""" Module for Gene ontology related functions called in R""" import scipy import rpy silent_eval = rpy.with_mode(rpy.NO_CONVERSION, rpy.r) def goterms_from_gene(genelist, ontology='BP', garbage=None): """ Returns the go-terms from a specified genelist (Entrez id). Recalculates the information content if needed based on selected evidence codes. """ rpy.r.library("GOSim") _CODES = {"IMP" : "inferred from mutant phenotype", "IGI" : "inferred from genetic interaction", "IPI" :"inferred from physical interaction", "ISS" : "inferred from sequence similarity", "IDA" : "inferred from direct assay", "IEP" : "inferred from expression pattern", "IEA" : "inferred from electronic annotation", "TAS" : "traceable author statement", "NAS" : "non-traceable author statement", "ND" : "no biological data available", "IC" : "inferred by curator" } _ONTOLOGIES = ['BP', 'CC', 'MF'] #assert(scipy.all([(code in _CODES) for code in garbage]) or garbage==None) assert(ontology in _ONTOLOGIES) dummy = rpy.r.setOntology(ontology) ddef = False if ontology=='BP' and garbage!=None: # This is for ont=BP and garbage =['IEA', 'ISS', 'ND'] rpy.r.load("ICsBPIMP_IGI_IPI_ISS_IDA_IEP_TAS_NAS_IC.rda") ic = rpy.r.assign("IC",rpy.r.IC, envir=rpy.r.GOSimEnv) print len(ic) else: ic = rpy.r('get("IC", envir=GOSimEnv)') print "loading GO definitions environment" gene2terms = {} for gene in genelist: info = rpy.r('GOENTREZID2GO[["' + str(gene) + '"]]') #print info if info: skip=False for term, desc in info.items(): if ic.get(term)==scipy.isinf: print "\nIC is Inf on this GO term %s for this gene: %s" %(term,gene) skip=True if ic.get(term)==None: #print "\nHave no IC on this GO term %s for this gene: %s" %(term,gene) skip=True if desc['Ontology']!=ontology: #print "\nThis GO term %s belongs to: %s:" %(term,desc['Ontology']) skip = True if not skip: if gene2terms.has_key(gene): gene2terms[gene].append(term) else: gene2terms[gene] = [term] else: print "\nHave no Annotation on this gene: %s" %gene return gene2terms def genego_matrix(goterms, tmat, gene_ids, term_ids, func=max): ngenes = len(gene_ids) nterms = len(term_ids) gene2indx = {} for i,id in enumerate(gene_ids): gene2indx[id]=i term2indx = {} for i,id in enumerate(term_ids): term2indx[id]=i #G = scipy.empty((nterms, ngenes),'d') G = [] new_gene_index = [] for gene, terms in goterms.items(): g_ind = gene2indx[gene] if len(terms)>0: t_ind = [] new_gene_index.append(g_ind) for term in terms: if term2indx.has_key(term): t_ind.append(term2indx[term]) subsim = tmat[t_ind, :] gene_vec = scipy.apply_along_axis(func, 0, subsim) G.append(gene_vec) return scipy.asarray(G), new_gene_index def genego_sim(gene2go, gene_ids, all_go_terms, STerm, go_term_sim="OA", term_sim="Lin", verbose=False): """Returns go-terms x genes similarity matrix. :input: - gene2go: dict: keys: gene_id, values: go_terms - gene_ids: list of gene ids (entrez ids) - STerm: (go_terms x go_terms) similarity matrix - go_terms_sim: similarity measure between a gene and multiple go terms (max, mean, OA) - term_sim: similarity measure between two go-terms - verbose """ rpy.r.library("GOSim") #gene_ids = gene2go.keys() GG = scipy.empty((len(all_go_terms), len(gene_ids)), 'd') for j,gene in enumerate(gene_ids): for i,go_term in enumerate(all_go_terms): if verbose: print "\nAssigning similarity from %s to terms(gene): %s" %(go_term,gene) GG_ij = rpy.r.getGSim(go_term, gene2go[gene], similarity=go_term_sim, similarityTerm=term_sim, STerm=STerm, verbose=verbose) GG[i,j] = GG_ij return GG def goterm2desc(gotermlist): """Returns the go-terms description keyed by go-term. """ rpy.r.library("GO") term2desc = {} for term in gotermlist: try: desc = rpy.r('Term(GOTERM[["' +str(term)+ '"]])') term2desc[str(term)] = desc except: raise Warning("Description not found for %s\n Mapping incomplete" %term) return term2desc def parents_dag(go_terms, ontology=['BP']): """ Returns a list of lists representation of a GO DAG parents of goterms. make the networkx graph by: G = networkx.Digraph() G = networkx.from_dict_of_lists(edge_dict, G) """ try: rpy.r.library("GOstats") except: raise ImportError, "Gostats" assert(go_terms[0][:3]=='GO:') # go valid namespace go_env = {'BP':rpy.r.GOBPPARENTS, 'MF':rpy.r.GOMFPARENTS, 'CC': rpy.r.GOCCPARENTS} graph = rpy.r.GOGraph(go_terms, go_env[ontology[0]]) edges = rpy.r.edges(graph) edges.pop('all') edge_dict = {} for head, neighbours in edges.items(): for nn in neighbours.values(): if edge_dict.has_key(nn): edge_dict[nn].append(head) else: edge_dict[nn] = [head] return edge_dict def gene_GO_hypergeo_test(genelist,universe="entrezUniverse",ontology="BP",chip = "hgu133a",pval_cutoff=0.01,cond=False,test_direction="over"): #assert(scipy.alltrue([True for i in genelist if i in universe])) universeGeneIds=universe params = rpy.r.new("GOHyperGParams", geneIds=genelist, annotation="hgu133a", ontology=ontology, pvalueCutoff=pval_cutoff, conditional=cond, testDirection=test_direction ) result = rpy.r.summary(rpy.r.hyperGTest(params)) return rpy.r.summary(result), params