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R/pwmAlignment.R
In DiffLogo: DiffLogo: A comparative visualisation of biooligomer motifs
Defines functions
multipleLocalPwmsAlignment
alignmentTreeLeftRightTriversal
alignmentTree
joinTwoNodesInAlignmentTree
addLastTreeNodeToDistanceMatrix
minimumMatrixElementIndexes
pwmsDistanceMatrix
alignPwmSets
reverseAlignmentVector
switchDirection
findBestShiftForPwmSets
twoSetsAveragePwmDivergenceFromAlignmentVector
extendPwmsFromAlignmentVector
localPwmAlignment
findBestShiftForPwms
divergencePenaltyForUnaligned
Documented in
alignPwmSets
extendPwmsFromAlignmentVector
localPwmAlignment
multipleLocalPwmsAlignment
pwmsDistanceMatrix
reverseAlignmentVector
switchDirection
twoSetsAveragePwmDivergenceFromAlignmentVector
divergencePenaltyForUnaligned = function(pwm, unaligned_at_left,
aligned_length,
unaligned_at_right, divergence,
base_distribution) {
shift_divergence = 0
if (unaligned_at_left > 0) {
shift_divergence = shift_divergence +
pwmDivergence( matrix( pwm[,1:unaligned_at_left], nrow=nrow(pwm)),
baseDistributionPwm( unaligned_at_left, nrow(pwm), base_distribution = base_distribution),
divergence
);
}
if (unaligned_at_right > 0) {
aligned_length = ncol(pwm) - unaligned_at_right
shift_divergence = shift_divergence +
pwmDivergence( matrix(pwm[,(aligned_length+1):ncol(pwm)], nrow=nrow(pwm)),
baseDistributionPwm(ncol(pwm)-aligned_length, nrow(pwm), base_distribution = base_distribution),
divergence
);
}
return(shift_divergence)
}
findBestShiftForPwms = function(static_pwm, shifted_pwm, divergence, unaligned_penalty, base_distribution, length_normalization) {
best_divergence = Inf
best_shift = 0
for (shift in 0:(ncol(static_pwm)-1)){
intersection_length = min(ncol(static_pwm) - shift, ncol(shifted_pwm))
shift_divergence = pwmDivergence(
matrix( static_pwm[, (shift+1):(shift+intersection_length)], nrow=nrow(static_pwm)),
matrix( shifted_pwm[,1:intersection_length], nrow=nrow(shifted_pwm)),
divergence=divergence)
shift_divergence = shift_divergence+unaligned_penalty(
static_pwm,
unaligned_at_left = shift,
intersection_length,
unaligned_at_right = max(0, ncol(static_pwm) - (shift+intersection_length)),
divergence,
base_distribution);
shift_divergence = shift_divergence+unaligned_penalty(
shifted_pwm,
unaligned_at_left = 0,
intersection_length,
unaligned_at_right = max(0, ncol(shifted_pwm) - intersection_length),
divergence,
base_distribution);
if (length_normalization) {
shift_divergence = shift_divergence / max(ncol(static_pwm), shift + ncol(shifted_pwm));
}
if (shift_divergence < best_divergence) {
best_divergence = shift_divergence
best_shift = shift
}
}
return(list('divergence' = best_divergence, 'shift' = best_shift));
}
##' Finds best local alignment for two PWMs.
##'
##' @title Align pwms
##' @param pwm_left first PWM, a matrix of type matrix
##' @param pwm_right first PWM, a matrix of type matrix
##' @param divergence is a measure of difference between two pwm columns. Smaller is more similar. If you want to use non-uniform background distribution, provide your own function.
##' @param unaligned_penalty distance for unaligned columns at edges of matrixes. See divergencePenaltyForUnaligned as an example for providing your own function
##' @param try_reverse_complement If false the alignment will not be performed on reverse complements. If true, the input pwms should have column order of ACTG/ACGU.
##' @param base_distribution is a vector of length nrow(pwm) that is added to unaligned columns of pwms for comparing. If NULL, uniform distribution is used
##' @param length_normalization If true, will minimize the average divergence between PWMs. Otherwise will minimize the sum of divergences between positions. In both cases unalignes positions are compared to base_distribution and are counted when computing the alignment length.
##' @return list of length two containing the alignment and the divergence
##' @author Lando Andrey
localPwmAlignment = function(pwm_left, pwm_right, divergence=shannonDivergence, unaligned_penalty=divergencePenaltyForUnaligned, try_reverse_complement=TRUE, base_distribution=NULL, length_normalization = FALSE) {
no_change = list("shift"=0, "direction"="forward")
result_alignment_vector = list()
best_divergence = Inf
alignment = findBestShiftForPwms(pwm_left, pwm_right, divergence=divergence,
unaligned_penalty=unaligned_penalty,
base_distribution,
length_normalization=length_normalization)
if (alignment$divergence < best_divergence) {
result_alignment_vector[[1]] = no_change
result_alignment_vector[[2]] = list("shift" = alignment$shift, "direction"="forward")
result_divergence = alignment$divergence
best_divergence = alignment$divergence
}
alignment = findBestShiftForPwms(pwm_right, pwm_left, divergence=divergence,
unaligned_penalty=unaligned_penalty,
base_distribution=base_distribution,
length_normalization=length_normalization)
if (alignment$divergence < best_divergence) {
result_alignment_vector[[1]] = list("shift" = alignment$shift, "direction"="forward")
result_alignment_vector[[2]] = no_change
result_divergence = alignment$divergence
best_divergence = alignment$divergence
}
if (try_reverse_complement) {
alignment = findBestShiftForPwms(pwm_left, revCompPwm(pwm_right),
divergence=divergence,
unaligned_penalty=unaligned_penalty,
base_distribution=base_distribution,
length_normalization=length_normalization)
if (alignment$divergence < best_divergence) {
result_alignment_vector[[1]] = no_change
result_alignment_vector[[2]] = list("shift" = alignment$shift, "direction"="reverse")
result_divergence = alignment$divergence
best_divergence = alignment$divergence
}
alignment = findBestShiftForPwms(revCompPwm(pwm_right), pwm_left,
divergence=divergence,
unaligned_penalty=unaligned_penalty,
base_distribution=base_distribution,
length_normalization=length_normalization)
if (alignment$divergence < best_divergence) {
result_alignment_vector[[1]] = list("shift" = alignment$shift, "direction"="forward")
result_alignment_vector[[2]] = list("shift" = 0, "direction"="reverse")
result_divergence = alignment$divergence
best_divergence = alignment$divergence
}
}
return(list("vector"=result_alignment_vector, "divergence"=result_divergence))
}
addBefore = function (matrix, to_add_length, base_distribution=NULL) {
return(cbind(baseDistributionPwm(to_add_length, nrow(matrix), base_distribution), matrix))
}
addAfter = function (matrix, to_add_length, base_distribution=NULL) {
return(cbind( matrix, baseDistributionPwm(to_add_length, nrow(matrix), base_distribution)))
}
##' Extends pwms by adding base_distribution to both sides, so that they keep aligned, but have equal length.
