Dynamic Energy Budget theory

Dynamic Energy Budget theory for metabolic organization of life Bas Kooijman Dept of Theoretical Biology Vrije Universiteit, Amsterdam http://www.bio.vu.nl/thb/deb/ embryo adult juvenile Leiden, 2004/02/06

Dynamic Energy Budget theory • First principles, quantitative, axiomatic set up • Aim: Biological equivalent of Theoretical Physics • Primary target: the individual with consequences for • sub-organismal organization • supra-organismal organization • Relationships between levels of organisation • Many popular empirical models are special cases of DEB • Applications in • ecotoxicology • biotechnology • Direct links with empiry

system earth space ecosystem population individual cell time molecule Space-time scales Each process has its characteristic domain of space-time scales When changing the space-time scale, new processes will become important other will become less important Individuals are special because of straightforward energy/mass balances

Empirical special cases of DEB

Some DEB pillars • life cycle perspective of individual as primary target • embryo, juvenile, adult (levels in metabolic organization) • life as coupled chemical transformations (reserve & structure) • time, energy & mass balances • surface area/ volume relationships (spatial structure & transport) • homeostasis (stoichiometric constraints via Synthesizing Units) • syntrophy (basis for symbioses, evolutionary perspective) • intensive/extensive parameters: body size scaling

Surface area/volume interactions • nutrient supply to ecosystems (erosion)  surface area • production (nutrient concentration) volume • food availability for cows: grass weight/ surface area • food availability for daphnids: algal weight/ volume • feeding rate  surface area; maintenance rate  volume • isomorphs: surface area  volume2/3 • V0-morphs: surface area  volume0 • V1-morphs: surface area  volume1 • many active enzyme linked to membranes (surfaces) • substrate and product concentrations linked to volumes

Biomass: reserve(s) + structure(s) • Reserve(s), structure(s): generalized compounds, • mixtures of proteins, lipids, carbohydrates: fixed composition • Compounds in • reserve(s): equal turnover times, no maintenance costs • structure: unequal turnover times, maintenance costs • Reasons to delineate reserve, distinct from structure • metabolic memory • explanation of respiration patterns (freshly laid eggs don’t respire) • biomass composition depends on growth rate • fluxes are linear sums of assimilation, dissipation and growth • basis of method of indirect calorimetry • explanation of inter-species body size scaling relationships

Biomass composition Data Esener et al 1982, 1983; Kleibsiella on glycerol at 35°C nHE 1.66 nOE 0.422 nNE 0.312 nHV 1.64 nOV 0.379 nNV 0.189 nHW Relative abundance nOW O2 nNW Weight yield, mol.mol-1 Spec prod, mol.mol-1.h-1 Spec growth rate, h-1 CO2 Spec growth rate kE 2.11 h-1 kM 0.021 h-1 yEV 1.135 yXE 1.490 rm 1.05 h-1 g = 1 Spec growth rate, h-1

General assumptions • State variables: structural body mass & reserves • they do not change in composition • Food is converted into faeces • Assimilates derived from food are added to reserves, • which fuel all other metabolic processes • Three categories of processes: • Assimilation: synthesis of (embryonic) reserves • Dissipation: no synthesis of biomass • Growth: synthesis of structural body mass • Product formation: included in these processes (overheads) • Basic life stage patterns • dividers (correspond with juvenile stage) • reproducers • embryo (no feeding • initial structural body mass is negligibly small • initial amount of reserves is substantial) • juvenile (feeding, but no reproduction) • adult (feeding & male/female reproduction)

Specific assumptions • Reserve density hatchling = mother at egg formation • foetuses: embryos unrestricted by energy reserves • Stage transitions: cumulated investment in maturation > threshold • embryo  juvenile initiates feeding • juvenile  adult initiates reproduction & ceases maturation • Somatic & maturity maintenance  structure volume • (but some maintenance costs  surface area) • maturity maintenance does not increase • after a given cumulated investment in maturation • Feeding rate  surface area; fixed food handling time • Partitioning of reserves should not affect dynamics • comp. body mass does not change at steady state (weak homeostasis) • Fixed fraction of catabolic energy is spent on • somatic maintenance + growth (-rule) • Starving individuals: priority to somatic maintenance • do not change reserve dynamics; continue maturation, reproduction. • or change reserve dynamics; cease maturation, reprod.; do or do not shrink in structure

