netbiosig2013-talk vuk janjic
DESCRIPTION
Presentation for Network Biology SIG 2013 by Vuk Janjic, Imperial College London, UK. “A Journey to the Core of Human Disease”TRANSCRIPT
Outline
Background
MethodsDataConstructing the networksGraphletsK-core decomposition
The Core DiseasomeTopological uniquenessFunctional annotationDrug targetsComputing the Core Diseasome
Key cardio-vascular disease genes
G-protein coupled receptors
Imperial College London Vuk Janjić [email protected]
Outline
Background
MethodsDataConstructing the networksGraphletsK-core decomposition
The Core DiseasomeTopological uniquenessFunctional annotationDrug targetsComputing the Core Diseasome
Key cardio-vascular disease genes
G-protein coupled receptors
Imperial College London Vuk Janjić [email protected]
Background
I A LOT of system-level biological data due to advances inbiotechnology
I We’re looking for a “core subnetwork” of the humanprotein-protein interaction (PPI) network in which genes (theirprotein products) involved in a multitude of diseases reside
I No a priori knowledge of genes’ involvement in disease and byusing k-core decomposition
I Other studies have used a similar approach, but with adifferent goal in mind
Imperial College London Vuk Janjić [email protected] 1/17
Background
I A LOT of system-level biological data due to advances inbiotechnology
I We’re looking for a “core subnetwork” of the humanprotein-protein interaction (PPI) network in which genes (theirprotein products) involved in a multitude of diseases reside
I No a priori knowledge of genes’ involvement in disease and byusing k-core decomposition
I Other studies have used a similar approach, but with adifferent goal in mind
Imperial College London Vuk Janjić [email protected] 1/17
Background
I A LOT of system-level biological data due to advances inbiotechnology
I We’re looking for a “core subnetwork” of the humanprotein-protein interaction (PPI) network in which genes (theirprotein products) involved in a multitude of diseases reside
I No a priori knowledge of genes’ involvement in disease and byusing k-core decomposition
I Other studies have used a similar approach, but with adifferent goal in mind
Imperial College London Vuk Janjić [email protected] 1/17
Background
I A LOT of system-level biological data due to advances inbiotechnology
I We’re looking for a “core subnetwork” of the humanprotein-protein interaction (PPI) network in which genes (theirprotein products) involved in a multitude of diseases reside
I No a priori knowledge of genes’ involvement in disease and byusing k-core decomposition
I Other studies have used a similar approach, but with adifferent goal in mind
Imperial College London Vuk Janjić [email protected] 1/17
Outline
Background
MethodsDataConstructing the networksGraphletsK-core decomposition
The Core DiseasomeTopological uniquenessFunctional annotationDrug targetsComputing the Core Diseasome
Key cardio-vascular disease genes
G-protein coupled receptors
Imperial College London Vuk Janjić [email protected]
Data
# of nodes # of edges ReferenceProtein-protein 11,100 56,708 HPRD, BioGRID
Genetic 274 281 BioGRIDDisease-gene 561 / 4,004 4,029 Disease Ontology
(diseases/genes)
Table: Interaction data
Janjić V. & Pržulj N., Molecular BioSystems, 8, 2614-2625 (2012).