##'
##' @title Extend pwms with respect to alignment
##' @param pwms is a list of matrixes
##' @param alignment_vector is a list of shifts ($shift) and orientations ($direction)
##' @param base_distribution is a vector of length nrow(pwm) that is added to unaligned columns of pwms for comparing. If NULL, uniform distribution is used
##' @return extended pwms
##' @export
##' @author Lando Andrey
##' @examples
##' file1 = system.file("extdata/homer/Max.motif", package = "DiffLogo")
##' file2 = system.file("extdata/homer/c-Myc.motif", package = "DiffLogo")
##' pwm1 = getPwmFromFile(file1)
##' pwm2 = getPwmFromFile(file2)
##'
##' pwms <- list(pwm1, pwm2)
##' multiple_pwms_alignment = multipleLocalPwmsAlignment(pwms)
##' aligned_pwms = extendPwmsFromAlignmentVector(pwms, multiple_pwms_alignment$alignment$vector)
extendPwmsFromAlignmentVector = function(pwms, alignment_vector, base_distribution=NULL) {
stopifnot(length(pwms)==length(alignment_vector))
max_length = 0
for (i in 1:length(pwms)) {
if (alignment_vector[[i]]$direction == 'reverse') {
pwms[[i]] = revCompPwm(pwms[[i]])
}
pwms[[i]] = addBefore(pwms[[i]], alignment_vector[[i]]$shift, base_distribution)
max_length = max(max_length, ncol(pwms[[i]]))
}
for (i in 1:length(pwms)) {
pwms[[i]] = addAfter(pwms[[i]], max_length - ncol(pwms[[i]]), base_distribution)
}
return(pwms)
}
##' Computes average pwm divergence from alignment vector for two datasets. This equals to average divergence between all pairs where one pwm comes from left set, and other comes from right
##'
##' @title Average divergence between two sets.
##' @param left_pwms_list is a list of matrixes
##' @param left_pwms_alignment is a list of shifts ($shift) and orientations ($direction)
##' @param right_pwms_list is a list of matrixes
##' @param right_pwms_alignment is a list of shifts ($shift) and orientations ($direction)
##' @param divergence divergence measure.
##' @return float
##' @author Lando Andrey
twoSetsAveragePwmDivergenceFromAlignmentVector = function(left_pwms_list,
left_pwms_alignment,
right_pwms_list,
right_pwms_alignment,
divergence = shannonDivergence){
stopifnot(length(left_pwms_list)==length(left_pwms_alignment))
stopifnot(length(right_pwms_list)==length(right_pwms_alignment))
pwms_divergences = c()
for (left_pwm_index in 1:length(left_pwms_list)) {
for (right_pwm_index in 1:length(right_pwms_list)) {
stopifnot(!is.null(left_pwms_list[left_pwm_index]))
stopifnot(!is.null(right_pwms_list[right_pwm_index]))
stopifnot(!is.null(left_pwms_alignment[left_pwm_index]))
stopifnot(!is.null(right_pwms_alignment[right_pwm_index]))
pwms = extendPwmsFromAlignmentVector(c(left_pwms_list[left_pwm_index], right_pwms_list[right_pwm_index]),
c(left_pwms_alignment[left_pwm_index], right_pwms_alignment[right_pwm_index]))
pwms_divergences = c(pwms_divergences, pwmDivergence(pwms[[1]], pwms[[2]], divergence = divergence))
}
}
return(mean(pwms_divergences))
}
findBestShiftForPwmSets = function(static_pwms_list, static_pwms_alignment,
shifted_pwms_list, shifted_pwms_alignment,
divergence = shannonDivergence,
unaligned_penalty = divergencePenaltyForUnaligned) {
stopifnot(length(static_pwms_list)==length(static_pwms_alignment$vector))
stopifnot(length(shifted_pwms_list)==length(shifted_pwms_alignment$vector))
best_divergence = Inf
best_shift = 0
max_possible_shift = 0
result = list()
for (i in 1:length(static_pwms_list)) {
max_possible_shift = max(max_possible_shift,
ncol(static_pwms_list[[i]])
+static_pwms_alignment$vector[[i]]$shift)
}
for (shift in 0:max_possible_shift) {
divergence_for_shift = twoSetsAveragePwmDivergenceFromAlignmentVector(
static_pwms_list, static_pwms_alignment$vector,
shifted_pwms_list, shifted_pwms_alignment$vector,
divergence=divergence)
if (divergence_for_shift < best_divergence) {
best_divergence = divergence_for_shift
result = list("vector" = c(static_pwms_alignment$vector, shifted_pwms_alignment$vector),
"divergence" = best_divergence)
}
for (i in 1:length(shifted_pwms_alignment$vector)) {
shifted_pwms_alignment$vector[[i]]$shift = shifted_pwms_alignment$vector[[i]]$shift+1
}
}
return(result)
}
##' Switches between 'forward' and 'reverse'
##'
##' @title Switches between 'forward' and 'reverse'
##' @param direction either 'forward' or 'reverse'
##' @return either 'reverse' or 'forward'
switchDirection = function(direction) {
if (direction=='forward') {
return('reverse')
} else if (direction=='reverse') {
return('forward')
}
stopifnot(FALSE);
}
##' Returns alignment vector as if all pwm were reverted.
