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SubmittedtotheJournalofMathematicalBiology RadekErban·HansG.Othmer 6 0 Taxis Equations for Amoeboid Cells 0 2 February9,2008–(cid:13)c Springer-Verlag2008 n a J Abstract The classical macroscopic chemotaxis equations have previously been 9 derivedfromanindividual-baseddescriptionofthetacticresponseofcellsthatuse 2 a “run-and-tumble”strategyin responseto environmentalcues[17,18].Here we derive macroscopicequationsfor the more complextype of behavioralresponse ] B characteristicofcrawlingcells,whichdetectasignal,extractdirectionalinforma- C tion from a scalar concentration field, and change their motile behavior accord- ingly. We present severalmodels of increasingcomplexity for which the deriva- . o tion ofpopulation-levelequationsis possible,andwe showhowexperimentally- i b measuredstatisticscanbeobtainedfromthetransportequationformalism.Wealso - showthatamoeboidcellsthatdonotadapttoconstantsignalscanstillaggregate q [ insteadygradients,butnotinresponsetoperiodicwaves.Thisisincontrasttothe caseofcellsthatusea“run-and-tumble”strategy,whereadaptationisessential. 1 v 8 1. Introduction 4 0 Motile organisms sense their environment and can respond to it by (i) directed 1 movementtoward or away from a signal, which is called taxis, (ii) by changing 0 their speed of movementand/orfrequencyof turning,whichis called kinesis, or 6 (iii)byacombinationofthese.Usuallytheseresponsesarebothcalledtaxes,and 0 / weadoptthisconventionhere.Taxisinvolvesthreemajorcomponents:(i)anex- o ternalsignal,(ii)signaltransductionmachineryfortransducingtheexternalsignal i b into an internal signal, and (iii) internal components that respond to the trans- - ducedsignalandleadtochangesinthepatternofmotility.Inordertomoveaway q : from noxioussubstances (repellents) or toward food sources (attractants) organ- v isms must extract directional information from an extracellular scalar field, and i X there are two distinct strategies that are used to do this. A simple paradigm will r illustratethese. a RadekErban:MathematicalInstitute,UniversityofOxford,24-29StGiles’,Oxford,OX1 3LB,UnitedKingdom,e-mail:[email protected] Hans G. Othmer: School of Mathematics, 270A Vincent Hall, University of Minnesota, Minneapolis,MN55455,USA,e-mail:[email protected] Keywords:amoeboidcells,microscopicmodels, direction-sensing, aggregation, chemo- taxisequation,velocityjumpprocess 2 R.ErbanandH.G.Othmer Supposethat one is close enoughto a bakery to detect the odors,but cannot seethebakery.Tofindit,onestrategyistousesensorsattheendofeacharmthat measurethedifferenceinthesignalatthecurrentlocationandusethedifferenceto decideonadirection.Clearlyhumansdonotusethisstrategy,butinstead,execute the “bakery walk”, which is to take a sniff and judge the signal intensity at the presentlocation,takeastepandanothersniff,comparethesignals,andfromthe comparisondecideonthenextstep. The first strategy is used by amoeboid cells (cells which move by crawling through their environment),which have receptors on the cell membrane and are large enough to detect typical differences in the signal over their body length. Smallcellssuchasbacteriacannoteffectivelymakea“two-pointinspace”mea- surementovertheirbodylength,andthereforetheyadoptthesecondstrategyand measure the temporal variation in the signal as they move through the external field.Ineithercase,animportantconsiderationinunderstandingpopulation-level behavioris whether or not the individualmerely detects the signaland responds to it, or whether the individualalters it as well, for example by consuming it or byamplifyingitsoastorelaythesignal.Intheformercasethereisnofeedback from the local density of individuals to the external field, but when the individ- ualproducesordegradesthesignal,thereiscouplingbetweenthelocaldensityof