MolecularMicrobiology(2013)87(3),690–706 (cid:2) doi:10.1111/mmi.12124 Firstpublishedonline11January2013 Shigella IpaD has a dual role: signal transduction from the type III secretion system needle tip and intracellular secretion regulation A.DorotheaRoehrich,1EnoraGuillossou,1 Introduction ArielJ.Blocker1,2*andIsabelMartinez-Argudo1† TypeIIIsecretionsystems(T3SSs)arecommonvirulence 1SchoolofCellular&MolecularMedicine,Universityof factors among Gram-negative bacteria. They are protein Bristol,UniversityWalk,BristolBS81TD,UK. transport devices used for injecting effector proteins into 2SchoolofBiochemistry,UniversityofBristol,University host cells to modulate their responses in favour of the Walk,BristolBS81TD,UK. bacterium (Cornelis, 2006). To study conserved aspects of type III secretion, we use Shigella flexneri as a model Summary system. It is the causative agent of human bacillary dys- entery, a form of inflammatory diarrhoea, and uses the Type III secretion systems (T3SSs) are protein injec- T3SStopromoteitsinvasionintogutepithelialcells.The tion devices essential for the interaction of many T3SS consists of a basal body spanning both bacterial Gram-negative bacteria with eukaryotic cells. While membranesandahollowextracellularneedleservingas ShigellaassemblesitsT3SSwhentheenvironmental secretionchannel.Thedistalendoftheneedleistopped conditions are appropriate for invasion, secretion is by the tip complex, which is required for pore formation onlyactivatedafterphysicalcontactwithahostcell. and protein translocation into host cells. In Shigella, the First,thetranslocatorsaresecretedtoformaporein apparatus is assembled when the environmental condi- the host cell membrane, followed by effectors which tionsareappropriateforinvasion,butsecretionisblocked manipulatethehostcell.Secretionactivationistightly until physical contact with a host cell generates an acti- controlled by conserved T3SS components: the vationsignal(reviewedinSchroederandHilbi,2008). needletipproteinsIpaDandIpaB,theneedleitselfand Proteintranslocationintohostcellsrequiresthreepro- the intracellular gatekeeper protein MxiC. To further teins known as translocators (IpaB, IpaC and IpaD in characterize the role of IpaD during activation, we Shigella). Of these, IpaD is hydrophilic and constitutively combinedrandommutagenesiswithageneticscreen present atop mature needles (Espina etal., 2006; Sani to identify ipaD mutant strains unable to respond to etal., 2007; Veenendaal etal., 2007). It probably serves host cell contact. Class II mutants have an overall asascaffoldforthemostlyhydrophobicproteinsIpaBand defect in secretion induction. They map to IpaD’s IpaC,whichlaterformtheporeinthehostcellmembrane. C-terminalhelixandlikelyaffectactivationsignalgen- IpaBisalsoconstitutivelypresentatneedletips,whilethe eration or transmission. The Class I mutant secretes other hydrophobic translocator, IpaC, is only recruited to translocatorsprematurelyandisspecificallydefective the needle tip upon activation (Veenendaal etal., 2007; in IpaD secretion upon activation. A phenotypically Roehrich etal., 2010; Shen etal., 2010). In Yersinia, the equivalent mutant was found in mxiC. We show that needle tip is formed by the hydrophilic translocator LcrV: IpaDandMxiCactinthesameintracellularpathway.In in this species no hydrophobic translocator has been summary, we demonstrate that IpaD has a dual role found constitutively present atop needles (Mueller etal., and acts at two distinct locations during secretion 2005;2008;Blockeretal.,2008). activation. TypeIIIsecretionisatightlyregulatedprocessinitiated only after host cell contact. As type III proteins are expressedwhentheenvironmentalconditionsareappro- priateforinvasion,secretionhastobepreventedpriorto Accepted 4 December, 2012. *For correspondence. E-mail ariel. [email protected]; Tel. (+44)1173312063; Fax (+44)1173312 cell contact. Recently, we proposed a model featuring 091.