Engineering Functional Biomaterials to Advance Environmental and Resource Sustainability
Advisor: Professor Na Wei
Date: Tuesday Sep 3rd, 7:30am-9:30am
Location: Zoom meeting (ID: 2646521647; Password: 591564)
(https://illinois.zoom.us/j/2646521647?pwd=TGdndGdWNG5QK3oyNGh1V3ZmRnpwUT09&omn=86760292225)
Abstract
Recovering resources from waste streams offers a sustainable solution to the growing scarcity of resources and the increasing environmental impact of waste. A significant challenge lies in efficiently extracting or converting valuable resources from complex waste mixtures into recoverable forms. In recent years, protein-based biosorption and biocatalysis have emerged as promising alternatives to conventional methods due to their inherent advantages, such as strong substrate affinity, selectivity, rapid adsorption kinetics, potent enzymatic activity, and minimal energy and chemical requirements. The ability to engineer and manipulate proteins opens avenues for creating innovative biomaterials with tailored functionalities, addressing critical environmental and resource sustainability challenges.
This dissertation aims to develop novel protein-based biosorbents and enzyme-based biocatalysts for resource recovery, separation, and conversion applications. The research focuses on three key objectives: (1) designing a novel magnetic nanoplatform for protein immobilization; (2) evaluating this nanoplatform by fabricating protein-based biosorbents for the selective recovery and efficient separation of rare earth elements (REEs); and (3) engineering renewable enzyme biocatalysts for phosphate conversion and recovery from biorefinery waste streams. These findings contribute to advancing innovative biosorptive and biocatalytic technologies, addressing critical resource recovery challenges, and promoting sustainable management of phosphorus and rare earth elements, thus fostering a more sustainable Earth.
First, we employed SpyTag-SpyCatcher chemistry to conjugate model proteins onto magnetic nanoparticles (MNPs), establishing a modular, magnetic-responsive platform for protein immobilization. This approach significantly enhanced protein stability while retaining functionality. The protein-immobilized MNPs also maintained high colloidal stability and magnetic responsiveness in solution, enabling convenient protein separation and reuse.
Next, leveraging the developed nanoplatform, we created a highly specific and reusable lanmodulin-based biosorbent for efficient REE recovery from low-grade waste streams. This biosorbent demonstrated high selectivity, rapid adsorption-desorption kinetics, and stability through multiple uses. Additionally, by immobilizing the Hans-LanM protein onto magnetic nanoparticles, we engineered another novel biosorbent that could effectively separate REE pairs and groups.
Finally, we developed a renewable surface-displayed phytase biocatalyst for efficient phosphate conversion and recovery from biorefinery waste streams. This biocatalyst exhibited high activity, storage stability, easy regenerability, and reusability. We also employed a machine learning algorithm to identify phytase variants with enhanced activity and robustness against inhibitory substances in biorefinery solutions.