34dc2bb14c176fb8f788df267fdb3fd4c8f461b4 braney Fri Feb 17 07:00:46 2023 -0800 fix some encoding issues and an errant printf on the TOGO hgc page. diff --git src/hg/hgc/togaClick.c src/hg/hgc/togaClick.c index 5608e5c..00a4c8c 100644 --- src/hg/hgc/togaClick.c +++ src/hg/hgc/togaClick.c @@ -1,696 +1,695 @@ /* togaClick - click handling for TOGA tracks */ #include "common.h" #include "hgc.h" #include "togaClick.h" #include "string.h" #include "htmshell.h" #include "chromAlias.h" struct togaDataBB *togaDataBBLoad(char **row) /* Load a togaData from row fetched with select * from togaData * from database. Dispose of this with togaDataFree(). */ { struct togaDataBB *ret; AllocVar(ret); ret->projection = cloneString(row[0]); ret->ref_trans_id = cloneString(row[1]); ret->ref_region = cloneString(row[2]); ret->query_region = cloneString(row[3]); ret->chain_score = cloneString(row[4]); ret->chain_synteny = cloneString(row[5]); ret->chain_flank = cloneString(row[6]); ret->chain_gl_cds_fract = cloneString(row[7]); ret->chain_loc_cds_fract = cloneString(row[8]); ret->chain_exon_cov = cloneString(row[9]); ret->chain_intron_cov = cloneString(row[10]); ret->status = cloneString(row[11]); ret->perc_intact_ign_M = cloneString(row[12]); ret->perc_intact_int_M = cloneString(row[13]); ret->intact_codon_prop = cloneString(row[14]); ret->ouf_prop = cloneString(row[15]); ret->mid_intact = cloneString(row[16]); ret->mid_pres = cloneString(row[17]); ret->prot_alignment = cloneString(row[18]); ret->svg_line = cloneString(row[19]); ret->ref_link = cloneString(row[20]); ret->inact_mut_html_table = cloneString(row[21]); ret->exon_ali_html = cloneString(row[22]); return ret; } struct togaData *togaDataLoad(char **row) /* Load a togaData from row fetched with select * from togaData * from database. Dispose of this with togaDataFree(). */ { struct togaData *ret; AllocVar(ret); ret->projection = cloneString(row[0]); ret->ref_trans_id = cloneString(row[1]); ret->ref_region = cloneString(row[2]); ret->query_region = cloneString(row[3]); ret->chain_score = cloneString(row[4]); ret->chain_synteny = cloneString(row[5]); ret->chain_flank = cloneString(row[6]); ret->chain_gl_cds_fract = cloneString(row[7]); ret->chain_loc_cds_fract = cloneString(row[8]); ret->chain_exon_cov = cloneString(row[9]); ret->chain_intron_cov = cloneString(row[10]); ret->status = cloneString(row[11]); ret->perc_intact_ign_M = cloneString(row[12]); ret->perc_intact_int_M = cloneString(row[13]); ret->intact_codon_prop = cloneString(row[14]); ret->ouf_prop = cloneString(row[15]); ret->mid_intact = cloneString(row[16]); ret->mid_pres = cloneString(row[17]); ret->prot_alignment = cloneString(row[18]); ret->svg_line = cloneString(row[19]); return ret; } void togaDataBBFree(struct togaDataBB **pEl) /* Free a single dynamically allocated togaDatasuch as created * with togaDataLoad(). */ { struct togaDataBB *el; if ((el = *pEl) == NULL) return; freeMem(el->projection); freeMem(el->ref_trans_id); freeMem(el->ref_region); freeMem(el->query_region); freeMem(el->chain_score); freeMem(el->chain_synteny); freeMem(el->chain_flank); freeMem(el->chain_gl_cds_fract); freeMem(el->chain_loc_cds_fract); freeMem(el->chain_exon_cov); freeMem(el->chain_intron_cov); freeMem(el->status); freeMem(el->perc_intact_ign_M); freeMem(el->perc_intact_int_M); freeMem(el->intact_codon_prop); freeMem(el->ouf_prop); freeMem(el->mid_intact); freeMem(el->mid_pres); freeMem(el->prot_alignment); freeMem(el->svg_line); freeMem(el->ref_link); freeMem(el->inact_mut_html_table); freeMem(el->exon_ali_html); freez(pEl); } void togaDataFree(struct togaData **pEl) /* Free a single dynamically allocated