Effects of Substitution Ratios of Zinc-Substituted Hydroxyapatite on Adsorption and Desorption Behaviors of Bone Morphogenetic Protein-2.

Understanding interactions between bone morphogenetic proteins (BMPs) and biomaterials is of great significance in preserving the structure and bioactivity of BMPs when utilized in clinical applications. Currently, bone morphogenetic protein-2 (BMP-2) is one of the most important growth factors in bone tissue engineering; however, atomistic interactions between BMP-2 and zinc-substituted hydroxyapatite (Zn-HAP, commonly used in artificial bone implants) have not been well clarified until now. Thus, in this work, the interaction energies, binding/debinding states, and molecular structures of BMP-2 upon a series of Zn-HAP surfaces (Zn-HAPs, 1 at%, 2.5 at%, 5 at%, and 10 at% substitution) were investigated by hybrid molecular dynamics (MD) and steered molecular dynamics (SMD) simulations. Meanwhile, cellular studies including alkaline phosphatase (ALP) activity and reverse transcription-polymerase chain reaction (RT-PCR) assay were performed to verify the theoretical modeling findings. It was found that, compared to pure HAP, Zn-HAPs exhibited a higher binding affinity of BMP-2 at the adsorption process; meanwhile, the detachment of BMP-2 upon Zn-HAPs was more difficult at the desorption process. In addition, molecular structures of BMP-2 could be well stabilized upon Zn-HAPs, especially for Zn10-HAP (with a 10 at% substitution), which showed both the higher stability of cystine-knots and less change in the secondary structures of BMP-2 than those upon HAP. Cellular studies confirmed that higher ALP activity and osteogenic marker gene expression were achieved upon BMP-2/Zn-HAPs than those upon BMP-2/HAP. These findings verified that Zn-HAPs favor the adsorption of BMP-2 and leverage the bioactivity of BMP-2. Together, this work clarified the interaction mechanisms between BMP-2 and Zn-HAPs at the atom level, which could provide new molecular-level insights into the design of BMP-2-loaded biomaterials for bone tissue engineering.

Size-fitting effect for hybridization of DNA/mercaptohexanol mixed monolayers on gold.

In this article we proposed a simple hexagonal model for exploring the hybridization of thiol-modified probe DNA self-assembled monolayers (SAMs) on gold with target DNA molecules in solution. The size-fitting coefficient d(c)/d(t) from the model was used to discuss the principle for DNA optimal hybridization, where d(c) was the channel diameter among three adjacent probe DNA molecules on gold and dt was the gyration diameter of the target DNA molecules in solution. Experimentally we investigated the hybridization effect (hybridization efficiency H(E) and hybridization density H(D)) of thiol-modified probe DNA (DNA base amount m = 15, 25 or 35)/mercaptohexanol (MCH) mixed SAMs on gold in 1 M electrolyte solution by chronocoulometry (CC) and electrochemical impedance spectroscopy (EIS). The surface coverage Γ(m) of the probe DNA on gold was adjusted by changing the mixed concentration ratio of probe DNA with MCH (C(DNA)/C(MCH)) in the assembly solution. Results indicated that with the increase of C(DNA)/C(MCH), H(E) decreased gradually; H(D) first increased and then decreased, which arrived at the biggest at C(DNA)/C(MCH) = 1 for all the probe DNA/MCH mixed SAMs (m = 15, 25, 35). The optimal Γ(m) for achieving the biggest H(D) in DNA hybridization decreased with the increase of m from 15 to 35. The experimental conclusions obtained by CC and EIS measurements verified each other. Combining the simple model with our experimental results, we ascertained that d(c)/d(t) decreased with the increase of m, which showed a good linear relationship. These conclusions provided an important reference and guidance for controllably constructing DNA sensors with optimal performance.