individuals and the intensity of the signal. The latter occurs, for example, when individuals move toward a signal from neighboringcells and relay the signal as well, as in the aggregation of the cellular slime mold Dictyostelium discoideum (Dd). Oneofthe best-characterizedsystemsthatadoptsthe “bakerywalk”strategy is the flagellated bacterium E. coli, for which the signal transduction machinery is well characterized[5]. E. colialternates between a moreor less linear motion called a run and a highly erratic motion called tumbling, which produces little translocationbutreorientsthecell. Runtimesaretypicallymuchlongerthanthe tumbling time, and when bacteria move in a favorable direction (i.e., either in the direction of foodstuffs or away from noxious substances), the run times are increased further. Since these bacteria are too small to detect spatial differences in the concentration of an attractant on the scale of a cell length, they choose a new directionessentially atrandomat the endof a tumble,althoughithas some biasin the directionofthe precedingrun [4]. The effectof alternatingthese two modesofbehaviorand,inparticular,ofincreasingtherunlengthwhenmovingina favorabledirection,isthatabacteriumexecutesathree-dimensionalrandomwalk with drift in the favorable direction, when observed on a sufficiently long time scale[3,30].Inaddition,thesebacteriaadapttoconstantsignallevelsandineffect onlyaltertherunlengthinresponsetochangesinextracellularsignals.Modelsfor signaltransductionandadaptationinthissystemhasbeendeveloped[46,2],anda simplifiedversionofthefirstmodelhasbeenincorporatedintoapopulation-level description of behavior [17,18]. The latter analysis shows how parameters that characterizesignaltransductionandresponseinindividualcellsareembeddedin the macroscopicsensitivity χ in the macroscopicchemotaxisequationdescribed later.Havingthebacterialexampleinmind,wewillcallthe“bakerywalk”strategy asa“run-and-tumble”strategyinwhatfollows. TaxisEquationsforAmoeboidCells 3 Thedirectedmotionofamoeboidcells(e.g.Ddorleukocytes),whichiscru- cial in embryonic development,wound repair, the immune response to bacterial invasion, and tumor formation and metastasis, is much more complicated than bacterial motion. Cells detect extracellular chemical and mechanical signals via membranereceptors,and these trigger signaltransductioncascades thatproduce intracellularsignals.Smalldifferencesintheextracellularsignaloverthecellare amplifiedintolargeend-to-endintracellulardifferencesthatcontrolthemotilema- chineryof the cell and therebydeterminethe spatial localizationof contactsites with the substrate and the sites of force-generation needed to produce directed motion [40,7]. Movementof Dd and other amoeboidcells involvesat least four differentstages[36,43].(1)Cellsfirstextendlocalizedprotrusionsattheleading edge, which take the form of lamellipodia,filopodia or pseudopodia.(2) Not all protrusionsare persistent, in thatthey must anchorto the substrate or to another cellinorderfortheremainderofthecelltofollow[44].Protrusionsarestabilized byformationofadhesivecomplexes,whichserveassitesformolecularsignaling andalso transmitmechanicalforceto the substrate.(3)Next, in fibroblastsacto- myosinfilamentscontractatthefrontofthecellandpullthecellbodytowardthe protrusion,whereasinDd,contractionisattherearandthecytoplasmissqueezed forward.