dynamic energy budget theory - i
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Dynamic Energy Budget Theory - I. Tânia Sousa with contributions from : Tjalling Jager & Bas Kooijman. A Theory of Metabolism. What is metabolism ?. A Theory of Metabolism. What is metabolism ? - PowerPoint PPT PresentationTRANSCRIPT
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Dynamic Energy Budget Theory - I
Tânia Sousa with contributions from : Tjalling Jager & Bas Kooijman
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What is metabolism?
A Theory of Metabolism
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What is metabolism?
“Using resources (energy and materials) to make new cells, to repair old ones, and to get rid of wastes requires the assemblage of biochemical pathways that we call metabolism. Metabolism is a universal feature of life that links organisms with their environment, and with each other.”
A Theory of Metabolism
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What is metabolism?
“Using resources (energy and materials) to make new cells, to repair old ones, and to get rid of wastes requires the assemblage of biochemical pathways that we call metabolism. Metabolism is a universal feature of life that links organisms with their environment, and with each other.”
What should a theory of metabolism look like?
A Theory of Metabolism
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What is metabolism? What should a theory of metabolism look like?
It should be a qualitative and quantitative description of how organisms use mass and energy to do the things they need to do to stay alive
A Theory of Metabolism
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What is metabolism? What should a theory of metabolism look like?
It should be a qualitative and quantitative description of how organisms use mass and energy to do the things they need to do to stay alive
Which type of questions can a theory of metabolism help you with?
A Theory of Metabolism
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What is metabolism? What should a theory of metabolism look like? Which type of questions can a theory of
metabolism help you with? What is the minimum amount of food (and
habitat) a panda needs to survive? If the temperature of ocean increases by 0.5ºC
what will happen to the survival of the sardine larvae?
A Theory of Metabolism
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Toxicology
Which is the toxicity of the environmental concentration of a compound?
Which are the toxic effects of a compound?
Climate Change Will an increase in 1ºC have a drastic
impact on the distribution range of a species?
Waste water treatment plant What are the necessary conditions to
mantain an healthy microbian comunity in the biological reactors?
Fisheries Management What is the sustainable fishing quota?
Environmental Applications
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Minamata is a small factory town dominated
by the Chisso Corporation. The town faces the Shiranui Sea, and Minamata Bay is part of this sea.
Chisso Corporation started developing plastics, drugs, and perfumes through the use of a chemical called acetaldehyde in 1932. Acetaldehyde is produced using mercury as a compound, and was key component in the production of their products.
In the mid-1950's people begin to notice a "strange disease". Victimswere diagnosed as having a degeneration of their nervous ystems.
Minimata Disaster: Mercury Poisoning
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Human-made toxicants
Wide variety of uses paints, detergents, solvents, pesticides,
pharmaceuticals, polymers, … probably some 100.000 compounds
Chemical industry is BIG business! production value 2009: 3.4 trillion
dollar (3.400.000.000.000 $) equals the GDP of Germany
All are toxic, some are intended to kill fungicides, insecticides, herbicides,
nematicides, molluscicides, …
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Human-made & natural toxicant
Dioxins e.g., 2,3,7,8-TCDD human: paper and fiber bleaching, incineration
of waste, metal smelting, cigarette smoke natural: incomplete combustion of chlorine-
containing things
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Natural toxicants: defense
Oleandrin oleander (Nerium oleander) gastrointestinal and cardiac effects, skin
irritation, CNS effects (coma), death
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Human-made vs. natural
What is the difference? Time scale
major increase after second world war rapid development of new types of molecules
Spatial scale amounts emitted landscape and even global instead of local
Since 1970’s, most countries have programmes for environmental protection ...
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Daphnia reproduction test OECD guideline 211
Ecotoxicology
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Reproduction test
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Reproduction test
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Reproduction test
wait for 21 days …
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Range of Concentrations
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Dose-response plot
EC50
tota
l off
spri
ng
log concentration
NOEC
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If EC50 is the answer …… what was the question?“What is the concentration of chemical X that
leads to 50% effect on the total number of offspring of Daphnia magna (Straus) after 21-day constant exposure under standardised laboratory conditions?”
What does this answer tell me about other situations? (almost) nothing! EC50EC50
tota
loffs
prin
g
log concentration
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Organisms are complex…
Response to stress depends on organism (species, life stage, sex, …) endpoint (size, reproduction, development, …) type of stressor (toxicant, radiation, parasites,
…) exposure scenario (pulsed, multiple stress, …) environmental conditions (temperature, food,
…) etc., etc.
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E.g., effect on reproduction
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E.g., effect on reproduction
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E.g., effect on reproduction
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E.g., effect on reproduction
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E.g., effect on reproduction
To understand an effect on reproduction …• need to know how food is used to make offspring• and how chemicals interfere with this process
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Why is DEB important for
toxicity? The use of DEB theory allows extrapolation of
toxicity test results to other situations and other species
To study the effects of toxicity on life-history traits, DEB follows naturally food is used to fuel all traits over the life cycle toxicants affect DEB parameters should allow extrapolation to untested
conditions it is valuable for environmental risk assessment
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It captures the quantitative aspects of
metabolism at the individual level for all species
Why the hope for generality? universality of physics and evolution
Entropy production is >=0 widespread biological empirical patterns
What is DEB theory?
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Growth as a function of
time
Depends on length at birth, maximum length and growth rate
It was proposed in 1929 by Putter and in 1938 by Von Bertalanffy
A widespread biological empirical fact: Von Bertalanffy growth
trb
BeLLLtL )()(
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A widespread biological empirical
fact:Kleiber’s Law
Metabolism (respiration or heat production) as a function of mass
Metabolism increases with weigth raised to the power 3/4
Max Kleiber originally formulated this basic relationship back in the 1930s.
bM aW
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Indirect calorimetry calculates heat that living
organisms produce from their production of carbon dioxide and nitrogen waste and from their consumption of oxygen.
