817 lines
27 KiB
R
817 lines
27 KiB
R
# RPR-SX-PDB.R
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#
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# Purpose: A Bioinformatics Course:
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# R code accompanying the RPR-SX-PDB unit.
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#
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# Version: 1.0
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#
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# Date: 2017 10 19
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# Author: Boris Steipe (boris.steipe@utoronto.ca)
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#
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# Versions:
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# 1.0 First live version, completely refactores 2016 code
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# with remarkable speed gains. Added section on x, y, z
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# (density) plots.
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# 0.1 First code copied from 2016 material.
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#
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# TODO:
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# Confirm that SS residue numbers are indices
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# Set task seed from student number
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#
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# == DO NOT SIMPLY source() THIS FILE! =======================================
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#
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# If there are portions you don't understand, use R's help system, Google for an
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# answer, or ask your instructor. Don't continue if you don't understand what's
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# going on. That's not how it works ...
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#
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# ==============================================================================
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#TOC> ==========================================================================
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#TOC>
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#TOC> Section Title Line
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#TOC> ----------------------------------------------------
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#TOC> 1 Introduction to the bio3D package 63
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#TOC> 2 A Ramachandran plot 151
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#TOC> 3 Density plots 227
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#TOC> 3.1 Density-based colours 241
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#TOC> 3.2 Plotting with smoothScatter() 260
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#TOC> 3.3 Plotting hexbins 275
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#TOC> 3.4 Plotting density contours 299
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#TOC> 3.4.1 ... as overlay on a colored grid 333
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#TOC> 3.4.2 ... as filled countour 350
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#TOC> 3.4.3 ... as a perspective plot 381
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#TOC> 4 cis-peptide bonds 399
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#TOC> 5 H-bond lengths 414
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#TOC>
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#TOC> ==========================================================================
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# In this example of protein structure interpretation, we ...
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# - load the library "bio3D" which supports work with
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# protein structure files,
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# - explore some elementary functions of the library
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# - explore plotting of density values with scatterplots
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# - assemble a script to see whether H-bond lengths systematically differ
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# between alpha-helical and beta-sheet structures.
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# = 1 Introduction to the bio3D package ===================================
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if (! require(bio3d, quietly=TRUE)) {
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install.packages("bio3d")
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library(bio3d)
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}
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# Package information:
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# library(help = bio3d) # basic information
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# browseVignettes("bio3d") # available vignettes
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# data(package = "bio3d") # available datasets
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# bio3d can load molecules directly from the PDB servers, you don't _have_ to
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# store them locally, but you could.
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#
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# But before you _load_ a file, have a look what such a file contains. I have
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# packaged the 1BM8 file into the project:
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file.show("./data/1BM8.pdb")
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# Have a look at the header section, the atom records, the coordinate records
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# etc.
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#
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# Task: Answer the following questions:
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#
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# What is the resolution of the structure?
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# Is the first residue in the SEQRES section also the first residue
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# with an ATOM record?
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# How many water molecules does the structure contain?
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# Can you explain REMARK 525 regarding HOH 459 and HOH 473?
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# Are all atoms of the N-terminal residue present?
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# Are all atoms of the C-terminal residue present?
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apses <- read.pdb("1bm8") # load a molecule directly from the PDB via the
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# Internet. (This is not your local version.)
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# check what we have:
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apses
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# what is this actually?
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str(apses)
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# bio3d's pdb objects are simple lists. Great! You know lists!
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# You see that there is a list element called $atom which is a data frame in
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# which the columns arevectors of the same length - namely the number of atoms
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# in the structure file. And there is a matrix of (x, y, z) triplets called xyz.
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# And there is a vector that holds sequence, and two tables called helix and
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# sheet. Let's pull out a few values to confirm how selection and subsetting
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# works here:
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# selection by atom ...
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i <- 5
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apses$atom[i,]
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apses$atom[i, c("x", "y", "z")] # here we are selecting with column names!
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apses$xyz[c(i*3-2, i*3-1, i*3)] # here we are selcting with row numbers
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# all atoms of a residue ...
