HindawiPublishingCorporation BioMedResearchInternational Volume2013,ArticleID458571,13pages http://dx.doi.org/10.1155/2013/458571 Research Article Structure-Based Mechanism for Early PLP-Mediated Steps of Rabbit Cytosolic Serine Hydroxymethyltransferase Reaction MartinoL.DiSalvo,1J.NeelScarsdale,2GalinaKazanina,2RobertoContestabile,1 VerneSchirch,3andH.TonieWright3 1DipartimentodiScienzeBiochimiche,SapienzaUniversita`diRoma,00185Roma,Italy 2CenterfortheStudyofBiologicalComplexityandInstituteforStructuralBiologyandDrugDiscovery,Richmond, VA23284-2030,USA 3DepartmentofBiochemistryandInstituteofStructuralBiologyandDrugDiscovery,VirginiaCommonwealthUniversity, Richmond,VA23219,USA CorrespondenceshouldbeaddressedtoMartinoL.DiSalvo;[email protected] Received6June2013;Accepted26June2013 AcademicEditor:AlessandroPaiardini Copyright©2013MartinoL.DiSalvoetal.ThisisanopenaccessarticledistributedundertheCreativeCommonsAttribution License,whichpermitsunrestricteduse,distribution,andreproductioninanymedium,providedtheoriginalworkisproperly cited. SerinehydroxymethyltransferasecatalyzesthereversibleinterconversionofL-serineandglycinewithtransferofone-carbongroups toandfromtetrahydrofolate.ActivesiteresidueThr254isknowntobeinvolvedinthetransaldiminationreaction,acrucialstep 󸀠 inthecatalyticmechanismofallpyridoxal5-phosphate-(PLP-)dependentenzymes,whichdeterminesbindingofsubstratesand releaseofproducts.InordertobetterunderstandtheroleofThr254,wehaveexpressed,characterized,anddeterminedthecrystal structuresofrabbitcytosolicserinehydroxymethyltransferaseT254AandT254Cmutantforms,intheabsenceandpresenceof substrates.Thesemutantsaccumulateakineticallystablegem-diamineintermediate,andtheircrystalstructuresshowdifferences intheactivesitewithrespecttowildtype.Thekineticandcrystallographicdataacquiredwithmutantenzymespermitustoinfer thatconversionofgem-diaminetoexternalaldimineissignificantlyslowedbecauseintermediatesaretrappedintoananomalous positionbyamisorientationofthePLPring,andanewenergybarrierhampersthetransaldiminationreaction.Thisbarrierlikely arisesfromthelossofthestabilizinghydrogenbondbetweenthehydroxymethylgroupofThr254andthe𝜀-aminogroupofactive siteLys257,whichstabilizestheexternalaldimineintermediateinwildtypeSHMTs. 1.Introduction enzymes exist in complexes that absorbs in the 310nm to 500nmrangeastheresultofaconjugated𝜋-electronsystem. Serine hydroxymethyltransferase (SHMT: EC 2.1.2.1) is These absorption properties have played an important role 󸀠 a ubiquitous pyridoxal 5 -phosphate- (PLP-) dependent inelucidatingthemechanismsofPLPadditionandcatalysis, enzyme that catalyzes the reversible interconversion of L- since several intermediates on the reaction pathway have serineandglycine,coupledtotheformationandbreakdown unique structural and absorbance characteristics [10, 11]. of 5,10-methylenetetrahydrofolate (5,10-CH2-H4PteGlu) [1, SHMT is distinctive among the PLP-dependent enzymes 2]. Because of its essential role in one-carbon units in the number of these absorbing complexes that can be metabolism, SHMT has been often indicated as a potential observed, and these have been exploited to determinate target of chemotherapeutic agents [3–5]. It also catalyzes kinetic rates for their interconversion by stopped-flow and the conversion of 5,10-methenylene- to 5-formyl-H4PteGlu temperaturejumpspectroscopy[11–13]. 󸀠 [6], the transamination and racemization of D- and L- In PLP-dependent enzymes, the 4 -aldehyde of PLP is alanine [7], the retro-aldol cleavage of erythro and threo boundasanaldiminetothe𝜀-aminomoietyofanactivesite isomers of both L-threonine and L-𝛽-phenylserine [8], and Lysresidueinwhatiscalledthe“internalaldimine.”Forthose the decarboxylation of aminomalonate [9]. PLP-dependent PLP-dependent enzymes that catalyze reactions involving 2 BioMedResearchInternational Enz Lys257 N HC H 2−(Oen3PoOlimiCnIHne t2feorrnmal, aAlHNdmi+amxi≈ne3 O 40nm2−)O3POHCH2C:ONOHH−C2R NL+yOsH25−7 Enz 2−O3PHOOHCCHHO−2NO−+RHCH N¨LysOH25−7Enz 2−O3PHO CCHO:2NOH−RHHC NLy+sO2H57−Enz 2−O3PO CH2 HHC NC+OOHO−R−Lys257Enz HO NLys257 Enz (ketoenamiInneHtNe fr+onraml ,aAldmimaxin≈e 430nm) (AGemmaxNH-d≈+ia3m43innem I) (AGmemax-d≈NHia3+m43innem II) E(AxtmeraNHnxa+≈l a4l2d6imnmin)e HC H 2−O3PO CH2 O− COO− R (caHrybdinraotleadm iinnHNtee,+rAnaml aaxld≈im34in0enm) 2−O3PO CH2 HC N+HO− N H Quinonoid intermediate (Amax≈498nm) Scheme1:MechanismoftransaldiminationreactionofSHMT. substrateaminoacids,theinitialstepinthecatalyticreaction only the T226A mutant of ecSHMT (Thr226 in ecSHMT is the formation of the “geminal diamine” (gem-diamine) numberingisequivalenttorcSHMTThr254)hadsignificant 󸀠 between the C4 aldehyde of PLP and the amino group of spectralandkineticdifferencesfromthewildtypeenzyme. the substrate. The orientation of the substrate in the active Therewasa32-foldlower𝑘 intheconversionofL-serineto cat sitewithrespecttotheplaneofPLP,towhichitiscovalently glycine,andtheT226Amutantwasvirtuallyinactivetoward linked through its amino group, in turn determines which cleavageofL-allo-threoninecomparedtowildtypeecSHMT. ofthethreesubstituentbondsonC𝛼ofthesubstratewillbe Furthermore,inthepresenceofL-serinetheT226Amutant cleaved.In1966,Dunathan[14]providedaunifyingconcept exhibitedalargespectralabsorbancepeakat343nm,which forthespecificselectionofthesubstratescissilebondinPLP- is characteristic of a gem-diamine intermediate and only a dependent enzymes, which has been confirmed in solution smallpeakat425nmcharacteristicoftheexternalaldimine. andstructuralstudies.Inhisproposal,allbondsbrokenand Stopped-flow analysis showed that the 343nm peak was madeonthecatalyticpathwayarethenearestperpendicular formed rapidly, but its conversion to the 425nm absorbing totheconjugated𝜋systemofthePLPring.Theresultingcar- peak was slow [17]. Since the gem-diamine is generally a banionatC𝛼ofthesubstrateaminoacidisstabilizedbyreso- short-lived intermediate on the reaction pathways of PLP- nancewiththe𝜋-electronsysteminthepyridineringofPLP. dependentenzymes,thisT226AecSHMTmutantofferedthe Thisintermediateonthecatalyticpathwayisreferredtoasthe opportunitytoinvestigatethestructuralchangesthatappar- “quinonoid” complex and absorbs near 500nm (Scheme1). entlyslowedtheconversionofthegem-diamineintermediate Solution studies have shown that SHMT passes through to the external aldimine. We were unable to obtain crystals severalordered,spectrophotometricallyidentifiableinterme- for the T226A mutant of ecSHMT. However, we were able diatesthatreflectchangesintheelectronsystemofthePLP tocrystallizethehomologousT254AandT254Cmutantsof cofactor[12,15]andareconsistentwithDunathan’sproposal. rcSHMT. We report here the kinetic properties and crystal Prior to the availability of crystallographic structure structuresoftheT254mutantsofrcSHMTandtheirglycine information on SHMT, it was noted that the amino acid and L-serine complexes. In addition, we have increased the sequencesofSHMTsfromdiversespecieshaveaconserved resolutionofthestructureofwildtypercSHMTto2.1A˚ asan runof4threonineresiduesterminating2residuesupstream aidinexaminingdetailsofthegem-diaminestructures. 254 257 of the active site lysine: V-V-T-T-T -T-H-K (PLP)-T (numberingisthatforrabbitcytosolicserinehydroxymethyl- 2.ResultsandDiscussion transferase(rcSHMT))[16].Todeterminethepossibleroles ofthisconservedsequenceinSHMTcatalysis,eachthreonine 2.1. Spectroscopic Studies. Wild type rcSHMT exhibits a of this active site stretch was mutated in ecSHMT to an characteristicmajorsingleabsorptionbandwithmaximum alanine, and the effects of the changes on the spectral and intensityat430nm,duetotheprotonatedinternalaldimine kinetic properties were investigated [17]. It was found that betweenenzymeandcofactor.Also,aminorbandisobserved BioMedResearchInternational 3 at340nm(Scheme1).Theadditionofsaturatingconcentra- for the Thr to Ala mutant and 531-fold for the Thr to Cys tionsofglycineresultsinadecreaseofthemajorabsorption mutant.Similarly,𝐾𝑚valuesforL-allo-threoninewerefound band,withaslightblue shiftat426nmandtheappearance tobeonlyslightlyhigherthanwildtype(lessthan2-foldfor of a well-defined band at 343nm. A small band centered both mutants), whereas 𝑘 values showed a 9- to 29-fold cat at 498nm is also visible. It is well established that these decreaseforT254AandT254Cmutants,respectively. absorptionbandscorrespondtotheformationoftheexternal TobetterunderstandtheroleofThr254intheformation aldimine,thegem-diamine,andthequinonoidintermediates, and breakdown of the gem-diamine intermediate and thus respectively[1,12,18].Allabsorptionbandsofwildtypeand on the transaldimination reaction, the rate of the spectral mutantenzymesareshowninFigure1. changesoccurringwhenL-serineandglycinewereaddedto Like the wild type, the T254A