The Salmonella SPI-2 effector SseJ exhibits eukaryotic activator-dependent phospholipase A and glycerophospholipid : cholesterol acyltransferase activity

Intracellular replication of Salmonella enterica serovar Typhimurium within membrane-bound compartments, called Salmonella-containing vacuoles, depends on the activities of several effector proteins translocated by the Salmonella pathogenicity island 2 (SPI-2)-encoded type III secretion system. The SPI-2 effector protein SseJ shows similarity at the amino acid level to several GDSL lipases with glycerophospholipid : cholesterol acyltransferase (GCAT) activity. In this study, we show that catalytic serine-dependent phospholipase A (PLA) and GCAT activity of recombinant SseJ is potentiated by factor(s) present in HeLa cells, RAW macrophages and Saccharomyces cerevisiae. SseJ activity was enhanced with increasing amounts of, or preincubation with, eukaryotic cell extracts. Analysis of the activating factor(s) shows that it is soluble and heat- and protease-sensitive. We conclude that PLA and GCAT activities of SseJ are potentiated by proteinaceous eukaryotic factor(s).


INTRODUCTION
Salmonella enterica serovar Typhimurium (S. Typhimurium) invades a variety of host cell types and replicates intracellularly within a membrane-bound compartment, the Salmonellacontaining vacuole (SCV). Numerous Salmonella virulence genes are required for growth of this pathogen in mice; several of these are associated with the Salmonella pathogenicity island 2 (SPI-2) type III secretion system (T3SS). This is expressed upon bacterial entry into host cells and translocates a variety of effector proteins across the SCV into the host cell (Cirillo et al., 1998;Waterman & Holden, 2003). A functional SPI-2 T3SS is essential for intracellular survival and systemic growth of Salmonella in mice (Hensel et al., 1995;Ochman et al., 1996). Approximately 20 SPI-2 effectors have been identified to date, but their molecular functions remain largely unknown (Haraga et al., 2008;Waterman & Holden, 2003).
Interestingly, deletion of sseJ does not have a detectable effect on replication of S. Typhimurium in epithelial cells or macrophage-like cell lines, but results in a mild replication defect in elicited peritoneal macrophages (Ruiz-Albert et al., 2002) and reduced virulence after intraperitoneal inoculation of BALB/c mice (Freeman et al., 2003;Ruiz-Albert et al., 2002). SseJ has been linked functionally to SifA by virtue of the phenotype of a sifA sseJ double mutant (Ruiz-Albert et al., 2002). SifA is a SPI-2 T3SS effector required for the formation of tubules (called Sifs) that extend from SCVs in epithelial cells (Stein et al., 1996). sifA mutants fail to make Sifs and gradually lose their vacuolar membrane (Beuzon et al., 2000). However, the process of vacuolar membrane loss is significantly delayed in a sifA sseJ double mutant Ruiz-Albert et al., 2002), suggesting that SseJ may help to destabilize the SCV membrane around the sifA mutant. Furthermore, deletion of sseJ has been shown to result in increased levels of Sifs . Therefore, SseJ appears to oppose the activity of SifA.
The N-terminal domain of SseJ contains a translocation signal also found in some other SPI-2 effector proteins: SspH1, SspH2, SlrP, SifA, SifB and SseI (Miao & Miller, 2000). The C-terminal region (amino acids 140-408) is 29 % identical to several members of the GDSL lipase family, with highest similarity at the amino acid sequence level to a glycerophospholipid : cholesterol acyltransferase (GCAT) found in Aeromonas hydrophila (Brumlik & Buckley, 1996;Miao & Miller, 2000). Members of the GDSL family of lipases are characterized by the presence of a conserved GDSL motif and a catalytic triad (S-D-H) (Akoh et al., 2004;Upton & Buckley, 1995). Mutation of residues of the catalytic triad causes loss of lipolytic and acyltransferase activity (Brumlik & Buckley, 1996). Alignment of SseJ with GCAT (Flieger et al., 2002) reveals the presence of a GDSL motif as well as the conserved catalytic triad (S151, D274, H384). In agreement with these predicted catalytic residues, recent studies have shown that the virulence attenuation of DsseJ in mice cannot be rescued by expression of SseJ S151A , SseJ D274N or SseJ H384N , indicating that these residues are important for function of SseJ in vivo . In vitro, S151, D247 and H384 have been shown to be necessary for deacylase activity of recombinant SseJ , supporting the notion that these represent a catalytic triad similar to those of other GDSL lipases . Recently, SseJ has been shown to esterify cholesterol in vitro, in HeLa cells and macrophages (Nawabi et al., 2008).