Imperial College London Vuk Janjić [email protected] 2/17
Constructing the networks
Table: Basic network properties for our four networks
H-ALL H-SIM REST CORENumber of nodes 11,100 1,706 8,227 88Number of edges 56,807 8,655 24,730 865
Clustering coefficient 0.125 0.173 0.102 0.462Diameter 13 9 16 3
Radius 7 5 8 2Avg. degree 10.23 10.14 4.53 19.65
Avg. path length 3.69 3.48 4.53 1.87
Imperial College London Vuk Janjić [email protected] 3/17
Constructing the networks
Table: Basic network properties for our four networks
H-ALL H-SIM REST CORENumber of nodes 11,100 1,706 8,227 88Number of edges 56,807 8,655 24,730 865
Clustering coefficient 0.125 0.173 0.102 0.462Diameter 13 9 16 3
Radius 7 5 8 2Avg. degree 10.23 10.14 4.53 19.65
Avg. path length 3.69 3.48 4.53 1.87
Imperial College London Vuk Janjić [email protected] 3/17
Constructing the networks
Table: Basic network properties for our four networks
H-ALL H-SIM REST CORENumber of nodes 11,100 1,706 8,227 88Number of edges 56,807 8,655 24,730 865
Clustering coefficient 0.125 0.173 0.102 0.462Diameter 13 9 16 3
Radius 7 5 8 2Avg. degree 10.23 10.14 4.53 19.65
Avg. path length 3.69 3.48 4.53 1.87
Imperial College London Vuk Janjić [email protected] 3/17
Constructing the networks
2-node
graphlet
4-node graphlets3-node graphlets
5-node graphlets
G0 G1 G2 G3 G4 G5 G6 G7 G8
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G20 G21 G22 G23 G24 G25 G26 G27 G28 G29
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Figure: Graphlets with automorphism orbits.
Pržulj N., Bioinformatics, 23, e177-e183 (2007).
Imperial College London Vuk Janjić [email protected] 3/17
Constructing the networks
Table: Basic network properties for our four networks
H-ALL H-SIM REST CORENumber of nodes 11,100 1,706 8,227 88Number of edges 56,807 8,655 24,730 865
Clustering coefficient 0.125 0.173 0.102 0.462Diameter 13 9 16 3
Radius 7 5 8 2Avg. degree 10.23 10.14 4.53 19.65
Avg. path length 3.69 3.48 4.53 1.87
Imperial College London Vuk Janjić [email protected] 3/17
Constructing the networks
Table: Basic network properties for our four networks
H-ALL H-SIM REST CORENumber of nodes 11,100 1,706 8,227 88Number of edges 56,807 8,655 24,730 865
Clustering coefficient 0.125 0.173 0.102 0.462Diameter 13 9 16 3
Radius 7 5 8 2Avg. degree 10.23 10.14 4.53 19.65
Avg. path length 3.69 3.48 4.53 1.87
Imperial College London Vuk Janjić [email protected] 3/17
Constructing the networks
Table: Basic network properties for our four networks
H-ALL H-SIM REST CORENumber of nodes 11,100 1,706 8,227 88Number of edges 56,807 8,655 24,730 865
Clustering coefficient 0.125 0.173 0.102 0.462Diameter 13 9 16 3
Radius 7 5 8 2Avg. degree 10.23 10.14 4.53 19.65
Avg. path length 3.69 3.48 4.53 1.87
Imperial College London Vuk Janjić [email protected] 3/17
Constructing the networks
Table: Basic network properties for our four networks
H-ALL H-SIM REST CORENumber of nodes 11,100 1,706 8,227 88Number of edges 56,807 8,655 24,730 865
Clustering coefficient 0.125 0.173 0.102 0.462Diameter 13 9 16 3
Radius 7 5 8 2Avg. degree 10.23 10.14 4.53 19.65
Avg. path length 3.69 3.48 4.53 1.87
Imperial College London Vuk Janjić [email protected] 3/17
Constructing the networks
Table: Basic network properties for our four networks
H-ALL H-SIM REST CORENumber of nodes 11,100 1,706 8,227 88Number of edges 56,807 8,655 24,730 865
Clustering coefficient 0.125 0.173 0.102 0.462Diameter 13 9 16 3
Radius 7 5 8 2Avg. degree 10.23 10.14 4.53 19.65
Avg. path length 3.69 3.48 4.53 1.87
Imperial College London Vuk Janjić [email protected] 3/17
Constructing the networks
3-core
2-core
1-core
Figure: A three-level deep k-core decomposition of a network.
