Abstract
The sugars streptose and dihydrohydroxystreptose (DHHS) are unique to the bacteria Streptomyces griseus and Coxiella burnetii respectively. Streptose forms the central moiety of the antibiotic streptomycin, whilst DHHS is found in the O-antigen of the zoonotic pathogen C. burnetii. Biosynthesis of these sugars has been proposed to follow a similar path to that of TDP-rhamnose, catalysed by the enzymes RmlA/RmlB/RmlC/RmlD. Streptose and DHHS biosynthesis unusually require a ring contraction step that might be performed by the orthologues of RmlC or RmlD. Genome sequencing of S. griseus and C. burnetii proposed the StrM and CBU1838 proteins respectively as RmlC orthologues. Here, we demonstrate through both coupled and direct observation studies that both enzymes can perform the RmlC 3’’,5’’ double epimerisation activity; and that this activity supports TDP-rhamnose biosynthesis in vivo. We demonstrate that proton exchange is faster at the 3’’ position than the 5’’ position, in contrast to a previously studied orthologue. We solved the crystal structures of CBU1838 and StrM in complex with TDP and show that they form an active site highly similar to previously characterised enzymes. These results further support the hypothesis that streptose and DHHS are biosynthesised using the TDP pathway and are consistent with the ring contraction step being performed on a double epimerised substrate, most likely by the RmlD paralogue. This work will support the determination of the full pathways for streptose and DHHS biosynthesis.
Introduction
The gammaproteobacterium Coxiella burnetii evolved recently from tick endosymbionts1 to become an obligate intracellular pathogen of mammals 2. This bacterium infects a wide range of mammals causing reproductive failures 3,4. It is a significant economic pathogen of sheep, goats and cattle 5, causing spontaneous abortion of pregnancies 6. Humans can be infected by C. burnetii either through aerosols or consumption of meat and dairy products (with 1-10 bacteria sufficient to cause disease) 7,8. C. burnetii in unpasteurised ruminant milk poses a particular risk 9-11. Humans generally present with a self-limiting febrile illness 12. A small percentage of cases lead to more serious complications such as miscarriage, hepatitis, or endocarditis 2,13,14. C. burnetii infection can be effectively treated with doxycycline 2. However, diagnosis is often challenging as C. burnetii grows only in highly defined media, requires environment-controlled microaerobic incubators, 15 and symptoms of infection are generally non-specific.
From a “One Health” perspective, a vaccine against C. burnetii would be the ideal approach to reduce veterinary and human infection 6. Inactivated whole cell vaccines have proved effective in animals and humans 16,17. These are not licensed for human use in the USA, EU or UK as they cause severe reactions in seropositive individuals 18. Current efforts to develop novel vaccines are focused on development of subunit 19 or epitope based vaccines 20,21. A very strong subunit vaccine candidate is the C. burnetii polysaccharide O-antigen. A complete O-antigen is required for immune evasion and efficient infection of mammalian cells 22,23. Serial passaging of C. burnetii selects for mutants that cease producing some or all their O-antigen 24,25. The most common mutants either lack a polymer of the unusual saccharide virenose (“intermediate”), or the entire O-antigen 26 (Figure 1A). Strains lacking the O-antigen are avirulent in the guinea-pig model of infection 27. The O-antigen is the dominant epitope of wild-type C. burnetii 28, suggesting that any vaccine against C. burnetii will require the O-antigen 28. This highlights the importance of a deepened understanding of the biosynthesis of this polysaccharide.
The C. burnetii O-antigen characteristically contains two C-3 methylated/hydroxymethylated sugars, virenose and dihydrohydroxystreptose (DHHS; Figure 1B) 29,30. Virenose is also found in Bacillus cereus and Streptomyces albaduncus 31,32. Biosynthetic pathways have been proposed in these two organisms, and a similar pathway has been proposed in C. burnetii 33. No equivalent pathway has been proposed for DHHS biosynthesis. The most similar known sugar to DHHS is streptose (Figure 1B), the central saccharide unit of the aminoglycoside antibiotic streptomycin 34, produced by Streptomyces griseus. Streptose differs from DHHS in having no hydroxyl at C-6; and being oxidised at the C-3 hydroxymethyl group. Streptose is synthesised from TDP-glucose, in a manner analogous to the biosynthesis of rhamnose (Figure 1C) 34-37. A reasonable path to DHHS synthesis would involve a C-4 oxidase of TDP-glucose, a 5’’-mono or 3’’,5’’-double epimerase 38, and an enzyme similar to the streptose synthase 37 (Figure 1D,E). Although it remains possible that the epimerase might also perform the ring rearrangement, the only precedent for this reaction was performed by an enzyme from a different structural class 39.
