backtranseq |
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Function
Back-translate a protein sequence to a nucleotide sequenceDescription
backtranseq reads a protein sequence and writes the nucleic acid sequence it is most likely to have come from.
Algorithm
backtranseq uses a codon usage table which gives the frequency of usage of each codon for each amino acid. For each amino acid in the input sequence, the corresponding most frequently occuring codon is used in the nucleic acid sequence that is output.
Usage
Here is a sample session with backtranseqNote that this is a human protein and so the default human codon frequency file is used ie. is not specified
% backtranseq Back-translate a protein sequence to a nucleotide sequence Input (gapped) protein sequence(s): tsw:opsd_human (gapped) nucleotide output sequence(s) [opsd_human.fasta]: |
Go to the input files for this example
Go to the output files for this example
Example 2
This uses a drosophila sequence and codon table.
% backtranseq -cfile Edrome.cut Back-translate a protein sequence to a nucleotide sequence Input (gapped) protein sequence(s): tsw:ach2_drome (gapped) nucleotide output sequence(s) [ach2_drome.fasta]: |
Go to the input files for this example
Go to the output files for this example
Command line arguments
Back-translate a protein sequence to a nucleotide sequence Version: EMBOSS:6.4.0.0 Standard (Mandatory) qualifiers: [-sequence] seqall (Gapped) protein sequence(s) filename and optional format, or reference (input USA) [-outfile] seqoutall [ |
Qualifier | Type | Description | Allowed values | Default |
---|---|---|---|---|
Standard (Mandatory) qualifiers | ||||
[-sequence] (Parameter 1) |
seqall | (Gapped) protein sequence(s) filename and optional format, or reference (input USA) | Readable sequence(s) | Required |
[-outfile] (Parameter 2) |
seqoutall | (Aligned) nucleotide sequence set(s) filename and optional format (output USA) | Writeable sequence(s) | <*>.format |
Additional (Optional) qualifiers | ||||
-cfile | codon | Codon usage table name | Codon usage file in EMBOSS data path | Ehuman.cut |
Advanced (Unprompted) qualifiers | ||||
(none) | ||||
Associated qualifiers | ||||
"-sequence" associated seqall qualifiers | ||||
-sbegin1 -sbegin_sequence |
integer | Start of each sequence to be used | Any integer value | 0 |
-send1 -send_sequence |
integer | End of each sequence to be used | Any integer value | 0 |
-sreverse1 -sreverse_sequence |
boolean | Reverse (if DNA) | Boolean value Yes/No | N |
-sask1 -sask_sequence |
boolean | Ask for begin/end/reverse | Boolean value Yes/No | N |
-snucleotide1 -snucleotide_sequence |
boolean | Sequence is nucleotide | Boolean value Yes/No | N |
-sprotein1 -sprotein_sequence |
boolean | Sequence is protein | Boolean value Yes/No | N |
-slower1 -slower_sequence |
boolean | Make lower case | Boolean value Yes/No | N |
-supper1 -supper_sequence |
boolean | Make upper case | Boolean value Yes/No | N |
-sformat1 -sformat_sequence |
string | Input sequence format | Any string | |
-sdbname1 -sdbname_sequence |
string | Database name | Any string | |
-sid1 -sid_sequence |
string | Entryname | Any string | |
-ufo1 -ufo_sequence |
string | UFO features | Any string | |
-fformat1 -fformat_sequence |
string | Features format | Any string | |
-fopenfile1 -fopenfile_sequence |
string | Features file name | Any string | |
"-cfile" associated codon qualifiers | ||||
-format | string | Data format | Any string | |
"-outfile" associated seqoutall qualifiers | ||||
-osformat2 -osformat_outfile |
string | Output seq format | Any string | |
-osextension2 -osextension_outfile |
string | File name extension | Any string | |
-osname2 -osname_outfile |
string | Base file name | Any string | |
-osdirectory2 -osdirectory_outfile |
string | Output directory | Any string | |
-osdbname2 -osdbname_outfile |
string | Database name to add | Any string | |
-ossingle2 -ossingle_outfile |
boolean | Separate file for each entry | Boolean value Yes/No | N |
-oufo2 -oufo_outfile |
string | UFO features | Any string | |
-offormat2 -offormat_outfile |
string | Features format | Any string | |
-ofname2 -ofname_outfile |
string | Features file name | Any string | |
-ofdirectory2 -ofdirectory_outfile |
string | Output directory | Any string | |
General qualifiers | ||||
-auto | boolean | Turn off prompts | Boolean value Yes/No | N |
-stdout | boolean | Write first file to standard output | Boolean value Yes/No | N |
-filter | boolean | Read first file from standard input, write first file to standard output | Boolean value Yes/No | N |
-options | boolean | Prompt for standard and additional values | Boolean value Yes/No | N |
-debug | boolean | Write debug output to program.dbg | Boolean value Yes/No | N |
-verbose | boolean | Report some/full command line options | Boolean value Yes/No | Y |
-help | boolean | Report command line options and exit. More information on associated and general qualifiers can be found with -help -verbose | Boolean value Yes/No | N |
-warning | boolean | Report warnings | Boolean value Yes/No | Y |
-error | boolean | Report errors | Boolean value Yes/No | Y |
-fatal | boolean | Report fatal errors | Boolean value Yes/No | Y |
-die | boolean | Report dying program messages | Boolean value Yes/No | Y |
-version | boolean | Report version number and exit | Boolean value Yes/No | N |
Input file format
backtranambig reads one or more protein sequences.
