The structure of GDP-4-keto-6-deoxy-D-mannose-3-dehydratase: A unique coenzyme B6-dependent enzyme

doi:10.1110/ps.062328306

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The structure of GDP-4-keto-6-deoxy-D-mannose-3-dehydratase: A unique coenzyme B₆-dependent enzyme

Paul D. Cook, James B. Thoden and Hazel M. Holden

Department of Biochemistry, University of Wisconsin—Madison, Madison, Wisconsin 53706, USA

(RECEIVED May 3, 2006; FINAL REVISION June 12, 2006; ACCEPTED June 18, 2006)

Abstract

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Abstract
Introduction
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Discussion
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L-Colitose is a 3,6-dideoxysugar found in the O-antigens ofsome Gram-negative bacteria such as Escherichia coli and inmarine bacteria such as Pseudoalteromonas tetraodonis. The focusof this investigation, GDP-4-keto-6-deoxy-D-mannose-3-dehydratase,catalyzes the third step in colitose production, which is theremoval of the hydroxyl group at C3' of GDP-4-keto-6-deoxymannose.It is an especially intriguing PLP-dependent enzyme in thatit acts as both a transaminase and a dehydratase. Here we presentthe first X-ray structure of this enzyme isolated from E. coliStrain 5a, type O55:H7. The two subunits of the protein forma tight dimer with a buried surface area of $~$ 5000 Å². Thisis a characteristic feature of the aspartate aminotransferasesuperfamily. Although the PLP-binding pocket is formed primarilyby one subunit, there is a loop, delineated by Phe 240 to Glu253 in the second subunit, that completes the active site architecture.The hydrated form of PLP was observed in one of the enzyme/cofactorcomplexes described here. Amino acid residues involved in anchoringthe cofactor to the protein include Gly 56, Ser 57, Asp 159,Glu 162, and Ser 183 from one subunit and Asn 248 from the secondmonomer. In the second enzyme/cofactor complex reported, a glutamateketimine intermediate was found trapped in the active site.Taken together, these two structures, along with previouslyreported biochemical data, support the role of His 188 as theactive site base required for catalysis.

Keywords: PLP-dependent enzyme; colitose; molecular structure; 3,6-dideoxysugars; O-antigens

Introduction

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Abstract
Introduction
Results
Discussion
Materials and methods
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The biochemical importance of carbohydrates cannot be overstated,for they are essential elements in nearly every physiologicalprocess and represent the most abundant biomolecules in livingsystems. Di- and trideoxysugars are an especially importantand intriguing class of carbohydrates that are synthesized byplants, fungi, and bacteria (Kennedy and White 1983; Rupprath et al. 2005).Many are formed from simple monosaccharides such as glucose6-phosphate or fructose 6-phosphate via a myriad of enzymaticreactions including dehydrations, reductions, and methylations.Most of the deoxysugars of biological relevance are constructedaround the 3,6-dideoxyhexoses or the 2,3(4),6-trideoxyhexoses,which are further modified by epimerization, amination, andC-, N-, and O-methylation reactions. These modifications yieldan astonishing array of biological molecules with differingthree-dimensional shapes and hydrophilicities.

Several of these unusual sugars have been isolated from theO-antigens of various Gram-negative bacteria, where they contributeto the enormous structural variations observed in bacterialcell walls (Lerouge and Vanderleyden 2002). Others have beenfound in polyketide antibiotics such as erythromycin, wherethey have been shown to provide or enhance the pharmacologicalactivities of the respective drugs (Weymouth-Wilson 1997).

One of these unusual sugars is L-colitose (Scheme 1), a 3,6-dideoxysugarisolated from the O-antigens of Gram-negative bacteria suchas Escherichia coli (Edstrom and Heath 1965), Yersinia pseudotuberculosis(Kotandrova et al. 1989), Salmonella enterica (Xiang et al. 1993),Vibrio cholerae (Hisatsune et al. 1993), and in marine bacteriasuch as Pseudoalteromonas tetraodonis (Muldoon et al. 2001)and Pseudoalteromonas carrageenovora (Silipo et al. 2005). Reportsdescribing the isolation of colitose date as far back as 1958(Luderitz et al. 1958).

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Scheme 1.