†Presentaddress:ÁreadeGenética,FacultaddeCienciasAmbi- gatingmechanismslocatedinthecytoplasmthatprevent entalesyBioquímica,CampusTecnológicodelaFábricadeArmas, secretion in the absence of activation signals (Martinez- Universidad de Castilla-La Mancha,Avda. Carlos III, s/n, E-45071, Toledo,Spain. Argudo and Blocker, 2010). We hypothesized that under ©2013BlackwellPublishingLtd CharacterizationofipaDandmxiCpointmutants 691 non-activated conditions, a mechanism that represses helicesofthecoiledcoil(Johnsonetal.,2007;Veenendaal translocatorsecretion,directlyorindirectlyinvolvingIpaD etal., 2007). The C-terminal globular domain is a site of and/or IpaB, is put in place. In addition, the gatekeeper interactionwithIpaB,whiletheN-terminalglobulardomain protein MxiC prevents premature effector secretion (Bot- of IpaD has been proposed to act as a self-chaperone teaux etal., 2009; Martinez-Argudo and Blocker, 2010) (Johnsonetal.,2007).IntheLcrVclassofhydrophilictip anditrequiresasecretionsignaltodoso(Botteauxetal., proteins,thechaperoneisformedbyaseparatepolypep- 2009). After reception of the activation signal, such tidecalledLcrG(Lawtonetal.,2002). repression mechanisms would be counteracted and TheneedletipwasfirstvisualizedintheYersiniaT3SS secretion happens in an ordered way: translocator pro- (Mueller etal., 2005). We proposed that the tip contains teins are secreted first, then MxiC (Kenjale etal., 2005; fourmoleculesofIpaDandonemoleculeofIpaB(Johnson Martinez-ArgudoandBlocker,2010)followedbyearlyand etal.,2007;Veenendaaletal.,2007;Blockeretal.,2008). late effectors (Mavris etal., 2002; Parsot, 2009). As a The crystal structure of IpaD allowed construction of a DmxiC mutant shows weak and delayed secretion of pentamer based on dimer contacts in one of the crystal translocators in response to activation when compared formswithahelicalrisesimilartothatoftheMxiHneedle with the wild-type strain, we suggested that, in Shigella, (Cordesetal.,2003;Johnsonetal.,2007).Intheproposed MxiCalsoplaysaroleinactivatingtranslocatorsecretion IpaD pentamer, the position between the fourth and first (Martinez-ArgudoandBlocker,2010). IpaDmoleculesisstructurallydifferentfromallotherposi- MxiCbelongstoafamilyofT3SSproteinsthatincludes tions. This final position might thus be filled by IpaB Yersinia YopN/TyeA, enteropathogenic Escherichia coli (Johnson etal., 2007; Veenendaal etal., 2007; Blocker SepLandSalmonellaInvEandSsaL(Pallenetal.,2005). etal.,2008).Themodelputstheproposedcentralcoiled Besides similar sequences, the proteins have conserved coil and the C-terminal globular domain of IpaB in an domain topologies and structures (Schubot etal., 2005; equivalentconformationtothatofIpaD,positioningIpaB’s Deaneetal.,2008;2010)andallblockeffectorsecretionin domainhomologoustopore-formingcolicinsanditsputa- theabsenceofanactivationsignal.However,mutantsdo tive transmembrane helices in the ideal place to interact notshowthesamephenotypewithrespecttothecontrolof withthehostcellmembrane(Johnsonetal.,2007;Barta translocatorsecretion.InDinvE,DssaL,DsepLandDmxiC etal., 2012a). Together with mutagenesis data this sug- mutants,secretionoftranslocatorsisimpaired(Kuboriand gests that IpaB could be the host cell sensor and that a Galan,2002;Coombesetal.,2004;O’Connelletal.,2004; conformationalchangeinthetipcomplexmightbesignal- Deng etal., 2005), whereas it is constitutive in DyopN or ling event triggering T3SS activation (Veenendaal etal., DtyeA mutants (Iriarte etal., 1998; Ferracci etal., 2005). 2007;Roehrichetal.,2010;Shenetal.,2010). How the gatekeepers perform their tasks is unclear, but Congored(CR)isasmallamphipathicdyemoleculethat Salmonella InvE interacts with chaperone–translocator wasoriginallyusedtoassessinfectivityofShigellastrains: complexes (Kubori and Galan, 2002) and Shigella MxiC only colonies binding CR on agar plates were infective, interactswiththeATPaseinvitro(Botteauxetal.,2009). while ‘white’ colonies were not (Payne and Finkelstein, Despiteintenseresearchwestilldonotunderstandhow 1977).ItwaslaterfoundthatCRspecificallyactivatestype theactivationsignalgeneratedaftercontactwiththehost IIIsecretion(Parsotetal.,1995)andthatitstargetislikely cell is transduced to the cytoplasmic side of theT3SS to in the tip complex (Veenendaal etal., 2007). All T3SS initiatesecretion.ThefirstpartoftheT3SSthatestablishes component-knockout(KO)strainsthatarenotinducibleby contactwiththehostcellisprobablytheneedletip.There- CRarealsonon-invasive,suggestingthatCRandhostcell fore, it is likely that the tip complex senses the host cell. contactinduceT3SSactivationusingarelatedmechanism ExperimentaldatafromtheShigellaandYersiniasystems (Menardetal.,1993;1994;Blockeretal.,2001). suggestthattheneedleisdirectlyinvolvedintransmitting To test our hypothesis that, as part of the tip complex, the activation signal. Particular single amino acid muta- IpaD is involved in conformational changes crucial for tionsintheneedleproteinleadtoalteredsecretionpheno- signal transduction, we sought to identify ipaD point types and tip complex composition (Kenjale etal., 2005; mutantsunabletorespondtohostcellcontact.Foreaseof Torruellasetal.,2005;Veenendaaletal.,2007). analysis,wechosetosetupageneticscreenformutants TheShigellaneedleproteinMxiHisessentiallyacoiled insensitivetoinductionbyCR.Allmutantsisolatedshowed coilhairpinthatpolymerizesintothehelicalneedleusing a wild-type-like tip complex composition. Yet, six out of bothofitstermini(Cordesetal.,2003;Kenjaleetal.,2005; seven mutants were impaired in host cell sensing and Deaneetal.,2006;Fujiietal.,2012;Loquetetal.,2012). inductionoftypeIIIsecretion.Thepositionofthesemuta- SimilartotheneedleproteinMxiH,IpaDcontainsalonger tions highlights the importance of the C-terminal helix of centralcoiledcoilandrequiresitsextremeC-terminusfor IpaD in signal transduction. The remaining ipaD mutant binding to the needle. In addition, it has two globular wasunabletopreventsecretionundernon-inducingcon- domains, one at the N-terminus and one linking the two ditions. Parallel analysis of a mxiC mutant with a similar ©2013BlackwellPublishingLtd,MolecularMicrobiology,87,690–706 692 A.D.Roehrich,E.Guillossou,A.J.BlockerandI.Martinez-Argudo (cid:2) Table1. ipaDmutantsisolatedinthisstudyandtheirphenotypes. Phenotypicproperties Timesthemutant Class ipaDmutation wasfound Leakage CRinduction IpaDexpression Needletipcomposition Invasion – Wild-type – WT WT WT WT WT – Knockout – ++ (–)a NA –– –– I L99P,N255D 1 + (WT)b – WT WT IIa N186Y 1 WT –– WT WT – IIa N273I,Q277L 1 WT –– WT WT – IIa K291I(orTorN) 7c WT –– WT WT – IIb N292Y 1 WT – WT WT WT IIb T296I 11c WT – WT WT – IIb Y104L,Q299L 1 WT – WT WT – Themutationresponsiblefortheobservedphenotypeisindicatedinboldletters.‘WT’indicateswild-type-likeproperties,+or++anincreaseand –or––adecrease.‘NA’meansnotapplicable. a. DipaDisnotinduciblebyCR,butneverthelessproteinsaredetectableasitisafastconstitutivesecreter. b. MutantL99PonlyhasadefectinIpaDsecretionafterCRinduction. c. MutantsK291I/T/NandT296Iwerefoundindependentlyintwoandthreeseparatelibrariesrespectively. phenotype further supports the regulatory roles of both containingCR.Wild-typeShigellacoloniesstainlightred IpaD and MxiC in translocator secretion.Taken together, onCR-containingplates,whilemutantsunabletosecrete these data demonstrate that IpaD has a dual role during effectors are white (Maurelli etal., 1984). Constitutive secretionactivation. secretor mutant colonies, such as those containing bac- teria that have lost their needle tip, are bright red on CR Results plates,probablybecauseofthesecretionoflateeffectors (Parsot etal., 1995). Upon random PCR mutagenesis of FortheShigellaT3SS,‘induction’describestheburstofIpa theipaDgene,themutantDNAlibrarieswereclonedand protein secretion upon host cell sensing (Menard etal., amplifiedasdescribedinExperimentalprocedures.After 1994)oradditionofCR,asmallamphipathicdyemolecule transformation of the mutant libraries into the Shigella which acts as an artificial inducer of its T3SS (Bahrani DipaD mutant, we screened for white colonies in plates etal.,1997).Inductionisaveryfasteventasaround50% containing CR (Fig.S1). Around 500000 transformants of the Ipa proteins are secreted at 37°C in the 15min were screened and as expected a substantial proportion following CR addition (Bahrani etal., 1997; Magdalena ofthemwerebrightred(10–20%,indicatingexpressionof etal.,2002;Parsotetal.,2005).Priortoinductionthereis non-functionalipaDalleles).Onehundredandten‘white’ a slow, low level of Ipa protein secretion known as colonies were selected and their plasmids isolated and ‘leakage’, where around 5% of Ipa proteins are secreted retransformed into the DipaD mutant to ensure the white (Magdalenaetal.,2002;Parsotetal.,2005).