Imperial College London Vuk Janjić [email protected] 3/17
Constructing the networks
Table: Basic network properties for our four networks
H-ALL H-SIM REST CORENumber of nodes 11,100 1,706 8,227 88Number of edges 56,807 8,655 24,730 865
Clustering coefficient 0.125 0.173 0.102 0.462Diameter 13 9 16 3
Radius 7 5 8 2Avg. degree 10.23 10.14 4.53 19.65
Avg. path length 3.69 3.48 4.5 1.87
Imperial College London Vuk Janjić [email protected] 3/17
Constructing the networks
Table: Basic network properties for our four networks
H-ALL H-SIM REST CORENumber of nodes 11,100 1,706 8,227 88Number of edges 56,807 8,655 24,730 865
Clustering coefficient 0.125 0.173 0.102 0.462Diameter 13 9 16 3
Radius 7 5 8 2Avg. degree 10.23 10.14 4.53 19.65
Avg. path length 3.69 3.48 4.5 1.87
Imperial College London Vuk Janjić [email protected] 3/17
Constructing the networks
Table: Basic network properties for our four networks
H-ALL H-SIM REST CORENumber of nodes 11,100 1,706 8,227 88Number of edges 56,807 8,655 24,730 865
Clustering coefficient 0.125 0.173 0.102 0.462Diameter 13 9 16 3
Radius 7 5 8 2Avg. degree 10.23 10.14 4.53 19.65
Avg. path length 3.69 3.48 4.5 1.87
Imperial College London Vuk Janjić [email protected] 3/17
Outline
Background
MethodsDataConstructing the networksGraphletsK-core decomposition
The Core DiseasomeTopological uniquenessFunctional annotationDrug targetsComputing the Core Diseasome
Key cardio-vascular disease genes
G-protein coupled receptors
Imperial College London Vuk Janjić [email protected]
Topological uniqueness
Maxim um EC = 10.52%
Algorithm executions 1-4,000
Edg
e c
orr
ectn
ess (
%)
13
12
11
10
9
8
7
6
Imperial College London Vuk Janjić [email protected] 4/17
Functional annotation
I Statistics performed using:I hypergeometric testI H-ALL as the background modelI Benjamini-Hochberg False Discovery Rate correction for
multiple hypothesis testing
I Enriched Molecular Function Gene Ontology (GO) termsI enzyme binding, transcription factor binding, transcription
regulator activity, DNA binding, promoter bindingI Enriched Biological Process GO terms (mostly regulatory)
I positive regulation of macromolecule metabolic process,positive regulation of cellular biosynthetic process, response toorganic substance, regulation of cell proliferation, positiveregulation of gene expression
Imperial College London Vuk Janjić [email protected] 5/17
Functional annotation
I Statistics performed using:I hypergeometric testI H-ALL as the background modelI Benjamini-Hochberg False Discovery Rate correction for
multiple hypothesis testingI Enriched Molecular Function Gene Ontology (GO) terms
I enzyme binding, transcription factor binding, transcriptionregulator activity, DNA binding, promoter binding
I Enriched Biological Process GO terms (mostly regulatory)I positive regulation of macromolecule metabolic process,
positive regulation of cellular biosynthetic process, response toorganic substance, regulation of cell proliferation, positiveregulation of gene expression
Imperial College London Vuk Janjić [email protected] 5/17
Functional annotation
I Statistics performed using:I hypergeometric testI H-ALL as the background modelI Benjamini-Hochberg False Discovery Rate correction for
multiple hypothesis testingI Enriched Molecular Function Gene Ontology (GO) terms
I enzyme binding, transcription factor binding, transcriptionregulator activity, DNA binding, promoter binding
I Enriched Biological Process GO terms (mostly regulatory)I positive regulation of macromolecule metabolic process,
positive regulation of cellular biosynthetic process, response toorganic substance, regulation of cell proliferation, positiveregulation of gene expression
Imperial College London Vuk Janjić [email protected] 5/17
Functional annotation
Table: Regulation of cell death and apoptosis enrichment.
regulation of cell death regulation of apoptosis(GO:10941) (GO:42981)
H-ALL 8.9% 8.8%H-SIM 19.9% (p = 8.59× 10−60) 19.8% (p = 1.13× 10−59)REST no enrichment no enrichmentCORE 32.1% (p = 6.93× 10−10) 29.8% (p = 1.1× 10−8)
Imperial College London Vuk Janjić [email protected] 6/17
Functional annotation
I Top 1% hubs contain only 9 (out of 185) apoptosis annotatedproteins
I These 9 are evenly split between H-SIM and REST (5 are inH-SIM and 4 in REST)
I Cell death has no annotated proteins in the top 1% of hubs.
