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  EMBOSS: matcher
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<A HREF="/" ONMOUSEOVER="self.status='Go to the EMBOSS home page';return true"><img border=0 src="/images/emboss_icon.jpg" alt="" width=150 height=48></a>
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<td align=left valign=middle>
<b><font size="+6">
matcher
</font></b>
</td></tr>
</table>
<br>&nbsp;
<p>


<H2>
Wiki
</H2>

The master copies of EMBOSS documentation are available
at <a href="http://emboss.open-bio.org/wiki/Appdocs">
http://emboss.open-bio.org/wiki/Appdocs</a>
on the EMBOSS Wiki.

<p>
Please help by correcting and extending the Wiki pages.

<H2>
    Function
</H2>
Waterman-Eggert local alignment of two sequences

<H2>
    Description
</H2>


<p><b>matcher</b> identifies local similarities in two input sequences using a rigorous algorithm based on Bill Pearson's <b>lalign</b> application, version 2.0u4 (Feb. 1996). The substitution matrix, gap insertion and extension penalty are specified. The specified number of top-scoring pair-wise local sequence alignments are written to file.</p>


<H2>
Algorithm
</H2>


<p><b>matcher</b> is based on Bill Pearson's <b>lalign</b> application, version 2.0u4 (Feb. 1996). lalign uses code developed by X. Huang and W. Miller (Adv. Appl. Math. (1991) 12:337-357) for the "sim" program, which is a linear-space version of an algorithm described by M. S. Waterman and M. Eggert (J. Mol. Biol. 197:723-728).</p>

<H2>
    Usage
</H2>

Here is a sample session with <b>matcher</b>
<p>

<p>
<table width="90%"><tr><td bgcolor="#CCFFFF"><pre>

% <b>matcher tsw:hba_human tsw:hbb_human </b>
Waterman-Eggert local alignment of two sequences
Output alignment [hba_human.matcher]: <b></b>

</pre></td></tr></table><p>
<p>
<a href="#input.1">Go to the input files for this example</a><br><a href="#output.1">Go to the output files for this example</a><p><p>
<p>
<b>Example 2</b>
<p>
To find the 10 best alignments: 
<p>

<p>
<table width="90%"><tr><td bgcolor="#CCFFFF"><pre>

% <b>matcher tsw:hba_human tsw:hbb_human -alt 10 </b>
Waterman-Eggert local alignment of two sequences
Output alignment [hba_human.matcher]: <b></b>

</pre></td></tr></table><p>
<p>
<a href="#output.2">Go to the output files for this example</a><p><p>



<H2>
    Command line arguments
</H2>
<table CELLSPACING=0 CELLPADDING=3 BGCOLOR="#f5f5ff" ><tr><td>
<pre>
Waterman-Eggert local alignment of two sequences
Version: EMBOSS:6.6.0.0

   Standard (Mandatory) qualifiers:
  [-asequence]         sequence   Sequence filename and optional format, or
                                  reference (input USA)
  [-bsequence]         sequence   Sequence filename and optional format, or
                                  reference (input USA)
  [-outfile]           align      [*.matcher] Output alignment file name
                                  (default -aformat markx0)

   Additional (Optional) qualifiers:
   -datafile           matrix     [EBLOSUM62 for protein, EDNAFULL for DNA]
                                  This is the scoring matrix file used when
                                  comparing sequences. By default it is the
                                  file 'EBLOSUM62' (for proteins) or the file
                                  'EDNAFULL' (for nucleic sequences). These
                                  files are found in the 'data' directory of
                                  the EMBOSS installation.
   -alternatives       integer    [1] This sets the number of alternative
                                  matches output. By default only the highest
                                  scoring alignment is shown. A value of 2
                                  gives you other reasonable alignments. In
                                  some cases, for example multidomain proteins
                                  of cDNA and genomic DNA comparisons, there
                                  may be other interesting and significant
                                  alignments. (Integer 1 or more)
   -gapopen            integer    [14 for protein, 16 for nucleic] The gap
                                  penalty is the score taken away when a gap
                                  is created. The best value depends on the
                                  choice of comparison matrix. The default
                                  value of 14 assumes you are using the
                                  EBLOSUM62 matrix for protein sequences, or a
                                  value of 16 and the EDNAFULL matrix for
                                  nucleotide sequences. (Positive integer)
   -gapextend          integer    [4 for any sequence] The gap length, or gap
                                  extension, penalty is added to the standard
                                  gap penalty for each base or residue in the
                                  gap. This is how long gaps are penalized.
                                  Usually you will expect a few long gaps
                                  rather than many short gaps, so the gap
                                  extension penalty should be lower than the
                                  gap penalty. An exception is where one or
                                  both sequences are single reads with
                                  possible sequencing errors in which case you
                                  would expect many single base gaps. You can
                                  get this result by setting the gap penalty
                                  to zero (or very low) and using the gap
                                  extension penalty to control gap scoring.
                                  (Positive integer)

   Advanced (Unprompted) qualifiers: (none)
   Associated qualifiers:

   "-asequence" associated qualifiers
   -sbegin1            integer    Start of the sequence to be used
   -send1              integer    End of the sequence to be used
   -sreverse1          boolean    Reverse (if DNA)
   -sask1              boolean    Ask for begin/end/reverse
   -snucleotide1       boolean    Sequence is nucleotide
   -sprotein1          boolean    Sequence is protein
   -slower1            boolean    Make lower case
   -supper1            boolean    Make upper case
   -scircular1         boolean    Sequence is circular
   -squick1            boolean    Read id and sequence only
   -sformat1           string     Input sequence format
   -iquery1            string     Input query fields or ID list
   -ioffset1           integer    Input start position offset
   -sdbname1           string     Database name
   -sid1               string     Entryname
   -ufo1               string     UFO features
   -fformat1           string     Features format
   -fopenfile1         string     Features file name

   "-bsequence" associated qualifiers
   -sbegin2            integer    Start of the sequence to be used
   -send2              integer    End of the sequence to be used
   -sreverse2          boolean    Reverse (if DNA)
   -sask2              boolean    Ask for begin/end/reverse
   -snucleotide2       boolean    Sequence is nucleotide
   -sprotein2          boolean    Sequence is protein
   -slower2            boolean    Make lower case
   -supper2            boolean    Make upper case
   -scircular2         boolean    Sequence is circular
   -squick2            boolean    Read id and sequence only
   -sformat2           string     Input sequence format
   -iquery2            string     Input query fields or ID list
   -ioffset2           integer    Input start position offset
   -sdbname2           string     Database name
   -sid2               string     Entryname
   -ufo2               string     UFO features
   -fformat2           string     Features format
   -fopenfile2         string     Features file name

   "-outfile" associated qualifiers
   -aformat3           string     Alignment format
   -aextension3        string     File name extension
   -adirectory3        string     Output directory
   -aname3             string     Base file name
   -awidth3            integer    Alignment width
   -aaccshow3          boolean    Show accession number in the header
   -adesshow3          boolean    Show description in the header
   -ausashow3          boolean    Show the full USA in the alignment
   -aglobal3           boolean    Show the full sequence in alignment

   General qualifiers:
   -auto               boolean    Turn off prompts
   -stdout             boolean    Write first file to standard output
   -filter             boolean    Read first file from standard input, write
                                  first file to standard output
   -options            boolean    Prompt for standard and additional values
   -debug              boolean    Write debug output to program.dbg
   -verbose            boolean    Report some/full command line options
   -help               boolean    Report command line options and exit. More
                                  information on associated and general
                                  qualifiers can be found with -help -verbose
   -warning            boolean    Report warnings
   -error              boolean    Report errors
   -fatal              boolean    Report fatal errors
   -die                boolean    Report dying program messages
   -version            boolean    Report version number and exit

</pre>
</td></tr></table>
<P>

<table border cellspacing=0 cellpadding=3 bgcolor="#ccccff">
<tr bgcolor="#FFFFCC">
<th align="left">Qualifier</th>
<th align="left">Type</th>
<th align="left">Description</th>
<th align="left">Allowed values</th>
<th align="left">Default</th>
</tr>

<tr bgcolor="#FFFFCC">
<th align="left" colspan=5>Standard (Mandatory) qualifiers</th>
</tr>

<tr bgcolor="#FFFFCC">
<td>[-asequence]<br>(Parameter 1)</td>
<td>sequence</td>
<td>Sequence filename and optional format, or reference (input USA)</td>
<td>Readable sequence</td>
<td><b>Required</b></td>
</tr>

<tr bgcolor="#FFFFCC">
<td>[-bsequence]<br>(Parameter 2)</td>
<td>sequence</td>
<td>Sequence filename and optional format, or reference (input USA)</td>
<td>Readable sequence</td>
<td><b>Required</b></td>
</tr>

<tr bgcolor="#FFFFCC">
<td>[-outfile]<br>(Parameter 3)</td>
<td>align</td>
<td>Output alignment file name</td>
<td>(default -aformat markx0)</td>
<td><i>&lt;*&gt;</i>.matcher</td>
</tr>

<tr bgcolor="#FFFFCC">
<th align="left" colspan=5>Additional (Optional) qualifiers</th>
</tr>

<tr bgcolor="#FFFFCC">
<td>-datafile</td>
<td>matrix</td>
<td>This is the scoring matrix file used when comparing sequences. By default it is the file 'EBLOSUM62' (for proteins) or the file 'EDNAFULL' (for nucleic sequences). These files are found in the 'data' directory of the EMBOSS installation.</td>
<td>Comparison matrix file in EMBOSS data path</td>
<td>EBLOSUM62 for protein<br>EDNAFULL for DNA</td>
</tr>

<tr bgcolor="#FFFFCC">
<td>-alternatives</td>
<td>integer</td>
<td>This sets the number of alternative matches output. By default only the highest scoring alignment is shown. A value of 2 gives you other reasonable alignments. In some cases, for example multidomain proteins of cDNA and genomic DNA comparisons, there may be other interesting and significant alignments.</td>
<td>Integer 1 or more</td>
<td>1</td>
</tr>

