The universality of peptidoglycan in bacteria underlies the broad spectrum of many successful antibiotics. However, in our times of widespread resistance, the diversity of peptidoglycan modifications offers a variety of new antibacterials targets. In some Gram-positive species such as Streptococcus pneumoniae, Staphylococcus aureus, or Mycobacterium tuberculosis, the second residue of the peptidoglycan precursor, D-glutamate, is amidated into iso-D-glutamine by the essential amidotransferase MurT/GatD complex. Here, we present the structure of this complex at 3.0 Å resolution. MurT has central and C-terminal domains similar to Mur ligases with a cysteine-rich insertion, which probably binds zinc, contributing to the interface with GatD. The mechanism of amidation by MurT is likely similar to the condensation catalyzed by Mur ligases. GatD is a glutaminase providing ammonia that is likely channeled to the MurT active site through a cavity network. The structure and assay presented here constitute a knowledge base for future drug development studies.
Peptidoglycan is a defining trait of bacteria and its metabolism is targeted by major antibiotics. A mesh-polymer that surrounds the cell, defining its shape and providing resistance to osmotic pressure, peptidoglycan is extraordinarily conserved, consisting of chains of alternating N-acetylglucosamine (GlcNAc) and N-acetylmuramic acid (MurNAc) that are cross-linked by peptide bridges attached to the MurNAc1.
On the other hand, peptidoglycan is also very diverse. Peptidoglycan is thin and mono-layered, or thick and multi-layered, in Gram-negative or Gram-positive bacteria. Chain length ranges from a few units (Staphylococcus aureus) to several hundred (Bacilli), with reducing ends or terminating with 1,6-anhydroMurNAc. Glycan chains are modified by various degrees of N-deacetylation, and O-acetylation and N-glycolylation1.
The peptide component shows even greater variety arising from the diverse residues assembled into the precursor pentapeptide by the Mur ligases C, D, E, and F1. The first residue is generally an L-Ala, but can be Gly or L-Ser. The second amino acid is D-Glu. The third residue attached to the C5 of the D-Glu can be L-Lys, as in Streptococcus pneumoniae, or a meso-diaminopimelate, as in many Gram-negative species, or a variety of other residues. The fourth and fifth residues, added as dipeptide, is generally D-Ala-D-Ala, but can be D-Ala-D-Ser or D-Ala-D-lactate.
Peptide cross-linking and maturation at the cell surface can also differ. The D,D-transpeptidase activity of the penicillin-binding proteins (PBPs) forms the most common 3–4 linkage with or without intervening branches. PBPs are also responsible in some Corynebacteria for the 2–4 linkage with an intermediate diamino acid. L,D-transpeptidases can form 3–3 linkages in many species, and account for most of the cross-linking in Mycobacteria, Clostridia, and in some β-lactam-resistant bacteria. The fifth and fourth residues can be trimmed by carboxypeptidases. The degree of cross-linking and trimming is variable1.
The modification of the precursor peptide in the cytoplasm provides additional diversity. Amino acids can be added on the second or third residue to form branches, such as the pentaglycine in S. aureus, and the L-Ala-L-Ala or L-Ser-L-Ala in S. pneumoniae. These branches are generally part of the cross-links. The meso-diaminopimelate is amidated in some species such as Bacillus subtilis. At the second position, the D-glutamate can be amidated into D-iso-glutamine in many Gram-positive organisms by the MurT/GatD amidotransferase complex that is the subject of our study.
MurT/GatD amidates the C1 carboxylate of the D-Glu to form a D-iso-Gln at the second position of the membrane-bound peptidoglycan precursor lipid II (Fig. 1). This activity was long known in S. aureus extract2, but the responsible operon (murTgatD) was identified only recently3,4. MurT is homologous to the Mur ligases that elongate the peptide of the UDP-linked soluble precursors5,6,7,8. GatD belongs to the class I glutaminase with a characteristic catalytic Cys-His-Asp/Glu triad, and is homologous to the glutaminase domain of a variety of amidotransferases such as cobyric acid synthase, CTP synthetase, or imidazole glycerol phosphate (IGP) synthase9. GatD is thought to hydrolyze L-glutamine to generate ammonia, which is used by MurT to amidate lipid II. By analogy with reactions catalyzed by Mur ligases, the acceptor carboxyl of the D-Glu is thought to be activated by phosphorylation10.
In vitro, MurT/GatD from S. aureus was shown to amidate both lipid II and its immediate precursor lipid I, which lacks GlcNAc, but none of the soluble UDP-linked precursors4. L-Gln is the nitrogen donor in neutral and basic conditions (pH 7.5 and 8.5). Ammonia could also serve as direct nitrogen source at pH 8.5, which is consistent with the mechanism of glutamine amidotransferases, where ammonia is transferred to the synthase subunit9. When ammonia was provided directly, amidation still required presence of GatD4. Amidated lipid II was shown to be the preferred substrate for transpeptidation by PBPs from S. pneumoniae11.
In the quest for novel antibacterial target, MurT/GatD is particularly important due to its presence in mycobacteria, staphylococci, enterococci, and streptococci. The essentiality of murTgatD has been demonstrated in important pathogens such as Mycobacterium tuberculosis12, S. pneumoniae11,13,14, and S. aureus4,15,16. MurT/GatD depletion in S. aureus caused increased susceptibility to β-lactams and lysozyme, including in methicillin-resistant strains3,17.
β-Lactams antibiotics have been so successful due to their large spectrum as they inhibit the D,D-transpeptidases that cross-link peptidoglycan, a nearly universal feature. However, drugs with narrower spectra are highly desirable. The diversity of the peptidoglycan offers such opportunities. In this context, we present the structure of a MurT/GatD complex, from the human pathogen S. pneumoniae. The structure show that MurT is similar to Mur ligases with a cysteine-rich insertion contributing to the interface with GatD. Amidation probably proceeds like the condensation catalyzed by Mur ligases. GatD is a glutaminase providing ammonia that is likely channeled to the acceptor site through a cavity network. This work, which reveals atomic details of the active sites and interface, provides essential knowledge for future efforts to design inhibitory molecules.
Distribution of the murTgatD operon
We searched available sequences to evaluate the distribution of murTgatD among bacteria. The operon is present in many Gram-positive bacteria of the Terrabacteria superphylum, it is universally present in the Actinobacteria and Chloroflexi, including in genera Corynabacterium, Mycobacterium, and Streptomyces. Among Firmicutes, murTgatD is present in the whole Lactobacillales order that includes genera: Streptococcus, Enterococcus, Lactococcus, Lactobacillus; it is widespread in the Clostridiales, including in the Clostridia. In Bacillales, murTgatD is ubiquitous in Staphylococcaceae, but is nearly absent from Bacillaceae or Listeriaceae. The operon is also ubiquitous in some classes of Cyanobacteria. A few strains from Gram-negative species also contain the operon suggesting gene transfer events.
Depletion of MurT/GatD
To investigate the function of murTgatD in S. pneumoniae R6, an ectopic copy under the control of the inducible promoter PcomX was introduced and the endogenous copy was deleted. Growth of the resulting strain required the presence of the ComS inducer, confirming the essentiality of MurT/GatD. Depletion of MurT/GatD with reduced concentrations of inducer caused aberrant morphologies (Supplementary Fig. 1). Mild depletion (2.5 nM ComS) resulted in some elongated cells with aborted septa, whereas severe depletion (1.5 nM ComS) produced a high proportion of aberrant cells, elongated or bulging, showing that proper cell wall assembly requires a functioning murTgatD operon, as observed previously with strain D3913.
