2.1. Protein expression and purification

The S. marcescens lip gene (SMA2252; Murdoch et al., 2011) encoding amino-acid residues 30–176 was amplified from genomic DNA (strain Db10) using the forward primer 5′-­catatgGCCAAAAGCGTGCCGTCGCGTTACAG-3′ and the reverse primer 5′-ggatccTCAGTCGACCTTTTTTACG­GGGCGCAGGC-3′ (the lower-case sequences correspond to the NdeI/BamHI restriction sites used for cloning). The PCR product was ligated into PCR-BluntII-TOPO using the Zero Blunt TOPO Cloning Kit (Invitrogen) and then cloned into a pET15b (Novagen) cloning vector modified to encode a tobacco etch virus (TEV) protease cleavage site in place of the thrombin protease cleavage site. The construct was verified by DNA sequencing (DNA Sequencing Unit, University of Dundee).

The recombinant protein was produced in Escherichia coli BL21 (DE3) pLysS cells (Stratagene). Cultures were grown for 3 h at 310 K in auto-induction medium (Studier, 2005) supplemented with 50 µg l⁻¹ carbenicillin before overnight growth at 295 K. Cells were harvested by centrifugation (3500g at 277 K for 30 min). The cell pellet was resuspended in buffer A (25 mM Tris–HCl pH 7.5, 500 mM NaCl, 20 mM imidazole pH 8.5) supplemented with an EDTA-free Protease Inhibitor Cocktail Tablet (Roche) and 0.2 mg DNase I (Sigma–Aldrich). Cells were lysed using a continuous-flow cell disrupter (Constant Systems) at 207 MPa and cell debris was removed following centrifugation (40 000g at 277 K for 30 min). SmLip was purified using nickel-affinity chromatography with a 5 ml HisTrap HP column (GE Healthcare) pre-charged with Ni²⁺. A step gradient of 5% buffer B (25 mM Tris–HCl pH 7.5, 500 mM NaCl, 500 mM imidazole) was used to remove histidine-rich proteins. A linear concentration gradient of imidazole from 5 to 50% buffer B was applied to elute the product, which was then dialyzed against buffer C (25 mM Tris–HCl, 250 mM NaCl pH 7.5) at 277 K overnight in the presence of His-tagged TEV protease. The resulting mixture was applied onto the HisTrap column, which bound the cleaved His tag, TEV protease and uncleaved SmLip. The SmLip sample from which the His tag had been cleaved was present in the flowthrough. Fractions were analyzed using SDS–PAGE and those containing SmLip were pooled. The protein was further purified by size-exclusion chromatography using a Superdex 75 26/60 column (GE Healthcare) equilibrated with buffer C on an ÄKTApurifier (GE Healthcare). The column had previously been calibrated with the molecular-weight standards blue dextran (>2000 kDa), thyro­globulin (669 kDa), ferritin (440 kDa), aldolase (158 kDa), conalbumin (75 kDa), ovalbumin (43 kDa), carbonic anhydrase (29.5 kDa), ribonuclease A (13.7 kDa) and aprotinin (6.5 kDa) (GE Healthcare; data not shown). The protein eluted as one peak of approximate mass 17 kDa, corresponding to a monomer. Fractions containing the protein were pooled and concentrated to 10 mg ml⁻¹ using Amicon Ultra devices (Millipore) for subsequent use. The purity of the protein was confirmed by SDS–PAGE and mass spectrometry (Fingerprint Proteomics Facility, University of Dundee). A theoretical extinction co­efficient of 16 960 M⁻¹ cm⁻¹ at 280 nm was used to estimate the protein concentration (ProtParam; Gasteiger et al., 2005); the theoretical mass of one subunit was estimated as 16.1 kDa with a calculated isoelectric point of 5.4. The purified protein sample was stored at 277 K until further use.

