CADLIVE GRAPHICAL NOTATION .
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Transcript of CADLIVE GRAPHICAL NOTATION .
CADLIVCADLIVEE
GRAPHICAL NOTATION
http://www.cadlive.jp
Regulator-reaction model and graphical notation
RegulatorReaction
ChemicalReaction
GraphicalNotation
S→ P S→ P
E -o S→ PE: Enzyme
E+S <-> E:S → P
A ->> S→ PA: Activator
I - || S→ PI: Inhibitor
MechanisticModel
SemanticModel
S P
S P
E
S P
A
S P
I
Generality(regulator-reaction equation in SBML extension)
Process diagram (temporal order of reaction)
Compactness (Each molecule appears once in a diagram)
Concept of Graphical NotationConcept of Graphical Notation
A B
P Q
A
B
A B
P Q
CADLIVEOther Notations
Process diagramTemporal order of reactions
Entity relationship
Non-redundant appearance of molecules,Compact drawing
CADLIVE(Kurata)
Kohn
Redundant appearance of molecules
Cell DesignerPatikaEdinburghBioD
Comparison of graphical notations
Homo association or modification
Homo association or modificationwith stoichiometric changes
Binding
Binding with stoichiometric changes
Reversible conversion
Irreversible conversion
Degradation
Translation
Transport
Transition state
Reaction
Set Modified from transition state
Activation
Inhibition
Enzymatic catalysis
Regulatory interaction
Protein synthesis
Transcription
DNAs, gene, enhancer, promoter
Fundamental Notation
Binding with stoichiometric changes
A B
A+B<->A-B+H2O3A+ 2B <-> A3:B2
Binding
The number of molecules
A B23
A
ATP ADP
Reaction with cofactors
A+ATP ->A-P+ADP
Homo association or modificationwith stoichiometric changes
+/-Number
SiteSpecies
A
+2P(Ser141)
A+P->A-2P
Multi-substarate and -product reaction
A
B
C
A
B
C
Set Transition state
Select reaction arrows from the transition state
E -o A+B ->C
E
Enhancer Promoter gene
Transcription
mRNA
proteinActivator
Suppressor
Gene expression
New notation for domain level drawing
Virtual binding
Virtual binding with stoichiometric changes
InnerLink arrow
Virtual homo association or modification
Virtual homo association or modificationwith stoichiometric changes
P D1 D2
Domain expansion
A
B
C
RNA D1 D2
1. Domain expansion
2. Virtual reactions and nodes
3. Link of a real node to virtual nodes (InnerLink)
Pro
A
B
+P(A) +P(B)
3 4 5
2
1A
ATPADP
(A) Phosphorylation reactions at the domain level. The protein of Pro is expanded into the domains of A and B. <1> The virtual node indicates the state that Pro is phosphorylated on the B domain. <2> The virtual node indicates the state that Pro is phosphorylated on the A domain. <3> The real node of phosphorylated Pro (Pro-P) is produced. The InnerLink arrow (green) shows that the A domain is phosphorylated. <4> The real node of Pro-P-P is produced. The InnerLink arrow shows both the A and B domains are phosphorylated. <5> The real node of Pro-P is produced by dephosphorylation of Pro-P-P. The InnerLink arrow indicates the B domain is phosphorylated.
Pro1
Pro2
+P 2
3
+P 1B
(B) A phosphorus exchange reaction (Pro1 + Pro2-P -> Pro1-P + Pro2). <1> The virtual node indicates the state that Pro1 is phosphorylated. <2> The real node of Pro2-P is produced. <3> The InnerLink arrow indicates that the real node is Pro1-P.
Pro1 A B C
Pro2 D E
Pro3 F G H
1
2
3
4
C
(C) Synthesis of the protein complex of Pro1:Pro2:Pro3. <1> The virtual node indicates the state that the B domain of Pro1 is bound to the E domain of Pro2. <2> The virtual node indicates the state that the D domain of Pro2 is bound to the F domain of Pro3. <3> The real node of Pro1:Pro2 is produced. The InnerLink arrow indicates that the B domain of Pro1 is bound to the E domain of Pro2. <4> The real node of Pro1:Pro2:Pro3 is produced. The InnerLinik arrow indicates that the D domain of Pro2 is bound to the F domain of Pro3.
Mammalian translation initiation system
A
B
Separation of real reactions and nodes from a domain-level interaction map(A) A domain- or subunit- based map with virtual reactions and nodes. (B) A real map containing no virtual reaction and node. CADLIVE can switch off the display of subunits, domains, virtual reactions and nodes, and InnerLink.
A B
C D
A B
C D
A hierarchical modular architecture by using WhiteBox One can pack molecular networks or modules into the WhiteBox. (A) The entire network. (B) Six functional modules. (C) Seven functional modules. (D) A biochemical network map at the domain-or subunit- level.
Hiroyuki Kurata, Kentaro Inoue, Kazuhiro Maeda, Koichi Masaki, Yuki Shimokawa, Quanyu Zhao, Extended CADLIVE: a novel graphical notation for designing a biochemical network map that enables computational pathway analysis, Nucleic Acids Res. On the web 2007.
Hiroyuki Kurata, Nana Matoba, Natsumi Shimizu, CADLIVE for constructing a large-scale biochemical network based on a simulation-directed notation and its application to yeast cell cycle. Nucleic Acids Res. 31: 4071-4084, 2003.