togaDatasuch as created * with togaDataLoad(). */ { struct togaData *el; if ((el = *pEl) == NULL) return; freeMem(el->projection); freeMem(el->ref_trans_id); freeMem(el->ref_region); freeMem(el->query_region); freeMem(el->chain_score); freeMem(el->chain_synteny); freeMem(el->chain_flank); freeMem(el->chain_gl_cds_fract); freeMem(el->chain_loc_cds_fract); freeMem(el->chain_exon_cov); freeMem(el->chain_intron_cov); freeMem(el->status); freeMem(el->perc_intact_ign_M); freeMem(el->perc_intact_int_M); freeMem(el->intact_codon_prop); freeMem(el->ouf_prop); freeMem(el->mid_intact); freeMem(el->mid_pres); freeMem(el->prot_alignment); freeMem(el->svg_line); freez(pEl); } struct togaNucl *togaNuclLoad(char **row) /* Load a togaNucl from row fetched with select * from togaNucl * from database. Dispose of this with togaNuclFree(). */ { struct togaNucl *ret; AllocVar(ret); ret->transcript = cloneString(row[0]); ret->exon_num = cloneString(row[1]); ret->exon_region = cloneString(row[2]); ret->pid = cloneString(row[3]); ret->blosum = cloneString(row[4]); ret->gaps = cloneString(row[5]); ret->ali_class = cloneString(row[6]); ret->exp_region = cloneString(row[7]); ret->in_exp_region = cloneString(row[8]); ret->alignment = cloneString(row[9]); return ret; } void togaNuclFree(struct togaNucl **pEl) /* Free a single dynamically allocated togaNucl such as created * with togaNuclLoad(). */ { struct togaNucl *el; if ((el = *pEl) == NULL) return; freeMem(el->transcript); freeMem(el->exon_num); freeMem(el->exon_region); freeMem(el->pid); freeMem(el->blosum); freeMem(el->gaps); freeMem(el->ali_class); freeMem(el->exp_region); freeMem(el->in_exp_region); freeMem(el->alignment); freez(pEl); } struct togaInactMut *togaInactMutLoad(char **row) /* Load a togaInactMut from row fetched with select * from togaInactMut * from database. Dispose of this with togaInactMutFree(). */ { struct togaInactMut *ret; AllocVar(ret); ret->transcript = cloneString(row[0]); ret->exon_num = cloneString(row[1]); ret->position = cloneString(row[2]); ret->mut_class = cloneString(row[3]); ret->mutation = cloneString(row[4]); ret->is_inact = cloneString(row[5]); ret->mut_id = cloneString(row[6]); return ret; } void togaInactMutFree(struct togaInactMut **pEl) /* Free a single dynamically allocated togaInactMut such as created * with togaInactMutLoad(). */ { struct togaInactMut *el; if ((el = *pEl) == NULL) return; freeMem(el->transcript); freeMem(el->exon_num); freeMem(el->position); freeMem(el->mut_class); freeMem(el->mutation); freeMem(el->is_inact); freeMem(el->mut_id); freez(pEl); } void extractHLTOGAsuffix(char *suffix) /* Extract suffix from TOGA table name. Prefix must be HLTOGAannot */ { int suff_len = strlen(suffix); if (suff_len <= HLTOGA_BED_PREFIX_LEN) // we cannot chop first PREFIX_LEN characters { // TODO: NOT SURE IF IT WORKS; but this must not happen char empty[5] = { '\0' }; strcpy(suffix, empty); } else { // just start the string 11 characters upstream memmove(suffix, suffix + HLTOGA_BED_PREFIX_LEN, suff_len - HLTOGA_BED_PREFIX_LEN + 1); } } void HLprintQueryProtSeqForAli(char *proteinAlignment) { // take protein sequence alignment // print only the query sequence char *str = proteinAlignment; int printed_char_num = 0; while ((str = strstr(str, "que:")) != NULL) { str += 10; char ch; while ((ch = *str++) != '<') { if (ch != '-') { putchar(ch); ++printed_char_num; } if (printed_char_num == 80) { printed_char_num = 0; printf("<BR>"); } } } } void doHillerLabTOGAGeneBig(char *database, struct trackDb *tdb, char *item, char *table_name) /* Put up TOGA Gene track info. */ // To think about -> put into a single bigBed // string: HTML formatted inact mut // string: HTML formatted exon ali section { int start = cartInt(cart, "o"); int end = cartInt(cart, "t"); char *chrom = cartString(cart, "c"); char *fileName = bbiNameFromSettingOrTable(tdb, NULL, tdb->table); struct bbiFile *bbi = bigBedFileOpenAlias(hReplaceGbdb(fileName), chromAliasFindAliases); struct lm *lm = lmInit(0); struct bigBedInterval *bbList = bigBedIntervalQuery(bbi, chrom, start, end, 0, lm); struct bigBedInterval *bb; char *fields[bbi->fieldCount]; for (bb = bbList; bb != NULL; bb = bb->next) { if (!