2.2. Crystallization, data collection and structure determination

Initial crystallization screens were carried out at 293 K by the sitting-drop vapour-diffusion method in 96-well plates. This was achieved using a Phoenix liquid-handling system (Rigaku, Art Robbins Instruments) and the commercially available PEG (Qiagen) and JCSG+ (Molecular Dimensions) screens. Crystallization occurred in two conditions, which were further optimized using the hanging-drop vapour-diffusion method with drops consisting of 1 µl protein solution at 10 mg ml⁻¹ in 25 mM Tris–HCl pH 7.5, 250 mM NaCl and 1 µl reservoir solution. The two conditions involved reservoirs consisting of 20% polyethylene glycol 3350, 200 mM KI and of 15% polyethylene glycol 3350, 200 mM NaCl. Monoclinic blocks with minimum dimensions of approximately 0.3 mm grew over 2 d and the addition of glycerol to 10% proved to be a suitable cryoprotectant.

Crystals from the iodide-containing condition were characterized first and data set I was measured in-house using a Rigaku MicroMax-007 rotating-anode X-ray generator (Cu Kα, λ = 1.541 Å) coupled to an R-AXIS IV⁺⁺ image-plate detector. A crystal from the second condition was stored in liquid N₂ and subsequently used to measure a high-resolution data set (data set II) on beamline ID29 at the European Synchrotron Radiation Facility (ESRF; Grenoble, France) using an ADSC Q315R detector. All data were indexed and integrated using XDS (Kabsch, 2010) and scaled using SCALA (Evans, 2006) from the CCP4 program suite (Winn et al., 2011).

Data set I was used to solve the structure by SAD methods targeting the iodides present in the crystallization conditions and to acquire a fairly complete model. The sites of potential anomalous scattering ions or atoms were identified using PHENIX (Adams et al., 2010) and experimental phases were calculated using Phaser (McCoy et al., 2007). Density modification was carried out using histogram matching, averaging on the basis of noncrystallographic symmetry (NCS), and model building was carried out using RESOLVE (Terwilliger, 2003). NCS restraints were employed in the initial refinement calculations, which were performed using REFMAC5 (Mur­shudov et al., 2011). Inspection of the model and the fit to electron-density and difference density maps was carried out in Coot (Emsley et al., 2010). The analysis then switched to the high-resolution synchrotron data set II when it became available and this was used to complete the refinement. MolProbity (Chen et al., 2010) was used to investigate model geometry in combination with the validation tools provided in Coot. Analyses of surface areas and interactions were made using the PISA (Krissinel & Henrick, 2007) web service and secondary-structure analysis was performed using DSSP (Kabsch & Sander, 1983). Crystallographic statistics are summarized in Table 1.

Table 1 Crystallographic statistics Values in parentheses are for the highest resolution shell.   Data set I Data set II Space group C2 C2 Wavelength (Å) 1.5418 1.007 Unit-cell parameters (Å, °) a = 139.7, b = 77.6,c = 54.3, β = 98.4 a = 139.7, b = 77.8, c = 54.5, β = 98.3 Resolution (Å) 19.7–2.35 (2.48–2.35) 39.8–1.92 (2.02–1.92) No. of reflections recorded 94650 (11192) 280802 (38597) Unique reflections 23495 (3109) 43478 (6188) Completeness (%) 98.3 (90.0) 98.2 (95.8) Multiplicity 4.0 (3.6) 6.5 (6.2) 〈I/σ(I)〉 30.9 (6.6) 20.6 (3.7) Anomalous completeness (%) 95.7 (84.5) — Anomalous multiplicity 2.0 (1.8) — Wilson B (Å2) 47.7 32.7 No. of residues/waters — 541/336 Rmerge† (%) 2.6 (17.1) 4.9 (44.2) Rwork‡ (%) — 22.0 Rfree§ (%) — 29.2 Average B factors (Å2)  Chain A — 36.1  Chain B — 41.6  Chain C — 49.5  Chain D — 59.8  Waters — 46.2  Na+ — 37.8  Ethylene glycol — 60.2 Cruickshank DPI¶ (Å) — 0.2 Ramachandran plot  Most favoured — 516 residues  Additional allowed — 21 residues  Outliers — Molecule D: Phe97, Asp129; molecule B: Pro142, Ser154 R.m.s.d. on ideal values††  Bond lengths (Å) — 0.01  Bond angles (°) — 1.42 †Rmerge = , where Ii(hkl) is the intensity of the ith measurement of reflection hkl and 〈I(hkl)〉 is the mean value of Ii(hkl) for all i measurements. ‡Rwork = , where Fobs is the observed structure factor and Fcalc is the calculated structure factor. §Rfree is the same as Rcryst except calculated with a subset (5%) of data that were excluded from the refinement calculations. ¶Cruickshank (1999). ††Engh & Huber (1991).

