Transcript Physical models

Integrative Genomics
The cost of disease
Organism versus Model
Concepts
GF Mapping
Models: Networks
The Central Dogma & Data
Hidden Structures/ Processes
G - genetic variation
Knowledge
T - transcript levels
Evolution
P - protein concentrations
M - metabolite concentrations
Networks
F – phenotype/phenome
GF Mapping
General Function Enormous
Used for Disease Gene Finding
Can Include Biological Knowledge
Biological Networks
Physical-Chemical Networks
Statistical Networks
Comparative Biology and Model Organisms
Alan D Lopez, Colin D Mathers, Majid Ezzati, Dean T Jamison, Christopher J L Murray Global and regional burden
of disease and risk factors, 2001: systematic analysis of population health data Lancet 2006; 367: 1747–57
Cost of Disease
•Most research in the bioscience is
motivated by hope of disease
intervention.
• Major WHO projects have tried to
tabulate the costs of different
diseases
• Genetic Diseases are diseases
where there is genetic variation in the
susceptibility.
• Even small improvements would
save many billions
Central Dogma
DNA
RNA
Protein
Metabolism & Cell Structure
Organism
Prokaryote
1010 atoms
Eukaryote
1013 atoms
Human
1014 cells
From wikipedia
What is a bacteria? A human being?
The Central Dogma & Data
Protein-DNA binding Data
Chip-chip protein arrays
DNA
Protei
n
mRNA
Translation
Transcription
Genetic Data
SNPs – Single Nucleotide
Polymorphisms
Re-sequencing
CNV - Copy Number Variation
Microsatellites
Transcript Data
Micro-array data
Gene Expression
Exon
Splice Junction
Metabolite
Cellular processes
Proteomic Data
NMR
Mass Spectrometry
2D-gel electrophoresis
Embryology
Organismal Biology
Metabonomic Data
NMR
Mass Spectrometry
2D-Gel electrophoresis
Metabonomics
Genetical Genomics
Proteomics
Transcriptomics
Genetic Mapping
Phenotype
Phenotypic Data
Clinical Phenotypes
Disease Status
Quantitative Traits
Blood Pressure
Body Mass Index
Structure of Integrative Genomics
DNA
Classes
Protei
n
mRNA
Metabolite
Phenotype
Parts
Concepts
GF Mapping
Models: Networks
Physical models:
Systems Biology
Phenomenological models:
Integrative Genomics
Hidden Structures/ Processes
Knowledge:
Evolution:
Unobservered/unobservable
Externally Derived Constraints on which Models are acceptable
Cells in Ontogeny
Individuals/Sequences in a Population
Analysis: Data + Models + Inference
Functional Explanation
Model Selection
Species
G: Genomes
A diploid genome:
Key challenge: Making a single molecule observable!!
Classical Solution (70s): Many
De Novo Sequencing: Halted extensions or degradation
extension
degradation
80s: From one to many: PCR – Polymerase Chain Reaction
00s: Re-sequencing: Hybridisation to complete genomes
Future Solution: One is enough!!
Observing the behavior of the polymerase
Passing DNA through millipores registering changes in current
G: Assembly and Hybridisation
Target genome
3*109 bp
(unobservable)
Reads
3-400 bp
(observable)
Contigs
Contigs and Contig Sizes as function of Genome Size (G), Read Size (L) and overlap (Ø):
{A,C}
Complementary or almost
complementary strings allow
interrogation.
probe
{T,G}
Lander & Waterman, 1988 Statistical Analysis of Random Clone
Fingerprinting
Sufficient overlap allows concatenation
T - Transcriptomics
Classical Expression Experiment:
The Gene is transcribed into pre-mRNA
Pre-mRNA is processed into mRNA
Probes are designed hybridizing to specific positions
Measures transcript levels
averaging of a set of cells.
RNA-Seq Expression Experiment: Advantages - Discoveries
More quantitative in evaluating
expression levels
More precise in positioning
Much more is transcribed than expected.
Transcription of genes very imprecise
Wang, Gerstein and Snyder (2009) RNA-Seq: a revolutionary tool for Transcriptomics NATURE REVIEwS genetics VOLUME 10.57-64
T - Transcriptomics
Concepts
GF Mapping
Physical models:
Models: Networks
Phenomenological models:
Hidden Structures/ Processes
Knowledge:
Evolution:
Unobservered/able
Externally Derived Constraints on which Models are acceptable
Cells in Ontogeny
Individuals/Sequences in a Population
Species
G F
• Mechanistically predicting relationships between different data types is very difficult
• Empirical mappings are important
• Functions from Genome to Phenotype stands out in importance
G is the most abundant data form - heritable and precise. F is of greatest interest.
DNA
mRNA
Protei
n
Metabolite
Phenotype
“Zero”-knowledge mapping: dominance,
recessive, interactions, penetrance, QTL,.
Mapping with knowledge: weighting
interactions according to co-occurence in
pathways.
Model based mapping:
genomesystemphenotype
Height
Weight
Disease
status
Intelligence
……….
Environment
The General Problem is Enormous
Set of Genotypes:
1
3* 107
• Diploid Genome
• In 1 individual, 3* 107 positions could segregate.
• In the complete human population 5*108 might segregate.
• Thus there could be 2500.000.000 possible genotypes
Partial Solution: Only consider functions dependent on few positions
• Causative for the trait
Classical Definitions:
• Single Locus
• Multiple Loci
Dominance
Recessive
Additive
Heterotic
Epistasis: The effect of one locus depends on the state of another
Quantitative Trait Loci (QTL). For instance sum of functions for positions plus error
term.
 X (G )  
i
i
i causative positions
Genotype and Phenotype Co-variation: Gene Mapping
Sampling Genotypes and Phenotypes
Decay of local dependency
Time
Reich et al. (2001)
Genetype -->Phenotype Function
Result:The Mapping Function
Dominant/Recessive
Penetrance
A set of characters.
Binary decision (0,1).
Spurious Occurrence
Quantitative Character.
Heterogeneity
genotype
Genotype  Phenotype
phenotype
Pedigree Analysis & Association Mapping
Association Mapping:
Pedigree Analysis:
M
r
D
Pedigree known
D
2N generations
M
r
Few meiosis (max 100s)
Resolution: cMorgans (Mbases)
Pedigree unknown
Many meiosis (>104)
Resolution: 10-5 Morgans (Kbases)
Adapted from McVean and others
Heritability: Inheritance in bags, not strings.
The Phenotype is the sum of a series of
factors, simplest independently genetic and
environmental factors: F= G + E
Parents:
Relatives share a calculatable fraction of factors,
the rest is drawn from the background
population.
This allows calculation of relative
effect of genetics and environment
Heritability is defined as the relative
contribution to the variance of the genetic
factors:  G2 / F2
Siblings:

Visscher, Hill and Wray (2008) Heritability in the genomics era — concepts and misconceptions nATurE rEvIEWS | genetics volumE 9.255-66
Heritability
Examples of heritability
Heritability of multiple characters:
Rzhetsky et al. (2006) Probing genetic overlap among complex human phenotypes PNAS vol. 104 no. 28 11694–11699
Visscher, Hill and Wray (2008) Heritability in the genomics era — concepts and misconceptions nATurE rEvIEWS | genetics volumE 9.255-66
Networks in Cellular Biology
• Dynamics
• Inference
• Evolution
A. Metabolic Pathways
Enzyme catalyzed set of reactions controlling
concentrations of metabolites
B. Regulatory Networks
Boehringer-Mannheim
Network of {GenesRNAProteins}, that regulates each other transcription.
C. Signaling Pathways
Cascade of Protein reactions that sends signal from
receptor on cell surface to regulation of genes.
A repertoire of Dynamic Network Models
To get to networks:
No space heterogeneity  molecules are represented by numbers/concentrations
Definition of Biochemical Network:
• A set of k nodes (chemical species) labelled by kind and possibly concentrations, Xk.
1
2
3
k
• A set of reactions/conservation laws (edges/hyperedges) is a
set of nodes. Nodes can be labelled by numbers in reactions. If
directed reactions, then an inset and an outset.
1
7
2
• Description of dynamics for each rule.
ODEs – ordinary differential equations
Mass Action
dX 7
 cX1 X 2
dt
Time Delay
dX (t)
 f (X (t  
))
dt
dX 7
 f (X1, X 2 )
dt
Discrete Deterministic – the reactions are applied.

Boolean – only 0/1 values.