##'
##' @title Reverse for alignment vector
##' @param alignment_vector list of list which $shift and $orientation
##' @param pwms list of matrixes.
##' @return list - reversed alignment vector
##' @author Lando Andrey
reverseAlignmentVector = function(alignment_vector, pwms) {
stopifnot(length(alignment_vector)==length(pwms));
alignment_length = 0;
for (i in 1:length(alignment_vector)) {
alignment_vector[[i]]$direction = switchDirection(alignment_vector[[i]]$direction);
stopifnot(alignment_vector[[i]]$shift >= 0);
alignment_length = max(alignment_length, ncol(pwms[[i]]) + alignment_vector[[i]]$shift);
}
min_shift = 0;
for (i in 1:length(alignment_vector)) {
alignment_vector[[i]]$shift = alignment_length - ncol(pwms[[i]]) - alignment_vector[[i]]$shift;
min_shift = min(min_shift, alignment_vector[[i]]$shift);
}
for (i in 1:length(alignment_vector)) {
alignment_vector[[i]]$shift = -min_shift + alignment_vector[[i]]$shift;
}
return(alignment_vector)
}
##' Align two sets of pwms
##'
##' @title Multiple PWMs alignment
##' @param left_pwms_set list of pwms(matrixes)
##' @param left_alignment alignment of left_pwms_set.
##' @param right_pwms_set list of pwms;
##' @param right_alignment alignment of right_pwms_set.
##' @param try_reverse_complement if true(default), also try reverse complement.
##' @return list - alignment of concatination of left_pwms_set and right_pwms_set
##' @author Lando Andrey
alignPwmSets = function(left_pwms_set, left_alignment, right_pwms_set, right_alignment, try_reverse_complement) {
stopifnot(length(left_pwms_set)==length(left_alignment$vector))
stopifnot(length(right_pwms_set)==length(right_alignment$vector))
result = list()
best_divergence = Inf
alignment = findBestShiftForPwmSets(left_pwms_set, left_alignment, right_pwms_set, right_alignment)
if (alignment$divergence < best_divergence) {
result = alignment
best_divergence = alignment$divergence
}
alignment = findBestShiftForPwmSets(right_pwms_set, right_alignment, left_pwms_set, left_alignment)
if (alignment$divergence < best_divergence) {
best_divergence = alignment$divergence
result$vector = c(alignment$vector[(length(right_pwms_set)+1):(length(alignment$vector))],
alignment$vector[1:length(right_pwms_set)])
result$divergence = best_divergence
}
if(try_reverse_complement) {
right_alignment$vector = reverseAlignmentVector(right_alignment$vector, right_pwms_set)
alignment = findBestShiftForPwmSets(left_pwms_set, left_alignment, right_pwms_set, right_alignment)
if (alignment$divergence < best_divergence) {
result = alignment
best_divergence = alignment$divergence
}
}
alignment = findBestShiftForPwmSets(right_pwms_set, right_alignment, left_pwms_set, left_alignment)
if (alignment$divergence < best_divergence) {
best_divergence = alignment$divergence
result$vector = c(alignment$vector[(length(right_pwms_set)+1):(length(alignment$vector))], alignment$vector[1:length(right_pwms_set)])
result$divergence = best_divergence
}
return(result)
}
##' Creates a distance matrix for pwms
##'
##' @title Multiple PWMs alignment
##' @param pwms list of pwms
##' @param diagonal_value value to put on diagonal.
##' @param bottom_default_value value to put on bottom triangle. Set to NULL to get symmetric distance matrix.
##' @param divergence divergence measure.
##' @param unaligned_penalty is a function for localPwmAlignment.
##' @param try_reverse_complement if True, alignment will try reverse complement pwms
##' @param base_distribution is a vector of length nrow(pwm) that is added to unaligned columns of pwms for comparing. If NULL, uniform distribution is used
##' @param length_normalization is a vector of length nrow(pwm) that is added to unaligned columns of pwms for comparing. If NULL, uniform distribution is used
##' @return list
##' @author Lando Andrey
pwmsDistanceMatrix = function(pwms,
diagonal_value = 0,
bottom_default_value = NULL,
divergence=shannonDivergence,
unaligned_penalty=divergencePenaltyForUnaligned,
try_reverse_complement=TRUE, base_distribution=NULL,
length_normalization = FALSE){
distance_matrix = matrix(0, ncol=length(pwms), nrow=length(pwms))
for (i in 1:(length(pwms)-1)) {
distance_matrix[[i, i]] = diagonal_value
for (j in (i+1):length(pwms)) {
distance_matrix[[i, j]] = localPwmAlignment(
pwms[[i]], pwms[[j]],
divergence=divergence,
unaligned_penalty=unaligned_penalty,
try_reverse_complement=try_reverse_complement,
base_distribution=base_distribution,
length_normalization = length_normalization)$divergence
if (is.null(bottom_default_value)) {
distance_matrix[[j, i]] = distance_matrix[[i, j]]
} else {
distance_matrix[[j, i]] = bottom_default_value
}
}
}
distance_matrix[[length(pwms), length(pwms)]] = diagonal_value
return(distance_matrix)
}
minimumMatrixElementIndexes = function(matrix) {
minimum_element = which.min(matrix)
col_of_minimum = round(minimum_element/ncol(matrix)-0.5)+1
row_of_minimum = minimum_element - ((col_of_minimum-1) * (ncol(matrix)))
first_index = min(col_of_minimum, row_of_minimum)
second_index = max(col_of_minimum, row_of_minimum)
return(list(first_index, second_index))
}
addLastTreeNodeToDistanceMatrix = function(distance_matrix, tree_nodes, try_reverse_complement) {
distance_matrix = cbind(distance_matrix, rep(Inf, ncol(distance_matrix)))
distance_matrix = rbind(distance_matrix, rep(Inf, ncol(distance_matrix)))
last = ncol(distance_matrix)
if (last > 0) {
for (i in 1:(last-1)) {
distance_matrix[[i, last]] = alignPwmSets( tree_nodes[[last]]$pwms, tree_nodes[[last]]$pwms_alignment,
tree_nodes[[i]]$pwms,tree_nodes[[i]]$pwms_alignment, try_reverse_complement)$divergence
}
}
return(distance_matrix)
}
joinTwoNodesInAlignmentTree = function(distance_matrix, tree_nodes, join_counter, try_reverse_complement) {
min_pwm_row_col = minimumMatrixElementIndexes(distance_matrix)