Two operons (cbu0825 to cbu0856, and cbu1831 to cbu1838) have been suggested as coding for DHHS synthesising genes 26. The cbu1831 to cbu1838 contains two genes that show high sequence identity to genes in the rhamnose biosynthesis pathway. CBU1834 has over 60% sequence identity to characterised RmlA orthologues 33, and so is highly likely to be a glucose-1-phosphate thymidylyltransferase. TDP-glucose has also been proposed to be a precursor of virenose 33, and so is not necessarily characteristic of DHHS biosynthesis. CBU1838 shows 48% identity with characterised RmlC orthologues. With this sequence identity, this protein is highly likely to be an orthologue of RmlC and act as a TDP-D-xylo-4-hexulose 3,5-epimerase. This activity is not required for virenose biosynthesis. As C. burnetii does not produce rhamnose, it is unlikely that it would be required for rhamnose biosynthesis. This leaves DHHS biosynthesis as the only reasonable function of CBU1838.
RmlC is part of a family of epimerases that use a deprotonation/reprotonation mechanism40. RmlC uses a histidine base to deprotonate the substrate, and a tyrosine acid to reprotonate from the opposite side of the sugar 41-44. The same residues are likely involved in epimerising at both 3’’ and 5’’ positions: the sugar ring flips between the two reactions to present the second site to be epimerised to the catalytic base and acid41. These amino acids are highly conserved in the family (Figure 2). RmlC orthologues have been characterised biochemically and structurally from a range of species (Table 1) 38,42,43,45,46. Paralogues that selectively epimerise at either the 3’ or 5’ carbon have also been characterised44,47,48. These studies have highlighted likely residues for binding to the TDP carrier43,49,50. For streptose and DHHS biosynthesis, only epimerisation at the 5’’ position is strictly necessary: the C3-C4 bond is broken in the streptose biosynthesis step35, which will remove the stereocentre at C3. RmlC paralogues for streptose (StrM) and DHHS (CBU1838) biosynthesis have been proposed bioinformatically33 (e.g. by KEGG 51); however, such assignments can be inaccurate and so experimental confirmation is desirable 52.
Here, we tested the hypothesis that StrM and CBU1838 are orthologues of RmlC. We expected that they would perform only the epimerisation step, and not perform the structural rearrangement activity that has yet to be assigned. As both enzymes contain all the catalytic residues proposed for 3’’,5’’-double epimerisation, we expected that they might perform both transformations. We demonstrate in vivo and in vitro that these enzymes are competent to perform the double epimerisation. Using NMR, we demonstrate that, surprisingly, proton-deuteron exchange at the 3’’ position is faster than at the 5’’ position for both enzymes. The structures of CBU_1838 and StrM show that they form an active site highly similar to previously characterised enzymes, in keeping with the biochemical data. These data support a 3’’, 5’’-double epimerised substrate for the streptose ring re-arrangement.
Results
CBU1838 complement RmlC in E. coli
We firstly tested whether CBU1838 can complement the E. coli RmlC orthologue RfbC. We cultured wild-type MG1655 E. coli and rfbC mutant bacteria, and rfbC mutants complemented with CBU1838. We extracted soluble small molecules from each culture. No TDP-linked sugars were detected in wild-type MG1655. In contrast, the rfbC mutant contained both TDP-glucose and TDP-6-deoxy-D-xylo-4-hexulose (Figure 3), as expected for a mutant at this essential step of the pathway. Neither of these compounds were detected when the rfbC mutant was complemented with CBU1838, restoring wild-type activity (Figure 3). These data gave good confidence that CBU1838 performs both 3’’ and 5’’ epimerisations of TDP-6-deoxy-D-xylo-4-hexulose, as expected.
StrM and CBU1838 complement RmlC in vitro
We next tested whether StrM and CBU1838 can perform the function of E. coli RmlC in a coupled assay. We used the test enzyme coupled to RmlB and RmlD in a catalytic cascade to convert TDP-glucose to TDP-rhamnose. Both StrM and CBU1838 complemented RmlC in these assays effectively (Figure 4). Identical concentrations of StrM and RmlC gave a similar effect. A higher concentration of CBU1838 was required to achieve the same effect. This is consistent with the expected function of CBU1838, epimerising a sugar that retains the 6’’-OH group.