The effect of MurT/GatD depletion on peptidoglycan composition was examined after the growth was stunted by the lack of inducer, which occurred at OD550 ≈ 0.4 (Supplementary Table 1). As expected, the proportion of (Glu)-muropeptides increased from 18 to 42% upon depletion of MurT/GatD, indicating that a minimal amount of around 58% amidated muropeptide is required for growth. The proportion of cross-linked muropeptides decreased from 47 to 36%, which was also expected as efficient cross-linking depends on the presence of iso-Gln11. Surprisingly, there was an increase in the proportion of branched muropeptides from 16 to 57%. As branching depends on the MurM enzyme, a strain was constructed by deleting murM in the MurT/GatD depletion strain. In this strain without branched muropeptide, depletion of MurT/GatD caused a similar increase of (Glu)-muropeptides and decrease of cross-linking.
In vitro enzymatic activity
A continuous assay was set up for the future evaluation of potential inhibitors. MurT/GatD utilizes three reactants: L-Gln, ATP, and (Glu)-lipid II; and generates four products: L-Glu, ADP, phosphate, and (iGln)-lipid II (Fig. 1). An ATPase assay was chosen, monitoring the generation of ADP with coupled reactions that consumes NADH, which can be quantified by its absorbance18. Comparable kinetics were observed when aliquots withdrawn after various time intervals were analyzed by thin layer chromatography (Supplementary Fig. 2). The identity of the two lipid II species was checked by mass spectrometry (Supplementary Fig. 2). Although all enzymes and reactants are soluble in water, including lipid II (Supplementary Fig. 2), no activity was detected without detergent. It is presumed that lipid II forms micelles (Supplementary Fig. 2), and that tight packing of the muropeptide heads hinders access to the enzyme. With 25 μM lipid II, the enzymatic activity was optimal with n-dodecyl-β-D-maltoside (DDM) at concentrations between 5 and 30 mM. A DDM concentration of 20 mM (150-fold the critical micelle concentration) was chosen to ensure a micelle concentration superior to that of lipid II.
Apparent KM was obtained for the three substrates, and kcat was measured with lipid II (Table 1, Fig. 2). The apparent KM for lipid II is in the range of values reported for Mur ligases and their UDP-linked substrates (e.g., 5 and 90 μM for MurD and C6,19). Turnover is similar to values measured with Mur ligases (e.g., 1 to 15 s−1 for MurD20,21). Due to the limited availability of lipid II, we used a concentration below its apparent KM to measure the dependence of kinetics on the concentrations of L-Gln or ATP. Assuming that MurT has a mechanism similar to other Mur ligases with an ordered binding of the substrates prior to products release22,23, these measurements allow the estimation of the apparent KM for ATP and L-Gln. An additional assumption is that GatD is not limiting. The KM for ATP is in the lower range of values for Mur ligases (e.g., 17 and 100 μM for MurE and C6,24). The KM for L-Gln is one order of magnitude lower than reported for other amidotransferases such as the IGP synthase25.
Overall structures of MurT and GatD
Despite the limited resolution (3.0 Å, statistics in Supplementary Table 2), the electron density map allowed us to trace the main chains of all four complexes in the asymmetric unit, revealing a triangular complex with a large interface area adjacent to the enzymatic cavities of MurT and GatD (Fig. 3a). The N-terminal region (1–42) of MurT was not visible although its presence was confirmed by mass spectrometry, indicating that this short segment is mobile. The central (43–302) and C-terminal (303–439) domains are characteristic of the Mur ligases26 (Fig. 3b, c and Supplementary Fig. 3). The enzymatic cavity is nestled between the two domains, with a large solvent-accessible area and one side contacting GatD (Fig. 3a).
The central domain of MurT superimposes to those of Mur ligases with r.m.s.ds (root-mean-square deviations) of 2.9–3.1 Å over 116–119 residues (shown with Mur C in Supplementary Fig. 3). It consists of a six-stranded parallel β-sheet (β2β3β1β4β5β6) sandwiched between α-helices α2, α3, α4 on one side and a three-helix bundle (α1α5α6) on the other side, flanked by a three-stranded antiparallel β-sheet (β11β13β12) (Fig. 3b). In Mur ligases, α-helices α2, α3, α4 (α5, 3/10-helix η3 and α7in MurC) are flanked by a fourth helix (α8, Supplementary Fig. 3) that is not formed in MurT, as the corresponding segment (169–177) contains two prolines. The central domain forms a mononucleotide-binding domain including a typical P-loop (Walker A motif GxxGK)27. Residues 137–141 are not resolved in crystal structure. This loop may form a mobile bridge extending towards the C-terminal domain over the GatD active site. The most striking difference between the central domain of MurT and those of Mur ligases is the insertion of a cysteine-rich region (187–236) between β6 and β11 (Fig. 3b). This region will be further presented below.
The C-terminal domain of MurT consists of a six-stranded β-sheet (β14β15β19β16β17β18) surrounded by four helices on one side (α7, η7, η8, and α8) and two on the other side (α9 and α10) (Fig. 3c). Helices α8 and η7 interact with GatD. This domain forms a Rossmann fold28 that superimposes onto those of Mur ligases with r.m.s.ds of 2.9–3.4 Å over 129–159 residues (shown with MurC in Supplementary Fig. 3).
The structure of GatD from pneumococcus is similar to that from S. aureus (PDB# 5N9M; r.m.s.d. of 1.7 Å over 213 residues) and to other class I glutaminases, such as the HisH subunit of IGP synthase from Thermotoga maritima (PDB# 1GPW; r.m.s.d. of 2.9 Å over 190 residues) (Supplementary Fig. 4). It consists of a seven-stranded β-sheet (β1β3β2β4β5β15β14) surrounded by three α-helices on one side (α2, α3, α4) and four on the other side (α1, α5, α6, α7), and flanked by two four-stranded β-sheets (β7β6β8β11 and β10β9β12β13) (Fig. 4a). A notable difference between pneumococcal and staphylococcal proteins is the presence of a long C-terminal α7 in S. aureus, whereas this region mainly forms a contorted loop in the S. pneumoniae complex (Supplementary Fig. 4). The GatD active site faces MurT with solvent and substrate access in a cleft between both subunits (Fig. 3a).
The MurT cysteine-rich insertion
The central domain of MurT compared to that of Mur ligases, comprises a 50 residue-long cysteine-rich insertion (187–236) (Fig. 3b), with five cysteines in S. pneumoniae, in positions 205, 208, 227, 230, and 232, of which the first four are largely conserved. This cysteine tetrad is present in Firmicutes with the exception of the Oenococcus, Weissella, and Leuconostoc genera, where they are replaced by pairs of serine and aspartate. The tetrad is also present in Cyanobacteria, Chloroflexi, and some Actinobacteria.
The electron density map showed a great proximity of the 205, 208, 227, and 230 cysteine side chains. The best models include two disulfide bonds, most likely between pairs 205–230 and 208–227 (Supplementary Fig. 5), although alternative pairings cannot be ruled out. We found no evidence of a coordinated metal ion.
The presence of these disulfide bonds is surprising, as MurT/GatD functions in the cytoplasm where cysteines are reduced29. We suspected that these bonds had formed during crystallization, following the gradual depletion of the reducing agent. To determine if disulfide bonds were present immediately after the purification in reducing conditions, accessible thiols in MurT/GatD or in a mutant (MT4C4S) with the four cysteines of the disulfide bonds replaced by serines were alkylated by reaction with iodoacetamide. The number of alkylations was determined by mass spectrometry (Supplementary Fig. 6). The major species exhibited six alkylations for wild-type MurT/GatD and two for the MT4C4S variant, implying that the four thiols of the cysteine tetrad were reduced and accessible after purification. As the thiols of MTCys120 and MTCys325 are buried, the two other accessible thiols likely belong to MTCys232 and MTCys417. Note that the active site thiol of GatD was also alkylated.
