insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(1, 'allele', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(2, 'anticodon', '(pos:<base_range>,aa:<amino_acid>) where <base_range> is the position of the anticodon and <amino_acid> is the abbreviation for the amino acid encoded', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(3, 'artificial_location', 'One of: heterogeneous population sequenced; low-quality sequence region;', null);
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(4, 'bound_moiety', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(5, 'cell_line', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(6, 'cell_type', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(7, 'chromosome', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(8, 'clone', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(9, 'clone_lib', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(10, 'codon_start', '1 or 2 or 3', null);
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(11, 'collected_by', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(12, 'collection_date', 'DD-Mmm-YYYY, Mmm-YYYY or YYYY', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(13, 'compare', '[accession-number.sequence-version]', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(14, 'country', '<country_value> - where <country_value> is any value from the controlled vocabulary', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(15, 'cultivar', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(16, 'dev_stage', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(17, 'direction', 'left, right, or both - where left indicates toward the 5'' end of the entry sequence (as presented) and right indicates toward the 3''end', null);
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(18, 'EC_number', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(19, 'ecotype', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(20, 'environmental_sample', 'none', '^.{0}$');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(21, 'exception', 'One of the following controlled vocabulary phrases: RNA editing; reasons given in citation; rearrangement required for product;', null);
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(22, 'focus', 'none', null);
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(23, 'frequency', 'free text representing the proportion of a population carrying the feature expressed as a fraction', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(24, 'function', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(25, 'gene', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(26, 'gene_synonym', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(27, 'germline', 'none', '^.{0}$');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(28, 'haplogroup', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(29, 'haplotype', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(30, 'host', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(31, 'identified_by', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(32, 'isolate', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(33, 'isolation_source', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(34, 'lab_host', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(35, 'lat_lon', 'free text - degrees latitude and longitude in format \"d[d.dddd] N|S d[dd.dddd] W|E\"', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(36, 'macronuclear', 'if the sequence shown is DNA and from an organism which undergoes chromosomal differentiation between macronuclear and micronuclear stages, this qualifier is used to denote that the sequence is from macronuclear DNA', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(37, 'map', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(38, 'mating_type', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(39, 'mobile_element_type', '<mobile_element_type>[:<mobile_element_name>] - where <mobile_element_type> is one of the following: transposon; retrotransposon; integron; insertion sequence; non-LTR retrotransposon; SINE; MITE; LINE; other;', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(40, 'mod_base', 'modified base abbreviation', null);
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(41, 'mol_type', 'One chosen from the following: genomic DNA; genomic RNA; mRNA; tRNA; rRNA; other RNA; other DNA; transcribed RNA; viral cRNA; unassigned DNA; unassigned RNA;', null);
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(42, 'ncRNA_class', 'TYPE - where Type is one of the following controlled vocabulary terms or phrases: antisense_RNA; autocatalytically_spliced_intron; ribozyme; hammerhead_ribozyme; RNase_P_RNA; RNase_MRP_RNA; telomerase_RNA; guide_RNA; rasiRNA; scRNA; siRNA; miRNA; piRNA; snoRNA; snRNA; SRP_RNA; vault_RNA; Y_RNA; other;', null);
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(43, 'note', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(44, 'number', 'free text (with no whitespace characters)', '^\\S*$');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(45, 'operon', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(46, 'organelle', 'One of the following controlled vocabulary terms and phrases: chromatophore; hyrogenosome; mitochondrion; nucleomorph; plastid; mitochondrion:kinetoplast; plastid:chloroplast; plastid:apicoplast; plastid:chromoplast; plastid:cyanelle; plastid:leucoplast; plastid:proplastid', null);
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(47, 'organism', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(48, 'PCR_conditions', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(49, 'PCR_primers', '[fwd_name: XXX1, ]fwd_seq: xxxxx1,[fwd_name: XXX2, ]fwd_seq: xxxxx2, [rev_name: YYY1, ]rev_seq: yyyyy1,[rev_name: YYY2, ]rev_seq: yyyyy2', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(50, 'phenotype', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(51, 'plasmid', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(52, 'pop_variant', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(53, 'product', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(54, 'proviral', 'none', '^.{0}$');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(55, 'pseudo', 'none', '^.{0}$');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(56, 'rearranged', 'none', '^.{0}$');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(57, 'replace', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(58, 'ribosomal_slippage', 'none', '^.{0}$');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(59, 'rpt_family', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(60, 'rpt_type', 'One of the following controlled vocabulary terms: tandem; inverted; flanking; terminal; direct; dispersed; other', null);
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(61, 'rpt_unit_range', '<base_range> - where <base_range> is the first and last base (separated by two dots) of a repeating unit', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(62, 'rpt_unit_seq', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(63, 'satellite', '<satellite_type>[:<class>][ <identifier>] - where <satellite_type> is one of the following: satellite; microsatellite; minisatellite', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(64, 'segment', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(65, 'serotype', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(66, 'serovar', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(67, 'sex', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(68, 'standard_name', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(69, 'strain', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(70, 'sub_clone', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(71, 'sub_species', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(72, 'sub_strain', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(73, 'tag_peptide', '<base_range> - where <base_range> provides the first and last base (separated by two dots) of the location for the proteolysis tag', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(74, 'tissue_lib', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(75, 'tissue_type', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(76, 'transgenic', 'none', '^.{0}$');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(77, 'transl_except', '(pos:location,aa:<amino_acid>) where <amino_acid> is the amino acid coded by the codon at the base_range position', null);
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(78, 'transl_table', '<integer> where <integer> is the number assigned to the genetic code table', '^[0-9]*$');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(79, 'trans_splicing', 'none', '^.{0}$');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(80, 'translation', 'contiguous string of one-letter amino acid abbreviations from this Annex paragraph 3, \"X\" is to be used for AA exceptions', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(81, 'variety', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(82, 'MOL_TYPE', 'protein', '^protein$');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(83, 'NOTE', 'free text', '.');
insert into QUALIFIER_KEY(ID, KEY, VALUE_TYPE, VALUE_REGEXP) values(84, 'ORGANISM', 'free text', '.');

insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(3, 'heterogeneous population sequenced');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(3, 'low-quality sequence region');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(10, '1');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(10, '2');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(10, '3');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(17, 'LEFT');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(17, 'RIGHT');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(17, 'BOTH');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(21, 'RNA editing');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(21, 'reasons given in citation');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(21, 'rearrangement required for product');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(41, 'genomic DNA');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(41, 'genomic RNA');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(41, 'mRNA');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(41, 'tRNA');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(41, 'rRNA');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(41, 'other RNA');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(41, 'other DNA');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(41, 'transcribed RNA');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(41, 'viral cRNA');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(41, 'unassigned DNA');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(41, 'unassigned RNA');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(42, 'antisense_RNA');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(42, 'autocatalytically_spliced_intron');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(42, 'ribozyme');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(42, 'hammerhead_ribozyme');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(42, 'RNase_P_RNA');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(42, 'RNase_MRP_RNA');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(42, 'telomerase_RNA');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(42, 'guide_RNA');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(42, 'rasiRNA');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(42, 'scRNA');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(42, 'siRNA');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(42, 'miRNA');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(42, 'piRNA');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(42, 'snoRNA');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(42, 'snRNA');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(42, 'SRP_RNA');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(42, 'vault_RNA');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(42, 'Y_RNA');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(42, 'other');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(46, 