The biosynthesis of the O-antigen in bacteria requires nucleotide-linkedsugars, which are transferred to the growing oligosaccharidechain. Four enzymes are involved in the production of GDP-L-colitose,as outlined in Scheme 1 (Bastin and Reeves 1995; Beyer et al. 2003).The focus of this investigation is GDP-4-keto-6-deoxy-D-mannose-3-dehydratase,which catalyzes the third step in the pathway, namely the removalof the hydroxyl group at C3' of the hexose. The enzymeis encoded by the colD gene, and hereafter is referred to asColD. It is an especially intriguing PLP-dependent enzyme inthat it lacks the conserved lysine that typically anchors thecofactor to the protein. Recent biochemical studies have demonstratedthat the enzyme from Y. pseudotuberculosis is bifunctional,with both deoxygenation and transamination activities (Beyer et al. 2003;Alam et al. 2004), and as such, it represents a new paradigmfor unusual deoxysugar formation.

PLP (pyridoxal 5'-phosphate) is a remarkable and versatile coenzymethat is ubiquitous in nature. Enzymes dependent upon PLP catalyzea wide range of chemical reactions including decarboxylations,racemizations, transaminations, and $beta$ -eliminations, among others(Jansonius 1998; Toney 2005). Most PLP-dependent enzymes containa conserved lysine residue, which forms a Schiff base with thecoenzyme in the resting state. This species is referred to asthe internal aldimine. In ColD, an internal aldimine is notpossible due to the replacement of a histidine for the conservedlysine. Rather, in ColD, PLP is first converted to pyridoxamine5'-phosphate (PMP) by reacting with glutamate as indicated inScheme 2. In the first step, glutamate forms a Schiff base withthe noncovalently bound PLP, a species referred to as the externalaldimine. Subsequently, an enzymatic base deprotonates the aldimineintermediate, leading to the formation of a carbanion that isstabilized by various resonance forms. Protonation of the carbanionat C4' of the PLP by an active site acid leads to a ketimineintermediate which, upon hydrolysis, results in PMP and ${alpha}$ -ketoglutarate.

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Scheme 2.

Here we describe the three-dimensional structures of ColD fromEscherichia coli, Strain 5a, type O55:H7, with a bound hydratedform of PLP and with a trapped glutamate ketimine intermediate.The employment of PMP in a dehydration reaction is quite rare,and thus these structures provide a wealth of new molecularinsight into this novel coenzyme B₆-dependent enzyme.

Results

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Abstract
Introduction
Results
Discussion
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The first structure of ColD was determined to 1.8 Å resolution.For this structural analysis, crystals were grown in the presenceof PLP and 2 mM ${alpha}$ -ketoglutarate. As can be seen in Figure 1A,the two subunits of ColD form a tight dimer with an extensivetotal buried surface area of $~$ 5000 Å², based on a proberadius of 1.4 Å (Zhang and Matthews 1995). This type ofquaternary structure is characteristic of the aspartate aminotransferasesuperfamily (Jansonius 1998). The dimer has overall dimensionsof $~$ 80 Å x 70 Å x 70 Å, with the active sitesseparated by $~$ 20 Å. Electron density corresponding to theentire polypeptide chain backbone is continuous from the N toC termini for both monomers in the asymmetric unit. The conformationsof the two subunits forming the dimer are virtually identical,and correspond with a root-mean-square deviation (RMSD) of 0.14Å for 367 structurally equivalent ${alpha}$ -carbons.

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Figure 1. The structure of ColD. The crystals of ColD employed in this investigation contained a dimer in the asymmetric unit as shown in A. The subunits are related by a twofold rotational axis, which lies perpendicular to the plane of the page. The PLP cofactors, separated by $~$ 21 Å, are displayed in space-filling representations. For all figures, the coordinates corresponding to subunits 1 and 2 of the dimer are color coded in blue and green, respectively. A separate ribbon representation of subunit 2 is given in B. The 10 $beta$ -strands characterizing the subunit are labeled A–J. Part of the active site region for subunit 2 is formed by a loop contributed by subunit 1 (Phe 240–Glu 253) as highlighted in C.

A ribbon representation of an individual subunit (a total of388 amino acids) is displayed in Figure 1B. It has a somewhatconcave-shaped appearance with molecular dimensions of $~$ 60 Åx 65 Å x 70 Å. The polypeptide chain initiates withtwo ${alpha}$ -helices defined by Asp 13–Ser 25 and Glu 32–Phe45. These helices lead up to the first strand of $beta$ -sheet labeled"A" in Figure 1B. Overall, the fold of the subunit is dominatedby a mixed eight-stranded $beta$ -sheet flanked by eight ${alpha}$ -helices.The $beta$ -strands are labeled "A," "G," "F," "E," "D," "B," "C,"and "I" in Figure 1B, and correspond to Tyr 49–Val 53,Gly 196–Thr 200, Met 179–Ser 184, Ile 155–Asp159, Lys 128–Asn 134, Glu 80–Pro 84, Arg 101–Val105, and Thr 351–His 353, respectively. Note that $beta$ -strandsA, G, and F run antiparallel. In addition to this large $beta$ -sheet,there are two strands of antiparallel sheet labeled "H" and"J" that correspond to residues Gly 303–Ile 308, and Leu367–Val 369, respectively. A rather large helix, formedby Glu 253–Lys 283, packs against both the first helixat the N terminus and the last helix at the C terminus. Thethird helix of the subunit, which connects $beta$ -strands A and B,is positioned such that the positive end of its helix dipolemoment projects toward the phosphate of the PLP cofactor. Thoseresidues involved in anchoring the PLP ligand to the proteinare provided primarily by one subunit. However, as shown inFigure 1C, there is a loop, delineated by Phe 240–Glu253, which forms one wall of the active site and is providedby the second subunit of the dimer.