2.3. Bacterial two-hybrid analyses

For generation of the plasmid pSC072, the gene fragment encoding SmLip amino acids 27–176 was PCR-amplified using primers 5′-TATAgcatgcGTAAAGAGGAGGCTGCATGTC­TTCCGCCAAAAGC-3′ and 5′-TATAtctagaGAGTCGAC­CTTTTTTACGGGGC-3′ and cloned into the vector pUT18 (Karimova et al., 2001) using SphI and XbaI restriction sites. The restriction sites are shown in lower case. For generation of another plasmid, pSC080, the same gene fragment was PCR-amplified using primers 5′-TATAggatccAATGTCTTC­CGCCAAAAGCG-3′ and 5′-TATAggtaccAATGATGACG­ACC­CCTATCGC-3′ and cloned into vector pT25 (Karimova et al., 1998) using BamHI and KpnI restriction sites (again shown in lower case). Bacterial two-hybrid analyses were performed following established protocols (Karimova et al., 1998, 2000). E. coli BTH101 was transformed with pSC072 (or pUT18 control) and pSC080 (or pT25 control) and the colour of the resulting transformants was scored on MacConkey media with 0.2% maltose (with a positive result being red). For quantitative measurement of the interaction, β-galacto­sidase assays were performed as described by Murdoch et al. (2011) on double-transformed BTH101 grown at 303 K in Luria–Bertani broth (LB) and permeabilized with toluene. Replicate assays were performed on independent transformants.

2.4. Cellular localization of Lip

Wild-type S. marcescens strain Db10 and the lip mutant SJC10 (Murdoch et al., 2011) were grown for 8 h at 303 K in LB. Subcellular fractionation was performed following an established method (Hatzixanthis et al., 2003). In brief, following isolation of clean supernatant by centrifugation, washed cell pellets were resuspended in 50 mM Tris–HCl pH 7.5, 40%(w/v) sucrose at 10 ml per gram of cells. EDTA was then added to 5 mM (final concentration) and lysozyme was added to 0.6 mg ml⁻¹ before incubation at 310 K for 30 min. Sphaeroplasts were harvested by centrifugation and taken up in an equivalent volume of 50 mM Tris–HCl pH 7.5 before French pressure treatment. Following ultracentrifugation of the resultant crude extract, the isolated membranes were again taken up in an equivalent volume of 50 mM Tris–HCl pH 7.5. This protocol ensured that equivalent proportions of each cell fraction were assayed. 4 µl of each fraction was mixed with SDS sample buffer (100 mM Tris–HCl pH 6.8, 3.2% SDS, 3.2 mM EDTA, 16% glycerol, 0.2 mg ml⁻¹ Bromophenol blue, 2.5% β-mercaptoethanol) and separated by 15% SDS–PAGE prior to anti-Lip immunoblotting. Whole-cell samples com­paring wild-type versus SJC10 were prepared by resuspending cells from 100 ml culture in 100 µl SDS sample buffer and boiling for 5 min prior to loading 6 µl onto the gel. Following SDS–PAGE, proteins were electroblotted onto polyvinylidine fluoride membrane (Millipore). SmLip was detected by hybridization of the primary antibody polyclonal rabbit anti-­Lip (1:4000) followed by the secondary antibody HRP-conjugated goat anti-rabbit (Thermo; 1:10000) and the use of an enhanced chemiluminescent detection kit (Millipore).