‘Constitutive colour was not due to loss-of-function mutations else- secretion’of Ipa proteins represents an unregulated and wherewithintheT3SS-encodingoperons. higher-levelsecretionthanleakageandinvolvesnotonly Twenty-two plasmids were confirmed as giving rise the Ipa proteins but also the ‘late effectors’, which are to white colonies and their ipaD gene was sequenced involvedinlaterstagesofinfection.IntheDipaBandDipaD (Table1). Mutant ipaD(L99P, N255D) was not white but mutant strains, constitutive secretion is very fast and slightly more red than wild-type when retransformed into detectable in minutes. It is thus named ‘fast constitutive theDipaDmutant;however,itshowedaninterestingphe- secretion’(Veenendaaletal.,2007).Werecentlyshowed notype(seebelow)andwasfurtherinvestigated.Incases thatconstitutivesecretionhasadifferentcauseinaDipaB where more than one mutation was found in the ipaD versus a ipaBD3 mutant (Martinez-Argudo and Blocker, gene, individual mutations were cloned independently in 2010).Asthelattermutantisinaconstitutivelyactivated order to identify which was responsible for the mutant state,wenowcallitsphenotype‘prematuresecretion’. phenotype and only the mutation generating the mutant phenotypewasfurtherinvestigated. IsolationofipaDmutantsaffectedinsecretion TotestourhypothesisthatIpaDisinvolvedintherecep- ipaDmutantstrainshavedifferentiallyaltered tionortransductionoftheactivationsignal,wesoughtto secretionprofiles identify ipaD mutant strains that are unable to secrete after induction by CR. For this, we used a screening TocharacterizetheipaDmutants,weanalysedtheirsecre- methodbasedonthecolourofShigellacoloniesinplates tionprofileduringexponentialgrowthinnon-inducingcon- ©2013BlackwellPublishingLtd,MolecularMicrobiology,87,690–706 CharacterizationofipaDandmxiCpointmutants 693 Fig.1. AllipaDmutantsisolatedcausepartialdefectsinsecretion. A.ExponentialleakageofShigellawild-type,DipaDmutant,complementedstrain(DipaD/ipaD+)andipaDmutants(intheDipaDbackground) isolatedfromamutantlibrary.SampleswerecollectedasdescribedinExperimentalproceduresandSilver-stained. B.ProteinsecretioninresponsetoartificialinducerCongored(CR)induction.SampleswerecollectedasdescribedinExperimental proceduresandSilver-stained(toppanel)andWestern-blottedwithantibodiesagainstthetranslocatorproteinsIpaB,IpaC,IpaDandthe regulatorMxiC(bottompanels). C.Totalproteinexpressionlevels.SampleswerecollectedasdescribedinExperimentalproceduresandWestern-blottedwiththeindicated antibodies. Resultsshownarerepresentativeofatleasttwoindependentexperiments. ditions(Fig.1A)andfollowingCRinduction(Fig.1B).We mented strain (Fig.1B). In this 15min assay, increased found two novel types of secretion profile. First, mutant secretionundernon-inducingconditionsisonlyvisibleifit ipaDL99PsecretedamuchhigherlevelofT3Sproteinsin is ‘fast’as for example in the DipaD mutant. In a second non-inducing conditions when compared to the DipaD/ groupofmutants(ipaDN186Y,ipaDK291andipaD(N273I, ipaD+ complemented strain, but still less than the DipaD Q277L)),inductionofsecretionwasimpaired:incompari- mutant (Fig.1A, c. 4h incubation). Additionally, mutant sontotheDipaD/ipaD+complementedstraintheysecreted ipaDL99P showed a defect in IpaD secretion (approxi- only approximately 40%, 20%, 10% and 10% of IpaB, mately 20% of the complemented strain) following CR IpaC, IpaD and MxiC respectively. Mutants ipaDN292Y, induction,whilesecretionofIpaB,IpaC,MxiCandeffectors ipaDT296I and ipaDQ299L showed a similar secretion was still induced to levels comparable with the comple- pattern, although the defects in secretion were less pro- ©2013BlackwellPublishingLtd,MolecularMicrobiology,87,690–706 694 A.D.Roehrich,E.Guillossou,A.J.BlockerandI.Martinez-Argudo (cid:2) Fig.2. TheipaDmutantsshowdefectsinHeLainvasionbuthavenormalneedletipcompositions. A.InvasionofHeLacellswasmeasuredwithagentamicinprotectionassayasdescribedinExperimentalprocedures.Everyexperimentwas normalizedtowild-typeandthedataareaveragesofatleastthreeindependentexperimentsperformedatleastinduplicate.Errorbars indicatethestandarddeviation.WheretheinvasionissignificantlydifferentfromthecomplementedstrainDipaD/ipaD+(P<0.001,ANOVAwith Tukey’sposthoctest),ipaDmutantstrains(intheDipaDbackground)aremarkedwith***. B.Needlesfromwild-type,DipaDmutant,complementedstrain(DipaD/ipaD+)andipaDmutants(intheDipaDbackground)overexpressingthe needleproteinMxiHwereisolatedasdescribedinExperimentalproceduresandWestern-blottedwithantibodiesagainstIpaBandIpaD (sampleswerenormalizedfortheamountofMxiHpresentinpreparationsasdetectedbySilverstain,bottompanel).Resultsshownare representativeofatleasttwoindependentexperiments.Forthecomplementedstrain(DipaD/ipaD+)resultsfromtwoexperimentsareshownto indicateexperimentalvariability.Incomparisontothecomplementedstrain,thewild-typecontainsc.50(cid:2)10%IpaD(average(cid:2)standard deviation),ipaDL99Pcontainsc.70(cid:2)30%IpaD,ClassIIamutantscontainc.90(cid:2)20%IpaDandClassIIbmutantscontainc.90(cid:2)40% IpaD.ForIpaB,thesevaluesare70(cid:2)40%forwild-type,100(cid:2)70%foripaDL99P,150(cid:2)100%forClassIIamutantsand130(cid:2)90%for ClassIIbmutants.TherearenosignificantdifferencesbetweensamplesinanANOVA(P>0.05)forbothIpaDandIpaB. C.TotalproteinexpressionlevelsinovernightculturesfromstrainsoverexpressingtheneedleproteinasinB.Sampleswerecollectedas describedinExperimentalproceduresandWestern-blottedwithantibodiesagainstIpaBandIpaD. nounced(approximately80%,60%,40%and20%ofIpaB, stitutive secretion has a different cause in ipaDL99P IpaC, IpaD and MxiC respectively; Fig.1B). We named (Fig.S2).Therefore,allIpaDmutantsisolatedarepartially theseClassesI,IIaandIIbrespectively,startingthenum- defectiveinsecretionregulation. beringwiththemostN-terminalmutation.Whenweana- lysedtheexpressionoftheIpaDmutantproteins,thelevel AllIpaDmutantproteinsaresecretedinaconstitutive of the mutant proteins was similar to the complemented secretorbackground strain with the exception of the IpaDL99P, which was presentataround60%ofthewild-typeallele(Fig.1C).As AsallthenewlyisolatedipaDmutantsshowedadefectin deletion of ipaD leads to constitutive secretion, we were IpaDsecretion,wewonderedifthemutationsmadethem concernedthattheincreasedsecretioninipaDL99Punder ‘unfit’ for secretion, for example by affecting their con- non-inducing conditions might be due to a decrease in formation in the cytoplasm. To test this possibility we IpaDexpression.However,theipaDL99Pmutantsecreted checkediftheIpaDmutantsweresecretedinaconstitu- moreIpaBandIpaCthanastrainexpressingmuchlower tivesecretorbackground.Weandothershavepreviously levels of the wild-type IpaD protein, indicating that con- shown that the translocator proteins IpaC and IpaD are ©2013BlackwellPublishingLtd,MolecularMicrobiology,87,690–706 CharacterizationofipaDandmxiCpointmutants 695 Fig.3. ClassIIipaDmutantsareseverely affectedininductionofsecretion. A.Analysisofproteinssecretedbythe indicatedstrainsinresponsetoCongored (CR)induction.SamplesfromShigella wild-type,DipaDmutant,complementedstrain (DipaD/ipaD+)andipaDmutants(intheDipaD background)werecollectedasdescribedin ExperimentalproceduresandSilver-stained. B.Totalproteinexpressionlevels.Samples werecollectedasdescribedinExperimental proceduresandWestern-blottedwithan antibodyagainstIpaD. Resultsshownarerepresentativeofatleast twoindependentexperiments. secreted constitutively in a DipaB background (Menard the control strain DipaB DipaD/ipaD+ (Fig.S3). This indi- etal., 1994; Martinez-Argudo and Blocker, 2010). We catesthatourmutationsarenotimpairingIpaD’sabilityto generated a DipaB DipaD double KO strain and after besecretedbytheT3SS. transformingalltheipaDmutantplasmidsindividuallyinto thisstrainwecomparedtheirsecretionphenotypetothat ClassIIipaDmutantsshowdefectsininvasion oftheKOstraintransformedwithawild-typecopyofthe ofculturedcells ipaD gene. Analysis of the secretion profile by Western blot established that the IpaD mutant proteins were con- Totestwhetherthedefectinproteinsecretionafteraddi- stitutively secreted by the DipaB DipaD/ipaD mutant tionofCRintheipaDmutantscorrelateswithadefectin strains, as efficiently as wild-type IpaD was secreted by signal reception/transduction after host cell contact, we analysedwhethertheipaDmutantsarestillabletoinvade HeLacells.Gentamicinprotectionassayswereperformed as described in Experimental procedures. In this assay, the DipaD mutant is completely non-invasive (Menard etal., 1993).All Class II ipaD mutant strains, except for ipaDN292Y,showedaseveredefectininvasion(c.20% of the complemented strain, Fig.2A). Mutant ipaDL99P was as invasive as the complemented strain. These results indicate that most of the mutations identified in ipaDthatcauseadefectinCR-inducedsecretionleadto