1. Sequence motifs, information content, logos, and Weight matrices
Morten Nielsen,
CBS, BioCentrum,
DTU

2. Objectives Visualization of binding motifs
Construction of sequence logos
Understand the concepts of weight matrix construction
One of the most important methods of bioinformatics

3. Outline Pattern recognition Information content
Regular expressions and probabilities
Information content
Sequence logos
Kullback-Leibler
Multiple alignment and sequence motifs
Weight matrix construction
Sequence weighting
Low (pseudo) counts
Calculate a weight matrix from a sequence alignment
Examples from the real world
MHC class II binding
Gibbs sampling

4. Host/virus interaction. Sars infection

5. Immune system

6. Processing of intracellular proteins

7. Encounter with death

8. Binding Motif. MHC class I with peptide
Anchor positions

9. Sequence information
SLLPAIVEL YLLPAIVHI TLWVDPYEV GLVPFLVSV KLLEPVLLL LLDVPTAAV LLDVPTAAV LLDVPTAAV
LLDVPTAAV VLFRGGPRG MVDGTLLLL YMNGTMSQV MLLSVPLLL SLLGLLVEV ALLPPINIL TLIKIQHTL
HLIDYLVTS ILAPPVVKL ALFPQLVIL GILGFVFTL STNRQSGRQ GLDVLTAKV RILGAVAKV QVCERIPTI
ILFGHENRV ILMEHIHKL ILDQKINEV SLAGGIIGV LLIENVASL FLLWATAEA SLPDFGISY KKREEAPSL
LERPGGNEI ALSNLEVKL ALNELLQHV DLERKVESL FLGENISNF ALSDHHIYL GLSEFTEYL STAPPAHGV
PLDGEYFTL GVLVGVALI RTLDKVLEV HLSTAFARV RLDSYVRSL YMNGTMSQV GILGFVFTL ILKEPVHGV
ILGFVFTLT LLFGYPVYV GLSPTVWLS WLSLLVPFV FLPSDFFPS CLGGLLTMV FIAGNSAYE KLGEFYNQM
KLVALGINA DLMGYIPLV RLVTLKDIV MLLAVLYCL AAGIGILTV YLEPGPVTA LLDGTATLR ITDQVPFSV
KTWGQYWQV TITDQVPFS AFHHVAREL YLNKIQNSL MMRKLAILS AIMDKNIIL IMDKNIILK SMVGNWAKV
SLLAPGAKQ KIFGSLAFL ELVSEFSRM KLTPLCVTL VLYRYGSFS YIGEVLVSV CINGVCWTV VMNILLQYV
ILTVILGVL KVLEYVIKV FLWGPRALV GLSRYVARL FLLTRILTI HLGNVKYLV GIAGGLALL GLQDCTMLV
TGAPVTYST VIYQYMDDL VLPDVFIRC VLPDVFIRC AVGIGIAVV LVVLGLLAV ALGLGLLPV GIGIGVLAA
GAGIGVAVL IAGIGILAI LIVIGILIL LAGIGLIAA VDGIGILTI GAGIGVLTA AAGIGIIQI QAGIGILLA
KARDPHSGH KACDPHSGH ACDPHSGHF SLYNTVATL RGPGRAFVT NLVPMVATV GLHCYEQLV PLKQHFQIV
AVFDRKSDA LLDFVRFMG VLVKSPNHV GLAPPQHLI LLGRNSFEV PLTFGWCYK VLEWRFDSR TLNAWVKVV
GLCTLVAML FIDSYICQV IISAVVGIL VMAGVGSPY LLWTLVVLL SVRDRLARL LLMDCSGSI CLTSTVQLV
VLHDDLLEA LMWITQCFL SLLMWITQC QLSLLMWIT LLGATCMFV RLTRFLSRV YMDGTMSQV FLTPKKLQC
ISNDVCAQV VKTDGNPPE SVYDFFVWL FLYGALLLA VLFSSDFRI LMWAKIGPV SLLLELEEV SLSRFSWGA
YTAFTIPSI RLMKQDFSV RLPRIFCSC FLWGPRAYA RLLQETELV SLFEGIDFY SLDQSVVEL RLNMFTPYI
NMFTPYIGV LMIIPLINV TLFIGSHVV SLVIVTTFV VLQWASLAV ILAKFLHWL STAPPHVNV LLLLTVLTV
VVLGVVFGI ILHNGAYSL MIMVKCWMI MLGTHTMEV MLGTHTMEV SLADTNSLA LLWAARPRL GVALQTMKQ
GLYDGMEHL KMVELVHFL YLQLVFGIE MLMAQEALA LMAQEALAF VYDGREHTV YLSGANLNL RMFPNAPYL
EAAGIGILT TLDSQVMSL STPPPGTRV KVAELVHFL IMIGVLVGV ALCRWGLLL LLFAGVQCQ VLLCESTAV
YLSTAFARV YLLEMLWRL SLDDYNHLV RTLDKVLEV GLPVEYLQV KLIANNTRV FIYAGSLSA KLVANNTRL
FLDEFMEGV ALQPGTALL VLDGLDVLL SLYSFPEPE ALYVDSLFF SLLQHLIGL ELTLGEFLK MINAYLDKL
AAGIGILTV FLPSDFFPS SVRDRLARL SLREWLLRI LLSAWILTA AAGIGILTV AVPDEIPPL FAYDGKDYI
AAGIGILTV FLPSDFFPS AAGIGILTV FLPSDFFPS AAGIGILTV FLWGPRALV ETVSEQSNV ITLWQRPLV