In this study, we analysed the biochemical activity of SseJ. We show that SseJ exhibits phospholipase A (PLA) and GCAT activity and that both enzymic activities require the presence of a eukaryotic activator.

METHODS
Bacterial strains and growth conditions. Escherichia coli was grown in Luria-Bertani (LB) medium supplemented with carbenicillin (50 mg ml 21 ) when appropriate. Saccharomyces cerevisiae AH 109 was grown in YPD medium supplemented with 20 mg l 21 adenine hemisulfate (YPDA). Strains used in this study are summarized in Table 1.
Cell culture. HeLa (93021013) and RAW 264.7 (91962702) cells were obtained from the European Collection of Cell Cultures, Salisbury, UK, and grown in Dulbecco's modified Eagle's medium (DMEM) supplemented with 10 % fetal calf serum (FCS) and 2 mM glutamine at 37 uC in 5 % CO 2 .
Transfection. HeLa cells (5610 5 ) were seeded in six-well plates 24 h prior to transfection with lipofectamine 2000 transfection reagent according to the manufacturer's manual (Invitrogen).
GST protein purification. Expression of GST fusion proteins was induced with 0.5 mM IPTG (Sigma) in E. coli BL21 (DE3) (Amersham Biosciences) at 25 uC for 4 h prior to collection of cell pellets by centrifugation. Cells were resuspended in 40 mM Tris, pH 7.4, containing Complete protease inhibitor cocktail (Roche) and subsequently lysed by passage through a French Press. The soluble fraction was isolated by ultracentrifugation at 130 000 g and subsequently incubated with glutathione-Sepharose beads (Amersham Biosciences) for 2 h at 4 uC. Beads were washed with PBS and 40 mM Tris, 100 mM NaCl, pH 8.0, before fusion proteins were eluted using 10 mM glutathione (Sigma), dialysed in 40 mM Tris, pH 7.4, and concentrated before use using Amicon-10 filter devices (Millipore).
Cell extracts. HeLa and RAW 264.7 cells were grown in 175 cm 2 dishes to 80 % confluence, scraped into ice-cold PBS, pelleted at 200 g for 5 min and resuspended in homogenization buffer [8.5 % sucrose (w/v), 3 mM imidazole]. HeLa cells were broken by passage through a 22G needle; RAW 264.7 cells were broken by passage through a 27G needle. Postnuclear supernatant (PNS) was obtained after centrifugation at 1500 g for 5 min at 4 uC. Membranes and cytosol fractions of HeLa cells were separated by ultracentrifugation at 100 000 g for 1 h. Where indicated, HeLa cell cytosol was further treated by incubation with 250 mg trypsin ml 21 for 15 min at 30 uC, followed by addition of the trypsin inhibitor aprotinin. For preparation of Sacc. cerevisiae cell extract, Sacc. cerevisiae AH109 was grown overnight in YPDA medium at 30 uC, and cells were resuspended in 50 mM Na 3 PO 4 buffer, pH 7.4, supplemented with protease inhibitors [10 mg aprotinin ml 21 , 5 mg leupeptin ml 21 , 1 mM pepstatin A and Complete protease inhibitor cocktail (Roche)]. Cells were broken by four passages through a French Press and the soluble cell extract was obtained after pelleting of cell debris by centrifugation at 14 000 g for 30 min. E. coli BL21 soluble extract was prepared from an overnight culture resuspended in 40 mM Tris, pH 7.4, containing Complete protease inhibitor cocktail (Roche) by passage through a French Press and subsequent ultracentrifugation at 130 000 g.