(4)Finallycellsdetachtheadhesivecontactsattherear,allowingthetail ofthecelltofollowthemaincellbody.InDdtheadhesivecontactsarerelatively weak and the cells move rapidly (∼ 20µm/min), whereas in fibroblasts they are verystrongandcellsmoveslowly.Thecoordinationandcontrolofthiscomplex processofdirectionsensing,amplificationofspatialdifferencesinthesignal,as- semblyof the motile machinery,andcontrolof the attachmentto the substratum involvesnumerousmoleculeswhose spatialdistributionservesto distinguishthe frontfromtherearofthecell,andwhosetemporalexpressionistightlycontrolled. Inaddition,Ddcellsadapttothemeanextracellularsignallevel[40]. Dd is a widely-used model system for studying signal transduction, chemo- taxis, and cell motility. Dd uses cAMP as a messenger for signaling initiated by pacemaker cells to control cell movement in various stages of development(re- viewed in [39]). In the absence of cAMP stimuli Dd cells extend pseudopods in more-or-less random directions, although not strictly so since formation of a pseudopodinhibitsformationofanotheronenearbyforsometime.Aggregation- competentcellsrespondtocAMPstimulibysuppressingexistingpseudopodsand roundingup(the“cringeresponse”),whichoccurswithinabout20secsandlasts about30secs[8].UnderuniformelevationoftheambientcAMPthisisfollowed by extensionof pseudopodsin variousdirectionsand an increase in the motility [53,54].However,onepseudopodusuallydominates,evenunderuniformstimu- lation.AlocalizedapplicationofcAMPelicitsthe“cringeresponse”followedby alocalizedextensionofapseudopodnearthepointofapplicationofthestimulus [47].Howthecelldeterminesthedirectioninwhichthesignalislargest,andhow itorganizesthemotilemachinerytopolarizeandmoveinthatdirection,arema- jorquestionsfromboththeexperimentalandtheoreticalviewpoint.SincecAMP receptors remain uniformly distributed around the cell membrane during a tac- ticresponse,receptorlocalizationoraggregationisnotpartoftheresponse[27]. Well-polarized cells are able to detect and respond to chemoattractantgradients 4 R.ErbanandH.G.Othmer withaslittle asa 2%concentrationdifferencebetweentheanteriorandposterior ofthecell[34].Directionalchangesofashallowgradientinducepolarizedcellsto turnonatimescaleof2-3seconds[23],whereaslargechangesleadtolarge-scale disassemblyofmotilecomponentsandcreationofanew“leadingedge”directed towardthestimulus[22].Polarityislabileincellsstarvedforshortperiodsinthat cellscanrapidlychangetheirleadingedgewhenthestimulusismoved[47]. There are a number of models for how cells extract directional information from the cAMP field. Fisher et al. [19] suggest that directional information is obtainedbytheextensionofpseudopodsbearingcAMPreceptorsandthatsensing thetemporalchangeexperiencedbyareceptorisequivalenttosensingthespatial gradient.However,Ddcellscontaina cAMP-degradingenzymeontheirsurface, and it has been shown that as a result, the cAMP concentration increases in all directionsnormalto the cellsurface[10]. Furthermore,morerecentexperiments show that cells in a steady gradient can polarize in the direction of the gradient without extendingpseudopods[40]. Thus cells must rely entirely on differences in the signal across the cell body for orientation. Moreover, the timing between differentcomponentsoftheresponseiscritical,becauseacellmustdecidehowto movebeforeitbeginstorelaythesignal.AnalysisofamodelforthecAMPrelay pathwayshowsthatacellexperiencesasignificantdifferenceinthefront-to-back ratioofcAMPwhenaneighboringcellbeginstosignal[10],whichdemonstrates thatsufficientend-to-enddifferencesforreliableorientationcanbegeneratedfor typicalextracellularsignals.Anactivator-inhibitormodelforanamplificationstep inchemotacticallysensitivecellswasalsopostulated[35].Amplificationofsmall externaldifferencesinvolvesaTuringinstabilityintheactivator-inhibitorsystem, coupledtoa slowerinactivatorthatsuppressestheprimaryactivation.While this modelreproducessomeoftheobservedbehavior,thereisnobiochemicalbasisfor it;itispurelyhypotheticalandomitssomeofthemajorknownprocesses.Amodel that takes into accountsome of the known biochemicalsteps has been proposed morerecently[31]. Theobjectiveofthispaperisto deriveequationsforthepopulation-levelbe- haviorofamoeboidcellssuchasDdorleukocytesthatincorporatedetailsaboutthe