metabolic control theory and the genetics and evolution of metabolic fluxes umr de génétique...
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Metabolic Control Theory and the genetics and evolution of metabolic
fluxes
UMR de Génétique Végétale, INRA/UPS/CNRS/INA PG
Ferme du Moulon, 91190 Gif-sur-Yvette, France
Christine Dillmann, Julie Fievet, Sébastien Lion, Frédéric Gabriel, Grégoire Talbot, Delphine Sicard, Dominique de Vienne
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Metabolic Control Theory and the genetics and evolution of metabolic fluxes
- Metabolic fluxes as model quantitative traits and the relationship between genotype and phenotype
- Experimental validation of the Metabolic Control Theory
- The metabolic bases of dominance and heterosis
- Evolution of enzyme concentrations in natural populations
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Quantitative traitsMost phenotypic traits …
Growth rate, flowering date, fruit pH, behaviour traits,
morphological traits, blood pressure, metabolic flux,
enzyme activity, mRNA/protein concentrations, etc.
« Quantitative » genetics
A
0
1
2
3
4
5
6
7
150 160 170 180 190 200Taille (cm)
N
… Display a continuous variation within populations :
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Continuous variation can be maintained by independent segregation of multiple factors. George Udny Yule, 1902.
G. J. Mendel, 1865
« Recherche sur les hybrides d’autres plantes »
A
A B
B a
a b
bx
A
a b
B
F2
aabb
Aabb
aaBb
AaBb
aaBB
AAbb
AABb
AaBB
AABB
0123456N
0 1 2 3 4 Number of«Capital letter » alleles
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E1 E2 Ej En
X0 S1 … Sj1 Sj … Xn
Enzymes
The “genotype” : all the genes that determine enzyme activities(concentrations and kinetic parameters, genetically variable)
The metabolic fluxes as model quantitative traits
The “phenotype” : the flux
Kacser H. and Burns J.A., 1981. The molecular basis of dominance. Genetics, 97, 639-666.
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E1 E2 Ej Ej+1 En
Sn-1Sj…S1S0 Sn…En-1
Stationary phase : v1 = v2 = … = vj = … = vn = J
Kacser and Burns, 1973 Heinrich and Rappoport, 1974
Metabolic control theory (1)
Michaelis-Menten enzymes
Enzymes far from saturation
)/()/(//1
)/()/(1max
11
1max
eqiiimiimiimi
eqiiimii KSSKV
KSKS
KSSKVv
Enzyme concentrations are independent
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E1 E2 Ej Ej+1 En
Sn-1Sj…S1S0 Sn…En-1
At stationary phase : v1 = v2 = … = vj = … = vn = J
Kacser and Burns, 1973 Heinrich and Rappoport, 1974
n
jj
n
n
E
KS
S
J
1
,00
1
Metabolic control theory (2)
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AjKinetic parameters :1,0 j
M
catK
K
k
j
j
Enzyme efficiency : Ej
Enzyme cellular concentration Qj
1,0
max
jM
KK
V
j
j= Aj Qj
Metabolic control theory (3) : genetically variable parameters
n
jj
n
n
E
KS
S
J
1
,00
1
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Genetic variability of kinetic parameters
- Few in vivo data
- Slightly variable
Wang & Dykhuisen, 2001. Pathway of gluconate metabolism in E. coli. Evolution, 55:897.
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fba1
IPGS
DS
Num
ber
of
mole
cule
s p
er
cell
Genetic variability of enzyme concentrations
- Highly variables
Fiévet et al, 2004
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Flu
x J
Qj or Aj or Ej = Qj x Aj
Jmax
n enzymes
1 enzyme
Relationship between enzymes and flux : independent enzymes
• non linear relationship between the flux and the concentration of on enzyme of the pathway• the flux tends asymptotically towards a maximum which depends on the concentrations of all the enzymes of the pathway
n
jj
n
n
E
KS
S
J
1
,00
1
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Metabolic Control Theory and the genetics and evolution of metabolic fluxes
- Metabolic fluxes as model quantitative traits and the relationship between genotype and phenotype
- Experimental validation of the Metabolic Control Theory
- The metabolic bases of dominance and heterosis
- Evolution of enzyme concentrations in natural populations
![Page 13: Metabolic Control Theory and the genetics and evolution of metabolic fluxes UMR de Génétique Végétale, INRA/UPS/CNRS/INA PG Ferme du Moulon, 91190 Gif-sur-Yvette,](https://reader031.vdocument.in/reader031/viewer/2022020111/56649b53550346318e8cea72/html5/thumbnails/13.jpg)
Experimental validation : in vivo
Kacser and Burns, 1981. Genetics 97:639
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Relationship RubisCO-photosynthesis
A typical example: dependence of carbon assimilation flux on rubisco levels in transgenic tobacco plants.
