Amyotrophic lateral sclerosis (ALS) is a neurodegenerative disorder characterized by progressive loss in function of motor neurons. Elevated levels of biologically important metal ions, such as copper (II) (Cu(II)), zinc (II) (Zn(II)) or iron (III) (Fe(III)), may contribute to the disease. Moreover, Cu(II) interactions with other proteins associated with ALS have been investigated; however, the effects of metallation on TAR DNA-binding protein of 43 kDa (TDP-43) are less known. The aim of the thesis was to evaluate interactions between full-length TDP-43 and metal ions, and gain insight into the mechanisms of these interactions. In Chapter 2, electrochemical methods were used to evaluate the coordination of Cu(II) ions to immobilized TDP-43. Cu(II)-TDP-43 binding was favourable at a neutral pH. Surface characterization confirmed protein immobilization and Cu(II)-TDP-43 coordination. Competitive Zn(II) ion binding studies revealed Zn(II) increases Cu(II) binding. In Chapter 3, Fe(III) ion binding studies revealed that Fe(III) reduces Cu(II) binding when co-exposed to the TDP-43-Au surface. Data shows significant uptake of Cu(II) by TDP-43 protein which may have important implications in normal and diseased states of TDP-43, indicating surface bioelectrochemistry is a viable tool for fundamental exploration of proteins and metals, and their interactions, as they inform disease mechanisms, disease detection and drug screening.
Author Keywords: Amyotrophic Lateral Sclerosis, bioelectrochemistry, electrochemistry, metalloprotein, surface characterization, TDP-43