Huaifeng Mi

Core–shell molecularly imprinted polymer nanoparticles with assistant recognition polymer chains for effective recognition and enrichment of natural low-abundance protein

Core-shell molecular imprinting of nanomaterials overcomes difficulties with template transfer and achieves higher binding capacities for macromolecular imprinting, which are more important to the imprinting of natural low-abundance proteins from cell extracts. In the present study, a novel strategy of preparing core-shell nanostructured molecularly imprinted polymers (MIPs) was developed that combined the core-shell approach with assistant recognition polymer chains (ARPCs). Vinyl-modified silica nanoparticles were used as support and ARPCs were used as additional functional monomers. Immunoglobulin heavy chain binding protein (BiP) from the endoplasmic reticulum (ER) was chosen as the model protein. The cloned template protein BiP was selectively assembled with ARPCs from their library, which contained numerous limited-length polymer chains with randomly distributed recognition and immobilization sites. The resulting complex was copolymerized onto the surface of vinyl-modified silica nanoparticles under low concentrations of the monomers. After template removal, core-shell-structured nanoparticles with a thin imprinted polymer layer were produced. The particles demonstrated considerably high adsorption capacity, fast adsorption kinetics and selective binding affinities toward the template BiP. Furthermore, the synthesized MIP nanoparticles successfully isolated cloned protein BiP from protein mixtures and highly enriched BiP from an ER extract containing thousands of kinds of proteins. The enrichment reached 115-fold and the binding capacity was 5.4 μg g(-1), which were higher than those achieved by using traditional MIP microspheres. The advantageous properties of MIP nanoparticles hold promise for further practical applications in biology, such as protein analysis and purification.

The design of protein-imprinted polymers as antibody substitutes for investigating protein–protein interactions

Co-immunoprecipitation is a very effective method for studying protein-protein interactions. However, the preparation of antibodies in this method involves the injection of antigen into mammals, and requires the use of the expensive protein A-Sepharose 4B. Molecular imprinting polymer can compensate for these deficiencies. In this paper, a new strategy for studying protein interactions is reported; this method is based on the use of protein-imprinted polymers (PIPs). PIP is a proper substitute for antibody. We designed and synthesized assistant recognition polymer chains (ARPCs), which were limited length polymer chains with randomly distributed recognition and immobilizing sites. The template protein was selectively assembled with ARPCs. The assemblies were adsorbed by macroporous microspheres, and were immobilized by cross-linking polymerization. After removing the templates, the two kinds of synthesized PIPs were used to adsorb natural BiP or FKBP23 from ER extract; both showed high selectivity. Furthermore, we investigated the binding specificity of BiP to FKBP23, using synthesized PIPs. The results showed that FKBP23 could bind to BiP in ER in a process regulated by the concentration of Ca(2+), which was consistent with the immunoprecipitation results. This strategy may provide a general solution for investigating protein interactions.

Two-step purification of low-content cellular protein using protein-imprinted polymers

We introduce a new method, based on molecular imprinting, for purification of low-content cellular protein. This is a combination method that uses two types of protein-imprinting polymers (PIPs) synthesized with limited-length polymer chains that contain randomly distributed recognition sites, namely assistant recognition polymer chains, and uses cloned bacterial protein as a template. The low-content cellular target protein was purified from cell extract by this method. This is believed to be the first time that low-content cellular protein has been purified by using PIPs and with only two steps.

Mouse FKBP23 mediates conformer-specific functions of BiP by catalyzing Pro117 cis/trans isomerization.

FK506-binding proteins (FKBPs) are cellular receptors for the immunosuppressant FK506 and rapamycin. They belong to the ubiquitous peptidyl-prolyl cis/trans isomerases (PPIases) family, which can catalyze the cis/trans isomerization of peptidyl-prolyl bond in peptides and proteins. In previous work, we revealed that mouse FKBP23 binds immunoglobulin binding protein (BiP), the major heat shock protein (Hsp) 70 chaperone in the ER, and the binding is interrelated with [Ca(2+)]. Furthermore, the binding can suppress the ATPase activity of BiP through the PPIase activity of FKBP23. In this work, FKBP23 is demonstrated to mediate functions of BiP by catalyzing the Pro(117)cis/trans conformational interconversion in the ATPase domain of BiP. This result may provide new understanding to the novel role of PPIase as a molecular switch.

Separation/enrichment of active natural low content protein using protein imprinted polymer

We describe a new type of protein-imprinted polymer for separation/enrichment of active natural protein present at a relatively low level in cell extracts, with a cloned bacterial protein as template. In this work, cloned pig cyclophilin 18 (pCyP18) was used as template. The template protein was selectively assembled with assistant recognition polymer chains (ARPCs) from their library, which consists of numerous limited length polymer chains with randomly distributed recognition and immobilizing sites. These assemblies of protein and ARPCs were adsorbed by porous polymeric beads and immobilized by cross-linking polymerization. After removing the template, the synthesized imprinted polymer was used to adsorb authentic pCyP18 from cell extract, and its proportional content was enriched 200 times. The assay of peptidyl-prolyl cis-trans-isomerase (PPIase) activity showed that natural pCyP18 is more active than cloned pCyP18 and, in particular, it is much more sensitive to the suppressant cyclosporine A (CsA).

Preparation of molecular imprinted polymer with quaternary ammonium groups as recognition sites for separation of pig cyclophilin 18 and bovine serum albumin

We introduce a new type of molecular imprinted polymer (MIP) with immobilized assistant recognition polymer chains (ARPCs) to create effective recognition sites. In this work, cloned pig cyclophilin 18 (pCyP18) and BSA were used as templates, respectively. The template protein was selectively assembled with ARPCs from the library which consists of numerous limited length polymer chains with randomly distributed recognition sites of the quaternary ammonium cationic groups and immobilizing sites. The assemblies of protein and ARPCs were adsorbed by macroporous microspheres and immobilized by cross-linking polymerization. After removing the templates, the two kinds of synthesized MIPs were used to adsorb cloned pCyP18 and BSA from protein mixtures respectively and both showed high selectivity. It confirms that this new method is suitable to separate proteins of both low and high molecular weight. The extended experiment on adsorption of natural pCyP18 from cytosol shows that the obtained MIP using cloned protein as template can be used to enrich natural protein of low content.