mutant form exhibits theenzymewasdeterminedatdifferentpHvaluesbymeans a 430nm absorption band (although much less intense of stopped-flow measurements. The 𝑘on and 𝑘off values for than wild type), indicative of the presence of an internal therateofformationandbreakdownoftheenzyme-substrate aldimine, and also shows an important band at around complex absorbing at 343nm were determined from a plot 340nmthatmayrepresenteithertheenolimineformorthe of𝑘 versussubstrateconcentration,afterlinearregression carbinolamine, a hydrated form of the internal aldimine in obs of data and extrapolation of the slope and intercept values whichthewatermoleculemimicsthesubstratenucleophilic (Table2).ForbothmutantsandforbothsubstratesateachpH attackandthegem-diamineformation.AsshowninFigure1, value,𝑘 wasalinearfunctionofsubstrateconcentration,as this band is usually present in very low concentration in obs expectedforasecond-orderreaction.Thesecond-orderrate the freshly purified wild type enzyme. The addition of constantsforsubstrateadditionandgem-diamineformation a saturating concentration of glycine to T254A mutant (𝑘on)werecorrectedfortheconcentrationoftheaminoacid resultsinthealmostcompletelossofabsorbanceat430nm, anionic form at each pH value and are listed as 𝑘󸀠 . The with a concomitant increase of absorbance at 343nm. This on anionic form of the 𝛼-amino group is assumed to be the effect was also observed with E. coli SHMT T226A mutant truesubstrateforthetransaldiminationreaction.InthepH (residue Thr226 of ecSHMT corresponds to residue Thr254 range used in the experiments (6.4–8.0), the concentration inrcSHMT).Kineticstudiesonthelattermutantshowedthat of the anionic form of the amino acid substrates increases thecomplexabsorbingat343nmisformedinabimolecular step providing strong evidence that it is indeed the gem- afrboomut34.30t⋅i1m0e4st.oTh1e0.𝑘7on⋅1v0a4luse−s1⋅iMnc−r1eawshedenwLit-hseprHineanwdasvaursieedd diamine intermediate [17]. The addition of H4PteGlu to as substrate and from 0.8 ⋅ 104 to about 4.4 ⋅ 104s−1⋅M−1 glycine-saturatedwildtypeSHMTresultsintheincreaseof the498nmabsorbingband,correspondingtothequinonoid when glycine was used as substrate; 𝑘on values were very similar for both T254 mutant forms. After correction for intermediate.Thelargeincreaseinabsorbancebelow400nm the concentration of anionic substrate, 𝑘󸀠 values showed a is the absorbance of the excess H4PteGlu. Instead, when on 10-folddecreaseaspHincreasedfrom6.4to8.0andranged the T254A mutant was saturated with glycine, even in the bpraensde.nThceeoefffHe4cPtsteoGftlhue,iatdddiditinoontosfhaoswataunryat4in9g8cnomncaebnstorrabtiionng 1fr3om⋅ 12006 ⋅to1016.8to⋅11.086⋅s−110⋅6Ms−−11⋅Mwi−t1hwgiltyhciLn-es.eThrinee saingdmofriodmal of L-serine to T254A rcSHMT mutant enzyme are similar dependence of 𝑘o󸀠n on pH suggests the titration of a group tothoseobservedforglycine,withadecreaseofthe430nm at the active site involved in a general acid catalysis, with absorbing band and a concomitant increase of the 343nm a pK𝑎 around 6.8 (Figure2). If the internal aldimine of the absorbing species. In contrast, when wild type rcSHMT is mutant enzymes is mostly in the carbinolamine form, as saturated with L-serine, there are a marked increase and inferred from the absorption spectra shown in Figure1, it a blue shift of the major absorbing band, centered now at mustbedehydrated(throughtheprotonationofthehydroxyl 426nm,butnoabsorbanceisobservedataround340. group followed by the elimination of water) in order to be ThespectralfeaturesoftheunligandedT224Cmutantare convertedintotheketoenaminethatisabletoreactwiththe largely similar to those of the wild type enzyme. However, incoming amino group of the substrates. Importantly, we the 340nm band is slightly more intense. If compared to haveobservedthattheratioofthe428nmand340nmbands theT254Amutant,therelativeintensitiesofthe430nmand changeswithpHinasimilarmanner,withtheketoenamine 340nmbandsarereversed.Spectralchangesuponsubstrates formbeingfavoredathigherpHvalues(datanotshown).A addition are similar to the ones observed with the T254A possible candidate for this acid catalysis is Tyr73, which is mutant, except that a residual absorbance is shown in the involved in a cation-𝜋 interaction with Arg263. It has been 420–430nmregion. shown that Tyr residues involved in cation-𝜋 interactions mayhavetheirpK𝑎 