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i <- 48
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apses$atom[apses$atom[,"resno"] == i, ]
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# sequence of the first ten residues
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apses$seqres[1:10] # the "A"s here identify chain "A"
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# Can we convert this to one letter code?
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aa321(apses$seqres[1:10])
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# Lets get the implicit sequence:
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aa321((apses$atom$resid[apses$calpha])[1:10]) # Do you understand this code?
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# Do explicit and implicit sequence have the same length?
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length(apses$seqres)
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length(apses$atom$resid[apses$calpha])
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# Are the sequences the same?
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sum(apses$seqres == apses$atom$resid[apses$calpha])
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# get a list of all CA atoms of arginine residues
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sel <- apses$atom$resid == "ARG" & apses$atom$elety == "CA"
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apses$atom[sel, c("eleno", "elety", "resid", "chain", "resno", "insert")]
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# The introduction to bio3d tutorial at
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# http://thegrantlab.org/bio3d/tutorials/structure-analysis
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# has the following example:
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plot.bio3d(apses$atom$b[apses$calpha], sse=apses, typ="l", ylab="B-factor")
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# Good for now. Let's do some real work.
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# = 2 A Ramachandran plot =================================================
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# Calculate a Ramachandran plot for the structure. The torsion.pdb() function
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# calculates all dihedral angles for backbone and sidechain bonds, NA where
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# the bond does not exist in an amino acid.
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tor <- torsion.pdb(apses)
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plot(tor$phi, tor$psi,
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xlim = c(-180, 180), ylim = c(-180, 180),
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main = "Ramachandran plot for 1BM8",
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xlab = expression(phi),
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ylab = expression(psi))
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abline(h = 0, lwd = 0.5, col = "#00000044")
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abline(v = 0, lwd = 0.5, col = "#00000044")
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# As you can see, there are a number of points in the upper-right
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# quadrant of the plot. This combination of phi-psi angles defines
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# the conformation of a left-handed alpha helix and is generally
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# only observed for glycine residues. Let's replot the data, but
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# color the points for glycine residues differently. First, we
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# get a vector of glycine residue indices in the structure:
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mySeq <- pdbseq(apses)
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# Explore the result object and extract the indices of GLY resiues.
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mySeq == "G"
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which(mySeq == "G")
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iGly <- which(mySeq == "G")
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# Now plot all non-gly residues.
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# Remember: negative indices exclude items from a vector
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plot(tor$phi[-iGly], tor$psi[-iGly],
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xlim=c(-180,180), ylim=c(-180,180),
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main = "Ramachandran plot for 1BM8",
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xlab = expression(phi),
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ylab = expression(psi))
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abline(h = 0, lwd = 0.5, col = "#00000044")
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abline(v = 0, lwd = 0.5, col = "#00000044")
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# Now plot GLY only, but with green dots:
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points(tor$phi[iGly], tor$psi[iGly], pch=21, cex=0.9, bg="#00CC00")
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# As you see, four residues in the upper-right quadrant are
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# not glycine. But what residues are these? Is there an
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# error in our script? Let's get their coordinate records:
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# subset CA records
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CA <- apses$atom[apses$calpha, c("eleno", "elety", "resid", "chain", "resno")]
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# get index of outliers
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iOutliers <- which(tor$phi > 30 & tor$phi < 90 &
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tor$psi > 0 & tor$psi < 90)
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# cbind records together
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(dat <- cbind(CA[iOutliers, ],
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phi = tor$phi[iOutliers],
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psi = tor$psi[iOutliers]))
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# remove the glycine ...
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(dat <- dat[dat$resid != "GLY", ])
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# let's add the residue numbers to the plot with the text function:
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for (i in 1:nrow(dat)) {
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points(dat$phi[i], dat$psi[i], pch=21, cex=0.9, bg="#CC0000")
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text(dat$phi[i],
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dat$psi[i],
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labels = sprintf("%s%d", aa321(dat$resid[i]), dat$resno[i]),
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pos = 4,
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offset = 0.4,
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cex = 0.7)
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}
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# You can check the residues in Chimera. Is there anything unusual about these
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# residues?