<tr bgcolor="#FFFFCC">
<td>-gapopen</td>
<td>integer</td>
<td>The gap penalty is the score taken away when a gap is created. The best value depends on the choice of comparison matrix. The default value of 14 assumes you are using the EBLOSUM62 matrix for protein sequences, or a value of 16 and the EDNAFULL matrix for nucleotide sequences.</td>
<td>Positive integer</td>
<td>14 for protein, 16 for nucleic</td>
</tr>

<tr bgcolor="#FFFFCC">
<td>-gapextend</td>
<td>integer</td>
<td>The gap length, or gap extension, penalty is added to the standard gap penalty for each base or residue in the gap. This is how long gaps are penalized. Usually you will expect a few long gaps rather than many short gaps, so the gap extension penalty should be lower than the gap penalty. An exception is where one or both sequences are single reads with possible sequencing errors in which case you would expect many single base gaps. You can get this result by setting the gap penalty to zero (or very low) and using the gap extension penalty to control gap scoring.</td>
<td>Positive integer</td>
<td>4 for any sequence</td>
</tr>

<tr bgcolor="#FFFFCC">
<th align="left" colspan=5>Advanced (Unprompted) qualifiers</th>
</tr>

<tr>
<td colspan=5>(none)</td>
</tr>

<tr bgcolor="#FFFFCC">
<th align="left" colspan=5>Associated qualifiers</th>
</tr>

<tr bgcolor="#FFFFCC">
<td align="left" colspan=5>"-asequence" associated sequence qualifiers
</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -sbegin1<br>-sbegin_asequence</td>
<td>integer</td>
<td>Start of the sequence to be used</td>
<td>Any integer value</td>
<td>0</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -send1<br>-send_asequence</td>
<td>integer</td>
<td>End of the sequence to be used</td>
<td>Any integer value</td>
<td>0</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -sreverse1<br>-sreverse_asequence</td>
<td>boolean</td>
<td>Reverse (if DNA)</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -sask1<br>-sask_asequence</td>
<td>boolean</td>
<td>Ask for begin/end/reverse</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -snucleotide1<br>-snucleotide_asequence</td>
<td>boolean</td>
<td>Sequence is nucleotide</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -sprotein1<br>-sprotein_asequence</td>
<td>boolean</td>
<td>Sequence is protein</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -slower1<br>-slower_asequence</td>
<td>boolean</td>
<td>Make lower case</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -supper1<br>-supper_asequence</td>
<td>boolean</td>
<td>Make upper case</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -scircular1<br>-scircular_asequence</td>
<td>boolean</td>
<td>Sequence is circular</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -squick1<br>-squick_asequence</td>
<td>boolean</td>
<td>Read id and sequence only</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -sformat1<br>-sformat_asequence</td>
<td>string</td>
<td>Input sequence format</td>
<td>Any string</td>
<td>&nbsp;</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -iquery1<br>-iquery_asequence</td>
<td>string</td>
<td>Input query fields or ID list</td>
<td>Any string</td>
<td>&nbsp;</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -ioffset1<br>-ioffset_asequence</td>
<td>integer</td>
<td>Input start position offset</td>
<td>Any integer value</td>
<td>0</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -sdbname1<br>-sdbname_asequence</td>
<td>string</td>
<td>Database name</td>
<td>Any string</td>
<td>&nbsp;</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -sid1<br>-sid_asequence</td>
<td>string</td>
<td>Entryname</td>
<td>Any string</td>
<td>&nbsp;</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -ufo1<br>-ufo_asequence</td>
<td>string</td>
<td>UFO features</td>
<td>Any string</td>
<td>&nbsp;</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -fformat1<br>-fformat_asequence</td>
<td>string</td>
<td>Features format</td>
<td>Any string</td>
<td>&nbsp;</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -fopenfile1<br>-fopenfile_asequence</td>
<td>string</td>
<td>Features file name</td>
<td>Any string</td>
<td>&nbsp;</td>
</tr>