Phospholipase assay. DPPC liposomes and 1-MPLPC micelles were prepared in 1 ml 40 mM Tris, pH 7.4, by sonication with a probe at a concentration of 13.4 mM. GST fusion proteins were preincubated with cell lysate for 1 h at 37 uC (30 uC for yeast cell extract), where indicated. In general, 5 mg GST fusion protein was incubated at 37 uC at pH 7.4 for 2 h with 3.35 mM DPPC liposomes (3.35 mM 1-MPLPC micelles for lysophospholipase assay), with or without cell extract (100 ml if not otherwise stated; 7 mg protein ml 21 ) in a final volume of 200 ml. Porcine liver PLA2 was used as a positive control in 40 mM Tris, pH 7.4, supplemented with 10 mM CaCl 2 . Free fatty acids (FFA) were quantified using a NEFA-C kit (Wako) according to the manufacturer's manual. To test whether superoxide dismutase (SOD-1) activates SseJ, 5 mg GST fusion protein was pre-incubated with 20 mg bovine SOD-1 (Sigma) in 150 ml 40 mM Tris, pH 7.4, at 37 uC for 1 h before addition of DPPC at a final concentration of 3.35 mM and incubation for 2 h at 37 uC.
Acyltransferase assay. Liposomes of equimolar amounts of DPPC and partially 3 H-labelled cholesterol (5 mM) were prepared in 20 mM Tris, pH 7.4, 160 mM KCl and 1.4 % (w/v) BSA by bath sonication for 30 min. Liposomes (50 ml) were incubated with 5 mg GST fusion protein and 100 ml eukaryotic cell lysate (7 mg ml 21 ) at 37 uC for 2 h in a final volume of 250 ml. The reaction was stopped by addition of 3 ml CHCl 3 : MeOH (1 : 2, v/v). Lipids were extracted by the method of Bligh & Dyer (1959), and subsequently separated by TLC on glass-backed Silica 60 plates using petroleum ether : diethylether (8 : 2, v/v). The cholesterol ester (CE) fractions were scraped into Betamax ES liquid scintillation fluid (MP Biomedicals) and d.p.m. were measured.
Statistical analysis. For analysis of the significance of differences between samples, Student's t test was used. Differences denoted as significant in the text fall below a P value of 0.05.

Lack of enzymic activity of recombinant SseJ in vitro
To analyse the enzymic activity of SseJ in vitro, SseJ and SseJS151V were purified as GST fusion proteins (Fig. 1a) GST-SseJ, GST-SseJS151V or GST was incubated with PNPB at 37 6C, pH 7.4, while A 405 was monitored over 30 min. Porcine liver esterase was used as a positive control. GST and GST-SseJS151V were used as negative controls. These data represent the mean from two independent experiments performed in triplicate. (c) GST-SseJ, GST-SseJS151V or GST was incubated with DPPC liposomes at pH 7.4. Released FFA were quantified after 2 h incubation at 37 6C. PLA2 from bovine pancreas functioned as a positive control. GST and GST-SseJS151V were used as negative controls. The value of FFA following incubation with GST alone was subtracted from values obtained after incubation of DPPC with GST-SseJ or GST-SseJS151V. These data represent the mean±SD derived from three independent experiments performed in triplicate.
and incubated with various substrates to test for esterase and PLA activity. As positive controls, porcine liver esterase was used to hydrolyse PNPB (Fig. 1b) and commercially available PLA2 was used to hydrolyse DPPC in liposomes (Fig. 1c). No enzymic activity was detected at pH 7.4 when GST-SseJ was incubated with PNPB ( Fig. 1b) or DPPC liposomes (Fig. 1c). Liposomes consisting of equimolar amounts of cholesterol and DPPC were also used to test whether SseJ displays acyltransferase activity in vitro, but no enzymic activity was detected (data not shown). To test whether the absence of detectable activity was due to the 25 kDa GST tag at the N terminus of SseJ, the GST tag was cleaved from the purified protein, but no activity was detected (data not shown). SseJ and SseJS151V were also purified as polyhistidine fusion proteins, but neither had detectable enzymic activity under the assay conditions used (data not shown).  (Fig. 2a). In the absence of PNS, FFA was detected at similar low levels following incubation of DPPC liposomes with GST-SseJ, GST-SseJS151V or GST (Fig. 2a). These results show that a factor present in HeLa cell extract is required for PLA activity of SseJ. Incubation of increasing amounts of GST-SseJ with a fixed amount of DPPC liposomes and a fixed amount of HeLa cell extract led to an increase in the amount of released FFA up to approximately 5 mg GST-SseJ, after which production of FFA plateaued (Fig. 2b). To determine whether the substrate concentration or activating factors were limiting under these conditions, 5 mg GST-SseJ and DPPC liposomes were incubated with an increasing amount of eukaryotic cell extract, which led to a linear increase in released FFA (Fig. 2c). This shows that HeLa cell-derived factor(s) limit the reaction under the assay conditions used.