'chromatophore');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(46, 'hyrogenosome');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(46, 'mitochondrion');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(46, 'nucleomorph');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(46, 'plastid');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(46, 'mitochondrion:kinetoplast');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(46, 'plastid:chloroplast');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(46, 'plastid:apicoplast');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(46, 'plastid:chromoplast');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(46, 'plastid:cyanelle');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(46, 'plastid:leucoplast');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(46, 'plastid:proplastid');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(60, 'tandem');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(60, 'inverted');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(60, 'flanking');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(60, 'terminal');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(60, 'direct');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(60, 'dispersed');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(60, 'other');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(78, '1');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(78, '2');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(78, '3');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(78, '4');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(78, '5');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(78, '6');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(78, '9');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(78, '10');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(78, '11');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(78, '12');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(78, '13');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(78, '14');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(78, '15');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(78, '16');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(78, '21');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(78, '22');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(78, '23');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(78, '24');
insert into QUALIFIER_VALUE(QUALIFIER_KEY_ID, VALUE) values(82, 'protein');

insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('a', 'i');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('a', 'i6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('a', 'm1a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('a', 'm2a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('a', 'm6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('a', 'ms2i6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('a', 'ms2t6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('a', 'mt6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('a', 't6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('a', 'OTHER');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('g', 'gal q');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('g', 'gm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('g', 'm1g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('g', 'm22g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('g', 'm2g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('g', 'm7g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('g', 'man q');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('g', 'osyw');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('g', 'q');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('g', 'yw');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('g', 'OTHER');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('c', 'ac4c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('c', 'cm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('c', 'm3c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('c', 'm5c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('c', 's2c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('c', 'OTHER');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('t', 'chm5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('t', 'cmnm5s2u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('t', 'cmnm5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('t', 'd');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('t', 'fm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('t', 'm1f');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('t', 'mam5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('t', 'mcm5s2u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('t', 'mcm5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('t', 'mo5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('t', 'mv');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('t', 'o5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('t', 'p');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('t', 's2t');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('t', 's2u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('t', 's4u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('t', 't');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('t', 'tm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('t', 'um');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('t', 'x');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('t', 'OTHER');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('r', 'i');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('r', 'm1i');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('r', 'i6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('r', 'm1a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('r', 'm2a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('r', 'm6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('r', 'ms2i6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('r', 'ms2t6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('r', 'mt6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('r', 't6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('r', 'gal q');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('r', 'gm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('r', 'm1g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('r', 'm22g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('r', 'm2g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('r', 'm7g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('r', 'man q');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('r', 'osyw');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('r', 'q');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('r', 'yw');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('r', 'OTHER');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('y', 'ac4c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('y', 'cm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('y', 'm3c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('y', 'm5c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('y', 's2');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('y', 'chm5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('y', 'cmnm5s2u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('y', 'cmnm5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('y', 'd');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('y', 'fm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('y', 'm1f');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('y', 'mam5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('y', 'mcm5s2u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('y', 'mcm5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('y', 'mo5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('y', 'mv');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('y', 'o5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('y', 'p');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('y', 's2t');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('y', 's2u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('y', 's4u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('y', 't');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('y', 'tm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('y', 'um');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('y', 'x');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('y', 'OTHER');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('m', 'i6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('m', 'm1a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('m', 'm2a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('m', 'm6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('m', 'ms2i6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('m', 'ms2t6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('m', 'mt6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('m', 't6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('m', 'ac4c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('m', 'cm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('m', 'm3c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('m', 'm5c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('m', 's2c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('m', 'OTHER');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'gal q');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'gm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'm1g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'm22g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'm2g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'm7g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'man q');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'osyw');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'q');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'yw');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'chm5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'cmnm5s2u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'cmnm5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'd');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'fm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'm1f');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'mam5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'mcm5s2u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'mcm5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'mo5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'mv');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'o5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'p');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 's2t');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 's2u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 's4u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 't');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'tm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'um');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'x');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('k', 'OTHER');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('s', 'gal q');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('s', 'gm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('s', 'm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('s', 'm22g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('s', 'm2g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('s', 'm7g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('s', 'man q');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('s', 'osyw');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('s', 'q');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('s', 'yw');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('s', 'ac4c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('s', 'cm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('s', 'm3c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('s', 