<tr bgcolor="#FFFFCC">
<td align="left" colspan=5>"-bsequence" associated sequence qualifiers
</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -sbegin2<br>-sbegin_bsequence</td>
<td>integer</td>
<td>Start of the sequence to be used</td>
<td>Any integer value</td>
<td>0</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -send2<br>-send_bsequence</td>
<td>integer</td>
<td>End of the sequence to be used</td>
<td>Any integer value</td>
<td>0</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -sreverse2<br>-sreverse_bsequence</td>
<td>boolean</td>
<td>Reverse (if DNA)</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -sask2<br>-sask_bsequence</td>
<td>boolean</td>
<td>Ask for begin/end/reverse</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -snucleotide2<br>-snucleotide_bsequence</td>
<td>boolean</td>
<td>Sequence is nucleotide</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -sprotein2<br>-sprotein_bsequence</td>
<td>boolean</td>
<td>Sequence is protein</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -slower2<br>-slower_bsequence</td>
<td>boolean</td>
<td>Make lower case</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -supper2<br>-supper_bsequence</td>
<td>boolean</td>
<td>Make upper case</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -scircular2<br>-scircular_bsequence</td>
<td>boolean</td>
<td>Sequence is circular</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -squick2<br>-squick_bsequence</td>
<td>boolean</td>
<td>Read id and sequence only</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -sformat2<br>-sformat_bsequence</td>
<td>string</td>
<td>Input sequence format</td>
<td>Any string</td>
<td>&nbsp;</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -iquery2<br>-iquery_bsequence</td>
<td>string</td>
<td>Input query fields or ID list</td>
<td>Any string</td>
<td>&nbsp;</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -ioffset2<br>-ioffset_bsequence</td>
<td>integer</td>
<td>Input start position offset</td>
<td>Any integer value</td>
<td>0</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -sdbname2<br>-sdbname_bsequence</td>
<td>string</td>
<td>Database name</td>
<td>Any string</td>
<td>&nbsp;</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -sid2<br>-sid_bsequence</td>
<td>string</td>
<td>Entryname</td>
<td>Any string</td>
<td>&nbsp;</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -ufo2<br>-ufo_bsequence</td>
<td>string</td>
<td>UFO features</td>
<td>Any string</td>
<td>&nbsp;</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -fformat2<br>-fformat_bsequence</td>
<td>string</td>
<td>Features format</td>
<td>Any string</td>
<td>&nbsp;</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -fopenfile2<br>-fopenfile_bsequence</td>
<td>string</td>
<td>Features file name</td>
<td>Any string</td>
<td>&nbsp;</td>
</tr>

<tr bgcolor="#FFFFCC">
<td align="left" colspan=5>"-outfile" associated align qualifiers
</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -aformat3<br>-aformat_outfile</td>
<td>string</td>
<td>Alignment format</td>
<td>Any string</td>
<td>markx0</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -aextension3<br>-aextension_outfile</td>
<td>string</td>
<td>File name extension</td>
<td>Any string</td>
<td>&nbsp;</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -adirectory3<br>-adirectory_outfile</td>
<td>string</td>
<td>Output directory</td>
<td>Any string</td>
<td>&nbsp;</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -aname3<br>-aname_outfile</td>
<td>string</td>
<td>Base file name</td>
<td>Any string</td>
<td>&nbsp;</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -awidth3<br>-awidth_outfile</td>
<td>integer</td>
<td>Alignment width</td>
<td>Any integer value</td>
<td>0</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -aaccshow3<br>-aaccshow_outfile</td>
<td>boolean</td>
<td>Show accession number in the header</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -adesshow3<br>-adesshow_outfile</td>
<td>boolean</td>
<td>Show description in the header</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -ausashow3<br>-ausashow_outfile</td>
<td>boolean</td>
<td>Show the full USA in the alignment</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -aglobal3<br>-aglobal_outfile</td>
<td>boolean</td>
<td>Show the full sequence in alignment</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<th align="left" colspan=5>General qualifiers</th>
</tr>

<tr bgcolor="#FFFFCC">
<td> -auto</td>
<td>boolean</td>
<td>Turn off prompts</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -stdout</td>
<td>boolean</td>
<td>Write first file to standard output</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -filter</td>
<td>boolean</td>
<td>Read first file from standard input, write first file to standard output</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -options</td>
<td>boolean</td>
<td>Prompt for standard and additional values</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -debug</td>
<td>boolean</td>
<td>Write debug output to program.dbg</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -verbose</td>
<td>boolean</td>
<td>Report some/full command line options</td>
<td>Boolean value Yes/No</td>
<td>Y</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -help</td>
<td>boolean</td>
<td>Report command line options and exit. More information on associated and general qualifiers can be found with -help -verbose</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -warning</td>
<td>boolean</td>
<td>Report warnings</td>
<td>Boolean value Yes/No</td>
<td>Y</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -error</td>
<td>boolean</td>
<td>Report errors</td>
<td>Boolean value Yes/No</td>
<td>Y</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -fatal</td>
<td>boolean</td>
<td>Report fatal errors</td>
<td>Boolean value Yes/No</td>
<td>Y</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -die</td>
<td>boolean</td>
<td>Report dying program messages</td>
<td>Boolean value Yes/No</td>
<td>Y</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -version</td>
<td>boolean</td>
<td>Report version number and exit</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

</table>


<H2>
    Input file format
</H2>


<b>matcher</b> reads in two nucleotide or protein sequences.

<p>
<p>

The input is a standard EMBOSS sequence query (also known as a 'USA').

<p>
Major sequence database sources defined as standard in EMBOSS
installations include srs:embl, srs:uniprot and ensembl

<p>

Data can also be read from sequence output in any supported format
written by an EMBOSS or third-party application.

<p>
The input format can be specified by using the
command-line qualifier <tt>-sformat xxx</tt>, 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.