These data further support the concept that StrM and CBU1838 perform both 3’’ and 5’’ epimerisations of TDP-6-deoxy-D-xylo-4-hexulose.
CBU1838 shows a reduced rate compared to RmlC and StrM, consistent with its modified substrate
We determined the kinetic constants for StrM and RmlC, in comparison to other characterised enzymes. We used purified TDP-6-deoxy-D-xylo-4-hexulose and coupled the test enzymes to RmlD. Data from StrM, RmlC, CBU1838 and EvaD all fitted very well to the Michaelis-Menten equation, with no evidence of cooperativity (Figure S1). StrM and RmlC showed a similar kcat, with StrM having a slightly lower KM (Table 2). CBU1838 showed a lower kcat and a clearly higher KM (Table 2). This is consistent with its expected 6’’-hydroxy substrate. As expected, the 5’’-specific epimerase EvaD showed a substantially lower kcat. We did not observe any activity with the 3’’-specific epimerase ChmJ (Figure S2). Previous studies have demonstrated that ChmJ has no 5’’-epimerisation activity 44, and that the coupling enzyme RmlD only reduces double-epimerised products 53,54. The kinetic constants provide further evidence that StrM is likely an orthologue of RmlC. CBU1838 can performs this activity, but its likely native substrate is 6’’-hydroxylated.
RmlC, StrM and 1838 epimerise at both the 3’’ and 5’’ positions
To give further confidence in the activity of CBU1838 and StrM, in a novel assay, we monitored their activity directly using NMR and GC-MS without employing a coupling agent. We performed 1H-NMR experiments in deuterated buffer. As RmlC uses a deprotonation-protonation mechanism with different proton acceptors and donors, we expected to observe a loss of signal from protons bound to the 5’’ and 3’’ carbon atoms. We observed solvent exchange at both positions for RmlC, StrM, CBU1838 and EvaD, with relative rates in the same order as the rates observed in a coupled assay (Figure 5A, S3). Surprisingly, the rate of exchange at the 3’’ position was significantly faster than the rate at the 5’’ position for RmlC, StrM and CBU1838 (Table 3); for RmlD the rate of exchange at the two positions was similar. When the reaction was permitted to proceed to completion, RmlC, StrM and CBU1838 all showed almost complete exchange at both 3’’ and 5’’ positions (Figure 5B). In contrast, the 3’’ specific enzyme ChmJ showed almost complete exchange at the 3’’ position, with very little exchange observed at the 5’’ position. GC-MS analysis of enzyme reactions run to completion confirmed that exchange had occurred at both positions for CBU1838, StrM and RmlC (Figure S4). Consistent with the NMR data and previous work44, ChmJ showed strong exchange at the 3’’ position only. These data strongly support a double epimerase activity for both CBU1838 and StrM.
Sugar backbone rearrangement is not observed with either StrM or CBU1838
In neither NMR nor GC-MS data was there any evidence of a rearrangement of the sugar backbone. The proposed biosynthetic pathways of both StrM and CBU1838 require such a rearrangement, catalysed by either the epimerase or a synthase/reductase for each pathway. Our direct detection of product formation and chemical structure analysis might have allowed us to detect this re-arrangement. However, as the five-membered rings are likely to be substantially disfavoured at equilibrium, the possibility remains that re-arranged structures were present but below the limit of detection.
The structures of StrM and CBU1838 are consistent with their role as double epimerases
We determined the structures of StrM and CBU1838 by X-ray crystallography, in the presence and absence of TDP (Table S1). Both proteins show an overall dimeric architecture consistent with previously solved members of this family (Figure 6A). Both proteins show a strand exchange in common with orthologues. TDP binds to both proteins in a similar manner (Figure 6B,C). TDP is held in place by a network of amino acid side chainsa (R25*, F28*, E30*, Q48, R61, H64, Y140, K170) from both protomers (starred residues from the domain swapped strands).
Additional interactions are formed through bound solvent from N50, Q72, Y134 and E145. These are all strongly conserved across RmlC orthologues (Figure 2). The CBU1838-TDP structure showed a citrate molecule (carried over from crystallisation) bound to the active site. This molecule occupies the same space as the substrate in previously solved structures. The citrate interacts with S52, H64, K74 and Y134 from the protein, and TDP (Figure 6D). These amino acids are well conserved amongst orthologues, and H64/Y134 are the catalytic base and acid proposed from previous studies. The conformation of these side chains is very similar to that seen in complexes of other enzymes with substrate analogues (Figure S6). These structures give further confidence that CBU1838 and StrM are indeed orthologues of RmlC. They have a very similar fold, show clear and specific binding to TDP, and retain the key catalytic residues in the correct orientation.
