sFRP1 Expression Regulates Wnt Signaling in Chronic Myeloid Leukemia K562 Cells.

BACKGROUND: Wnt signaling cascades play important roles in cell fate decisions and their deregulation has been documented in many diseases, including malignant tumors and leukemia. One mechanism of aberrant Wnt signaling is the silencing of Wnt inhibitors through epigenetic mechanisms. The sFRPs are one of the most studied Wnt inhibitors; and the sFRP1 loss is known in many hematological malignancies. Therefore, we aimed to compare the expression of Wnt related genes in the presence and absence of sFRP1 in a chronic myeloid leukemia (CML) cell line. OBJECTIVE: It is important to understand how sFRP1 and sFRP1 perform their effects on CML to design new agents and strategies for resistant and advanced forms of CML. MATERIALS AND METHODS: We used K562 cells, which normally do not express sFRP1 and its sFRP1 expressing subclone K562s. Total RNA was isolated from K562 and K562s cell lines and converted to cDNA. PCR Array experiments were performed using Human Wnt Signaling Pathway Plus RT2 Profiler™ kit. Wnt signaling pathway activation was studied by western blot for downstream signaling targets. RESULTS: The WNT3, LRP6, PRICKLE1 and BTRC expressions were significantly decreased in the presence of sFRP1; while WNT5B increased. The sFRP1 expression inhibited stabilization of total ß-catenin protein and downstream effector phosphorylation of noncanonical Wnt/PCP signaling; whereas Ca2+/PKC signaling remained active. CONCLUSION: The results suggest that sFRP1 could be a promising therapeutic anticancer agent. Defining these pathway interactions is crucial for designing new agents resistant and advanced forms of CML.

Systematic mapping of WNT-FZD protein interactions reveals functional selectivity by distinct WNT-FZD pairs.

The seven-transmembrane-spanning receptors of the FZD1-10 class are bound and activated by the WNT family of lipoglycoproteins, thereby inducing a complex network of signaling pathways. However, the specificity of the interaction between mammalian WNT and FZD proteins and the subsequent signaling cascade downstream of the different WNT-FZD pairs have not been systematically addressed to date. In this study, we determined the binding affinities of various WNTs for different members of the FZD family by using bio-layer interferometry and characterized their functional selectivity in a cell system. Using purified WNTs, we show that different FZD cysteine-rich domains prefer to bind to distinct WNTs with fast on-rates and slow off-rates. In a 32D cell-based system engineered to overexpress FZD2, FZD4, or FZD5, we found that WNT-3A (but not WNT-4, -5A, or -9B) activated the WNT-ß-catenin pathway through FZD2/4/5 as measured by phosphorylation of LRP6 and ß-catenin stabilization. Surprisingly, different WNT-FZD pairs showed differential effects on phosphorylation of DVL2 and DVL3, revealing a previously unappreciated DVL isoform selectivity by different WNT-FZD pairs in 32D cells. In summary, we present extensive mapping of WNT-FZD cysteine-rich domain interactions complemented by analysis of WNT-FZD pair functionality in a unique cell system expressing individual FZD isoforms. Differential WNT-FZD binding and selective functional readouts suggest that endogenous WNT ligands evolved with an intrinsic natural bias toward different downstream signaling pathways, a phenomenon that could be of great importance in the design of FZD-targeting drugs.