loweredby1to3pHunits(thenormal 2.2.KineticsStudies. ThespectralpropertiesofthercSHMT pK𝑎 of tyrosine residue is about 9.5) [19]. Furthermore, T254A and T254C mutant enzymes described above sug- this residue points toward the protein region where the gest that the gem-diamine intermediate accumulates upon transaldimination reaction takes place, and its phenolic 󸀠 substrateaddition.Thepurifiedmutantenzymesweretested hydroxylislocatedincloseproximitytoC4 (seeFigure6). for catalytic activity using L-serine and L-allo-threonine When L-serine was used as substrate, 𝑘off values showed a as substrates (Table1). For L-serine, both mutant enzymes decreasingtrendaspHwasincreasedandrangedfrom10.3 showed slightly increased 𝐾𝑚 values (about 2-fold) when to3.1s−1fortheT254Amutantformandfrom39to23s−1for comparedtowildtypercSHMT;𝑘catvaluesdecreased46-fold T254C.Incontrast,whenglycinewasusedassubstrate,𝑘off 4 BioMedResearchInternational 0.16 0.16 No ligand Wild type Wild type 0.12 +gly 0.12 +L-ser +H4PteGlu nce nce bsorba 0.08 +gly bsorba 0.08 No ligand A A 0.04 0.04 0.00 0.00 300 350 400 450 500 300 350 400 450 500 550 Wavelength (nm) Wavelength (nm) (a) (b) +gly T254A T254A 0.08 0.08 +L-ser nce 0.06 +H+g4lPyteGlu nce 0.06 ba ba bsor 0.04 bsor 0.04 A A No ligand 0.02 No ligand 0.02 0.00 0.00 300 350 400 450 500 300 350 400 450 500 550 Wavelength (nm) Wavelength (nm) (c) (d) T254C T254C +gly +gly 0.08 +H4PteGlu 0.08 +L-ser 0.06 0.06 nce No ligand nce ba ba No ligand or 0.04 or 0.04 bs bs A A 0.02 0.02 0.00 0.00 300 350 400 450 500 300 350 400 450 500 550 Wavelength (nm) Wavelength (nm) (e) (f) Figure1:AbsorptionspectraofwildtypeandmutantrcSHMTintheabsenceandpresenceofsubstrates.Leftpanelsshowtheabsorption ∘ spectraofwildtype,T254AandT254CrcSHMTsat30Cbefore(blacklines)andaftertheadditionof90%saturatingglycine(bluelines). Greenlinesarespectratakenaftertheadditionof100𝜇MH4PteGlutothesamplescontainingglycine.Rightpanelsshowtheabsorption spectraofthesameenzymesbefore(blacklines)andaftertheadditionof90%saturatingL-serine(redlines). values slightly increased with pH, ranging from 1 to 2.9s−1 the𝑘offvaluesdeterminedwiththemutantenzymesareabout fortheT254Amutantformandfrom5.1to7.0s−1forT254C. 2ordersofmagnitudelowerthanthewildtype. Thesedata Stopped-flowstudiesdonemanyyearsagoatpH7.3for suggestthatthemutationshavenotsignificantlyaffectedthe wild type rcSHMT [12] gave a comparable 𝑘on value to the rateofformationofthegem-diamineintermediatebuthavea valuesfortheT254AandT254Cmutants.Ontheotherhand, moresignificanteffectontherateofitsbreakdown. BioMedResearchInternational 5 25 T254A T254C 20 20 ) 610 60) 1× 15 ×1 15 −M −1 M 1 −(sn10 −1(s10 󳰀ko 󳰀kon 5 5 0 0 6.0 6.5 7.0 7.5 8.0 8.5 9.0 6.0 6.5 7.0 7.5 8.0 8.5 9.0 pH pH (a) (b) Figure2:Dependenceof𝑘󸀠 valuesdeterminedfromstopped-flowexperimentsonpH,forT254AandT254CrcSHMTmutants.Opencircles on correspondtodataobtainedwithL-serine,whileclosedcirclescorrespondtodataobtainedwithglycine.Thecontinuouslinesthroughthe experimentalpointswereobtainedthroughaleastsquareminimizationprocessusingtheequationforasigmoidalcurve(thesoftwareused wasGraphPad,Prism). Table 1: Kinetic constants for the hydroxymethyltransferase and external aldimine. These two hypotheses are not mutually retro-aldol cleavage reactions catalyzed by wild type and T254 exclusiveandcouldbeappliedatthesametime. mutantrcSHMTforms. Kinetic FormofrabbitcytosolicSHMT 2.3.CrystalStructures. Wedeterminedthecrystalstructures Substrate constant Wildtype T253A T253C oftheT254AandT254Cmutantenzymesandthecomplex L-Serine 𝐾𝑚(mM) 0.3 0.6 0.5 ofeachwithglycineandL-serine,andthestructureofwild 𝑘 (min−1) 850 18.5 1.6 type rcSHMT to a higher resolution than had previously cat been attained [20]. Table3 lists the crystallographic and L-allo-Threonine 𝐾𝑚(mM) 1.5 2.5 2.6 refinementdataforthenewrabbitcytosolicSHMTstructures 𝑘cat(min−1) 130 14.3 4.5 determinedanddescribedinthiswork.Allstructuresexcept for the T254C-glycine complex were solved in space group P41withatetramerof4independentlydeterminedsubunits perasymmetricunit.TheT254C-glycinecomplexwassolved If the rapid spectroscopic changes occurring when the enzyme was mixed with saturating concentration of sub- inspacegroupP41212withadimerperasymmetricunit.The oligomericstructureofrcSHMTconsistsoftwotightdimers strates were followed for a longer period of time (up to 50 each made of identical