Mercurial > repos > drosofff > msp_sr_signature
view smRtools.py @ 0:a2f293717ce3 draft
planemo upload for repository https://github.com/ARTbio/tools-artbio/tree/master/tools/msp_sr_signature commit fe40dec87779c1fcfbd03330e653aa886f4a2cda
| author | drosofff |
|---|---|
| date | Wed, 21 Oct 2015 11:35:25 -0400 |
| parents | |
| children | 6218b518cd16 |
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#!/usr/bin/python # version 1 7-5-2012 unification of the SmRNAwindow class import sys, subprocess from collections import defaultdict from numpy import mean, median, std ##Disable scipy import temporarily, as no working scipy on toolshed. ##from scipy import stats def get_fasta (index="/home/galaxy/galaxy-dist/bowtie/5.37_Dmel/5.37_Dmel"): '''This function will return a dictionary containing fasta identifiers as keys and the sequence as values. Index must be the path to a fasta file.''' p = subprocess.Popen(args=["bowtie-inspect","-a", "0", index], stdout=subprocess.PIPE, stderr=subprocess.STDOUT) # bowtie-inspect outputs sequences on single lines outputlines = p.stdout.readlines() p.wait() item_dic = {} for line in outputlines: if (line[0] == ">"): try: item_dic[current_item] = "".join(stringlist) # to dump the sequence of the previous item - try because of the keyerror of the first item except: pass current_item = line[1:].rstrip().split()[0] #take the first word before space because bowtie splits headers ! item_dic[current_item] = "" stringlist=[] else: stringlist.append(line.rstrip() ) item_dic[current_item] = "".join(stringlist) # for the last item return item_dic def get_fasta_headers (index): p = subprocess.Popen(args=["bowtie-inspect","-n", index], stdout=subprocess.PIPE, stderr=subprocess.STDOUT) # bowtie-inspect outputs sequences on single lines outputlines = p.stdout.readlines() p.wait() item_dic = {} for line in outputlines: header = line.rstrip().split()[0] #take the first word before space because bowtie splits headers ! item_dic[header] = 1 return item_dic def get_file_sample (file, numberoflines): '''import random to use this function''' F=open(file) fullfile = F.read().splitlines() F.close() if len(fullfile) < numberoflines: return "sample size exceeds file size" return random.sample(fullfile, numberoflines) def get_fasta_from_history (file): F = open (file, "r") item_dic = {} for line in F: if (line[0] == ">"): try: item_dic[current_item] = "".join(stringlist) # to dump the sequence of the previous item - try because of the keyerror of the first item except: pass current_item = line[1:-1].split()[0] #take the first word before space because bowtie splits headers ! item_dic[current_item] = "" stringlist=[] else: stringlist.append(line[:-1]) item_dic[current_item] = "".join(stringlist) # for the last item return item_dic def antipara (sequence): antidict = {"A":"T", "T":"A", "G":"C", "C":"G", "N":"N"} revseq = sequence[::-1] return "".join([antidict[i] for i in revseq]) def RNAtranslate (sequence): return "".join([i if i in "AGCN" else "U" for i in sequence]) def DNAtranslate (sequence): return "".join([i if i in "AGCN" else "T" for i in sequence]) def RNAfold (sequence_list): thestring= "\n".join(sequence_list) p = subprocess.Popen(args=["RNAfold","--noPS"], stdin= subprocess.PIPE, stdout=subprocess.PIPE, stderr=subprocess.STDOUT) output=p.communicate(thestring)[0] p.wait() output=output.split("\n") if not output[-1]: output = output[:-1] # nasty patch to remove last empty line buffer=[] for line in output: if line[0] in ["N","A","T","U","G","C"]: buffer.append(DNAtranslate(line)) if line[0] in ["(",".",")"]: fields=line.split("(") energy= fields[-1] energy = energy[:-1] # remove the ) parenthesis energy=float(energy) buffer.append(str(energy)) return dict(zip(buffer[::2], buffer[1::2])) def extractsubinstance (start, end, instance): ''' Testing whether this can be an function external to the class to save