(bb->start == start && bb->end == end)) continue; // our names are unique char *name = cloneFirstWordByDelimiterNoSkip(bb->rest, '\t'); boolean match = (isEmpty(name) && isEmpty(item)) || sameOk(name, item); if (!match) continue; char startBuf[16], endBuf[16]; bigBedIntervalToRow(bb, chrom, startBuf, endBuf, fields, bbi->fieldCount); break; } printf("<h3>Projection %s</h3><BR>\n", item); struct togaDataBB *info = togaDataBBLoad(&fields[11]); // Bogdan: why 11? 0-11 are bed-like fields likely printf("<B>Reference transcript: </B>%s<BR>", info->ref_link); printf("<B>Genomic locus in reference: </B>%s<BR>\n", info->ref_region); printf("<B>Genomic locus in query: </B>%s<BR>\n", info->query_region); printf("<B>Projection classification: </B>%s<BR>\n", info->status); printf("<B>Probability that query locus is orthologous: </B>%s<BR>\n", info->chain_score); // list of chain features (for orthology classification) printf("<a data-toggle=\"collapse\" href=\"#collapseChain\">Show features used for ortholog probability</a>\n"); printf("<div id=\"collapseChain\" class=\"panel-collapse collapse\">\n"); printf("<ul>\n"); printf("<li>Synteny (log10 value): %s</li>\n", info->chain_synteny); printf("<li>Global CDS fraction: %s</li>\n", info->chain_gl_cds_fract); printf("<li>Local CDS fraction: %s</li>\n", info->chain_loc_cds_fract); printf("<li>Local intron fraction: %s</li>\n", info->chain_intron_cov); printf("<li>Local CDS coverage: %s</li>\n", info->chain_exon_cov); printf("<li>Flank fraction: %s</li>\n", info->chain_flank); printf("</ul>\n"); printf("<br>\n<b>Feature description:</b>\n"); printf("For each projection (one reference transcript and one overlapping chain),\n"); printf("TOGA computes the following features by intersecting the reference coordinates of aligning\n"); printf("blocks in the chain with different gene parts (coding exons, UTR (untranslated region) exons, introns)\n"); printf("and the respective intergenic regions.\n<br>\n"); printf("We define the following variables:\n<ul>\n"); printf("<li>c: number of reference bases in the intersection between chain blocks and coding exons of the gene under consideration.</li>\n"); printf("<li>C: number of reference bases in the intersection between chain blocks and coding exons of all genes. </li>\n"); printf("<li>a: number of reference bases in the intersection between chain blocks and coding exons and introns of the gene under consideration. </li>\n"); printf("<li>A: number of reference bases in the intersection between chain blocks and coding exons and introns of all genes and the intersection\n"); printf("between chain blocks and intergenic regions (excludes UTRs). </li>\n"); printf("<li>f: number of reference bases in chain blocks overlapping the 10 kb flanks of the gene under consideration.