Advanced cancer cells show higher invasive, anti-anoikis, angiogenesis, and metastatic abilities. Several members of CCN [CTGF (connective tissue growth factor), Cyr61 (cysteine-rich 61), Nov (nephroblastoma overexpressed)] family can modulate these phenotypes of human carcinoma. CTGF is highly expressed in normal lung epithelium. We investigated the possibility that CTGF may regulate human lung adenocarcinoma metastasis activities. Overexpression of CTGF in CL1-5 and A549 cells decreased invasiveness and lung metastasis relative to control cells. CTGF-mediated CRMP-1 (collapsin response mediator protein-1) up-regulation was also noted in CTGF transfected clones, and was inhibited by anti-integrin AvB3 and AvB5 antibodies. Significantly, suppression of CRMP-1 expression by antisense oligonucleotides increased invasive ability. We also clarified the CT domain of CTGF as the major component responsible for CRMP-1 up-regulation and invasion inhibition. Immunohistochemistry of lung cancer specimens showed that reduced expression of CTGF was statistically significantly associated with advanced disease, lymph node metastasis, early postoperative relapse, and shorter survival. Because the first step of metastasis is to detach from the primary tumor mass and survive in the bloodstream, we analyzed several lung cancer cell lines which expressed different levels of CTGF undergo apoptosis in anoikis condition in order to understand whether CTGF is involved in anoikis regulation. In the chapter 3, we demonstrated that highly CTGF expressed cells showed increased sensitivity to anoikis, and were correlated with the expression of DAPK (death associated protein kinase), a newly identified protein kinase associated with apoptosis. We further found DAPK is upregulated in CTGF-overexpressed clones, and transiently transfected dominant-negative DAPK diminished DNA fragmentation after detachment in CTGF-overexpressed clones. The CT module of CTGF was also the region primarily responsible for the induction of DAPK via ERK/Elk-1 signaling pathway. In chapter 4, due to the significant inverse correlation between CTGF expression and tumor size in lung adenocarcinoma patients ( P < 0.041 ), we investigated the angiogenic and tumorigenic potential of CTGF-overexpressed CL1-5 lung adenocarcinoma cells. We identified consistently inverse correlation between CTGF and VEGF (vascular endothelial growth factor) or CD31 staining in cancerous tissue than in adjacent noncancer part in lung adenocarcinoma patient. In vitro study showed that CTGF inhibited VEGF, and HIF-1a (hypoxia-inducible factor) mRNA and protein expression, and decreased HRE (hypoxia-response element) luciferase activities. We further identified that CTGF inhibited in vivo tumor growth and in vitro and in vivo angiogenesis of lung adenocarcinoma cell lines. At molecular level, CTGF inhibited HIF-1a expression via destabilization of HIF-1a by ARD1-mediated acetylation. In summary, these studies provide evidences for the tumor metastasis suppressing effect of CTGF in the lung adenocarcinoma. Herein, as an invasion blocker, anoikis promoter and angiogenesis inhibitor that specifically targets cancer cells, CTGF has a unique potential for lung adenocarcinoma treatment.