The input is a standard EMBOSS sequence query (also known as a 'USA').
Major sequence database sources defined as standard in EMBOSS installations include srs:embl, srs:uniprot and ensembl
Data can also be read from sequence output in any supported format written by an EMBOSS or third-party application.
The input format can be specified by using the command-line qualifier -sformat xxx, where 'xxx' is replaced by the name of the required format. The available format names are: gff (gff3), gff2, embl (em), genbank (gb, refseq), ddbj, refseqp, pir (nbrf), swissprot (swiss, sw), dasgff and debug.
See: http://emboss.sf.net/docs/themes/SequenceFormats.html for further information on sequence formats.
Input files for usage example
'tsw:opsd_human' is a sequence entry in the example protein database 'tsw'
Database entry: tsw:opsd_human
ID OPSD_HUMAN Reviewed; 348 AA. AC P08100; Q16414; Q2M249; DT 01-AUG-1988, integrated into UniProtKB/Swiss-Prot. DT 01-AUG-1988, sequence version 1. DT 15-JUN-2010, entry version 128. DE RecName: Full=Rhodopsin; DE AltName: Full=Opsin-2; GN Name=RHO; Synonyms=OPN2; OS Homo sapiens (Human). OC Eukaryota; Metazoa; Chordata; Craniata; Vertebrata; Euteleostomi; OC Mammalia; Eutheria; Euarchontoglires; Primates; Haplorrhini; OC Catarrhini; Hominidae; Homo. OX NCBI_TaxID=9606; RN [1] RP NUCLEOTIDE SEQUENCE [GENOMIC DNA]. RX MEDLINE=84272729; PubMed=6589631; DOI=10.1073/pnas.81.15.4851; RA Nathans J., Hogness D.S.; RT "Isolation and nucleotide sequence of the gene encoding human RT rhodopsin."; RL Proc. Natl. Acad. Sci. U.S.A. 81:4851-4855(1984). RN [2] RP NUCLEOTIDE SEQUENCE [GENOMIC DNA]. RA Suwa M., Sato T., Okouchi I., Arita M., Futami K., Matsumoto S., RA Tsutsumi S., Aburatani H., Asai K., Akiyama Y.; RT "Genome-wide discovery and analysis of human seven transmembrane helix RT receptor genes."; RL Submitted (JUL-2001) to the EMBL/GenBank/DDBJ databases. RN [3] RP NUCLEOTIDE SEQUENCE [LARGE SCALE MRNA]. RC TISSUE=Retina; RX PubMed=17974005; DOI=10.1186/1471-2164-8-399; RA Bechtel S., Rosenfelder H., Duda A., Schmidt C.P., Ernst U., RA Wellenreuther R., Mehrle A., Schuster C., Bahr A., Bloecker H., RA Heubner D., Hoerlein A., Michel G., Wedler H., Koehrer K., RA Ottenwaelder B., Poustka A., Wiemann S., Schupp I.; RT "The full-ORF clone resource of the German cDNA consortium."; RL BMC Genomics 8:399-399(2007). RN [4] RP NUCLEOTIDE SEQUENCE [LARGE SCALE MRNA]. RX PubMed=15489334; DOI=10.1101/gr.2596504; RG The MGC Project Team; RT "The status, quality, and expansion of the NIH