When the PDB databank was searched for domains similar to the inserted region, the best match was the N-terminal zinc-ribbon domain of subunit RBN9 of the yeast RNA polymerase II (PDB# 3QT1 chain I30, Supplementary Fig. 5). Zinc-ribbons consist of a three-stranded antiparallel β-sheet supporting two “knuckles”, each carrying two cysteines that coordinate a Zn2+ cation31. The likeness (main chain r.m.s.d. 1.22 Å over 29 residues) between the RNA polymerase zinc-ribbon and the cysteine-rich insertion suggests that the latter also binds zinc in vivo, raising the question of why zinc was not found in our samples, despite the absence of chelators such as EDTA during purification. It is possible that zinc has been stripped by the high concentration of DTT as it chelates Zn2+ (KD ≈ 100 nM32).
That disulfide bonds are not required for catalysis was confirmed by the residual activity exhibited in vitro by the MT4C4S mutant (Table 2). However, the association with GatD was impacted by the quadruple mutation, as the ratio of the Coomassie-stained MurT/GatD bands after SDS-PAGE was 1.40, instead of 1.78 for the wild type (Supplementary Fig. 7). Also, the MT4C4S variant was degraded during storage at 4 °C. In vivo, the quadruple mutation was not tolerated (Table 2), although another mutant with lower in vitro activity was viable (GDY30A). It is therefore likely that the protein is destabilized and its abundance reduced in vivo.
MurT active site
Alignments of MurT and Mur ligases sequences revealed residues conserved in the whole Mur family or in MurT (Supplementary Fig. 8). To probe their importance, some residues were substituted and the activity was evaluated in vitro. In most cases, the conformation was likely unaffected as GatD was co-purified with MurT in comparable amounts with a ratio of MurT/GatD bands of 1.78 ± 0.15 (standard deviation). Partial digestion with trypsin at 30 °C after the metal-affinity chromatography resulted in similar fragment patterns for all active site variants, indicating that conformation and stability were little affected (Supplementary Fig. 9). GatD was resistant to digestion. The 35 kDa trypsin-resistant fragment of MurT could correspond to the C-terminal part of the protein digested in the loop 135–143. Interestingly, this part of the protein interacts with GatD, and MurT in the absence GatD was fully degraded by trypsin. The ability of some mutant MurT/GatD proteins to sustain growth of S. pneumoniae was also tested (Table 2).
To analyze the active site of MurT, we superimposed its structure with those of Mur ligases in complex with ligands (MurC PDB# 1P3D, r.m.s.d. of 3.6 Å over 303 residues; MurD PDB# 2UAG, r.m.s.d. of 4.4 Å over 290 residues; MurE PDB# 1E8C, r.m.s.d. of 3.7 Å over 292 residues; MurF PDB# 4CVM and 4QF5, r.m.s.ds of 3.7 and 4.7 Å over 316 and 309 residues, respectively, the latter superimposition is shown in Fig. 5). Models were also produced by computationally docking lipid II together with ATP in the active site (Fig. 6). The list of residues making contacts with the modeled substrates is given in Supplementary Table 3.
The Mur ligase structures show ATP sandwiched between the central and C-terminal domains and bound to the mononucleotide-binding motif. In MurT, the deep cleft to accommodate ATP is well defined and in the docking models the nucleotide fills a position very similar to that in Mur ligases. The substitution of MTLys59 of the P-loop (residues 52–60) by alanine abolished the enzymatic activity, as observed with MurC6. The primary amine of this lysine in MurC33 and MurF34 is coordinated by the two distal phosphates of ATP (Fig. 5a), and presumably plays a role in the transfer of the γ-phosphate to the acceptor peptide. Since the crucial role of MTLys59 was confirmed, the role of other conserved residues in ATP binding can reasonably be inferred from the structures of MurC and MurF, since the r.m.s.d. for residues of MurT and those of MurC or MurF within 4.0 Å of the bound nucleotide is only 1.05 Å (89 atoms) and 0.98 Å (81 atoms), respectively.
MTGly58, MTThr60, and MTArg304 would interact with the α-phosphate group (Fig. 5a). However, in apo-MurT, MTArg304 points away from the active site and the loop carrying this residue would have to flip by nearly 180° to interact with ATP. As conserved MTGly303 and MTArg304 form the hinge between the central and C-terminal domains, it is conceivable that reorientation of the two domains upon substrate binding might reposition MTArg304. MTGlu110 likely participates to ATP binding through coordination of one Mg2+ ion, while asparagines 132, 270, and 273 probably interact with the adenine (Fig. 5). No electron density was found in the ATP-binding pocket despite crystallization with ATP, or soaking in cryo-protectant solutions containing ATP.
Predictions of the binding mode of lipid II is more uncertain as substrate binding to Mur ligases offers little guidance. Lipid II lacks the uridine bound by the N-terminal domain of Mur ligases that also makes contacts with the pyrophosphate. Instead, the muropeptide-pyrophosphate of lipid II is anchored to the membrane by an undecaprenyl chain. The N-terminal region of MurT is mobile and not visible, precluding prediction of interactions with the pyrophosphate of lipid II.
Docking calculations suggest that the acceptor peptide is held against the loop connecting β2 and α2, which harbors the conserved MTGly83-Ala84-Asn85 motif (Fig. 7). MTAsn85 is fully conserved in MurT, but its position is poorly defined by the density map (Fig. 5b). A fully conserved asparagine is also found in MurD and MurF at the same position and the structures show an interaction with the acceptor carboxylate of the substrate peptide. Replacement of MTAsn85 by an alanine extinguished the activity of MurT/GatD (Table 2).
MTAsp112 and MTGlu113 are conserved in MurT and MurC, whereas they are replaced by a pair of serine residues in MurD and MurE, or a glycine and a hydrophobic residue in MurF. In MurC the two conserved acidic residues coordinate a Mg2+ ion between ATP and the acceptor carboxylate33. This arrangement was also found in the docking models. When the acidic residues in positions 112 and 113 were replaced by serines, the activity was lost, indicating that they could play an important role akin to that in MurC. In all Mur ligases, the Mg2+ ion coordinated by residues 112 and 113 and the acceptor carboxylate is also coordinated by a conserved histidine in an active site loop. The corresponding loop in MurT (135–143) that is not fully resolved in the crystal structure contains six conserved residues but lacks a histidine. Models gave no indication that residues of this loop could coordinate a Mg2+ ion as the histidine of Mur ligases.
In the high score docking models, localization of the acceptor peptide is consistent with its position in Mur ligases, but its orientation is unclear (Fig. 6). While the acceptor carboxylate is positioned close to the distal phosphate of ATP and a Mg2+ ion, the peptide chain runs in various directions. The pose presented in Fig. 6a is consistent with the substrate orientation in Mur ligases, whereas the pose presented in Fig. 6b presents an opposite orientation. The disaccharide has little or no interaction with the protein, as observed for the MurNAc in Mur ligases. In the computed models of the bound muropeptide, its lysine side chain forms a salt bridge with the pyrophosphate. This is in contrast to the situation in MurE where the ligand lysine is bridged to two conserved acidic residues of the C-terminal domain35. In MurT, the corresponding side of the catalytic cleft is devoid of acidic side chain, precluding a similar binding of the substrate lysine.
ATP and lipid II docked on the central-domain of the crystal structure do not interact with the C-terminal domain. Both domains are known to move relative to each other in Mur ligases26,36, and an acidic residue on a loop of the C-terminal domain is hydrogen-bonded to the ATP ribose in the closed conformation. The corresponding loop of MurT harbors three consecutive conserved residues Lys321-Asn322-Pro323, and MTAsn322 may contact the ATP ribose if the domains are brought in proximity. Reorientation of the domains may occur when the hinge MTArg304 interacts with ATP36.