<p>

See:
<A href="http://emboss.sf.net/docs/themes/SequenceFormats.html">
http://emboss.sf.net/docs/themes/SequenceFormats.html</A>
for further information on sequence formats.

<p>


<a name="input.1"></a>
<h3>Input files for usage example </h3>

'tsw:hba_human' is a sequence entry in the example protein database 'tsw'
<p>
<p><h3>Database entry: tsw:hba_human</h3>
<table width="90%"><tr><td bgcolor="#FFCCFF">
<pre>
ID   HBA_HUMAN               Reviewed;         142 AA.
AC   P69905; P01922; Q1HDT5; Q3MIF5; Q53F97; Q96KF1; Q9NYR7; Q9UCM0;
DT   21-JUL-1986, integrated into UniProtKB/Swiss-Prot.
DT   23-JAN-2007, sequence version 2.
DT   13-JUN-2012, entry version 108.
DE   RecName: Full=Hemoglobin subunit alpha;
DE   AltName: Full=Alpha-globin;
DE   AltName: Full=Hemoglobin alpha chain;
GN   Name=HBA1;
GN   and
GN   Name=HBA2;
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] (HBA1).
RX   MEDLINE=81088339; PubMed=7448866; DOI=10.1016/0092-8674(80)90347-5;
RA   Michelson A.M., Orkin S.H.;
RT   "The 3' untranslated regions of the duplicated human alpha-globin
RT   genes are unexpectedly divergent.";
RL   Cell 22:371-377(1980).
RN   [2]
RP   NUCLEOTIDE SEQUENCE [MRNA] (HBA2).
RX   MEDLINE=80137531; PubMed=6244294;
RA   Wilson J.T., Wilson L.B., Reddy V.B., Cavallesco C., Ghosh P.K.,
RA   Deriel J.K., Forget B.G., Weissman S.M.;
RT   "Nucleotide sequence of the coding portion of human alpha globin
RT   messenger RNA.";
RL   J. Biol. Chem. 255:2807-2815(1980).
RN   [3]
RP   NUCLEOTIDE SEQUENCE [GENOMIC DNA] (HBA2).
RX   MEDLINE=81175088; PubMed=6452630; DOI=10.1073/pnas.77.12.7054;
RA   Liebhaber S.A., Goossens M.J., Kan Y.W.;
RT   "Cloning and complete nucleotide sequence of human 5'-alpha-globin
RT   gene.";
RL   Proc. Natl. Acad. Sci. U.S.A. 77:7054-7058(1980).
RN   [4]
RP   NUCLEOTIDE SEQUENCE [GENOMIC DNA].
RX   PubMed=6946451; DOI=10.1073/pnas.78.8.5041;
RA   Orkin S.H., Goff S.C., Hechtman R.L.;
RT   "Mutation in an intervening sequence splice junction in man.";
RL   Proc. Natl. Acad. Sci. U.S.A. 78:5041-5045(1981).
RN   [5]
RP   NUCLEOTIDE SEQUENCE [GENOMIC DNA], AND VARIANT LYS-32.
RX   MEDLINE=21303311; PubMed=11410421;
RA   Zhao Y., Xu X.;
RT   "Alpha2(CD31 AGG--&gt;AAG, Arg--&gt;Lys) causing non-deletional alpha-
RT   thalassemia in a Chinese family with HbH disease.";