full-length cDNA RT project: the Mammalian Gene Collection (MGC)."; RL Genome Res. 14:2121-2127(2004). RN [5] RP NUCLEOTIDE SEQUENCE [GENOMIC DNA] OF 1-120. RX PubMed=8566799; DOI=10.1016/0378-1119(95)00688-5; RA Bennett J., Beller B., Sun D., Kariko K.; RT "Sequence analysis of the 5.34-kb 5' flanking region of the human RT rhodopsin-encoding gene."; [Part of this file has been deleted for brevity] FT /FTId=VAR_004816. FT VARIANT 209 209 V -> M (effect not known). FT /FTId=VAR_004817. FT VARIANT 211 211 H -> P (in RP4; dbSNP:rs28933993). FT /FTId=VAR_004818. FT VARIANT 211 211 H -> R (in RP4). FT /FTId=VAR_004819. FT VARIANT 216 216 M -> K (in RP4). FT /FTId=VAR_004820. FT VARIANT 220 220 F -> C (in RP4). FT /FTId=VAR_004821. FT VARIANT 222 222 C -> R (in RP4). FT /FTId=VAR_004822. FT VARIANT 255 255 Missing (in RP4). FT /FTId=VAR_004823. FT VARIANT 264 264 Missing (in RP4). FT /FTId=VAR_004824. FT VARIANT 267 267 P -> L (in RP4). FT /FTId=VAR_004825. FT VARIANT 267 267 P -> R (in RP4). FT /FTId=VAR_004826. FT VARIANT 292 292 A -> E (in CSNBAD1). FT /FTId=VAR_004827. FT VARIANT 296 296 K -> E (in RP4; dbSNP:rs29001653). FT /FTId=VAR_004828. FT VARIANT 297 297 S -> R (in RP4). FT /FTId=VAR_004829. FT VARIANT 342 342 T -> M (in RP4). FT /FTId=VAR_004830. FT VARIANT 345 345 V -> L (in RP4). FT /FTId=VAR_004831. FT VARIANT 345 345 V -> M (in RP4). FT /FTId=VAR_004832. FT VARIANT 347 347 P -> A (in RP4). FT /FTId=VAR_004833. FT VARIANT 347 347 P -> L (in RP4; common variant). FT /FTId=VAR_004834. FT VARIANT 347 347 P -> Q (in RP4). FT /FTId=VAR_004835. FT VARIANT 347 347 P -> R (in RP4; dbSNP:rs29001566). FT /FTId=VAR_004836. FT VARIANT 347 347 P -> S (in RP4; dbSNP:rs29001637). FT /FTId=VAR_004837. SQ SEQUENCE 348 AA; 38893 MW; 6F4F6FCBA34265B2 CRC64; MNGTEGPNFY VPFSNATGVV RSPFEYPQYY LAEPWQFSML AAYMFLLIVL GFPINFLTLY VTVQHKKLRT PLNYILLNLA VADLFMVLGG FTSTLYTSLH GYFVFGPTGC NLEGFFATLG GEIALWSLVV LAIERYVVVC KPMSNFRFGE NHAIMGVAFT WVMALACAAP PLAGWSRYIP EGLQCSCGID YYTLKPEVNN ESFVIYMFVV HFTIPMIIIF FCYGQLVFTV KEAAAQQQES ATTQKAEKEV TRMVIIMVIA FLICWVPYAS VAFYIFTHQG SNFGPIFMTI PAFFAKSAAI YNPVIYIMMN KQFRNCMLTT ICCGKNPLGD DEASATVSKT ETSQVAPA // |
Input files for usage example 2
Database entry: tsw:ach2_drome