GatD active site
The conserved residues GDCys107, GDHis206, and GDAsp32 are in positions close to the Cys83-His193-Glu195 catalytic triad of the glutaminase of yeast IGP synthase37 (Fig. 4b), identifying them as the probable catalytic residues. The corresponding residues in S. aureus GatD are Cys94-His189-Glu19. Glycine substitution of Cys94 in S. aureus GatD abolished amidation of lipid II4, and substitution of either Cys94 or His189 by alanine suppressed a residual glutaminase activity in the absence of MurT38. The glutamate of the triad in canonical class I glutaminases is highly conserved, two residues downstream of the catalytic histidine in sequence, but its catalytic role is uncertain as its replacement with a non-acidic residue had minor effect on the glutaminase activity of the human γ-glutamyl hydrolase or the Escherichia coli carbamoyl phosphate synthase39,40. Whereas GDAsp32 in S. pneumoniae GatD occupies a spatial position similar to the glutamate of the glutaminase triad, Asp19 in S. aureus GatD has a different orientation (Fig. 4c). This aspartate is at the junction between helix α1 and a loop joining strand β2. In S. pneumoniae GatD, this loop interacts with helix η8 of MurT. As S. aureus GatD was crystallized without MurT, the loop and Asp19 may have a non-native conformation. In T. maritima IGP synthase, Asp98 of the synthase subunit contributes to the glutaminase activity25. In MurT/GatD, MTAsp355 points towards GatD active site in an position analogous to Asp98 in the IGP synthase. However, unlike in the latter enzyme25, when MTAsp355 was replaced by an alanine, the activity was reduced but not suppressed (Table 2). The conserved GDGly72-Gly73-Gly74 likely provide the oxyanion hole, which is common to many hydrolases41.
After complete building of GatD in the electron density map, an elongated residual density was present in the vicinity of GDCys107 and occupied a volume that matched the position of the glutamine substrate in T. maritima IGP synthase25. Although no glutamine was added for crystallization, this compound could have been trapped while the protein was produced in E. coli; glutamine was thus tentatively placed in the residual density observed in GatD active site (Fig. 4).
Conserved GDArg142 at the extremity of the catalytic cleft opposite GDCys107 appears to interact with the glutamine substrate. The corresponding Arg128 in S. aureus GatD was found to interact with a glutamine outside of the active site, and its replacement by an alanine abrogated glutaminase activity38. The two structures support a model in which the side chain of GDArg142 helps to “capture” the substrate from the solution (Fig. 4c).
The MurT/GatD complex buries 1231 Å2 of solvent-accessible area, which is typical of enzymatic complexes42. The MurT loop 135–143, including the unresolved stretch 137–141, is at the interface with GatD in a position where it could connect the central and C-terminal domains and form a channel to conduct ammonia to the acceptor peptide. Individual replacement by alanine of four conserved charged residues of the loop had contrasting consequences. Whereas side chain ablation of MTAsp136 and MTArg140 reduced the enzymatic activity, that of MTAsp139 and MTGlu143 had minor effects. Although none of these substitutions changed the susceptibility to trypsin (Supplementary Fig. 9), the MTD136A and MTD139A substitutions impacted the interaction with GatD, as indicated by the modified ratio of purified MurT/GatD (Supplementary Fig. 7), complicating the interpretation of the enzymatic data.
Facing GatD, an opening in MurT is surrounded by negative charges provided by MTGlu201, MTAsp355, and MTAsp361. Flanking this negative gate is the positive charge of conserved MTArg135, which forms a bridge with MTGlu201 (Fig. 7a and Supplementary Figs 10 and 11). On the same side of the opening, a hydrophobic patch is formed by residues of the cysteine-rich insertion: MTTyr198, MTIle203, MTLeu204, MTIle211 (Fig. 7b). This hydrophobic surface is matched on GatD by a patch formed by GDLeu6, Cα and Cβ of GDAsn25, GDLeu26, GDIle36, GDIle54, GDLeu57, and GDPhe77. Another hydrophobic patch of MurT formed by MTTrp360 and MTVal391 on the other side of the negative gate is facing a corresponding patch on GatD formed by GDGly34, GDMet38, GDTyr41, and GDPro208 (Fig. 7b and Supplementary Figs 10 and 11). Lining this neutral patch and completing the interface, MTArg387 and MTArg390 make coulombic interaction with GDGlu245.
Residues of the hydrophobic interacting surfaces are not conserved with the exception of the pair MTTrp360 and GDGly34, which are in direct contact. Ablation of the indole rings by the MTW360A substitution abolished the interaction as GatD could not be co-purified with MurT (Supplementary Fig. 12). The resulting lone MurT protein was more susceptible to tryptic digestion than in the complex (Supplementary Fig. 9). This destabilization may result from the loss of interaction with GatD or directly from the absence of the indole ring, or from a combination of these intramolecular and intermolecular effects.
The GatD active site does not communicate directly with the opening in MurT. The passage is blocked by residues GDAsn28-Thr29-Tyr30 (Supplementary Fig. 10), with GDTyr30 in a position analogous to that of Tyr136 in T. maritima IGP synthase, where it plugs the entrance of the ammonia channel25. Substitution of Tyr136 by an alanine in IGP synthase uncoupled the glutaminase and synthase but preserved the overall activity25. In contrast, the GDY30A substitution severly reduced the MurT/GatD activity in vitro although it was tolerated in vivo (Table 2).
Viability of MurT/GatD point mutants
Different mutTgatD alleles were introduced at the native locus in a strain containing an ectopic copy of the operon. Deletion of the ectopic copy was then attempted. Only the wild type and GDY30A were tolerated, despite the fact that the GDY30A variant had a lower in vitro activity than other variants (Table 2). If less than 10% MurT/GatD activity is sufficient for growth, as implied by the viability of the GDY30A substitution, the lethality of the MTD355A and MT4C4S variants, which exhibit higher in vitro activity, may result from a lower stability in vivo or from disruption of other cellular interactions.
The essentiality of MurT/GatD is thought to result from the optimal transpeptidase activity of PBPs with amidated stem-peptides11. As predicted, depletion of MurT/GatD reduced the amount of cross-linked muropeptides (Supplementary Table 1). Reduced cross-linking could lead to reduced O-acetylation43, which could in turn increase susceptibility to lysozyme44.
The increase in branched peptides following depletion of MurT/GatD was unexpected. Non-amidated lipid II could be a better substrate for the MurM enzyme, thus inducing a balance between amidation and branching. However, as depletion of PBP2b also causes a surge in branched muropeptides45, we favor a more general explanation where branching is a phenotypic adaptation that compensate for a weaker cell wall. This adaptation could result from a greater availability of lipid II for MurM if its flow to the cell surface is reduced by the MurT or PBP2b depletion. This adaptation, however, is insufficient to rescue cells completely devoid of MurT/GatD, which remains an attractive drug target.
The limited resolution and absence of ligand leave a number of interrogation open for speculation. Of particular interest is the conformation of the loop 135–141. Two modeling resulted in markedly different conformation. In a model generated by SWISS-MODEL46 followed by energy minimization with YASARA47, the structure remained very close to the input crystal structure. In this model, the loop forms one side of the negative gate of MurT (Supplementary Fig. 10). MTAsp136 and MTAsp139 interact with MTArg140. In another model generated with Discovery Studio, the structure was more affected with many rearranged side chains. In this model, MurT shows no tunnel entrance (Supplementary Fig. 10), but MTArg140 protrudes inside GatD active site and MTArg135 closes the gate, while MTAsp136 forms a salt bridge with MTLys321. These models could represent different conformations accessible to the flexible loop.
The opening in MurT facing the active site of GatD communicates with a network of cavities inside MurT (Fig. 8). One branch is formed within the central domain between the Zinc-ribbon-like insertion and helix α2, another branch is extended between helix α7 of the C-terminal domain and the Zinc-ribbon-like region. These two branches may be obstructed by the reorientation of the domains. A third channel reaches into the MurT active site and likely serves to transfer ammonia generated by GatD. Escape of ammonia could be prevented by narrowing of the active site and the C-terminal domain contacting the substrates.