Discussion
Streptose and DHHS are monosaccharides produced by a single organism each. Both sugars are proposed to be synthesised through modified TDP-rhamnose pathways. S. griseus and C. burnetii contain putative orthologues of this biosynthetic pathway. Both organisms contain a single TDP-6-deoxy-D-xylo-4-hexulose 3’’,5’’-epimerase orthologue (StrM and CBU1838). We sought to determine whether these enzymes perform both epimerisations, and whether either might also perform the sugar ring rearrangement activity. Answering these questions will provide further insight into the biosynthesis of these unusual sugars.
CBU1838 showed robust double epimerase activity both in vitro and in vivo. CBU1838 complemented an rfbC (rmlC) mutation, restoring flux through the pathway and consuming cellular TDP-glucose and TDP-6-deoxy-D-xylo-4-hexulose (Figure 3). CBU1838 and StrM were competent to replace RmlC in vitro in a biosynthetic pathway (Figure 4). It was notable that substantially more CBU1838 was required to restore activity than RmlC or StrM. Similarly, CBU1838 showed a lower kcat, and higher KM, than either RmlC or StrM (Table 2). This is consistent with the proposed role of CBU1838, as the DHHS pathway requires a substrate with a 6’’-hydroxyl. CBU1838 contains a methionine residue (M123) in place of a phenylalanine conserved among other RmlC orthologues, which would provide space for the hydroxyl. The kcat and KM values that we obtained for StrM and RmlC are in the same order as those observed for other RmlC paralogues (Table S2). It is notable that our data were collected at 37 °C, whilst the comparative data were collected at 21-25 °C. It is likely that other enzymes would react faster at higher temperatures but might show a higher KM55.
Our NMR data show that CBU1838 and StrM have similar activity to E. coli RmlC, with CBU1838 again showing a reduced comparative activity. The rate of proton exchange at the 3’’ position was faster than that at the 5’’ position for all three enzymes (Figure 5; Table 3). The M. tuberculosis RmlC showed faster epimerisation at the 5’’ position 41. Dong et al. suggested that in the likely catalytic conformation, the 5’’ proton is more acidic than the 3’’ proton 41. Our experiments measured the loss of proton signal by NMR, whilst the previous study measured the product masses by GC-MS. Furthermore, our study used chemically prepared TDP-6-deoxy-D-xylo-4-hexulose, which has only recently become commercially available. This may explain some differences between our study and previous work. We note that as all the reactions involve proton transfers at all steps 40, there may be a strong kinetic isotope effect 56 on either or both epimerisations. As our methods for differentially measuring the two epimerisations rely on deuterium, this confounding effect cannot be excluded.
The structures of CBU1838 and StrM are highly similar to previously solved structures of paralogues from other species. TDP is held in place by residues that are strongly conserved (Figure 2, 6) 43,46,49. Although we were not able to determine a structure with a TDP-linked sugar, the side chains lining the sugar binding (and catalytic) cavity adopt conformations that are highly similar to those in previous structures 38,41,43-48,50. The proposed catalytic residues, H60 and Y130, occupy a very similar space to the equivalent residues in substrate analogue co-crystal structures 41,50. As their local hydrogen-bonding networks are also conserved, it is likely that they will also be catalytic in these proteins. The presence and conformation of these catalytic residues cannot predict the specificity of the enzymes. Whilst one example of a 5’’-specific enzyme showed a mutation that altered the conformation of an important active site side chain 47, 3’’-specific epimerases have shown a complete complement of active site residues 44,48. Our development of a functional assay in E. coli allowed us to confirm the activity of StrM and CBU1838 in vivo (Figure 3); although the 5’’-specific enzyme EvaD was expressed to the same levels as the active enzymes, it was not competent to complement rmlC. However, this assay did not distinguish between StrM (likely a direct RmlC orthologue) and CBU1838 (which is expected to use the 6’’-hydroxylated analogue).
The evidence presented in this and previous studies strongly suggests that both CBU1838 and StrM act as TDP-4-keto-(6-deoxy)-glucose 3’’, 5’’ double epimerases. The lower rates observed for CBU1838 are consistent with its natural substrate retaining the 6’’-hydroxyl group; an activity to generate this substrate has not yet been identified. This suggests that the streptose and DHHS synthase enzymes (Figure 1) accept a substrate that is epimerised at both the 3’’ and 5’’ positions. Although our data suggest that these enzymes cause proton exchange at the 3’’ carbon more efficiently than the 5’’ carbon, we cannot exclude that the kinetic isotope effect could be confounding. Our results provide powerful evidence that DHHS biosynthesis in Coxiella has convergently evolved to use a similar pathway to streptose biosynthesis in S. griseus. The key challenge that this presents is to identify the enzymes that provide the two remaining activities to generate DHHS.