Lavoisier noted in 1780 that heat production can be predicted from oxygen consumption this way, using multiple regression.
A widespread biological empirical fact:
Indirect Calorimetry
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Consistency with other scientific knowledge
(thermodynamics, evolution, etc) Consistency with empirical data Life-cycle approach: embryo, juvenile and
adult
Occam’s razor: the general model should be as simple as possible (and not more)
Basic concepts in DEB Theory
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The individual: time and spatial scales
Basic Concepts in DEB Theory
Life spanlog10 a
Volumelog10 m3
earth
whale
bacterium
water molecule
life on earth
whalebacterium
ATP molecule
30
20
10
0
-10
-20
-30
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Metabolism in a DEB
individual. The boundary of the
organism Rectangles are state
variables
A DEB organism
ME - Reserve
MV - StructureMH - Maturity
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What defines a DEB organism?
Biomass Mv - Mass of Structure ME - Mass of Reserve
Life-Cycle approach: different life stages MH - Level of Maturity (it represents neither mass
nor energy)
What about other possibles state variables such as age?
DEB model: the State Variables
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These gouramis are from the same nest, they have the same age and lived in the same tankSocial interaction during feeding caused the huge size differenceAge-based models for growth are bound to fail; growth depends on food intake
Why not age as a state variable?
Trichopsis vittatus
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Strong homeostasis
Reserve & Structure have constant aggregated chemical composition
DEB model: Reserve and Structure
Why more than 1 state variable to define the biomass? The aggregated chemical composition of organisms is not
constant – it changes with the growth rate Why not more than 2 state variables to define biomass?
Two are sufficient (in animals and bacteria) to capture the change in aggregated chemical composition with the growth rate
Strong homeostasis -> higher control over metabolism
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Metabolism at the chemical level is very complex
It is not possible to impose mass conservation without modeling all chemical reactions (which is impossible).
Why not use thousands of chemical species and chemical reactions to define
the organism?
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Weak homeostasis
At constant food organisms tend to constant aggregated chemical composition
DEB model: Reserve and Structure
Empirical support: growing biomass tends to constant chemical composition at constant food
Weak homeostasis -> higher control over metabolism
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Life Stages (dark blue) and transitions (light
blue)
Essential switch points for metabolic behavior Birth (start of feeding) Puberty (start of allocation to reproduction)
Switch points sometimes in reversed order (aphids)
DEB model: Maturity
embryo juvenile adult
fertilization birth puberty deathweaning
baby infant
MHb- threshold of maturity at birth
MHp- threshold of maturity at puberty
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Life-stages: Metamorphosis
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MH
b - Extremes in relative maturity at birth
Ommatophoca rossii (Ross Seal) ♂ 1.7-2.1 m, 129-216 kg♀ 1.3-2.2 m, 159-204 kgAt birth: 1 m, 16.5 kg; ab = 270 d
Didelphus marsupiales (Am opossum) ♂, ♀ 0.5 + 0.5 m, 6.5 kgAt birth: <2 g; ab = 8-13 d10-12 (upto 25) young/litter, 2 litters/a
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Notation 1
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Indices for compounds
Indices for transformations
General
Notation 2
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Metabolism in a DEB
individual. Rectangles are state
variables Arrows are flows of food
JXA, reserve JEA, JEC, JEM, JET , JEG, JER, JEJ or structure JVG.
Circles are processes
A DEB organism
ME - Reserve
MV - Structure
Feeding
MH - Maturity
XAJ EAJ
Assimilation
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Feeding: the uptake of food Assimilation: conversion of substrate (food,
nutrients, light) into reserve(s) Depends on substrate availability & structural
surface area (e.g. surface area of the gut)
Feeding & Assimilation
Empirical pattern: the heat increment of feeding suggests that there are processes only associated with food processing
Strong homeostasis imposes a fixed conversion efficiency Consistency with other fields: mass transfer (needed for
acquisition, digestion and food processing) is proportional to area
- surface maximum assimilation rate -yield of reserve on food
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If food availability is constant (or abundant)
feeding increases proportional to area or L2
(for isomorphs)
Feeding rate
Mytilus edulisData: Winter 1973
Length, cm
Filtra
tion
rate
, l/h
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Intra-taxon predation: efficient conversion
yEX a high yield of reserve on food
Hemiphractus fasciatusis a frog-eating frog
Beroe spis a comb jelly-eating comb jelly
Solaster papposus is a starfish-eating starfish
Chrysaora hysoscella is a jelly fish-eating jelly fish
Euspira catena is a snail-eating snail
Coluber constrictor is a snake-eating snake
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Asplanchna girodiis a rotifer-eating rotifer
Didinium nasutumis a ciliate-eating ciliate
Esox lucius is a fish-eating fish
Enallagma carunculatum is a insect-eating insect
Falco peregrinus is a bird-eating bird
Acinonyx jubatus is a mammal-eating mammal
Intra-taxon predation: efficient conversionyEX a high yield of reserve on food
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K 293K; 6400
}exp{)(
1
11
TTTT
TTkTk
A
AA ln ra
te
104 T-1, K-1
Daphnia magna
Metabolic rates: the effect of temperature
The Arrhenius relationship has good empirical support The Arrhenius temperature is given by minus the slope:
the higher the Arrhenius temperature the more sensitive organisms are to changes in temperature
reproductionyoung/d
ingestion106 cells/h
growth, d-1
aging, d-1
Arrhenius relationship: