Exemplo n.º 1
0
    def genome_domain(self, identity_dir, prefix):
        """Determine domain of User genomes based on identified marker genes."""
        bac_count = defaultdict(int)
        ar_count = defaultdict(int)

        # Load the marker files for each domain
        ar122_marker_file = CopyNumberFileAR122(identity_dir, prefix)
        ar122_marker_file.read()
        bac120_marker_file = CopyNumberFileBAC120(identity_dir, prefix)
        bac120_marker_file.read()

        # Get the number of single copy markers for each domain
        for out_d, marker_summary in ((ar_count, ar122_marker_file),
                                      (bac_count, bac120_marker_file)):
            for genome_id in marker_summary.genomes:
                out_d[genome_id] = len(
                    marker_summary.get_single_copy_hits(genome_id))

        bac_gids = set()
        ar_gids = set()
        bac_ar_diff = {}
        for gid in bac_count:
            arc_aa_per = (ar_count[gid] * 100.0 / Config.AR_MARKER_COUNT)
            bac_aa_per = (bac_count[gid] * 100.0 / Config.BAC_MARKER_COUNT)
            if bac_aa_per >= arc_aa_per:
                bac_gids.add(gid)
            else:
                ar_gids.add(gid)
            if abs(bac_aa_per - arc_aa_per) <= 10:
                bac_ar_diff[gid] = {
                    'bac120': round(bac_aa_per, 1),
                    'ar122': round(arc_aa_per, 1)
                }

        return bac_gids, ar_gids, bac_ar_diff
Exemplo n.º 2
0
    def _report_identified_marker_genes(self, gene_dict, outdir, prefix):
        """Report statistics for identified marker genes."""

        # Summarise the copy number of each AR122 and BAC120 markers.
        tln_summary_file = TlnTableSummaryFile(outdir, prefix)
        ar122_copy_number_file = CopyNumberFileAR122(outdir, prefix)
        bac120_copy_number_file = CopyNumberFileBAC120(outdir, prefix)

        # Process each genome.
        for db_genome_id, info in sorted(gene_dict.items()):
            cur_marker_dir = os.path.join(outdir, DIR_MARKER_GENE)
            pfam_tophit_file = TopHitPfamFile(cur_marker_dir, db_genome_id)
            tigr_tophit_file = TopHitTigrFile(cur_marker_dir, db_genome_id)
            pfam_tophit_file.read()
            tigr_tophit_file.read()

            # Summarise each of the markers for this genome.
            ar122_copy_number_file.add_genome(db_genome_id,
                                              info.get("aa_gene_path"),
                                              pfam_tophit_file,
                                              tigr_tophit_file)
            bac120_copy_number_file.add_genome(db_genome_id,
                                               info.get("aa_gene_path"),
                                               pfam_tophit_file,
                                               tigr_tophit_file)

            # Write the best translation table to disk for this genome.
            tln_summary_file.add_genome(db_genome_id,
                                        info.get("best_translation_table"))

        # Write each of the summary files to disk.
        ar122_copy_number_file.write()
        bac120_copy_number_file.write()
        tln_summary_file.write()

        # Create a symlink to store the summary files in the root.
        symlink_f(
            PATH_BAC120_MARKER_SUMMARY.format(prefix=prefix),
            os.path.join(
                outdir,
                os.path.basename(
                    PATH_BAC120_MARKER_SUMMARY.format(prefix=prefix))))
        symlink_f(
            PATH_AR122_MARKER_SUMMARY.format(prefix=prefix),
            os.path.join(
                outdir,
                os.path.basename(
                    PATH_AR122_MARKER_SUMMARY.format(prefix=prefix))))
        symlink_f(
            PATH_TLN_TABLE_SUMMARY.format(prefix=prefix),
            os.path.join(
                outdir,
                os.path.basename(
                    PATH_TLN_TABLE_SUMMARY.format(prefix=prefix))))
Exemplo n.º 3
0
    def _run_multi_align(self, db_genome_id, path, marker_set_id):
        """
        Returns the concatenated marker sequence for a specific genome
        :param db_genome_id: Selected genome
        :param path: Path to the genomic fasta file for the genome
        :param marker_set_id: Unique ID of marker set to use for alignment
        """

        cur_marker_dir = os.path.dirname(os.path.dirname(path))
        pfam_tophit_file = TopHitPfamFile(cur_marker_dir, db_genome_id)
        tigr_tophit_file = TopHitTigrFile(cur_marker_dir, db_genome_id)
        pfam_tophit_file.read()
        tigr_tophit_file.read()

        if marker_set_id == 'bac120':
            copy_number_file = CopyNumberFileBAC120('/dev/null', None)
        elif marker_set_id == 'ar122':
            copy_number_file = CopyNumberFileAR122('/dev/null', None)
        else:
            raise GTDBTkException('Unknown marker set.')