<font color=red>  [Part of this file has been deleted for brevity]</font>

FT                                /FTId=VAR_002841.
FT   VARIANT     132    132       S -&gt; P (in Questembert; highly unstable;
FT                                causes alpha-thalassemia).
FT                                /FTId=VAR_002843.
FT   VARIANT     134    134       S -&gt; R (in Val de Marne; O(2) affinity
FT                                up).
FT                                /FTId=VAR_002844.
FT   VARIANT     136    136       V -&gt; E (in Pavie).
FT                                /FTId=VAR_002845.
FT   VARIANT     137    137       L -&gt; M (in Chicago).
FT                                /FTId=VAR_002846.
FT   VARIANT     137    137       L -&gt; P (in Bibba; unstable; causes alpha-
FT                                thalassemia).
FT                                /FTId=VAR_002847.
FT   VARIANT     137    137       L -&gt; R (in Toyama).
FT                                /FTId=VAR_035242.
FT   VARIANT     139    139       S -&gt; P (in Attleboro; O(2) affinity up).
FT                                /FTId=VAR_002848.
FT   VARIANT     140    140       K -&gt; E (in Hanamaki; O(2) affinity up).
FT                                /FTId=VAR_002849.
FT   VARIANT     140    140       K -&gt; T (in Tokoname; O(2) affinity up).
FT                                /FTId=VAR_002850.
FT   VARIANT     141    141       Y -&gt; H (in Rouen/Ethiopia; O(2) affinity
FT                                up).
FT                                /FTId=VAR_002851.
FT   VARIANT     142    142       R -&gt; C (in Nunobiki; O(2) affinity up).
FT                                /FTId=VAR_002852.
FT   VARIANT     142    142       R -&gt; H (in Suresnes; O(2) affinity up).
FT                                /FTId=VAR_002854.
FT   VARIANT     142    142       R -&gt; L (in Legnano; O(2) affinity up).
FT                                /FTId=VAR_002853.
FT   VARIANT     142    142       R -&gt; P (in Singapore).
FT                                /FTId=VAR_002855.
FT   CONFLICT     10     10       N -&gt; H (in Ref. 13; BAD97112).
FT   HELIX         5     16
FT   HELIX        17     21
FT   HELIX        22     36
FT   HELIX        38     43
FT   HELIX        54     72
FT   HELIX        74     76
FT   HELIX        77     80
FT   HELIX        82     90
FT   HELIX        97    113
FT   TURN        115    117
FT   HELIX       120    137
FT   TURN        138    140
SQ   SEQUENCE   142 AA;  15258 MW;  15E13666573BBBAE CRC64;
     MVLSPADKTN VKAAWGKVGA HAGEYGAEAL ERMFLSFPTT KTYFPHFDLS HGSAQVKGHG
     KKVADALTNA VAHVDDMPNA LSALSDLHAH KLRVDPVNFK LLSHCLLVTL AAHLPAEFTP
     AVHASLDKFL ASVSTVLTSK YR
//
</pre>
</td></tr></table><p>
<p><h3>Database entry: tsw:hbb_human</h3>
<table width="90%"><tr><td bgcolor="#FFCCFF">
<pre>
ID   HBB_HUMAN               Reviewed;         147 AA.
AC   P68871; A4GX73; B2ZUE0; P02023; Q13852; Q14481; Q14510; Q45KT0;
AC   Q549N7; Q6FI08; Q6R7N2; Q8IZI1; Q9BX96; Q9UCD6; Q9UCP8; Q9UCP9;
DT   21-JUL-1986, integrated into UniProtKB/Swiss-Prot.
DT   23-JAN-2007, sequence version 2.
DT   13-JUN-2012, entry version 108.
DE   RecName: Full=Hemoglobin subunit beta;
DE   AltName: Full=Beta-globin;
DE   AltName: Full=Hemoglobin beta chain;
DE   Contains:
DE     RecName: Full=LVV-hemorphin-7;
GN   Name=HBB;
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=77126403; PubMed=1019344;
RA   Marotta C., Forget B., Cohen-Solal M., Weissman S.M.;
RT   "Nucleotide sequence analysis of coding and noncoding regions of human
RT   beta-globin mRNA.";
RL   Prog. Nucleic Acid Res. Mol. Biol. 19:165-175(1976).
RN   [2]
RP   NUCLEOTIDE SEQUENCE [GENOMIC DNA].
RX   MEDLINE=81064667; PubMed=6254664; DOI=10.1016/0092-8674(80)90428-6;
RA   Lawn R.M., Efstratiadis A., O'Connell C., Maniatis T.;
RT   "The nucleotide sequence of the human beta-globin gene.";
RL   Cell 21:647-651(1980).
RN   [3]
RP   NUCLEOTIDE SEQUENCE [GENOMIC DNA], AND VARIANT LYS-7.
RX   PubMed=16175509; DOI=10.1086/491748;
RA   Wood E.T., Stover D.A., Slatkin M., Nachman M.W., Hammer M.F.;
RT   "The beta-globin recombinational hotspot reduces the effects of strong
RT   selection around HbC, a recently arisen mutation providing resistance
RT   to malaria.";
RL   Am. J. Hum. Genet. 77:637-642(2005).
RN   [4]
RP   NUCLEOTIDE SEQUENCE [GENOMIC DNA].
RA   Lu L., Hu Z.H., Du C.S., Fu Y.S.;
RT   "DNA sequence of the human beta-globin gene isolated from a healthy
RT   Chinese.";
RL   Submitted (JUN-1997) to the EMBL/GenBank/DDBJ databases.
RN   [5]
RP   NUCLEOTIDE SEQUENCE [GENOMIC DNA], AND VARIANT ARG-113.
RA   Cabeda J.M., Correia C., Estevinho A., Cardoso C., Amorim M.L.,
RA   Cleto E., Vale L., Coimbra E., Pinho L., Justica B.;
RT   "Unexpected patterns of globin mutations in thalassemia patients from
RT   north of Portugal.";