\n"); printf("Alignment blocks overlapping exons of another gene that is located in these 10 kb flanks are ignored. </li>\n"); printf("<li>i: number of reference bases in the intersection between chain blocks and introns of the gene under consideration. </li>\n"); printf("<li>CDS (coding sequence): length of the coding region of the gene under consideration. </li>\n"); printf("<li>I: sum of all intron lengths of the gene under consideration. </li>\n"); printf("</ul>\n"); printf("Using these variables, TOGA computes the following features:\n"); printf("<ul>\n"); -printf("<li>“global CDS fraction” as C / A. Chains with a high value have alignments that largely overlap coding exons,"); +printf("<li>"global CDS fraction" as C / A. Chains with a high value have alignments that largely overlap coding exons,"); printf("which is a hallmark of paralogous or processed pseudogene chains. In contrast, chains with a low value also align many "); printf("intronic and intergenic regions, which is a hallmark of orthologous chains. </li>\n"); -printf("<li>“local CDS fraction” as c / a. Orthologous chains tend to have a lower value, as intronic "); +printf("<li>"local CDS fraction" as c / a. Orthologous chains tend to have a lower value, as intronic "); printf("regions partially align. This feature is not computed for single-exon genes. </li>\n"); -printf("<li>“local intron fraction” as i / I. Orthologous chains tend to have a higher value."); +printf("<li>"local intron fraction" as i / I. Orthologous chains tend to have a higher value."); printf("This feature is not computed for single-exon genes. </li>\n"); -printf("<li>“flank fraction” as f / 20,000. Orthologous chains tend to have higher values,"); +printf("<li>"flank fraction" as f / 20,000. Orthologous chains tend to have higher values,"); printf("as flanking intergenic regions partially align. This feature is important to detect orthologous loci of single-exon genes. </li>\n"); -printf("<li>“synteny” as log10 of the number of genes, whose coding exons overlap by at least one base aligning"); +printf("<li>"synteny" as log10 of the number of genes, whose coding exons overlap by at least one base aligning"); printf("blocks of this chain. Orthologous chains tend to cover several genes located in a conserved order, resulting in higher synteny values. </li>\n"); -printf("<li>“local CDS coverage” as c / CDS, which is only used for single-exon genes. </li>\n"); +printf("<li>"local CDS coverage" as c / CDS, which is only used for single-exon genes. </li>\n"); printf("</ul>\n"); printf("</ul>\n</div>\n<BR>\n"); htmlHorizontalLine(); // show inact mut plot printf("<h4>Visualization of inactivating mutations on exon-intron structure</h4>\n"); printf("%s<BR>\n", info->svg_line); printf("<BR>Exons shown in grey are missing (often overlap assembly gaps).\nExons shown in"); printf(" red or blue are deleted or do not align at all.\nRed indicates that the exon deletion "); printf("shifts the reading frame, while blue indicates that exon deletion(s) are framepreserving.<br>\n"); // GLP features printf("<a data-toggle=\"collapse\" href=\"#collapseGLP\">Show features used for transcript classification</a>\n"); printf("<div id=\"collapseGLP\" class=\"panel-collapse collapse\">\n"); printf("<ul>\n"); printf("<li>Percent intact, ignoring missing sequence: %s</li>\n", info->perc_intact_ign_M); printf("<li>Percent intact, treating missing as intact sequence: %s</li>\n", info->perc_intact_int_M); printf("<li>Proportion of intact codons: %s</li>\n", info->intact_codon_prop); printf("<li>Percent of CDS not covered by this chain (0 unless the chain covers only a part of the gene): %s</li>\n", info->ouf_prop); if (sameWord(info->mid_intact, ONE_)) { printf("<li>Middle 80 percent of CDS intact: %s</li>\n", YES_); } else { printf("<li>Middle 80 percent of CDS intact: %s</li>\n", NO_); } if (sameWord(info->mid_pres, ONE_)) { printf("<li>Middle 80 percent of CDS present: %s</li>\n", YES_); } else { printf("<li>Middle 