first_pwm_index = min_pwm_row_col[[1]]
second_pwm_index = min_pwm_row_col[[2]]
pwms_alignment = alignPwmSets(tree_nodes[[first_pwm_index]]$pwms,
tree_nodes[[first_pwm_index]]$pwms_alignment,
tree_nodes[[second_pwm_index]]$pwms,
tree_nodes[[second_pwm_index]]$pwms_alignment,
try_reverse_complement)
stopifnot(length(c(tree_nodes[[first_pwm_index]]$pwms, tree_nodes[[second_pwm_index]]$pwms)) == length(pwms_alignment$vector))
tree_nodes = c(tree_nodes,
list(
list("pwms"=c(tree_nodes[[first_pwm_index]]$pwms, tree_nodes[[second_pwm_index]]$pwms),
"left_child"=tree_nodes[[first_pwm_index]],
"right_child"=tree_nodes[[second_pwm_index]],
"num_leafs"=tree_nodes[[first_pwm_index]]$num_leaf + tree_nodes[[second_pwm_index]]$num_leaf,
"node_number"=join_counter,
"pwms_alignment" = pwms_alignment
)
)
);
join_counter = join_counter+1
tree_nodes[[first_pwm_index]] = NULL
tree_nodes[[second_pwm_index-1]] = NULL
distance_matrix = matrix(distance_matrix[-c(first_pwm_index, second_pwm_index), -c(first_pwm_index, second_pwm_index)],
nrow = nrow(distance_matrix)-2, ncol = ncol(distance_matrix)-2)
if (ncol(distance_matrix) != 0) {
distance_matrix = addLastTreeNodeToDistanceMatrix(distance_matrix, tree_nodes, try_reverse_complement)
}
return(list("distance_matrix"=distance_matrix, "tree_nodes"=tree_nodes))
}
alignmentTree = function(pwms, distance_matrix, try_reverse_complement) {
tree_nodes = list()
for (i in 1:length(pwms)) {
tree_nodes = c(tree_nodes,
list(
list( "pwms"=list(pwms[[i]]),
"left_child"=NULL,
"right_child"=NULL,
"num_leafs"=1,
"pwm_index"=i,
"pwms_alignment"=list("vector"=list(list("direction"="forward", "shift"=0)))
)
)
);
}
join_counter = 1
for (step in 1:(length(pwms)-1)) {
joined = joinTwoNodesInAlignmentTree(distance_matrix, tree_nodes, join_counter, try_reverse_complement)
distance_matrix = joined$distance_matrix
tree_nodes = joined$tree_nodes
join_counter = join_counter+1
}
return(tree_nodes[[1]])
}
alignmentTreeLeftRightTriversal = function(node) {
merge = list()
order = list()
height = list()
leftRightTreeTriversalHelper = function(node){
if (is.null(node$left_child)) {
order <<- c(order, node$pwm_index)
return(-(node$pwm_index))
} else {
left_index = leftRightTreeTriversalHelper(node$left_child)
right_index = leftRightTreeTriversalHelper(node$right_child)
merge <<- c(merge, list(c(left_index, right_index)))
height <<- c(height, list(node$pwms_alignment$divergence))
#height <<- c(height, list(node$node_number))
}
return(length(merge))
}
leftRightTreeTriversalHelper(node)
return(list("merge"=merge, "order"=unlist(order), "height"=height))
}
##' Creates a multiple alignment of pwms
##'
##' @title Multiple PWMs alignment
##' @param pwms list of pwms
##' @param divergence Divergence measure.
##' @param unaligned_penalty is a function for localPwmAlignment.
##' @param try_reverse_complement if True, alignment will try reverse complement pwms
##' @param base_distribution is a vector of length nrow(pwm) that is added to unaligned columns of pwms for comparing. If NULL, uniform distribution is used
##' @param length_normalization If true, will minimize the average divergence between PWMs. Otherwise will minimize the sum of divergences between positions. In both cases unalignes positions are compared to base_distribution and are counted when computing the alignment length.
##' @export
##' @return list
##' @author Lando Andrey
##' @examples
##' file1 = system.file("extdata/homer/Max.motif", package = "DiffLogo")
##' file2 = system.file("extdata/homer/c-Myc.motif", package = "DiffLogo")
##' pwm1 = getPwmFromFile(file1)
##' pwm2 = getPwmFromFile(file2)
##'
##' multiple_pwms_alignment = multipleLocalPwmsAlignment(list(pwm1, pwm2))
multipleLocalPwmsAlignment = function(
pwms,
divergence=shannonDivergence,
unaligned_penalty=divergencePenaltyForUnaligned,
try_reverse_complement=TRUE,
base_distribution=NULL,
length_normalization = FALSE)
{
distance_matrix = pwmsDistanceMatrix(
pwms,
bottom_default_value = Inf,
diagonal_value = Inf,
divergence=divergence,
unaligned_penalty=unaligned_penalty,
try_reverse_complement=try_reverse_complement,
base_distribution=base_distribution,
length_normalization = length_normalization);
alignment_tree_nodes = alignmentTree(pwms, distance_matrix, try_reverse_complement)
traversal_result = alignmentTreeLeftRightTriversal(alignment_tree_nodes)
alignment_tree_nodes$pwms_alignment$vector = alignment_tree_nodes$pwms_alignment$vector[ sort.list( unlist( traversal_result$order))];
alignment_length = 0;
for (i in 1:length(pwms)) {
alignment_length = max( alignment_length, ncol(pwms[[i]]) + alignment_tree_nodes$pwms_alignment$vector[[i]]$shift);
}
return(list("alignment"=alignment_tree_nodes$pwms_alignment,
"order"=unlist(traversal_result$order),
"merge"=t(matrix(unlist(traversal_result$merge), 2, byrow=FALSE)),
"height"=unlist(traversal_result$height),
"raw_tree"=list(alignment_tree_nodes),
"distance_matrix"=distance_matrix,
"alignment_length"=alignment_length
))
}
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Defines functions multipleLocalPwmsAlignment alignmentTreeLeftRightTriversal alignmentTree joinTwoNodesInAlignmentTree addLastTreeNodeToDistanceMatrix minimumMatrixElementIndexes pwmsDistanceMatrix alignPwmSets reverseAlignmentVector switchDirection findBestShiftForPwmSets twoSetsAveragePwmDivergenceFromAlignmentVector extendPwmsFromAlignmentVector localPwmAlignment findBestShiftForPwms divergencePenaltyForUnaligned
Documented in alignPwmSets extendPwmsFromAlignmentVector localPwmAlignment multipleLocalPwmsAlignment pwmsDistanceMatrix reverseAlignmentVector switchDirection twoSetsAveragePwmDivergenceFromAlignmentVector
divergencePenaltyForUnaligned = function(pwm, unaligned_at_left,
aligned_length,
unaligned_at_right, divergence,