<font color=red>  [Part of this file has been deleted for brevity]</font>

FT   VARIANT     141    141       A -&gt; V (in Puttelange; polycythemia; O(2)
FT                                affinity up).
FT                                /FTId=VAR_003082.
FT   VARIANT     142    142       L -&gt; R (in Olmsted; unstable).
FT                                /FTId=VAR_003083.
FT   VARIANT     143    143       A -&gt; D (in Ohio; O(2) affinity up).
FT                                /FTId=VAR_003084.
FT   VARIANT     144    144       H -&gt; D (in Rancho Mirage).
FT                                /FTId=VAR_003085.
FT   VARIANT     144    144       H -&gt; P (in Syracuse; O(2) affinity up).
FT                                /FTId=VAR_003087.
FT   VARIANT     144    144       H -&gt; Q (in Little Rock; O(2) affinity
FT                                up).
FT                                /FTId=VAR_003086.
FT   VARIANT     144    144       H -&gt; R (in Abruzzo; O(2) affinity up).
FT                                /FTId=VAR_003088.
FT   VARIANT     145    145       K -&gt; E (in Mito; O(2) affinity up).
FT                                /FTId=VAR_003089.
FT   VARIANT     146    146       Y -&gt; C (in Rainier; O(2) affinity up).
FT                                /FTId=VAR_003090.
FT   VARIANT     146    146       Y -&gt; H (in Bethesda; O(2) affinity up).
FT                                /FTId=VAR_003091.
FT   VARIANT     147    147       H -&gt; D (in Hiroshima; O(2) affinity up).
FT                                /FTId=VAR_003092.
FT   VARIANT     147    147       H -&gt; L (in Cowtown; O(2) affinity up).
FT                                /FTId=VAR_003093.
FT   VARIANT     147    147       H -&gt; P (in York; O(2) affinity up).
FT                                /FTId=VAR_003094.
FT   VARIANT     147    147       H -&gt; Q (in Kodaira; O(2) affinity up).
FT                                /FTId=VAR_003095.
FT   CONFLICT     26     26       Missing (in Ref. 15; ACD39349).
FT   CONFLICT     42     42       F -&gt; L (in Ref. 13; AAR96398).
FT   HELIX         6     16
FT   TURN         21     23
FT   HELIX        24     35
FT   HELIX        37     42
FT   HELIX        44     46
FT   HELIX        52     57
FT   HELIX        59     77
FT   TURN         78     80
FT   HELIX        82     94
FT   TURN         95     97
FT   HELIX       102    119
FT   HELIX       120    122
FT   HELIX       125    142
FT   HELIX       144    146
SQ   SEQUENCE   147 AA;  15998 MW;  A31F6D621C6556A1 CRC64;
     MVHLTPEEKS AVTALWGKVN VDEVGGEALG RLLVVYPWTQ RFFESFGDLS TPDAVMGNPK
     VKAHGKKVLG AFSDGLAHLD NLKGTFATLS ELHCDKLHVD PENFRLLGNV LVCVLAHHFG
     KEFTPPVQAA YQKVVAGVAN ALAHKYH
//
</pre>
</td></tr></table><p>

<H2>
    Output file format
</H2>


<p>

The output is a standard EMBOSS alignment file. 

<p>

The results can be output in one of several styles by using the
command-line qualifier <tt>-aformat xxx</tt>, where 'xxx' is replaced by
the name of the required format.  Some of the alignment formats can cope
with an unlimited number of sequences, while others are only for pairs
of sequences.  

<p>

The available multiple alignment format names are: multiple, simple,
fasta, msf, clustal, mega, meganon, nexus,, nexusnon, phylip,
phylipnon, selex, treecon, tcoffee, debug, srs.

<p>

The available pairwise alignment format names are: pair, markx0, markx1,
markx2, markx3, markx10, match, sam, bam, score, srspair

<p>

See:
<A href="http://emboss.sf.net/docs/themes/AlignFormats.html">
http://emboss.sf.net/docs/themes/AlignFormats.html</A>
for further information on alignment formats.

<p>
 

<p>


<a name="output.1"></a>
<h3>Output files for usage example </h3>
<p><h3>File: hba_human.matcher</h3>
<table width="90%"><tr><td bgcolor="#CCFFCC">
<pre>
########################################
# Program: matcher
# Rundate: Mon 15 Jul 2013 12:00:00
# Commandline: matcher
#    [-asequence] tsw:hba_human
#    [-bsequence] tsw:hbb_human
# Align_format: markx0
# Report_file: hba_human.matcher
########################################

#=======================================
#
# Aligned_sequences: 2
# 1: HBA_HUMAN
# 2: HBB_HUMAN
# Matrix: EBLOSUM62
# Gap_penalty: 14
# Extend_penalty: 4
#
# Length: 145
# Identity:      63/145 (43.4%)
# Similarity:    88/145 (60.7%)
# Gaps:           8/145 ( 5.5%)
# Score: 264
# 
#
#=======================================

             10        20        30        40         50 
HBA_HU LSPADKTNVKAAWGKVGAHAGEYGAEALERMFLSFPTTKTYFPHF-DLSH
       :.: .:. : : ::::  .  : : ::: :. . .: :. .:  : ::: 
HBB_HU LTPEEKSAVTALWGKV--NVDEVGGEALGRLLVVYPWTQRFFESFGDLST
            10          20        30        40        50 

                   60        70        80        90      
HBA_HU -----GSAQVKGHGKKVADALTNAVAHVDDMPNALSALSDLHAHKLRVDP
            :. .:: :::::  : .. .::.:..    . ::.::  :: :::
HBB_HU PDAVMGNPKVKAHGKKVLGAFSDGLAHLDNLKGTFATLSELHCDKLHVDP
              60        70        80        90       100 

