Class A Scavenger Receptor Deficiency Exacerbates Lung Tumorigenesis by Cultivating a Procarcinogenic Microenvironment in Humans and Mice

Abstract

Genetic alterations on 8p22 have been implicated in multiple cancers, including lung cancer. In this region, genetic variants of the class A scavenger receptor (SR-A) gene have been associated with prostate cancer risk and have been highlighted as a potential susceptibility gene of cancer. To determine whether common polymorphisms in the SR-A gene are associated with human lung cancer risk and to clarify the role of SR-A in lung carcinogenesis. The relationship of three potentially functional polymorphisms (T-365C, T+25C, and Ala275Pro) in the SR-A gene with lung cancer risk was evaluated in 1287 lung cancer case subjects and 1261 control subjects from the Chinese population. At the same time, SR-A null mice were used to investigate its role in lung cancer development. The T+25C polymorphism was independently associated with lung cancer risk and significantly correlated with decreased expression of SR-A. The decreased SR-A expression was also found in tumor tissues as compared with normal tissues. Depletion of SR-A boosted the growth and angiogenesis of implanted Lewis lung carcinoma in mice. The cancer-suppressing capability of SR-A was attributable to its expression in bone marrow-derived cells as evidenced by bone marrow transplantation. Further analysis revealed augmented expression of proangiogenic factors including matrix metalloproteinase-9 (MMP9) in SR-A-deficient mice, indicative of a more procarcinogenic microenvironment. Last, zoledronate, an MMP9 inhibitor, abrogated acceleration of tumor growth conferred by SR-A loss-of-function. Evidence from the population study and mouse model strongly indicates that SR-A may function as a tumor modulator to inhibit lung cancer growth through affecting the tumor microenvironment.