3.1. Structure determination

Full-length SmLip consists of 176 residues. A truncated version of SmLip consisting of an N-terminal hexahistidine tag plus a TEV protease recognition site followed by residues Ala30–Asp176 was obtained in recombinant form and purified. The N-terminal 29 amino acids, which include the lipid­ation signal peptide and the first four residues of the mature protein, have been omitted. This sample gave monoclinic crystals. The asymmetric unit consists of four polypeptide chains, labelled A–D, with an estimated solvent content of 45% and a V_M of 2.27 ų Da⁻¹.

Medium-resolution diffraction data were recorded in-house and the anomalous scattering information was used in a SAD approach to phasing. 13 potential iodide positions were identified and produced a figure of merit of 0.43 to 2.35 Å resolution. Subsequently, 12 of these positions were confirmed by refinement with this data set. The initial model constructed in RESOLVE consisted of 293 residues, with a correlation coefficient of 0.55 and R_work and R_free values of 46% and 49%, respectively. The first round of model building in Coot extended this to 467 residues, with a correlation coefficient of 0.72 and R_work and R_free values of 33% and 37%, respectively. At this point the high-resolution synchrotron data (1.92 Å resolution) became available and were used to continue the analysis. The refinement proceeded with the release of NCS restraints and the incorporation of water molecules, an Na⁺ ion, ethylene glycol and a number of side chains with dual rotamer conformations. This data set was derived from crystals grown in the presence of chloride instead of iodide. However, we did not assign any chloride ions to the structure, noting that typical water molecules occupy the previously identified iodide-binding sites. The refinement was terminated when there were no significant changes in R_work and R_free and inspection of the difference density map suggested that no further corrections or additions were justified. Several dual rotamers are incorporated into the model. Disorder was evident at several positions, for example the N-terminus, where it was not possible to interpret diffuse and weak electron density. Consequently, several residues are absent from the model. Molecule A consists of residues 32–173; molecule B of residues 33–142 and 147–176; molecule C of residues 34–50, 53–143 and 147–175; and molecule D of residues 33–50 and 55–175. The geometry of the model is acceptable (Table 1).

3.2. Self-association and localization in vivo

Previous work on SciN, the Lip homologue from entero­aggregative E. coli, showed that the protein is localized in the outer membrane, facing the periplasm (Aschtgen et al., 2008). Examination of the amino-acid sequence of the N-­terminus of SmLip predicts that this is also an outer-membrane lipoprotein. The LipoP 1.0 algorithm (Juncker et al., 2003) predicts that SmLip has a lipoprotein signal peptide and that signal peptidase II cleavage occurs between Gly25 and Cys26, with the cysteine subsequently being lipidated. Additionally, the residue at the +2 position following cleavage is Met27 (i.e. it is not an aspartate, which directs retention in the inner membrane); therefore, SmLip should proceed to the outer membrane via the Lol system (Bos et al., 2007).

In order to investigate whether SmLip undergoes self-interaction, the bacterial two-hybrid system (Karimova et al., 2000) was utilized in E. coli. This assay involves reconstitution of adenylate cyclase activity from two non-interacting cyclase fragments, called T18 and T25, from Bordetella pertussis. The presence of cyclic AMP activates the transcription of maltose and lactose catabolic operons by E. coli. This can be detected by direct measurement of β-galactosidase activity or by using the observation that bacteria capable of fermenting maltose acidify the medium and thus generate a red colour on MacConkey–maltose indicator plates.

SmLip was introduced as both bait and prey by encoding on plasmids pUT18 and pT25, and a strong positive result was observed (Fig. 1). Mature SmLip (lacking the N-terminal signal peptide) was used for this experiment, firstly to correspond to the form of SmLip for which the structure was solved and secondly to ensure that both partners were local­ized together in the cytoplasm after fusion with T18 or T25. This positive result indicates that Lip does indeed self-associate within the cell and that neither localization in the outer membrane nor other components of the type VI secretion apparatus are required for self-interaction. We note, however, that this system is unable to distinguish between dimerization or higher order oligomerization.

