In a recent study published in Cancer Research, researchers demonstrate the role of an oncogene in altering the immediate environment of tumors.
The tumor microenvironment (TME) is a mix of fluids, immune cells and blood vessels which envelops the tumors. Interactions between tumor cells and the TME determine the progression and fate of tumors. Therefore, understanding the composition and functions of the TME is thus very important for keeping cancer in check. Although several genetic mutations can result in the incidence of cancer, not much is known about their effects on the TME. A research team led by Chiaki Takahashi at Kanazawa University has recently reported the role of one such cancer gene, RB, in this regard.
Retinoblastoma (RB) is a tumor-suppressing gene, mutations in which promote the growth of tumors. Therefore, the team first inactivated RB in mice with sarcoma, a type of cancer, and observed the ensuing effects on tumor growth. The tumors in these mice were indeed enlarged. Further analysis of their TME revealed the presence of new blood vessels which usually nourish cancer cells. Newly recruited immunosuppressive cells, which overpower the body’s natural defense system, were also found in the TME. Inactivation of RB thus made the TME conducive for cancer progression.
The researchers then dug deeper to investigate molecular changes in the TME. The secretion of Ccl2, a molecule that attracts immunosuppressive cells, was found to be greatly increased. Alterations in the TME, however, were not seen in mice without the Ccl2 gene, suggesting its increase as the primary culprit for the RB-mediated TME changes. To establish the relevance of these findings to human cancer, breast cancer cell lines were used. As expected, enhanced secretion of Ccl2 was also observed in the breast tumor cells with inactivated RB. In previous reports, the research team has disclosed imbalances in certain mitochondrial metabolites in RB-associated cancer. Mitochondrial superoxide (MS) is one such metabolite. To build on those findings, they examined whether altered Ccl2 secretion was related to MS imbalance in RB-associated cancer. When breast cancer cells were treated with antioxidants, which prevent the accumulation of MS, Ccl2 secretion was greatly decreased. The two were thus closely linked.
This study elucidated detailed mechanisms by which mutations in the RB gene induce changes in the TME and promote tumor growth. A deeper understanding of this dynamic will help devise tumor-suppressing strategies in cancer patients with RB mutations. Preventing mitochondrial imbalances or directly targeting Ccl2 in the TME of such patients warrant further investigation as therapeutic approaches.
Figure 1.
RB controls TME. RB inactivation induces increased secretion of CCL2 which attracts immunosuppressive cells to TME. Through this mechanism, RB controls TME.
Figure 2.
The pathway whereby RB controls CCL2. Loss of RB increases fatty acid oxidation (FAO) by activating AMP-activated protein kinase (AMPK) leading to inactivation of Acetyl-CoA carboxylase (ACC) which suppresses FAO. This promotes mitochondrial superoxide production and JNK activation which enhances CCL2 expression.
Article
Retinoblastoma inactivation induces a protumoral microenvironment via enhanced CCL2 secretion
Journal: Cancer Research
Authors: Fengkai Li, Shunsuke Kitajima, Susumu Kohno, Akiyo Yoshida, Shoichiro Tange, Soichiro Sasaki, Nobuhiro Okada, Yuuki Nishimoto, Hayato Muranaka, Naoko Nagatani, Misa Suzuki, Sayuri Masuda, Tran C. Thai, Takumi Nishiuchi, Tomoaki Tanaka, David A. Barbie, Naofumi Mukaida, and
DOI:
Funder
Funding Program for Next Generation World-Leading Researchers LS049 (C.T.), Grant-in-Aid for Scientific Research on Innovative Areas 15H01487 and 17H05615 (C.T.), Grant-in-Aid for Scientific Research 17H03576 (C.T.) and 25830077 (S.K.), Hokuriku Bank Research Grant for Young Scientist (S.K.), the Uehara Memorial Foundation Post-Doctoral Fellowship (S.K.), the Strategic Young Researcher Overseas Visit Program for Accelerating Brain Circulation (S.K.), and JSPS Postdoctoral Fellowship for Research Abroad (S.K.).