memory''' subinstance = SmRNAwindow (instance.gene, instance.sequence[start-1:end], start) subinstance.gene = "%s %s %s" % (subinstance.gene, subinstance.windowoffset, subinstance.windowoffset + subinstance.size - 1) upcoordinate = [i for i in range(start,end+1) if instance.readDict.has_key(i) ] downcoordinate = [-i for i in range(start,end+1) if instance.readDict.has_key(-i) ] for i in upcoordinate: subinstance.readDict[i]=instance.readDict[i] for i in downcoordinate: subinstance.readDict[i]=instance.readDict[i] return subinstance class HandleSmRNAwindows: def __init__(self, alignmentFile="~", alignmentFileFormat="tabular", genomeRefFile="~", genomeRefFormat="bowtieIndex", biosample="undetermined", size_inf=None, size_sup=1000, norm=1.0): self.biosample = biosample self.alignmentFile = alignmentFile self.alignmentFileFormat = alignmentFileFormat # can be "tabular" or "sam" self.genomeRefFile = genomeRefFile self.genomeRefFormat = genomeRefFormat # can be "bowtieIndex" or "fastaSource" self.alignedReads = 0 self.instanceDict = {} self.size_inf=size_inf self.size_sup=size_sup self.norm=norm if genomeRefFormat == "bowtieIndex": self.itemDict = get_fasta (genomeRefFile) elif genomeRefFormat == "fastaSource": self.itemDict = get_fasta_from_history (genomeRefFile) for item in self.itemDict: self.instanceDict[item] = SmRNAwindow(item, sequence=self.itemDict[item], windowoffset=1, biosample=self.biosample, norm=self.norm) # create as many instances as there is items self.readfile() def readfile (self) : if self.alignmentFileFormat == "tabular": F = open (self.alignmentFile, "r") for line in F: fields = line.split() polarity = fields[1] gene = fields[2] offset = int(fields[3]) size = len (fields[4]) if self.size_inf: if (size>=self.size_inf and size<= self.size_sup): self.instanceDict[gene].addread (polarity, offset+1, size) # to correct to 1-based coordinates of SmRNAwindow self.alignedReads += 1 else: self.instanceDict[gene].addread (polarity, offset+1, size) # to correct to 1-based coordinates of SmRNAwindow self.alignedReads += 1 F.close() return self.instanceDict # elif self.alignmentFileFormat == "sam": # F = open (self.alignmentFile, "r") # dict = {"0":"+", "16":"-"} # for line in F: # if line[0]=='@': # continue # fields = line.split() # if fields[2] == "*": continue # polarity = dict[fields[1]] # gene = fields[2] # offset = int(fields[3]) # size = len (fields[9]) # if self.size_inf: # if (size>=self.size_inf and size<= self.size_sup): # self.instanceDict[gene].addread (polarity, offset, size) # self.alignedReads += 1 # else: # self.instanceDict[gene].addread (polarity, offset, size) # self.alignedReads += 1 # F.close() elif self.alignmentFileFormat == "bam" or self.alignmentFileFormat == "sam": import pysam samfile = pysam.Samfile(self.alignmentFile) for read in samfile: if read.tid == -1: continue # filter out unaligned reads if read.is_reverse: polarity="-" else: polarity="+" gene = samfile.getrname(read.tid) offset = read.pos size = read.qlen if self.size_inf: if (size>=self.size_inf and size<= self.size_sup): self.instanceDict[gene].addread (polarity, offset+1, size) # to correct to 1-based coordinates of SmRNAwindow self.alignedReads += 1 else: self.instanceDict[gene].addread (polarity, offset+1, size) # to correct to 1-based coordinates of SmRNAwindow self.alignedReads += 1 return self.instanceDict # def size_histogram (self): # size_dict={} # size_dict['F']= defaultdict (int) # size_dict['R']= defaultdict (int) # size_dict['both'] = defaultdict (int) # for item in self.instanceDict: # buffer_dict_F = self.instanceDict[item].size_histogram()['F'] # buffer_dict_R = self.instanceDict[item].size_histogram()['R'] # for size in buffer_dict_F: # size_dict['F'][size] += buffer_dict_F[size] # for size in buffer_dict_R: # size_dict['R'][size] -= buffer_dict_R[size] # allSizeKeys = list (set (size_dict['F'].keys() + size_dict['R'].keys() ) ) # for