Mesoporous silica nanoparticle (MSN) is one of the promising nanoparticles to serve as a multifunctional vehicle due to its high surface area, uniform pore size, easy functionalization, and biocompatibility. Therefore, it becomes highly suitable for biological applications. In additional to traditional applications of mesoporous silica such as catalysis and chromatography, biomedical applications of MSN such as enzyme immobilization, gene transfection, bioimage and drug delivery agents have recently gained much attention. In the first part of the thesis, the strategy is to combine an engineered protein with MSN to demonstrate the denature protein refolded back into its native form which is probably regulated by chaperones in cells. Our result is the first to report that the denature superoxide dismutase (SOD) enzyme carried by MSN has refolded in the cell and exhibits cellular SOD activity. This novel study can be applied to a protein or enzyme-base therapy in the future. In the second part, we proposed nanoparticles served as nuclear translocation blocker by conjugating antibody to interact with transcriptional activator in the cellular signaling pathways. We first designed a smart functionalized MSN to conjugate nuclear factor-κB (NF-κB) anti-p65 antibody and human immunodeficiency virus 1 (HIV 1) transactivating domain which associated with non-endocytosis and nuclear pore complex (NPC) trapping. This smart MSN particle did exhibit cellular penetration and bind NF-κB p65 when activation, via size hindrance to disrupt the p65 translocation, downstream gene transcription and cell proliferation. Unlike existing research, our results demonstrated a novel idea to use nanoparticles as nuclear translocation blocker for further signal regulation.