Red Blood Cell Homeostasis: Pharmacological Interventions to Explore Biochemical, Morphological and Mechanical Properties.

Duringtheirpassagethroughthecirculation,redbloodcells(RBCs)encounterseverephysiologicalconditionsconsistingofmechanicalstress,oxidativedamageandfastchangesinionicandosmoticconditions.Inordertosurvivefor120days,RBCsadapttotheirsurroundingsbysubtleregulationofmembraneorganizationandmetabolism.RBChomeostasisdependsoninteractionsbetweentheintegralmembraneproteinband3withothermembraneandcytoskeletalproteins,andwithkeyenzymesofvariousmetabolicpathways.Theseinteractionsareregulatedbythebindingofdeoxyhemoglobintoband3,andbyasignalingnetworkrevolvingaroundLynkinaseandSrcfamilykinase-mediatedphosphorylationofband3.Hereweshowthatmanipulationoftheinteractionbetweenthelipidbilayerandthecytoskeleton,usingvariouspharmacologicalagentsthatinterferewithprotein-proteininteractionsandmembranelipidorganization,hasvariouseffectson:(1)morphology,asshownbyhighresolutionmicroscopyandquantitativeimageanalysis;(2)organizationofmembraneproteins,asindicatedbyimmunofluorescenceconfocalmicroscopyandquantitativeaswellasqualitativeanalysisofvesiclegeneration;(3)membranelipidorganization,asindicatedbyflowcytometricanalysisofphosphatidylserineexposure;(4)deformability,asassessedincapillary-mimickingcircumstancesusingamicrofluidicssystem;(5)deformabilityasdeterminedusingaspleen-mimickingdevice;(6)metabolicactivityasindicatedbymetabolomics.Ourdatashowthatthereisacomplexrelationshipbetweenredcellmorphology,membraneorganizationanddeformability.Also,ourdatashowthatredbloodcellshavearelativelyhighresistancetodisturbanceofmembraneorganizationinvitro,whichmayreflecttheircapacitytowithstandmechanical,oxidativeandosmoticstressinvivo.