Figure 1 Detection of Lip–Lip self-interaction. The bacterial two-hybrid system was used to detect an in vivo interaction between Lip (minus signal peptide) fused to T25 (pSC080) and Lip (minus signal peptide) fused to T18 (pSC072). The empty vectors pUT18 and pT25 represent negative controls. The graph shows the output from the two-hybrid system detected as β-galactosidase activity expressed relative to the pUT18/pT25 baseline level (the maximal β-galactosidase activity observed for the Lip–Lip interaction corresponded to >5000 Miller units). Bars show mean ± SEM. Inset: colourimetric readout of the two-hybrid assay following growth of E. coli BTH101 carrying the above plasmids on MacConkey–maltose agar (red is a positive result).

As a control for any propensity of SmLip to form non­specific interactions, in addition to the lack of interaction with the T18 and T25 proteins demonstrated in Fig. 1 we tested whether SmLip gave a positive bacterial two-hybrid result with several cytoplasmic components of the T6SS (with which, as a periplasmic protein, it should not interact). SmLip gave a negative result (indistinguishable from the T25 + T18 negative control) when tested against the proteins VipB, TssK and TssL (data not shown).

In order to confirm the localization of the native Lip protein in S. marcescens, we utilized an anti-Lip polyclonal antibody to probe each of the major cellular fractions in this organism. As shown in Fig. 2, native SmLip is found exclusively in the membrane fraction, confirming the predicted localization of the protein and the functionality of the signal peptide.

Figure 2 Cellular localization of native SmLip in S. marcescens. Anti-Lip immunoblot of whole cells or cellular fractions prepared from wild-type S. marcescens strain Db10 or the Δlip mutant SJC10 (WC, whole cell; Peri, periplasm; Sph, sphaeroplast; Cyto, cytoplasm; Memb, membranes). The predicted size of mature SmLip is 16 kDa.

3.3. Overall structure

The SmLip polypeptide can be classified as a new member of the transthyretin-like superfamily and a detailed comparison will be given below. The protein displays a compact globular structure dominated by an eight-stranded β-sandwich (Fig. 3; Supplementary Fig. S1¹). The order of the strands is 8–7–1–4 and 6–5–2–3. There are three short α-helical segments and three 3₁₀-helix turns. The four SmLip polypeptide chains in the asymmetric unit are similar, with the root-mean-square (r.m.s.) deviations between superimposed C^α atoms ranging from 1.3 Å (monomers A and B) to 0.8 Å (monomers A and D) with an average value of 0.95 Å.

Figure 3 The secondary structure and fold of SmLip. β-Strands are shown as blue arrows and α-helices and 310-turns as red and green ribbons, respectively. The N- and C-terminal residues are labelled and the orientation of the protein with respect to the outer membrane and periplasm is suggested.

Although a set of core conserved proteins are encoded by the T6SS gene clusters in different Gram-negative bacteria (data not shown), there is a large degree of variation in the amino-acid sequences of these proteins. Lip and its ortho­logues, for example, are relatively poorly conserved. Excluding the signal peptide and lipobox motif (Fig. 4), SmLip shares only about 20% sequence identity with SciN, the homologue from enteroaggregative E. coli. This increases to near 40% in comparison with the homologue from the P. aeruginosa HSI-1 T6SS. Sequence conservation is noted in loop 1, near α1 and α2, in loop 2 and in the loop 4–β6 region (Fig. 4).

Figure 4 The primary and secondary structure of SmLip and sequence alignment with two homologues. S. marcescens Lip is aligned with the homologous proteins from enteroaggregative E. coli (GenBank CBG37366.1) and P. aeruginosa (NCBI Reference Sequence NP_248770.1, PA0080). The secondary structure of SmLip is depicted with blue arrows for β-strands and red and green cylinders for α-­helices and 310-helices, respectively. Residues conserved in all three sequences are shown in black boxes and those conserved in only two sequences are shown in grey boxes. The start and finish of the lipobox motif are marked by red boxes; the residues at the start and end of the sequence used in the structure analysis (Ala30–Asp176) are shown in blue boxes. The alignment was generated using T-­Coffee (Di Tommaso et al., 2011) in the M-Coffee mode and the figure was prepared using ALINE (Bond & Schüttelkopf, 2009).

