Biology:Ramachandran plot

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Short description: Visual representation of allowable protein conformations
Original hard-sphere, reduced-radius, and relaxed-tau φ,ψ regions from Ramachandran, with updated labels and axes
Backbone dihedral angles φ and ψ (and ω). All three angles are at 180° in the conformation shown

In biochemistry, a Ramachandran plot (also known as a Rama plot, a Ramachandran diagram or a [φ,ψ] plot), originally developed in 1963 by G. N. Ramachandran, C. Ramakrishnan, and V. Sasisekharan,[1] is a way to visualize energetically allowed regions for backbone dihedral angles ψ against φ of amino acid residues in protein structure. The figure on the left illustrates the definition of the φ and ψ backbone dihedral angles[2] (called φ and φ' by Ramachandran). The ω angle at the peptide bond is normally 180°, since the partial-double-bond character keeps the peptide bond planar.[3] The figure in the top right shows the allowed φ,ψ backbone conformational regions from the Ramachandran et al. 1963 and 1968 hard-sphere calculations: full radius in solid outline, reduced radius in dashed, and relaxed tau (N-Cα-C) angle in dotted lines.[4] Because dihedral angle values are circular and 0° is the same as 360°, the edges of the Ramachandran plot "wrap" right-to-left and bottom-to-top. For instance, the small strip of allowed values along the lower-left edge of the plot are a continuation of the large, extended-chain region at upper left.

A Ramachandran plot generated from human PCNA, a trimeric DNA clamp protein that contains both β-sheet and α-helix (PDB ID 1AXC). The red, brown, and yellow regions represent the favored, allowed, and "generously allowed" regions as defined by ProCheck

Uses

A Ramachandran plot can be used in two somewhat different ways. One is to show in theory which values, or conformations, of the ψ and φ angles are possible for an amino-acid residue in a protein (as at top right). A second is to show the empirical distribution of datapoints observed in a single structure (as at right, here) in usage for structure validation, or else in a database of many structures (as in the lower 3 plots at left). Either case is usually shown against outlines for the theoretically favored regions.

Amino-acid preferences

One might expect that larger side chains would result in more restrictions and consequently a smaller allowable region in the Ramachandran plot, but the effect of side chains is small.[5] In practice, the major effect seen is that of the presence or absence of the methylene group at Cβ.[5] Glycine has only a hydrogen atom for its side chain, with a much smaller van der Waals radius than the CH3, CH2, or CH group that starts the side chain of all other amino acids. Hence it is least restricted, and this is apparent in the Ramachandran plot for glycine (see Gly plot in gallery) for which the allowable area is considerably larger. In contrast, the Ramachandran plot for proline, with its 5-membered-ring side chain connecting Cα to backbone N, shows a limited number of possible combinations of ψ and φ (see Pro plot in gallery). The residue preceding proline ("pre-proline") also has limited combinations compared to the general case.

More recent updates

The first Ramachandran plot was calculated just after the first protein structure at atomic resolution was determined (myoglobin, in 1960[6]), although the conclusions were based on small-molecule crystallography of short peptides. Now, many decades later, there are tens of thousands of high-resolution protein structures determined by X-ray crystallography and deposited in the Protein Data Bank (PDB). Many studies have taken advantage of this data to produce more detailed and accurate φ,ψ plots (e.g., Morris et al. 1992;[7] Kleywegt & Jones 1996;[8] Hooft et al. 1997;[9] Hovmöller et al. 2002;[10] Lovell et al. 2003;[11] Anderson et al. 2005.[12] Ting et al. 2010[13]).

The four figures below show the datapoints from a large set of high-resolution structures and contours for favored and for allowed conformational regions for the general case (all amino acids except Gly, Pro, and pre-Pro), for Gly, and for Pro.[11] The most common regions are labeled: α for α helix, Lα for left-handed helix, β for β-sheet, and ppII for polyproline II. Such a clustering is alternatively described in the ABEGO system, where each letter stands for α (and 310) helix, right-handed β sheets (and extended structures), left-handed helixes, left-handed sheets, and finally unplottable cis peptide bonds sometimes seen with proline; it has been used in the classification of motifs[14] and more recently for designing proteins.[15]

While the Ramachandran plot has been a textbook resource for explaining the structural behavior of peptide bond, an exhaustive exploration of how a peptide behaves in every region of the Ramachandran plot was only recently published (Mannige 2017[16]).

The Molecular Biophysics Unit at Indian Institute of Science celebrated 50 years of Ramachandran Map[17] by organizing International Conference on Biomolecular Forms and Functions from 8–11 January 2013.[18]

Related conventions

One can also plot the dihedral angles in polysaccharides (e.g. with CARP).[19]