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# = 3 Density plots =======================================================
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# Such x, y scatter-plots of data that is sampled from a distribution can tell
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# us a lot about what shapes the distribution. The distribution is governed by
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# the free energy of the phi-psi landscape in folded proteins, since folded
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# proteins generally minimize the free energy of their conformations. We observe
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# empirically, from comparing frequency statistics and mutation experiments,
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# that this generall follows a Boltzmann distribution, where the free energy
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# changes we observe in experments that change one conformation into another are
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# proportional to the log-ratio of the number of times we observe each
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# observation in the protein structure database (after correcting for
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# observation bias). The proper way to visualize such 2D landscapes is with
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# contour plots.
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# == 3.1 Density-based colours =============================================
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# A first approximation to scatterplots that visualize the density of the
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# underlying distribution is coloring via the densCols() function.
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?densCols
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iNA <- c(which(is.na(tor$phi)), which(is.na(tor$psi)))
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phi <- tor$phi[-iNA]
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psi <- tor$psi[-iNA]
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plot (phi, psi,
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xlim = c(-180, 180), ylim = c(-180, 180),
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col=densCols(phi,psi),
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pch=20, cex=2,
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main = "Ramachandran plot for 1BM8",
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xlab = expression(phi),
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ylab = expression(psi))
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abline(h = 0, lwd = 0.5, col = "#00000044")
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abline(v = 0, lwd = 0.5, col = "#00000044")
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# == 3.2 Plotting with smoothScatter() =====================================
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# A better way, that spreads out the underlying density is smoothScatter()
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smoothScatter(phi,psi)
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smoothScatter(phi, psi,
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xlim = c(-180, 180), ylim = c(-180, 180),
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col = "#0033BB33",
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pch = 3, cex = 0.6,
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main = "Ramachandran plot for 1BM8",
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xlab = expression(phi),
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ylab = expression(psi))
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abline(h = 0, lwd = 0.5, col = "#00000044")
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abline(v = 0, lwd = 0.5, col = "#00000044")
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# == 3.3 Plotting hexbins ==================================================
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# If we wish to approximate values in a histogram-like fashion, we can use
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# hexbin()
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if (! require(hexbin, quietly=TRUE)) {
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install.packages("hexbin")
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library(hexbin)
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}
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# Package information:
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# library(help = hexbin) # basic information
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# browseVignettes("hexbin") # available vignettes
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# data(package = "hexbin") # available datasets
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myColorRamp <- colorRampPalette(c("#EEEEEE",
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"#3399CC",
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"#2266DD"))
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plot(hexbin(phi, psi, xbins = 10),
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colramp = myColorRamp,
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main = "phi-psi Density Bins for 1BM8",
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xlab = expression(phi),
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ylab = expression(psi))
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# == 3.4 Plotting density contours =========================================
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# The best way to handle such data is provided by the function contour():
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?contour
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# Contour plots are not produced along the haphazardly sampled values of a data
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# set, but on a regular grid. This means, we need to convert observed values
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# into estimated densities. Density estimation is an important topic for
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# exploratory data analysis, base R has the density() function for 1D
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# distributions. But for 2D data like or phi-psi plots, we need a function from
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# the MASS package: kde2d()
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if (! require(MASS, quietly=TRUE)) {
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install.packages("MASS")
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library(MASS)
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}
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# Package information:
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# library(help = MASS) # basic information
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# browseVignettes("MASS") # available vignettes
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# data(package = "MASS") # available datasets
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?kde2d
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dPhiPsi <-kde2d(phi, psi,
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n = 60,
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lims = c(-180, 180, -180, 180))
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str(dPhiPsi)
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# This is a list, with gridpoints in x and y, and the estimated densities in z.
