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Predicting RNA Structure and Function

Predicting RNA Structure and Function. Ribozyme. The Ribosome : The protein factory of the cell mainly made of RNA. Non coding DNA (98.5% human genome). Intergenic Repetitive elements Promoters Introns untranslated region (UTR). Some biological functions of ncRNA.

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Predicting RNA Structure and Function

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  1. PredictingRNA Structure and Function

  2. Ribozyme

  3. The Ribosome : The protein factory of the cell mainly made of RNA

  4. Non coding DNA (98.5% human genome) • Intergenic • Repetitive elements • Promoters • Introns • untranslated region (UTR)

  5. Some biological functions of ncRNA • Control of mRNA stability (UTR) • Control of splicing (snRNP) • Control of translation (microRNA) The function of the RNA molecule depends on its folded structure

  6. Example:Control of Ironlevels by mRNA structure Iron Responsive Element IRE G U A G CN N N’ N N’ N N’ N N’ C N N’ N N’ N N’ N N’ N N’ conserved Recognized by IRP1, IRP2 5’ 3’

  7. Low Iron IRE-IRP inhibits translation of ferritin IRE-IRP Inhibition of degradation of TR High Iron IRE-IRP off -> ferritin translated Transferin receptor degradated F: Ferritin = iron storage TR: Transferin receptor = iron uptake IRP1/2 IRE 3’ 5’ F mRNA IRP1/2 3’ TR mRNA 5’

  8. RNA Structural levels Tertiary Structure Secondary Structure tRNA

  9. 3’ G A U C U U G A U C RNA Secondary Structure • The RNA molecule folds on itself. • The base pairing is as follows: G C A U G U hydrogen bond. LOOP U U C G U A A U G C 5’ 3’ STEM 5’

  10. RNA Secondary structureShort Range Interactions HAIRPIN LOOP G G A U U G C C G G A U A A U G C AG C U U BULGE INTERNAL LOOP STEM DANGLING ENDS 5’ 3’

  11. long range interactions of RNA secondary structural elements These patterns are excluded from the prediction schemes as their computation is too intensive. Pseudo-knot Kissing hairpins Hairpin-bulge contact

  12. Predicting RNA secondary Structure • Searching for a structure with Minimal Free Energy (MFE)

  13. Free energy model • Free energy of structure (at fixed temperature, ionic concentration) = sum of loop energies • Standard model uses experimentally determined thermodynamic parameters

  14. Why is MFE secondary structure prediction hard? • MFE structure can be found by calculating free energy of all possible structures • but, number of potential structures grows exponentially with the number, n, of bases • structures can be arbitrarily complex

  15. RNA folding with Dynamic programming (Zuker and Steigler) • W(i,j): MFE structure of substrand from i to j W(i,j) i j

  16. RNA folding with dynamic programming • Assume a function W(i,j) which is the MFE for the sequence starting at i and ending at j (i<j) • Define scores, for example a base pair’s score is less than a non-pair • Consider 4 recursion possibilities: • i,jare a base pair, added to the structure for i+1..j-1 • Define this as V(i,j) • i is unpaired, added to the structure for i+1..j • j is unpaired, added to the structure for i..j-1 • i,j are paired, but not to each other; the structure for i..j adds together sub-structures for 2 sub-sequences: i..k and k+1..j a bifurcation (i<k<j) • Choose the minimal energy possibility

  17. Simplifying Assumptions for Structure Prediction • RNA folds into one minimum free-energy structure. • There are no knots (base pairs never cross). • The energy of a particular base pair in a double stranded regions is calculated independently • Neighbors do not influence the energy.

  18. Sequence dependent free-energy Nearest Neighbor Model U U C G U A A U G C A UCGAC 3’ U U C G G C A U G C A UCGAC 3’ 5’ 5’ • Assign negative energies to interactions between base pair regions. • Energy is influenced by the previous base pair • (not by the base pairs further down).

  19. Sequence dependent free-energy values of the base pairs (nearest neighbor model) U U C G U A A U G C A UCGAC 3’ U U C G G C A U G C A UCGAC 3’ 5’ 5’ • These energies are estimated experimentally from small synthetic RNAs. Example values: GC GC GC GC AU GC CG UA -2.3 -2.9 -3.4 -2.1

  20. Mfold :Adding Complexity to Energy Calculations • Positive energy - added for destabilizing regions such as bulges, loops, etc. • More than one structure can be predicted

  21. Free energy computation U U A A G C G C A G C U A A U C G A U A3’ A 5’ +5.9 4 nt loop -1.1 mismatch of hairpin -2.9 stacking +3.3 1nt bulge -2.9 stacking -1.8 stacking -0.9 stacking -1.8 stacking 5’ dangling -2.1 stacking -0.3 G= -4.6 KCAL/MOL -0.3