size in allSizeKeys: # size_dict['both'][size] = size_dict['F'][size] + size_dict['R'][size] # return size_dict def size_histogram (self): # in HandleSmRNAwindows '''refactored on 7-9-2014 to debug size_histogram tool''' size_dict={} size_dict['F']= defaultdict (float) size_dict['R']= defaultdict (float) size_dict['both'] = defaultdict (float) for item in self.instanceDict: buffer_dict = self.instanceDict[item].size_histogram() for polarity in ["F", "R"]: for size in buffer_dict[polarity]: size_dict[polarity][size] += buffer_dict[polarity][size] for size in buffer_dict["both"]: size_dict["both"][size] += buffer_dict["F"][size] - buffer_dict["R"][size] return size_dict def CountFeatures (self, GFF3="path/to/file"): featureDict = defaultdict(int) F = open (GFF3, "r") for line in F: if line[0] == "#": continue fields = line[:-1].split() chrom, feature, leftcoord, rightcoord, polarity = fields[0], fields[2], fields[3], fields[4], fields[6] featureDict[feature] += self.instanceDict[chrom].readcount(upstream_coord=int(leftcoord), downstream_coord=int(rightcoord), polarity="both", method="destructive") F.close() return featureDict class SmRNAwindow: def __init__(self, gene, sequence="ATGC", windowoffset=1, biosample="Undetermined", norm=1.0): self.biosample = biosample self.sequence = sequence self.gene = gene self.windowoffset = windowoffset self.size = len(sequence) self.readDict = defaultdict(list) # with a {+/-offset:[size1, size2, ...], ...} self.matchedreadsUp = 0 self.matchedreadsDown = 0 self.norm=norm def addread (self, polarity, offset, size): '''ATTENTION ATTENTION ATTENTION''' ''' We removed the conversion from 0 to 1 based offset, as we do this now during readparsing.''' if polarity == "+": self.readDict[offset].append(size) self.matchedreadsUp += 1 else: self.readDict[-(offset + size -1)].append(size) self.matchedreadsDown += 1 return def barycenter (self, upstream_coord=None, downstream_coord=None): '''refactored 24-12-2013 to save memory and introduce offset filtering see readcount method for further discussion on that In this version, attempt to replace the dictionary structure by a list of tupple to save memory too''' upstream_coord = upstream_coord or self.windowoffset downstream_coord = downstream_coord or self.windowoffset+self.size-1 window_size = downstream_coord - upstream_coord +1 def weigthAverage (TuppleList): weightSum = 0 PonderWeightSum = 0 for tuple in TuppleList: PonderWeightSum += tuple[0] * tuple[1] weightSum += tuple[1] if weightSum > 0: return PonderWeightSum / float(weightSum) else: return 0 forwardTuppleList = [(k, len(self.readDict[k])) for k in self.readDict.keys() if (k > 0 and abs(k) >= upstream_coord and abs(k) <= downstream_coord)] # both forward and in the proper offset window reverseTuppleList = [(-k, len(self.readDict[k])) for k in self.readDict.keys() if (k < 0 and abs(k) >= upstream_coord and abs(k) <= downstream_coord)] # both reverse and in the proper offset window Fbarycenter = (weigthAverage (forwardTuppleList) - upstream_coord) / window_size Rbarycenter = (weigthAverage (reverseTuppleList) - upstream_coord) / window_size return Fbarycenter, Rbarycenter def correlation_mapper (self, reference, window_size): '''to map correlation with a sliding window 26-2-2013''' from scipy import stats if window_size > self.size: return [] F=open(reference, "r") reference_forward = [] reference_reverse = [] for line in F: fields=line.split() reference_forward.append(int(float(fields[1]))) reference_reverse.append(int(float(fields[2]))) F.close() local_object_forward=[] local_object_reverse=[] ## Dict to list for the local object for i in range(1, self.size+1): local_object_forward.append(len(self.readDict[i])) local_object_reverse.append(len(self.readDict[-i])) ## start compiling results by slides results=[] for coordinate in range(self.size - window_size): local_forward=local_object_forward[coordinate:coordinate + window_size] local_reverse=local_object_reverse[coordinate:coordinate + window_size] if sum(local_forward) == 0 or sum(local_reverse) == 0: continue try: reference_to_local_cor_forward = stats.spearmanr(local_forward, reference_forward) reference_to_local_cor_reverse = stats.spearmanr(local_reverse, reference_reverse) if (reference_to_local_cor_forward[0] > 0.2 or reference_to_local_cor_reverse[0]>0.2): results.append([coordinate+1, reference_to_local_cor_forward[0], reference_to_local_cor_reverse[0]]) except: pass return results def readcount (self, size_inf=0, size_sup=1000, upstream_coord=None, downstream_coord=None, polarity="both", method="conservative"): '''refactored 24-12-2013 to save memory and introduce offset filtering take a look at the defaut parameters that cannot be defined relatively to the instance are they are defined before instanciation the trick is to pass None and then test polarity parameter can take "both", "forward" or "reverse" as value''' upstream_coord = upstream_coord or self.windowoffset downstream_coord = downstream_coord or self.windowoffset+self.size-1 if upstream_coord == 1 and downstream_coord == self.windowoffset+self.size-1 and polarity == "both": return self.matchedreadsUp + self.matchedreadsDown if upstream_coord == 1 and downstream_coord == self.windowoffset+self.size-1 and polarity == "forward": return self.matchedreadsUp if upstream_coord == 1 and downstream_coord == self.windowoffset+self.size-1 and polarity == "reverse": return self.matchedreadsDown n=0 if polarity == "both": for offset in xrange(upstream_coord, downstream_coord+1): if self.readDict.has_key(offset): for read in self.readDict[offset]: if (read>=size_inf and read<= size_sup): n += 1 if method != "conservative": del self.readDict[offset] ## Carefull ! precludes re-use on the self.readDict dictionary !!!!!! TEST if self.readDict.has_key(-offset): for read in self.readDict[-offset]: if (read>=size_inf and read<= size_sup): n += 1 if method != "conservative": del self.readDict[-offset] return n elif polarity == "forward": for offset in xrange(upstream_coord, downstream_coord+1): if self.readDict.has_key(offset): for read in self.readDict[offset]: if (read>=size_inf and read<= size_sup): n += 1 return n elif polarity == "reverse": for offset in xrange(upstream_coord, downstream_coord+1): if self.readDict.has_key(-offset): for read in self.readDict[-offset]: if (read>=size_inf and read<= size_sup): n += 1 return n def readsizes (self): '''return a dictionary of number of reads by size (the keys)''' dicsize = {} for offset in self.readDict: for size in self.readDict[offset]: dicsize[size] = dicsize.get(size, 0) + 1 for offset in range (min(dicsize.keys()), max(dicsize.keys())+1): dicsize[size] = dicsize.get(size, 0) # to fill offsets with null values return dicsize # def size_histogram(self): # norm=self.norm # hist_dict={} # hist_dict['F']={} # hist_dict['R']={} # for offset in self.readDict: # for size in self.readDict[offset]: # if offset < 0: # hist_dict['R'][size] = hist_dict['R'].get(size, 0) - 1*norm # else: # hist_dict['F'][size] = hist_dict['F'].get(size, 0) + 1*norm # ## patch to avoid missing graphs when parsed by R-lattice. 27-08-2014. Test and validate ! # if not (hist_dict['F']) and (not hist_dict['R']): # hist_dict['F'][21] = 0 # hist_dict['R'][21] = 0 # ## # return hist_dict def size_histogram(self, minquery=None, maxquery=None): # in SmRNAwindow '''refactored on 7-9-2014 to debug size_histogram tool''' norm=self.norm size_dict={} size_dict['F']= defaultdict (float) size_dict['R']= defaultdict (float) size_dict['both']= defaultdict (float) for offset in self.readDict: for size in self.readDict[offset]: if offset < 0: size_dict['R'][size] = size_dict['R'][size] - 1*norm else: size_dict['F'][size] = size_dict['F'][size] + 1*norm ## patch to avoid missing graphs when parsed by R-lattice. 