monomers. These tight dimers are seconds),aslowfirst-orderincreasewasobservedat426nm. looselyassociatedtoformaso-calleddimerofdimers.Disor- For the T254A mutant with saturating concentration of L- −1 dereddensityrecurredintheinsertsegmentaroundresidue serine,therateconstantwasdeterminedtobe10min .This 272 and at the amino termini of all monomer subunits, as value is in agreement with previous studies on the T226A observed in previously determined SHMT structures, but mutant of ecSHMT [17]. It is interesting to notice that this rate constant is very close to the 𝑘 measured for both thesedisorderedresiduesarenotclosetotheregionsofthe cat enzymearoundthePLPandsubstratebindingsite,whichare hydroxymethyltransferaseandretro-aldolcleavagereactions thesubjectofthisstudy. catalyzed by this mutant. This shows that for the T254A mutanttheconversionofthegem-diamineintotheexternal aldimineintermediatehasbecometherate-limitingstep. 2.3.1. Differences in Structure of Unliganded Wild Type and Thespectralandkineticstudiesbothstronglysuggestthat T254Mutants. Exceptforthesmalldifferencesintheactive removing the hydroxymethyl group of Thr254 by replacing site described herein, all structures are virtually identical it with either an Ala or a Cys residue greatly slows the (rmsd <0.4A˚ in all cases). The interactions of the PLP conversionofthegem-diamineintermediatestotheexternal cofactorwiththeproteininthewildtypeandT254mutants aldimine. This may be the result of either blocking the arealmostidentical.ThedistanceoftheAsp228carboxylate conversionofgem-diamineItogem-diamineIIorofslowing toN1ofthepyridineringisunchangedinthemutantsasare conversionofgem-diamineIItotheexternalaldimine.There- the noncovalent bond constraints on the phosphoryl group fore,theslowingofthecatalyticcyclecouldbeexplainedby of the PLP tail and the coplanarity of the His148 imidazole either the mutant gem-diamine complexes being in a more with the PLP ring. The active sites of all subunits of the stable form (in an energy well) compared to the wild type wildtypehavephosphateorMESbufferanionsboundwhere enzyme or by an increased energy barrier to pass to the the carboxylate moiety of the amino acid substrate binds 6 BioMedResearchInternational Table2:Kineticconstantsfortherateofformationandbreakdownofthegem-diaminecomplexformutantrcSHMTformswithglycineand L-serinesubstrates. T253A T253C Substrate pH 𝑘on(s−1M−1⋅104) 𝑘o󸀠n(s−1M−1⋅106) 𝑘off(s−1) 𝑘on(s−1M−1⋅104) 𝑘o󸀠n(s−1M−1⋅106) 𝑘off(s−1) 6.4 3.3 20 10.3 2.9 18 39 6.8 5.8 14 8.3 4.0 10 36 L-Serine 7.2 8.7 8.6 5.8 6.8 6.7 32 7.6 9.5 3.7 5.3 8.7 3.4 27 8.0 10.7 1.8 3.1 9.4 1.5 23 6.4 0.8 13 1.0 0.5 8.5 5.1 6.8 1.3 8.0 1.3 0.7 4.5 6.7 Glycine 7.2 2.1 5.0 1.9 1.5 3.8 6.9 7.6 3.0 2.9 2.4 2.1 2.2 7.0 8.0 4.4 1.8 2.9 3.7 1.6 6.8 in SHMT-substrate complexes (see next paragraph). In the insolution,theamountofthecanonical428nmketoenamine T254Amutant,thissiteisoccupiedbyphosphateionsinone bandishigherthanintheT254Amutant. dimerandbyMESintheotherdimer.IntheT254Cmutant thisanionicsiteisoccupiedbywaterinthreesubunitsandby 2.3.2. The Glycine and L-Serine Complexes of T254A and anapparentphosphateinthefourthsubunit(Table4). T254C Mutants. The structures of the T254A and T254C There are significant differences between the wild type mutants with glycine and L-serine substrate ligands are all and the T254 mutants in the conformation of the PLP inthegem-diamineform(Table4),showingboththeamino methylenephosphatetailalthoughtheseareseentoadiffer- group of the substrate and the 𝜀-amino group of Lys257 󸀠 entextentindifferentsubunits(Figure3).Thesedifferences formingbondstoC4 ofPLP.Inallsubunitsofbothmutants correlate with the absence of the C𝛽 methyl group in the andwithbothsubstrates,theorientationofthePLPringand Ala254 and Cys254 side chains in the mutants. In the wild the conformation of the methylene phosphate tail are very typestructure,thismethylgroupofThr254projectstoward similar.Interestingly,theinhomogeneityseenintheinternal themethylenephosphatetail.Replacementofthesidechain aldiminestructuresofthemutantenzymeshasdisappeared by Ala or Cys opens a small space that allows the cofactor upon binding of substrates. For example, Figure4 shows a 󸀠 tail to assume a different conformation, moving the C5 comparisonbetweentheactivesitestructuresoftheT254A 󸀠 towardsthiscavity.Thisisthemostevidentchangeobserved