SseJ does not display lysophospholipase activity
To analyse whether SseJ hydrolyses lysophospholipids, GST-SseJ, GST-SseJS151V or GST was incubated with 1-MPLPC micelles at 37 u C, pH 7.4 for 2 h in the presence of HeLa cell PNS. In contrast to incubation of GST-SseJ with DPPC liposomes, the amount of FFA after incubation of GST-SseJ with 1-MPLPC micelles did not significantly differ from the amount of FFA detected in the presence of GST-SseJS151V or GST (Fig. 3). Therefore, SseJ does not exhibit lysophospholipase activity at pH 7.4 in the presence of HeLa cell PNS using 1-MPLPC micelles as a substrate.

HeLa cell extract-activated SseJ displays GCAT activity
To test whether SseJ can carry out acyl transfer in the presence of eukaryotic activator, GST-SseJ, GST-SseJS151V or GST was incubated in the presence of HeLa cell PNS with liposomes comprising an equimolar mix of DPPC and partially 3 H-labelled cholesterol. The formation of 3 H-labelled CE was measured after lipid extraction and separation via TLC. In the presence of GST-SseJ and HeLa cell PNS, 58 214.8±1162.6 d.p.m. were detected in the CE fraction, while GST-SseJS151V and GST produced 5543.7±1418.5 d.p.m. and 4011.6±1710.3 d.p.m., respectively, demonstrating that SseJ possesses GCAT activity in the presence of HeLa cell extract (Fig. 4).

Analysis of the SseJ-activating factor(s)
HeLa cell extract was required for PLA and GCAT activity of SseJ in vitro. In addition to HeLa cell extract, mouse macrophage RAW 264.7 cell extract contained factor(s) that activated SseJ (Fig. 5a). Soluble extracts of E. coli, S. Typhimurium or Sacc. cerevisiae did not activate SseJ ( Fig.  5a and data not shown). Interestingly, the activity of GST-SseJ was detectable when GST-SseJ was pre-incubated with Sacc. cerevisiae extract at 30 u C for 1 h before addition of DPPC liposomes and incubation for 2 h at 37 u C (FFA released without pre-incubation, 88.38±4.84 nmol; FFA released after pre-incubation, 132.48±14.9 nmol FFA) indicating that Sacc. cerevisiae extract also contained SseJactivating factor(s) (Fig. 5b). Similarly, incubation of GST-SseJ with HeLa cell extract for 1 h at 37 u C prior to addition of DPPC liposomes also led to an increase in released FFA compared to FFA released by GST-SseJ that was incubated with activator and substrate simultaneously (221.50±24.69 nmol FFA versus 149.48±22.12 nmol) (Fig. 5b). However, pre-incubation of GST-SseJ with E. coli soluble extract did not result in detectable PLA activity of GST-SseJ. We conclude that SseJ was activated by factor(s) present in Sacc. cerevisiae extract only after pre-incubation, suggesting that the concentration of activator might be lower in yeast extract than in HeLa or RAW cell extract.
Several phospholipases are known to require divalent cations, such as Ca 2+ (Clark et al., 1991;Dessen et al., 1999;Reynolds et al., 1993). The addition of 10 mM CaCl 2 ,  MgCl 2 or ZnCl 2 did not activate SseJ phospholipase activity in vitro (data not shown). Fractionation of HeLa cell PNS into cytosolic and membrane fractions prior to addition to the assay demonstrated that the activator was mainly retained in the cytosolic fraction (Fig. 6a). Incubating HeLa cell cytosol at 56 u C decreased its ability to activate SseJ and treatment of cytosol at 100 u C led to a complete loss of activating ability (Fig. 6b). When cytosol was pre-treated with trypsin before incubation with SseJ, the activating ability of the extract was reduced (Fig. 6c). After subjecting cytosol to size-exclusion filtration with 100 kDa cut-off, the activating factor was retained in the .100 kDa fraction  (b) HeLa cell cytosol was subjected to 37 6C for 30 min, 56 6C for 30 min or 100 6C for 5 min before addition to the phospholipase assay. Data represent mean±SD derived from two independent experiments performed in triplicate. (c) HeLa cell cytosol was pre-treated with trypsin for 15 min. The pre-treated cytosol was added to the phospholipase assay after addition of the protease inhibitor aprotinin. In the control, protease inhibitor was added to the cytosolic fraction before addition of trypsin. The results represent the mean±SD for each sample (in triplicate) and are representative of three independent experiments.
