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Genome sizes (sample)Genome sizes (sample)
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Some genomics historySome genomics history• 1995: first bacterial genome, Haemophilus influenza, 1.8 Mbp, sequenced at TIGR
• first use of whole-genome shotgun for a bacterium• Fleischmann et al. 1995 became most-cited paper of the year
• 2869 citations to date
• 1995-6: 2nd and 3rd bacteria published by TIGR: Mycoplasma genitalium, Methanococcus jannaschii
• 1996: first eukaryote, S. cerevisiae (yeast), 13 Mbp, sequenced by a consortium of (mostly European) labs
• 1997: E. coli finished (7th bacterial genome)• 1998-2001: T. pallidum (syphilis), B. burgdorferi (Lyme disease), M. tuberculosis,
Vibrio cholerae, Neisseria meningitidis, Streptococcus pneumoniae, Chlamydia pneumoniae [all at TIGR]
• 2000: fruit fly, Drosophila melanogaster• 2000: first plant genome, Arabidopsis thaliana• 2001: human genome, first draft• 2002: malaria genome, Plasmodium falciparum• 2002: anthrax genome, Bacillus anthracis• TODAY (Sept 4, 2008):
• 744 complete microbial genomes!• 1199 microbial genomes in progress!• 476 eukaryotic genomes in progress!
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New directions:New directions:sequencing ancient DNAsequencing ancient DNA
(some assembly required)
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J. P. Noonan et al., Science 309, 597 -599 (2005)
6Published by AAAS
J. P. Noonan et al., Science 309, 597 -599 (2005)
Fig. 1. Schematic illustration of the ancient DNA extraction and library construction process
7Published by AAAS
J. P. Noonan et al., Science 309, 597 -599 (2005)
Fig. 2. Characterization of two independent cave bear genomic libraries
Fig. 2. Predicted origin of 9035 clones from library CB1 (A) and 4992 clones from library CB2 (B) are shown, as determined by BLAST comparison to GenBank and environmental sequence databases. Other refers to viral or plasmid-derived DNAs. Distribution of sequence annotation features in 6,775 nucleotides of carnivore sequence from library CB1 (C) and 20,086 nucleotides of carnivore sequence from library CB2 (D) are shown as determined by alignment to the July 2004 dog genome assembly.
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10Published by AAAS
H. N. Poinar et al., Science 311, 392 -394 (2006)
Fig. 1. Characterization of the mammoth metagenomic library, including percentage of read distributions to various taxa
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JournalsJournals
• The very best:• Science• www.sciencemag.org
• Nature• www.nature.com/nature
• PLoS Biology• www.plosbiology.org
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Bioinformatics JournalsBioinformatics Journals•Bioinformatics• bioinformatics.oxfordjournals.org
•BMC Bioinformatics• www.biomedcentral.com/bioinformatics
• PLoS Computational Biology• compbiol.plosjournals.org
• Journal of Computational Biology• www.liebertpub.com/cmb
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Radically new journalsRadically new journals• PLoS ONE• www.plosone.org
•Biology Direct• www.biology-direct.com• Reviewers’ comments are public
Both journals can be annotated by readersPapers can be negative results,
confirmations of other results, or brand new
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Genomics JournalsGenomics Journals•Genome Biology• genomebiology.com
•Genome Research• www.genome.org
•Nucleic Acids Research• nar.oxfordjournals.org
•BMC Genomics• www.biomedcentral.com/bmcgenomics
Before assembly…Before assembly…
… we need to cover a basic sequence alignment algorithm
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Sequence AlignmentSequence AlignmentWhen we have very similar sequences:
• Closely related species• Very little changed sequence• Small differences can be very important• Computationally “easy” to align• Assembly ONLY deals with these
When sequences are not so similar:• Distantly related species• Most positions changed• Sequences that are most highly conserved are under the
strongest selective (evolutionary) pressure.– E.g., some genes in humans and E. coli clearly have a
common ancestor, the proteins can be aligned• Computationally “difficult” to align
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Sequence AlignmentSequence Alignment
Algorithms for sequence alignment• Choose best alignment, subject to some mutation
model.
• A common (but overly simplistic) model for DNA mutations is called “edits”, which counts the number of substitutions, insertions and deletions.