mutantwitheitherL-serine(a)orglycine(b)boundtoC4 in the mutants. The fact that not all of the T254A and C ofPLPinthegem-diamineformandtheinternalaldimine. subunits show this change to the same extent suggests that Thecomparisonismadewiththesubunitoftheunliganded there is a low barrier to this switch of conformations and mutant enzyme in which the internal aldimine shows the thatthecrystallizationprocessisselectingoutanasymmetric largest difference with respect to wild type (Figure3(d)). distribution. As a consequence of the elbow-like rotation It can be seen that, in both gem-diamine structures, the of the methylene phosphate PLP tail in the mutant T254 orientation of the PLP ring and the conformation of the forms,thePLPringorientationalsodivergesfromthatofthe methylenephosphatetailandoftheactivesitelysine(Lys257) wild type. Moreover, in the mutant enzyme structures with are very similar to those of the internal aldimine form and thelargestPLPtailconformationaldifferences,thealdimine therefore differ significantly from the wild type internal linkagebetweenC4󸀠andthe𝜀-aminogroupoftheactivesite aldimine structure. The carboxylate group of substrates is lysine(Lys257)isfarfrombeingintheplaneofthePLPring oriented to form dual hydrogen bonds with Arg402 and (Figure3(d)), as required by the double bond conjugation also with Y83. Residues Ser203 and His231 make hydrogen 󸀠 present in the ketoenamine form of the internal aldimine. bondswiththeO3 ofPLP, asalreadyobserved inallother As the aldimine linkage is driven away from this plane, its SHMTstructures.IntheL-serinegem-diaminecomplex,the conjugation with the 𝜋-electron system of the pyrimidine hydroxylgroupofthesubstratemakesH-bondinteractions ringisdiminished,andthemaximumabsorbanceisshiftedto withGlu75andTyr83,asalsoobservedinthecrystalstructure lowerwavelengths[21],asobservedforthemutantenzymes of the Bacillus stearothermophilus SHMT-L-serine complex insolution(Figure1).Asdiscussedabove,wecannotexclude [22]. that the 340nm absorbing band of the unliganded mutant Wild type rcSHMT enzyme cocrystallized with glycine enzymesmaycorrespondtothehydratedformoftheinternal and5-CHO-H4PteGlushowedtwooftheenzymesubunitsin aldimine(carbinolamine;Scheme1).Intheinternalaldimine thegem-diamineform[19](Table4).Noexternalaldimines formoftheT254Cmutant,theconformationalchangeofthe werepresent,astheothertwosubunitswereintheinternal methylene phosphate tail and the displacement of the PLP aldimine form. It is worth noting that structural variation ringarelessevident(datanotshown).Thiscorrelateswiththe amongsubunitsinligandbindingsiteoccupancyandtypeof observationthat,intheabsorptionspectrumofthismutant intermediatecomplexisalsofoundinothereukaryoticand BioMedResearchInternational 7 ) 5 5 T254C+L-ser.114.0,114.0,155.6P411.8–2.55(2.62–2.90.9(76.9).202(.284).263(.362)52787(5963)5963(375)3840.1 0.0071.16 142712812102.00(96%) 1 1 ) 5 6 hiswork. T254C+gly.114.6,114.6,156.922P41190.0–2.65(2.72–2.69.6(62.0).221(.333).305(.414)19976(1244)1654(96)36.6NA 0.0061.08 70269672.24(93%) t in 0) d 4 ucturesdetermine T254C114.0,114.0,154.7P4111.8–2.40(2.46–2.90.1(86.9).195(.242).256(.346)62364(4393)7009(470)39.441.9 0.0061.13 14351331551.81(97%) r 1 st T 0) statisticsforrcSHM T254A+L-ser.115.5,115.5,156.3P41115–2.40(2.46–2.488.3(85.8).197(.247).258(.318)63363(4478)7156(510)37.337.3 0.0061.13 14251461251.88(96%) nt ) ctionandrefineme T254A+gly.115.0,115.0,156.8P410.0–2.65(2.72–2.6599.6(99.8).203(.292).277(.399)52905(3769)5968(406)3434.6 0.0071.22 1403142992.04(97%) e 2 oll c 5) a 5 allographicdat T254A115.1,115.1,157.4P418–2.55(2.62–2.92.2(87.9).201(.306).271(.432)55295(3849)6204(426)44.843.8 0.0071.24 1424142872.04(96%) st 1. y 1 r 1 C 3: 0) Table Wildtype5.6,115.6,156.0P41–2.10(2.16–2.198.5(98.2).199(.248).242(.316)05631(7668)11736(845)30.839.8 0.0081.3 14601231331.73(93%) 1 0 1 1 9. 