27-08-2014. Test and validate ! if not (size_dict['F']) and (not size_dict['R']): size_dict['F'][21] = 0 size_dict['R'][21] = 0 ## allSizeKeys = list (set (size_dict['F'].keys() + size_dict['R'].keys() ) ) for size in allSizeKeys: size_dict['both'][size] = size_dict['F'][size] - size_dict['R'][size] if minquery: for polarity in size_dict.keys(): for size in xrange(minquery, maxquery+1): if not size in size_dict[polarity].keys(): size_dict[polarity][size]=0 return size_dict def statsizes (self, upstream_coord=None, downstream_coord=None): ''' migration to memory saving by specifying possible subcoordinates see the readcount method for further discussion''' upstream_coord = upstream_coord or self.windowoffset downstream_coord = downstream_coord or self.windowoffset+self.size-1 L = [] for offset in self.readDict: if (abs(offset) < upstream_coord or abs(offset) > downstream_coord): continue for size in self.readDict[offset]: L.append(size) meansize = mean(L) stdv = std(L) mediansize = median(L) return meansize, mediansize, stdv def foldEnergy (self, upstream_coord=None, downstream_coord=None): ''' migration to memory saving by specifying possible subcoordinates see the readcount method for further discussion''' upstream_coord = upstream_coord or self.windowoffset downstream_coord = downstream_coord or self.windowoffset+self.size-1 Energy = RNAfold ([self.sequence[upstream_coord-1:downstream_coord] ]) return float(Energy[self.sequence[upstream_coord-1:downstream_coord]]) def Ufreq (self, size_scope, upstream_coord=None, downstream_coord=None): ''' migration to memory saving by specifying possible subcoordinates see the readcount method for further discussion. size_scope must be an interable''' upstream_coord = upstream_coord or self.windowoffset downstream_coord = downstream_coord or self.windowoffset+self.size-1 freqDic = {"A":0,"T":0,"G":0,"C":0, "N":0} convertDic = {"A":"T","T":"A","G":"C","C":"G","N":"N"} for offset in self.readDict: if (abs(offset) < upstream_coord or abs(offset) > downstream_coord): continue for size in self.readDict[offset]: if size in size_scope: startbase = self.sequence[abs(offset)-self.windowoffset] if offset < 0: startbase = convertDic[startbase] freqDic[startbase] += 1 base_sum = float ( sum( freqDic.values()) ) if base_sum == 0: return "." else: return freqDic["T"] / base_sum * 100 def Ufreq_stranded (self, size_scope, upstream_coord=None, downstream_coord=None): ''' migration to memory saving by specifying possible subcoordinates see the readcount method for further discussion. size_scope must be an interable This method is similar to the Ufreq method but take strandness into account''' upstream_coord = upstream_coord or self.windowoffset downstream_coord = downstream_coord or self.windowoffset+self.size-1 freqDic = {"Afor":0,"Tfor":0,"Gfor":0,"Cfor":0, "Nfor":0,"Arev":0,"Trev":0,"Grev":0,"Crev":0, "Nrev":0} convertDic = {"A":"T","T":"A","G":"C","C":"G","N":"N"} for offset in self.readDict: if (abs(offset) < upstream_coord or abs(offset) > downstream_coord): continue for size in self.readDict[offset]: if size in size_scope: startbase = self.sequence[abs(offset)-self.windowoffset] if offset < 0: startbase = convertDic[startbase] freqDic[startbase+"rev"] += 1 else: freqDic[startbase+"for"] += 1 forward_sum = float ( freqDic["Afor"]+freqDic["Tfor"]+freqDic["Gfor"]+freqDic["Cfor"]+freqDic["Nfor"]) reverse_sum = float ( freqDic["Arev"]+freqDic["Trev"]+freqDic["Grev"]+freqDic["Crev"]+freqDic["Nrev"]) if forward_sum == 0 and reverse_sum == 0: return ". | ." elif reverse_sum == 0: return "%s | ." % (freqDic["Tfor"] / forward_sum * 100) elif forward_sum == 0: return ". | %s" % (freqDic["Trev"] / reverse_sum * 100) else: return "%s | %s" % (freqDic["Tfor"] / forward_sum * 100, freqDic["Trev"] / reverse_sum * 100) def readplot (self): norm=self.norm readmap = {} for offset in self.readDict.keys(): readmap[abs(offset)] = ( len(self.readDict.get(-abs(offset),[]))*norm , len(self.readDict.get(abs(offset),[]))*norm ) mylist = [] for offset in sorted(readmap): if readmap[offset][1] != 0: mylist.append("%s\t%s\t%s\t%s" % (self.gene, offset, readmap[offset][1], "F") ) if readmap[offset][0] != 0: mylist.append("%s\t%s\t%s\t%s" % (self.gene, offset, -readmap[offset][0], "R") ) ## patch to avoid missing graphs when parsed by R-lattice. 