The hypotheses about substrate binding, loop conformation and domain movement await the determination of structures with bound ligands. The stabilizing role of zinc in the cysteine-rich region also require further investigation. The structure presented here will be invaluable in these endeavors, while substrate analogues and known inhibitors of Mur ligases will be tested to initiate a search for antibacterials aimed at the major pathogens S. pneumoniae, S. aureus, and M. tuberculosis.
Construction of a MurT/GatD depletion strain
Pneumococcal strains used and produced are listed in Supplementary Table 4. Depletion of MurT/GatD was performed by using the ComRS gene depletion system48. The strain SPH131 contains a replaceable Janus cassette behind the ComS-inducible PcomX promoter of the ComRS system. This Janus cassette was substituted with the murTgatD genes by transforming SPH131 with an amplicon comprising the operon fused with the 1000 bp regions flanking the Janus, giving rise to strain SPH476. This amplicon was constructed by amplifying the murTgatD operon from strain RH1 using the primers ds188 and ds189 (Supplementary Table 5). The Janus upstream and downstream regions were amplified using pairs khb31/khb36 and khb33/khb34. The three fragments were joined by overlap extension PCR49. Next, the native murTgatD operon in strain SPH476 was deleted by replacement with a Janus cassette. DNA fragments corresponding to the 1000 bp regions upstream and downstream of the native operon were amplified using pairs ds190/ds191 and ds192/ds193, respectively. Janus was amplified from strain SPH131 with the primer pair Kan484F/RpsL41R. The three PCR-products were fused by overlap extension PCR. The resulting amplicon was transformed into strain SPH476 generating strain SPH477, which required 0.2 µM ComS in the growth medium to drive ectopic expression of murTgatD. The Janus in the SPH477 genome was removed by transforming this strain with a DNA amplicon corresponding to the 1000 bp regions upstream and downstream of the native murTgatD. These fragments were amplified from RH1 using the pairs ds190/ds195 and ds193/ds194, and joined by overlap extension PCR. The resulting strain, SPH478, required 0.2 µM ComS in the growth medium.
Depletion of MurT/GatD and cell wall isolation
For isolation of cell wall material from MurT/GatD-depleted cells, strain SPH478 was first grown in 5 mL C medium to an OD550 = 0.35 in the presence of 0.2 μM ComS. Then, the cells were washed once with 5 mL ComS-free C medium before they were transferred to a bottle containing 1 L of ComS-free C medium. Cells were incubated at 37 °C, and growth was monitored at OD550 every 30 min. When growth levelled out because of MurT/GatD depletion (OD550 ≈ 0.4), cells were collected at 5000 g for 10 min. Cell wall material was isolated and analyzed as follows50. The cell pellet from 2 L of culture was resuspended in 40 mL of ice-cold 50 mM TrisHCl (pH 7.0) and added dropwise to 150 mL of boiling 5% sodium dodecyl sulfate (SDS). After boiling for another 30 min, the suspension was centrifuged 45 min at 130,000 g and 25 °C. Following two washes with 30 mL of 1 M NaCl and repeated washes with water until free of SDS, the pellet was resuspended in 2–4 mL of water, one-third volume of acid-washed glass beads (0.17–0.18 mm diameter, Sigma) was added to disrupt cells in a FastPrep machine (FP120, Thermo Scientific). After filtration to remove glass beads, and clarification with a 5 min centrifugation at 10,000 g, the supernatant was centrifuged for 45 min at 130,000 g and 25 °C. The pellet was resuspended and stirred for 2 h at 37 °C in 20 ml of 100 mM TrisHCl (pH 7.5), 20 mM MgSO4, 10 μg mL−1 DNase A and 50 μg mL−1 RNase I, prior to addition of 10 mM CaCl2 and 100 μg mL−1 trypsin and further incubation overnight at 37 °C, and enzymes were inactivated 15 min at 80 °C with 1% SDS. Cell wall was centrifuged for 45 min at 130,000 g at 25 °C, resuspended in 20 mL of 8 M LiCl, and incubated for 15 min at 37 °C. The procedure was repeated with 10 mM ethylenediaminetetraacetic acid (EDTA, pH 7.0). Cell wall was washed with water, acetone, and water before resuspension in 2–4 mL of water and lyophilization. To remove teichoic acids, 5 mg of cell wall was stirred with 48% hydrofluoric acid (HF) for two days at 4 °C. Peptidoglycan was centrifuged (45 min, 130,000 g, 4 °C), washed with water, 100 mM TrisHCl (pH 7.0), and twice with water. Peptidoglycan (0.5 mg in 200 μL) was digested with 10 μg of cellosyl in 20 mM sodium phosphate (pH 4.8) for 24 h at 37 °C. The reaction was stopped by heating at 100 °C for 10 min prior to centrifugation for 10 min at 13,000 g to clarify the solution. An equivalent volume of 500 mM sodium borate (pH 9.0) and a few crystals of NaBH4 were added and incubated 30 min at 20 °C to reduce saccharrides, and the reaction was stopped lowering the pH to 4.0 with H3PO4. Muropeptides were analyzed by reversed-phase HPLC using a Prontosil 120–3-C18-AQ (250 4.6 mm, 3 μM) column on an Agilent 1100 system. The separation was obtained with a linear 135-min gradient from 0 to 30% methanol in 10 mM sodium phosphate (pH 6.0) and the column temperature was 55 °C. The muropeptides were quantified by their peak area.
To prepare MurT/GatD-depleted cells for morphological examination, strain SPH478 was grown in 5 mL C-medium containing 0.2 µM ComS to an OD550 = 0.2. Then the cells were washed once with 5 mL ComS-free C-medium and diluted to OD550 = 0.01 in 5 mL C-medium containing 0.2 µM, 2.5 nM or 1.5 nM ComS. When the cell cultures reached OD550 = 0.3, the cells were harvested at 4000 g and diluted to OD550 = 0.01 in 10 mL fresh C-medium containing the same concentrations of ComS as described above. Cultures reaching OD550 = 0.3 were harvested at 4000 g for 5 min. Cells were washed once with ice cold PBS before they were fixed and prepared for scanning and transmission electron microscopy (SEM and TEM) as follows51. For SEM, cells were dehydrated with 70 and 90% ethanol for 10 min each and then with 100% ethanol overnight, and subjected to critical point drying with liquid CO2. Samples were coated with Au-Pd and examined with a Zeiss EVO 50 EP scanning electron microscope. For TEM, fixed cells were post-fixed for 1 h at room temperature using 1% OsO4 (w/v) and 1.5% K3[Fe(CN)6] (w/v) dissolved in water. Following three washing steps in water, cells were pre-stained for 30 min with 1% uranyl acetate. Next, cells were washed for three times in water and dehydrated with sequential 10-min incubations in 70, 90, and 100% ethanol. Finally, cells were stepwise infiltrated in LR White resin as follows: LR White resin: EtOH in ratios 1:3 for 30 min, 1:1 overnight and 3:1 for 4 h, and finally 100% LR White resin overnight followed by embedding in 100% LR White resin at 60 °C overnight. Thin sections were cut with a diamond knife mounted on an ultra-microtome (Leica, EM UC 6). The sections were counterstained with 1% KMnO4 for 10 min. After staining, grids were washed thoroughly in water. The sections were examined under a FEI MORGAGNI 268 electron microscope.
Site-directed mutagenesis for the recombinant production of point mutants of MurT/GatD were performed on double-stranded expression plasmids using primers with the desired mutations (Supplementary Table 5)52. Site-directed mutagenesis for expression of MurT/GatD in S. pneumoniae was performed by using overlap extension PCR with primers containing the desired mutations (Supplementary Table 5). The complementary forward and reverse primers annealing internally in the murT or gatD genes were used in combination with the primers ds190 and ds193, which bind 1000 bp upstream and downstream of murTgatD. Point mutated versions of the murTgatD operon were introduced into the S. pneumoniae genome by replacement of the Janus cassette in strain SPH477. The ectopic copy of murTgatD behind PcomX was then deleted by replacement with a Janus cassette amplified from strain SPH131 using the primer pair khb31/khb34. If the point mutation in murTgatD was not tolerated, the ectopic murTgatD could not be deleted.