80 percent of CDS present: %s</li>\n", NO_); } printf("</ul>\n</div>\n<BR>\n"); htmlHorizontalLine(); printf("<h4>Predicted protein sequence</h4><BR>\n"); printf("<a data-toggle=\"collapse\" href=\"#collapseProt\">Show protein sequence of query</a>\n"); printf("<div id=\"collapseProt\" class=\"panel-collapse collapse\">\n"); // printf("<TT>{protein seq of the query without dashes or other things. Should end with *}\n"); printf("<TT>"); HLprintQueryProtSeqForAli(info->prot_alignment); printf("\n<BR>\n</TT>\n</div>\n"); // and show protein sequence htmlHorizontalLine(); printf("<h4>Protein sequence alignment</h4><BR>\n"); printf("<a data-toggle=\"collapse\" href=\"#collapseProtAli\">Show alignment between reference and query</a>\n"); printf("<div id=\"collapseProtAli\" class=\"panel-collapse collapse\">\n"); printf("<TT>%s</TT><BR>\n", info->prot_alignment); printf("</div>\n<BR><BR>\n"); // show inactivating mutations if required printf("<h4>List of inactivating mutations</h4><BR>\n"); printf("<a data-toggle=\"collapse\" href=\"#collapseMuts\">Show inactivating mutations</a>\n"); printf("<div id=\"collapseMuts\" class=\"panel-collapse collapse\">\n"); printf("<table border = \"1\" width = \"640\">\n"); // init table printf("<tr><th>Exon number</th><th>Codon number</th><th>Mutation class</th><th>Mutation</th><th>Treated as inactivating</th><th>Mutation ID</th>\n"); printf("</tr>\n"); printf("%s\n", info->inact_mut_html_table); printf("</table>\n"); printf("</div>\n<BR>\n"); // show exons data htmlHorizontalLine(); printf("<h4>Exon alignments</h4><BR>\n"); printf("<a data-toggle=\"collapse\" href=\"#collapseExons\">Show exon sequences and features</a><BR><BR>\n"); printf("<div id=\"collapseExons\" class=\"panel-collapse collapse\">\n"); // printf("%s\n", info->exon_ali_string); printf("%s\n", info->exon_ali_html); htmlHorizontalLine(); printf("</div>\n<BR>\n"); // TODO: check whether I need this -printf("%s", hgTracksPathAndSettings()); hPrintf("<link rel=\"stylesheet\" href=\"https://maxcdn.bootstrapcdn.com/bootstrap/3.4.1/css/bootstrap.min.css\">"); hPrintf("<script src=\"https://ajax.googleapis.com/ajax/libs/jquery/3.5.1/jquery.min.js\"></script>"); hPrintf("<script src=\"https://maxcdn.bootstrapcdn.com/bootstrap/3.4.1/js/bootstrap.min.js\"></script>"); printTrackHtml(tdb); // and do I need this? } void doHillerLabTOGAGene(char *database, struct trackDb *tdb, char *item, char *table_name) /* Put up TOGA Gene track info. */ { //int start = cartInt(cart, "o"); char headerTitle[512]; char suffix[512]; strcpy(suffix, table_name); extractHLTOGAsuffix(suffix); safef(headerTitle, sizeof(headerTitle), "%s", item); genericHeader(tdb, headerTitle); printf("<h2>TOGA gene annotation</h2>\n"); // htmlHorizontalLine(); if (startsWith("bigBed", tdb->type)) { doHillerLabTOGAGeneBig(database, tdb, item, table_name); return; } struct sqlConnection *conn = hAllocConn(database); // define TOGA table names: initate with pre-defined prefixes char togaDataTableName[256]; char togaNuclTableName[256]; char togaInactMutTableName[256]; strcpy(togaDataTableName, HLTOGA_DATA_PREFIX); strcpy(togaNuclTableName, HLTOGA_NUCL_PREFIX); strcpy(togaInactMutTableName, HLTOGA_INACT_PREFIX); // add suffix strcat(togaDataTableName, suffix); strcat(togaNuclTableName, suffix); strcat(togaInactMutTableName, suffix); if (hTableExists(database, togaDataTableName)) { printf("<h3>Projection %s</h3><BR>\n", item); char query[256]; struct sqlResult *sr = NULL; char **row; struct togaData *info = NULL; sqlSafef(query, sizeof(query), "select * from %s where transcript='%s'", togaDataTableName, item); sr = sqlGetResult(conn, query); if ((row = sqlNextRow(sr)) != NULL) { info = togaDataLoad(row); // parse sql output // fill HTML template: printf("<B>Reference transcript: </B><A HREF=\"http://www.ensembl.org/Homo_sapiens/transview?transcript=%s\" target=_blank>%s</A><BR>", info->ref_trans_id, info->ref_trans_id); printf("<B>Genomic locus in reference: </B>%s<BR>\n", info->ref_region); printf("<B>Genomic locus in query: </B>%s<BR>\n", info->query_region); printf("<B>Projection classification: </B>%s<BR>\n", info->status); printf("<B>Probability that query locus is orthologous: </B>%s<BR>\n", info->chain_score); // list of chain features (for orthology classification) printf("<a data-toggle=\"collapse\" href=\"#collapseChain\">Show features used for ortholog probability</a>\n"); printf("<div id=\"collapseChain\" class=\"panel-collapse collapse\">\n"); printf("<ul>\n"); printf("<li>Synteny (log10 value): %s</li>\n", info->chain_synteny); printf("<li>Global CDS fraction: %s</li>\n", info->chain_gl_cds_fract); printf("<li>Local CDS fraction: %s</li>\n", info->chain_loc_cds_fract); printf("<li>Local intron fraction: %s</li>\n", info->chain_intron_cov); printf("<li>Local CDS coverage: %s</li>\n", info->chain_exon_cov); printf("<li>Flank fraction: %s</li>\n", info->chain_flank); printf("</ul>\n"); printf("<br>\n<b>Feature description:</b>\n"); printf("For each projection (one reference transcript and one overlapping chain),\n"); printf("TOGA computes the following features by intersecting the reference coordinates of aligning\n"); printf("blocks in the chain with different gene parts (coding exons, UTR (untranslated region) exons, introns)\n"); printf("and the respective intergenic regions.\n<br>\n"); printf("We define the following variables:\n<ul>\n"); printf("<li>c: number of reference bases in the intersection between chain blocks and coding exons of the gene under consideration.</li>\n"); printf("<li>C: number of reference bases in the intersection between chain blocks and coding exons of all genes. </li>\n"); printf("<li>a: number of reference bases in the intersection between chain blocks and coding exons and introns of the gene under consideration. </li>\n"); printf("<li>A: number of reference bases in the intersection between chain blocks and coding exons and introns of all genes and the intersection\n"); printf("between chain blocks and intergenic regions (excludes UTRs). </li>\n"); printf("<li>f: number of reference bases in chain blocks overlapping the 10 kb flanks of the gene under consideration.\n"); printf("Alignment blocks overlapping exons of another gene that is located in these 10 kb flanks are ignored. </li>\n"); printf("<li>i: number of reference bases in the intersection between chain blocks and introns of the gene under consideration. </li>\n"); printf("<li>CDS (coding sequence): length of the coding region of the gene under consideration. </li>\n"); printf("<li>I: sum of all intron lengths of the gene under consideration. </li>\n"); printf("</ul>\n"); printf("Using these variables, TOGA computes the following features:\n"); printf("<ul>\n"); - printf("<li>“global CDS fraction” as C / A. Chains with a high value have alignments that largely overlap coding exons,"); + printf("<li>"global CDS fraction" as C / A. Chains with a high value have alignments that largely overlap coding exons,"); printf("which is a hallmark of paralogous or processed pseudogene chains. In contrast, chains with a low value also align many "); printf("intronic and intergenic regions, which is a hallmark of orthologous chains. </li>\n"); - printf("<li>“local CDS fraction” as c / a. Orthologous chains tend to have a lower value, as intronic "); + printf("<li>"local CDS fraction" as c / a. Orthologous chains tend to have a lower value, as intronic "); printf("regions partially align. This feature is not computed for single-exon genes. </li>\n"); - printf("<li>“local intron fraction” as i / I. Orthologous chains tend to have a higher value."); + printf("<li>"local intron fraction" as i / I. Orthologous chains tend to have a higher value."); printf("This feature is not computed for single-exon genes. </li>\n"); - printf("<li>“flank fraction” as f / 20,000. Orthologous chains tend to have higher values,"); + printf("<li>"flank fraction" as f / 20,000. Orthologous chains tend to have higher values,"); printf("as flanking intergenic regions partially align. This feature is important to detect orthologous loci of single-exon genes. </li>\n"); - printf("<li>“synteny” as log10 of the number of genes, whose coding exons overlap by at least one base aligning"); + printf("<li>"synteny" as log10 of the number of genes, whose coding exons overlap by at least one base aligning"); printf("blocks of this chain. Orthologous chains tend to cover several genes located in a conserved order, resulting in higher synteny values. </li>\n"); - printf("<li>“local CDS coverage” as c / CDS, which is only used for single-exon genes. </li>\n"); + printf("<li>"local CDS coverage" as c / CDS, which is only used for single-exon genes. </li>\n"); printf("</ul>\n"); printf("</ul>\n</div>\n<BR>\n"); htmlHorizontalLine(); // show inact mut plot printf("<h4>Visualization of inactivating mutations on exon-intron structure</h4>\n"); printf("%s<BR>\n", info->svg_line); printf("<BR>Exons shown in grey are missing (often overlap assembly gaps).\nExons shown in"); printf(" red or blue are deleted or do not align at all.\nRed indicates that the exon deletion "); printf("shifts the reading frame, while blue indicates that exon deletion(s) are framepreserving.<br>\n"); // GLP features printf("<a data-toggle=\"collapse\" href=\"#collapseGLP\">Show features used for transcript classification</a>\n"); printf("<div id=\"collapseGLP\" class=\"panel-collapse collapse\">\n"); printf("<ul>\n"); printf("<li>Percent intact, ignoring missing sequence: %s</li>\n", info->perc_intact_ign_M); printf("<li>Percent intact, treating missing as intact sequence: %s</li>\n", info->perc_intact_int_M); printf("<li>Proportion of intact codons: %s</li>\n", info->intact_codon_prop); printf("<li>Percent of CDS not covered by this chain (0 unless the chain covers only a part of the gene): %s</li>\n", info->ouf_prop); if (sameWord(info->mid_intact, ONE_)) { printf("<li>Middle 80 percent of CDS intact: %s</li>\n", YES_); } else { printf("<li>Middle 80 percent of CDS intact: %s</li>\n", NO_); } if (sameWord(info->mid_pres, ONE_)) { printf("<li>Middle 80 percent of CDS present: %s</li>\n", YES_); } else { printf("<li>Middle 80 percent of CDS present: %s</li>\n", NO_); } printf("</ul>\n</div>\n<BR>\n"); printf("<HR ALIGN=\"CENTER\"><h4>Query protein sequence</h4><BR>"); printf("<a data-toggle=\"collapse\" href=\"#collapseProt\">Show protein sequence of query</a>\n"); printf("<div id=\"collapseProt\" class=\"panel-collapse collapse\">\n"); printf("<TT>{protein seq of the query without dashes or other things. Should end with *}\n"); printf("<BR>\n</TT>\n</div>\n"); // and show protein sequence htmlHorizontalLine(); printf("<h4>Protein sequence alignment</h4><BR>\n"); printf("<a data-toggle=\"collapse\" href=\"#collapseProtAli\">Show alignment between reference and query</a>\n"); printf("<div id=\"collapseProtAli\" class=\"panel-collapse collapse\">\n"); printf("<TT>%s</TT><BR>\n", info->prot_alignment); printf("</div>\n<BR><BR>\n"); // do