parkinson’s law in bacterial regulation sergei maslov brookhaven national laboratory
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Parkinson’s Law in bacterial regulation
Sergei MaslovBrookhaven National Laboratory
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Regulation inside bacteria
Genomes of bacteria contain between several 100s to 10,000s genes
Only a small subset of proteins encoded by these genes is needed under any given environmental condition
Protein production from genes is turned on and off by special regulatory genes – transcription factors often in response to environmental signals
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How E. coli utilizes lactose
LacZLacY LacA
Lactose
LacI
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How many regulatorsdoes a bacterium need?
Transcription factors
“Workhorse” genes
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5
+
NR=NG2/80,000
NR/NG = NG/80,000
Stover et al., Nature (2000), van Nimwegen, TIG (2003)figure from Maslov et al. PNAS (2007)
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Parkinson's Law
The report of the Royal Commission on the Civil Service was published on Thursday afternoon. Time has not permitted any comment in this week's issue of The Economist on the contents of the Report. But the startling discovery enunciated by a correspondent in the following article is certainly relevant to what should have been in it.
Nov 19th 1955 | From The Economist print edition
The total of those employed inside a bureaucracy grew by 5-7% per year "irrespective of any variation in the amount of work (if any) to be done."Parkinson explains the growth of bureaucracy by two forces: • "An official wants to multiply subordinates, not rivals" • "Officials make work for each other."
Is this what happens in bacterial genomes? Probably not!
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Economies of scale in bacterial evolution
• NR=NG2/80,000 NG/NR=80,000/NG
• Economies of scale: as genome gets larger it gets easier to add new pathways as they get shorter
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nutrient
Horizontal gene transfer:entire pathways could be added in one step
Pathways could be also removed
nutrient
Redundant enzymes are removed
Central metabolic core anabolic pathways biomass production
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“Home Depot” or toolbox model
Disclaimer: authors of this study (unfortunately) received no financial support from Home Depot, Inc. Homebase, LTD or Obi, GMBH
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Bottom-down modeling metabolic networks
Food WasteMilk
Spherical cow approximation
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• New pathways come from the “universal metabolic network” of size Nuniv : the union of all reactions in all organisms (bacterial answer to “Home depot”)
• Metabolic network in a given bacterium(# of enzymes ~ # of metabolites): NG
• Probability of a new pathway to merge with existing pathways: pmerge= NG /Nuniv
• Length before merger: Ladded
pathway=1/pmerge=Nuniv/NG
• Assume one regulator per function/pathway: ΔNG/ΔNR=Ladded pathway+1 ~ Nuniv/NG
• Quadratic law: NR=NG2 /2Nuniv
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Toolbox model E. coli metabolic network (spanning tree)
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Inspired by “scope-expansion” algorithm by Reinhart Heinrich and collaborators
TY Pang, S. Maslov, PNAS 2011
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Model with multi-substrate & multi-products reactions from KEGG and minimal pathways
TY Pang, S. Maslov, PNAS 2011
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P(U)~U-γ=U-1.5
Does not work for P(U)=const
What about non-metabolic genes?
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101
102
103
104
105
100
101
102
103
104
105
# of installed packages
# o
f se
lect
ed p
acka
ges
100
102
104
1.6
1.7
1.8
Linux data
slope 1.7
Nselected packages ~ Ninstalled packages
1.7
Software packages for Linux
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What it all means for regulatory networks?
Trends in complexity of regulation vs. genome size
NR<Kout>=NG<Kin>=number of edges in a regulatory network
NR/NG= <Kin>/<Kout> increases with NG Either <Kout> decreases with NG:
functions become more specialized Or <Kin> grows with NG:
regulation gets more coordinated & interconnected
Most likely both trends at onceE. van Nimwegen, TIG (2003)
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nutrient
TF1
nutrient
TF2
Regulatory templates:one worker – one boss
<Kout>: <Kin>=1=const
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nutrient
TF1
nutrient
Regulatory templates:long top-to-bottom regulation
<Kout>=const<Kin>:
TF2<Kout>:<Kin> :
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nutrient
nutrient
TF1
TF2
Hierarchy & middle management:too slow!
TF3
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One hub to rule them all (CRP)
nutrient
TF1
nutrient
TF2
TF3
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Predictions of the toolbox model
Powerlaw distribution of pathways sizes: (# of pathways of size S) ~ (S, # of genes in a pathway)-3
Same as powerlaw distribution of regulon sizes = out-degrees of TFs in the regulatory network?
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100
101
102
10-4
10-3
10-2
10-1
100
branch length/regulon size
cum
ula
tive
dis
trib
uti
on
-1=1
-1=2
Green – regulons in E. coli from RegulonDBRed – KEGG toolbox model
Distribution of regulon sizes
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Regulon size distribution
nutrient
TF1
nutrient
TF2
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Pavel Novichkov and collaborators, LBL
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Pavel Novichkov and collaborators, LBL
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Take home messages Contrary to human organizations
Parkinson’s law does not apply to bacterial genomes: Thanks, natural selection!
Economies of scale make it easier to add pathways to large genomes
Open questions: What sets the upper bound of 10,000 genes in
bacterial genomes? Model of overlap between regulons and pathways? How to describe non-metabolic TFs and genes? Apply toolbox to other systems: see Linux on
Thursday
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US Department Of Energy, Office of Biological and Environmental Research
Systems Biology Knowledgebase (KBase)Visit us @ kbase.us
Toolbox model: • Tin Yau Pang (Stony Brook)• Kim Sneppen (CMOL,
NBI Copenhagen)• Sandeep Krishna (NCBS, India)• Marco C. Lagomarsino (U. of
Pierre and Marie Curie, Paris)• Jacopo Grilli (U. of Milano)• Bruno Bassetti (U. of Milano)
Collaborators and Funding Kbase: • Adam Arkin (Berkeley) • Rick Stevens (Argonne)• Bob Cottingham (Oak Ridge)• Pavel Novichkov (LBL)• Mark Gerstein (Yale)• Doreen Ware (Cold Spring Harbor)• David Weston (Oak Ridge)• 60+ other collaborators
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Thank you!