base_distribution) {
shift_divergence = 0
if (unaligned_at_left > 0) {
shift_divergence = shift_divergence +
pwmDivergence( matrix( pwm[,1:unaligned_at_left], nrow=nrow(pwm)),
baseDistributionPwm( unaligned_at_left, nrow(pwm), base_distribution = base_distribution),
divergence
);
}
if (unaligned_at_right > 0) {
aligned_length = ncol(pwm) - unaligned_at_right
shift_divergence = shift_divergence +
pwmDivergence( matrix(pwm[,(aligned_length+1):ncol(pwm)], nrow=nrow(pwm)),
baseDistributionPwm(ncol(pwm)-aligned_length, nrow(pwm), base_distribution = base_distribution),
divergence
);
}
return(shift_divergence)
}
findBestShiftForPwms = function(static_pwm, shifted_pwm, divergence, unaligned_penalty, base_distribution, length_normalization) {
best_divergence = Inf
best_shift = 0
for (shift in 0:(ncol(static_pwm)-1)){
intersection_length = min(ncol(static_pwm) - shift, ncol(shifted_pwm))
shift_divergence = pwmDivergence(
matrix( static_pwm[, (shift+1):(shift+intersection_length)], nrow=nrow(static_pwm)),
matrix( shifted_pwm[,1:intersection_length], nrow=nrow(shifted_pwm)),
divergence=divergence)
shift_divergence = shift_divergence+unaligned_penalty(
static_pwm,
unaligned_at_left = shift,
intersection_length,
unaligned_at_right = max(0, ncol(static_pwm) - (shift+intersection_length)),
divergence,
base_distribution);
shift_divergence = shift_divergence+unaligned_penalty(
shifted_pwm,
unaligned_at_left = 0,
intersection_length,
unaligned_at_right = max(0, ncol(shifted_pwm) - intersection_length),
divergence,
base_distribution);
if (length_normalization) {
shift_divergence = shift_divergence / max(ncol(static_pwm), shift + ncol(shifted_pwm));
}
if (shift_divergence < best_divergence) {
best_divergence = shift_divergence
best_shift = shift
}
}
return(list('divergence' = best_divergence, 'shift' = best_shift));
}
##' Finds best local alignment for two PWMs.
##'
##' @title Align pwms
##' @param pwm_left first PWM, a matrix of type matrix
##' @param pwm_right first PWM, a matrix of type matrix
##' @param divergence is a measure of difference between two pwm columns. Smaller is more similar. If you want to use non-uniform background distribution, provide your own function.
##' @param unaligned_penalty distance for unaligned columns at edges of matrixes. See divergencePenaltyForUnaligned as an example for providing your own function
##' @param try_reverse_complement If false the alignment will not be performed on reverse complements. If true, the input pwms should have column order of ACTG/ACGU.
##' @param base_distribution is a vector of length nrow(pwm) that is added to unaligned columns of pwms for comparing. If NULL, uniform distribution is used
##' @param length_normalization If true, will minimize the average divergence between PWMs. Otherwise will minimize the sum of divergences between positions. In both cases unalignes positions are compared to base_distribution and are counted when computing the alignment length.
##' @return list of length two containing the alignment and the divergence
##' @author Lando Andrey
localPwmAlignment = function(pwm_left, pwm_right, divergence=shannonDivergence, unaligned_penalty=divergencePenaltyForUnaligned, try_reverse_complement=TRUE, base_distribution=NULL, length_normalization = FALSE) {
no_change = list("shift"=0, "direction"="forward")
result_alignment_vector = list()
best_divergence = Inf
alignment = findBestShiftForPwms(pwm_left, pwm_right, divergence=divergence,
unaligned_penalty=unaligned_penalty,
base_distribution,
length_normalization=length_normalization)
if (alignment$divergence < best_divergence) {
result_alignment_vector[[1]] = no_change
result_alignment_vector[[2]] = list("shift" = alignment$shift, "direction"="forward")
result_divergence = alignment$divergence
best_divergence = alignment$divergence
}
alignment = findBestShiftForPwms(pwm_right, pwm_left, divergence=divergence,
unaligned_penalty=unaligned_penalty,
base_distribution=base_distribution,
length_normalization=length_normalization)
if (alignment$divergence < best_divergence) {
result_alignment_vector[[1]] = list("shift" = alignment$shift, "direction"="forward")
result_alignment_vector[[2]] = no_change
result_divergence = alignment$divergence
best_divergence = alignment$divergence
}
if (try_reverse_complement) {
alignment = findBestShiftForPwms(pwm_left, revCompPwm(pwm_right),
divergence=divergence,
unaligned_penalty=unaligned_penalty,
base_distribution=base_distribution,
length_normalization=length_normalization)
if (alignment$divergence < best_divergence) {
result_alignment_vector[[1]] = no_change
result_alignment_vector[[2]] = list("shift" = alignment$shift, "direction"="reverse")
result_divergence = alignment$divergence
best_divergence = alignment$divergence
}
alignment = findBestShiftForPwms(revCompPwm(pwm_right), pwm_left,
divergence=divergence,
unaligned_penalty=unaligned_penalty,
base_distribution=base_distribution,
length_normalization=length_normalization)
if (alignment$divergence < best_divergence) {
result_alignment_vector[[1]] = list("shift" = alignment$shift, "direction"="forward")
result_alignment_vector[[2]] = list("shift" = 0, "direction"="reverse")
result_divergence = alignment$divergence
best_divergence = alignment$divergence
}
}
return(list("vector"=result_alignment_vector, "divergence"=result_divergence))
}
addBefore = function (matrix, to_add_length, base_distribution=NULL) {
return(cbind(baseDistributionPwm(to_add_length, nrow(matrix), base_distribution), matrix))
}
addAfter = function (matrix, to_add_length, base_distribution=NULL) {
return(cbind( matrix, baseDistributionPwm(to_add_length, nrow(matrix), base_distribution)))
}
##' Extends pwms by adding base_distribution to both sides, so that they keep aligned, but have equal length.
