def flux_sensitivity(self, metaboliteConcentrations, externalMoleculeLevels, catalyzedReactionBounds, targets, coefficient): """ Sensitivity performed with flux_sensitivity variant simulations. Disables kinetic constraints one by one to determine impact on certain fluxes. Args: metaboliteConcentrations (ndarray[float] with mol/volume units): concentrations for all metabolites externalMoleculeLevels (ndarray[float]): limits for external molecule exchanges catalyzedReactionBounds (ndarray[float]): max limit for each enzyme catalyzed reaction targets (ndarray[float]): flux target for each reaction with a kinetic constraint coefficient (float with mass-time/volume units): conversion factor for fluxes """ succ_rxn = 'SUCCINATE-DEHYDROGENASE-UBIQUINONE-RXN-SUC/UBIQUINONE-8//FUM/CPD-9956.31.' iso_rxn = 'ISOCITDEH-RXN' succ_flux = [] iso_flux = [] for rxn in self.kineticsConstrainedReactions: fba = FluxBalanceAnalysis(**self.fbaObjectOptions) fba.enableKineticTargets() fba.setInternalMoleculeLevels( metaboliteConcentrations.asNumber(COUNTS_UNITS / VOLUME_UNITS)) self._setExternalMoleculeLevels(fba, externalMoleculeLevels, metaboliteConcentrations) flux = (self.ngam * coefficient).asNumber(COUNTS_UNITS / VOLUME_UNITS) fba.setReactionFluxBounds(fba._reactionID_NGAM, lowerBounds=flux, upperBounds=flux) flux = self.currentPolypeptideElongationEnergy.asNumber( COUNTS_UNITS / VOLUME_UNITS) fba.setReactionFluxBounds( self.fba._reactionID_polypeptideElongationEnergy, lowerBounds=flux, upperBounds=flux) fba.setReactionFluxBounds(self.reactionsWithCatalystsList, upperBounds=catalyzedReactionBounds, raiseForReversible=False) fba.setKineticTarget(self.kineticsConstrainedReactions, targets, raiseForReversible=False) fba.disableKineticTargets(rxn) # Fluxes of interest for each disabled constraint succ_flux += [ ((COUNTS_UNITS / VOLUME_UNITS) * fba.getReactionFluxes(succ_rxn)[0] / coefficient).asNumber( units.mmol / units.g / units.h) ] iso_flux += [ ((COUNTS_UNITS / VOLUME_UNITS) * fba.getReactionFluxes(iso_rxn)[0] / coefficient).asNumber( units.mmol / units.g / units.h) ] # Fluxes of interest for the original simulation succ_flux += [((COUNTS_UNITS / VOLUME_UNITS) * self.fba.getReactionFluxes(succ_rxn)[0] / coefficient).asNumber(units.mmol / units.g / units.h)] iso_flux += [((COUNTS_UNITS / VOLUME_UNITS) * self.fba.getReactionFluxes(iso_rxn)[0] / coefficient).asNumber(units.mmol / units.g / units.h)] self.writeToListener('FBAResults', 'succinate_flux_sensitivity', np.array(succ_flux)) self.writeToListener('FBAResults', 'isocitrate_flux_sensitivity', np.array(iso_flux))
class Metabolism(wholecell.processes.process.Process): """ Metabolism """ _name = "Metabolism" # Constructor def __init__(self): super(Metabolism, self).__init__() # Construct object graph def initialize(self, sim, sim_data): super(Metabolism, self).initialize(sim, sim_data) # Load constants self.nAvogadro = sim_data.constants.nAvogadro self.cellDensity = sim_data.constants.cellDensity self.ngam = sim_data.constants.nonGrowthAssociatedMaintenance self.exchangeConstraints = sim_data.process.metabolism.exchangeConstraints self.getBiomassAsConcentrations = sim_data.mass.getBiomassAsConcentrations self.nutrientToDoublingTime = sim_data.nutrientToDoublingTime # Create objective for homeostatic constraints nutrients_time_series_label = sim_data.external_state.environment.nutrients_time_series_label concDict = sim_data.process.metabolism.concentrationUpdates.concentrationsBasedOnNutrients( sim_data.external_state.environment. nutrients_time_series[nutrients_time_series_label][0][1]) self.concModificationsBasedOnCondition = self.getBiomassAsConcentrations( sim_data.conditionToDoublingTime[sim_data.condition]) concDict.update(self.concModificationsBasedOnCondition) self.homeostaticObjective = dict( (key, concDict[key].asNumber(COUNTS_UNITS / VOLUME_UNITS)) for key in concDict) # Load initial mass initWaterMass = sim_data.mass.avgCellWaterMassInit initDryMass = sim_data.mass.avgCellDryMassInit initCellMass = initWaterMass + initDryMass energyCostPerWetMass = sim_data.constants.darkATP * initDryMass / initCellMass # Setup molecules in external environment that can be exchanged externalExchangedMolecules = sim_data.external_state.environment.nutrient_data[ "secretionExchangeMolecules"] self.metaboliteNamesFromNutrients = set() for time, nutrientsLabel in sim_data.external_state.environment.nutrients_time_series[ nutrients_time_series_label]: externalExchangedMolecules += sim_data.external_state.environment.nutrient_data[ "importExchangeMolecules"][nutrientsLabel] self.metaboliteNamesFromNutrients.update( sim_data.process.metabolism.concentrationUpdates. concentrationsBasedOnNutrients( nutrientsLabel, sim_data.process.metabolism.nutrientsToInternalConc)) externalExchangedMolecules = sorted(set(externalExchangedMolecules)) self.metaboliteNamesFromNutrients = sorted( self.metaboliteNamesFromNutrients) moleculeMasses = dict( zip( externalExchangedMolecules, sim_data.getter.getMass(externalExchangedMolecules).asNumber( MASS_UNITS / COUNTS_UNITS))) # Data structures to compute reaction bounds based on enzyme presence/absence self.catalystsList = sim_data.process.metabolism.catalystsList self.reactionsWithCatalystsList = sim_data.process.metabolism.reactionCatalystsList self.reactionCatalystsDict = sim_data.process.metabolism.reactionCatalysts catalysisMatrixI = sim_data.process.metabolism.catalysisMatrixI catalysisMatrixJ = sim_data.process.metabolism.catalysisMatrixJ catalysisMatrixV = sim_data.process.metabolism.catalysisMatrixV shape = (catalysisMatrixI.max() + 1, catalysisMatrixJ.max() + 1) self.catalysisMatrix = csr_matrix( (catalysisMatrixV, (catalysisMatrixI, catalysisMatrixJ)), shape=shape) self.catalyzedReactionBoundsPrev = np.inf * np.ones( len(self.reactionsWithCatalystsList)) # Function to compute reaction targets based on kinetic parameters and molecule concentrations self.getKineticConstraints = sim_data.process.metabolism.getKineticConstraints # Remove disabled reactions so they don't get included in the FBA problem setup if hasattr( sim_data.process.metabolism, "kineticTargetShuffleRxns" ) and sim_data.process.metabolism.kineticTargetShuffleRxns is not None: self.kineticsConstrainedReactions = sim_data.process.metabolism.kineticTargetShuffleRxns self.active_constraints_mask = np.ones(len( self.kineticsConstrainedReactions), dtype=bool) else: constrainedReactionList = sim_data.process.metabolism.constrainedReactionList constraintsToDisable = sim_data.process.metabolism.constraintsToDisable self.active_constraints_mask = np.array([ (rxn not in constraintsToDisable) for rxn in constrainedReactionList ]) self.kineticsConstrainedReactions = list( np.array(constrainedReactionList)[ self.active_constraints_mask]) self.kineticsEnzymesList = sim_data.process.metabolism.enzymeIdList self.kineticsSubstratesList = sim_data.process.metabolism.kineticsSubstratesList constraintToReactionMatrixI = sim_data.process.metabolism.constraintToReactionMatrixI constraintToReactionMatrixJ = sim_data.process.metabolism.constraintToReactionMatrixJ constraintToReactionMatrixV = sim_data.process.metabolism.constraintToReactionMatrixV shape = (constraintToReactionMatrixI.max() + 1, constraintToReactionMatrixJ.max() + 1) self.constraintToReactionMatrix = np.zeros(shape, np.float64) self.constraintToReactionMatrix[ constraintToReactionMatrixI, constraintToReactionMatrixJ] = constraintToReactionMatrixV self.constraintIsKcatOnly = sim_data.process.metabolism.constraintIsKcatOnly # Set solver and kinetic objective weight (lambda) solver = sim_data.process.metabolism.solver kinetic_objective_weight = sim_data.process.metabolism.kinetic_objective_weight # Disable kinetics completely if weight is 0 or specified in file above self.use_kinetics = True if not USE_KINETICS or kinetic_objective_weight == 0: self.use_kinetics = False kinetic_objective_weight = 0 # Set up FBA solver # reactionRateTargets value is just for initialization, it gets reset each timestep during evolveState self.fbaObjectOptions = { "reactionStoich": sim_data.process.metabolism.reactionStoich, "externalExchangedMolecules": externalExchangedMolecules, "objective": self.homeostaticObjective, "objectiveType": "homeostatic_kinetics_mixed", "objectiveParameters": { "kineticObjectiveWeight": kinetic_objective_weight, "reactionRateTargets": { reaction: 1 for reaction in self.kineticsConstrainedReactions }, "oneSidedReactionTargets": [], }, "moleculeMasses": moleculeMasses, "secretionPenaltyCoeff": sim_data.constants. secretion_penalty_coeff, # The "inconvenient constant"--limit secretion (e.g., of CO2) "solver": solver, "maintenanceCostGAM": energyCostPerWetMass.asNumber(COUNTS_UNITS / MASS_UNITS), "maintenanceReaction": sim_data.process.metabolism.maintenanceReaction, } if not self.use_kinetics: self.fbaObjectOptions["objectiveType"] = "homeostatic" self.fba = FluxBalanceAnalysis(**self.fbaObjectOptions) self.internalExchangeIdxs = np.array([ self.metaboliteNamesFromNutrients.index(x) for x in self.fba.getOutputMoleculeIDs() ]) # Disable all rates during burn-in if self.use_kinetics: if KINETICS_BURN_IN_PERIOD > 0: self.fba.disableKineticTargets() self.burnInComplete = False else: self.burnInComplete = True # Values will get updated at each time point self.currentNgam = 1 * (COUNTS_UNITS / VOLUME_UNITS) self.currentPolypeptideElongationEnergy = 1 * (COUNTS_UNITS / VOLUME_UNITS) # External molecules self.externalMoleculeIDs = self.fba.getExternalMoleculeIDs() # Views self.metaboliteNames = self.fba.getOutputMoleculeIDs() self.metabolites = self.bulkMoleculesView( self.metaboliteNamesFromNutrients) self.catalysts = self.bulkMoleculesView(self.catalystsList) self.kineticsEnzymes = self.bulkMoleculesView(self.kineticsEnzymesList) self.kineticsSubstrates = self.bulkMoleculesView( self.kineticsSubstratesList) outputMoleculeIDs = self.fba.getOutputMoleculeIDs() assert outputMoleculeIDs == self.fba.getInternalMoleculeIDs() # Set the priority to a low value self.bulkMoleculesRequestPriorityIs(REQUEST_PRIORITY_METABOLISM) self.AAs = [ x[:-3] for x in sorted(sim_data.amino_acid_1_to_3_ordered.values()) ] self.shuffleIdxs = None if hasattr( sim_data.process.metabolism, "kineticTargetShuffleIdxs" ) and sim_data.process.metabolism.kineticTargetShuffleIdxs is not None: self.shuffleIdxs = sim_data.process.metabolism.kineticTargetShuffleIdxs self.shuffleCatalyzedIdxs = None if hasattr( sim_data.process.metabolism, "catalystShuffleIdxs" ) and sim_data.process.metabolism.catalystShuffleIdxs is not None: self.shuffleCatalyzedIdxs = sim_data.process.metabolism.catalystShuffleIdxs self.run_flux_sensitivity = getattr(sim_data.process.metabolism, 'run_flux_sensitivity', False) def calculateRequest(self): self.metabolites.requestAll() self.catalysts.requestAll() self.kineticsEnzymes.requestAll() self.kineticsSubstrates.requestAll() def evolveState(self): metaboliteCountsInit = self.metabolites.counts() cellMass = (self.readFromListener("Mass", "cellMass") * units.fg) dryMass = (self.readFromListener("Mass", "dryMass") * units.fg) cellVolume = cellMass / self.cellDensity countsToMolar = 1 / (self.nAvogadro * cellVolume) current_nutrients = self._external_states['Environment'].nutrients self.concModificationsBasedOnCondition = self.getBiomassAsConcentrations( self.nutrientToDoublingTime.get( current_nutrients, self.nutrientToDoublingTime["minimal"])) # Coefficient to convert between flux (mol/g DCW/hr) basis and concentration (M) basis coefficient = dryMass / cellMass * self.cellDensity * ( self.timeStepSec() * units.s) # Set external molecule levels externalMoleculeLevels, newObjective = self.exchangeConstraints( self.externalMoleculeIDs, coefficient, COUNTS_UNITS / VOLUME_UNITS, current_nutrients, self.concModificationsBasedOnCondition, ) updatedObjective = False if newObjective != None and newObjective != self.homeostaticObjective: # Build new fba instance with new objective self.fbaObjectOptions["objective"] = newObjective self.fba = FluxBalanceAnalysis(**self.fbaObjectOptions) self.internalExchangeIdxs = np.array([ self.metaboliteNamesFromNutrients.index(x) for x in self.fba.getOutputMoleculeIDs() ]) self.homeostaticObjective = newObjective updatedObjective = True # After completing the burn-in, enable kinetic rates if self.use_kinetics and (not self.burnInComplete) and ( self._sim.time() > KINETICS_BURN_IN_PERIOD): self.burnInComplete = True self.fba.enableKineticTargets() # Allow flexibility for solver in first time step after an environment shift if updatedObjective: self.fba.disableKineticTargets() self.burnInComplete = False # Find metabolite concentrations from metabolite counts metaboliteConcentrations = countsToMolar * metaboliteCountsInit[ self.internalExchangeIdxs] # Make a dictionary of metabolite names to metabolite concentrations metaboliteConcentrationsDict = dict( zip(self.metaboliteNames, metaboliteConcentrations)) self.fba.setInternalMoleculeLevels( metaboliteConcentrations.asNumber(COUNTS_UNITS / VOLUME_UNITS)) # Set external molecule levels self._setExternalMoleculeLevels(self.fba, externalMoleculeLevels, metaboliteConcentrations) # Change the ngam and polypeptide elongation energy penalty only if they are noticably different from the current value ADJUSTMENT_RATIO = .01 # Calculate new NGAM and update if necessary self.newNgam = self.ngam * coefficient ngam_diff = np.abs(self.currentNgam.asNumber() - self.newNgam.asNumber()) / ( self.currentNgam.asNumber() + 1e-20) if ngam_diff > ADJUSTMENT_RATIO: self.currentNgam = self.newNgam flux = (self.ngam * coefficient).asNumber(COUNTS_UNITS / VOLUME_UNITS) self.fba.setReactionFluxBounds(self.fba._reactionID_NGAM, lowerBounds=flux, upperBounds=flux) # Calculate GTP usage based on how much was needed in polypeptide elongation in previous step and update if necessary newPolypeptideElongationEnergy = countsToMolar * 0 if hasattr(self._sim.processes["PolypeptideElongation"], "gtpRequest"): newPolypeptideElongationEnergy = countsToMolar * self._sim.processes[ "PolypeptideElongation"].gtpRequest poly_diff = np.abs( (self.currentPolypeptideElongationEnergy.asNumber() - newPolypeptideElongationEnergy.asNumber())) / ( self.currentPolypeptideElongationEnergy.asNumber() + 1e-20) if poly_diff > ADJUSTMENT_RATIO: self.currentPolypeptideElongationEnergy = newPolypeptideElongationEnergy flux = self.currentPolypeptideElongationEnergy.asNumber( COUNTS_UNITS / VOLUME_UNITS) self.fba.setReactionFluxBounds( self.fba._reactionID_polypeptideElongationEnergy, lowerBounds=flux, upperBounds=flux) # Constrain reactions based on absence of catalysts ## Read counts for catalysts and enzymes (catalysts with kinetics constraints) catalystsCountsInit = self.catalysts.counts() ## Set hard upper bounds constraints based on enzyme presence (infinite upper bound) or absence (upper bound of zero) catalyzedReactionBounds = np.inf * np.ones( len(self.reactionsWithCatalystsList)) rxnPresence = self.catalysisMatrix.dot(catalystsCountsInit) catalyzedReactionBounds[rxnPresence == 0] = 0 if self.shuffleCatalyzedIdxs is not None: catalyzedReactionBounds = catalyzedReactionBounds[ self.shuffleCatalyzedIdxs] ## Only update reaction limits that are different from previous time step updateIdxs = np.where( catalyzedReactionBounds != self.catalyzedReactionBoundsPrev)[0] updateRxns = [ self.reactionsWithCatalystsList[idx] for idx in updateIdxs ] updateVals = catalyzedReactionBounds[updateIdxs] self.fba.setReactionFluxBounds(updateRxns, upperBounds=updateVals, raiseForReversible=False) self.catalyzedReactionBoundsPrev = catalyzedReactionBounds # Constrain reactions based on kinetic values kineticsEnzymesCountsInit = self.kineticsEnzymes.counts() kineticsEnzymesConcentrations = countsToMolar * kineticsEnzymesCountsInit kineticsSubstratesCountsInit = self.kineticsSubstrates.counts() kineticsSubstratesConcentrations = countsToMolar * kineticsSubstratesCountsInit ## Set target fluxes for reactions based on their most relaxed constraint constraintValues = self.getKineticConstraints( kineticsEnzymesConcentrations.asNumber(units.umol / units.L), kineticsSubstratesConcentrations.asNumber(units.umol / units.L), ) reactionTargets = (units.umol / units.L / units.s) * np.max( self.constraintToReactionMatrix * constraintValues, axis=1) ## Shuffle parameters (only performed in very specific cases) if self.shuffleIdxs is not None: reactionTargets = (units.umol / units.L / units.s ) * reactionTargets.asNumber()[self.shuffleIdxs] ## Record which constraint was used, add constraintToReactionMatrix to ensure the index is one of the constraints if multiplication is 0 reactionConstraint = np.argmax( self.constraintToReactionMatrix * constraintValues + self.constraintToReactionMatrix, axis=1) ## Calculate reaction flux target for current time step targets = (TIME_UNITS * self.timeStepSec() * reactionTargets).asNumber( COUNTS_UNITS / VOLUME_UNITS)[self.active_constraints_mask] ## Set kinetic targets only if kinetics is enabled if self.use_kinetics and self.burnInComplete: self.fba.setKineticTarget(self.kineticsConstrainedReactions, targets, raiseForReversible=False) # Runs sensitivity if option is set # Needs to be after all FBA problem setup but will not affect simulation if self.run_flux_sensitivity: self.flux_sensitivity(metaboliteConcentrations, externalMoleculeLevels, catalyzedReactionBounds, targets, coefficient) # Solve FBA problem and update metabolite counts deltaMetabolites = ( 1 / countsToMolar) * (COUNTS_UNITS / VOLUME_UNITS * self.fba.getOutputMoleculeLevelsChange()) metaboliteCountsFinal = np.zeros_like(metaboliteCountsInit) metaboliteCountsFinal[self.internalExchangeIdxs] = np.fmax( stochasticRound( self.randomState, metaboliteCountsInit[self.internalExchangeIdxs] + deltaMetabolites.asNumber()), 0).astype(np.int64) self.metabolites.countsIs(metaboliteCountsFinal) exFluxes = ((COUNTS_UNITS / VOLUME_UNITS) * self.fba.getExternalExchangeFluxes() / coefficient).asNumber(units.mmol / units.g / units.h) # Write outputs to listeners self.writeToListener("FBAResults", "deltaMetabolites", metaboliteCountsFinal - metaboliteCountsInit) self.writeToListener("FBAResults", "reactionFluxes", self.fba.getReactionFluxes() / self.timeStepSec()) self.writeToListener("FBAResults", "externalExchangeFluxes", exFluxes) self.writeToListener("FBAResults", "objectiveValue", self.fba.getObjectiveValue()) self.writeToListener("FBAResults", "shadowPrices", self.fba.getShadowPrices(self.metaboliteNames)) self.writeToListener( "FBAResults", "reducedCosts", self.fba.getReducedCosts(self.fba.getReactionIDs())) self.writeToListener("FBAResults", "targetConcentrations", [ self.homeostaticObjective[mol] for mol in self.fba.getHomeostaticTargetMolecules() ]) self.writeToListener("FBAResults", "homeostaticObjectiveValues", self.fba.getHomeostaticObjectiveValues()) self.writeToListener("FBAResults", "kineticObjectiveValues", self.fba.getKineticObjectiveValues()) self.writeToListener("EnzymeKinetics", "metaboliteCountsInit", metaboliteCountsInit) self.writeToListener("EnzymeKinetics", "metaboliteCountsFinal", metaboliteCountsFinal) self.writeToListener("EnzymeKinetics", "enzymeCountsInit", kineticsEnzymesCountsInit) self.writeToListener( "EnzymeKinetics", "metaboliteConcentrations", metaboliteConcentrations.asNumber(COUNTS_UNITS / VOLUME_UNITS)) self.writeToListener( "EnzymeKinetics", "countsToMolar", countsToMolar.asNumber(COUNTS_UNITS / VOLUME_UNITS)) self.writeToListener( "EnzymeKinetics", "actualFluxes", self.fba.getReactionFluxes(self.kineticsConstrainedReactions) / self.timeStepSec()) self.writeToListener("EnzymeKinetics", "targetFluxes", targets / self.timeStepSec()) self.writeToListener("EnzymeKinetics", "reactionConstraint", reactionConstraint[self.active_constraints_mask]) def flux_sensitivity(self, metaboliteConcentrations, externalMoleculeLevels, catalyzedReactionBounds, targets, coefficient): """ Sensitivity performed with flux_sensitivity variant simulations. Disables kinetic constraints one by one to determine impact on certain fluxes. Args: metaboliteConcentrations (ndarray[float] with mol/volume units): concentrations for all metabolites externalMoleculeLevels (ndarray[float]): limits for external molecule exchanges catalyzedReactionBounds (ndarray[float]): max limit for each enzyme catalyzed reaction targets (ndarray[float]): flux target for each reaction with a kinetic constraint coefficient (float with mass-time/volume units): conversion factor for fluxes """ succ_rxn = 'SUCCINATE-DEHYDROGENASE-UBIQUINONE-RXN-SUC/UBIQUINONE-8//FUM/CPD-9956.31.' iso_rxn = 'ISOCITDEH-RXN' succ_flux = [] iso_flux = [] for rxn in self.kineticsConstrainedReactions: fba = FluxBalanceAnalysis(**self.fbaObjectOptions) fba.enableKineticTargets() fba.setInternalMoleculeLevels( metaboliteConcentrations.asNumber(COUNTS_UNITS / VOLUME_UNITS)) self._setExternalMoleculeLevels(fba, externalMoleculeLevels, metaboliteConcentrations) flux = (self.ngam * coefficient).asNumber(COUNTS_UNITS / VOLUME_UNITS) fba.setReactionFluxBounds(fba._reactionID_NGAM, lowerBounds=flux, upperBounds=flux) flux = self.currentPolypeptideElongationEnergy.asNumber( COUNTS_UNITS / VOLUME_UNITS) fba.setReactionFluxBounds( self.fba._reactionID_polypeptideElongationEnergy, lowerBounds=flux, upperBounds=flux) fba.setReactionFluxBounds(self.reactionsWithCatalystsList, upperBounds=catalyzedReactionBounds, raiseForReversible=False) fba.setKineticTarget(self.kineticsConstrainedReactions, targets, raiseForReversible=False) fba.disableKineticTargets(rxn) # Fluxes of interest for each disabled constraint succ_flux += [ ((COUNTS_UNITS / VOLUME_UNITS) * fba.getReactionFluxes(succ_rxn)[0] / coefficient).asNumber( units.mmol / units.g / units.h) ] iso_flux += [ ((COUNTS_UNITS / VOLUME_UNITS) * fba.getReactionFluxes(iso_rxn)[0] / coefficient).asNumber( units.mmol / units.g / units.h) ] # Fluxes of interest for the original simulation succ_flux += [((COUNTS_UNITS / VOLUME_UNITS) * self.fba.getReactionFluxes(succ_rxn)[0] / coefficient).asNumber(units.mmol / units.g / units.h)] iso_flux += [((COUNTS_UNITS / VOLUME_UNITS) * self.fba.getReactionFluxes(iso_rxn)[0] / coefficient).asNumber(units.mmol / units.g / units.h)] self.writeToListener('FBAResults', 'succinate_flux_sensitivity', np.array(succ_flux)) self.writeToListener('FBAResults', 'isocitrate_flux_sensitivity', np.array(iso_flux)) # limit amino acid uptake to what is needed to meet concentration objective to prevent use as carbon source def _setExternalMoleculeLevels(self, fba, externalMoleculeLevels, metaboliteConcentrations): for aa in self.AAs: if aa + "[p]" in fba.getExternalMoleculeIDs(): idx = self.externalMoleculeIDs.index(aa + "[p]") elif aa + "[c]" in fba.getExternalMoleculeIDs(): idx = self.externalMoleculeIDs.index(aa + "[c]") else: continue concDiff = self.homeostaticObjective[ aa + "[c]"] - metaboliteConcentrations[ self.metaboliteNames.index(aa + "[c]")].asNumber( COUNTS_UNITS / VOLUME_UNITS) if concDiff < 0: concDiff = 0 if externalMoleculeLevels[idx] > concDiff: externalMoleculeLevels[idx] = concDiff fba.setExternalMoleculeLevels(externalMoleculeLevels)