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# Generic plot with default parameters
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contour(dPhiPsi)
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# === 3.4.1 ... as overlay on a colored grid
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image(dPhiPsi,
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col = myColorRamp(100),
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main = "Ramachandran plot for 1BM8",
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xlab = expression(phi),
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ylab = expression(psi))
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contour(dPhiPsi, col = "royalblue",
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add = TRUE,
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method = "edge",
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nlevels = 10,
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lty = 2)
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points(phi, psi, col = "#00338866", pch = 3, cex = 0.7)
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abline(h = 0, lwd = 0.5, col = "#00000044")
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abline(v = 0, lwd = 0.5, col = "#00000044")
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# === 3.4.2 ... as filled countour
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filled.contour(dPhiPsi,
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xlim = c(-180, 180), ylim = c(-180, 180),
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nlevels = 10,
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color.palette = myColorRamp,
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main = "Ramachandran plot for 1BM8",
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xlab = expression(phi),
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ylab = expression(psi))
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# Note: we can pass additional plotting and overlay commands to the counter plot
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# in a block of expressions passed via the plot.axes parameter:
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filled.contour(dPhiPsi,
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xlim = c(-180, 180), ylim = c(-180, 180),
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nlevels = 10,
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color.palette = myColorRamp,
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main = "Ramachandran plot for 1BM8",
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xlab = expression(phi),
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ylab = expression(psi),
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plot.axes = {
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contour(dPhiPsi, col = "#00000044",
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add = TRUE,
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method = "edge",
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nlevels = 10,
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lty = 2)
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points(phi, psi, col = "#00338866", pch = 3, cex = 0.7)
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abline(h = 0, lwd = 0.5, col = "#00000044")
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abline(v = 0, lwd = 0.5, col = "#00000044")
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})
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# === 3.4.3 ... as a perspective plot
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persp(dPhiPsi,
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xlab = "phi",
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ylab = "psi",
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zlab = "Density")
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persp(dPhiPsi,
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theta = 40,
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phi = 10,
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col = "#99AACC",
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xlab = "phi",
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ylab = "psi",
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zlab = "Density")
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# = 4 cis-peptide bonds ===================================================
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# Are there any cis-peptide bonds in the structure?
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tor$omega
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#... gives us a quick answer. But wait - what values do we
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# expect? And why are the values so different, ranging from -180° to 180°?
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# Consider this plot: what am I doing here and why?
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om <- c(360 + tor$omega[tor$omega < 0],
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tor$omega[tor$omega >= 0])
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hist(om, xlim=c(0,360))
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abline(v=180, col="red")
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# Note: a cis-peptide bond will have an omega torsion angle around 0°
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# = 5 H-bond lengths ======================================================
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# Let's do something a little less trivial and compare
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# backbone H-bond lengths between helices and strands.
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# Secondary structure is defined in the bio3d object's ...$helix and ...$strand
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# list elements.
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str(apses)
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# We need to
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# - collect all N atoms in alpha helices resp.
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# beta strands;
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# - collect all O atoms in alpha helices resp.
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# beta strands;
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# - fetch the atom coordinates;
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# - calculate all N, O distances;
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# - filter them for distances that indicate H-bonds; and,
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# - plot the results.
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# Secondary structure can either be obtained from definitions contained in most
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# PDB files, or by running the DSSP algorithm IF(!) you have it installed on
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# your machine. See the dssp() function of bio3d for instructions how to obtain
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# and install DSSP and STRIDE. This is highly recommended for "real" work with
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# structure coordinate files. The 1BM8 file contains secondary structure
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# definitions:
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apses$helix
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apses$sheet
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# A function to collect atom indices for particular type of secondary structure
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ssSelect <- function(PDB, myChain = "A", ssType, myElety) {
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# Function to retrieve specified atom types from specified secondary
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# structure types in a PDB object.
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# Parameters:
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# PDB A bio3D PDB object
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# myChain chr The chain to use. Default: chain "A".