ID ACH2_DROME Reviewed; 576 AA. AC P17644; Q0KI18; Q9VC73; DT 01-AUG-1990, integrated into UniProtKB/Swiss-Prot. DT 01-AUG-1990, sequence version 1. DT 15-JUN-2010, entry version 110. DE RecName: Full=Acetylcholine receptor subunit alpha-like 2; DE Flags: Precursor; GN Name=nAcRalpha-96Ab; Synonyms=Acr96Ab, AcrE, sad; ORFNames=CG6844; OS Drosophila melanogaster (Fruit fly). OC Eukaryota; Metazoa; Arthropoda; Hexapoda; Insecta; Pterygota; OC Neoptera; Endopterygota; Diptera; Brachycera; Muscomorpha; OC Ephydroidea; Drosophilidae; Drosophila; Sophophora. OX NCBI_TaxID=7227; RN [1] RP NUCLEOTIDE SEQUENCE [GENOMIC DNA], TISSUE SPECIFICITY, AND RP DEVELOPMENTAL STAGE. RC TISSUE=Head; RX MEDLINE=90353591; PubMed=2117557; DOI=10.1016/0014-5793(90)81170-S; RA Jonas P., Baumann A., Merz B., Gundelfinger E.D.; RT "Structure and developmental expression of the D alpha 2 gene encoding RT a novel nicotinic acetylcholine receptor protein of Drosophila RT melanogaster."; RL FEBS Lett. 269:264-268(1990). RN [2] RP NUCLEOTIDE SEQUENCE [MRNA]. RX MEDLINE=90360975; PubMed=1697262; RA Sawruk E., Schloss P., Betz H., Schmitt B.; RT "Heterogeneity of Drosophila nicotinic acetylcholine receptors: SAD, a RT novel developmentally regulated alpha-subunit."; RL EMBO J. 9:2671-2677(1990). RN [3] RP NUCLEOTIDE SEQUENCE [MRNA], TISSUE SPECIFICITY, AND DEVELOPMENTAL RP STAGE. RC TISSUE=Head; RX MEDLINE=90301489; PubMed=2114015; DOI=10.1093/nar/18.12.3640; RA Baumann A., Jonas P., Gundelfinger E.D.; RT "Sequence of D alpha 2, a novel alpha-like subunit of Drosophila RT nicotinic acetylcholine receptors."; RL Nucleic Acids Res. 18:3640-3640(1990). RN [4] RP NUCLEOTIDE SEQUENCE [LARGE SCALE GENOMIC DNA]. RC STRAIN=Berkeley; RX MEDLINE=20196006; PubMed=10731132; DOI=10.1126/science.287.5461.2185; RA Adams M.D., Celniker S.E., Holt R.A., Evans C.A., Gocayne J.D., RA Amanatides P.G., Scherer S.E., Li P.W., Hoskins R.A., Galle R.F., RA George R.A., Lewis S.E., Richards S., Ashburner M., Henderson S.N., RA Sutton G.G., Wortman J.R., Yandell M.D., Zhang Q., Chen L.X., RA Brandon R.C., Rogers Y.-H.C., Blazej R.G., Champe M., Pfeiffer B.D., RA Wan K.H., Doyle C., Baxter E.G., Helt G., Nelson C.R., Miklos G.L.G., RA Abril J.F., Agbayani A., An H.-J., Andrews-Pfannkoch C., Baldwin D., [Part of this file has been deleted for brevity] DR GO; GO:0005515; F:protein binding; IPI:IntAct. DR GO; GO:0004872; F:receptor activity; IEA:UniProtKB-KW. DR GO; GO:0006811; P:ion transport; IEA:UniProtKB-KW. DR InterPro; IPR006202; Neur_chan_lig_bd. DR InterPro; IPR006201; Neur_channel. DR InterPro; IPR006029; Neurotrans-gated_channel_TM. DR InterPro; IPR018000; Neurotransmitter_ion_chnl_CS. DR InterPro; IPR002394; Nicotinic_acetylcholine_rcpt_N. DR Gene3D; G3DSA:2.70.170.10; Neur_chan_lig_bd; 1. DR PANTHER; PTHR18945; Neur_channel; 1. DR Pfam; PF02931; Neur_chan_LBD; 