School of Biomedical Engineering and Sciences and Department of Mechanical Engineering, Virginia Tech, Blacksburg, Virginia 24060, USA.
Int J Hyperthermia. 2010;26(8):748-64. doi: 10.3109/02656736.2010.486778. Epub 2010 Sep 21.
Hyperthermia can induce heat shock protein (HSP) expression in tumours, which will cause enhanced tumour viability and increased resistance to additional thermal, chemotherapy, and radiation treatments. The study objective was to determine the relationship of hyperthermia protocols with HSP expression kinetics and cell death and develop corresponding computational predictive models of normal and cancerous prostate cell response.
HSP expression kinetics and cell viability were measured in PC3 prostate cancer and RWPE-1 normal prostate cells subjected to hyperthermia protocols of 44° to 60°C for 1 to 30 min. Hsp27, Hsp60, and Hsp70 expression kinetics were determined by western blotting and visualised with immunofluorescence and confocal microscopy. Based on measured HSP expression data, a mathematical model was developed for predicting thermally induced HSP expression. Cell viability was measured with propidium iodide staining and flow cytometry to quantify the injury parameters necessary for predicting cell death following hyperthermia.
Significant Hsp27 and Hsp70 levels were induced in both cell types with maximum HSP expression occurring at 16 h post-heating, and diminishing substantially after 72 h. PC3 cells were slightly more sensitive to thermal stress than RWPE-1 cells. Arrhenius analysis of injury data suggested a transition between injury mechanisms at 54°C. HSP expression and injury models were effective at predicting cellular response to hyperthermia.
Measurement of thermally induced HSP expression kinetics and cell viability associated with hyperthermia enabled development of thermal dosimetry guidelines and predictive models for HSP expression and cell injury as a function of thermal stress to investigate and design more effective hyperthermia therapies.
热疗可诱导肿瘤中热休克蛋白(HSP)的表达,从而导致肿瘤活力增强,并增加对额外热疗、化疗和放疗的抵抗力。本研究旨在确定热疗方案与 HSP 表达动力学和细胞死亡的关系,并开发相应的正常和癌变前列腺细胞反应的计算预测模型。
将 HSP27、HSP60 和 HSP70 的表达动力学通过蛋白质印迹法进行测量,并通过免疫荧光和共聚焦显微镜进行可视化,检测接受 44°C 至 60°C、1 至 30 分钟的热疗方案的 PC3 前列腺癌细胞和 RWPE-1 正常前列腺细胞中的 HSP 表达动力学和细胞活力。基于测量的 HSP 表达数据,开发了用于预测热诱导 HSP 表达的数学模型。通过碘化丙啶染色和流式细胞术测量细胞活力,以量化预测热疗后细胞死亡所需的损伤参数。
两种细胞类型均显著诱导了 Hsp27 和 Hsp70 水平,最大 HSP 表达发生在加热后 16 小时,72 小时后显著减少。PC3 细胞比 RWPE-1 细胞对热应激略敏感。损伤数据的 Arrhenius 分析表明,在 54°C 时,损伤机制发生了转变。HSP 表达和损伤模型能够有效地预测细胞对热疗的反应。
测量与热疗相关的热诱导 HSP 表达动力学和细胞活力,使制定热剂量学指南和 HSP 表达和细胞损伤的预测模型成为可能,这些模型可作为热应激的函数来研究和设计更有效的热疗疗法。