27-08-2014. Test and validate ! if not mylist: mylist.append("%s\t%s\t%s\t%s" % (self.gene, 1, 0, "F") ) ### return mylist def readcoverage (self, upstream_coord=None, downstream_coord=None, windowName=None): '''Use by MirParser tool''' upstream_coord = upstream_coord or 1 downstream_coord = downstream_coord or self.size windowName = windowName or "%s_%s_%s" % (self.gene, upstream_coord, downstream_coord) forORrev_coverage = dict ([(i,0) for i in xrange(1, downstream_coord-upstream_coord+1)]) totalforward = self.readcount(upstream_coord=upstream_coord, downstream_coord=downstream_coord, polarity="forward") totalreverse = self.readcount(upstream_coord=upstream_coord, downstream_coord=downstream_coord, polarity="reverse") if totalforward > totalreverse: majorcoverage = "forward" for offset in self.readDict.keys(): if (offset > 0) and ((offset-upstream_coord+1) in forORrev_coverage.keys() ): for read in self.readDict[offset]: for i in xrange(read): try: forORrev_coverage[offset-upstream_coord+1+i] += 1 except KeyError: continue # a sense read may span over the downstream limit else: majorcoverage = "reverse" for offset in self.readDict.keys(): if (offset < 0) and (-offset-upstream_coord+1 in forORrev_coverage.keys() ): for read in self.readDict[offset]: for i in xrange(read): try: forORrev_coverage[-offset-upstream_coord-i] += 1 ## positive coordinates in the instance, with + for forward coverage and - for reverse coverage except KeyError: continue # an antisense read may span over the upstream limit output_list = [] maximum = max (forORrev_coverage.values()) or 1 for n in sorted (forORrev_coverage): output_list.append("%s\t%s\t%s\t%s\t%s\t%s\t%s" % (self.biosample, windowName, n, float(n)/(downstream_coord-upstream_coord+1), forORrev_coverage[n], float(forORrev_coverage[n])/maximum, majorcoverage)) return "\n".join(output_list) def signature (self, minquery, maxquery, mintarget, maxtarget, scope, zscore="no", upstream_coord=None, downstream_coord=None): ''' migration to memory saving by specifying possible subcoordinates see the readcount method for further discussion scope must be a python iterable; scope define the *relative* offset range to be computed''' upstream_coord = upstream_coord or self.windowoffset downstream_coord = downstream_coord or self.windowoffset+self.size-1 query_range = range (minquery, maxquery+1) target_range = range (mintarget, maxtarget+1) Query_table = {} Target_table = {} frequency_table = dict ([(i, 0) for i in scope]) for offset in self.readDict: if (abs(offset) < upstream_coord or abs(offset) > downstream_coord): continue for size in self.readDict[offset]: if size in query_range: Query_table[offset] = Query_table.get(offset, 0) + 1 if size in target_range: Target_table[offset] = Target_table.get(offset, 0) + 1 for offset in Query_table: for i in scope: frequency_table[i] += min(Query_table[offset], Target_table.get(-offset -i +1, 0)) if minquery==mintarget and maxquery==maxtarget: ## added to incorporate the division by 2 in the method (26/11/2013), see signature_options.py and lattice_signature.py frequency_table = dict([(i,frequency_table[i]/2) for i in frequency_table]) if zscore == "yes": z_mean = mean(frequency_table.values() ) z_std = std(frequency_table.values() ) if z_std == 0: frequency_table = dict([(i,0) for i in frequency_table] ) else: frequency_table = dict([(i, (frequency_table[i]- z_mean)/z_std) for i in frequency_table] ) return frequency_table def hannon_signature (self, minquery, maxquery, mintarget, maxtarget, scope, upstream_coord=None, downstream_coord=None): ''' migration to memory saving by specifying possible subcoordinates see the readcount method for further discussion note that scope must be an iterable (a list or a tuple), which specifies the relative offsets that will be computed''' upstream_coord = upstream_coord or self.windowoffset downstream_coord = downstream_coord or self.windowoffset+self.size-1 query_range = range (minquery, maxquery+1) target_range = range (mintarget, maxtarget+1) Query_table = {} Target_table = {} Total_Query_Numb = 0 general_frequency_table = dict ([(i,0) for i in scope]) ## filtering the appropriate reads for the study for offset in self.readDict: if (abs(offset) < upstream_coord or abs(offset) > downstream_coord): continue for size in self.readDict[offset]: if size in query_range: Query_table[offset] = Query_table.get(offset, 0) + 1 Total_Query_Numb += 1 if size in target_range: Target_table[offset] = Target_table.get(offset, 0) + 1 for offset in Query_table: frequency_table = dict ([(i,0) for i in scope]) number_of_targets = 0 for i in scope: frequency_table[i] += Query_table[offset] * Target_table.get(-offset -i +1, 0) number_of_targets += Target_table.get(-offset -i +1, 0) for i in scope: try: general_frequency_table[i] += (1. / number_of_targets / Total_Query_Numb) * frequency_table[i] except ZeroDivisionError : continue return general_frequency_table def phasing (self, size_range, scope): ''' to calculate autocorelation like signal - scope must be an python iterable''' read_table = {} total_read_number = 0 general_frequency_table = dict ([(i, 0) for i in scope]) ## read input filtering for offset in self.readDict: for size in self.readDict[offset]: if size in size_range: read_table[offset] = read_table.get(offset, 0) + 1 total_read_number += 1 ## per offset read phasing computing for offset in read_table: frequency_table = dict ([(i, 0) for i in scope]) # local frequency table number_of_targets = 0 for i in scope: if offset > 0: frequency_table[i] += read_table[offset] * read_table.get(offset + i, 0) number_of_targets += read_table.get(offset + i, 0) else: frequency_table[i] += read_table[offset] * read_table.get(offset - i, 0) number_of_targets += read_table.get(offset - i, 0) ## inclusion of local frequency table in the general frequency table (all offsets average) for i in scope: try: general_frequency_table[i] += (1. / number_of_targets / total_read_number) * frequency_table[i] except ZeroDivisionError : continue return general_frequency_table def z_signature (self, minquery, maxquery, mintarget, maxtarget, scope): '''Must do: from numpy import mean, std, to use this method; scope must be a python iterable and defines the relative offsets to compute''' frequency_table = self.signature (minquery, maxquery, mintarget, maxtarget, scope) z_table = {} frequency_list = [frequency_table[i] for i in sorted (frequency_table)] if std(frequency_list): meanlist = mean(frequency_list) stdlist = std(frequency_list) z_list = [(i-meanlist)/stdlist for i in frequency_list] return dict (zip (sorted(frequency_table), z_list) ) else: return dict (zip (sorted(frequency_table), [0 for i in frequency_table]) ) def percent_signature (self, minquery, maxquery, mintarget, maxtarget, scope): frequency_table = self.signature (minquery, maxquery, mintarget, maxtarget, scope) total = float(sum ([self.readsizes().get(i,0) for i in set(range(minquery,maxquery)+range(mintarget,maxtarget))]) ) if total == 0: return dict( [(i,0) for i in scope]) return dict( [(i, frequency_table[i]/total*100) for i in scope]) def pairer (self, overlap, minquery, maxquery, mintarget, maxtarget): queryhash = defaultdict(list) targethash = defaultdict(list) query_range = range (int(minquery), int(maxquery)+1) target_range = range (int(mintarget), int(maxtarget)+1) paired_sequences = [] for offset in self.readDict: # selection of data for size in self.readDict[offset]: if size in query_range: queryhash[offset].append(size) if size in target_range: targethash[offset].append(size) for offset in queryhash: if offset >= 0: matched_offset = -offset - overlap + 1 else: matched_offset = -offset - overlap + 1 if targethash[matched_offset]: paired = min ( len(queryhash[offset]), len(targethash[matched_offset]) ) if offset >= 0: for i in range (paired): paired_sequences.append("+%s" % RNAtranslate ( self.sequence[offset:offset+queryhash[offset][i]]) ) paired_sequences.append("-%s" % RNAtranslate (antipara (self.sequence[-matched_offset-targethash[matched_offset][i]+1:-matched_offset+1]) ) ) if offset < 0: for i in range (paired): paired_sequences.append("-%s" % RNAtranslate (antipara (self.sequence[-offset-queryhash[offset][i]+1:-offset+1]) ) ) paired_sequences.append("+%s" % RNAtranslate (self.sequence[matched_offset:matched_offset+targethash[matched_offset][i]] ) ) return paired_sequences def pairable (self, overlap, minquery, maxquery, mintarget, maxtarget): queryhash = defaultdict(list) targethash = defaultdict(list) query_range = range (int(minquery), int(maxquery)+1) target_range = range (int(mintarget), int(maxtarget)+1) paired_sequences = [] for offset in self.readDict: # selection of data for size in self.readDict[offset]: if size in query_range: queryhash[offset].append(size) if size in target_range: targethash[offset].append(size) for offset in queryhash: matched_offset = -offset - overlap + 1 if targethash[matched_offset]: if offset >= 0: for i in queryhash[offset]: paired_sequences.append("+%s" % RNAtranslate (self.sequence[offset:offset+i]) ) for i in targethash[matched_offset]: paired_sequences.append( "-%s" % RNAtranslate (antipara (self.sequence[-matched_offset-i+1:-matched_offset+1]) ) ) if offset < 0: for i in queryhash[offset]: paired_sequences.append("-%s" % RNAtranslate (antipara (self.sequence[-offset-i+1:-offset+1]) ) ) for i in targethash[matched_offset]: paired_sequences.append("+%s" % RNAtranslate (self.sequence[matched_offset:matched_offset+i] ) ) return paired_sequences def newpairable_bowtie (self, overlap, minquery, maxquery, mintarget, maxtarget): ''' revision of pairable on 3-12-2012, with focus on the offset shift problem (bowtie is 1-based cooordinates whereas python strings are 0-based coordinates''' queryhash = defaultdict(list) targethash = defaultdict(list) query_range = range (int(minquery), int(maxquery)+1) target_range = range (int(mintarget), int(maxtarget)+1) bowtie_output = [] for offset in self.readDict: # selection of data for size in self.readDict[offset]: if size in query_range: queryhash[offset].append(size) if size in target_range: targethash[offset].append(size) counter = 0 for offset in queryhash: matched_offset = -offset - overlap + 1 if targethash[matched_offset]: if offset >= 0: for i in queryhash[offset]: counter += 1 bowtie_output.append("%s\t%s\t%s\t%s\t%s" % (counter, "+", self.gene, offset-1, self.sequence[offset-1:offset-1+i]) ) # attention a la base 1-0 de l'offset if offset < 0: for i in queryhash[offset]: counter += 1 bowtie_output.append("%s\t%s\t%s\t%s\t%s" % (counter, "-", self.gene, -offset-i, self.sequence[-offset-i:-offset])) # attention a la base 1-0 de l'offset return bowtie_output def __main__(bowtie_index_path, bowtie_output_path): sequenceDic = get_fasta (bowtie_index_path) objDic = {} F = open (bowtie_output_path, "r") # F is the bowtie output taken as input for line in F: fields = line.split() polarity = fields[1] gene = fields[2] offset = int(fields[3]) size = len (fields[4]) try: objDic[gene].addread (polarity, offset, size) except KeyError: objDic[gene] = SmRNAwindow(gene, sequenceDic[gene]) objDic[gene].addread (polarity, offset, size) F.close() for gene in objDic: print gene, objDic[gene].pairer(19,19,23,19,23) if __name__ == "__main__" : __main__(sys.argv[1], sys.argv[2])