adefectininvasionofculturedcells. Fig.4. ImpairedsecretionofIpaDL99Pisduetolackofregulation byMxiC. ipaDmutantstrainshavenormalneedle A.SecretionofIpaDafterCongored(CR)inductionbyaDipaB tipcompositions DipaDdoublemutantcomplementedwitheitheripaDaloneora combinedipaBD3ipaDplasmid.Sampleswerecollectedas AsallisolatedipaDmutantshadapartialdefectinsecre- describedinExperimentalproceduresandWestern-blottedwithan tion and as IpaD forms part of the tip complex, one pos- antibodyagainstIpaD. B.Totalproteinexpressionlevels.Sampleswerecollectedas sible explanation is that the mutants have a defect in describedinExperimentalproceduresandWestern-blottedwithan the needle tip composition. Altered tip compositions are antibodyagainstIpaD. known to alter secretion regulation (Veenendaal etal., Resultsshownarerepresentativeofatleasttwoindependent experiments. 2007).Therefore,weexaminedthetipcomplexcomposi- ©2013BlackwellPublishingLtd,MolecularMicrobiology,87,690–706 696 A.D.Roehrich,E.Guillossou,A.J.BlockerandI.Martinez-Argudo (cid:2) Fig.5. ThemutationsL99PandK291Iaffect differentIpaDfunctions. A.ExponentialleakageoftheDipaDmutant, complementedstrain(DipaD/ipaD+)andipaD mutants(intheDipaDbackground).Samples werecollectedasdescribedinExperimental proceduresandWestern-blottedwiththe indicatedantibodies. B.ProteinsecretioninresponsetoCongored (CR)induction.Sampleswerecollectedas describedinExperimentalprocedures, Silver-stained(toppanel)andWestern-blotted withtheindicatedantibodies(bottompanels). C.Totalproteinexpressionlevels.Samples werecollectedasdescribedinExperimental proceduresandWestern-blottedwiththe indicatedantibodies. Resultsshownarerepresentativeofatleast twoindependentexperiments. tion of the ipaD mutants. Needles were purified from the wascompletelyuninducible.Totestwhetherthecombina- differentipaDmutantstrainsasdescribedinExperimental tionofmutationswouldproduceastrongerphenotype,we procedures and analysed by Western blot for the pres- constructed two new mutant ipaD plasmids combining ence of the tip proteins IpaD and IpaB. All mutants had ClassIIamutationsN186YandK291IorClassIIbmuta- wild-typelevelsofbothIpaDandIpaBwithinthelevelsof tions N292Y, T296I and Q299L. Mutant ipaD(N186Y, experimental variability (Fig.2B).This was also the case K291I)considerablyreducedthesecretionlevelsfollowing in the ipaDL99P mutant, which was expressed at lower CRinductioncomparedtosingleN186YandK291Imuta- levels (Fig.2C). This indicates that none of the mutants tions,whilethetriplemutantipaD(N292Y,T296I,Q299L) hasadefectinneedletipcomplexcomposition. showed a phenotype similar to Class IIa single mutants (Fig.3).Justliketheoriginalsinglemutants,thesecombi- nationsshowednormalleakage(notshown). ClassIIaandIIbipaDmutantsareaffectedinsignalling Our previous results indicate that the gatekeeper Induction of secretion was impaired in mutants from protein MxiC facilitates secretion of the translocators Classes IIa and IIb. We have hypothesized that, as part IpaB,IpaCandIpaD,astranslocatorsecretionisonlyvery of the tip complex, IpaD is involved in conformational weaklyinducibleinaDmxiCmutant(Martinez-Argudoand changes essential for the transduction of the activation Blocker,2010).Wealsofoundthattranslocatorsecretion signal (Veenendaal etal., 2007; Martinez-Argudo and is MxiC-independent in a DipaB or DipaD constitutive Blocker, 2010). Therefore, we should be able to isolate secretorbackground,butthatitisstillMxiC-dependentin mutantsunabletotransmitthesignal.However,nomutant aconstitutively‘on’ipaBD3strain,asinthewild-typestrain ©2013BlackwellPublishingLtd,MolecularMicrobiology,87,690–706 CharacterizationofipaDandmxiCpointmutants 697 Fig.6. mxiC(E201K,E276K,E293K)hasa phenotypesimilartoipaDL99P. A.Exponentialleakage.Sampleswere collectedasdescribedinExperimental proceduresandWestern-blottedwiththe indicatedantibodies. B.ProteinsecretioninresponsetoCongored (CR)induction.Sampleswerecollected describedinExperimentalprocedures, Silver-stained(toppanel)andWestern-blotted withtheindicatedantibodies(bottompanels). C.Totalproteinexpressionlevels.Samples werecollectedasdescribedinExperimental proceduresandWestern-blottedwiththe indicatedantibodies. ThecomplementedstrainDmxiC/mxiC+was grownwith25mMIPTG,whilethe DmxiC/mxiC(E201K,E276K,E293K)mutant wasgrownwith10mMIPTGbecauseofits highermxiCexpressionlevel.Resultsshown