Gallery

Software

References

  1. Ramachandran, G.N.; Ramakrishnan, C.; Sasisekharan, V. (1963). "Stereochemistry of polypeptide chain configurations". Journal of Molecular Biology 7: 95–9. doi:10.1016/S0022-2836(63)80023-6. PMID 13990617. 
  2. Richardson, J.S. (1981). "The Anatomy and Taxonomy of Protein Structure". Anatomy and Taxonomy of Protein Structures. Advances in Protein Chemistry. 34. pp. 167–339. doi:10.1016/S0065-3233(08)60520-3. ISBN 9780120342341. 
  3. Pauling, L.; Corey, H.R.; Branson, H. R. (1951). "The Structure of Proteins: Two Hydrogen-Bonded Helical Configurations of the Polypeptide Chain". Proceedings of the National Academy of Sciences of the United States of America 37 (4): 205–211. doi:10.1073/pnas.37.4.205. PMID 14816373. Bibcode1951PNAS...37..205P. 
  4. Ramachandran, G.N.; Sasiskharan, V. (1968). Conformation of polypeptides and proteins. Advances in Protein Chemistry. 23. pp. 283–437. doi:10.1016/S0065-3233(08)60402-7. ISBN 9780120342235. 
  5. 5.0 5.1 Chakrabarti, Pinak; Pal, Debnath (2001). "The interrelationships of side-chain and main-chain conformations in proteins". Progress in Biophysics and Molecular Biology 76 (1–2): 1–102. doi:10.1016/S0079-6107(01)00005-0. PMID 11389934. 
  6. Kendrew, J.C.; Dickerson, R.E.; Strandberg, B.E.; Hart, R.G.; Davies, D.R.; Phillips, D.C.; Shore, V.C. (1960). "Structure of myoglobin: a three-dimensional Fourier synthesis at 2Å resolution". Nature 185 (4711): 422–427. doi:10.1038/185422a0. PMID 18990802. Bibcode1960Natur.185..422K. 
  7. Morris, A.L.; MacArthur, M.W.; Hutchinson, E G.; Thornton, J.M. (1992). "Stereochemical quality of protein structure coordinates". Proteins: Structure, Function, and Genetics 12 (4): 345–64. doi:10.1002/prot.340120407. PMID 1579569. 
  8. Kleywegt, G.J.; Jones, T.A. (1996). "Phi/psi-chology: Ramachandran revisited". Structure 4 (12): 1395–400. doi:10.1016/S0969-2126(96)00147-5. PMID 8994966. 
  9. Hooft, R.W.W.; Sander, C.; Vriend, G. (1997). "Objectively judging the quality of a protein structure from a Ramachandran plot". Comput Appl Biosci 13 (4): 425–430. doi:10.1093/bioinformatics/13.4.425. PMID 9283757. 
  10. Hovmöller, S.; Zhou, T.; Ohlson, T. (2002). "Conformations of amino acids in proteins". Acta Crystallographica D 58 (Pt 5): 768–76. doi:10.1107/S0907444902003359. PMID 11976487. http://scripts.iucr.org/cgi-bin/paper?S0907444902003359. 
  11. 11.0 11.1 Lovell, S.C.; Davis, I.W.; Arendall, W.B.; De Bakker, P.I.W.; Word, J.M.; Prisant, M.G.; Richardson, J.S.; Richardson, D.C. (2003). "Structure validation by Cα geometry: ϕ,ψ and Cβ deviation". Proteins: Structure, Function, and Genetics 50 (3): 437–50. doi:10.1002/prot.10286. PMID 12557186. 
  12. "Main-chain conformational tendencies of amino acids". Proteins 60 (4): 679–89. 2005. doi:10.1002/prot.20530. PMID 16021632. 
  13. 13.0 13.1 Ting, D.; Wang, G.; Mitra, R.; Jordan, M.I.; Dunbrack, R.L. (2010). "Neighbor-dependent Ramachandran probability distributions of amino acids developed from a hierarchical Dirichlet process model". PLOS Computational Biology 6 (4): e1000763. doi:10.1371/journal.pcbi.1000763. PMID 20442867. Bibcode2010PLSCB...6E0763T. 
  14. Wintjens, René T.; Rooman, Marianne J.; Wodak, Shoshana J. (January 1996). "Automatic Classification and Analysis of αα-Turn Motifs in Proteins". Journal of Molecular Biology 255 (1): 235–253. doi:10.1006/jmbi.1996.0020. PMID 8568871. 
  15. Lin, Yu-Ru; Koga, Nobuyasu; Tatsumi-Koga, Rie; Liu, Gaohua; Clouser, Amanda F.; Montelione, Gaetano T.; Baker, David (6 October 2015). "Control over overall shape and size in de novo designed proteins". Proceedings of the National Academy of Sciences 112 (40): E5478–E5485. doi:10.1073/pnas.1509508112. PMID 26396255. Bibcode2015PNAS..112E5478L. 
  16. Mannige, Ranjan (16 May 2017). "An exhaustive survey of regular peptide conformations using a new metric for backbone handedness (h)". PeerJ 5: e3327. doi:10.7717/peerj.3327. PMID 28533975. 
  17. "50th Anniversary of Ramachandran Plots". Professor Laurence A. Moran. http://sandwalk.blogspot.in/2013/01/50th-anniversary-of-ramachandran-plots.html. Retrieved 17 January 2013. 
  18. "ICBFF-2013". MBU, IISc, Bangalore. http://icbff2013.com/. Retrieved 28 January 2013. 
  19. Lütteke, T.; Frank, M.; von der Lieth, C.W. (2005). "Carbohydrate Structure Suite (CSS): analysis of carbohydrate 3D structures derived from the PDB". Nucleic Acids Res 33 (Database issue): D242–246. doi:10.1093/nar/gki013. PMID 15608187. 

Further reading

  • Branden, C.-I.; Tooze, J. (1991), Introduction to Protein Structure, Garland Publishing, NY, ISBN 0-8153-0344-0 

External links