1 1 d ed Cell/spacegroup ResolutionCompleteness(%)𝑅work𝑅free𝑁work𝑁free⟩⟨𝐵protein⟩⟨𝐵waterRMSDfromidealBondlengthsBondanglesRamachandranplotFavoredAdditionallyallowGenerouslyalloweForbiddenMolProbityscore 8 BioMedResearchInternational Thr254/Ala254 Thr254/Ala254 Lys257 Lys257 (a) (b) Thr254/Ala254 Thr254/Ala254 Lys257 Lys257 (c) (d) Figure3:SuperpositionoftheactivesitestructuresofrcSHMTwildtype(salmon)andT254A(cyan)intheinternalaldimineform.Panels (a)to(d)correspondtodifferentsubunitsofthetetramer. prokaryoticSHMTs[22–26].TheabovewildtypercSHMT- exchange required to interconvert the two gem-diamine glycine-5-CHO-H4PteGlu ternary complex structure and intermediates(seebelowfordiscussion). thatofmousecytosolicSHMT(whichwasalsococrystallized Inthewildtypegem-diamine,thebondbetweenthesub- 󸀠 with glycine and 5-CHO-H4PteGlu [25]) are the only wild strateaminogroupandC4 ofPLPliesroughlyperpendicular typeSHMTstructuresinwhichgem-diamineintermediates to the cofactor ring, indicating a strong similarity to gem- canbeseen. diamine I intermediate, in which the amino group of the 󸀠 When wild type and T254A rcSHMT-glycine gem- substrate has attacked the C4 Schiff base of the cofactor diamine structures are superimposed, some striking differ- with a trajectory that is perpendicular to the pyridine ring ences can be noticed (Figure5). The methylene phosphate (Scheme1). It appears that the wild type rcSHMT in the tail conformation and the orientation of the PLP ring are crystal has been trapped as a gem-diamine I intermediate significantly different. The carboxylate group of glycine in that barely accumulates in solution. On the other hand, wild type rcSHMT gem-diamine, although still interacting the gem-diamine forms found in T254 mutants seem to with Y83 and Arg402 through one of its oxygen atoms, is be in an aberrant position. The best way to appreciate this nomoreorientedtointeractoptimallywithArg402,andthe is to superimpose the structures of wild type gem-diamine other oxygen points away from it. Moreover, the position (Figure6(a))orT254mutantgem-diamine(Figure6(b))with of the two amino groups in the gem-diamine is different wild type internal and external aldimines. In SHMTs, as between wild type and mutant (see arrows in Figure5). In PLP reacts with the substrate and the internal aldimine is particular, the hydrogen atoms of the amino groups point convertedintotheexternalaldimine,thepyridineringrotates ∘ away from Tyr73, which might be involved in the proton by about 25 , primarily around the C2-C5 axis. This is also BioMedResearchInternational 9 Tyr83 Tyr83 Glu75 Glu75 Arg402 Arg402 Lys257 Lys257 Ser203 Ser203 His231 His231 Ala254 Ala254 (a) (b) Figure4:SuperpositionoftheactivesitestructuresoftheT254Amutantintheinternalaldimineform(cyan)andasagem-diaminecomplex (orange)witheitherL-serine(a)orglycine(b). of the PLP ring is also observed in the unliganded forms ofT254AandT254CrcSHMTstructures.Thegem-diamine structures of the mutant enzyme appear to be close to the gem-diamine II intermediate (Scheme1), and the angle of Tyr83 thebondfromC4󸀠 ofthePLPringtothe𝜀-aminogroupof Tyr73 ∘ K257 being close to the 90 predicted for this intermediate II,inwhichtheaminogroupofLys257hastobeeliminated in order to form the external aldimine intermediate. More- over, the carboxylate group of the substrate makes optimal dual hydrogen bonds with Arg402 (Figure6(b); structure in orange), as is observed in the external aldimine form of Arg402 wild type SHMT-glycine complex (Figure6(b); structure in magenta). These observations suggest that in the T254 rcSHMT crystals, the PLP-substrate complex is blocked in the form of an anomalous and stable gem-diamine intermediate. As Thr254/Ala254 mentioned above, it is noteworthy that in the T254 mutant gem-diamine intermediates the position and orientation of Figure5:Superpositionoftheactivesitestructuresofthewildtype the two amino groups point away from Tyr73 compared to (slate)andT254Amutantform(orange)ofrcSHMTasgem-diamine thewildtypegem-diaminestructure.Tyrosine73wasshown complexes with glycine (pdb 1ls3). The arrows in the figure point in E. coli and bsSHMT to have an important role in the towardstheaminogroupsofthegem-diaminecomplexes. transaldiminationprocessandwasproposedtoactasproton exchangerbetweengem-diaminesIandII.Interestingly,Tyr to Phe mutants of this residue also accumulate the gem- observed in prokaryotic B. stearothermophilus SHMT with diamineintermediate[18,27]. both glycine and L-serine as substrates and in the ternary An additional remarkable variation in the T254 mutant complexwithglycineand5-CHO-H4PteGlu[22].Inthewild structurescomparedtowildtypeisobservedinthepeptide type rcSHMT gem-diamine, the PLP ring lies between the bond between His256 and Lys257. Among the determined positions observed in the internal and external aldimines. mutant structures, this peptide bond adopts two