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# ssType chr A vector of keywords "helix" and/or "sheet"
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# myElety chr A vector of $eletype atom types to return
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# Value: num Indices of the matching atom rows in PDB$atom
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# Build a vector of $resno numbers
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starts <- numeric()
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ends <- numeric()
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if ("helix" %in% ssType) {
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sel <- PDB$helix$chain %in% myChain
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starts <- c(starts, PDB$helix$start[sel])
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ends <- c(ends, PDB$helix$end[sel])
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}
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if ("sheet" %in% ssType) {
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sel <- PDB$sheet$chain %in% myChain
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starts <- c(starts, PDB$sheet$start[sel])
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ends <- c(ends, PDB$sheet$end[sel])
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}
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myResno <- numeric()
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for (i in seq_along(starts)) {
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myResno <- c(myResno, starts[i]:ends[i])
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}
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# get id's from PDB
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x <- atom.select(PDB,
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string = "protein",
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type = "ATOM",
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chain = myChain,
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resno = myResno,
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elety = myElety)
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return(x$atom)
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}
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# Example:
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ssSelect(apses, ssType = "sheet", myElety = "N")
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ssSelect(apses, ssType = "sheet", myElety = "O")
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# That looks correct: O atoms should be stored three index position after N: the
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# sequence of atoms in a PDB file is usually N, CA, C, O ... followed by the
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# side chain coordinates.
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# Now to extract the coordinates and calculate distances. Our function needs to
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# take the PDB object and two vectors of atom indices as argument, and return a
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# vector of pair-distances (actually dist.xyz() returns a matrix).
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pairDist <- function(PDB, a, b) {
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# Calculate pairwise distances between atoms indicated by a and b
|
|
# Parameters:
|
|
# PDB A bio3D PDB object
|
|
# a int A vector of atom indexes
|
|
# b int A vector of atom indexes
|
|
# Value: num matrix of Euclidian distances between the atoms given in a, b.
|
|
# There are as many rows as atoms in a, as many columns as
|
|
# atoms in b.
|
|
|
|
dMat <- numeric()
|
|
if (length(a) > 0 && length(b) > 0) {
|
|
|
|
A <- PDB$atom[a, c("x", "y", "z")]
|
|
B <- PDB$atom[b, c("x", "y", "z")]
|
|
dMat <- dist.xyz(A, B)
|
|
|
|
}
|
|
return(dMat)
|
|
}
|
|
|
|
# Let's see if this looks correct. Let's look at all the pairwise distances
|
|
# between N and O atoms in both types of secondary structure:
|
|
|
|
iN <- ssSelect(apses, ssType = c("helix", "sheet"), myElety = "N")
|
|
iO <- ssSelect(apses, ssType = c("helix", "sheet"), myElety = "O")
|
|
x <- pairDist(apses, iN, iO)
|
|
hist(x,
|
|
breaks = 80,
|
|
col = "lavenderblush",
|
|
main = "",
|
|
xlab = "N-O distances (Å)")
|
|
|
|
# Since we are collecting distance from all secondary structure elements, we
|
|
# are just seing a big peak of (meaningless) long-distance separations. We
|
|
# need to zoom in on the shorter distances, in which we expect
|
|
# hydrogen bonds:
|
|
hist(x[x < 4.2], # restrict to N-O distance less than 4.2 Å long
|
|
breaks=seq(2.0, 4.2, 0.1),
|
|
xlim=c(2.0,4.2),
|
|
col = "lavenderblush",
|
|
main = "",
|
|
xlab = "N-O distances (Å)")
|
|
|
|
# There is a large peak at about 2.2Å, and another
|
|
# large peak above 3.5Å. But these are not typical hydrogen
|
|
# bond distances! Rather these are (N,O) pairs in peptide
|
|
# bonds, and within residues. That's not good, because these will contaminate
|
|
# our statistics.
|
|
# We need to exclude all distances between N of a residue
|
|
# and O of a preceeding residue, and all (N,O) pairs in the
|
|
# same residue. We need a function to filter distances by residue numbers. And while we are filtering, we might as well throw away the non-H bond distances too.