Unlike the typical PLP-dependent enzymes, ColD does not containthe lysine residue necessary to form a Schiff base between itsside chain N and C4' of the cofactor (the internal aldimine).Aldehydes, like PLP, react with water to form hydrates, as indicatedin Figure 2A. Whether the carbonyl or hydrate moiety is favoredat equilibrium depends upon the chemical nature of the aldehyde(or ketone). In the case of free PLP in solution, the aldehydeform is favored. There is spectral evidence, however, that whenPLP is bound to a protein, the hydrate may be favored (Harris et al. 1976;Nishino et al. 1997; Tramonti et al. 2002). Shown in Figure 2Bis the electron density corresponding to the PLP ligand in subunit2. Originally the ligand was modeled into the electron densityas an aldehyde with C4' having sp² hybridization. As the modelrefinement continued, however, it became clear from electrondensity maps calculated with (F_o – F_c) coefficients that,in fact, the hydrated form of PLP, with C4' having sp³ hybridization,was trapped in the active site.

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Figure 2. The complex of ColD with the hydrated form of PLP. Aldehydes react with water to form hydrates. This type of reaction for PLP is shown in A, along with the numbering used to define the various atoms of the cofactor. Electron density corresponding to the hydrated form of PLP is displayed in B. The map, contoured at 2 ${sigma}$ , was calculated with coefficients of the form (F_o – F_c), where F_o was the native structure factor amplitude and F_c was the calculated structure factor amplitude from the model lacking coordinates for the PLP. Those residues situated within $~$ 3.5 Å of the hydrated PLP in subunit 2 are shown in C. The dashed lines indicate possible hydrogen bonds between atoms positioned within 3.2 Å of each other. Asn 248 is contributed by subunit 1.

Those residues located within $~$ 3.5 Å of the hydrated PLPin subunit 2 are shown in Figure 2C. Most of the protein:ligandinteractions occur near the phosphoryl group. Indeed, the phosphorylmoiety is anchored firmly in place by eight hydrogen bondinginteractions. Specifically, the backbone amide groups of Gly56 and Ser 57 participate in hydrogen bonding interactions withtwo of the phosphoryl oxygens of PLP. In addition, the sidechain atoms, O of Ser 57 (subunit 2) and N² of Asn 248 (subunit1), lie within 2.4 Å and 2.9 Å, respectively, ofone of the phosphoryl oxygens. Ser 183 provides another hydrogenbonding interaction between its side chain O and a PLPphosphoryl oxygen. Three ordered water molecules complete thehydrogen bonding pattern observed around the phosphoryl group.Only two side chains, Asp 159 and Glu 162, form hydrogen bondswith the pyridoxal ring of PLP. Asp 159 is positioned at theend of $beta$ -strand E, whereas Glu 162 resides in a Type I turn.For the side chain oxygen of Glu 162 to lie within $~$ 2.8 Åof O3' of the pyridoxal ring, one of these oxygens must be protonated.The indole ring of Trp 88 provides an off-centered parallelstacking interaction with the cofactor. Note that His 188, whichis a lysine residue in most PLP-dependent enzymes, is locatedat $~$ 4 Å from the cofactor C4'.

For the second structure reported here, ColD was crystallizedin the presence of 2 mM glutamate and the structure solved to1.9 Å resolution. Again, the two subunits in the asymmetricunit are virtually identical, and correspond with an RMSD of0.18 Å for 372 structurally equivalent ${alpha}$ -carbons.

