Investigation of differences in the protein transport capability of homochiral nanochannels

Abstract

Chiral recognition plays a crucial role in the normal functioning of biological systems. The recognition of proteins in chiral environments underpins many fundamental life processes. Taking advantage of the distinct interactions between different proteins and chiral environments, this study presents the design of homochiral metal–organic framework (MOF)/nanochannels based membrane separator, enabling highly selective and high-throughput protein separation. The chiral separation membrane was fabricated by employing TiO2 nanochannel membrane (TM) as the supporting membrane and Ti ion source. Using terephthalic acid (BDC) and d/l-phenylalanine (DP/LP) as ligands, a layered TiMOF (MIL-125(Ti) used in this study) incorporating chiral selector molecules (named as DP/M and LP/M) were synthesized in situ within the TiO2 nanochannels. The bovine serum albumin (BSA) adsorption capacity of DP/M decorated TM was demonstrated to be 2.8 times higher than that of LP/M decorated TM, and was found to be related to the content of the chiral selector DP in the separation membrane. Furthermore, different recognition abilities by the chiral channels were observed for proteins with different isoelectric points. Based on a comprehensive exploration of the variations in the interaction forces between protein and chiral selector molecules, a nanoscale chromatography column-like separation model was proposed. The chiral separation membranes designed in this study provide a new platform for understanding the interactions between chiral compounds and proteins, and open up new avenues for fabricating chiral bio-interface materials, elucidating the role of chiral recognition in biological systems, and developing novel biomaterials and devices.