-rule for allocation Ingestion  Respiration  Ingestion rate, 105 cells/h O2 consumption, g/h Length, mm Length, mm Length, mm Reproduction  Cum # of young • 80% of adult budget • to reproduction in daphnids • puberty at 2.5 mm • No change in • ingest., resp., or growth • Where do resources for • reprod come from? Or: • What is fate of resources • in juveniles? Growth: Von Bertalanffy Age, d Age, d

Embryonic development Crocodylus johnstoni, Data from Whitehead 1987 embryo yolk O2 consumption, ml/h weight, g time, d time, d : scaled time l : scaled length e: scaled reserve density g: energy investment ratio ;

Synthesizing units • Generalized enzymes that follow classic enzyme kinetics • E + S  ES  EP  E + P • with two modifications: • back flux is negligibly small • E + S  ES  EP  E + P • specification of transformation is on the basis of • arrival fluxes of substrates rather than concentrations • Concentration: problematic • (intracellular) environments: spatially heterogeneous • state variables in dynamic systems • In spatially homogeneous environments: • arrival fluxes  concentrations

Mitochondria TriCarboxylic Acid cycle Enzymes pass metabolites directly to other enzymes enzymes catalizing transformations 5 & 7: bound to inner membrane (and FAD/FADH2) Net transformation: Acetyl-CoA + 3 NAD+ + FAD + GDP 3- + Pi2- + 2 H2O = 2 CO2 + 3 NADH + FADH2 + GTP 4- + 2 H+ + HS-CoA Dual function of intermediary metabolites building blocks  energy substrate all eukaryotes once possessed mitochondria, most still do Transformations: 1 Oxaloacetate + Acetyl CoA + H2O = Citrate + HSCoA 2 Citrate = cis-Aconitrate + H2O 3 cis-Aconitrate + H2O = Isocitrate 4 Isocitrate + NAD+ = α-Ketoglutarate + CO2+ NADH + H+ 5 α-Ketoglutarate + NAD+ + HSCoA = Succinyl CoA + CO2 + NADH + H+ 6 Succinyl CoA + GDP 3- + Pi 2- + H+ = Succinate + GTP 4- + HSCoA 7 Succinate + FAD = Fumarate + FADH2 8 Fumarate + H2O = Malate 9 Malate + NAD+ = Oxaloacetate + NADH + H+

Pathway  whole cell Fixed stoichiometries for maintenance and growth Variable overall stoichiometry Can a model for pathway kinetics give this result?

Constraints on pathway dynamics Requirements by cell for maintenance and growth: metabolite i enzyme i rejection, production flux spec maintenance flux spec growth rate yield coefficients (fixed) reserve density ME/MV abundance of X0 in E abundance of Si in E, V Supply flux to pathway: Amount of SU i per mol of structure:

Linear pathway SUi SUi+1 = If all metabolites would follow the full pathway: : Product i : Intermediary metabolite i

Chain of length 1 Change in Unbounded fraction Steady state Unbounded fraction Production flux

Closed handshaking at all nodes Change in Unbounded fractions Steady state Unbounded fractions Production fluxes

Open handshaking at all nodes Change in Unbounded fractions Steady state Unbounded fractions Production fluxes

General handshaking Change in Unbounded fractions Steady state Unbounded fractions Production fluxes Rejection fluxes

Numerical matching for n=4 0 4 1 3 2 2 3 Unbounded fraction 4 Product flux 1 Spec growth rate • = 0.73, 0.67, 0.001, 0.27 handshaking • = 0.67, 0.91, 0.96, 0.97 binding prob k = 0.12, 0.19, 0.54, 0.19 dissociation nSE = 0.032,0.032,0.032,0.032 # in reserve nSV = 0.045,0.045,0.045,0.045 # in structure yEV= 1.2 res/struct kE= 0.4 res turnover jEM = 0.02 maint flux n0E = 0.05 sub in res 0 Rejected flux 1 2 3 Spec growth rate