not forget to free toga data struct togaDataFree(&info); } else { // no data found, need to report this printf("Not found data for %s\n", item); } sqlFreeResult(&sr); } // show inactivating mutations if required printf("<h4>List of inactivating mutations</h4><BR>\n"); if (hTableExists(database, togaInactMutTableName)) { char query[256]; struct sqlResult *sr = NULL; char **row; sqlSafef(query, sizeof(query), "select * from %s where transcript='%s'", togaInactMutTableName, item); sr = sqlGetResult(conn, query); printf("<a data-toggle=\"collapse\" href=\"#collapseMuts\">Show inactivating mutations</a>\n"); printf("<div id=\"collapseMuts\" class=\"panel-collapse collapse\">\n"); printf("<table border = \"1\" width = \"640\">\n"); // init table printf("<tr><th>Exon number</th><th>Codon number</th><th>Mutation class</th><th>Mutation</th><th>Treated as inactivating</th><th>Mutation ID</th>\n"); printf("</tr>\n"); while ((row = sqlNextRow(sr)) != NULL) { struct togaInactMut *info = NULL; info = togaInactMutLoad(row); printf("<tr>\n"); printf("<td>%s</td>\n", info->exon_num); printf("<td>%s</td>\n", info->position); printf("<td>%s</td>\n", info->mut_class); printf("<td>%s</td>\n", info->mutation); if (sameWord(info->is_inact, ONE_)){ printf("<td>%s</td>\n", YES_); } else { printf("<td>%s</td>\n", NO_); } printf("<td>%s</td>\n", info->mut_id); printf("</tr>\n"); togaInactMutFree(&info); } sqlFreeResult(&sr); printf("</table>\n"); printf("</div>\n<BR>\n"); } else { printf("<B>Sorry, cannot find TOGAInactMut table.</B><BR>\n"); } // show exons data htmlHorizontalLine(); printf("<h4>Exon alignments</h4><BR>\n"); if (hTableExists(database, togaNuclTableName)) { char query[256]; struct sqlResult *sr = NULL; char **row; printf("<a data-toggle=\"collapse\" href=\"#collapseExons\">Show exon sequences and features</a>\n"); printf("<div id=\"collapseExons\" class=\"panel-collapse collapse\">\n"); sqlSafef(query, sizeof(query), "select * from %s where transcript='%s'", togaNuclTableName, item); sr = sqlGetResult(conn, query); while ((row = sqlNextRow(sr)) != NULL) { struct togaNucl *info = NULL; info = togaNuclLoad(row); printf("<h5>Exon number: %s</h5><BR>\n", info->exon_num); printf("<B>Exon region:</B> %s<BR>\n", info->exon_region); printf("<B>Nucleotide percent identity:</B> %s | <B>BLOSUM:</B> %s <BR>\n", info->pid, info->blosum); if (sameWord(info->gaps, ONE_)){ printf("<B>Intersects assembly gaps:</B> %s<BR>\n", YES_); } else { printf("<B>Intersects assembly gaps:</B> %s<BR>\n", NO_); } printf("<B>Exon alignment class:</B> %s<BR>\n", info->ali_class); if (sameWord(info->in_exp_region, ONE_)){ printf("<B>Detected within expected region (%s):</B> %s<BR>\n", info->exp_region, YES_); } else { printf("<B>Detected within expected region (%s):</B> %s<BR>\n", info->exp_region, NO_); } // printf("<B>Expected region:</B> %s<BR>\n", info->exp_region); printf("<BR>\n"); printf("<B>Sequence alignment between reference and query exon:</B><BR>\n"); printf("%s<BR>\n", info->alignment); togaNuclFree(&info); } sqlFreeResult(&sr); printf("</div>\n<BR><BR>\n"); } else { printf("<B>Sorry, cannot find TOGANucl table.</B><BR>\n"); } htmlHorizontalLine(); // TODO: check whether I need this printf("%s", hgTracksPathAndSettings()); hPrintf("<link rel=\"stylesheet\" href=\"https://maxcdn.bootstrapcdn.com/bootstrap/3.4.1/css/bootstrap.min.css\">"); hPrintf("<script src=\"https://ajax.googleapis.com/ajax/libs/jquery/3.5.1/jquery.min.js\"></script>"); hPrintf("<script src=\"https://maxcdn.bootstrapcdn.com/bootstrap/3.4.1/js/bootstrap.min.js\"></script>"); printTrackHtml(tdb); // and do I need this? hFreeConn(&conn); }