##'
##' @title Extend pwms with respect to alignment
##' @param pwms is a list of matrixes
##' @param alignment_vector is a list of shifts ($shift) and orientations ($direction)
##' @param base_distribution is a vector of length nrow(pwm) that is added to unaligned columns of pwms for comparing. If NULL, uniform distribution is used
##' @return extended pwms
##' @export
##' @author Lando Andrey
##' @examples
##' file1 = system.file("extdata/homer/Max.motif", package = "DiffLogo")
##' file2 = system.file("extdata/homer/c-Myc.motif", package = "DiffLogo")
##' pwm1 = getPwmFromFile(file1)
##' pwm2 = getPwmFromFile(file2)
##'
##' pwms <- list(pwm1, pwm2)
##' multiple_pwms_alignment = multipleLocalPwmsAlignment(pwms)
##' aligned_pwms = extendPwmsFromAlignmentVector(pwms, multiple_pwms_alignment$alignment$vector)
extendPwmsFromAlignmentVector = function(pwms, alignment_vector, base_distribution=NULL) {
stopifnot(length(pwms)==length(alignment_vector))
max_length = 0
for (i in 1:length(pwms)) {
if (alignment_vector[[i]]$direction == 'reverse') {
pwms[[i]] = revCompPwm(pwms[[i]])
}
pwms[[i]] = addBefore(pwms[[i]], alignment_vector[[i]]$shift, base_distribution)
max_length = max(max_length, ncol(pwms[[i]]))
}
for (i in 1:length(pwms)) {
pwms[[i]] = addAfter(pwms[[i]], max_length - ncol(pwms[[i]]), base_distribution)
}
return(pwms)
}
##' Computes average pwm divergence from alignment vector for two datasets. This equals to average divergence between all pairs where one pwm comes from left set, and other comes from right
##'
##' @title Average divergence between two sets.
##' @param left_pwms_list is a list of matrixes
##' @param left_pwms_alignment is a list of shifts ($shift) and orientations ($direction)
##' @param right_pwms_list is a list of matrixes
##' @param right_pwms_alignment is a list of shifts ($shift) and orientations ($direction)
##' @param divergence divergence measure.
##' @return float
##' @author Lando Andrey
twoSetsAveragePwmDivergenceFromAlignmentVector = function(left_pwms_list,
left_pwms_alignment,
right_pwms_list,
right_pwms_alignment,
divergence = shannonDivergence){
stopifnot(length(left_pwms_list)==length(left_pwms_alignment))
stopifnot(length(right_pwms_list)==length(right_pwms_alignment))
pwms_divergences = c()
for (left_pwm_index in 1:length(left_pwms_list)) {
for (right_pwm_index in 1:length(right_pwms_list)) {
stopifnot(!is.null(left_pwms_list[left_pwm_index]))
stopifnot(!is.null(right_pwms_list[right_pwm_index]))
stopifnot(!is.null(left_pwms_alignment[left_pwm_index]))
stopifnot(!is.null(right_pwms_alignment[right_pwm_index]))
pwms = extendPwmsFromAlignmentVector(c(left_pwms_list[left_pwm_index], right_pwms_list[right_pwm_index]),
c(left_pwms_alignment[left_pwm_index], right_pwms_alignment[right_pwm_index]))
pwms_divergences = c(pwms_divergences, pwmDivergence(pwms[[1]], pwms[[2]], divergence = divergence))
}
}
return(mean(pwms_divergences))
}
findBestShiftForPwmSets = function(static_pwms_list, static_pwms_alignment,
shifted_pwms_list, shifted_pwms_alignment,
divergence = shannonDivergence,
unaligned_penalty = divergencePenaltyForUnaligned) {
stopifnot(length(static_pwms_list)==length(static_pwms_alignment$vector))
stopifnot(length(shifted_pwms_list)==length(shifted_pwms_alignment$vector))
best_divergence = Inf
best_shift = 0
max_possible_shift = 0
result = list()
for (i in 1:length(static_pwms_list)) {
max_possible_shift = max(max_possible_shift,
ncol(static_pwms_list[[i]])
+static_pwms_alignment$vector[[i]]$shift)
}
for (shift in 0:max_possible_shift) {
divergence_for_shift = twoSetsAveragePwmDivergenceFromAlignmentVector(
static_pwms_list, static_pwms_alignment$vector,
shifted_pwms_list, shifted_pwms_alignment$vector,
divergence=divergence)
if (divergence_for_shift < best_divergence) {
best_divergence = divergence_for_shift
result = list("vector" = c(static_pwms_alignment$vector, shifted_pwms_alignment$vector),
"divergence" = best_divergence)
}
for (i in 1:length(shifted_pwms_alignment$vector)) {
shifted_pwms_alignment$vector[[i]]$shift = shifted_pwms_alignment$vector[[i]]$shift+1
}
}
return(result)
}
##' Switches between 'forward' and 'reverse'
##'
##' @title Switches between 'forward' and 'reverse'
##' @param direction either 'forward' or 'reverse'
##' @return either 'reverse' or 'forward'
switchDirection = function(direction) {
if (direction=='forward') {
return('reverse')
} else if (direction=='reverse') {
return('forward')
}
stopifnot(FALSE);
}
##' Returns alignment vector as if all pwm were reverted.
##'
##' @title Reverse for alignment vector
##' @param alignment_vector list of list which $shift and $orientation
##' @param pwms list of matrixes.