Matching pathway  whole cell No exact match possible between production of products and intermediary metabolites by pathway and requirements by the cell But very close approximation is possible by tuning abundance parameters and/or binding and handshaking parameters Best approximation requires all four tuning parameters per node growth-dependent reserve abundance plays a key role in tuning Kooijman, S. A. L. M. and Segel, L. A. (2004) How growth affects the fate of cellular substrates. Bull. Math. Biol. (to appear)

Simultaneous Substrate Processing Flux of C: production production Chemical reaction: 1A + 1B 1C Poisson arrival events for molecules A and B blocked time intervals • acceptation event ¤ rejection event

Simultaneous Nutrient Limitation B12 content, 10-21 mol/cell P content, fmol/cell Specific growth rate of Pavlova lutheri as function of intracellular phosphorus and vitamin B12 at 20 ºC Data from Droop 1974 Note the absence of high contents for both compounds due to damming up of reserves, and low contents in structure (at zero growth)

Product Formation According to Dynamic Energy Budget theory: Product formation rate = wA. Assimilation rate + wM. Maintenance rate + wG . Growth rate For pyruvate: wG<0 ethanol pyruvate, mg/l pyruvate glycerol, ethanol, g/l glycerol Applies to all products, heat & non-limiting substrates Indirect calorimetry (Lavoisier, 1780): heat = wO JO + wC JC + wN JN No reserve: 2-dim basis for product formation throughput rate, h-1 Glucose-limited growth of Saccharomyces Data from Schatzmann, 1975

Symbiosis substrate product Product formation is basic to symbioses

Symbiosis substrate substrate Product formation is basic to symbioses

Steps in symbiogenesis Internalization Free-living, clustering Free-living, homogeneous Reserves merge Structures merge

Symbiogenesis • symbioses: fundamental organization of life based on syntrophy • ranges from weak to strong interactions; basis of biodiversity • symbiogenesis: evolution of eukaryotes (mitochondria, plastids) • DEB model is closed under symbiogenesis: • it is possible to model symbiogenesis of two initially independently • living populations that follow the DEB rules by incremental changes • of parameter values such that a single population emerges that • again follows the DEB rules • essential property for models that apply to all organisms • Kooijman, Auger, Poggiale, Kooi 2003 • Quantitative steps in symbiogenesis and the evolution of homeostasis • Biological Reviews78: 435 - 463

Inter-species body size scaling • parameter values tend to co-vary across species • parameters are either intensive or extensive • ratios of extensive parameters are intensive • maximum body length is • allocation fraction to growth + maint. (intensive) • volume-specific maintenance power (intensive) • surface area-specific assimilation power (extensive) • conclusion : (so are all extensive parameters) • write physiological property as function of parameters • (including maximum body weight) • evaluate this property as function of max body weight Kooijman 1986 Energy budgets can explain body size scaling relations J. Theor. Biol.121: 269-282

Scaling of metabolic rate Respiration: contributions from growth and maintenance Weight: contributions from structure and reserve Structure ; = length; endotherms

Scaling of metabolic rate slope = 1 O2 consumption, l/h Log metabolic rate, w 2 curves fitted: endotherms 0.0226 L2 + 0.0185 L3 0.0516 L2.44 slope = 2/3 ectotherms unicellulars Length, cm Log weight, g Intra-species Inter-species (Daphnia pulex)

Von Bertalanffy growth Length, mm Data from Greve, 1972 Arrhenius Age, d

Von Bertalanffy growth rate

PhD Vacancies at Dept Theor Biol VUA 3 in NWO program Computational Life Sciences possibly 6 more in 2004 (EU, STW, NWO) see http://www.bio.vu.nl/thb/ selection date: 11 Feb 2004 International tele-course on DEB applications in ecotoxicology 11 march – 15 april 2004 free registration is open see http://www.bio.vu.nl/thb/

Dynamic Energy Budget theory