|
|
|
|
filterHB <- function(PDB, iN, iO, dMat, cutoff = 3.9) {
|
|
# Filters distances between O(i-1) and N(i), and between N(i) and O(i)
|
|
# in a distance matrix where there is one row per N-atom and one
|
|
# column per O atom.
|
|
# Parameters:
|
|
# PDB a bio3D PDB object
|
|
# iN int a vector of N atom indexes
|
|
# iO int a vector of O atom indexes
|
|
# dMat num a distance matrix created by pairDist()
|
|
# cutoff num only return distances that are shorter than "cutoff
|
|
# Value: a distance matrix in which values that do not match the
|
|
# filter criteria have bee set to NA.
|
|
|
|
if (length(iN) > 0 && length(iO) > 0) {
|
|
|
|
resN <- PDB$atom$resno[iN]
|
|
resO <- PDB$atom$resno[iO]
|
|
|
|
for (i in seq_along(resN)) { # for all N atoms
|
|
for (j in seq_along(resO)) { # for all O atoms
|
|
if (dMat[i, j] > cutoff || # if: distance > cutoff, or ...
|
|
(resN[i] - 1) == resO[j] || # distance is N(i)---O(i-1), or ...
|
|
resN[i] == resO[j]) { # distance is N(i)---O(i), then:
|
|
dMat[i, j] <- NA # set this distance to NA.
|
|
}
|
|
}
|
|
}
|
|
}
|
|
return(dMat)
|
|
}
|
|
|
|
# Inspect the result:
|
|
hist(filterHB(apses, iN, iO, x),
|
|
breaks=seq(2.0, 4.2, 0.1),
|
|
xlim=c(2.0,4.2),
|
|
col = "paleturquoise",
|
|
main = "",
|
|
xlab = "N-O distances (Å)")
|
|
|
|
|
|
# Finally we can calculate alpha- and beta- structure
|
|
# bonds and compare them. In this section we'll explore
|
|
# different options for histogram plots.
|
|
|
|
# H-bonds in helices ...
|
|
iN <- ssSelect(apses, ssType = c("helix"), myElety = "N")
|
|
iO <- ssSelect(apses, ssType = c("helix"), myElety = "O")
|
|
dH <- filterHB(apses, iN, iO, pairDist(apses, iN, iO))
|
|
dH <- dH[!is.na(dH)]
|
|
|
|
# H-bonds in sheets. (We commonly use the letter "E" to symbolize a beta
|
|
# strand or sheet, because "E" visually evokes an extended strand with
|
|
# protruding sidechains.)
|
|
iN <- ssSelect(apses, ssType = c("sheet"), myElety = "N")
|
|
iO <- ssSelect(apses, ssType = c("sheet"), myElety = "O")
|
|
dE <- filterHB(apses, iN, iO, pairDist(apses, iN, iO))
|
|
dE <- dE[!is.na(dE)]
|
|
|
|
# The plain histogram functions without parameters
|
|
# give us white stacks.
|
|
|
|
hist(dH)
|
|
|
|
# and ...
|
|
hist(dE)
|
|
|
|
# We can see that the histrograms look different
|
|
# but that is better visualized by showing two plots
|
|
# in the same window. We use the par() function, for
|
|
# more flexible layout, look up the layout() function.
|
|
?par
|
|
?layout
|
|
|
|
opar <- par(no.readonly=TRUE) # store current state
|
|
par(mfrow=c(2,1)) # set graphics parameters: 2 rows, one column
|
|
|
|
# plot two histograms
|
|
hist(dH)
|
|
hist(dE)
|
|
|
|
|
|
# add color:
|
|
hist(dH, col="#DD0055")
|
|
hist(dE, col="#00AA70")
|
|
|
|
|
|
|
|
# For better comparison, plot both in the
|
|
# same window:
|
|
|
|
hist(dH, col="#DD0055")
|
|
hist(dE, col="#00AA70", add=TRUE)
