Introduction to Bioinformatics - Tutorial no. 13 Probe Design Gene Networks.
Post on 20-Dec-2015
220 Views
Preview:
Transcript
Probe design problem
Given a genome with a set of genes. Recall that each gene is represented by a
probe (a short segment) of the corresponding cDNA.
The length of a probe can be 20, 50, 70! The probe design problem tries to identify a
probe for every gene.
Probe design problem (Informal definition)
Given a genome, for every cDNA (or mRNA) Xi, a probe pi is identified such that
pi is a substring of Xi; and pi does not cross-hybridize with other mRNAs
Probe design problem creates a probe pi for every mRNA Xi
X2 X3 X4X1
p1 p1 p1p1 X X X
Primer3 Input
Sequence
5’ PCR primer
Oligo probe
3’ PCR primer
Include in PCR primerExclude from
PCR primer
Repeats library
Primer3 Output
mRNA position
Length
Hybrid Tm
% GC Self complementarity
3’ complementarity
Sequence
Product
5’ PCR primer Oligo
probe
3’ PCR primer
OligoDB Input
Oligonucleotide lengthNumber for each mRNA
Background database
Ensembl Gene IDEnsembl
mRNA ID
BioCarta
Main focus: Pathways and tools to study them.
Pathway tool is web-based. http://www.biocarta.com/genes/index.asp
Static pages of pathways. Metabolic and regulatory pathways.
Need licence to add/edit pathways.
BioCarta Metabolic Pathway Example Glycolysis. Compounds shown in
chemical and textual form.
Enzymes above arrows with legend at bottom.
Only enzymes are clickable.
ExPASy “Expert Protein Analysis System”. Main focus: Analysis of protein sequences and
structures. Pathway tool is web-based.
http://www.expasy.org/cgi-bin/search-biochem-index Static pages of pathways.
Metabolic and Regulatory pathways. Scanned in version of the Boehringer Mannheim
“Biochemical Pathways” map. Map partitioned into 115 pieces. Keywords matched against entries in map.
Cannot add/edit pathways.
ExPASy Metabolic Pathway Example Glycolysis. Color convention based on
Michal’s “Biochemical Pathways”. Color of compounds
depends on compound type. Color of arrows depend on
species (plant, animal, yeast, prokaryotes).
Only enzymes and arrows outside diagram are clickable.
ExPASy Regulatory Pathway Example Insulin receptors. Only enzymes and
arrows outside diagram are clickable.
KEGG
“Kyoto Encyclopedia of Genes and Genomes”. Main focus: Biochemical pathway visualization. Pathway tool is web-based.
http://www.kegg.com/kegg/kegg2.html Static pages of pathways.
Metabolic and Regulatory pathways. Different organisms.
KEGG Metabolic Pathway Example Glycolysis. Substrates and products
are drawn in circles. Enzymes, represented by
EC number, are drawn in rectangles.
Adjacent pathways are drawn in semi-rectangles.
Enzymes found in the gene catalog of a specific organism are marked green.
All items are clickable.
KEGG Metabolic Pathway Example Select specific species
Link to other pathway
Link to compound
Link to enzyme
WIT
“What is There”. Main focus: Produce metabolic
reconstructions for sequenced (or partially sequenced) genomes.
Pathway tool is Web-based.http://wit.mcs.anl.gov/WIT2/
Static pages of pathways. Only metabolic pathways.
MetaCyc
Electronic encyclopedia of over 450 metabolic pathways from over 150 different organisms.
Software: Implemented in COMMON LISP; AI techniques
incorporated to allow inference, such as pathway prediction from sequenced genomes.
Need a licence to obtain software. Free for academic purposes only.
Graph layout algorithm for drawing metabolic pathways dynamically at run-time.
Need to manipulate database to add/edit pathways.
MetaCyc Metabolic Pathway Example Glycolysis. Everything
(Substrates, products, adjacent pathways, and arrows) is clickable.
top related