arerepresentativeofatleasttwoindependent experiments. (Martinez-Argudo and Blocker, 2010; Roehrich etal., ground. Thus, impaired secretion of these IpaD mutant 2010).IntheipaBD3mutantIpaBisexpressedlackingits proteinsisnotduetoalackofregulationbyMxiC.Moreo- lastthreeC-terminalaminoacids.Thismutantislockedin ver,theconstitutivesecretionpatternofallthestrainswas asecretion‘on’conformation(i.e.similartothesecretion similar to that of the ipaBD3 DipaD/ipaD+ strain (not activated wild-type), as it is a constitutive secretor, inva- shown), indicating that the ipaBD3 mutation is epistatic sive and recruits some IpaC to the needle tip (Roehrich overtheipaDClassIImutations. etal.,2010).Toruleoutthepossibilitythatthedecreased These results, together with the fact that the composi- secretion of Class II IpaD mutant proteins was due to tion of the needle tip is wild-type-like for those mutants lack of regulation by MxiC, we investigated if they were (Fig.2B), indicate that Class IIa and IIb mutants are secreted in an ipaBD3 background. We made a plasmid affected in signalling from the needle tip and not in a expressingbothipaBD3andipaDintowhichallthemuta- downstreamactivationstep. tionsweresubsequentlycloned.Allplasmidsweretrans- formed into the strain DipaB DipaD and their secretion LackofsecretionoftheClassIIpaDL99Pmutant profileanalysed.FormutantsbelongingtoClassII,secre- proteinisduetolackofregulationbyMxiC tion of IpaD became constitutive in all the mutants (not shown). This was also the case when non-inducible In the ipaDL99P mutant strain, only IpaD secretion was mutant ipaD(N186Y, K291I) was expressed in this back- impaired after activation (Fig.1B). As mentioned above, ©2013BlackwellPublishingLtd,MolecularMicrobiology,87,690–706 698 A.D.Roehrich,E.Guillossou,A.J.BlockerandI.Martinez-Argudo (cid:2) Fig.7. IpaDandMxiCarebothinvolvedin theregulationofthemechanismthatprevents secretion. A.ExponentialleakageoftheDipaDmutant andaDipaDDmxiCdoublemutant complementedwithipaDandmxiCcontaining plasmids.Sampleswerecollectedas describedinExperimentalproceduresand Western-blottedwiththeindicatedantibodies. Allsamplesdetectedwiththesameantibody wereanalysedonthesamegel. B.ProteinsecretioninresponsetoCongored (CR)induction.Sampleswerecollectedas describedinExperimentalprocedures, Silver-stained(toppanel)andWestern-blotted withthedesignatedantibodies(bottom panels). C.Totalproteinexpressionlevels.Samples werecollectedasdescribedinExperimental proceduresandWestern-blottedwiththe indicatedantibodies. Bacteriaweregrownwith1%arabinoseand 25mMIPTGasrequiredforexpressionof ipaDandmxiCrespectively.Mutant mxiC(E201K,E276K,E293K)isabbreviated mxiC***.Resultsshownarerepresentativeof atleasttwoindependentexperiments. secretion of the translocator proteins from the cytoplasm conditions by Western blot and found that the mutant is promoted by MxiC in wild-type and ipaBD3 back- secreted IpaB, IpaC, MxiC and effector proteins (Fig.5A grounds(Martinez-ArgudoandBlocker,2010).Inorderto and not shown). This suggested that in the ipaDL99P examineifsecretionoftheIpaDL99Pmutantproteinwas mutantaregulatoryfunctionofIpaDisalteredandthat,as stilldependentonMxiC,weanalyseditssecretioninthe a result, the mechanism that prevents secretion before ipaBD3background.WhencomparedwithipaBD3DipaD/ activationsignalreceptionisimpaired.Ontheotherhand, ipaD+,strainipaBD3ipaDL99Pshowedadifferentpattern ClassIImutantsdidnotshowadefectinthepreventionof of secretion: IpaDL99P secretion was impaired in the secretion under non-induced conditions (Fig.1A).There- ipaBD3 background, but constitutive in the DipaB back- fore,ClassIandClassIImutantscouldaffecttwodifferent ground (Fig.4). Therefore, the impairment in IpaDL99P aspectsofIpaDfunction.Totestthishypothesis,wemade secretion is probably due to a lack of intracytoplasmic adoublemutantcombiningmutationipaDK291I(ClassIIa) regulationbyMxiC. andipaDL99P(ClassI).Ifdifferentfunctionswereaffected intheseclasses,onewouldexpecttoseebothphenotypes inthecombinedmutant.However,ifbothclassesaffected IpaDhasadualroleinT3SSregulation the same function, dominance of one of the phenotypes TheipaDL99PstrainsecreteshigherlevelsofT3Sproteins would be more likely. The mutant ipaD(L99P, K291I) innon-inducingconditionscomparedtothecomplemented