ABSTRACT
Tumor metastasis depends on the dynamic balance of the actomyosin cytoskeleton. As a key component of actomyosin filaments, non-muscle myosin-IIA disassembly contributes to tumor cell spreading and migration. However, its regulatory mechanism in tumor migration and invasion is poorly understood. Here, we found that oncoprotein hepatitis B X-interacting protein (HBXIP) blocked the myosin-IIA assemble state promoting breast cancer cell migration. Mechanistically, mass spectrometry analysis, co-immunoprecipitation assay and GST-pull down assay proved that HBXIP directly interacted with the assembly-competent domain (ACD) of non-muscle heavy chain myosin-IIA (NMHC-IIA). The interaction was enhanced by NMHC-IIA S1916 phosphorylation via HBXIP-recruited protein kinase PKCβII. Moreover, HBXIP induced the transcription of PRKCB, encoding PKCβII, by coactivating Sp1, and triggered PKCβII kinase activity. Interestingly, RNA sequencing and mouse metastasis model indicated that the anti-hyperlipidemic drug bezafibrate (BZF) suppressed breast cancer metastasis via inhibiting PKCβII-mediated NMHC-IIA phosphorylation in vitro and in vivo. We reveal a novel mechanism by which HBXIP promotes myosin-IIA disassembly via interacting and phosphorylating NMHC-IIA, and BZF can serve as an effective anti-metastatic drug in breast cancer.
ABSTRACT
The effect of temperature on the pH-dependence of actomyosin superprecipitation was studied, using actomyosin extracted from the rabbit and frog skeletal muscle tissues. The pH optima of superprecipitation was rather broad in both the rabbit and frog actomyosin. In the frog, superprecipitation measured at 16-42 degrees C was relatively independent of pH variations between 6.7 to 8.5, but it was significantly inhibited at pHs outside of this range, showing a sharp inflection of the curve. The pH at the inflection point was inversely proportional to the incubation temperature, but the (OH-)/(H+) ratio at the inflection point was not changed with temperature. The log (OH-)/(H+) was approximately -0.6 on the acidic side and 3.16 on the alkaline side. Similarly, superprecipitation of the frog actomyosin was virtually independent of the medium pH of the intermediate range (approximately 6.0-8.5); but it was drastically inhibited at pHs below or above this range, thus revealing a sharp inflection of the curve. Again, the pH at the inflection point changed inversely with temperature, preserving a constant (OH-)/(H+) ratio. The log (OH-)/(H+) ratio at the inflection point was approximately -2 on the acidic side and 3.5 on the alkaline side. The above pH effects were not associated with irreversible protein damage or with the changes in buffer species. These results strongly suggest that suppression of the superprecipitation of rabbit and frog actomyosin gels, at a low and high pH, be due to alterations in the fractional dissociation of histidine-imidazole and cysteine-SH groups, respectively.