individual-basedresponsetosignals.Wepresentseveralmodelswiththeincreased complexityforwhichthederivationofpopulation-levelequationsispossible.We show how experimentally-measuredstatistics can be obtainedfromthe transport equation formalism. The paper is organizedas follows. We discuss the classical chemotaxis description and summarize the state of the art of the derivation of macroscopicequationsandpopulation-levelstatisticsfromindividual-basedmod- elsintheremainderofthissection.InSection2,weestablishthegeneralsetupfor modelsofamoeboidcellsandwepresentindividual-basedmodelswhichcapture the essentialbehavioralresponsesof eukaryoticcells. InSection 3we derivethe macroscopicmomentequationsfromthemicroscopicmodelandthedependence ofthemeanspeedonthesignalstrengthisstudied.Finally,weprovideconclusions andthediscussionofthepresentedapproachesinSection4. TaxisEquationsforAmoeboidCells 5 1.1. Macroscopicdescriptionsofchemotaxis The simplest description of cell movementin the presence of both diffusiveand tacticcomponentsresultsbypostulatingthatthefluxofcellsjisgivenby j=−D∇n+nu , (1) c wherenisthedensityofcells,u isthemacroscopicchemotacticvelocityandD c isthedifusionconstant.Thetaxisispositiveornegativeaccordingasu isparallel c oranti-paralleltothedirectionofincreaseofthechemotacticsubstanceS.Keller andSegel[28]postulatedthatthechemotacticvelocityisgivenbyu =χ(S)∇S c andthen(1)canbewrittenas j= −D∇n+nχ(S)∇S (2) whereχ(S)iscalledthechemotacticsensitivity.Intheabsenceofcelldivisionor deaththeresultingconservationequationforthecelldensityn(x,t)is ∂n =∇·(D∇n−nχ(S)∇S) (3) ∂t and this is called a classical chemotaxis equation. Unless the distribution of the chemotactic substance is fixed, (3) is coupled to an evolution equation for this substance,andperhapsothergoverningvariables. Other phenomenologicalapproachesto the derivationof the chemotactic ve- locityhavebeentaken.Forexample,byapproachingtaxisfromamechanicalpoint ofview,PateandOthmer[41]derivedthevelocityintermsofforcesexertedbyan amoeboidcell.StartingfromNewton’slaw,neglectinginertialeffects,andassum- ingthatthemotiveforceexertedbyacellisafunctionoftheattractantconcentra- tion,theyshowedhowthechemotacticsensitivityisrelatedtotherateofchangeof theforcewithattractantconcentration.Inthisformulationthedependenceofthe fluxonthegradientoftheattractantarisesfromthedifferenceintheforceexerted indifferentdirectionsduetodifferentattractantconcentrations.Experimentalsup- port for this comes from work of [51], who show that as many pseudopods are produceddown-gradientasup,butthoseup-gradientaremoresuccessfulingen- eratingcellmovement.Weshalluseaversionofthemechanicalapproachtotaxis inamodeldescribedinthefollowingsection. Thefirstderivationthatdirectlyrelatesthechemotacticvelocitytoproperties of individual cells is due to Patlak [42], who used kinetic theory arguments to expressu intermsofaveragesofthevelocitiesandruntimesofindividualcells. c ThisapproachwasextendedbyAlt[1],whoshowedthatfora classofreceptor- basedmodelsthefluxisapproximatelygivenby(2).Theseapproachesarebased onvelocity-jumpprocesses,whichleadtotransportequationsoftheform ∂ ′ ′ ′ p(x,v,t)+v·∇p(x,v,t) =−λp(x,v,t)+λ T(v,v)p(x,v,t)dv. (4) ∂t Z V where p(x,v,t) is the density of cells at position x ∈ Ω ⊂ Rn, moving with velocity v ∈ V ⊂ Rn at time t ≥ 0, λ is the turning rate and kernel T(v,v′) 6 R.ErbanandH.G.Othmer givestheprobabilityofachangeinvelocityfromv′ tov, giventhatareorienta- tionoccurs[37].Externalsignalsentereitherthroughadirecteffectontheturning rateλandtheturningkernelT,orindirectlyviainternalvariablesthatreflectthe externalsignalandinturninfluenceλand/orT.Thefirstcaseariseswhenexper- imental results are used to directly estimate parametersin the equation [20], but