Laurer et al, Planta 190 332-345 (1993).
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Experimental validation : in vitro
glucose fructose 1,6 bisP
GAP
DHAP
glycérol 3 P
NADH
NAD+
GPI FBA
TPI
Créatine-P + ADP Créatine + ATPCréatine kinase
ATP
ADP
PFK1
ATP
ADP
HKglucose 6 P fructose 6 P
First part of glycolysis
Julie Fievet et Gilles Curien
Temps
Concentration
du NADH
Etat stationnaire
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Mixing enzymes, substrates, cofactors
EnzymesHXK+PGI+PF
K+FBA+TPI+G3
DH+CK
SubstratesGlucose+Creatine P+NADH+buffer
ATP
One tube one «genotype»
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Experimental validation
HXK concentration (µM)
Each enzyme vary at a turn, the other being kept constant
= Titration curves
• non linear relationship between the flux and the concentration of on enzyme of the pathway• the flux tends asymptotically towards a maximum which depends ont the concentrations of all the enzymes of the pathway
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Complex equationsComplex equations
Many parametersMany parameters
Estimation of kinetic parameters : explicit modelling
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Estimation of kinetic parameters : MCT-based modelling
i iiii iii SpQSApQA
SJ
11
1 Ai composite activity parameterpi dispensability
ppii=0=0ppii≠0≠0
J0
Jmax
0max
max0
ˆii
iii JJ
JJpS
i
j ij
refi
i pS
Jn
J
n
QAS ˆ
1111ˆ
maxmax
The maximum value for the flux is estimated from titration curves :
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Qref Jmax J0 Spi SAi
hxk 0,1 18,24 0 0 379,93
pgi 0,15 13,27 0 0 520,5
pfk 0,29 17,87 0 0 107,02
fba 1,54 18,54 0 0 18,54
tpi 0,84 12,61 10,46 61,35 59,79
Activity parameters are estimated “in systemo”. They are different Activity parameters are estimated “in systemo”. They are different from what can be estimated on isolated enzymesfrom what can be estimated on isolated enzymes
The global equation can be used to predict the flux for other enzyme The global equation can be used to predict the flux for other enzyme concentrations :concentrations :
i iii
prédit
pSQAS
J
ˆˆ1
1
Predicting the flux
Fievet et al, submitted
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Predicted flux (µM/s)
Flux m
easu
red in v
itro
(µM
/s)
r = 0,94
Testing the predictor for the flux on 122 genotubesTesting the predictor for the flux on 122 genotubes
Fievet et al, submitted
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Metabolic Control Theory and the genetics and evolution of metabolic fluxes
(1) Based on MCT, we validated a simple model which describes the relationship between flux and enzyme concentrations
i iii pSQAS
J
ˆˆ1
1
(2) Composite kinetic parameters can be estimated « in vivo » from titration curves
(3) It should also work for more complex networks like …
S1 S2
S3
S4 S5
S6
S7 S8
E1
E2
E3
E5
E4
E6
E7
E8
E9
E10
… with one stable stationary state
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Metabolic Control Theory and the genetics and evolution of metabolic fluxes
- Metabolic fluxes as model quantitative traits and the relationship between genotype and phenotype
- Experimental validation of the Metabolic Control Theory
- The metabolic bases of dominance and heterosis
- Evolution of enzyme concentrations in natural populations
![Page 24: Metabolic Control Theory and the genetics and evolution of metabolic fluxes UMR de Génétique Végétale, INRA/UPS/CNRS/INA PG Ferme du Moulon, 91190 Gif-sur-Yvette,](https://reader031.vdocument.in/reader031/viewer/2022020111/56649b53550346318e8cea72/html5/thumbnails/24.jpg)
Genetical consequences of ~hyperbolic relationships : dominance
- Most deleterious mutations are recessive
- There is ~ additivity between highly deleterious mutations
Three observations
- There is ~ additivity between slightly deleterious mutations
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- R. A. Fisher (1928, 1931, 1958) : «modifiers» of dominance relationship between alleles arise due to natural selection
- S. Wright (1934) : dominance can be explained by the non linear genotype-phenotype relationship.