Methods
Gene cloning and synthesis
The gene fragments for rmlB, rmlC and rmlD were amplified from E. coli DH5α (NEB) genomic DNA (gDNA) by PCR. The CBU1838 gene fragment was codon-optimised using IDT’s tools and ordered as a gBlock from IDT and amplified by PCR. Primer sequences are provided in Table S3. Gene fragments were cloned into pNIC28-Bsa4 (Addgene #26103, gift of Opher Gileadi, SGC Oxford) using ligation-independent cloning (LIC), following published methods 57. Briefly, 16.5 µg pNIC28-Bsa4 plasmid was digested with 60 U BsaI (NEB) in 100 µL following the manufacturer’s protocol, and incubated for 2 h at 50 °C. To generate the LIC cohesive ends in both the plasmid and PCR product, a mixture of 1 µL water, 5 µL BsaI-digested plasmid/PCR-pure DNA, 2 µL 5X T4 DNA polymerase buffer (Fermentas), 1 µL 25 mM dGTP (insert) or dCTP (plasmid), 0.5 µL 100 mM DTT, 0.5 µL T4 DNA polymerase (Fermentas) was prepared, and incubated at 22 °C for 30 min, then 20 min at 75 °C. 2 µL of treated DNA product was added to 1 µL of treated plasmid. The mixture was incubated at room temperature for 10 min followed by transformation into 5-alpha competent cells (NEB). The E. coli RmlD contains an inactivating point mutation. This was corrected by site-directed mutagenesis (SDM) using the QuikChange Lightening kit (Agilent), following the manufacturer’s instructions.
TDP-sugar epimerase genes for Streptomyces griseus strM, Amycolatopsis orientalis evaD and Streptomyces bikiniensis chmJ were codon optimised using an in-house Python script (https://github.com/njharmer/CodonOptimise) and cloned into pET28b with an additional SUMO tag, pET28b, and pET21a respectively by Twist Bioscience. Plasmid were transformed into the expression strain E. coli BL21 (DE3) (Novagen) using kanamycin (50 µg/mL) for selection. For complementation of E. coli rfbC mutants, TDP-sugar epimerase genes for strM, evaD and CBU1838 were cloned into the cloning vector pTWIST-A-MC under the control of the lac operon, with a strong ribosome binding site calculated by the RBS Calculator (De Novo DNA). The Genbank files for all plasmids are available in Supplementary Data.
Preparation of electrocompetent E. coli mutant cell lines and complementation
ΔrfbC E. coli strains (Keio collection; Horizon Discovery #OEC4987-200827372) were grown overnight on LB plates with 50 µg/mL kanamycin. Colonies were inoculated from LB plates into 10 mL fresh LB broth and incubated overnight at 37°C with shaking at 225 rpm. 1 mL of overnight culture was inoculated into 100 mL fresh LB medium with kanamycin and incubated at 37 °C with shaking at 225 rpm until OD600 was approximately 0.6. Cells were harvested by centrifugation (4200 xg, 10 min, 4 °C). The cells were resuspended in 40 mL pre-chilled autoclaved Milli-Q water. Cells were harvested by centrifugation as above and resuspended in 40 mL pre-chilled autoclaved 10 % (v/v) glycerol. A minimum of three 10 % glycerol washes were conducted before cells were resuspended in 500 µL 10 % (v/v) glycerol.
Complementation plasmids (40 ng) were added to 50 µL electrocompetent cells, vortexed for 30 s and incubated on ice for 10 min. The suspension was transferred to a pre-chilled 0.1 cm electroporation cuvette (Thermo Scientific #5510-11). A single pulse of 1.8 kV was given by a Gene Pulser Xcell® Microbial System (Bio-Rad #1652662). Cells were recovered by adding 1000 µL pre-warmed LB medium. The complemented cell suspension was incubated at 37 °C for 1 hour shaking at 225 rpm. Transformed cells were grown on LB agar plates supplemented with 100μg/mL ampicillin overnight at 37 °C.