A close-up view of the electron density observed in the activesite of subunit 2 is displayed in Figure 3A. Initially the externalaldimine form of PLP was modeled into the electron densitywhereby the ${alpha}$ -amino nitrogen of glutamate and C4' of the pyridoxalring form a Schiff base. For this intermediate, the hybridizationabout the ${alpha}$ -carbon of glutamate is sp³ while the hybridizationabout C4' of the cofactor is sp² (Scheme 2). Accordingly, thebond angles about the ${alpha}$ -carbon and C4' should be $~$ 109° and $~$ 120°, respectively. During the course of the structure refinement,however, the external aldimine model never matched the electrondensity well. If, however, the hybridization about the ${alpha}$ -carbonand C4' were restrained to sp² and sp³, respectively, the modelfitted strikingly well into the electron density (Fig. 3A).This type of geometry at the ${alpha}$ -carbon and C4' would be expectedfor the glutamate ketimine intermediate (Scheme 2). While cautionmust be applied when interpreting electron density maps calculatedat 1.9 Å resolution, the observation of such an intermediateis not unprecedented. Indeed, it has been previously reportedin the elegant structural analyses of aspartate aminotransferase,which were conducted at 2.3–2.4 Å resolution (Malashkevich et al. 1993).Aspartate aminotransferase contains the typical lysine residueobserved in most PLP-dependent enzymes.

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Figure 3. The structure of ColD with a glutamate ketimine intermediate trapped in the active site. Electron density corresponding to the ketimine intermediate is presented in A. The map was calculated in the same manner as described for Figure 2B. Note that the ${alpha}$ -carboxylate group of the intermediate is not well ordered, suggesting free rotation. A close-up view of the active site is displayed in B. Possible hydrogen bonding interactions are indicated by the dashed lines. For the sake of clarity, the hydrogen bonding interaction between Ser 183 and the phosphoryl group of the ketimine intermediate was omitted. Ser 183 forms the same interaction with the ketimine phosphoryl group as it does with hydrated PLP (Fig. 2C).

Those residues lying within 3.5 Å of the glutamate ketimineintermediate in subunits 1 and 2 are displayed in Figure 3B.Note that the ${alpha}$ -carbon chains for the ColD dimer, whether complexedwith either the hydrated or ketimine form of PLP, are virtuallyidentical (RMSD of 0.09 Å). The protein accommodates themore bulky ketimine intermediate by the exclusion of water moleculesfrom the active site rather than by major side chain adjustments.Both His 215 and Arg 250 from the first subunit form electrostaticinteractions with the side chain carboxylate group of the ketimineintermediate. As observed for the protein complexed with thePLP hydrate, one of the carboxylate oxygens of Glu 162 liesquite closely to O3' of the pyridoxal ring ( $~$ 2.6 Å), whichis indicative of a proton being shared between them.

Discussion

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Abstract
Introduction
Results
Discussion
Materials and methods
References

The structure of ColD was solved via molecular replacement withthe X-ray coordinates for ArnB from Salmonella typhimurium (Noland et al. 2002).These two enzymes demonstrate a 23% amino acid sequence identity.ArnB plays a key role in lipid A modification by catalyzingthe amination at C-4'' of UDP-L-threo-pentapyranosyl-4''-ulose.Both ColD and ArnB are dimeric. Their structurally equivalent ${alpha}$ -carbons correspond with an RMSD of 2.5 Å. A superpositionof one subunit of ColD onto that of ArnB is displayed in Figure 4A.As can be seen, the overall backbone traces for the two enzymesare very similar. They begin to align at Leu 6 in ColD and Phe13 in ArnB. The two proteins differ primarily in three areaslabeled R1, R2, and R3 in Figure 4A. The first region of differenceoccurs in the loop defined by Phe 68 to Arg 74, which servesto connect the third ${alpha}$ -helix of the ColD subunit and $beta$ -strandB. The second area occurs near Lys 224 to Val 230 where, inColD, these residues adopt a $beta$ -hairpin motif. This region isapparently more flexible in ArnB where there is a break in themodel from Asp 220 to Gln 232. Finally, the loops leading outof $beta$ -strands H in ColD (Lys 309 to Ile 315) and ArnB adopt significantlydifferent orientations (Fig. 4A). In ArnB, Phe 330 is in thecis peptide conformation. The structurally equivalent residuein ColD is Thr 334, which adopts strained dihedral angles ( ${varphi}$ = $~$ 58°, ${psi}$ = $~$ –116°).

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Figure 4. Comparison of ColD with ArnB. A superposition of the ${alpha}$ -carbon traces for ColD (purple) and ArnB (white) is presented in A. Labeled residues are for ColD. The observed hydrogen-bonding pattern around PMP in ArnB is shown in B. X-ray coordinates for this figure were obtained from the Protein Data Bank (accession no. 1MDO).