An alignment of SmLip with eight orthologues (Supplementary Fig. S2¹) reinforces the observation of a low level of sequence identity for this protein. Excluding two residues in the lipobox motif, only six residues are strictly conserved: Asn48, Leu99-X-Pro101-Gly102, Gly120 and Ala124. All six residues appear to contribute to the conformation of specific parts of the fold (data not shown). The side chain of Asn48 accepts a hydrogen bond from the main-chain amide of Gln126, helping to define the conformation of loop 4. The Leu99-X-Pro101-Gly102 segment defines the structure of the turn after β3 leading into loop 2. Gly120 and Ala124 occur in β5 and contribute hydrogen bonds to form interactions with β2 and β6 on either side. An increase in size of the side chain at either of these positions would be likely to be disruptive to the formation of this β-sheet, which forms one side of the structure. There is no obvious hydrophobic, basic or acidic surface feature on SmLip that is likely to be conserved within the Lip proteins since the few conserved residues are mainly buried.

The information provided in §3.2 identifies that the N-­terminus of the structure is placed close to the outer membrane, hence the assignment of the orientation of SmLip with respect to the outer membrane (Fig. 3). By extension, we note that the areas of SmLip in which sequence conservation is observed mainly appear to contribute to stabilizing parts of the structure that jut out into the periplasm. They may therefore serve to define the structure of parts of Lip that are responsible for interaction with other molecules in the periplasm.

3.4. The tetramer is likely to be a crystallographic artefact

Gel-filtration data acquired during purification indicated that SmLip is a monomer in solution (data not shown). In contrast, the bacterial two-hybrid data revealed a propensity for self-interaction and the asymmetric unit is a tetramer displaying 222 point-group symmetry (Fig. 5). The accessible surface area (ASA) of the SmLip polypeptide averages out at approximately 8350 Ų; the range is from 8200 Ų for molecule D to 8510 Ų for molecule A. Each molecule in the asymmetric unit interacts with two of the other three and two types of protein–protein interface are formed between molecules A–B and C–D (interface I) and between molecules A–C and B–D (interface II). The type I interface, which is larger, covers an area that is approximately 13% of the ASA of the SmLip molecule. Such coverage certainly indicates potential for a biologically relevant dimer. This interface is primarily formed by the antiparallel alignment of two β7 strands. Three aromatic residues, Phe147, Trp151 and Phe153, contribute van der Waals interactions to the association and, by virtue of their relative bulk, also to the ASA (data not shown). The type II interface covers about 6.5% of the ASA of a molecule, a level typical of the values observed simply owing to molecular packing in a crystal lattice. This interface is formed by the antiparallel alignment of two β4 strands. The areas of SmLip involved in forming a tetramer are not con­served in the homologues from E. coli or P. aeruginosa (Fig. 4) and it is unlikely that such a tetramer is a generic feature of this lipoprotein.

Figure 5 The asymmetric unit. The four molecules that constitute the asymmetric unit are shown in different colours using the secondary-structure assignment given in Fig. 1 and labelled. The two types of protein–protein interface are labelled, as are the β4 and β7 strands. Residues that contribute significantly to the type I interface (Phe147, Trp151 and Phe153) are depicted as sticks.

The spatial placement of the N-­terminal residues in the asymmetric unit is such that it is unlikely that an oligomeric assembly could form when the protein is anchored in the membrane by the lipidated Cys26 at the N-terminus. The N-­termini of molecules A and D are on the same side of the tetrameric assembly but are opposite to those of molecules B and C. As explained, there are no direct interactions formed between molecules A and D or molecules B and C. That the bacterial two-hybrid experiments reveal a propensity for self-interaction of the truncated protein in the cytoplasm is in one sense consistent with the crystal structure of the truncated version of SmLip, which shows a tetrameric assembly con­taining a plausible dimer. On the other hand, the structure of the tetramer is incompatible with dimeric or tetrameric structures if the N-terminus is membrane-bound. These observations may be a result of the different concentrations and experimental conditions used. We suggest that SmLip is a membrane-bound monomer but displays a propensity to interact with itself.