Two hypothesis to explain dominance
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Dominance : Fisher’s model does not work
Population genetics models : mutations are eliminated before they become recessive.
Mutations in Chlamydomonas reinhardtii (Orr, 1991).
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Recessive mutations occur in Chlamydomonas as frequently as in drosophila
Dominance : Fisher’s model does not work
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Dominance
Ei
Flux
A1A1 A1A2 A2A2
Kacser H. and Burns J.A., 1981. The molecular basis of dominance. Genetics, 97, 639-666.
Ei
Flux
Weak dominance
Dominance : S. Wright was right
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Généralisation : several variables enzymes
E. Coli - Dykhuisen et al., 1987, Genetics, 115, 25
Flu
x
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Generalization : metabolic model for heterosis
i ii iii
hybrid
Levure
Huître
P1 Homozygous line
Maïs
F1 hybrid
Increased vigorF1 > (P1 ,P2 )
P2 Homozygous line
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J
Ej
Ei
Ej
Ei
Line 1 x Line 2 Hybrid F1
Metabolic heterosis due to dominance at different loci
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JP1
JP2
Heterosis in vitro
0%
20%
40%
60%
80%
100%
dis01 01*12 dis12
TPI
FBA
PFK
PGI
HXK
Tube1
Tube 2
Tube (1+2)/2
0,00
1,00
2,00
3,00
4,00
5,00
6,00
7,00
8,00
9,00
dis01 01*12 dis12
Flux
Simulations
Fievet et al, in prep
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Metabolic Control Theory and the genetics and evolution of metabolic fluxes
(4) Dominance and heterosis arise as emergent properties of metabolic systems
(5) Heterosis can be explained by antagonistic epistatic relationships between enzymes
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Metabolic Control Theory and the genetics and evolution of metabolic fluxes
- Metabolic fluxes as model quantitative traits and the relationship between genotype and phenotype
- Experimental validation of the Metabolic Control Theory
- The metabolic bases of dominance and heterosis
- Evolution of enzyme concentrations in natural populations
![Page 35: Metabolic Control Theory and the genetics and evolution of metabolic fluxes UMR de Génétique Végétale, INRA/UPS/CNRS/INA PG Ferme du Moulon, 91190 Gif-sur-Yvette,](https://reader031.vdocument.in/reader031/viewer/2022020111/56649b53550346318e8cea72/html5/thumbnails/35.jpg)
Evolution of enzyme concentration under selection for increasing the flux
W=
Monte-Carlo simulations
Analytical predictions
Natural selection shapes the sharing out of the control of the flux
Talbot et al, in prep
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Dominique de VienneDominique de Vienne
Bruno BostBruno Bost
Julie FiévetJulie Fiévet
Frédéric GabrielFrédéric Gabriel
Sébastien LionSébastien Lion
Delphine SicardDelphine Sicard
Grégoire TalbotGrégoire Talbot
Gilles CurienGilles Curien
Olivier MartinOlivier Martin
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Heterosis and epistasis-A substitution at one locus changes the effects of a substitution at another locus
-The effect of a substituion depends on the genetic background
EA1 EB1EB2
EA2
Enzyme A Enzyme B
sJ
A1B2
A2B1
A1B1
A2B2
Flux
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Heterosis and epistasis
Tryptophane
flux
Synergistic epistasis in tryptophane metabolic pathway
Niederberger et al., 1992, Biochem. J. 287, 473.
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-2-1.5
-1-0.5
00.5
11.5
22.5
33.5
4
-0.5 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 5
Epistasis index
Antagonistic SynergisticAdditivity
I = 1
Jhyb J
JH =
Enzyme A Enzyme B
sJ
A1B2
A2B1
A1B1
A2B2
Heterosis and epistasisH
ete
rosi
s in
de
x
Fievet et al, in prep
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Autres axes de recherche
La concentration d’enzymes allouée à une chaîne est nécessairement finie ( « compétition » corrélations négatives)
Corrélations physiologiques, positives ou négatives
Matrice n x n des Ej/Ei Etotal fixé, ou fonction de coût
1- Les concentrations des enzymes ne sont pas nécessairement indépendantes
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Autres axes de recherche
2- Comment agit la sélection pour maximiser/optimiser un flux ?
- Approche expérimentale : variabilité des paramètres enzymatiques et évolution expérimentale chez la levure (modèle : glycolyse)
- Evolution des flux avec ou sans contraintes sur les concentrations d’enzymes.
J
Ej
Red curve: No co-regulation
Blue curves:Co-regulations