A model for the dissemination of circulating tumour cell clusters involving platelet recruitment and a plastic switch between cooperative and individual behaviours.

Jorian D Hapeman, Caroline S Carneiro, Aurora M Nedelcu
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Abstract

Background: In spite of extensive research, cancer remains a major health problem worldwide. As cancer progresses, cells acquire traits that allow them to disperse and disseminate to distant locations in the body - a process known as metastasis. While in the vasculature, these cells are referred to as circulating tumour cells (CTCs) and can manifest either as single cells or clusters of cells (i.e., CTC clusters), with the latter being the most aggressive. The increased metastatic potential of CTC clusters is generally associated with cooperative group benefits in terms of survival, including increased resistance to shear stress, anoikis, immune attacks and drugs. However, the adoption of a group phenotype poses a challenge when exiting the vasculature (extravasation) as the large size can hinder the passage through vessel walls. Despite their significant role in the metastatic process, the mechanisms through which CTC clusters extravasate remain largely unknown. Based on the observed in vivo association between CTC clusters and platelets, we hypothesized that cancer cells take advantage of the platelet-derived Transforming Growth Factor Beta 1 (TGF-β1) - a signalling factor that has been widely implicated in many aspects of cancer, to facilitate their own dissemination. To address this possibility, we evaluated the effect of exogenous TGF-β1 on an experimentally evolved non-small cell lung cancer cell line that we previously developed and used to investigate the biology of CTC clusters.

Results: We found that exogenous TGF-β1 induced the dissociation of clusters in suspension into adherent single cells. Once adhered, cells released their own TGF-β1 and were able to individually migrate and invade in the absence of exogenous TGF-β1. Based on these findings we developed a model that involves a TGF-β1-mediated plastic switch between a cooperative phenotype and a single-celled stage that enables the extravasation of CTC clusters.

Conclusions: This model allows for the possibility that therapies can be developed against TGF-β1 signalling components and/or TGF-β1 target genes to suppress the metastatic potential of CTC clusters. Considering the negative impact that metastasis has on cancer prognosis and the lack of therapies against this process, interfering with the ability of CTC clusters to switch between cooperative and individual behaviours could provide new strategies to improve patient survival.

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循环肿瘤细胞群传播的模型,涉及血小板募集和合作行为与个体行为之间的塑性切换。
背景:尽管进行了广泛的研究,癌症仍然是世界范围内的一个主要健康问题。随着癌症的发展,细胞获得了一些特性,使它们能够分散并扩散到身体的远处——这一过程被称为转移。而在脉管系统中,这些细胞被称为循环肿瘤细胞(CTC),可以表现为单个细胞或细胞簇(即CTC簇),后者是最具侵略性的。CTC集群转移潜力的增加通常与生存方面的合作群体利益相关,包括对剪切应力、疾病、免疫攻击和药物的抵抗力增强。然而,采用群体表型在退出脉管系统(外溢)时提出了挑战,因为大尺寸会阻碍通过血管壁。尽管它们在转移过程中起着重要作用,但CTC簇外渗的机制仍然很大程度上未知。基于在体内观察到的CTC簇与血小板之间的关联,我们假设癌细胞利用血小板衍生的转化生长因子β1 (TGF-β1)——一种广泛涉及癌症许多方面的信号因子,来促进其自身的传播。为了解决这种可能性,我们评估了外源性TGF-β1对实验进化的非小细胞肺癌细胞系的影响,我们之前开发并用于研究CTC簇的生物学。结果:我们发现外源性TGF-β1诱导悬浮液中的细胞团解离成贴壁的单细胞。一旦粘附,细胞释放自身的TGF-β1,在没有外源TGF-β1的情况下能够独立迁移和侵袭。基于这些发现,我们建立了一个模型,该模型涉及TGF-β1介导的在合作表型和单细胞阶段之间的塑料转换,从而使CTC簇外溢。结论:该模型允许针对TGF-β1信号成分和/或TGF-β1靶基因开发治疗方法以抑制CTC簇的转移潜力的可能性。考虑到转移对癌症预后的负面影响以及缺乏针对这一过程的治疗方法,干扰CTC集群在合作行为和个体行为之间切换的能力可能为提高患者生存率提供新的策略。
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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