Stochastic
Discrete: the reaction fires after exponential with some intensity I(X 1,X2) updating the number of molecules
Continuous: the concentrations fluctuate according to a diffusion process.
Number of Networks
• undirected graphs
• Connected undirected graphs
n  k(nk )
an   (1)  2
ank
k 
k1
n
• Directed Acyclic Graphs - DAGs
k1

• Interesting Problems to consider:
• The size of neighborhood of a graph?
• Given a set of subgraphs, who many graphs have them as subgraphs?
Networks  A Cell  A Human
• A cell has ~1013 atoms.
1013
• Describing atomic behavior needs ~1015 time steps per second
1028
• A human has ~1013 cells.
1041
• Large descriptive networks have 103-105 edges, nodes and
labels
• What happened to the missing 36 orders of magnitude???
105
• Which approximations have been made?
A Spatial homogeneity  103-107 molecules can be represented by concentration ~104
B One molecule (104), one action per second (1015)
~1019
C Little explicit description beyond the cell
~10 13
A Compartmentalisation can be added, some models (ie Turing) create spatial heterogeneity
B Hopefully valid, but hard to test
C Techniques (ie medical imaging) gather beyond cell data
Protein Interaction Network based model of Interactions
The path from genotype to
genotype could go through
a network and this
knowledge can be exploited
NETWORK
GENOME
1
Groups of connected genes
can be grouped in a
supergene and disease
dominance assumed: a
mutation in any allele will
cause the disease.
2
n
Rhzetsky et al. (2008) Network Properties of genes harboring inherited disease mutations PNAS. 105.11.4323-28
PHENOTYPE
PIN based model of Interactions
Emily et al, 2009
Single marker association
Protein Interaction Network
PIN gene pairs are allowed
to interact
Interactions creates nonindependence in combinations
Phenotype i
SNP 1
Gene 1
Gene 2
3*3 table
SNP 2
Comparative Biology
Most Recent
Common Ancestor
Time Direction
?
ATTGCGTATATAT….CAG
observable
Key Questions:
•Which phylogeny?
•Which ancestral states?
•Which process?
ATTGCGTATATAT….CAG
observable
ATTGCGTATATAT….CAG
observable
Key Generalisations:
•Homologous objects
•Co-modelling
•Genealogical Structures?
Comparative Biology: Evolutionary Models
Object
Nucleotides/Amino Acids/codons
Continuous Quantities
Sequences
Gene Structure
Genome Structure
Structure
RNA
Protein
Networks
Metabolic Pathways
Protein Interaction
Regulatory Pathways
Signal Transduction
Macromolecular Assemblies
Motors
Shape
Patterns
Tissue/Organs/Skeleton/….
Dynamics
MD movements of proteins
Locomotion
Culture
Language
Vocabulary
Grammar
Phonetics
Semantics
Phenotype
Dynamical Systems
Type
Reference
CTFS continuous time finite states
Jukes-Cantor 69 +500 others
CTCS continuous time countable states Felsenstein 68 + 50 others
CTCS
Thorne, Kishino Felsenstein,91 + 40others
Matching
DeGroot, 07
CTCS MM
Miklos,
SCFG-model like
non-evolutionary: extreme variety
CTCS
?
CTCS
CTCS
CTCS
?
?
- (non-evolutionary models)
- (non-evolutionary models)
- (non-evolutionary models)
analogues to genetic models
“Infinite Allele Model” (CTCS)
Holmes, I. 06 + few others
Lesk, A;Taylor, W.
Snijder, T (sociological networks)
Stumpf, Wiuf, Ideker
Quayle and Bullock, 06
Soyer et al.,06
Dryden and Mardia, 1998
Turing, 52;
Grenander,
Cavalli-Sforza & Feldman, 83
Swadesh,52, Sankoff,72, Gray & Aitkinson, 2003
Dunn 05
Bouchard-Côté 2007
Sankoff,70
Brownian Motion/Diffusion
-
Summary of this lecture
The cost of disease
Organism versus Model
Concepts
GF Mapping
Models: Networks
The Central Dogma & Data
Hidden Structures/ Processes
G - genetic variation
Knowledge
T - transcript levels
Evolution
P - protein concentrations
M - metabolite concentrations
Networks
F – phenotype/phenome
GF Mapping
General Function Enormous
Used for Disease Gene Finding
Can Include Biological Knowledge
Biological Networks
Physical-Chemical Networks
Statistical Networks
Comparative Biology and Model Organisms