The hydrogen-bonding pattern surrounding the PMP cofactor inArnB is displayed in Figure 4B. Like that observed in ColD,the phosphate group is anchored to the protein through sidechain hydroxyl groups and amide nitrogens and, in addition,is surrounded by several ordered water molecules. The main differencein the binding of PMP to ArnB occurs at His 163, which, in ColDis a glutamate. As observed in ColD, the indole side chain ofTrp 88 in ArnB forms a parallel stacking interaction with thepyridoxamine ring of the cofactor.

Once the model for ColD was built and refined, a search withDALI (Holm and Sander 1996) revealed the closest structuralrelative of ColD to be 3-amino-5-hydroxybenzoic acid synthase(ABHA synthase) rather than ArnB (Eads et al. 1999). ABHAsynthase and ColD superimpose with an RMSD of 1.8 Å for677 structurally equivalent ${alpha}$ -carbons. These two proteins displayan even lower amino acid sequence identity of 18% amino acid,however. ABHA synthase catalyzes the ${alpha}$ , $beta$ -dehydration and 1,4-enolizationof 5-deoxy-5-amino-3-dehydroshikimic acid to produce 3-amino-5-hydroxybenzoicacid, which serves as the starter unit for the production ofansamycin antibiotics (Ghisalba and Nuesch 1981). A superpositionof the polypeptide chains for ColD and ABHA synthase is presentedin Figure 5A. As noted for the comparison of the ColD and ArnBmodels, there are three loops (Phe 68–Arg 74, Lys 224–Val230, and Lys 309–Ile 315) where ColD and ABHA synthasediffer to any significant extent. The cis peptide in ArnB isnot conserved in ABHA synthase. A close-up view of the bindingregion for the internal aldimine in ABHA synthase is depictedin Figure 5B. The hydrogen bonding pattern around the phosphateis a similar to that observed in both ColD and ArnB. As seenin ArnB, a histidine side chain lies within 2.8 Å of O3'of the pyridoxamine ring. This residue varies among PLP-dependent enzymes,and has also been observed as an asparagine or aspartate. Trp88 in ColD, which stacks with the pyridoxal ring of the hydratedPLP cofactor, is replaced with a phenylalanine in ABHA synthase.

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Figure 5. Comparison of ColD with ABHA synthase. Shown in A is a superposition of the ${alpha}$ -carbon traces for ColD (purple) and ArnB (white). Labeled residues are for ColD. The observed hydrogen-bonding pattern around the internal aldimine in ABHA synthase is shown in B. X-ray coordinates for this figure were obtained from the Protein Data Bank (accession no. 1B9H). Those residues highlighted in green belong to one subunit, while Asn 234 is contributed by the second subunit in the dimer of ABHA synthase.

A glutamate ketimine intermediate was first observed structurallyin chicken mitochondrial aspartate aminotransferase (AATase)(Malashkevich et al. 1993). The polypeptide chains for the dimersof ColD and AATase superimpose less well with an RMSD of 3.5Å for 531 structurally equivalent ${alpha}$ -carbons. Not surprisingly,there are significant differences in the active sites of thesetwo enzymes. As can be seen in Figure 6, the conformations ofthe trapped ketimine intermediates in ColD and AATase are quitedifferent, with variations initiating at C4' of the cofactor.In AATase, the pyridoxamine ring of the cofactor and N, C ${alpha}$ , C $beta$ ,and the ${alpha}$ -carboxylate group of glutamate all lie nearly in aplane. Furthermore, the glutamate (or Schiff base) nitrogensits within 2.5 Å from the pyridoxamine O3' in the AATaseketimine. This is indicative of a proton being shared betweenthese two atoms. Strikingly, the distance between O3' and theSchiff base nitrogen in the ColD model is 3.5 Å. Moreover,in ColD, O3' lies at 2.7 Å from the carboxylate of Glu162, which means that there is a proton located somewhere betweenthem. In light of these differences, it can be speculated thatin the ColD ketimine intermediate a proton is not shared betweenO3' and the Schiff base nitrogen as is so often drawn in textbooks,but rather the proton is formally bonded to the nitrogen. Thisis referred to as the ketoenamine tautomer, and it has beenpostulated that enzymes can enhance their catalytic activityby promoting this tautomeric form (Toney 2001). The two ketimineintermediates observed in ColD and AATase differ by $~$ 77°with respect to the dihedral angle defined by C3–C4–C4'–N.Other differences in the ketimine conformations seen in ColDand AATase include the positioning of the ${alpha}$ -carboxylate moiety.In AATase, it participates in a salt bridge with Arg 386, whereasin ColD, it lies close to His 188.