thelatterapproachismorefundamental.Thereductionof(4)tothemacroscopic chemotaxisequationsforthefirstcaseisdonein[24,38]and[6]. Somestatisticsofthedensitydistributioninthefirstcase,whereintheexternal fieldmodifiestheturningkernelorturningratedirectly,caneasilybederivedand used to interpret experimental data. To outline the procedure, we consider two- dimensionalmotionofamoeboidcellsinaconstantchemotacticgradientdirected alongthepositivex1axisoftheplane,i.e. ∇S =k∇Ske1, wherewedenoted e1 =[1,0]. (5) Moreover, we assume that the gradient only influences the turn angle distribu- tion T;details of the procedureare given in [37]. We assume for simplicity that the individualsmovewith a constantspeeds. i.e.a velocityofan individualcan be expressed as v(φ) ≡ s[cos(φ),sin(φ)] where φ ∈ [0,2π). We assume that T(v,v′) ≡ T(φ,φ′)isthesumofasymmetricprobabilitydistributionh(φ)and abiastermk(φ)thatresultsfromthegradientofthechemotacticsubstance.Since thegradientisdirectedalongthepositivex1 axis,weassumethatthebiasissym- metric about φ = 0 and takes its maximum there. Thus we write T(φ,φ′) = h(φ−φ′)+k(φ)wherehandkarenormalizedasfollows. 2π 2π h(φ)dφ=1 k(φ)dφ=0 (6) Z0 Z0 Let p(x,φ,t) be the density of cells at position x ∈ R2, moving with velocity v(φ) ≡ s[cos(φ),sin(φ)],φ ∈ [0,2π),attimet ≥ 0.Thestatisticsofinterestare themeanlocationofcellsX(t),theirmeansquareddisplacementD2(t),andtheir meanvelocityV(t),whicharedefinedasfollows. 1 2π X(t)= xp(x,φ,t) dφdx, N0 ZR2Z0 1 2π D2(t)= kxk2 p(x,φ,t) dφdx, N0 ZR2Z0 1 2π V(t)= v(φ)p(x,φ,t) dφdx, N0 ZR2Z0 1 2π B(t)= (x·v(φ))p(x,φ,t) dφdx, N0 ZR2Z0 whereN0 isthetotalnumberofindividualspresentandB(t)isanauxiliaryvari- able that is neededin the analysis. Two furtherquantitiesthatarise naturallyare the taxis coefficientχ, which is analogousto the chemotactic sensitivity defined TaxisEquationsforAmoeboidCells 7 earlierbecauseitmeasurestheresponsetoadirectionalsignal,andthepersistence indexψ .Thesearedefinedas d 2π π χ≡ k(φ)cosφdφ and ψ =2 h(φ)cosφdφ. (7) d Z0 Z0 The persistence index measures the tendencyof a cell to continuein the current direction.Sincewehaveassumedthatthespeedisconstant,wemustalsoassume thatχandψ satisfytherelationχ<1−ψ ,forotherwisetheformerassumption d d isviolated(cf.(10)). Onecannowshow,bytakingmomentsof(4),using(6)andsymmetriesofh andk,thatthemomentssatisfythefollowingevolutionequations[37]. dX dV =V =−λ0V+λχse1 (8) dt dt dD2 dB =2B =s2−λ0B+λχsX1 (9) dt dt whereλ0 ≡λ(1−ψd).Thesolutionof(8)subjecttozeroinitialdatais 1 X(t)=sCI t− (1−e−λ0t) e1, V(t)=sCI(1−e−λ0t)e1 (10) (cid:18) λ0 (cid:19) whereC ≡ χ/(1−ψ ) is sometimescalled the chemotropismindex.Thusthe I d mean velocity of cell movement is parallel to the direction of the chemotactic gradient and approaches V∞ = sCIe1 as t → ∞. Thus the asymptotic mean speedisthecellspeeddecreasedbythefactorC . I A measure of the fluctuations of the cell path around the expected value is providedbythemeansquaredeviation,whichisdefinedas 1 2π σ2(t)= kx−X(t)k2 p(x,φ,t)dφdx=D2(t)−kX(t)k2 . (11) N0 ZR2Z0 Using(8)–(9),onealsofindsadifferentialequationforσ2.Solvingthisequation, wefind 2s2 1 5 σ2 ∼ (1−C2)t+ C2−1 as t→∞ λ0 (cid:26) I λ0 (cid:18)2 I (cid:19)(cid:27) andfromthisonecanextractthediffusioncoefficientas 2s2 D = (1−C2). λ0 I Thereforeiftheeffectofanexternalgradientcanbequantifiedexperimentallyand representedasthedistributionk,themacroscopicdiffusioncoefficient,thepersis- tenceindex,andthechemotacticsensitivitycanbecomputedfrommeasurements of the mean displacement,the asymptoticspeed and the mean-squareddisplace- ment. However,it is not as straightforwardto derive directly the macroscopic evo- lution equations based on detailed models of signal transduction and response. 