        copy_number_file.add_genome(db_genome_id, path, pfam_tophit_file,
                                    tigr_tophit_file)
        single_copy_hits = copy_number_file.get_single_copy_hits(db_genome_id)

        # gather information for all marker genes
        marker_paths = {
            "PFAM":
            os.path.join(self.pfam_hmm_dir, 'individual_hmms'),
            "TIGRFAM":
            os.path.join(os.path.dirname(self.tigrfam_hmm_dir),
                         'individual_hmms')
        }

        marker_dict_original = {}
        if marker_set_id == "bac120":
            for db_marker in sorted(self.bac120_markers):
                marker_dict_original.update({
                    marker.replace(".HMM", "").replace(".hmm", ""):
                    os.path.join(marker_paths[db_marker], marker)
                    for marker in self.bac120_markers[db_marker]
                })
        elif marker_set_id == "ar122":
            for db_marker in sorted(self.ar122_markers):
                marker_dict_original.update({
                    marker.replace(".HMM", "").replace(".hmm", ""):
                    os.path.join(marker_paths[db_marker], marker)
                    for marker in self.ar122_markers[db_marker]
                })
        elif marker_set_id == "rps23":
            for db_marker in sorted(self.rps23_markers):
                marker_dict_original.update({
                    marker.replace(".HMM", "").replace(".hmm", ""):
                    os.path.join(marker_paths[db_marker], marker)
                    for marker in self.rps23_markers[db_marker]
                })

        # Iterate over each of the expected markers and store the gene sequence.
        gene_dict = dict()
        result_align = dict()
        for marker_id, marker_path in marker_dict_original.items():
            hit = single_copy_hits.get(marker_id)
            if hit:
                # print(marker_id)
                gene_dict[marker_id] = {
                    "marker_path": marker_path,
                    "gene": hit['hit'].gene_id,
                    "gene_seq": hit['seq'],
                    "bitscore": hit['hit'].bit_score
                }
            else:
                hmm_len = self._get_hmm_size(marker_path)
                result_align[marker_id] = '-' * hmm_len

        # Align the markers.
        result_align.update(self._run_align(gene_dict, db_genome_id))

        # we concatenate the aligned markers together and associate them with
        # the genome.
        return ''.join([x[1] for x in sorted(result_align.items())])
Exemplo n.º 4
0
 def setUp(self):
     self.dir_tmp = tempfile.mkdtemp(prefix='gtdbtk_tmp_')
     self.cn = CopyNumberFileAR122(self.dir_tmp, 'tst')
Exemplo n.º 5
0
    def _report_identified_marker_genes(self, gene_dict, outdir, prefix,
                                        write_single_copy_genes):
        """Report statistics for identified marker genes."""

        # Summarise the copy number of each AR122 and BAC120 markers.
        tln_summary_file = TlnTableSummaryFile(outdir, prefix)
        ar122_copy_number_file = CopyNumberFileAR122(outdir, prefix)
        bac120_copy_number_file = CopyNumberFileBAC120(outdir, prefix)

        # Process each genome.
        for db_genome_id, info in tqdm_log(sorted(gene_dict.items()),
                                           unit='genome'):
            cur_marker_dir = os.path.join(outdir, DIR_MARKER_GENE)
            pfam_tophit_file = TopHitPfamFile(cur_marker_dir, db_genome_id)
            tigr_tophit_file = TopHitTigrFile(cur_marker_dir, db_genome_id)
            pfam_tophit_file.read()
            tigr_tophit_file.read()

            # Summarise each of the markers for this genome.
            ar122_copy_number_file.add_genome(db_genome_id,
                                              info.get("aa_gene_path"),
                                              pfam_tophit_file,
                                              tigr_tophit_file)
            bac120_copy_number_file.add_genome(db_genome_id,
                                               info.get("aa_gene_path"),
                                               pfam_tophit_file,
                                               tigr_tophit_file)

            # Write the best translation table to disk for this genome.
            tln_summary_file.add_genome(db_genome_id,
                                        info.get("best_translation_table"))

        # Write each of the summary files to disk.
        ar122_copy_number_file.write()
        bac120_copy_number_file.write()
        tln_summary_file.write()

