子特征，显着改善了癌症生物学的建模。尽管治疗反应评估通常忽略了分子谱或治疗反应的多样性，但患者源性癌症类器官（PCO）培养物含有亚克隆群体，具有再现异质性的潜力。在这里，我们证明了评估个体PCO异质性的优势，以提高这些检测预测临床反应的敏感性。此外，类器官传代培养鉴定出治疗反应改变的亚克隆群体。最后，利用靶向抗egfr治疗的PCOs剂量递增研究，与预处理培养相比，揭示了不同途径的表达。总的来说，这些研究证明了基于人群的类器官反应评估的重要性，利用PCOs来识别肿瘤整体测序中未观察到的分子异质性，以及PCO异质性对理解治疗耐药机制的重要性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Scientific Reports Natural Science Disciplines-

CiteScore

7.50

自引率

4.30%

发文量

19567

审稿时长

3.9 months

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