A reviewer commented on the possibility that the SmLip tetramer might represent an inactive or alternative state of the protein. This is an intriguing suggestion and raises questions about how conversion to an active form might occur and how the T6SS itself is regulated. We have no data to address this issue and further studies would be required to investigate such a possibility.

3.5. Comparisons with structural homologues

A search for structural neighbours in the Protein Data Bank using the PDBeFold (https://pdbe.org/fold) and ProFunc servers (Laskowski et al., 2005) gives a Z score of 6.1 with sea bream transthyretin (Eneqvist et al., 2004; PDB entry 1sn0). This matched 84 residues with an r.m.s.d. of 2.7 Å. The β-sheet structures align well (Supplementary Fig. S3¹). The r.m.s.d. and relatively low Z score reflect the low sequence identity shared between the two proteins of approximately 7%. Nevertheless, the structural relationship is clear and SmLip can be classed as a new member of the transthyretin-like protein family. The only other member of this protein family is 5-hydroxyisourate hydrolase (EC 3.5.2.17; Hennebry et al., 2006), an enzyme that is found only in prokaryotes, leading to the conclusion that this represents an example of divergent evolution (Hennebry, 2009). The sequence identity shared between this hydrolase and SmLip is only 6%, but the similarity in fold is evident (data not shown). We carried out further comparisons seeking to inform on Lip function.

Transthyretin binds the hormone thyroxine, self-interacts to form a tetramer and also forms a complex with retinol-binding protein (Blake et al., 1978; Wojtczak et al., 1992; Monaco et al., 1995; Zanotti et al., 2008). In common with transthyretin, SmLip forms a tetrameric assembly. However, the SmLip oligomer is distinct and an overlay of one SmLip polypeptide with a subunit from transthyretin does not produce an overlap of any of the other polypeptides (data not shown).

Transthyretin forms a dimer by antiparallel self-association of the β6 and β8 strands, creating a curved eight-stranded β-­sheet (Blake et al., 1978). The binding of the hormone thyroxine occurs at the tetramer interface created by the convex surfaces of two of these eight-stranded β-sheets as the protein assembles as a dimer of dimers. The thyroxine-binding residues in transthyretin are not conserved in SmLip and an overlay of an SmLip polypeptide and transthyretin subunit places the ligand-binding site on the surface of the former (Supplementary Fig. S3¹). It is unlikely that SmLip acts to bind hydrophobic ligands of the type that transthyretin can bind.

Transthyretin associates with retinol-binding protein using residues in three turns: two from one subunit that link β1 to β2 and β4 to β5, and one from another subunit that links β1 to β2 (Monaco et al., 1995). These parts of the transthyretin structure correspond to loops 1 and 3 of SmLip. Loop 1 is directed out from the globular fold into the periplasmic space; it is placed to interact with physiological partners and may represent a binding site for other proteins/molecules.

In a recent study of Klebsiella pneumoniae 5-hydroxy­isourate hydrolase, the residues important for catalytic function were confirmed as His7, Arg41, His92 and Ser108, which together with Tyr105 form a polar and symmetric active site at a dimer interface (French & Ealick, 2011). A structure-based sequence alignment matches four of these catalytic residues (with the exception being Ser108) to Asp42, Gly105, His161 and Val172, respectively, in SmLip. The polypeptides do not overlay in the vicinity of Ser108 (data not shown) and it is unlikely that Lip has any hydrolase activity.

The biological role of SmLip or its orthologues in the T6SS has yet to be unambiguously defined. Structural comparisons appear to rule out, rather than assign, a function. The pro­pensity to self-associate using parts of the SmLip structure that will be exposed in the periplasm suggests that this protein, exploiting the lipid anchor, helps to bind and position different components of the secretion apparatus at the outer mem­brane. Future experiments, aided by the structural model, can address this hypothesis.