1. DR Pfam; PF02932; Neur_chan_memb; 1. DR PRINTS; PR00254; NICOTINICR. DR PRINTS; PR00252; NRIONCHANNEL. DR SUPFAM; SSF90112; Neu_channel_TM; 1. DR SUPFAM; SSF63712; Neur_chan_LBD; 1. DR TIGRFAMs; TIGR00860; LIC; 1. DR PROSITE; PS00236; NEUROTR_ION_CHANNEL; 1. PE 1: Evidence at protein level; KW Cell junction; Cell membrane; Complete proteome; Disulfide bond; KW Glycoprotein; Ion transport; Ionic channel; Membrane; KW Postsynaptic cell membrane; Receptor; Signal; Synapse; Transmembrane; KW Transport. FT SIGNAL 1 21 Probable. FT CHAIN 22 576 Acetylcholine receptor subunit alpha-like FT 2. FT /FTId=PRO_0000000300. FT TOPO_DOM 22 261 Extracellular (Potential). FT TRANSMEM 262 285 Helical; (Potential). FT TRANSMEM 293 311 Helical; (Potential). FT TRANSMEM 327 346 Helical; (Potential). FT TOPO_DOM 347 526 Cytoplasmic (Potential). FT TRANSMEM 527 545 Helical; (Potential). FT CARBOHYD 65 65 N-linked (GlcNAc...) (Potential). FT CARBOHYD 254 254 N-linked (GlcNAc...) (Potential). FT CARBOHYD 570 570 N-linked (GlcNAc...) (Potential). FT DISULFID 169 183 By similarity. FT DISULFID 243 244 Associated with receptor activation (By FT similarity). SQ SEQUENCE 576 AA; 65506 MW; 97D6A46CADC3F42F CRC64; MAPGCCTTRP RPIALLAHIW RHCKPLCLLL VLLLLCETVQ ANPDAKRLYD DLLSNYNRLI RPVSNNTDTV LVKLGLRLSQ LIDLNLKDQI LTTNVWLEHE WQDHKFKWDP SEYGGVTELY VPSEHIWLPD IVLYNNADGE YVVTTMTKAI LHYTGKVVWT PPAIFKSSCE IDVRYFPFDQ QTCFMKFGSW TYDGDQIDLK HISQKNDKDN KVEIGIDLRE YYPSVEWDIL GVPAERHEKY YPCCAEPYPD IFFNITLRRK TLFYTVNLII PCVGISYLSV LVFYLPADSG EKIALCISIL LSQTMFFLLI SEIIPSTSLA LPLLGKYLLF TMLLVGLSVV ITIIILNIHY RKPSTHKMRP WIRSFFIKRL PKLLLMRVPK DLLRDLAANK INYGLKFSKT KFGQALMDEM QMNSGGSSPD SLRRMQGRVG AGGCNGMHVT TATNRFSGLV GALGGGLSTL SGYNGLPSVL SGLDDSLSDV AARKKYPFEL EKAIHNVMFI QHHMQRQDEF NAEDQDWGFV AMVMDRLFLW LFMIASLVGT FVILGEAPSL YDDTKAIDVQ LSDVAKQIYN LTEKKN // |
Output file format
The output is a nucleotide sequence containing the most favoured back translation of the specified protein, and using the specified translation table (which defaults to human).
The output is a standard EMBOSS sequence file.
The results can be output in one of several styles by using the command-line qualifier -osformat xxx, where 'xxx' is replaced by the name of the required format. The available format names are: embl, genbank, gff, pir, swiss, dasgff, debug, listfile, dbmotif, diffseq, excel, feattable, motif, nametable, regions, seqtable, simple, srs, table, tagseq.
See: http://emboss.sf.net/docs/themes/SequenceFormats.html for further information on sequence formats.
