Functional characterization and localization of a Bacillus subtilis sortase and its substrate and use of this sortase system to covalently anchor a heterologous protein to the B. subtilis cell wall for surface display.

Sortases catalyze the covalent anchoring of proteins to the cell surface on Gram-positive bacteria. Bioinformatic analysis suggests the presence of structural genes encoding sortases and their substrates in the Bacillus subtilis genome. In this study, a ß-lactamase reporter was fused to the cell wall anchoring domain from a putative sortase substrate, YhcR. Covalent anchoring of this fusion protein to the cell wall was confirmed by using the eight-protease-deficient B. subtilis strain WB800 as the host. Inactivation of yhcS abolished the cell wall anchoring reaction. The amounts of fusion protein anchored to the cell wall were proportional to the levels of YhcS. These data demonstrate that YhcS and YhcR are the sortase and sortase substrate, respectively, in B. subtilis. Furthermore, yhcS is not essential for the survival of B. subtilis under the cultivation condition tested. YhcR fusions were distributed helically in the lateral cell wall. Interestingly, when viewed with an epifluorescence microscope, YhcS also appeared to form short helical arcs. This is the first report to illustrate such distribution of sortases in a rod-shaped bacterium. Models for the spatial distribution of both the sortase and its substrate are discussed. The amount of the reporters displayed on the surface was unambiguously quantified via a unique strategy. Under optimal conditions with the overproduction of YhcS, 47,300 YhcR fusions could be displayed per cell. Displayed reporters were biologically functional and surface accessible. Characterization of the sortase-substrate system allowed the successful development of a YhcR-based covalent surface display system. This system may have various biotechnological applications.

Development of a LytE-based high-density surface display system in Bacillus subtilis.

The three N-terminal, tandemly arranged LysM motifs from a Bacillus subtilis cell wall hydrolase, LytE, formed a cell wall-binding module. This module, designated CWBM(LytE), was demonstrated to have tight cell wall-binding capability and could recognize two classes of cell wall binding sites with fivefold difference in affinity. The lower-affinity sites were approximately three times more abundant. Fusion proteins with ß-lactamase attached to either the N- or C-terminal end of CWBM(LytE) showed lower cell wall-binding affinity. The number of the wall-bound fusion proteins was less than that of CWBM(LytE). These effects were less dramatic with CWBM(LytE) at the N-terminal end of the fusion. Both CWBM(LytE) and ß-lactamase were essentially functional whether they were at the N- or C-terminal end of the fusion. In the optimal case, 1.2 × 10(7) molecules could be displayed per cell. As cells overproducing CWBM(LytE) and its fusions formed filamentous cells (with an average of nine individual cells per filamentous cell), 1.1 × 10(8)ß-lactamase molecules could be displayed per filamentous cell. Overproduced CWBM(LytE) and its fusions were distributed on the entire cell surface. Surface exposure and accessibility of these proteins were confirmed by immunofluorescence microscopy.

Centrosome replication in hydroxyurea-arrested CHO cells expressing GFP-tagged centrin2.

Centrosome duplication is tightly coupled with the cell cycle and neither too many nor too few centrosomes are induced in a normal cell. To study how centrosome assembly is regulated, we analyzed the abnormal process of multiple centrosome replications in Chinese hamster ovary (CHO) cells induced by hydroxyurea (HU), which is known to uncouple the centrosome cycle from the cell cycle. Green fluorescent protein (GFP)-tagged centrin2 expressed in CHO cells labels both centrioles and the pericentriolar material (PCM). Counting fluorescent spots of GFP-centrin in synchronized cells showed that in G(1)/S-arrested cells, centrioles are initially duplicated in a template manner. Further treatment with HU overrides the suppression of excess centriole/centrosome replication in a cell where the full complement of centrioles/centrosomes already exists. Time-lapse fluorescence microscopy revealed that small centrin-containing foci emerged in the cytoplasm during HU treatment. These foci are surrounded by a PCM cloud and their number continuously increases as cells are exposed to HU for longer periods of time. Both the centrosome and cytoplasmic foci are highly mobile, continuously changing their position in a manner dependent on microtubules/microtubule dynamics. The centrosome number increases as small foci grow in size and resolve into recognizable centrosomes. As this occurs in a random fashion, the cells arrested longer with HU induced highly heterogeneous numbers of centrosomes.

NK cells use perforin rather than granulysin for anticryptococcal activity.

Cytotoxic lymphocytes have the capacity to kill microbes directly; however, the mechanisms involved are poorly understood. Using Cryptococcus neoformans, which causes a potentially fatal fungal infection in HIV-infected patients, our previous studies showed that granulysin is necessary, while perforin is dispensable, for CD8 T lymphocyte fungal killing. By contrast, the mechanisms by which NK cells exert their antimicrobial activity are not clear, and in particular, the contribution of granulysin and perforin to NK-mediated antifungal activity is unknown. Primary human NK cells and a human NK cell line YT were found to constitutively express granulysin and perforin, and possessed anticryptococcal activity, in contrast to CD8 T lymphocytes, which required stimulation. When granulysin protein and mRNA were blocked by granulysin small interfering RNA, the NK cell-mediated antifungal effect was not affected in contrast to the abrogated activity observed in CD8 T lymphocytes. However, when perforin was inhibited by concanamycin A, and silenced using hairpin small interfering RNA, the anticryptococcal activities of NK cells were abrogated. Furthermore, when granulysin and perforin were both inhibited, the anticryptococcal activities of the NK cells were not reduced further than by silencing perforin alone. These results indicate that the antifungal activity is constitutively expressed in NK cells in contrast to CD8 T lymphocytes, in which it requires prior activation, and perforin, but not granulysin, plays the dominant role in NK cell anticryptococcal activity, in contrast to CD8 T lymphocytes, in which granulysin, but not perforin, plays the dominant role in anticryptococcal activity.