(data not shown). This shows that the activating activity is likely to be proteinaceous and to have a molecular mass over 100 kDa or to be present in a complex with a mass of .100 kDa.
To analyse whether cleavage or other covalent modification of SseJ is responsible for its activation, macrophages were infected with strains of S. Typhimurium expressing double HA-tagged SseJ (SseJ-2HA) for 14 h. The electrophoretic mobility of translocated SseJ was compared with SseJ produced by S. Typhimurium grown in vitro. No differences in electrophoretic mobility were detected (data not shown).
Superoxide dismutase (SOD-1) is known to be required for the activity of ExoU, a T3SS effector with phospholipase activity expressed by Pseudomonas aeruginosa (Sato et al., 2006). GST-SseJ, GST-SseJS151V or GST was therefore incubated with bovine SOD-1 in excess for 1 h at 37 u C prior to addition of DPPC liposomes and further incubation for 2 h at 37 u C, pH 7.4; however, no activity of GST-SseJ was detected (Fig. 5c). Therefore, SseJ is likely to be activated by a novel eukaryotic proteinaceous factor.

DISCUSSION
In this work we have analysed the biochemical activity of SseJ, a Salmonella SPI-2 T3SS effector protein. We found that both the PLA activity and the GCAT activity of SseJ need to be activated by a factor or factors present in eukaryotic cells. We have not yet established the identity of the activator but it is likely to be proteinaceous. There is a formal possibility that a dormant eukaryotic enzyme could be activated (directly or indirectly) by SseJ. This can only be ruled out (or confirmed) conclusively by identification of the activator itself. However, a dormant eukaryotic enzyme seems highly unlikely, given the amino acid sequence similarity between SseJ and other GDSL lipases and GCAT of A. hydrophila. Purified SseJ has been reported to possess deacylase activity on PNPB  and GCAT activity on phosphatidylcholine/cholesterol liposomes (Nawabi et al., 2008). However, we were unable to detect deacylase or GCAT activity of SseJ in the absence of activator using very similar assay conditions to those described elsewhere (Nawabi et al., 2008;Ohlson et al., 2005).
The N-terminal 140 aa of SseJ have similarity to several other SPI-2 effectors and contain a signal for its translocation (Miao & Miller, 2000). The region of SseJ encompassing amino acids 140-408, however, is similar to several members of the GDSL lipase family, including GCAT of Aeromonas spp. (26.8 % amino acid identity) (Brumlik & Buckley, 1996) and PlaC of Legionella pneumophila (19.5 % amino acid identity), which also possesses GCAT activity (Banerji et al., 2005;Brumlik & Buckley, 1996). The GDSL lipase family is characterized by five conserved blocks of amino acids. The first contains the GDSL motif including the catalytic serine, and the third and fifth contain aspartic acid and histidine residues, respectively; together with the serine in block 1 these constitute the catalytic triad (Akoh et al., 2004). The corresponding residues in SseJ (Table 2) are essential for the function of the protein in vivo and for deacylase activity in vitro , and we show in this paper that the predicted catalytic serine in block 1 is essential for both PLA and GCAT activity when stimulated by eukaryotic cell extract. It is not clear why Nawabi et al. (2008) were able to detect GCAT activity in the absence of the activator while we were not. It is possible that differences in methods of enzyme expression and purification, substrate choice (synthetic DPPC versus natural egg phosphatidylcholine) or lipid extraction could have revealed activity in the absence of eukaryotic activator. Notwithstanding this discrepancy, we have clearly demonstrated that the GCAT activity of SseJ is significantly enhanced after exposure to (a) eukaryotic factor(s).