distinct Strikingly,inthemutantT254gem-diaminethecofactorring orientations, one similar to the wild type rcSHMT and ∘ has a different orientation, which is unlikely to correspond the other differing by up to 180 . The local variation in to that occurring in the transaldimination reaction. This is conformation of the His256-Lys257 peptide bond may be obviouslyaconsequenceofthemutation,sincethisposition linkedtothercSHMTT254mutations,since,intheinternal 10 BioMedResearchInternational Tyr83 Tyr73 Tyr83 Tyr73 Lys257 Lys257 Arg402 Arg402 (a) (b) Figure6:Superpositionofwildtypestructurescorrespondingtotheinternalaldimine(salmon;rcSHMT)andexternalaldimine(magenta; mcSHMT,pdb1eji)formsofthecofactorwiththeglycinegem-diamineformofthewildtype(slate)andT254Amutant(orange). aldimine of wild type rcSHMT, the carbonyl oxygen of variesinthemutants.TheselocalstructurechangesinT254 His256, which is flipped in some mutant structures, makes mutantscouldberesponsibleforaperturbationoftheproton a hydrogen bond through a water molecule to the Thr254 transferchainwhichslowsthetransaldiminationreaction. side chain. The lack of uniformity in structure among the Available external aldimine SHMT structures (such as, subunits of the T254 mutants in the conformation of the E.coliSHMTasternarycomplexwithglycineand5-CHO- PLPmethylenephosphatetail,thepositionofthePLPring, H4PteGlu(pdb1dfo)andbsSHMTwithglycineandL-serine and the orientation of the His256-Lys257 peptide bond (pdb 1kl1 and 1kkp, resp.)) all show a good hydrogen bond suggest that mutation of T254 relaxes some local structural betweentheLys257𝜀-aminogroupandthehydroxylgroupof constraintsaroundtheactivesite. theThr254sidechain,asoriginallysuggestedbyPascarellaet al.[16].Thenucleophilicityofthe𝜀-aminogroupandtheNH2 ofthesubstratemustbebalancedsothattransaldimination 3.Conclusions canoccurrapidlyfromeitherdirection.Thehydrogenbond between Thr254 and the Lys257 𝜀-amino group is likely to The T254A and T254C mutations have created a small be a critical determinant of this balance. In the T254A and empty space in the active site of rcSHMT due to the T254Cmutants,whichlackthehydroxylgroup,thisH-bond absence of the threonine methyl group. This has allowed cannotbeformed.Wesuggestthatthelossofthishydrogen the methylene phosphate tail of PLP to adopt a stable, bonddestabilizestheexternalaldimineoftheT254mutants uncharacteristicconformationthatisinturnresponsiblefor relativetothegem-diamineintermediatesandresultsinthe an aberrant positioning of the PLP ring. This clearly affects trappingofthelatter. thetransaldiminationstepoftheSHMTreaction,makingit PLP-dependentenzymestypicallycatalyzethereversible therate-limitingstepinthecatalyticcycle.Inthesemutants, transaldiminationreactionbetweentheinternalandexternal wheneitherL-serineorglycineisaddedtotheenzyme,gem- aldiminesveryrapidly,withinthedeadtimeofstopped-flow diamine intermediates greatly accumulate. This may be the measurements, and do not accumulate gem-diamine inter- resultofeitherblockingtheconversionofgem-diamineIto mediates.Thisisacrucialstepinthecatalyticmechanismof gem-diamineII,slowingtheconversionofgem-diamineIIto allPLP-dependentenzymesbecauseitdeterminesbindingof theexternalaldimine,orboth. substrates and release of products. Our studies show that a Conversion of the gem-diamine II into the external aldiminerequiresthatthe𝜀-aminogroupofLys257isproto- single,semiconservativemutationofanactivesiteresiduecan 󸀠 becriticalforthetransaldiminationinSHMT. natedandthatitleavesperpendicularlyfromthesifaceofC4 ofPLP.InScheme1thisisshownasadirectprotontransfer from the substrate amino group in gem-diamine I to the 4.MaterialsandMethods leavingaminogroupofLys257ingem-diamineII.However, thisprotontransferalmostcertainlydoesnotoccurdirectly 4.1. Materials. All chemicals, coenzymes, antibiotics, and butthroughshiftsofprotonsinanetworkofacid-basegroups buffers were from Sigma-Aldrich (St. Louis, MO, USA) at the active site. It is possible, based on the wild type and or FisherScientific (Pittsburgh, PA, USA). (6S)-H4PteGlu T254mutantstructures,thatprotonationoftheLys257amine and (6S)-5-CHO-H4PteGlu were gifts from Merck Eprova ofthegem-diamineismediatedbyTyr73.Thepositionofthe AG(Schaffhausen,Switzerland).Crystallizationbufferswere gem-diamine amino groups relative to the Tyr73 side chain fromHamptonResearch(LagunaNiguel,CA,USA).