Imperial College London Vuk Janjić [email protected] 7/17
Functional annotation
I Top 1% hubs contain only 9 (out of 185) apoptosis annotatedproteins
I These 9 are evenly split between H-SIM and REST (5 are inH-SIM and 4 in REST)
I Cell death has no annotated proteins in the top 1% of hubs.
Imperial College London Vuk Janjić [email protected] 7/17
Functional annotation
I Top 1% hubs contain only 9 (out of 185) apoptosis annotatedproteins
I These 9 are evenly split between H-SIM and REST (5 are inH-SIM and 4 in REST)
I Cell death has no annotated proteins in the top 1% of hubs.
Imperial College London Vuk Janjić [email protected] 7/17
Functional annotation
I Could the Core Diseasome be capturing genes causal todiseases for which we generally have no effective cure,including cancer, hematologic diseases, neurodegenerativediseases, progression of viral and HIV infection?
Imperial College London Vuk Janjić [email protected] 8/17
Driver genes
I Genetic interactions are increasingly starting to show that avery small number of genetic changes may trigger diseaseonset. These mutations are usually called driver mutations.
Ashworth A. et al., Cell, 145, 30–38, (2011).
Imperial College London Vuk Janjić [email protected] 9/17
Driver genes
I We verify that CORE genes:I are enriched in genetic interactions (GIs)
I 22 of them participate in 21 GIs within CORE (p = 10−16)I 32 of them participate in 100 GIs total (including 59 genes
outside of core)
I capture 15 driver genes (both known and predicted).
Imperial College London Vuk Janjić [email protected] 10/17
Driver genes
I We verify that CORE genes:I are enriched in genetic interactions (GIs)
I 22 of them participate in 21 GIs within CORE (p = 10−16)I 32 of them participate in 100 GIs total (including 59 genes
outside of core)I capture 15 driver genes (both known and predicted).
Imperial College London Vuk Janjić [email protected] 10/17
Driver genes
SIN3A
NCOR1
HDAC5
PMLGATA1
CTBP1
SUMO1
RUNX1
SMARCB1SMARCC1
UBE2I
ETS1
DAXX
RUNX2
SMARCA4
CEBPA MYOD1
SMAD3
RARA
HDAC4
NCOR2SP1
EP300
HDAC3
RXRA
MYC
TP73
CEBPB
KAT2BJUN
CREBBPBRCA1
SMARCA2
SMAD4
POLR2A
STUB1SMAD2
NCOA2
CCND1
CDKN1A
HIF1A
MDM2
PARP1
CSNK2A1
RELA
CAV1
ABL1
HSPA8
HSPA4
UBC
HSP90AA1
PAK1
EGFR
RAF1
MST1R
ERBB2
KHDRBS1
CASP3
CHUK
CTNNB1
ESR1
FOXO1RB1AKT1
AR ESR2
PTPN11LYN
PTK2B CRK
CRKL
KIT
CBL
PTPN6
PLCG1
LCKJAK2
PIK3R1INSR
BCR
EPOR
IRS1
SHC1
PTPN1
IGF1R
PTK2
BCAR1
PXN
Imperial College London Vuk Janjić [email protected] 11/17
Drug targets
I Amongst the 22 genes participating in genetic interactionswithin CORE, there are 11 drug targets linked to 116 distinctdrugs (p = 8.64× 10−5)
MDM2MDM2
JUNJUN
RB1RB1
ARAR
SMAD2SMAD2
NCOA2NCOA2
KAT2BKAT2BCCND1CCND1
ESR1ESR1
CTNNB1CTNNB1
CREBBPCREBBP
I Out of these 11 drug targets, 3 aretargeted by 23 or more drugs:ESR1 is targeted by 61 differentdrugs, AR by 40, and NCOA2 by23. (the p-value of any targetbeing hit by more than 22 drugs is0.0017)
I 2 known driver genes in CORE aredrug targets: RB1 and CTNNB1
