Sequence analysis June 18, 2008 Learning objectives-Understand the concept of sliding window...
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Transcript of Sequence analysis June 18, 2008 Learning objectives-Understand the concept of sliding window...
Sequence analysis
June 18, 2008
Learning objectives-Understand the concept of sliding window programs. Understand difference between identity, similarity and homology. Appreciate that proteins can be modular
Workshop-Learn to recognize amino acid structures. Perform sliding window to compute %G+C as a function of position in sequence. Become familiar with the Dotter program.
Sliding window
A sliding window-gathers information about properties of nucleotides or amino acids.
GCATATGCGCATATCCCGTCAATACCA
GCATATGCGCATATCCCGTCAATACCA
GCATATGCGCATATCCCGTCAATACCA
4
5
6
A simple example is to calculate the %G+C content within a window. Then move the window one nucleotide and repeat the calculation.
Sliding window
If the window is too small it is difficult to detect the trendof the measurement. If too large you could miss meaningfuldata.
Large window size
Small window size
%G+C
%G+C
Sequence number
Sequence number
Dot Plot with window = 1
A T G C C T A G
A T G C C T A G
**
**
**
**
**
**
**
*
*
Window = 1
Note that 25% ofthe table will befilled due to randomchance. 1 in 4 chanceat each position
Dot Plot with window = 3
A T G C C T A GA T G C C T A G
*
**
**
*
Window = 3The larger the windowthe more noise canbe filtered
What is thepercent chance thatyou will receive a match randomly? Onein (four)3
chance.(¼)3 * 100 = 1.56%
{
Four levels of protein structure
1) Primary
2) Secondary
3) Tertiary
4) Quaternary
Linear sequence-AGHIPLLQ
Initial folding patterns-AGHIPLLQTTT
Complex folding patterns-
Interactions between polypeptides
Chou-Fasman Rules (Mathews, Van Holde, Ahern)Amino Acid -Helix -Sheet Turn Ala 1.29 0.90 0.78 Cys 1.11 0.74 0.80 Leu 1.30 1.02 0.59 Met 1.47 0.97 0.39 Glu 1.44 0.75 1.00 Gln 1.27 0.80 0.97 His 1.22 1.08 0.69 Lys 1.23 0.77 0.96 Val 0.91 1.49 0.47 Ile 0.97 1.45 0.51 Phe 1.07 1.32 0.58 Tyr 0.72 1.25 1.05 Trp 0.99 1.14 0.75 Thr 0.82 1.21 1.03 Gly 0.56 0.92 1.64 Ser 0.82 0.95 1.33 Asp 1.04 0.72 1.41 Asn 0.90 0.76 1.23 Pro 0.52 0.64 1.91 Arg 0.96 0.99 0.88
Favors-Helix
Favors-Sheet
FavorsTurns
Chou&Fasman structure prediction
Chou & Fasman [Biochemistry 13(2):222-245 (1974)]. By studying a number of proteins whose structures were known, they were able to determine stretches of amino acids that could serve to form an -helix or a -sheet. These amino acids are called helix formers or sheet formers and can have different strengths for forming their structures. Once these nucleation sites are determined, adjacent amino acids are examined to see if the structure can be extended in either or both directions. Values for some amino acids allow extension, other amino acids do not. Some amino acids are categorized as helix breakers, or sheet breakers. A string of these will terminate the current structure. This method is about 60-65% accurate.
Amino Acid Hydrop. VALUEA 1.8C 2.5D -3.5E -3.5F 2.8G -0.4H -3.2I 4.5K -3.9L 3.8M 1.9N -3.5P -1.6Q -3.5R -4.5S -0.8T -0.7V 4.2W -0.9Y -1.3
Kyte-Doolittle Hydropathy
– Another sliding window routine [J. Mol. Biol. 157:105-132 (1982)]. They determine a "hydropathy scale" for each amino acid based on empirical observations.
1 2 3 4 56 7
Evolutionary Basis of Sequence Alignment
1. Identity: Quantity that describes how muchtwo sequences are alike in the strictest terms.2. Similarity: Quantity that relates how much two amino acid sequences are alike.3. Homology: a conclusion drawn from datasuggesting that two genes share a commonevolutionary history.
Purpose of finding differences and similarities of amino acids in two proteins.
Infer structural information
Infer functional information
Infer evolutionary relationships
One is mouse trypsin and the other is crayfish trypsin.They are homologous proteins. The sequences share 41% identity.
Modular nature of proteins
Proteins possess local regions of similarity.
Proteins can be thought of as assemblies of modular domains.
Modular nature of proteins (cont. 1)
Exon 1a Exon 2a
Duplication of Exon 2a
Exon 1a Exon 2a Exon 2a
Exchange with Gene B
Gene A
Gene A
Gene A
Gene B
Exon 1a Exon 2a Exon 3 (Exon 2b from Gene B)
Exon 1b Exon 2b Exon 3 (Exon 2a from Gene A)
Exon 1b Exon 2b Exon 2bGene B
Similarity
It is easy to score if an amino acid is identical to another (thescore is 1 if identical and 0 if not). However, it is not easy togive a score for amino acids that are somewhat similar.
+NH3CO2
- +NH3CO2
-
Leucine Isoleucine
Should they get a 0 (non-identical) or a 1 (identical) orSomething in between?
Two proteins that are similar in certain regions
Tissue plasminogen activator (PLAT)Coagulation factor 12 (F12).
The Dotter Program
• Program consists of three components:
•Sliding window
•A table that gives a score for each amino acid match
•A graph that converts the score to a dot of certain density (the higher the dot density the higher the score)