        # Create a symlink to store the summary files in the root.
        symlink_f(
            PATH_BAC120_MARKER_SUMMARY.format(prefix=prefix),
            os.path.join(
                outdir,
                os.path.basename(
                    PATH_BAC120_MARKER_SUMMARY.format(prefix=prefix))))
        symlink_f(
            PATH_AR122_MARKER_SUMMARY.format(prefix=prefix),
            os.path.join(
                outdir,
                os.path.basename(
                    PATH_AR122_MARKER_SUMMARY.format(prefix=prefix))))
        symlink_f(
            PATH_TLN_TABLE_SUMMARY.format(prefix=prefix),
            os.path.join(
                outdir,
                os.path.basename(
                    PATH_TLN_TABLE_SUMMARY.format(prefix=prefix))))

        # Write the single copy AR122/BAC120 FASTA files to disk.
        if write_single_copy_genes:
            fasta_dir = os.path.join(outdir, DIR_IDENTIFY_FASTA)
            self.logger.info(
                f'Writing unaligned single-copy genes to: {fasta_dir}')

            # Iterate over each domain.
            marker_doms = list()
            marker_doms.append((Config.AR122_MARKERS['PFAM'] +
                                Config.AR122_MARKERS['TIGRFAM'],
                                ar122_copy_number_file, 'ar122'))
            marker_doms.append((Config.BAC120_MARKERS['PFAM'] +
                                Config.BAC120_MARKERS['TIGRFAM'],
                                bac120_copy_number_file, 'bac120'))
            for marker_names, marker_file, marker_d in marker_doms:

                # Create the domain-specific subdirectory.
                fasta_d_dir = os.path.join(fasta_dir, marker_d)
                make_sure_path_exists(fasta_d_dir)

                # Iterate over each marker.
                for marker_name in marker_names:
                    marker_name = marker_name.rstrip(r'\.[HMMhmm]')
                    marker_path = os.path.join(fasta_d_dir,
                                               f'{marker_name}.fa')

                    to_write = list()
                    for genome_id in sorted(gene_dict):
                        unq_hits = marker_file.get_single_copy_hits(genome_id)
                        if marker_name in unq_hits:
                            to_write.append(f'>{genome_id}')
                            to_write.append(unq_hits[marker_name]['seq'])

                    if len(to_write) > 0:
                        with open(marker_path, 'w') as fh:
                            fh.write('\n'.join(to_write))
Exemplo n.º 6
0
    def align(self,
              identify_dir,
              skip_gtdb_refs,
              taxa_filter,
              min_perc_aa,
              custom_msa_filters,
              skip_trimming,
              rnd_seed,
              cols_per_gene,
              min_consensus,
              max_consensus,
              min_per_taxa,
              out_dir,
              prefix,
              outgroup_taxon,
              genomes_to_process=None):
        """Align marker genes in genomes."""

        # If the user is re-running this step, check if the identify step is consistent.
        genomic_files = self._path_to_identify_data(identify_dir,
                                                    identify_dir != out_dir)
        if genomes_to_process is not None and len(genomic_files) != len(
                genomes_to_process):
            self.logger.error(
                '{} are not present in the input list of genome to process.'.
                format(
                    list(
                        set(genomic_files.keys()) -
                        set(genomes_to_process.keys()))))
            raise InconsistentGenomeBatch(
                'You are attempting to run GTDB-Tk on a non-empty directory that contains extra '
                'genomes not present in your initial identify directory. Remove them, or run '
                'GTDB-Tk on a new directory.')

        # If this is being run as a part of classify_wf, copy the required files.
        if identify_dir != out_dir:
            identify_path = os.path.join(out_dir, DIR_IDENTIFY)
            make_sure_path_exists(identify_path)
            copy(
                CopyNumberFileBAC120(identify_dir, prefix).path, identify_path)
            copy(CopyNumberFileAR122(identify_dir, prefix).path, identify_path)
            copy(TlnTableSummaryFile(identify_dir, prefix).path, identify_path)

        # Create the align intermediate directory.
        make_sure_path_exists(os.path.join(out_dir, DIR_ALIGN_INTERMEDIATE))

        # Write out files with marker information
        ar122_marker_info_file = MarkerInfoFileAR122(out_dir, prefix)
        ar122_marker_info_file.write()
        bac120_marker_info_file = MarkerInfoFileBAC120(out_dir, prefix)
        bac120_marker_info_file.write()

        # Determine what domain each genome belongs to.
        bac_gids, ar_gids, _bac_ar_diff = self.genome_domain(
            identify_dir, prefix)