##' @return list - reversed alignment vector
##' @author Lando Andrey
reverseAlignmentVector = function(alignment_vector, pwms) {
stopifnot(length(alignment_vector)==length(pwms));
alignment_length = 0;
for (i in 1:length(alignment_vector)) {
alignment_vector[[i]]$direction = switchDirection(alignment_vector[[i]]$direction);
stopifnot(alignment_vector[[i]]$shift >= 0);
alignment_length = max(alignment_length, ncol(pwms[[i]]) + alignment_vector[[i]]$shift);
}
min_shift = 0;
for (i in 1:length(alignment_vector)) {
alignment_vector[[i]]$shift = alignment_length - ncol(pwms[[i]]) - alignment_vector[[i]]$shift;
min_shift = min(min_shift, alignment_vector[[i]]$shift);
}
for (i in 1:length(alignment_vector)) {
alignment_vector[[i]]$shift = -min_shift + alignment_vector[[i]]$shift;
}
return(alignment_vector)
}
##' Align two sets of pwms
##'
##' @title Multiple PWMs alignment
##' @param left_pwms_set list of pwms(matrixes)
##' @param left_alignment alignment of left_pwms_set.
##' @param right_pwms_set list of pwms;
##' @param right_alignment alignment of right_pwms_set.
##' @param try_reverse_complement if true(default), also try reverse complement.
##' @return list - alignment of concatination of left_pwms_set and right_pwms_set
##' @author Lando Andrey
alignPwmSets = function(left_pwms_set, left_alignment, right_pwms_set, right_alignment, try_reverse_complement) {
stopifnot(length(left_pwms_set)==length(left_alignment$vector))
stopifnot(length(right_pwms_set)==length(right_alignment$vector))
result = list()
best_divergence = Inf
alignment = findBestShiftForPwmSets(left_pwms_set, left_alignment, right_pwms_set, right_alignment)
if (alignment$divergence < best_divergence) {
result = alignment
best_divergence = alignment$divergence
}
alignment = findBestShiftForPwmSets(right_pwms_set, right_alignment, left_pwms_set, left_alignment)
if (alignment$divergence < best_divergence) {
best_divergence = alignment$divergence
result$vector = c(alignment$vector[(length(right_pwms_set)+1):(length(alignment$vector))],
alignment$vector[1:length(right_pwms_set)])
result$divergence = best_divergence
}
if(try_reverse_complement) {
right_alignment$vector = reverseAlignmentVector(right_alignment$vector, right_pwms_set)
alignment = findBestShiftForPwmSets(left_pwms_set, left_alignment, right_pwms_set, right_alignment)
if (alignment$divergence < best_divergence) {
result = alignment
best_divergence = alignment$divergence
}
}
alignment = findBestShiftForPwmSets(right_pwms_set, right_alignment, left_pwms_set, left_alignment)
if (alignment$divergence < best_divergence) {
best_divergence = alignment$divergence
result$vector = c(alignment$vector[(length(right_pwms_set)+1):(length(alignment$vector))], alignment$vector[1:length(right_pwms_set)])
result$divergence = best_divergence
}
return(result)
}
##' Creates a distance matrix for pwms
##'
##' @title Multiple PWMs alignment
##' @param pwms list of pwms
##' @param diagonal_value value to put on diagonal.
##' @param bottom_default_value value to put on bottom triangle. Set to NULL to get symmetric distance matrix.
##' @param divergence divergence measure.
##' @param unaligned_penalty is a function for localPwmAlignment.
##' @param try_reverse_complement if True, alignment will try reverse complement pwms
##' @param base_distribution is a vector of length nrow(pwm) that is added to unaligned columns of pwms for comparing. If NULL, uniform distribution is used
##' @param length_normalization is a vector of length nrow(pwm) that is added to unaligned columns of pwms for comparing. If NULL, uniform distribution is used
##' @return list
##' @author Lando Andrey
pwmsDistanceMatrix = function(pwms,
diagonal_value = 0,
bottom_default_value = NULL,
divergence=shannonDivergence,
unaligned_penalty=divergencePenaltyForUnaligned,
try_reverse_complement=TRUE, base_distribution=NULL,
length_normalization = FALSE){
distance_matrix = matrix(0, ncol=length(pwms), nrow=length(pwms))
for (i in 1:(length(pwms)-1)) {
distance_matrix[[i, i]] = diagonal_value
for (j in (i+1):length(pwms)) {
distance_matrix[[i, j]] = localPwmAlignment(
pwms[[i]], pwms[[j]],
divergence=divergence,
unaligned_penalty=unaligned_penalty,
try_reverse_complement=try_reverse_complement,
base_distribution=base_distribution,
length_normalization = length_normalization)$divergence
if (is.null(bottom_default_value)) {
distance_matrix[[j, i]] = distance_matrix[[i, j]]
} else {
distance_matrix[[j, i]] = bottom_default_value
}
}
}
distance_matrix[[length(pwms), length(pwms)]] = diagonal_value
return(distance_matrix)
}
minimumMatrixElementIndexes = function(matrix) {
minimum_element = which.min(matrix)
col_of_minimum = round(minimum_element/ncol(matrix)-0.5)+1
row_of_minimum = minimum_element - ((col_of_minimum-1) * (ncol(matrix)))
first_index = min(col_of_minimum, row_of_minimum)
second_index = max(col_of_minimum, row_of_minimum)
return(list(first_index, second_index))
}
addLastTreeNodeToDistanceMatrix = function(distance_matrix, tree_nodes, try_reverse_complement) {
distance_matrix = cbind(distance_matrix, rep(Inf, ncol(distance_matrix)))
distance_matrix = rbind(distance_matrix, rep(Inf, ncol(distance_matrix)))
last = ncol(distance_matrix)
if (last > 0) {
for (i in 1:(last-1)) {
distance_matrix[[i, last]] = alignPwmSets( tree_nodes[[last]]$pwms, tree_nodes[[last]]$pwms_alignment,