Both GCAT and PlaC need to be activated by proteases (Banerji et al., 2005;Vipond et al., 1998). GCAT activity is potentiated as a result of proteolytic processing by AspA, the major secreted serine protease of Aeromonas salmonicida (Hilton et al., 1990;Vipond et al., 1998). Pro-GCAT (37 kDa) is cleaved at two sites, resulting in three GCAT fragments, two of which are connected via a disulfide bond (33 kDa), so that only a very small fragment of pro-GCAT is lost (Vipond et al., 1998). Both pro-and processed GCAT possess activity in vitro, but only processed GCAT can penetrate lipid monolayers at surface pressures equivalent to those of natural membranes (.30 mN m 21 ) (Hilton et al., 1990;Hilton & Buckley, 1991). Activation of PlaC is dependent on the zinc metalloprotease ProA, although it is not clear whether this effect is direct or indirect (Banerji et al., 2005). Despite these two precedents, it seems unlikely that SseJ is activated by proteolytic cleavage, since several protease inhibitors were added to cell extracts prior to incubation with SseJ and no size difference between intrabacterial and translocated SseJ was detected by Western blotting. Another difference from GCAT and PlaC is that SseJ requires (a) eukaryotic factor(s) for its activity. ExoU, a P. aeruginosa T3SS effector protein with PLA2 activity (belonging to the patatin-like lipase family), also requires a eukaryotic activator, which has recently been identified as superoxide dismutase (SOD-1) (Sato et al., 2006). However, the mechanism by which SOD-1 activates ExoU has not yet been elucidated. Purified bovine SOD-1 did not activate SseJ in vitro, and it therefore seems likely that SseJ is activated by a unique mechanism. Attempts to identify the eukaryotic activator(s) are underway and this will provide further insight into the mechanism of activation of SseJ.
It is interesting to consider how the GCAT activity of SseJ might influence the biology of the SCV. SseJ is translocated by the SPI-2 T3SS and localizes to the cytosolic face of the vacuole and Sifs (Freeman et al., 2003), tubular extensions of the SCV which form along microtubules, and which are particularly noticeable in epithelial cells (Garcia-del Portillo et al., 1993). Therefore, SseJ is likely to act on phospholipids, present in the SCV membrane and Sifs, transferring acyl chains to cholesterol, which appears by microscopy to be particularly abundant in the SCV membrane (Catron et al., 2002). Although the resolution of light microscopy does not allow one to conclude that cholesterol is present in the SCV membrane itself, immunolabelling of intra-vacuolar Salmonella after exposure of the SCV to saponin (a cholesterol-dependent membrane-permeabilizing reagent) indicates that cholesterol is present in the SCV membrane. The function of SseJ is linked to that of SifA, an SPI-2 T3SS effector whose function has been clarified in recent years. Following translocation and localization to the SCV membrane and Sifs, SifA is prenylated and anchored in the SCV membrane of SCVs and Sifs (Reinicke et al., 2005). SifA binds to SKIP, a host cell protein that prevents the microtubule motor kinesin from being recruited to the SCV. sifA mutants fail to induce the formation of Sifs (Stein et al., 1996) and gradually lose their vacuolar membranes (Beuzon et al., 2000) in a kinesindependent manner (Guignot et al., 2004).
Two intracellular phenotypes have been described that result from mutation of sseJ. First, the loss of vacuolar membrane around sifA mutants requires the activity of SseJ (Ruiz-Albert et al., 2002), and second, deletion of sseJ induces the formation of more Sifs per cell, suggesting that SseJ inhibits Sif formation . Therefore, SseJ appears to oppose the activity of SifA. If the GCAT activity of SseJ in the SCV membrane esterifies cholesterol and removes it from the SCV to lipid droplets (Nawabi et al., 2008), its absence could increase membrane rigidity, facilitating kinesin-mediated rupture of vacuolar membranes around sifA mutant bacteria. Membrane association of prenylated Rab proteins is dependent on the cholesterol content of the membrane (Chen et al., 2008;Lebrand et al., 2002). Hence, by regulating the amount of cholesterol in the SCV membrane, SseJ could control the amount of SifA on the SCV. In the sseJ mutant, more cholesterol could lead to greater incorporation of SifA into the SCV membrane and thereby to an increased level of Sif formation.
The dynamic properties of the SCV membrane are also likely to be altered by SseJ-mediated deacylation of phospholipids, since membrane curvature is affected by the lipid composition of the phospholipid bilayer (McMahon & Gallop, 2005). Furthermore, GCAT activity could influence host cell signalling pathways by affecting lipid raft composition through its effect on cholesterol and by generating FFA and lysophospholipid. Eukaryotic activator-dependent activity of SseJ