        # # Create a temporary directory that will be used to generate each of the alignments.
        # with tempfile.TemporaryDirectory(prefix='gtdbtk_tmp_') as dir_tmp_arc, \
        #         tempfile.TemporaryDirectory(prefix='gtdbtk_tmp_') as dir_tmp_bac:
        #
        #     cur_gid_dict = {x: genomic_files[x] for x in ar_gids}
        #     self.logger.info(f'Collecting marker sequences from {len(cur_gid_dict):,} '
        #                      f'genomes identified as archaeal.')
        #     align.concat_single_copy_hits(dir_tmp_arc,
        #                                   cur_gid_dict,
        #                                   ar122_marker_info_file)
        #

        self.logger.info(
            f'Aligning markers in {len(genomic_files):,} genomes with {self.cpus} CPUs.'
        )
        dom_iter = ((bac_gids, Config.CONCAT_BAC120, Config.MASK_BAC120,
                     "bac120", 'bacterial', CopyNumberFileBAC120),
                    (ar_gids, Config.CONCAT_AR122, Config.MASK_AR122, "ar122",
                     'archaeal', CopyNumberFileAR122))
        gtdb_taxonomy = Taxonomy().read(self.taxonomy_file)
        for gids, msa_file, mask_file, marker_set_id, domain_str, copy_number_f in dom_iter:

            # No genomes identified as this domain.
            if len(gids) == 0:
                continue

            self.logger.info(
                f'Processing {len(gids):,} genomes identified as {domain_str}.'
            )
            if marker_set_id == 'bac120':
                marker_info_file = bac120_marker_info_file
                marker_filtered_genomes = os.path.join(
                    out_dir,
                    PATH_BAC120_FILTERED_GENOMES.format(prefix=prefix))
                marker_msa_path = os.path.join(
                    out_dir, PATH_BAC120_MSA.format(prefix=prefix))
                marker_user_msa_path = os.path.join(
                    out_dir, PATH_BAC120_USER_MSA.format(prefix=prefix))
            else:
                marker_info_file = ar122_marker_info_file
                marker_filtered_genomes = os.path.join(
                    out_dir, PATH_AR122_FILTERED_GENOMES.format(prefix=prefix))
                marker_msa_path = os.path.join(
                    out_dir, PATH_AR122_MSA.format(prefix=prefix))
                marker_user_msa_path = os.path.join(
                    out_dir, PATH_AR122_USER_MSA.format(prefix=prefix))

            cur_genome_files = {
                gid: f
                for gid, f in genomic_files.items() if gid in gids
            }

            if skip_gtdb_refs:
                gtdb_msa = {}
            else:
                gtdb_msa = self._msa_filter_by_taxa(msa_file, gtdb_taxonomy,
                                                    taxa_filter,
                                                    outgroup_taxon)
            gtdb_msa_mask = os.path.join(Config.MASK_DIR, mask_file)

            # Generate the user MSA.
            user_msa = align.align_marker_set(cur_genome_files,
                                              marker_info_file, copy_number_f,
                                              self.cpus)

            # self.logger.log(Config.LOG_TASK, f'Aligning {len(cur_genome_files):,} {domain_str} genomes.')
            # hmm_aligner = HmmAligner(self.cpus,
            #                          self.pfam_top_hit_suffix,
            #                          self.tigrfam_top_hit_suffix,
            #                          self.protein_file_suffix,
            #                          self.pfam_hmm_dir,
            #                          self.tigrfam_hmms,
            #                          Config.BAC120_MARKERS,
            #                          Config.AR122_MARKERS)
            # user_msa = hmm_aligner.align_marker_set(cur_genome_files,
            #                                         marker_set_id)

            # Write the individual marker alignments to disk
            if self.debug:
                self._write_individual_markers(user_msa, marker_set_id,
                                               marker_info_file.path, out_dir,
                                               prefix)

            # filter columns without sufficient representation across taxa
            if skip_trimming:
                self.logger.info(
                    'Skipping custom filtering and selection of columns.')
                pruned_seqs = {}
                trimmed_seqs = merge_two_dicts(gtdb_msa, user_msa)

            elif custom_msa_filters:
                aligned_genomes = merge_two_dicts(gtdb_msa, user_msa)
                self.logger.info(
                    'Performing custom filtering and selection of columns.')