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Figure 6. Comparison of the ColD glutamate ketimine intermediate with that observed in aspartate aminotransferase. Those residues highlighted in blue bonds correspond to the ColD model, whereas those amino acids depicted in green bonds correspond to aspartate aminotransferase (PDB accession no. 1MAQ). Residue labels beginning with an asterisk refer to aspartate aminotransferase.

It is important to note that the orientation of the glutamateketimine intermediate observed in AATase (Fig. 6) can be easilyaccommodated in the ColD active site if the side chain of Trp88 moves slightly. In this orientation the ${alpha}$ -carboxylate of theketimine intermediate in ColD would participate in a salt bridgewith the guanidinium group of Arg 331 and the side chain carboxylatewould be situated near the imidazole group of His 215. Importantly,this orientation of the ketimine in the ColD active site placesthe side chain of His 188 on the re face of its sp² hybridized ${alpha}$ -carbon. As will be discussed below, it has been postulatedthat bond cleavage at the sugar C3' and bond formation at thecofactor C4' most likely occurs on the re face of the Schiffbase complex (Alam et al. 2004). The unusual binding of theglutamate ketamine observed in the ColD active site, where theplanarity of the intermediate is broken, may simply be a functionof the pH (6.0) at which the crystals were obtained.

While GDP was included in the initial crystallization trials,it was not observed in any of the electron density maps. Repeatedattempts at soaking crystals in solutions containing GDP upto 10 mM were also unsuccessful. From the structure of the ColDdimer it is clear that a rather large open cleft extends fromthe ketimine intermediate to the surface. Preliminary attemptsat collecting X-ray data from crystals grown in the presenceof GDP-4-keto-6-deoxymannose have, however, met with some limitedsuccess (unpublished data). In a map calculated with coefficientsof the form (F_o – F_c), a tube of electron density wasobserved that extends from the PLP cofactor toward the proteinsurface. Embedded in this density were two large peaks (4 ${sigma}$ ) separatedby $~$ 2.8 Å. Assuming that these two peaks correspond tothe phosphoryl moieties of the substrate, it was possible tobuild a model for it with its sugar C4' keto group placed nearthe PLP cofactor and the phosphoryl and GDP-ribosyl groups extendingtoward the solvent. Importantly, this model places the phosphorylmoieties near the positively charged side chains of Arg 331in subunit 1 and Arg 219 and Arg 250 in subunit 2. If this modelis correct, most of the ligand/protein binding interactionswould be primarily through the sugar and the phosphoryl groupsof the substrate. It is not known whether ColD exhibits a strictspecificity for GDP or can utilize other nucleotide-linked sugars.

ColD functions in the GDP–colitose biosynthetic pathwayby removing the hydroxyl group at C3'. Like colitose, tyveloseis another 3,6-dideoxyhexose that occurs in the O-antigens ofsome Gram-negative bacteria. However, the removal of its 3'-hydroxylgroup occurs via a completely different reaction mechanism.Specifically, the dehydration at C3' is catalyzed by the E₁/E₃complex, which requires NAD, FAD, and [2Fe-2S] clusters (He and Liu 2002).Indeed, ColD is an especially intriguing sugar dehydratase inthat it lacks any requirement for NAD, FAD, and iron–sulfurcenters.

A proposed mechanism for ColD has been previously put forth(Alam et al. 2004), and is presented in adapted forms in Schemes 2and 3. In the first step (Scheme 2), PLP is converted to PMPthrough its reaction with L-glutamate. A catalytic base is requiredfor this process which, based on the structure presented here,we propose to be His 188. This residue resides within $~$ 4.4 Åof the glutamate ketimine ${alpha}$ -carbon. If glutamate is modeled intothe active site on the basis of the observed ketimine orientationin AATase, His 188 is positioned such that its imidazole ringis $~$ 3 Å from the ${alpha}$ -carbon proton.

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Scheme 3.

Following the production of PMP, a Schiff base is formed betweenthe C4' sugar carbon and the cofactor, labeled 1 in Scheme 3.From detailed biochemical investigations, it is known that deprotonationat C4' of the cofactor is stereospecific, and that a catalyticbase removes the pro-R hydrogen (Alam et al. 2004). Again, basedon the ColD model presented here, it can be speculated thatHis 188 serves as the catalytic base to initiate the deprotonationevent leading to the intermediate labeled 2 in Scheme 3. TheColD active site is markedly devoid of potential bases otherthan His 188, His 215, Asp 159, and Glu 162. As previously noted,both Asp 159 and Glu 162 are involved in hydrogen bonding interactionswith the cofactor ring, and most likely are not involved incatalysis. Likewise, His 215 is not in the correct positionto promote catalysis in light of previously reported stereochemicalconsiderations (Alam et al. 2004).