Detecting expression of complemented E. coli
Complemented E. coli strain colonies were inoculated into 100 mL bottles containing 10 mL LB medium, 100 μg/mL ampicillin and incubated overnight at 37 °C with shaking at 225 rpm. 1 mL of each overnight culture was inoculated into individual 500 mL conical flasks containing 100 mL LB medium supplemented with ampicillin and incubated at 37 °C with shaking at 225 rpm. When the OD600 nm reached 0.6, gene expression was induced by adding 200 µM IPTG. Cultures were incubated at 20 °C with shaking at 225 rpm overnight. 50 mL aliquots of overnight cultures were harvested by centrifugation (4500 xg, 30 min, 4 °C). Cells were lysed using 1 mL BugBuster Master Mix (Millipore #71456-4), following the manufacturer’s instructions. The soluble and insoluble fractions were separated by centrifugation at 16 000 xg for 30 min at 4 °C. Samples were separated on a 4-12% ExpressPlus™ PAGE gel (GenScript #M41212) following the manufacturer’s instructions. Samples were transferred to a nitrocellulose membrane (Sartorius Stedim Biotech #11327-41BL) using a Pierce G2 Fast Blotter (Thermo Scientific # 15146375) using the pre-programmed protocol. Antibodies were added using an iBind Western device (ThermoFisher #SLF1000), following the manufacturer’s recommendations. The primary and secondary antibodies used were anti-penta His (Qiagen #34660) and goat anti-mouse IgG (LiCOR #926-68070) at a dilution of 1:1000. Blots were imaged using an Odyssey Clx imaging system (LiCOR).
Sample preparation for LC-MS QQQ analysis
Complemented E. coli strain colonies were inoculated into 100 mL bottles containing 10 mL LB medium, 100 μg/mL ampicillin for complemented strains, and incubated overnight at 37 °C with shaking at 225 rpm. 1 mL of each overnight culture was inoculated into individual 500 mL conical flasks containing 100 mL LB medium supplemented with ampicillin as necessary and incubated at 37 °C with shaking at 225 rpm until OD600 nm reached 0.6. Expression was induced by adding 200 µM IPTG. Cultures were incubated at 20 °C with shaking at 225 rpm overnight. 50 mL aliquots of overnight cultures were harvested by centrifugation (4500 xg, 30 min, 4 °C). Cellular contents were extracted into 1 mL 50 % (v/v) acetonitrile. Cell suspensions were incubated at 25 °C for 30 min and centrifuged at 20 000 xg for 30 min at 4 °C. The supernatant was filtered using Millex Non-Sterile Low Protein Binding Hydrophilic LCR (PTFE) Membrane (0.45 µm) filters (Merck #SLLHR04NL) into 1.5 mL MS vials with silicone/PTFE septa and stored at -20 °C for later analysis.
Quantitative LC-MS QQQ Analysis
Quantitative analysis was performed using an Agilent 6420B triple quadrupole (QQQ) mass spectrometer (Agilent Technologies, Palo Alto, USA) coupled to a 1200 series Rapid Resolution HPLC system. 5 µL of sample extract was loaded onto an Agilent Poroshell 120 HILIC-Z, 2.7 µm, 2.1 × 150 mm analytical column (Agilent Technologies #673775-924). For detection using negative ion mode, mobile phase A comprised 90 % (v/v) LC-MS grade acetonitrile with 10 mM ammonium acetate and 5 M medronic acid, and mobile phase B was 100% water (LC-MS grade) also with 10 mM ammonium acetate and 5 M medronic acid. The following gradient was used: 0 min – 10% B; 6 min – 35% B; 10 – 13 min – 40% B; 15 min – 10% B; followed by 5 minutes re-equilibration time at a flow rate of 0.25 mL min-1 with the column held at 25 °C for the duration. The QQQ source conditions for electrospray ionisation were: 350 °C gas temperature with a drying gas flow rate of 11 L min-1 and a nebuliser pressure of 35 psig. The capillary voltage was 4 kV.
MS Data Analysis
Data analysis was undertaken using Agilent MassHunter Quantitative Analysis software (version B.07.01, SP1). Data was normalised to the internal standard, 13C TDP-glucose, and the optical density of each culture pre-extraction. TDP-glucose, TDP-rhamnose, GDP-mannose, GDP-fucose and UDP-glucose concentrations were calculated using standard calibration curves. For the other compounds (where a standard was not available) normalised peak areas were compared.