8 R.ErbanandH.G.Othmer Suppose that the internal dynamics that describe signal detection, transduction, processingandresponsearedescribedbythesystem dy =f(y,S) (12) dt where y ∈ Rm is the vector of internal variables and S is the chemotactic sub- stance (S is extracellular cAMP for Dd aggregation). Models that describe the cAMPtransductionpathwayexist[33,48,49],butfordescribingchemotaxisone would have to formulatea more detailedmodel. The formof this system can be verygeneralbutitshouldalwayshavethe“adaptive”propertythatthesteady-state value(correspondingtotheconstantstimulus)oftheappropriateinternalvariable (the“responseregulator”)isindependentoftheabsolutevalueofthestimulus,and thatthesteadystateisgloballyattractingwithrespecttothepositiveconeofRm. We showedearlierthatfornon-interactingwalkerstheinternaldynamicscan be incorporatedin the transportequationasfollows[17]. Letp(x,v,y,t) bethe densityofindividualsina(2N +m)−dimensionalphasespacewithcoordinates [x,v,y],wherex ∈RN isthepositionofacell,v ∈V ⊂ RN isitsvelocityand y ∈ Y ⊂ Rm isitsinternalstate,whichevolvesaccordingto(12).Theevolution ofpisgovernedbythetransportequation ∂p ′ ′ ′ +∇ ·vp+∇ ·fp=−λ(y)p+ λ(y)T(v,v,y)p(x,v ,y,t)dv (13) x y ∂t Z V where,asbefore,weassumethattherandomvelocitychangesaretheresultofa Poisson processofintensityλ(y). ThekernelT(v,v′,y)givesthe probabilityof achangeinvelocityfromv′ tov,giventhatareorientationoccurs.ThekernelT is non-negativeand satisfies the normalization condition T(v,v′,y)dv = 1. V Toconnectthiswiththechemotaxisequation(3),wehaveRtoderiveanevolution equationforthemacroscopicdensityofindividuals n(x,t)= p(x,v,y,t)dvdy. (14) Z Z Y V The problemturnsoutto be tractable forsystems thatexecute“run-and-tumble” motion,suchasE.coli.Toillustratethis,assumeforsimplicitythatthemotionis restricted to 1D, the signal is time-independent,the speed s is constant, and the turningphaseisneglected;thegeneralcasesaretreatedelsewhere[17,18].Letp+ (resp.p−)bethedensityofindividualsmovingtotheright(resp.left).Then(13) leadstoatelegraphprocessdescribedbythehyperbolicsystem ∂p+ ∂p+ m ∂ +s + f (y,S)p+ =λ(y) −p++p− , (15) i ∂t ∂x ∂y Xi=1 i (cid:2) (cid:3) (cid:2) (cid:3) − − m ∂p ∂p ∂ −s + f (y,S)p− =λ(y) p+−p− . (16) i ∂t ∂x ∂y Xi=1 i (cid:2) (cid:3) (cid:2) (cid:3) TaxisEquationsforAmoeboidCells 9 Theessentialcomponentsoftheinternaldynamicsinthebacterialcontextarefast excitation,followedbysloweradaptationandreturntothebasalturningrate,and theseaspectsarecapturedinthesystem[39] dy1 g(S(x))−(y1+y2) dy2 g(S(x))−y2 = and = . (17) dt τ dt τ e a Hereg encodesthefirststepofsignaltransduction,S isthechemoattractant,and τ andτ aretimeconstantsforexcitationandadaptation,respectively.Thecom- e a ponent y1 adapts perfectly to constant stimuli, i.e., the steady state response is independent of the magnitude of the stimulus S. To obtain a macroscopic limit equationforthetotaldensityn(x,t)weincorporatethevariablesy intothestate i andderiveasystemoffourmomentequationsforvariousdensitiesandfluxes[17]. Assumingthattheturningratehastheformλ(y) = λ0−by1,forλ0 > 0,b > 0, we show that this system reduces to the classical chemotaxis equation for large times ∂n ∂ s2 ∂n bs2τ g′(S(x)) a ′ = − S (x)n (18) ∂t ∂x(cid:18)2λ0 ∂x (cid:20)λ0(1+2λ0τa)(1+2λ0τe)(cid:21) (cid:19) where the chemotactic sensitivity is given explicitly in terms of parameters that characterize signal transduction and response. We have only used the simplified dynamics (17) to obtain the macroscopic chemotactic sensitivity, but this model capturestheessentialaspectsforbacterialtaxis[46,17].Anopenproblemishow oneextractstheelementaryprocessesofexcitationandadaptationfromacomplex networkofthetypeusedforsignaltransductioninE.coli.Finally,letusnotethat theglobalexistenceresultsfor(13)whichiscoupledwiththeevolutionequation fortheextracellularsignalwererecentlygivenin[14]. Equation (18) was derived for cells such