The expulsion of the sugar C3' hydroxyl group, as indicatedin 2, requires an active site acid. Most likely His 188, whichis now protonated, functions in this capacity. Following thedeparture of the C3' hydroxyl moiety in the form of water, a ${Delta}$ ^3,4-aminomannoseen intermediate is formed as shown in 3. Hydrolysisof this intermediate leads to the loss of PLP and the intermediateshown in 4 of Scheme 3. We propose that His 188 serves to activatea water molecule for this hydrolysis event. It has been demonstratedthat in the next step labeled 4 in Scheme 3, the incorporationof a hydrogen at the sugar C3' is stereospecific (Alam et al. 2004).Again, His 188 probably functions in this step as the activesite acid. It is presently not known whether the final expulsionof ammonia, as indicted in 5 in Scheme 3, occurs on the enzymeor in solution.

Why did ColD evolve with a histidine in place of the lysinethat normally forms an internal aldimine with PLP? We hypothesizethat this occurred because of the unique chemistry involvedin the reaction. In going from 3 to 4 in Scheme 3, an enzymaticbase is required. In theory, this could be accomplished by alysine residue. However, in this case, the lysine would mostlikely react directly with the C4' of the cofactor to form aninternal aldimine. As such, the next step leading to 4, whichis the stereospecific protonation at C3', would never occurgiven the arrangement of side chains in the active site of ColD.By having a histidine residue in place of a lysine, the formationof an internal aldimine is prevented, and importantly, histidineprovides the functional group necessary for the reaction toproceed from 3 to 4. Experiments designed to test this hypothesisare presently underway.

From a chemical viewpoint, the in vitro synthesis of nucleotide-linkedsugars is a complicated and arduous process at best. But naturehas developed a large repertoire of enzymes for the specificand efficient biosynthesis of unique carbohydrates. To betterunderstand the determinants of protein-substrate specificitiesand the fundamental reaction mechanisms utilized in these biosyntheticpathways, the structures and functions of the enzymes must becarefully studied. The models of ColD presented here providenew and powerful structural foundations upon which to more fullyexplore this fascinating PLP-dependent enzyme.

Materials and methods

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Abstract
Introduction
Results
Discussion
Materials and methods
References

Molecular cloning of the ColD gene
Genomic DNA from enterohemorrhagic E. coli O55:H7 was providedby the laboratory of Dr. Rodney Welch, Department of MedicalMicrobiology and Immunology, University of Wisconsin–Madison.The colD gene was PCR-amplified using primers that introduceda 5' NdeI site and a 3' XhoI site. The purified PCR productwas A-tailed and ligated into the pGEM-T (Promega) vector forscreening and sequencing. A ColD-pGEM-T vector construct ofthe correct sequence was then appropriately digested and ligatedinto a pET28b(+) vector that had been modified to provide anN-terminal TEV protease recognition site (Thoden et al. 2005).

DH5- ${alpha}$ E. coli cells were transformed with the resulting plasmidand plated onto LB Agar Kan plates. Multiple colonies were pickedto grow overnight in LB Kan medium from which plasmid DNA wasisolated. Plasmids were tested for the presence of the colDgene by digestion with NdeI and XhoI.

Protein expression and purification
The ColD-pET28JT plasmid was used to transform Rosetta (DE3)E. coli cells (Novagen). The culture was grown at 37°C withshaking until an optical density of 0.9 was reached at 600 nm.The flasks were then cooled on ice and induced with 1 mMIPTG. Cells were allowed to express at 16°C for 24 h afterinduction with IPTG.

The cells were harvested and disrupted by sonication on ice.The lysate was cleared by centrifugation and ColD was purifiedutilizing Ni-NTA resin (Qiagen) according to the manufacturer'sinstructions. The N-terminal His-tag was cleaved from the proteinby the addition of both 1 mM DTT and TEV protease in a 1:50(TEV protease:ColD) molar ratio. The cleavage reaction was carriedout at 4°C for 36 h and subsequently passed through thenickel column to remove the TEV protease. The ColD protein samplewas dialyzed against 25 mM Tris-HCl and 200 mM NaCl (pH 8.0)with the addition of 1 mM PLP and 2 mM glutamate or ${alpha}$ -ketoglutarate.Following dialysis, the sample was concentrated to 20 mg/mLbased on an extinction coefficient of 0.95 (mg/mL)^–1 ·cm^–1 as calculated with the ProtParam tool on the ExPASyProteomics Server.