Output files for usage example
File: opsd_human.fasta
>OPSD_HUMAN P08100 Rhodopsin (Opsin-2) ATGAACGGCACCGAGGGCCCCAACTTCTACGTGCCCTTCAGCAACGCCACCGGCGTGGTG AGGAGCCCCTTCGAGTACCCCCAGTACTACCTGGCCGAGCCCTGGCAGTTCAGCATGCTG GCCGCCTACATGTTCCTGCTGATCGTGCTGGGCTTCCCCATCAACTTCCTGACCCTGTAC GTGACCGTGCAGCACAAGAAGCTGAGGACCCCCCTGAACTACATCCTGCTGAACCTGGCC GTGGCCGACCTGTTCATGGTGCTGGGCGGCTTCACCAGCACCCTGTACACCAGCCTGCAC GGCTACTTCGTGTTCGGCCCCACCGGCTGCAACCTGGAGGGCTTCTTCGCCACCCTGGGC GGCGAGATCGCCCTGTGGAGCCTGGTGGTGCTGGCCATCGAGAGGTACGTGGTGGTGTGC AAGCCCATGAGCAACTTCAGGTTCGGCGAGAACCACGCCATCATGGGCGTGGCCTTCACC TGGGTGATGGCCCTGGCCTGCGCCGCCCCCCCCCTGGCCGGCTGGAGCAGGTACATCCCC GAGGGCCTGCAGTGCAGCTGCGGCATCGACTACTACACCCTGAAGCCCGAGGTGAACAAC GAGAGCTTCGTGATCTACATGTTCGTGGTGCACTTCACCATCCCCATGATCATCATCTTC TTCTGCTACGGCCAGCTGGTGTTCACCGTGAAGGAGGCCGCCGCCCAGCAGCAGGAGAGC GCCACCACCCAGAAGGCCGAGAAGGAGGTGACCAGGATGGTGATCATCATGGTGATCGCC TTCCTGATCTGCTGGGTGCCCTACGCCAGCGTGGCCTTCTACATCTTCACCCACCAGGGC AGCAACTTCGGCCCCATCTTCATGACCATCCCCGCCTTCTTCGCCAAGAGCGCCGCCATC TACAACCCCGTGATCTACATCATGATGAACAAGCAGTTCAGGAACTGCATGCTGACCACC ATCTGCTGCGGCAAGAACCCCCTGGGCGACGACGAGGCCAGCGCCACCGTGAGCAAGACC GAGACCAGCCAGGTGGCCCCCGCC |
Output files for usage example 2
File: ach2_drome.fasta
>ACH2_DROME P17644 Acetylcholine receptor subunit alpha-like 2 (Precursor) ATGGCCCCCGGCTGCTGCACCACCCGCCCCCGCCCCATCGCCCTGCTGGCCCACATCTGG CGCCACTGCAAGCCCCTGTGCCTGCTGCTGGTGCTGCTGCTGCTGTGCGAGACCGTGCAG GCCAACCCCGATGCCAAGCGCCTGTACGATGATCTGCTGAGCAACTACAACCGCCTGATC CGCCCCGTGAGCAACAACACCGATACCGTGCTGGTGAAGCTGGGCCTGCGCCTGAGCCAG CTGATCGATCTGAACCTGAAGGATCAGATCCTGACCACCAACGTGTGGCTGGAGCACGAG TGGCAGGATCACAAGTTCAAGTGGGATCCCAGCGAGTACGGCGGCGTGACCGAGCTGTAC GTGCCCAGCGAGCACATCTGGCTGCCCGATATCGTGCTGTACAACAACGCCGATGGCGAG TACGTGGTGACCACCATGACCAAGGCCATCCTGCACTACACCGGCAAGGTGGTGTGGACC CCCCCCGCCATCTTCAAGAGCAGCTGCGAGATCGATGTGCGCTACTTCCCCTTCGATCAG CAGACCTGCTTCATGAAGTTCGGCAGCTGGACCTACGATGGCGATCAGATCGATCTGAAG CACATCAGCCAGAAGAACGATAAGGATAACAAGGTGGAGATCGGCATCGATCTGCGCGAG TACTACCCCAGCGTGGAGTGGGATATCCTGGGCGTGCCCGCCGAGCGCCACGAGAAGTAC TACCCCTGCTGCGCCGAGCCCTACCCCGATATCTTCTTCAACATCACCCTGCGCCGCAAG ACCCTGTTCTACACCGTGAACCTGATCATCCCCTGCGTGGGCATCAGCTACCTGAGCGTG CTGGTGTTCTACCTGCCCGCCGATAGCGGCGAGAAGATCGCCCTGTGCATCAGCATCCTG CTGAGCCAGACCATGTTCTTCCTGCTGATCAGCGAGATCATCCCCAGCACCAGCCTGGCC CTGCCCCTGCTGGGCAAGTACCTGCTGTTCACCATGCTGCTGGTGGGCCTGAGCGTGGTG ATCACCATCATCATCCTGAACATCCACTACCGCAAGCCCAGCACCCACAAGATGCGCCCC TGGATCCGCAGCTTCTTCATCAAGCGCCTGCCCAAGCTGCTGCTGATGCGCGTGCCCAAG GATCTGCTGCGCGATCTGGCCGCCAACAAGATCAACTACGGCCTGAAGTTCAGCAAGACC AAGTTCGGCCAGGCCCTGATGGATGAGATGCAGATGAACAGCGGCGGCAGCAGCCCCGAT AGCCTGCGCCGCATGCAGGGCCGCGTGGGCGCCGGCGGCTGCAACGGCATGCACGTGACC ACCGCCACCAACCGCTTCAGCGGCCTGGTGGGCGCCCTGGGCGGCGGCCTGAGCACCCTG AGCGGCTACAACGGCCTGCCCAGCGTGCTGAGCGGCCTGGATGATAGCCTGAGCGATGTG GCCGCCCGCAAGAAGTACCCCTTCGAGCTGGAGAAGGCCATCCACAACGTGATGTTCATC CAGCACCACATGCAGCGCCAGGATGAGTTCAACGCCGAGGATCAGGATTGGGGCTTCGTG GCCATGGTGATGGATCGCCTGTTCCTGTGGCTGTTCATGATCGCCAGCCTGGTGGGCACC TTCGTGATCCTGGGCGAGGCCCCCAGCCTGTACGATGATACCAAGGCCATCGATGTGCAG CTGAGCGATGTGGCCAAGCAGATCTACAACCTGACCGAGAAGAAGAAC |
Data files
The codon usage table is read by default from "Ehum.cut" in the 'data/CODONS' directory of the EMBOSS distribution. If the name of a codon usage file is specified on the command line, then this file will first be searched for in the current directory and then in the 'data/CODONS' directory of the EMBOSS distribution.
EMBOSS data files are distributed with the application and stored in the standard EMBOSS data directory, which is defined by the EMBOSS environment variable EMBOSS_DATA.
To see the available EMBOSS data files, run:
% embossdata -showall
To fetch one of the data files (for example 'Exxx.dat') into your current directory for you to inspect or modify, run:
% embossdata -fetch -file Exxx.dat
Users can provide their own data files in their own directories. Project specific files can be put in the current directory, or for tidier directory listings in a subdirectory called ".embossdata". Files for all EMBOSS runs can be put in the user's home directory, or again in a subdirectory called ".embossdata".
The directories are searched in the following order:
- . (your current directory)
- .embossdata (under your current directory)
- ~/ (your home directory)
- ~/.embossdata
Notes
backtranseq reads a data file containing the codon usage table. The default file is Ehum.cut - the human codon usage table. Many others are available and can be set by name with the -cfile qualifier. It is important to use one that is appropriate for the species that your protein comes from. The specified data file must exist in the EMBOSS data directory (see below for more information).
References
None.Warnings
None.Diagnostic Error Messages
"Corrupt codon index file" - the codon usage file is incomplete or empty."The file 'drosoph.cut' does not exist" - the codon usage file cannot be opened.
Exit status
This program always exits with a status of 0, unless the codon usage table cannot be opened.Known bugs
None.See also
Program name | Description |
---|---|
backtranambig | Back-translate a protein sequence to ambiguous nucleotide sequence |
checktrans | Reports STOP codons and ORF statistics of a protein |
coderet | Extract CDS, mRNA and translations from feature tables |
compseq | Calculate the composition of unique words in sequences |
emowse | Search protein sequences by digest fragment molecular weight |
freak | Generate residue/base frequency table or plot |
mwcontam | Find weights common to multiple molecular weights files |
mwfilter | Filter noisy data from molecular weights file |
oddcomp | Identify proteins with specified sequence word composition |
pepdigest | Reports on protein proteolytic enzyme or reagent cleavage sites |
pepinfo | Plot amino acid properties of a protein sequence in parallel |
pepstats | Calculates statistics of protein properties |
plotorf | Plot potential open reading frames in a nucleotide sequence |
prettyseq | Write a nucleotide sequence and its translation to file |
remap | Display restriction enzyme binding sites in a nucleotide sequence |
showorf | Display a nucleotide sequence and translation in pretty format |
showseq | Displays sequences with features in pretty format |
sixpack | Display a DNA sequence with 6-frame translation and ORFs |
transeq | Translate nucleic acid sequences |
wordcount | Count and extract unique words in molecular sequence(s) |
Author(s)
Alan BleasbyEuropean Bioinformatics Institute, Wellcome Trust Genome Campus, Hinxton, Cambridge CB10 1SD, UK
Please report all bugs to the EMBOSS bug team (emboss-bug © emboss.open-bio.org) not to the original author.