Imperial College London Vuk Janjić [email protected] 12/17
Drug targets
I Amongst the 22 genes participating in genetic interactionswithin CORE, there are 11 drug targets linked to 116 distinctdrugs (p = 8.64× 10−5)
MDM2MDM2
JUNJUN
RB1RB1
ARAR
SMAD2SMAD2
NCOA2NCOA2
KAT2BKAT2BCCND1CCND1
ESR1ESR1
CTNNB1CTNNB1
CREBBPCREBBP
I Out of these 11 drug targets, 3 aretargeted by 23 or more drugs:ESR1 is targeted by 61 differentdrugs, AR by 40, and NCOA2 by23. (the p-value of any targetbeing hit by more than 22 drugs is0.0017)
I 2 known driver genes in CORE aredrug targets: RB1 and CTNNB1
Imperial College London Vuk Janjić [email protected] 12/17
Drug targets
I Amongst the 22 genes participating in genetic interactionswithin CORE, there are 11 drug targets linked to 116 distinctdrugs (p = 8.64× 10−5)
MDM2MDM2
JUNJUN
RB1RB1
ARAR
SMAD2SMAD2
NCOA2NCOA2
KAT2BKAT2BCCND1CCND1
ESR1ESR1
CTNNB1CTNNB1
CREBBPCREBBP
I Out of these 11 drug targets, 3 aretargeted by 23 or more drugs:ESR1 is targeted by 61 differentdrugs, AR by 40, and NCOA2 by23. (the p-value of any targetbeing hit by more than 22 drugs is0.0017)
I 2 known driver genes in CORE aredrug targets: RB1 and CTNNB1
Imperial College London Vuk Janjić [email protected] 12/17
Computing the Core Diseasome
Breast cancer
Prostate cancer
Leukemia
Yersinia infection
Adenovirus infection
Rheumatoid arthritis
Embryoma
Alzheimer's disease
Systemic scleroderma
Lymphoma
Parkinson disease
Melanoma
Colon cancer
Brain tumor
Eating disorder
CoreDiseasome
(88 genes)
H-ALL Core(17 genes)
H-SIM Core(12 genes)
Linked via
57 intermediary genes
and 175 edges
Linked via
57 intermediary genes
and 175 edges
BCL2
BCL3
CARM1
CASP8
E2F1
GNB2L1
HSF1
IKBKB
AHR
ARNT
CSK
GAB2
HIPK2
MEN1
NG1
JAK1
KAT5
KRT18
MAPK14
MDM4
RBBP4
SMARCE1
TSC2
MYB
NCK1
NEDD9
PIAS3
SKI
SOS1
BCL2
BCL3
CARM1
CASP8
E2F1
GNB2L1
HSF1
IKBKB
AHR
ARNT
CSK
GAB2
HIPK2
MEN1
NG1
JAK1
KAT5
KRT18
MAPK14
MDM4
RBBP4
SMARCE1
TSC2
MYB
NCK1
NEDD9
PIAS3
SKI
SOS1
Imperial College London Vuk Janjić [email protected] 13/17
Outline
Background
MethodsDataConstructing the networksGraphletsK-core decomposition
The Core DiseasomeTopological uniquenessFunctional annotationDrug targetsComputing the Core Diseasome
Key cardio-vascular disease genes
G-protein coupled receptors
Imperial College London Vuk Janjić [email protected]
Key cardio-vascular disease genes
I Cardio-vascular disease (CVD)
I Interlogous Interaction Database (I2D), Jurisica Lab @Toronto
I around 15,000 nodes and 173,000 interactions (60,000predicted interactions)
I Study identifies 10 “Key CVD proteins” via clustering methodsI All 10 “key” CVD proteins captured by k-core decomp. of:
I the whole PPI network (p = 10−11)I induced CVD network (p = 10−10)
Imperial College London Vuk Janjić [email protected] 14/17
Key cardio-vascular disease genes
I Cardio-vascular disease (CVD)I Interlogous Interaction Database (I2D), Jurisica Lab @
TorontoI around 15,000 nodes and 173,000 interactions (60,000
predicted interactions)