Crystallization of ColD
Crystallization conditions were first surveyed by the hangingdrop method of vapor diffusion with a sparse matrix screen developedin the laboratory. Large crystals were subsequently grown viabatch methods by mixing 20 µL of a protein solution with20 µL of precipitant. Protein concentrations were typicallyat 20 mg/mL and the solutions contained 25 mM Tris (pH 8.0),200 mM NaCl, 1 mM PLP, and 2 mM glutamate or ${alpha}$ -ketoglutarate.The precipitant solutions contained 28% poly(ethylene glycol)3400, 100 mM MES (pH 6.0), 400 mM MgCl₂, 1 mM PLP, 2 mM glutamateor ${alpha}$ -ketoglutarate, and 1 mM GDP. The crystals grew to maximumdimensions of 1.8 x 0.5 x 0.5 mm in $~$ 2 d. They belonged to thespace group P2₁2₁2₁, with unit cell dimensions of a = 74.9,b = 88.1, and c = 125.8, and contained a dimer in the asymmetricunit.

Structural analysis of ColD
X-ray data sets were collected from two different crystal complexes.In one form the protein contained hydrated PLP in its activesite, while in the second form the protein contained the trappedglutamate ketimine intermediate. All X-ray data were measuredwith a Bruker HISTAR area detector system. The X-ray sourcewas CuK radiation from a Rigaku RU200 X-ray generator operatedat 50 kV and 90 mA. The X-ray data were processed with XDS (Kabsch 1993)and internally scaled with XSCALIBRE (I. Rayment and G. Wesenberg,unpubl.). Relevant X-ray data collection statistics are presentedin Table 1.

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Table 1. X-ray data collection statistics

The structure of the ColD/hydrated PLP complex was solved viamolecular replacement with the program Phaser and employingArnB, a 4-amino-4-deoxy-L-arabinose lipopolysaccharide-modifyingenzyme (PDB accession no. 1MDO) as a search model (Noland et al. 2002).The electron densities corresponding to the two subunits inthe asymmetric unit were averaged with the software packageDM (Cowtan and Main 1998), and a model was manually built onthe basis of this averaged map. The model was then placed backinto the unit cell for subsequent least-squares refinement withthe software package TNT (Tronrud et al. 1987). Alternate cyclesof manual model rebuilding and least-squares refinement reducedthe R-factor to 17.0% at 1.8 Å resolution. The structureof the trapped glutamate ketimine intermediate was solved viadifference Fourier methods. Alternate cycles of manual modelrebuilding and least-squares refinement of this model reducedthe R-factor to 17.6% at 1.9 Å resolution. Relevant refinementstatistics are given in Table 2.

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Table 2. Least-squares refinement statistics

In each subunit (for both complexes) Met 193, Val 334, and Asn354 adopt ${varphi}$ , ${psi}$ angles that are outside of the allowed regionsof the Ramachandran plot (all near the "nucleophile elbow" regionof ${varphi}$ = $~$ 60°, ${psi}$ = $~$ –100°). The electron densities forthese residues are unambiguous. Met 193 is positioned $~$ 10 Åfrom the phosphate of PLP, and is located in a sharp, nonclassicalreverse turn. The side chain of Val 334 lies within $~$ 5 Åof the PLP, and is situated in a Type II' turn. Asn 354 sitsin a surface loop $~$ 20 Å from the active site. Other thanthese amino acids, 89.3%, 10.5%, and 0.1% of the remaining residuesfall into the "most-favored," "additionally allowed," and "generouslyallowed" regions of the Ramachandran plot, respectively. Bothcomplexes contain one magnesium ion. This cation resides neara crystalline lattice interface. While 1 mM GDP was includedin the crystallizations, it was not observed in the electrondensity maps.

PDB accession numbers
X-ray coordinates have been deposited in the Protein Data Bankwith accession numbers 2GMS and 2GMU.

Footnotes

Reprint requests to: Hazel M. Holden, 433 Babcock Drive, Departmentof Biochemistry, University of Wisconsin––MadisonMadison, WI 53706, USA; e-mail: Hazel_Holden{at}biochem.wisc.edu;fax: (608) 262-1319.

Article and publication are at http://www.proteinscience.org/cgi/doi/10.1110/ps.062328306.

Acknowledgments

We thank Professors Ivan Rayment and W.W. Cleland for helpfuldiscussions. We are indebted to Professor Rodney Welch for graciouslyproviding genomic DNA. This research was supported by a grantfrom the NIH (DK47814 to H.M.H.).

References

TOP
Abstract
Introduction
Results
Discussion
Materials and methods
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