6), and indicates that the release of NTD is not

just a response to the Tris–HCl buffer environment. This is not consistent with the ‘anchorless’ proteins thus far identified, including enolase and GAPDH, whose dissociation from the outer surface of Lactobacillus see more crispatus was favored when the pH was above the isoelectric point of these enzymes (Antikainen et al., 2007b). It has been reported that treatment with buffers normally used for cell washing (Tris–HCl or PBS) at pH 7.3 allowed the extraction of 12-fold higher protein concentrations compared with buffers adjusted to pH 4 (Sanchez et al., 2009), suggesting that most of the surface-associated proteins that interact with the cell envelop may depend on electrostatic interactions and thus are sensitive to pH. However, this does not apply to NTD. Further research is necessary to explore in detail the mechanism involved.

To determine whether the NTD activity also presents on the lactobacillus surface, enzymatic assay was carried out using whole lactobacillus cells. However, it is conceivable DAPT cost that lactobacillus cells may take up the highly concentrated substrates efficiently as other bacteria, as there have been many reports concerning nucleoside synthesis using bacteria whole cells (Fernandez-Lucas et al., 2007; Zheng et al., 2008), which implies that a set of membrane transportation system exists to facilitate the substrate import and product export. This uptake occurs very fast due to Nucleoside-specific membrane transporters in lactic acid bacteria (Kilstrup et al., 2005; Martinussen et al.,

2010), namely, the conversion of nucleoside may be attributed to cytoplasmic enzyme when a whole cell assay was performed. Thus, considering that the 17-DMAG (Alvespimycin) HCl incubation in conventional buffer will strip most of the NTD from the cell surface (Fig. 5a), whole cells after incubation in PBS-citrate buffer for 40 min were used in the same assay as a control. If surface-located NTD retain its biologic activity, washed cells were supposed to exhibit lower catalysis rate at the start point, at which time the activity of intracellular enzymes is yet limited by transportation kinetics. Data presented in Fig. 6 reveal a significantly reduced catalysis activity of washed whole cells after 1 min reaction. However, as the reaction time increases, the activity difference between washed cells and original cells gradually diminishes. This is consistent with our assumption that the uptake kinetics of nucleoside by lactobacillus is fairly fast. In a short period of reaction time, the conversion was mainly catalyzed by surface enzyme, as time elapsed, intracellular enzyme activity became dominant due to the function of membrane-located substrate and product transporters. From a physiologic point of view, the presence of NTD at the outside is puzzling, as the role of the enzyme is to balance the deoxynucleotide pools inside the cell (Kilstrup et al., 2005).