Expression and purification of TDP-sugar epimerases
RmlB, RmlC, RmlD, StrM, EvaD and ChmJ were expressed in 500 mL of ZYM-5052 auto-induction media supplemented with 100 µg/mL kanamycin following the methods of 58. Each flask was inoculated with 10 mL of an overnight culture and grown at 37 °C with agitation at 200 rpm until OD600 reached 0.6. Cultures were further incubated at 20 °C for 18 hours with agitation. Cells were harvested by centrifugation at 4500xg for 30 min at 4 °C. The pellet was resuspended in binding buffer (20 mM Tris-HCl, 500 mM NaCl, 10 mM imidazole, pH 8.0) and lysed by sonication (SONIC Vibra cell VCX130). The sample was clarified by centrifugation (24 000 xg for 30 min at 4 °C). The soluble fraction was purified using an ÄKTAxpress chromatography system (Cytiva). The sample was purified using a 1 mL HisTrap crude column (Cytiva). After loading sample, the column was washed with binding buffer, and the protein step eluted into binding buffer supplemented with 250 mM. The eluate was purified over a Superdex 200 pg 16/600 size-exclusion column (Cytiva) and eluted isocratically into 10 mM HEPES, 500 mM NaCl, pH 7.5 (for coupled assays and crystallisation) or 10 mM NaxHPO4, 500 mM NaCl, pH 7.5 for NMR studies. The eluted protein was concentrated using a Vivaspin centrifugal concentrator (Generon) and stored at -20 °C with 20 % (v/v) glycerol for enzymatic assays; or stored at -80°C in small aliquots without any glycerol for crystallization or NMR.
Biochemical assays
The TDP-rhamnose biosynthesis assay coupled the product of RmlC paralogues to RmlD. In brief, reactions were performed in 96-well flat-bottomed plates (Greiner #655001) in a total volume of 200 µL. For initial studies, reactions consisted of 50 mM HEPES pH 7.5, 20 mM MgCl2, 350 µM NADPH, 4 µM NAD+, 0.4 µM RmlB, 2 µM RmlC paralogue and 2 µM RmlD. Reactions were initiated by addition of 500 µM TDP-glucose (Carbosynth #MT04383). Reactions were monitored by measurement of the absorbance at 340 nm over 30 min in an Infinite M200PRO plate reader (Tecan) incubating at 30 °C. For determination of kinetic parameters, RmlB and NAD+ were removed and TDP-glucose was replaced with TDP-6-deoxy-D-xylo-4-hexulose (Carbosynth #NT29846) added at a concentration range between 0-3 mM (EcRmlC / SgStrM) or 0-9 mM (CBU1838 or AoEvaD). Three experimental replicates were performed for all reactions. Data were fitted to the Michaelis-Menten equation using Graphpad v. 8.1.2.
Deuterium-incorporation analysis by 1H NMR
Reaction mixtures contained 10 mM MgCl2, 2.38 mM TDP-6-deoxy-D-xylo-4-hexulose (Carbosynth) and 8 µM NAD+ in a final volume of 250 µL deuterated 100 mM phosphate buffer pD 7.0. A “zero time” spectrum was recorded without any epimerase. Epimerases (38 nM EcRmlC, 46 nM SgStrM, 177 nM CBU1838, or 530 nM AoEvaD) were added to the above reaction mixture to a final volume of 250 µL.
All data were collected on a Bruker Neo 600 MHz spectrometer equipped with TCI cryoprobe. Standard Bruker proton experiments were carried out at 298 K (25 °C). Periodic 1H NMR experiments (64 scans) were carried out in 3 mm NMR tubes. 1H NMR spectra were recorded every 10 min over a 90 min period, set using the Topspin multi_zgvd command. Later intervals were set manually to record at 2 h, 4 h, 8 h, 18 h and 24 h, as appropriate. TopSpin 4.0.6 was used for data processing using command ‘efp’ followed by automatic phase correction (‘apk’) and automatic baseline correction (‘abs’). The residual water peak at 4.7058 ppm was used as reference for spectra calibration. A set of selected diagnostic signals from no-enzyme control samples was integrated for calibration of the relative abundance of each signal. An integral of H-6 thymidine peak (1H) was used for peak intensity calibration of the rest of integrals of diagnostic signals and GraphPad Prism v8.1.2 was used to analyse the data obtained.