                trim_msa = TrimMSA(
                    cols_per_gene, min_perc_aa / 100.0, min_consensus / 100.0,
                    max_consensus / 100.0, min_per_taxa / 100.0, rnd_seed,
                    os.path.join(out_dir, f'filter_{marker_set_id}'))

                trimmed_seqs, pruned_seqs = trim_msa.trim(
                    aligned_genomes, marker_info_file.path)

                if trimmed_seqs:
                    self.logger.info(
                        'Filtered MSA from {:,} to {:,} AAs.'.format(
                            len(list(aligned_genomes.values())[0]),
                            len(list(trimmed_seqs.values())[0])))

                self.logger.info(
                    'Filtered {:,} genomes with amino acids in <{:.1f}% of columns in filtered MSA.'
                    .format(len(pruned_seqs), min_perc_aa))

                filtered_user_genomes = set(pruned_seqs).intersection(user_msa)
                if len(filtered_user_genomes):
                    self.logger.info(
                        'Filtered genomes include {:.} user submitted genomes.'
                        .format(len(filtered_user_genomes)))
            else:
                self.logger.log(
                    Config.LOG_TASK,
                    f'Masking columns of {domain_str} multiple sequence alignment using canonical mask.'
                )
                trimmed_seqs, pruned_seqs = self._apply_mask(
                    gtdb_msa, user_msa, gtdb_msa_mask, min_perc_aa / 100.0)
                self.logger.info(
                    'Masked {} alignment from {:,} to {:,} AAs.'.format(
                        domain_str, len(list(user_msa.values())[0]),
                        len(list(trimmed_seqs.values())[0])))

                if min_perc_aa > 0:
                    self.logger.info(
                        '{:,} {} user genomes have amino acids in <{:.1f}% of columns in filtered MSA.'
                        .format(len(pruned_seqs), domain_str, min_perc_aa))

            # write out filtering information
            with open(marker_filtered_genomes, 'w') as fout:
                for pruned_seq_id, pruned_seq in pruned_seqs.items():
                    if len(pruned_seq) == 0:
                        perc_alignment = 0
                    else:
                        valid_bases = sum(
                            [1 for c in pruned_seq if c.isalpha()])
                        perc_alignment = valid_bases * 100.0 / len(pruned_seq)
                    fout.write(
                        f'{pruned_seq_id}\tInsufficient number of amino acids in MSA ({perc_alignment:.1f}%)\n'
                    )

            # write out MSAs
            if not skip_gtdb_refs:
                self.logger.info(
                    f'Creating concatenated alignment for {len(trimmed_seqs):,} '
                    f'{domain_str} GTDB and user genomes.')
                self._write_msa(trimmed_seqs, marker_msa_path, gtdb_taxonomy)

            trimmed_user_msa = {
                k: v
                for k, v in trimmed_seqs.items() if k in user_msa
            }
            if len(trimmed_user_msa) > 0:
                self.logger.info(
                    f'Creating concatenated alignment for {len(trimmed_user_msa):,} '
                    f'{domain_str} user genomes.')
                self._write_msa(trimmed_user_msa, marker_user_msa_path,
                                gtdb_taxonomy)
            else:
                self.logger.info(
                    f'All {domain_str} user genomes have been filtered out.')

            # Create symlinks to the summary files
            if marker_set_id == 'bac120':
                symlink_f(
                    PATH_BAC120_FILTERED_GENOMES.format(prefix=prefix),
                    os.path.join(
                        out_dir,
                        os.path.basename(
                            PATH_BAC120_FILTERED_GENOMES.format(
                                prefix=prefix))))
                if len(trimmed_user_msa) > 0:
                    symlink_f(
                        PATH_BAC120_USER_MSA.format(prefix=prefix),
                        os.path.join(
                            out_dir,
                            os.path.basename(
                                PATH_BAC120_USER_MSA.format(prefix=prefix))))
                if not skip_gtdb_refs:
                    symlink_f(
                        PATH_BAC120_MSA.format(prefix=prefix),
                        os.path.join(
                            out_dir,
                            os.path.basename(
                                PATH_BAC120_MSA.format(prefix=prefix))))
            elif marker_set_id == 'ar122':
                symlink_f(
                    PATH_AR122_FILTERED_GENOMES.format(prefix=prefix),
                    os.path.join(
                        out_dir,
                        os.path.basename(
                            PATH_AR122_FILTERED_GENOMES.format(
                                prefix=prefix))))
                if len(trimmed_user_msa) > 0:
                    symlink_f(
                        PATH_AR122_USER_MSA.format(prefix=prefix),
                        os.path.join(
                            out_dir,
                            os.path.basename(
                                PATH_AR122_USER_MSA.format(prefix=prefix))))
                if not skip_gtdb_refs:
                    symlink_f(
                        PATH_AR122_MSA.format(prefix=prefix),
                        os.path.join(
                            out_dir,
                            os.path.basename(
                                PATH_AR122_MSA.format(prefix=prefix))))
            else:
                raise GenomeMarkerSetUnknown(
                    'There was an error determining the marker set.')