|
|
|
|
# ... oops, we dind't reset the graphics parameters. You can either close the
|
|
# window, a new window will open with default parameters, or ...
|
|
par(opar) # ... reset the graphics parameters
|
|
|
|
hist(dH, col="#DD0055")
|
|
hist(dE, col="#00AA70", add=TRUE)
|
|
|
|
# We see that the leftmost column of the sheet bonds hides the helix bonds in
|
|
# that column. Not good. But we can make the colors transparent! We just need to
|
|
# add a fourth set of two hexadecimal-numbers to the #RRGGBB triplet. Lets use
|
|
# 2/3 transparent, in hexadecimal, 1/3 of 256 is x55 - i.e. an RGB triplet
|
|
# specied as #RRGGBB55 is only 33% opaque:
|
|
|
|
hist(dH, col="#DD005555")
|
|
hist(dE, col="#00AA7055", add=TRUE)
|
|
|
|
# To finalize the plots, let's do two more things: Explicitly define the breaks,
|
|
# to make sure they match up - otherwise they would not need to... like in this
|
|
# example:
|
|
|
|
hist(dH, col="#DD005555")
|
|
hist(dE[dE < 3], col="#00AA7055", add=TRUE)
|
|
|
|
# Breaks are a parameter in hist() that can either be a scalar, to define how
|
|
# many columns you want, or a vector, that defines the actual breakpoints.
|
|
brk=seq(2.4, 4.0, 0.1)
|
|
|
|
hist(dH, col="#DD005555", breaks=brk)
|
|
hist(dE, col="#00AA7055", breaks=brk, add=TRUE)
|
|
|
|
# The last thing to do is to think about rescaling the plot. You notice that the
|
|
# y-axis is scaled in absolute frequency (i.e. counts). That gives us some
|
|
# impression of the relative frequency, but it is of course skewed by observing
|
|
# relatively more or less of one type of secondary structure in a protein. As
|
|
# part of the hist() function we can rescale the values so that the sum over all
|
|
# is one: set the prameter freq=FALSE.
|
|
|
|
hist(dH, col="#DD005555", breaks=brk, freq=FALSE)
|
|
hist(dE, col="#00AA7055", breaks=brk, freq=FALSE, add=TRUE)
|
|
|
|
# Adding labels and legend ...
|
|
|
|
hH <- hist(dH,
|
|
freq=FALSE,
|
|
breaks=brk,
|
|
col="#DD005550",
|
|
xlab="(N,O) distance (Å)",
|
|
ylab="Density",
|
|
ylim=c(0,4),
|
|
main="Helix and Sheet H-bond lengths")
|
|
hE <- hist(dE,
|
|
freq=FALSE,
|
|
breaks=brk,
|
|
col="#00AA7060",
|
|
add=TRUE)
|
|
|
|
legend("topright",
|
|
c(sprintf("alpha (N = %3d)", sum(hH$counts)),
|
|
sprintf("beta (N = %3d)", sum(hE$counts))),
|
|
fill = c("#DD005550", "#00AA7060"), bty = 'n',
|
|
border = NA)
|
|
|
|
|
|
# With all the functions we have defined,
|
|
# it is easy to try this with a larger protein.
|
|
# 3ugj for example is VERY large.
|
|
|
|
pdb <- read.pdb("3ugj")
|
|
|
|
# helices...
|
|
iN <- ssSelect(pdb, ssType = c("helix"), myElety = "N")
|
|
iO <- ssSelect(pdb, ssType = c("helix"), myElety = "O")
|
|
dH <- filterHB(pdb, iN, iO, pairDist(pdb, iN, iO))
|
|
dH <- dH[!is.na(dH)]
|
|
|
|
# sheets
|
|
iN <- ssSelect(pdb, ssType = c("sheet"), myElety = "N")
|
|
iO <- ssSelect(pdb, ssType = c("sheet"), myElety = "O")
|
|
dE <- filterHB(pdb, iN, iO, pairDist(pdb, iN, iO))
|
|
dE <- dE[!is.na(dE)]