Deuterium-incorporation analysis GC-MS
0.5 mg TDP-6-deoxy-D-xylo-4-hexulose (Carbosynth) was incubated in deuterated buffer alone, or with the addition of either 1 µM of EcRmlB, EcRmlC, SgStrM, CBU_1838 or AoEvaD in 250 µL final volume. After 18 h, enzymes were inactivated and removal by ethanol precipitation followed by centrifugation at 14,000 xg for 10 min. Sodium borohydride (∼2 mg) was added to each sample for the reduction of keto-moeity followed by incubation at room temperature for 2 h, with shaking at 120 rpm. The reaction was terminated with few drops of glacial acetic acid, followed by 20 µL 10 % (v/v) acetic acid in methanol. Solvents were evaporated under reduced pressure using GeneVac, for 1 h at 35 °C and 25 µg myo-inositol was added to the sample as an internal standard. The sugar-nucleotide bond was hydrolysed by using 250 µL 2 M trifluoroacetic acid (TFA) followed by incubation at 100 °C for 1.5 h. After cooling the samples, solvents were evaporated again and 100 µL isopropanol was added before a final evaporation in order to remove traces of TFA for 1 h.
A second reduction was achieved by addition of 250 µL 1 M ammonia, containing 10 mg/mL sodium borohydride for 1 h and then 250 µL acetic acid-methanol (1:9, v/v) was added. The samples were dried under reduced pressure (GeneVac, 1h at 40 °C) and the addition of acetic acid-methanol followed by drying was repeated once again. This was followed by addition of 250 µL methanol (without acetic acid) twice with evaporating the solvent off each time (20 min each). The resulting sample was acetylated by incubation at 120 °C for 20 min in a mixture of 100 µL acetic anhydride and 100 µL pyridine. After this, approximately 200 µL toluene was added, and the mixture was concentrated under reduced pressure. The addition of toluene and evaporation was repeated at room temperature.
The alditol acetates were separated by partition between equal volume of methylene chloride and water. After partition the methylene chloride layer was left to evaporate slowly at room temperature. Finally, samples were dissolved in acetone and analysed by gas chromatography-mass spectrometry (GC-MS).
Crystallization
Protein concentrations used for crystallization were 5.85 mg/mL (SgStrM) and 5.2 mg/mL or 7.8 mg/mL (CBU_1838). Crystals were grown using the microbatch method using an Oryx8 crystallization robot (Douglas Instruments). Crystals were grown in hydrophobic plates (Douglas Instruments #VB-Silver-1/1) and covered in a 1:1 mix of paraffin oil and silicone oil (Molecular Dimensions). Crystals were grown either as a 1:1 mixture of protein and mother liquor, or as a 3:2:1 mixture of protein, mother liquor and seed stocks where seeds had been prepared from previous crystals. The successful co-crystallisation conditions, substrates soaking conditions, and cryoprotectants used are detailed in Table S4.
X-ray data collection and structure determination
Data were collected at Diamond Light Source (Didcot, UK) at 100 K using Pilatus 6M-F detectors (Table S1). All data were processed using XDS 59. CBU1838 data were subjected to anisotropic ellipsoidal truncation using the STARANISO server 60. The resolution limit for StrM datasets was set at a point where CC1/2 was above 0.3 in the highest resolution shell. CBU1838 data were processed to include regions where the mean I/σ was systematically above 1.2. Further data processing and structural studies was carried out using the CCP4 program package 61 and the CCP4i2 interface 62. Molecular replacement was used to provide initial phases for datasets using Morda 63 and MolRep 64. Density fitting was performed using Coot 65 and refined with REFMAC5 66. Model validation was carried out with internal modules of CCP4i2 and Coot, employing MolProbity calculations 67.
Author contributions
RAF, JP and NJH designed the study and obtained funding. ARC, SR, MVV, MR, SAN, MC and DS collected data. ARC, SR, MVV, MR, MC, DS, MI, RAF and NJH analysed data. ARC and NJH wrote the initial manuscript. All authors contributed to revision of the manuscript.
Acknowledgements
The authors thank Simone de Rose (University of Exeter) for assistance with crystallisation.
SR, MVV, RF and NJH were funded by BBSRC grant BB/N001591/1. ARC and NJH were funded by BBSRC grant BB/M016404/1 and by Dstl grant DSTLX-1000098217. Work at the John Innes Centre (MR, SAN, RAF) was supported by the UK BBSRC Institute Strategic Program on Molecules from Nature -Products and Pathways [BBS/E/J/000PR9790] and the John Innes Foundation, and the InnovateUK: IBCatalyst (GrantBB/M02903411).
Footnotes
↵a Residue numbers given are for CBU1838. The equivalent residues in StrM are (in order mentioned on this page) R21*, F24*, E26*, Q45, R57, H60, Y135, and K165; N47, Q68, Y129, and E140; S49 and K70.