Pre-treatment with systemic agents for advanced NSCLC elicits changes in the phenotype of autologous T cell therapy products.

The antitumor activity of adoptive T cell therapies (ACT) is highly dependent on the expansion, persistence, and continued activity of adoptively transferred cells. Clinical studies using ACTs have revealed that products that possess and maintain less differentiated phenotypes, including memory and precursor T cells, show increased antitumor efficacy and superior patient outcomes owing to their increased expansion, persistence, and ability to differentiate into effector progeny that elicit antitumor responses. Strategies that drive the differentiation into memory or precursor-type T cell subsets with high potential for persistence and self-renewal will enhance adoptively transferred T cell maintenance and promote durable antitumor efficacy. Because of the high costs associated with ACT manufacturing, ACTs are often only offered to patients after multiple rounds of systemic therapy. An essential factor to consider in producing autologous ACT medicinal products is the impact of the patient's initial T cell fitness and subtype composition, which will likely differ with age, disease history, and treatment with prior anti-cancer therapies. This study evaluated the impact of systemic anti-cancer therapy for non-small cell lung cancer treatment on the T cell phenotype of the patient at baseline and the quality and characteristics of the genetically modified autologous T cell therapy product after manufacturing.

A model to identify novel targets involved in oxidative stress-induced apoptosis in human lung epithelial cells by RNA interference.

Chronic obstructive pulmonary disease (COPD) is an increasing health problem primarily associated with cigarette smoking, and one of the leading causes of morbidity and mortality worldwide. Despite recent advances in understanding the pathogenesis of the disease, overall patient outcome remains poor with limited therapeutic intervention. Chronic inflammation, an imbalance between proteolytic and anti-proteolytic activities (leading to lung parenchyma destruction) and excessive oxidative stress contribute to COPD pathophysiology. Oxidative stress-triggered apoptosis of alveolar structural cells, including epithelial cells, may be an important event in the development of COPD. In this study, we developed a cell-based oxidative stress-induced apoptosis assay and performed a high-throughput screen (HTS) using a human druggable genome siRNA library. Our results have identified potential novel pathways (e.g. unfolded protein response, proteosomal activity) and targets (e.g. MAP3K14, HMGB2) that regulate the response of lung epithelial cells to oxidative stress. This assay has proven to be a useful tool for the identification of potential new therapeutic targets for lung disease.