|
|
|
|
# histograms ...
|
|
brk=seq(2.4, 4.0, 0.1)
|
|
|
|
hH <- hist(dH,
|
|
freq=FALSE,
|
|
breaks=brk,
|
|
col="#DD005550",
|
|
xlab="(N,O) distance (Å)",
|
|
ylab="Density",
|
|
ylim=c(0,4),
|
|
main="Helix and Sheet H-bond lengths")
|
|
hE <- hist(dE,
|
|
freq=FALSE,
|
|
breaks=brk,
|
|
col="#00AA7060",
|
|
add=TRUE)
|
|
|
|
legend('topright',
|
|
c(paste("alpha (N = ", sum(hH$counts), ")"),
|
|
paste("beta (N = ", sum(hE$counts), ")")),
|
|
fill = c("#DD005550", "#00AA7060"), bty = 'n',
|
|
border = NA,
|
|
inset = 0.1)
|
|
|
|
# It looks more and more that the distribution is indeed different. Our sample
|
|
# is large, but derives from a single protein. To do database scale statistics,
|
|
# we should look at many more proteins. To give you a sense of how, let's do
|
|
# this for just ten proteins, randomly selected from non-homologous,
|
|
# high-resolution, single domain structures. I have provided a utility function
|
|
# for such a selection (details beyond the scope of this project).
|
|
|
|
myPDBs <- selectPDBrep(10)
|
|
# My selection is "2OVJ", "1HQS", "3BON", "4JZX", "3BQ3", "2IUM", "2C9E",
|
|
# "4X1F", "2V3I", "3GE3". Yours will be different.
|
|
|
|
# We are loading the files online - don't do this if you have bandwidth
|
|
# limitations.
|
|
|
|
|
|
dH <- c() # collect all helix H-bonds here
|
|
dE <- c() # collect all sheet H-bonds here
|
|
|
|
for (i in seq_along(myPDBs)) {
|
|
pdb <- read.pdb(myPDBs[i])
|
|
|
|
# helices...
|
|
iN <- ssSelect(pdb, ssType = c("helix"), myElety = "N")
|
|
iO <- ssSelect(pdb, ssType = c("helix"), myElety = "O")
|
|
x <- filterHB(pdb, iN, iO, pairDist(pdb, iN, iO))
|
|
dH <- c(dH, x[!is.na(x)])
|
|
|
|
# sheets
|
|
iN <- ssSelect(pdb, ssType = c("sheet"), myElety = "N")
|
|
iO <- ssSelect(pdb, ssType = c("sheet"), myElety = "O")
|
|
x <- filterHB(pdb, iN, iO, pairDist(pdb, iN, iO))
|
|
dE <- c(dE, x[!is.na(x)])
|
|
}
|
|
|
|
# Inspect the results
|
|
|
|
length(dH) # 4415 (your numbers are different, but it should be a lot)
|
|
length(dE) # 262
|
|
|
|
brk=seq(2.0, 4.0, 0.1)
|
|
|
|
hH <- hist(dH,
|
|
freq=FALSE,
|
|
breaks=brk,
|
|
col="#DD005550",
|
|
xlab="(N,O) distance (Å)",
|
|
ylab="Density",
|
|
ylim=c(0,4),
|
|
cex.main = 0.8,
|
|
main="Helix and Sheet H-bond lengths (10 representative structures)")
|
|
hE <- hist(dE,
|
|
freq=FALSE,
|
|
breaks=brk,
|
|
col="#00AA7060",
|
|
add=TRUE)
|
|
|
|
legend('topright',
|
|
c(paste("alpha (N = ", sum(hH$counts), ")"),
|
|
paste("beta (N = ", sum(hE$counts), ")")),
|
|
fill = c("#DD005550", "#00AA7060"), bty = 'n',
|
|
border = NA,
|
|
inset = 0.1)
|
|
|
|
# Task:
|
|
# Why do you think these distributions are different?
|
|
# At what distance do you think H-bonds have the lowest energy?
|
|
# For alpha-helices? For beta-strands?
|
|
|
|
|
|
|
|
|
|
# [END]
|