Production of MurT/GatD
The complex was expressed from a modified pET-30 plasmid to allow co-expression in E. coli BL21 Star™ (DE3) of MurT with a N-terminal poly-histidine-tag and GatD without tag. After growth in Luria broth to saturation, expression was induced overnight at 20 °C by the addition of 0.5 mM IPTG. Cells were resuspended in 50 mM HEPES, pH 7.5, 300 mM NaCl, 10 mM MgCl2, 25 mM imidazole, 2 mM TCEP, and Complete™ protease inhibitors. After cell breakage with a Microfluidizer M−110P (Microfluidics) and removal of cellular debris and membranes by ultracentrifugation, the lysate was loaded onto a 1 mL HisTrap FF column (GE Healthcare) and proteins were eluted with imidazole concentration steps at 50, 100 and 200 mM. Fractions of the 100 mM imidazole step were pooled and diluted 10-fold in the same buffer without NaCl, imidazole or TCEP but with 5 mM DTT, and loaded onto a 8 mL Q Sepharose column (GE Healthcare). Proteins were eluted with a 150–450 mM NaCl gradient over 70 mL. After concentration using Amicon® Ultra-4 cells with a 30k cutoff, proteins were further purified by size-exclusion chromatography on an ENrich™ SEC650 column (BioRad) equilibrated with 50 mM HEPES, pH 7.5, 150 mM NaCl and 10 mM MgCl2, 2 mM DTT. For crystallization, the complex was concentrated again to more than 50 mg mL−1. Concentration was determined by measuring the absorbance at 280 nm with the extinction coefficient ε280 = 63,860 M−1 cm−1 (0.788 mg-1 mL cm−1). For activity measurements of the wild type and mutant proteins, the anion exchange chromatography was omitted and the final buffer contained 2 mM TCEP instead of DTT.
Crystallization trials on the native MurT/GatD complex were performed in 96-well Greiner Crystal Quick plates with 100 nL protein (6 mg mL−1) and 100 nL reservoir solution. Native MurT/GatD crystallized in 0.2 M tri-ammonium or tri-sodium citrate buffers, pH 6.0–8.2, 20% PEG 3350 at 20 °C in 24–48 h. Crystallization conditions were manually refined and large native crystals were finally obtained in 0.2 M tri-sodium citrate pH 6.1, 14% PEG 3350, 4 mM NiSO4. Native MurT/GatD crystals were cryoprotected by transfer into 0.2 M Tri-sodium citrate pH 6.1, 16% PEG 3350, 4 mM NiSO4, 20% glycerol, and then flash-frozen in liquid nitrogen. Seleno-methionine (SeMet) derivatives of MurT/GatD crystals were obtained in 0.2 M Tri-sodium citrate pH 6.2, 15% PEG 3350 and were cryoprotected by exchanging the mother liquor with crystallization solution containing 20% glycerol, and flash-frozen in liquid nitrogen. Native and SeMet MurT/GatD crystals crystallized in the space group R3 with isomorphous unit cell parameters (Supplementary Table 2). Native diffraction data were collected on the automated ID30a-1 beamline of the European Synchrotron Radiation Facility (ESRF, Grenoble, France). Single-wavelength anomalous diffraction (SAD) data were collected on the BM30A-FIP beamline at ESRF. The diffraction data were reduced by using XDS53 and phase determination was achieved using the SIRAS (Single Isomorphous Replacement with Anomalous Scattering) method, including a heavy-atom search with SHELXD54, followed by phasing with SHARP55 and density modification with SOLOMON56. All calculations were performed automatically using the autoSHARP package57. After automated model building using PHENIX58, the crystallographic model was refined by using REFMAC559 in the CCP4 package, iterated with manual building. Water, ion and glutamine molecules were added manually in COOT60. Model quality was determined by using PROCHECK61, with all residues within most favorable or allowed regions of the Ramachandran plot. The data collection and refinement statistics are summarized in Supplementary Table 2).
The activity of MurT/GatD was monitored through its hydrolysis of ATP. A classical ATPase assay was used where ADP is phosphorylated by pyruvate kinase from phosphoenolpyruvate, pyruvate being reduced to L-lactate by lactate dehydrogenase consuming NADH, which is followed by its absorbance at 340 nm62. For the determination of the enzymatic parameters, 10 μL of the substrate under investigation (lipid II, ATP or L-Gln) at 10-fold the final concentration in 50 mM HEPES, pH 7.5, 150 mM NaCl and 10 mM MgCl2 were placed in a 1 cm quartz cuvette prior to the addition at time t = 0 of 90 μL of the reaction mix (minus the substrate being studied) in the same buffer to reach the following final concentrations: 250 μM NADH, 1 mM potassium phosphoenolpyruvate, 25 μg mL−1 L-lactate dehydrogenase (porcine, Roche Diagnostics), 50 μg.mL-1 pyruvate kinase (rabbit, Roche Diagnostics), 2 mM TCEP, 1% n-dodecyl-β-D-maltoside (DDM, Anatrace), 190 nM MurT/GatD, 10 μM lipid II, 2 mM ATP and 10 mM L-Gln. The absorbance at 340 nm was recorded at 30 °C with a thermostated Uvikon 943 double beam spectrophotometer (Kontron Instruments). When investigating the activity of MurT/GatD mutants, 10 μL of lipid II and 40 μL of MurT/GatD variant were placed in the cuvette prior to the addition of 50 μL of reaction mix to reach the same final concentrations stated above, except lipid II at 20 μM. The amounts of NADH, potassium phosphoenolpyruvate, L-lactate dehydrogenase and pyruvate kinase were checked to be non-limiting.
Initial velocities (Vi) were measured by linear fitting of the reaction progress curves at early time points using the extinction coefficient of NADH at 340 nm ε = 6300 M−1cm−1. The apparent KM and Vmax were extracted from non-linear fitting of the Vi at different substrate concentrations [S] to the Michaelis-Menten equation Vi = [S]Vmax/(KM + [S]). Fittings were performed using the Kaleidagraph (Synergy) software. Alternatively, the complete progress curves were collectively fitted to a Michaelis-Menten model of the reaction to extract the apparent KD and kcat using the Dynafit software (Biokin)63.
The number of accessible free thiols was determined by alkylation under native condition of wild-type and 4C4S MurT/GatD and mass spectrometry analysis. One fourth-volume of 0.5 M iodoacetamide in 1.5 M Tris HCl pH 8.8 were added to the purified proteins for 5 min at room temperature prior to desalting on G-25 Sephadex resin (NAP-5 column, GE Healthcare) in 50 mM ammonium acetate pH 7. Samples were analyzed by electrospray mass spectrometry.
Calculations were performed in BIOVIA Discovery Studio 4.5 (Accelrys). The structure of MurT/GatD was cleaned, side-chain conformations were optimized for residues with inserted atoms, missing loops were modeled based on SEQRES information, and the protonation state was predicted at pH 7.5 (Prepare Protein protocol of DS 4.5). CDOCKER64 was used to dock flexible ligands onto the rigid protein.
To propare ligands, canonical tautomers were generated, keeping the largest fragments, standard charges of common functional groups were used, kekule structures were generated, ionization states at a given pH range and tautomers were enumerated (Prepared Ligand protocol of DS 4.5). Reasonable 3D conformations were created using Catalyst. High-temperature molecular dynamics were used to generate random ligand conformations from the initial ligand structure. Due to the high flexibility of lipid II, several conformations generated with the BEST algorithm65 were docked to cover the full range of conformers. The lowest energy poses were retained and clustered according to their binding mode and the interaction with key residues. Snapshots of the docked ligands were generated using BIOVIA DS Visualizer.