• The resulting alignment suggests a possible “history” for the sequence.
This slide and subsequent alignment slides courtesy of Nathan Edwards, available atwww.umiacs.umd.edu/~nedwards/teaching/CMSC858E_Fall_2005/
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Example AlignmentsExample Alignments
ACGTCTAG
||*****^
ACTCTAG-
2 matches, 5 mismatches, 1 not aligned
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Example AlignmentsExample Alignments
ACGTCTAG
^**|||||
-ACTCTAG
5 matches, 2 mismatches, 1 not aligned
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Example AlignmentsExample Alignments
ACGTCTAG ||^||||| AC-TCTAG
7 matches, 0 mismatches, 1 not aligned
Edit distance here = 1
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Example AlignmentsExample Alignments
...AACTGAGTTTACGCGCATAGA... |^^^||^|^^| T---CG-A--G
Many equally good alignments!
Even exact matching sequence can be found (at random) in long enough sequences
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Global Alignment problemGlobal Alignment problem
Given two related sequences, S (length n) and T (length m), find an alignment of S and T.
Edit distance: minimum number of substitutions, insertions and deletions.
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Dynamic Programming for Dynamic Programming for pairwise alignmentpairwise alignment
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Dynamic Programming Dynamic Programming FormulationFormulation
Definition: Let D(i,j) be the edit distance of the alignment of S[1...i] and T[1...j].
Edit distance of S and T, then, is D(n,m).
Dynamic programming solves the global alignment problem by computing D(i,j) for all i=0...n and j=0...m.
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Recurrence Relation for DRecurrence Relation for D
Computation of D is a recursive/iterative process.• D(i,j) in terms of D(i’,j’) for i’ < i and j’ < j.
Base conditions for D(i,j):
• D(i,0) = i, for all i = 0,...,n• D(0,j) = j, for all j = 0,...,m
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Recurrence relation for DRecurrence relation for D
For i > 0, j > 0:
D(i,j) = min {
D(i-1,j) + 1,
D(i,j-1) + 1,
D(i-1,j-1) + δ(S(i),T(j)) }
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Dynamic programmingDynamic programming
D(i,j) is computed by optimally solving sub-problems
The optimal solution to D(i,j) is a simple combination (addition) of two optimally solved subproblems
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Using the recurrenceUsing the recurrence
We could code this as a recursive function call...• ...but an exponential number of function
evaluations–each position explores 3 alternatives
There are only (n+1)x(m+1) pairs i and j• We must be evaluating D(i,j) multiple times• Why not cache the results?
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Using the recurrenceUsing the recurrenceCompute D(i,j) bottom up.
Store the intermediate results in a table (the table we already saw).
Start with smallest (i,j) = (1,1).
Compute D(i,j) after D(i-1,j), D(i,j-1), and D(i-1,j-1) have been determined.
(n+1)(m+1) cells to fill, so O(nm) time.
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TracebackTraceback
Our dynamic programming table helps us compute the edit distance “score”
We need the actual alignment corresponding to this edit distance
The corresponding alignment can be read off, by doing a little extra accounting.
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TracebackTraceback
If D(i,j) == D(i-1,j) + 1,Pointer(i,j) = (i-1,j)
If D(i,j) == D(i,j-1) + 1,Pointer(i,j) = (i,j-1)
If D(i,j) == D(i-1,j-1) + δ(S(i),T(j)),Pointer(i,j) = (i-1,j-1)
Break ties arbitrarily, or keep multiple pointers
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TracebackTracebackFollow the pointers from cell (n,m).
Any path to (0,0) corresponds to the (reverse of the) edits of the optimal alignment• “horizontal” pointers: insertion in S• “vertical” pointers: insertion in T• “diagonal” pointers: match or substitution
An optimal alignment can be found in O(n+m) time.
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Original referencesOriginal references
T.F. Smith and M.S. Waterman, Identification of common molecular subsequences. J. Molecular Biology (1981), 147(1):195-7.
Altschul SF, Gish W, Miller W, Myers EW, and Lipman DJ. Basic local alignment search tool. J. Molecular Biology (1990), 215(3):403-10.
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