'm5c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('s', 's2c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('s', 'OTHER');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 'i6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 'm1a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 'm2a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 'm6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 'ms2i6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 'ms2t6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 'mt6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 't6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 'chm5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 'cmnm5s2u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 'cmnm5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 'd');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 'fm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 'm1f');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 'mam5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 'mcm5s2u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 'mcm5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 'mo5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 'mv');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 'o5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 'p');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 's2t');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 's2u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 's4u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 't');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 'tm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 'um');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 'x');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('w', 'OTHER');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'gal q');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'gm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'm1g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'm22g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'm2g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'm7g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'man q');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'osyw');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'q');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'yw');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'ac4c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'cm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'm3c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'm5c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 's2c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'chm5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'cmnm5s2u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'cmnm5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'd');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'fm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'm1f');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'mam5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'mcm5s2u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'mcm5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'mo5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'mv');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'o5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'p');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 's2t');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 's2u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 's4u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 't');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'tm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'um');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'x');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('b', 'OTHER');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'i6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'm1a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'm2a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'm6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'ms2i6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'ms2t6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'mt6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 't6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'gal q');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'gm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'm1g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'm22g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'm2g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'm7g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'man q');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'osyw');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'q');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'yw');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'chm5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'cmnm5s2u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'cmnm5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'd');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'fm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'm1f');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'mam5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'mcm5s2u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'mcm5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'mo5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'mv');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'o5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'p');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 's2t');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 's2u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 's4u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 't');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'tm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'um');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'x');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('d', 'OTHER');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'i6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'm1a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'm2a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'm6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'ms2i6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'ms2t6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'mt6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 't6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'ac4c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'cm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'm3c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'm5c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 's2c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'chm5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'cmnm5s2u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'cmnm5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'd');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'fm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'm1f');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'mam5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'mcm5s2u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'mcm5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'mo5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'mv');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'o5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'p');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 's2t');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 's2u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 's4u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 't');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'tm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'um');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'x');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('h', 'OTHER');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('v', 'i6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('v', 'm1a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('v', 'm2a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('v', 'm6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('v', 'ms2i6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('v', 'ms2t6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('v', 'mt6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('v', 't6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('v', 'gal q');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('v', 'gm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('v', 'm1g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('v', 'm22g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('v', 'm2g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('v', 'm7g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('v', 'man q');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('v', 'osyw');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('v', 'q');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('v', 'yw');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('v', 'ac4c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('v', 'cm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('v', 'm3c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('v', 'm5c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('v', 's2c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('v', 'OTHER');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'i6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'm1a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'm2a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'm6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'ms2i6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'ms2t6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'mt6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 't6a');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'gal q');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'gm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'm1g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'm22g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'm2g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'm7g');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'man q');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'osyw');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'q');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'yw');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'ac4c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'cm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'm3c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'm5c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 's2c');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'chm5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'cmnm5s2u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'cmnm5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'd');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'fm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'm1f');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'mam5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'mcm5s2u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'mcm5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'mo5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'mv');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'o5u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'p');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 's2t');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 's2u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 's4u');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 't');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'tm');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'um');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'x');
insert into MOD_BASE(NUCLEOTIDE, MOD_BASE_ALLOWED) values('n', 'OTHER');