Coordinates and structure factors have been deposited in the Protein Data Bank, with Accession No. 6FQB [https://doi.org/10.2210/pdb6FQB/pdb]. The data that support the findings of this study are available from the corresponding author upon request.
Vollmer, W., Blanot, D. & de Pedro, M. A. Peptidoglycan structure and architecture. FEMS Microbiol. Rev. 32, 149–167 (2008).
Siewert, G. & Strominger, J. L. Biosynthesis of the peptidoglycan of bacterial cell walls. XI. Formation of the isoglutamine amide group in the cell walls of Staphylococcus aureus. J. Biol. Chem. 243, 783–790 (1968).
Figueiredo, T. A. et al. Identification of genetic determinants and enzymes involved with the amidation of glutamic acid residues in the peptidoglycan of Staphylococcus aureus. PLoS. Pathog. 8, e1002508 (2012).
Munch, D. et al. Identification and in vitro analysis of the GatD/MurT enzyme-complex catalyzing lipid II amidation in Staphylococcus aureus. PLoS. Pathog. 8, e1002509 (2012).
Barreteau, H. et al. Cytoplasmic steps of peptidoglycan biosynthesis. FEMS Microbiol. Rev. 32, 168–207 (2008).
Bouhss, A., Mengin-Lecreulx, D., Blanot, D., van Heijenoort, J. & Parquet, C. Invariant amino acids in the Mur peptide synthetases of bacterial peptidoglycan synthesis and their modification by site-directed mutagenesis in the UDP-MurNAc:L-alanine ligase from Escherichia coli. Biochemistry (Mosc.) 36, 11556–11563 (1997).
Eveland, S. S., Pompliano, D. L. & Anderson, M. S. Conditionally lethal Escherichia coli murein mutants contain point defects that map to regions conserved among murein and folyl poly-gamma-glutamate ligases: identification of a ligase superfamily. Biochemistry (Mosc.) 36, 6223–6229 (1997).
Kouidmi, I., Levesque, R. C. & Paradis-Bleau, C. The biology of Mur ligases as an antibacterial target. Mol. Microbiol. 94, 242–253 (2014).
Mouilleron, S. & Golinelli-Pimpaneau, B. Conformational changes in ammonia-channeling glutamine amidotransferases. Curr. Opin. Struct. Biol. 17, 653–664 (2007).
Vaganay, S., Tanner, M. E., van Heijenoort, J. & Blanot, D. Study of the reaction mechanism of the D-glutamic acid-adding enzyme from Escherichia coli. Microb. Drug. Resist. 2, 51–54 (1996).
Zapun, A. et al. In vitro reconstitution of peptidoglycan assembly from the Gram-positive pathogen Streptococcus pneumoniae. Acs. Chem. Biol. 8, 2688–2696 (2013).
DeJesus, M. A. et al. Comprehensive essentiality analysis of the Mycobacterium tuberculosis genome via saturating transposon mutagenesis. mBio 8, e02133–16 (2017).
Liu, X. et al. High-throughput CRISPRi phenotyping identifies new essential genes in Streptococcus pneumoniae. Mol. Syst. Biol. 13, 931 (2017).
Thanassi, J. A., Hartman-Neumann, S. L., Dougherty, T. J., Dougherty, B. A. & Pucci, M. J. Identification of 113 conserved essential genes using a high-throughput gene disruption system in Streptococcus pneumoniae. Nucleic Acids Res. 30, 3152–3162 (2002).
Chaudhuri, R. R. et al. Comprehensive identification of essential Staphylococcus aureus genes using transposon-mediated differential hybridisation (TMDH). BMC Genom. 10, 291 (2009).
Xu, H. H. et al. Staphylococcus aureus TargetArray: comprehensive differential essential gene expression as a mechanistic tool to profile antibacterials. Antimicrob. Agents Chemother. 54, 3659–3670 (2010).
Figueiredo, T. A., Ludovice, A. M. & Sobral, R. G. Contribution of peptidoglycan amidation to beta-lactam and lysozyme resistance in different genetic lineages of Staphylococcus aureus. Microb. Drug. Resist. 20, 238–249 (2014).
Wampler, D. E. & Westhead, E. W. Two aspartokinases from Escherichia coli. Nature of the inhibition and molecular changes accompanying reversible inactivation. Biochemistry (Mosc.) 7, 1661–1671 (1968).
Bouhss, A. et al. Role of the ortholog and paralog amino acid invariants in the active site of the UDP-MurNAc-L-alanine:D-glutamate ligase (MurD). Biochemistry (Mosc.) 38, 12240–12247 (1999).
Munshi, T. et al. Characterisation of ATP-dependent Mur ligases involved in the biogenesis of cell wall peptidoglycan in Mycobacterium tuberculosis. PLoS. One. 8, e60143 (2013).
Pratviel-Sosa, F., Mengin-Lecreulx, D. & van Heijenoort, J. Over-production, purification and properties of the uridine diphosphate N-acetylmuramoyl-L-alanine:D-glutamate ligase from Escherichia coli. Eur. J. Biochem. 202, 1169–1176 (1991).
Anderson, M. S., Eveland, S. S., Onishi, H. R. & Pompliano, D. L. Kinetic mechanism of the Escherichia coli UDPMurNAc-tripeptide D-alanyl-D-alanine-adding enzyme: use of a glutathione S-transferase fusion. Biochemistry (Mosc.) 35, 16264–16269 (1996).
Emanuele, J. J., Jin, H., Yanchunas, J. & Villafranca, J. J. Evaluation of the kinetic mechanism of Escherichia coli uridine diphosphate-N-acetylmuramate:L-alanine ligase. Biochemistry (Mosc.) 36, 7264–7271 (1997).
Basavannacharya, C. et al. Essential residues for the enzyme activity of ATP-dependent MurE ligase from Mycobacterium tuberculosis. Protein Cell 1, 1011–1022 (2010).
List, F. et al. Catalysis uncoupling in a glutamine amidotransferase bienzyme by unblocking the glutaminase active site. Chem. Biol. 19, 1589–1599 (2012).
Smith, C. A. Structure, function and dynamics in the mur family of bacterial cell wall ligases. J. Mol. Biol. 362, 640–655 (2006).
Saraste, M., Sibbald, P. R. & Wittinghofer, A. The P-loop–a common motif in ATP- and GTP-binding proteins. Trends Biochem. Sci. 15, 430–434 (1990).
Rao, S. T. & Rossmann, M. G. Comparison of super-secondary structures in proteins. J. Mol. Biol. 76, 241–256 (1973).
Derman, A. I., Prinz, W. A., Belin, D. & Beckwith, J. Mutations that allow disulfide bond formation in the cytoplasm of Escherichia coli. Science 262, 1744–1747 (1993).
Ruan, W., Lehmann, E., Thomm, M., Kostrewa, D. & Cramer, P. Evolution of two modes of intrinsic RNA polymerase transcript cleavage. J. Biol. Chem. 286, 18701–18707 (2011).
Krishna, S. S., Majumdar, I. & Grishin, N. V. Structural classification of zinc fingers: survey and summary. Nucleic Acids Res. 31, 532–550 (2003).
Krezel, A. et al. Coordination of heavy metals by dithiothreitol, a commonly used thiol group protectant. J. Inorg. Biochem. 84, 77–88 (2001).
Mol, C. D. et al. Crystal structures of active fully assembled substrate- and product-bound complexes of UDP-N-acetylmuramic acid:L-alanine ligase (MurC) from Haemophilus influenzae. J. Bacteriol. 185, 4152–4162 (2003).
Cha, S. S., An, Y. J., Jeong, C. S., Yu, J. H. & Chung, K. M. ATP-binding mode including a carbamoylated lysine and two Mg(2+) ions, and substrate-binding mode in Acinetobacter baumannii MurF. Biochem. Biophys. Res. Commun. 450, 1045–1050 (2014).