10. Sequence Information
Say that a peptide must have L at P2 in order to bind, and that A,F,W,and Y are found at P1. Which position has most information?
How many questions do I need to ask to tell if a peptide binds looking at only P1 or P2?
P1: 4 questions (at most)
P2: 1 question (L or not)
P2 has the most information
Calculate pa at each position
Entropy
Information content
Conserved positions
PV=1, P!v=0 => S=0, I=log(20)
Mutable positions
Paa=1/20 => S=log(20), I=0

11. Information content
A R N D C Q E G H I L K M F P S T W Y V S I

12. Sequence logos Height of a column equal to I
HLA-A0201
Height of a column equal to I
Relative height of a letter is p
Highly useful tool to visualize sequence motifs
High information
positions

13. Kullback Leibler Logo

14. Characterizing a binding motif from small data sets
10 MHC restricted peptides
What can we learn?
A at P1 favors
binding?
I is not allowed at P9?
K at P4 favors binding?
Which positions are important for binding?
ALAKAAAAM
ALAKAAAAN
ALAKAAAAR
ALAKAAAAT
ALAKAAAAV
GMNERPILT
GILGFVFTM
TLNAWVKVV
KLNEPVLLL
AVVPFIVSV

15. Simple motifs Yes/No rules
10 MHC restricted peptides
ALAKAAAAM
ALAKAAAAN
ALAKAAAAR
ALAKAAAAT
ALAKAAAAV
GMNERPILT
GILGFVFTM
TLNAWVKVV
KLNEPVLLL
AVVPFIVSV
Only 11 of 212 peptides identified!
Need more flexible rules
If not fit P1 but fit P2 then ok
Not all positions are equally important
We know that P2 and P9 determines binding more than other positions
Cannot discriminate between good and very good binders

16. Simple motifs Yes/No rules
10 MHC restricted peptides
ALAKAAAAM
ALAKAAAAN
ALAKAAAAR
ALAKAAAAT
ALAKAAAAV
GMNERPILT
GILGFVFTM
TLNAWVKVV
KLNEPVLLL
AVVPFIVSV
Example
Two first peptides will not fit the motif. They are all good binders (aff< 500nM)
RLLDDTPEV 84 nM
GLLGNVSTV 23 nM
ALAKAAAAL 309 nM

17. Extended motifs Fitness of aa at each position given by P(aa)
Example P1
PA = 6/10
PG = 2/10
PT = PK = 1/10
PC = PD = …PV = 0
Problems
Few data
Data redundancy/duplication
ALAKAAAAM
ALAKAAAAN
ALAKAAAAR
ALAKAAAAT
ALAKAAAAV
GMNERPILT
GILGFVFTM
TLNAWVKVV
KLNEPVLLL
AVVPFIVSV
RLLDDTPEV 84 nM
GLLGNVSTV 23 nM
ALAKAAAAL 309 nM

18. Sequence information Raw sequence counting
ALAKAAAAM
ALAKAAAAN
ALAKAAAAR
ALAKAAAAT
ALAKAAAAV
GMNERPILT
GILGFVFTM
TLNAWVKVV
KLNEPVLLL
AVVPFIVSV

19. } Sequence weighting Poor or biased sampling of sequence space
ALAKAAAAM
ALAKAAAAN
ALAKAAAAR
ALAKAAAAT
ALAKAAAAV
GMNERPILT
GILGFVFTM
TLNAWVKVV
KLNEPVLLL
AVVPFIVSV }
Similar sequences
Weight 1/5
Poor or biased sampling of sequence space
Example P1
PA = 2/6
PG = 2/6
PT = PK = 1/6
PC = PD = …PV = 0
RLLDDTPEV 84 nM
GLLGNVSTV 23 nM
ALAKAAAAL 309 nM

20. Sequence weighting ALAKAAAAM ALAKAAAAN ALAKAAAAR ALAKAAAAT ALAKAAAAV
GMNERPILT
GILGFVFTM
TLNAWVKVV
KLNEPVLLL
AVVPFIVSV