showedbothphenotypes:itsecretedIpaB,IpaCandMxiC strain(Fig.1A).Tofurtherinvestigatethis,weanalysedthe under non-inducing conditions and was impaired in CR supernatant of exponential cultures under non-induced induction (Fig.5).Together with the fact that secretion in ©2013BlackwellPublishingLtd,MolecularMicrobiology,87,690–706 CharacterizationofipaDandmxiCpointmutants 699 Fig.8. PrematuresecretioninipaDL99Pis MxiC-dependent. A.ExponentialleakageofaDipaDDmxiC doublemutantcomplementedwitheitheripaD oripaDL99PaloneoradditionallywithmxiC. Sampleswerecollectedasdescribedin ExperimentalproceduresandWestern-blotted withtheindicatedantibodies. B.Totalproteinexpressionlevels.Samples werecollectedasdescribedinExperimental proceduresandWestern-blottedwiththe indicatedantibodies. Bacteriaweregrownwith1%arabinoseand 25mMIPTGasrequiredforexpressionof ipaDandmxiCrespectively.Resultsshown arerepresentativeofatleasttwoindependent experiments. thedifferentmutantclassesisdifferentiallyaffectedbyan secretion. To distinguish between these possibilities, we additionalipaBD3mutation,thisresultsuggeststhatIpaD analysed whether IpaB and IpaC were secreted from a hasadualroleinregulationofT3SSsecretion. DipaDDmxiC/ipaDL99Pstrainundernon-inducingcondi- tions(Fig.8).WefoundprematuresecretionintheDipaD DmxiC/ipaDL99P strain was reduced in comparison to IpaDandMxiCarebothinvolvedintheregulationofthe ipaDL99P alone. Thus, premature secretion of IpaB and mechanismthatcontrolssecretion IpaCinipaDL99PisdependentonthepresenceofMxiC. IntracytoplasmicMxiCisrequiredforsecretionoftranslo- cator proteins after activation (Martinez-Argudo and Discussion Blocker,2010).Intriguingly,wegeneratedamutantinmxiC with a very similar phenotype to the ipaDL99P mutant: Type III secretion systems are activated by host cell mxiC(E201K, E276K, E293K) is a triple mutant in a con- contact which we proposed leads to a conformational served negatively charged patch on the surface of MxiC change in the needle tip complex that triggers secretion thathasbeensuggestedtobeinvolvedinproteininterac- from the cytoplasm (Veenendaal etal., 2007; Blocker tions(Deaneetal.,2008).ThismutantalsosecretesIpaB, etal., 2008; Martinez-Argudo and Blocker, 2010). To IpaC, MxiC and effector proteins in non-inducing condi- investigate the role of the major component of the tip tions. Furthermore, it is also impaired in IpaD secretion complexIpaDintransductionoftheactivationsignalinto afterinduction,butnotaffectedininductionofanyofthe thecytoplasm,weusedageneticscreentoidentifyipaD otherproteins(Fig.6andnotshown).Ourresultssuggest mutants unable to secrete after induction by CR.All pre- thatboththeipaDL99PandmxiC(E201K,E276K,E293K) viousmutationsdescribedinIpaDaresilentorleadtoat mutationscauseprematureactivationofsecretion. leastpartialloss-of-functionandhenceconstitutivesecre- When IpaDL99P and MxiC(E201K, E276K, E293K) tion(Pickingetal.,2005;Bartaetal.,2012b;Epleretal., were expressed together, we observed an increase in 2012). Here we describe several mutations in ipaD that secretionundernon-inducedconditionsincomparisonto lead to separate defects in secretion activation (Class I thesinglemutants(Fig.7).Theseresultsstronglysuggest andClassII)andusethemtoconcludethatIpaDhastwo that as MxiC, IpaD is involved in the mechanism that rolesinthisprocess. controlssecretion. IpaDisinvolvedinsignaltransductionfromthe PrematuresecretionintheipaDL99Pmutantis needletip MxiC-dependent All our results suggest that Class II ipaD mutants are WethuswonderedwhetherIpaDisinvolvedinthesame affected in signalling from the tip complex. Their very activationrouteasMxiCorwhetherithasanindependent identification supports the existence of at least two func- role in controlling secretion. If the former was true, one tional states of the needle tip.All Class II mutants have would expect the ipaDL99P mutant to require MxiC for wild-type-likeneedletipcomplexcompositionandshowa prematuresecretion.However,ifIpaDwasdirectlyaffect- decrease in protein secretion after induction by CR. Fur- ing secretion of the translocators IpaB and IpaC, thermore,thedefectinsecretionofIpaDClassIImutantsis ipaDL99P should lead to MxiC-independent constitutive notduetotheirinabilitytobesecretedbytheT3SSortoa ©2013BlackwellPublishingLtd,MolecularMicrobiology,87,690–706