cell death. Our TEM images demonstr

cell death. Our TEM images demonstrate the obvious differences in
cell boundary between these two-type bacteria tested in our
experiment. M. caseolyticus,aGþ bacterium, showed a thick cell
boundary (Fig. 1b e M. caseolyticus A), while cell boundary of
P. fluorescens,aG
bacterium was much thinner, (Fig. 1a e
P. fluorescens A). More lipid oxidation was noticed with Gþ bacterium,
M. caseolyticus, than G
bacterium P. fluorescens (Fig. 3a).
These observations are consistent with the hypothesis proposed by
van Grieken et al. (2010) and indicate that G
bacteria could be
more vulnerable to antimicrobial treatments, such as TiO2 under
UVA light, than Gþ bacteria in some cases.
Kþ plays an important role in the cell biology and usually exists
only in cytoplasm. Therefore, Kþ levels in the culture medium can
indicate severeness of cell damage or losses in cell membrane
integrity. Our experimental results showed that Kþ levels in bacterium-TiO2
suspensions dramatically increased after treatment
and the Kþ levels of M. caseolyticus in the suspensions were higher
than that of P. fluorescens under the same conditions and at the
same sampling time. Lan et al. (Lan, Hu, Hu, & Qu, 2007) reported
that Staphylococcus aureus, a well known Gþ bacterium, released
more Kþ than E. coli,aG
bacterium, after treated with a AgBr/TiO2-
based photocatalytic nanoparticles. Our results, in line with their
finding, further show that Gþ bacteria are easier to be inactivated
by TiO2 nanoparticles than G
bacteria under UVA light.