  22. Prediction Tools based on Energy Calculation Fold, Mfold Zucker & Stiegler (1981) Nuc. Acids Res. 9:133-148 Zucker (1989) Science 244:48-52 RNAfold Vienna RNA secondary structure server Hofacker (2003) Nuc. Acids Res. 31:3429-3431

  23. Insight from Multiple Alignment Information from multiple sequence alignment (MSA) can help to predict the probability of positions i,j to be base-paired. G C C U U C G G G C G A C U U C G G U C G G C U U C G G C C

  24. Compensatory Substitutions Mutations that maintain the secondary structure U U C G U A A U G C A UCGAC 3’ C G 5’

  25. RNA secondary structure can be revealed by identification of compensatory mutations U C U G C G N N’ G C G C C U U C G G G C G A C U U C G G U C G G C U U C G G C C

  26. Insight from Multiple Alignment Information from multiple sequence alignment (MSA) can help to predict the probability of positions i,j to be base-paired. • Conservation – no additional information • Consistent mutations (GC GU) – support stem • Inconsistent mutations – does not support stem. • Compensatory mutations – support stem.

  27. RNAalifold (Hofacker 2002) From the vienna RNA package Predicts the consensus secondary structure for a set of aligned RNA sequences by using modified dynamic programming algorithm that add alignment information to the standard energy model Improvement in prediction accuracy

  28. Other related programs Sean Eddy’s Lab WU http://www.genetics.wustl.edu/eddy • COVE RNA structure analysis using the covariance model (implementation of the stochastic free grammar method) • QRNA (Rivas and Eddy 2001) Searching for conserved RNA structures • tRNAscan-SEtRNA detection in genome sequences

  29. RNA families • Rfam : General non-coding RNA database (most of the data is taken from specific databases) http://www.sanger.ac.uk/Software/Rfam/ Includes many families of non coding RNAs and functional motifs, as well as their alignment and their secondary structures

  30. Rfam /Pfam • Pfam uses the HMMER (based on Hidden Markov Models) • Rfam uses the INFERNAL (based on Covariation Model)

  31. Rfam (currently version 7.0) • Different RNA families or functional Motifs from mRNA, UTRs etc. • View and download multiple sequence alignments • Read family annotation • Examine species distribution of family members • Follow links to otherdatabases

  32. An example of an RNA family miR-1 MicroRNAs mir-1 microRNA precursor family This family represents the microRNA (miRNA) mir-1 family. miRNAs are transcribed as ~70nt precursors (modelled here) and subsequently processed by the Dicer enzyme to give a ~22nt product. The products are thought to have regulatory roles through complementarity to mRNA.

  33. Seed alignment (based on 7 sequences)

  34. Predicting microRNA target

  35. Predicting microRNA target genes • Why is it hard?? • Lots of known miRNAs • Mostly unknown target genes • Initial method outline • Look at conserved miRNAs • Look for conserved target sites

  36. miRNAs in animals • 0.5%-1.0% of predicted genes encode miRNA (!!) • One of the more abundant regulatory classes • Tissue-specific or developmental stage-specific expression • High evolutionary conservation

  37. TargetScan Algorithm by Lewis et al 2003 The Goal – a ranked list of candidate target genes • Stage 1: Search UTRs in one organism • Bases 2-8 from miRNA = “miRNA seed” • Perfect Watson-Crick complementarity • No wobble pairs (G-U) • 7nt matches = “seed matches”

  38. TargetScan Algorithm • Stage 2: Extend seed matches • Allow G-U (wobble) pairs • Both directions • Stop at mismatches

  39. TargetScan Algorithm • Stage 3: Optimize basepairing • Remaining 3’ region of miRNA • 35 bases of UTR 5’ to each seed match • RNAfold program (Hofacker et al 1994)

  40. TargetScan Algorithm • Stage 4: Folding free energy (G) assigned to each putative miRNA:target interaction • Assign rank to each UTR • Repeat this process for each of the other organisms with UTR datasets

  41. Predicting RNA-binding protein (RBP) targets

  42. Predicting RBPs target • Different types of RBPs • Proteins that regulate RNA stability (bind usually at the 3’UTR) • Splicing Factors (bind exonic and intronic regions) • …… • Why is it hard • Different proteins bind different sequences • Most RBP sites are short and degenertaive (e.g. CTCTCT )

  43. Predicting Exon Splicing Enhancers ESE-finder (Krainer) 1. Built PSSM for ESE, based on experimental data (SELEX)

  44. ESE-finder 2. A given sequence is tested against 5 PSSM in overlapping windows 3. Each position in the sequence is given a score 4. Position which fit a PSSM (score above a cutoff) are predicted as ESEs

  45. Predicting RBPs target • RNA binding sites can be predicted by general motif finders • MEME http://metameme.sdsc.edu/mhmm-overview.html • DRIM http://bioinfo.cs.technion.ac.il/drim/

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