I Study identifies 10 “Key CVD proteins” via clustering methodsI All 10 “key” CVD proteins captured by k-core decomp. of:
I the whole PPI network (p = 10−11)I induced CVD network (p = 10−10)
Imperial College London Vuk Janjić [email protected] 14/17
Key cardio-vascular disease genes
I Cardio-vascular disease (CVD)I Interlogous Interaction Database (I2D), Jurisica Lab @
TorontoI around 15,000 nodes and 173,000 interactions (60,000
predicted interactions)
I Study identifies 10 “Key CVD proteins” via clustering methods
I All 10 “key” CVD proteins captured by k-core decomp. of:I the whole PPI network (p = 10−11)I induced CVD network (p = 10−10)
Imperial College London Vuk Janjić [email protected] 14/17
Key cardio-vascular disease genes
I Cardio-vascular disease (CVD)I Interlogous Interaction Database (I2D), Jurisica Lab @
TorontoI around 15,000 nodes and 173,000 interactions (60,000
predicted interactions)
I Study identifies 10 “Key CVD proteins” via clustering methodsI All 10 “key” CVD proteins captured by k-core decomp. of:
I the whole PPI network (p = 10−11)I induced CVD network (p = 10−10)
Imperial College London Vuk Janjić [email protected] 14/17
Key cardio-vascular disease genes
SMARCC1
ETS1
SMARCB1
RUNX1
SMARCA4
RUNX2
NCOR1
SMAD3
CTBP1
HDAC5
KAT2B
GATA1
UBE2I
SIN3A
JUN
MYOD1
PML
SUMO1
ESR2
EP300HDAC4
NCOR2
RXRA
CREBBP
CHUK
DAXX
ESR1
RB1
CASP3
CSNK2A1
SMAD4
MYC
SMAD2
HSP90AA1
HSPA8
ABL1
UBC
CAV1
SMARCA2
LCK
EGFR
KHDRBS1
RAF1
MST1R
PTPN6
PAK1
ERBB2
STUB1
JAK2
POLR2A
TP73
HSPA4
CEBPA
BRCA1
CEBPB
AR
AKT1
CTNNB1
PARP1
NCOA2CCND1RELA
HIF1A
HDAC3
RARA
MDM2
CDKN1A
FOXO1
SP1
KIT
CBL
CRKL
PLCG1EPOR
PXN
BCAR1
PTK2
IGF1R
PTPN1
IRS1
SHC1INSR
LYN
PTK2BCRK
PTPN11
PIK3R1
BCR
8 Key CVD genes
8 validated CVD gene predictions
2 non-valdated CVD gene predictions
11 drug targets
5 driver gene
Sarajlic, A. et al., PLoS One, in press (2013)
Imperial College London Vuk Janjić [email protected] 15/17
Outline
Background
MethodsDataConstructing the networksGraphletsK-core decomposition
The Core DiseasomeTopological uniquenessFunctional annotationDrug targetsComputing the Core Diseasome
Key cardio-vascular disease genes
G-protein coupled receptors
Imperial College London Vuk Janjić [email protected]
G-protein coupled receptors
I New unpublished interaction network of human G-proteincoupled receptors (GPCRs) from Štagljar Lab (U-of-T)
I The whole GPCR network is basically a signal transduction“backbone” of the human PPI network — it’s wiring allows itto quickly reach all parts of the interactome
I The “core” of this GPCR network has 68 interactions between25 proteins
I Its “core” proteins primarily expressed in brain, and involved ina range of personality and behavioural disorders:
I attention deficit hyperactivity disorder, weight gain, bipolardisorder, antipsychotic agent-induced weight gain, attentiondeficit disorder / conduct disorder / oppositional defiantdisorder, schizophrenia, weight loss, obesity, mood disorders,tardive dyskinesia, and personality traits.