as bacteria, that use the “run-and- tumble”strategy,andourobjectiveinthispaperistoattemptasimilarreduction of the transport equation to a chemotaxis equation for more complex amoeboid eukaryoticcells.Inthefollowingsectionweintroducethegeneralsetupforstudy- ing amoeboidtaxis. Then we study several “caricature” or “cartoon”models for amoeboidchemotaxiswiththeobjectiveofderivingmacroscopicpopulation-level equationsin eachcase. We start with a modelwhichcan captureinterestingfea- turesofeukaryoticmotilitywithoutintroducingadditionalinternalstatevariables, andthenaddinternalstatevariablestothemodel. 2. Amoeboidtaxiswithinternalvariables Afundamentalassumptionintheuseofvelocity-jumpprocesses[37]todescribe cellmotionisthatthejumpsareinstantaneous,andthereforetheforcesareDirac distributions.Thisapproximatesthecaseinwhichverylargeforcesactoververy shorttime intervals,andevenif one incorporatesa restingor tumblingphase, as was done in [38], the macroscopic description of motion is unchanged. This is appropriatefortheanalysisofbacterialmotion(andothersystemsthatusea“run- and-tumble”strategy),assummarizedabove,sincetheeffectoftheexternalsignal 10 R.ErbanandH.G.Othmer is to changethe rotationalbehaviorof the flagella, and not, so far as it is under- stood, to affect the force generation mechanism itself. However, the situation is verydifferentwhen analyzingthe movementof crawlingcells, for here the con- troloftheforce-generationmachineryisanessentialcomponentoftheresponse. WhileamoeboidcellssuchasDdextendpseudopods“randomly”intheabsenceof signals,thedirectionofextensionistightlycontrolledinthepresenceofadirected external signal, and the direction in which forces are exerted on the substrate is controlledviathelocationofcontactswiththesubstrate.Thereforeitisappropri- atetoincorporatetheforce-generationmachineryaspartoftheinternalstate,and asafirststepwecondensethisallintoadescriptionofhowtheforceexertedbya cellonitssurroundings(andvice-versa)dependsontheexternalsignal.Inreality amoeboidcells are also highly deformable,and a completetheoreticaltreatment oftaxisatthesinglecelllevelhastotakethisintoaccount.Thisiscurrentlyunder investigationbutwillnotbepursuedhere;insteadweonlydescribethemotionof thecentroidofthecell.However,thefollowingframeworkissufficientlygeneral toallowdistributedinternalvariableswithinacell. Hereafterwe use y as it appearsin (19) to denote the chemicalvariablesin- volvedinsignaltransduction,controlofactinpolymerization,etc,andwedenote theforceperunitmassonthecentroidofacellbyF(x,v,y).Thereforetheinter- nalstateequationsaregivenby dy =G(y,S) (19) dt andthevelocityevolvesaccordingto dv =F(x,v,y). (20) dt HereG :Y×S→YisingeneralamappingbetweensuitableBanachspacesand F : RN ×RN ×Y → RN whereN = 1,2,or3isthedimensionofthephysi- calspace.Thisgeneralityisneededbecausethevariableycanincludequantities that depend on the location in the cell or on the membrane, and which may, for example,satisfyareaction-diffusionequationoranotherevolutionequation. The cell is therefore described by the position and velocity of its centroid, and the internal state y ∈ Y. In some importantcases described later there is a projectionP :Y→Z⊂YfromYontoasuitablefinite-dimensionalsubspaceZ, obtainedforexamplebyconsideringthefirstfewmodesinasuitablebasisforY, suchthat P(G(y,S))=G(z,S) and F(x,v,y)=F(x,v,z), where z≡Py. (21) HereG(·,S):Z→ZandF(·,·,·):RN×RN×Z→RN aremappingsbetween finite-dimensionalspaces.ThefirstequalitydefinesthefunctionG,thoughitmay ofcoursebedifficulttofindwhenGisnonlinear.ThefunctionFisexplicitlygiven bythesecondequalitywhenthereductionispossible. GivenasuitablechoiceoftheprojectionP,wecanreducetheinfinite-dimen- sionalsystem(19)–(20)tothefollowingsetofordinarydifferentialequationsin

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