21. Pseudo counts ALAKAAAAM
ALAKAAAAN
ALAKAAAAR
ALAKAAAAT
ALAKAAAAV
GMNERPILT
GILGFVFTM
TLNAWVKVV
KLNEPVLLL
AVVPFIVSV
I is not found at position P9. Does this mean that I is forbidden (P(I)=0)?
No! Use Blosum substitution matrix to estimate pseudo frequency of I at P9

22. What is a pseudo count? Say V is observed at P1
A R N D C Q E G H I L K M F P S T W Y V A R N D C …. Y V
Say V is observed at P1
Knowing that V at P1 binds, what is the probability that a peptide could have I at P1?
P(I|V) = 0.16

23. Pseudo count estimation
ALAKAAAAM
ALAKAAAAN
ALAKAAAAR
ALAKAAAAT
ALAKAAAAV
GMNERPILT
GILGFVFTM
TLNAWVKVV
KLNEPVLLL
AVVPFIVSV
Calculate observed amino acids frequencies fa
Pseudo frequency for amino acid b
Example

24. Weight on pseudo count
ALAKAAAAM
ALAKAAAAN
ALAKAAAAR
ALAKAAAAT
ALAKAAAAV
GMNERPILT
GILGFVFTM
TLNAWVKVV
KLNEPVLLL
AVVPFIVSV
Pseudo counts are important when only limited data is available
With large data sets only “true” observation should count
 is the effective number of sequences (N-1),  is the weight on prior

25. Weight on pseudo count Example
ALAKAAAAM
ALAKAAAAN
ALAKAAAAR
ALAKAAAAT
ALAKAAAAV
GMNERPILT
GILGFVFTM
TLNAWVKVV
KLNEPVLLL
AVVPFIVSV
Example
If  large, p ≈ f and only the observed data defines the motif
If  small, p ≈ g and the pseudo counts (or prior) defines the motif
 is [50-200] normally

26. Sequence weighting and pseudo counts
ALAKAAAAM
ALAKAAAAN
ALAKAAAAR
ALAKAAAAT
ALAKAAAAV
GMNERPILT
GILGFVFTM
TLNAWVKVV
KLNEPVLLL
AVVPFIVSV
RLLDDTPEV 84nM
GLLGNVSTV 23nM
ALAKAAAAL 309nM
P7P and P7S > 0

27. Position specific weighting
We know that positions 2 and 9 are anchor positions for most MHC binding motifs
Increase weight on high information positions
Motif found on large data set

28. Weight matrices
Estimate amino acid frequencies from alignment including sequence weighting and pseudo count
What do the numbers mean?
P2(V)>P2(M). Does this mean that V enables binding more than M.
In nature not all amino acids are found equally often
In nature V is found more often than M, so we must somehow rescale with the background
qM = 0.025, qV = 0.073
Finding 5% V is hence not significant, but 5% M highly significant
A R N D C Q E G H I L K M F P S T W Y V

29. Weight matrices A weight matrix is given as Wij = log(pij/qj)
where i is a position in the motif, and j an amino acid. qj is the background frequency for amino acid j.
W is a L x 20 matrix, L is motif length
A R N D C Q E G H I L K M F P S T W Y V

30. Scoring a sequence to a weight matrix
Score sequences to weight matrix by looking up and adding L values from the matrix
A R N D C Q E G H I L K M F P S T W Y V
Which peptide is most likely to bind?
Which peptide second?
RLLDDTPEV
GLLGNVSTV
ALAKAAAAL
11.9
14.7
4.3
84nM
23nM
309nM

31. An example!! (See handout)

33. The Blosum matrix A R N D C Q E G H I L K M F P S T W Y V

35. Example from real life 10 peptides from MHCpep database
Bind to the MHC complex
Relevant for immune system recognition
Estimate sequence motif and weight matrix
Evaluate motif “correctness” on 528 peptides
ALAKAAAAM
ALAKAAAAN
ALAKAAAAR
ALAKAAAAT
ALAKAAAAV
GMNERPILT
GILGFVFTM
TLNAWVKVV
KLNEPVLLL
AVVPFIVSV

36. Prediction accuracy Measured affinity Prediction score
Pearson correlation 0.45
Measured affinity
Prediction score

37. Predictive performance

38. Class II MHC binding
MHC class II binds peptides in the class II antigen presentation pathway
Binds peptides of length 9-18 (even whole proteins can bind!)
Binding cleft is open
Binding core is 9 aa

39. Gibbs sampler www.cbs.dtu.dk/biotools/EasyGibbs
100 10mer peptides
2100~1030 combinations
Monte Carlo simulations can do it

40. Gibbs sampler. Prediction accuracy

41. Gibbs sampling can detect MHC class II binding motif
Summary
Weight matrices can accurately describe a sequence motif like MHC class I
Use sequence weighting to remove data redundancy
Use pseudo count to compensate for few data points
Gibbs sampling can detect MHC class II binding motif