Imperial College London Vuk Janjić [email protected] 16/17
G-protein coupled receptors
I New unpublished interaction network of human G-proteincoupled receptors (GPCRs) from Štagljar Lab (U-of-T)
I The whole GPCR network is basically a signal transduction“backbone” of the human PPI network — it’s wiring allows itto quickly reach all parts of the interactome
I The “core” of this GPCR network has 68 interactions between25 proteins
I Its “core” proteins primarily expressed in brain, and involved ina range of personality and behavioural disorders:
I attention deficit hyperactivity disorder, weight gain, bipolardisorder, antipsychotic agent-induced weight gain, attentiondeficit disorder / conduct disorder / oppositional defiantdisorder, schizophrenia, weight loss, obesity, mood disorders,tardive dyskinesia, and personality traits.
Imperial College London Vuk Janjić [email protected] 16/17
G-protein coupled receptors
I New unpublished interaction network of human G-proteincoupled receptors (GPCRs) from Štagljar Lab (U-of-T)
I The whole GPCR network is basically a signal transduction“backbone” of the human PPI network — it’s wiring allows itto quickly reach all parts of the interactome
I The “core” of this GPCR network has 68 interactions between25 proteins
I Its “core” proteins primarily expressed in brain, and involved ina range of personality and behavioural disorders:
I attention deficit hyperactivity disorder, weight gain, bipolardisorder, antipsychotic agent-induced weight gain, attentiondeficit disorder / conduct disorder / oppositional defiantdisorder, schizophrenia, weight loss, obesity, mood disorders,tardive dyskinesia, and personality traits.
Imperial College London Vuk Janjić [email protected] 16/17
G-protein coupled receptors
I New unpublished interaction network of human G-proteincoupled receptors (GPCRs) from Štagljar Lab (U-of-T)
I The whole GPCR network is basically a signal transduction“backbone” of the human PPI network — it’s wiring allows itto quickly reach all parts of the interactome
I The “core” of this GPCR network has 68 interactions between25 proteins
I Its “core” proteins primarily expressed in brain, and involved ina range of personality and behavioural disorders:
I attention deficit hyperactivity disorder, weight gain, bipolardisorder, antipsychotic agent-induced weight gain, attentiondeficit disorder / conduct disorder / oppositional defiantdisorder, schizophrenia, weight loss, obesity, mood disorders,tardive dyskinesia, and personality traits.
Imperial College London Vuk Janjić [email protected] 16/17
We’ve seen that. . . (i.e., take-home messages)
I A sub-network of the human PPI network exist, such that it’stopology is unique within that context and it captures diseasegenes, driver genes and their drug targets
I ...and it can be obtained purely computationallyI Usability of the “core” approach in identifying therapeutically
relevant regions of the interactome in two case studies —Cardiovascular disease and G-protein coupled receptors
Imperial College London Vuk Janjić [email protected] 17/17
We’ve seen that. . . (i.e., take-home messages)
I A sub-network of the human PPI network exist, such that it’stopology is unique within that context and it captures diseasegenes, driver genes and their drug targets
I ...and it can be obtained purely computationally
I Usability of the “core” approach in identifying therapeuticallyrelevant regions of the interactome in two case studies —Cardiovascular disease and G-protein coupled receptors
Imperial College London Vuk Janjić [email protected] 17/17
We’ve seen that. . . (i.e., take-home messages)
I A sub-network of the human PPI network exist, such that it’stopology is unique within that context and it captures diseasegenes, driver genes and their drug targets
I ...and it can be obtained purely computationallyI Usability of the “core” approach in identifying therapeutically
relevant regions of the interactome in two case studies —Cardiovascular disease and G-protein coupled receptors
Imperial College London Vuk Janjić [email protected] 17/17
Questions...