Ruane, K. M. et al. Specificity determinants for lysine incorporation in Staphylococcus aureus peptidoglycan as revealed by the structure of a MurE enzyme ternary complex. J. Biol. Chem. 288, 33439–33448 (2013).
Šink, R. et al. Crystallographic study of peptidoglycan biosynthesis enzyme MurD: domain movement revisited. PLoS. One. 11, e0152075 (2016).
Chaudhuri, B. N. et al. Crystal structure of imidazole glycerol phosphate synthase: a tunnel through a (beta/alpha)8 barrel joins two active sites. Structure 9, 987–997 (2001).
Leisico, F. et al. First insights of peptidoglycan amidation in Gram-positive bacteria—the high-resolution crystal structure of Staphylococcus aureus glutamine amidotransferase GatD. Sci. Rep. 8, 5313 (2018).
Huang, X. & Raushel, F. M. Deconstruction of the catalytic array within the amidotransferase subunit of carbamoyl phosphate synthetase. Biochemistry (Mosc.) 38, 15909–15914 (1999).
Chave, K. J., Auger, I. E., Galivan, J. & Ryan, T. J. Molecular modeling and site-directed mutagenesis define the catalytic motif in human gamma-glutamyl hydrolase. J. Biol. Chem. 275, 40365–40370 (2000).
Zalkin, H. & Smith, J. L. in Advances in Enzymology and Related Areas of Molecular Biology (ed. Purich, D. L.) 87–144, https://doi.org/10.1002/9780470123188.ch4 (John Wiley & Sons, Inc., 1998).
Sowmya, G., Breen, E. J. & Ranganathan, S. Linking structural features of protein complexes and biological function. Protein Sci. 24, 1486–1494 (2015).
Sychantha, D. et al. In vitro characterization of the antivirulence target of Gram-positive pathogens, peptidoglycan O-acetyltransferase A (OatA). PLoS. Pathog. 13, e1006667 (2017).
Davis, K. M., Akinbi, H. T., Standish, A. J. & Weiser, J. N. Resistance to mucosal lysozyme compensates for the fitness deficit of peptidoglycan modifications by Streptococcus pneumoniae. PLoS. Pathog. 4, e1000241 (2008).
Berg, K. H., Stamsås, G. A., Straume, D. & Håvarstein, L. S. Effects of low PBP2b levels on cell morphology and peptidoglycan composition in Streptococcus pneumoniae R6. J. Bacteriol. 195, 4342–4354 (2013).
Arnold, K., Bordoli, L., Kopp, J. & Schwede, T. The SWISS-MODEL workspace: a web-based environment for protein structure homology modelling. Bioinformatics 22, 195–201 (2006).
Krieger, E. & Vriend, G. YASARA View - molecular graphics for all devices- from smartphones to workstations. Bioinformatics 30, 2981–2982 (2014).
Berg, K. H., Biørnstad, T. J., Straume, D. & Håvarstein, L. S. Peptide-regulated gene depletion system developed for use in Streptococcus pneumoniae. J. Bacteriol. 193, 5207–5215 (2011).
Higuchi, R., Krummel, B. & Saiki, R. K. A general method of in vitro preparation and specific mutagenesis of DNA fragments: study of protein and DNA interactions. Nucleic Acids Res. 16, 7351–7367 (1988).
Bui, N. K. et al. Isolation and analysis of cell wall components from Streptococcus pneumoniae. Anal. Biochem. 421, 657–666 (2012).
Straume, D., Stamsås, G. A., Salehian, Z. & Håvarstein, L. S. Overexpression of the fratricide immunity protein ComM leads to growth inhibition and morphological abnormalities in Streptococcus pneumoniae. Microbiology 163, 9–21 (2017).
Braman, B., Papworth, C. & Greener, A. Methods in Molecular Biology. 31–44 (Humana Press Inc., Totowa, NJ, 1996).
Kabsch, W. XDS. Acta Crystallogr. D. Biol. Crystallogr. 66, 125–132 (2010).
Sheldrick, G. M. Experimental phasing with SHELXC/D/E: combining chain tracing with density modification. Acta Crystallogr. D. Biol. Crystallogr. 66, 479–485 (2010).
de La Fortelle, E. & Bricogne, G. Maximum-likelihood heavy-atom parameter refinement for multiple isomorphous replacement and multiwavelength anomalous diffraction methods. Methods Enzymol. 276, 472–494 (1997).
Abrahams, J. P. & Leslie, A. G. Methods used in the structure determination of bovine mitochondrial F1 ATPase. Acta Crystallogr. D. Biol. Crystallogr. 52, 30–42 (1996).
Vonrhein, C., Blanc, E., Roversi, P. & Bricogne, G. Automated structure solution with autoSHARP. Methods Mol. Biol. 364, 215–230 (2007).
Terwilliger, T. C. et al. Iterative model building, structure refinement and density modification with the PHENIX AutoBuild wizard. Acta Crystallogr. D. Biol. Crystallogr. 64, 61–69 (2008).
Murshudov, G. N. et al. REFMAC5 for the refinement of macromolecular crystal structures. Acta Crystallogr. D. Biol. Crystallogr. 67, 355–367 (2011).
Emsley, P., Lohkamp, B., Scott, W. G. & Cowtan, K. Features and development of Coot. Acta Crystallogr. D. Biol. Crystallogr. 66, 486–501 (2010).
Laskowski, R. A., MacArthur, M. W., Moss, D. S. & Thornton, J. M. PROCHECK: a program to check the stereochemical quality of protein structures. J. Appl. Crystallogr. 26, 283–291 (1993).
Pullman, M. E., Penefsky, H. S., Datta, A. & Racker, E. Partial resolution of the enzymes catalyzing oxidative phosphorylation. I. Purification and properties of soluble dinitrophenol-stimulated adenosine triphosphatase. J. Biol. Chem. 235, 3322–3329 (1960).
Kuzmic, P. Program DYNAFIT for the analysis of enzyme kinetic data: application to HIV proteinase. Anal. Biochem. 237, 260–273 (1996).
Wu, G., Robertson, D. H., Brooks, C. L. & Vieth, M. Detailed analysis of grid-based molecular docking: a case study of CDOCKER-A CHARMm-based MD docking algorithm. J. Comput. Chem. 24, 1549–1562 (2003).
Smellie, A., Kahn, S. D. & Teig, S. L. Analysis of conformational coverage. 1. Validation and estimation of coverage. J. Chem. Inf. Comput. Sci. 35, 285–294 (1995).
We thank Jennifer Galindo and Charlène Thedevuide for assistance in protein preparation, Luca Signor for mass spectrometry analysis, Philippe Calvez and Daphna Fenel for electron microscopy of lipid II, David Cobessi for support in SAD data collection on BM30A, Teresa Santos-Silva for access to S. aureus GatD structure prior to publication, as well as T. Vernet and A. Dessen for critical reading and administrative support. This work was supported by grant AstraZeneca IMMI 2014016. We acknowledge the platforms of the Grenoble Instruct center (ISBG; UMS 3518 CNRS-CEA-UGA-EMBL) supported by the French Infrastructure for Integrated Structural Biology Initiative FRISBI (ANR-10-INSB-05-02) and by the Grenoble Alliance for Integrated Structural Cell Biology GRAL (ANR-10-LABX-49-01) within the Grenoble Partnership for Structural Biology (PSB). W. Vollmer is funded by the Wellcome Trust (grant 101824/Z/13/Z).
The authors declare no competing interests.
Publisher's note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Electronic supplementary material
About this article
Cite this article
Morlot, C., Straume, D., Peters, K. et al. Structure of the essential peptidoglycan amidotransferase MurT/GatD complex from Streptococcus pneumoniae. Nat Commun 9, 3180 (2018). https://doi.org/10.1038/s41467-018-05602-w
Nature Chemistry (2021)