In this study, we report a facile one-step chemical method to synthesize reduced titanium dioxide (TiO$_2$) nanotube arrays (NTAs) with point defects. Treatment with NaBH$_4$ introduces oxygen vacancies (OVs) in the TiO$_2$ lattice. Chemical analysis and optical studies indicate that the OV density can be significantly increased by changing reduction time treatment, leading to higher optical transmission of the TiO$_2$ NTAs and retarded carrier recombination in the photoelectrochemical process. A cathodoluminescence (CL) study of reduced TiO$_2$ (TiO$_{2−x}$) NTAs revealed that OVs contribute significantly to the emission bands in the visible range. It was found that the TiO$_2$ NTAs reduced for a longer duration exhibited a higher concentration of OVs. A typical CL spectrum of TiO$_2$ was deconvoluted to four Gaussian components, assigned to F, F$^+$ , and Ti$^{3+}$ centers. X-ray photoelectron spectroscopy measurements were used to support the change in the surface chemical bonding and electronic valence band position in TiO$_2$. Electron paramagnetic resonance spectra confirmed the presence of OVs in the TiO$_{2−x}$ sample. The prepared TiO$_{2−x}$ NTAs show an enhanced photocurrent for water splitting due to pronounced light absorption in the visible region, enhanced electrical conductivity, and improved charge transportation.