tree_nodes[[i]]$pwms,tree_nodes[[i]]$pwms_alignment, try_reverse_complement)$divergence
}
}
return(distance_matrix)
}
joinTwoNodesInAlignmentTree = function(distance_matrix, tree_nodes, join_counter, try_reverse_complement) {
min_pwm_row_col = minimumMatrixElementIndexes(distance_matrix)
first_pwm_index = min_pwm_row_col[[1]]
second_pwm_index = min_pwm_row_col[[2]]
pwms_alignment = alignPwmSets(tree_nodes[[first_pwm_index]]$pwms,
tree_nodes[[first_pwm_index]]$pwms_alignment,
tree_nodes[[second_pwm_index]]$pwms,
tree_nodes[[second_pwm_index]]$pwms_alignment,
try_reverse_complement)
stopifnot(length(c(tree_nodes[[first_pwm_index]]$pwms, tree_nodes[[second_pwm_index]]$pwms)) == length(pwms_alignment$vector))
tree_nodes = c(tree_nodes,
list(
list("pwms"=c(tree_nodes[[first_pwm_index]]$pwms, tree_nodes[[second_pwm_index]]$pwms),
"left_child"=tree_nodes[[first_pwm_index]],
"right_child"=tree_nodes[[second_pwm_index]],
"num_leafs"=tree_nodes[[first_pwm_index]]$num_leaf + tree_nodes[[second_pwm_index]]$num_leaf,
"node_number"=join_counter,
"pwms_alignment" = pwms_alignment
)
)
);
join_counter = join_counter+1
tree_nodes[[first_pwm_index]] = NULL
tree_nodes[[second_pwm_index-1]] = NULL
distance_matrix = matrix(distance_matrix[-c(first_pwm_index, second_pwm_index), -c(first_pwm_index, second_pwm_index)],
nrow = nrow(distance_matrix)-2, ncol = ncol(distance_matrix)-2)
if (ncol(distance_matrix) != 0) {
distance_matrix = addLastTreeNodeToDistanceMatrix(distance_matrix, tree_nodes, try_reverse_complement)
}
return(list("distance_matrix"=distance_matrix, "tree_nodes"=tree_nodes))
}
alignmentTree = function(pwms, distance_matrix, try_reverse_complement) {
tree_nodes = list()
for (i in 1:length(pwms)) {
tree_nodes = c(tree_nodes,
list(
list( "pwms"=list(pwms[[i]]),
"left_child"=NULL,
"right_child"=NULL,
"num_leafs"=1,
"pwm_index"=i,
"pwms_alignment"=list("vector"=list(list("direction"="forward", "shift"=0)))
)
)
);
}
join_counter = 1
for (step in 1:(length(pwms)-1)) {
joined = joinTwoNodesInAlignmentTree(distance_matrix, tree_nodes, join_counter, try_reverse_complement)
distance_matrix = joined$distance_matrix
tree_nodes = joined$tree_nodes
join_counter = join_counter+1
}
return(tree_nodes[[1]])
}
alignmentTreeLeftRightTriversal = function(node) {
merge = list()
order = list()
height = list()
leftRightTreeTriversalHelper = function(node){
if (is.null(node$left_child)) {
order <<- c(order, node$pwm_index)
return(-(node$pwm_index))
} else {
left_index = leftRightTreeTriversalHelper(node$left_child)
right_index = leftRightTreeTriversalHelper(node$right_child)
merge <<- c(merge, list(c(left_index, right_index)))
height <<- c(height, list(node$pwms_alignment$divergence))
#height <<- c(height, list(node$node_number))
}
return(length(merge))
}
leftRightTreeTriversalHelper(node)
return(list("merge"=merge, "order"=unlist(order), "height"=height))
}
##' Creates a multiple alignment of pwms
##'
##' @title Multiple PWMs alignment
##' @param pwms list of pwms
##' @param divergence Divergence measure.
##' @param unaligned_penalty is a function for localPwmAlignment.
##' @param try_reverse_complement if True, alignment will try reverse complement pwms
##' @param base_distribution is a vector of length nrow(pwm) that is added to unaligned columns of pwms for comparing. If NULL, uniform distribution is used
##' @param length_normalization If true, will minimize the average divergence between PWMs. Otherwise will minimize the sum of divergences between positions. In both cases unalignes positions are compared to base_distribution and are counted when computing the alignment length.
##' @export
##' @return list
##' @author Lando Andrey
##' @examples
##' file1 = system.file("extdata/homer/Max.motif", package = "DiffLogo")
##' file2 = system.file("extdata/homer/c-Myc.motif", package = "DiffLogo")
##' pwm1 = getPwmFromFile(file1)
##' pwm2 = getPwmFromFile(file2)
##'
##' multiple_pwms_alignment = multipleLocalPwmsAlignment(list(pwm1, pwm2))
multipleLocalPwmsAlignment = function(
pwms,
divergence=shannonDivergence,
unaligned_penalty=divergencePenaltyForUnaligned,
try_reverse_complement=TRUE,
base_distribution=NULL,
length_normalization = FALSE)
{
distance_matrix = pwmsDistanceMatrix(
pwms,
bottom_default_value = Inf,
diagonal_value = Inf,
divergence=divergence,
unaligned_penalty=unaligned_penalty,
try_reverse_complement=try_reverse_complement,
base_distribution=base_distribution,
length_normalization = length_normalization);
alignment_tree_nodes = alignmentTree(pwms, distance_matrix, try_reverse_complement)
traversal_result = alignmentTreeLeftRightTriversal(alignment_tree_nodes)
alignment_tree_nodes$pwms_alignment$vector = alignment_tree_nodes$pwms_alignment$vector[ sort.list( unlist( traversal_result$order))];
alignment_length = 0;
for (i in 1:length(pwms)) {
alignment_length = max( alignment_length, ncol(pwms[[i]]) + alignment_tree_nodes$pwms_alignment$vector[[i]]$shift);
}
return(list("alignment"=alignment_tree_nodes$pwms_alignment,
"order"=unlist(traversal_result$order),
"merge"=t(matrix(unlist(traversal_result$merge), 2, byrow=FALSE)),
"height"=unlist(traversal_result$height),
"raw_tree"=list(alignment_tree_nodes),
"distance_matrix"=distance_matrix,
"alignment_length"=alignment_length
))
}
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