        100       110       120       130       140 
HBA_HU VNFKLLSHCLLVTLAAHLPAEFTPAVHASLDKFLASVSTVLTSKY
        ::.:: . :.  :: :   :::: : :.  : .: :.  :  ::
HBB_HU ENFRLLGNVLVCVLAHHFGKEFTPPVQAAYQKVVAGVANALAHKY
             110       120       130       140      


#---------------------------------------
#---------------------------------------
</pre>
</td></tr></table><p>

<a name="output.2"></a>
<h3>Output files for usage example 2</h3>
<p><h3>File: hba_human.matcher</h3>
<table width="90%"><tr><td bgcolor="#CCFFCC">
<pre>
########################################
# Program: matcher
# Rundate: Mon 15 Jul 2013 12:00:00
# Commandline: matcher
#    [-asequence] tsw:hba_human
#    [-bsequence] tsw:hbb_human
#    -alternatives 10
# Align_format: markx0
# Report_file: hba_human.matcher
########################################

#=======================================
#
# Aligned_sequences: 2
# 1: HBA_HUMAN
# 2: HBB_HUMAN
# Matrix: EBLOSUM62
# Gap_penalty: 14
# Extend_penalty: 4
#
# Length: 145
# Identity:      63/145 (43.4%)
# Similarity:    88/145 (60.7%)
# Gaps:           8/145 ( 5.5%)
# Score: 264
# 
#
#=======================================

             10        20        30        40         50 
HBA_HU LSPADKTNVKAAWGKVGAHAGEYGAEALERMFLSFPTTKTYFPHF-DLSH
       :.: .:. : : ::::  .  : : ::: :. . .: :. .:  : ::: 
HBB_HU LTPEEKSAVTALWGKV--NVDEVGGEALGRLLVVYPWTQRFFESFGDLST
            10          20        30        40        50 

                   60        70        80        90      
HBA_HU -----GSAQVKGHGKKVADALTNAVAHVDDMPNALSALSDLHAHKLRVDP
            :. .:: :::::  : .. .::.:..    . ::.::  :: :::
HBB_HU PDAVMGNPKVKAHGKKVLGAFSDGLAHLDNLKGTFATLSELHCDKLHVDP
              60        70        80        90       100 

        100       110       120       130       140 
HBA_HU VNFKLLSHCLLVTLAAHLPAEFTPAVHASLDKFLASVSTVLTSKY
        ::.:: . :.  :: :   :::: : :.  : .: :.  :  ::
HBB_HU ENFRLLGNVLVCVLAHHFGKEFTPPVQAAYQKVVAGVANALAHKY
             110       120       130       140      


#=======================================
#


<font color=red>  [Part of this file has been deleted for brevity]</font>

#
# Aligned_sequences: 2
# 1: HBA_HUMAN
# 2: HBB_HUMAN
# Matrix: EBLOSUM62
# Gap_penalty: 14
# Extend_penalty: 4
#
# Length: 12
# Identity:       6/12 (50.0%)
# Similarity:     6/12 (50.0%)
# Gaps:           0/12 ( 0.0%)
# Score: 20
# 
#
#=======================================

            120    
HBA_HU HLPAEFTPAVHA
       ::  :   :: :
HBB_HU HLTPEEKSAVTA
             10    


#=======================================
#
# Aligned_sequences: 2
# 1: HBA_HUMAN
# 2: HBB_HUMAN
# Matrix: EBLOSUM62
# Gap_penalty: 14
# Extend_penalty: 4
#
# Length: 21
# Identity:       6/21 (28.6%)
# Similarity:     7/21 (33.3%)
# Gaps:           0/21 ( 0.0%)
# Score: 19
# 
#
#=======================================

           10        20     
HBA_HU PADKTNVKAAWGKVGAHAGEY
       :      :   :   : : .:
HBB_HU PVQAAYQKVVAGVANALAHKY
         130       140      


#---------------------------------------
#---------------------------------------
</pre>
</td></tr></table><p>


<H2>
    Data files
</H2>


For protein sequences EBLOSUM62 is used for the substitution matrix.
For nucleotide sequence, EDNAFULL is used.

<p>

EMBOSS data files are distributed with the application and stored
in the standard EMBOSS data directory, which is defined
by EMBOSS environment variable EMBOSS_DATA.

<p>

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".

<p>
The directories are searched in the following order:

<ul>
   <li> . (your current directory)
   <li> .embossdata (under your current directory)
   <li> ~/ (your home directory)
   <li> ~/.embossdata
</ul>

<H2>
    Notes
</H2>

<p><b>matcher</b> is rigorous but also very slow. The advantage of <b>matcher</b> over <b>water</b> (which is also rigorous) is that it uses far less memory, so you are much less likely to run out of memory when aligning large sequences.</p>
<p><b>matcher</b> reports a specified number of alignments between the two sequences. <b>water</b> in contrast will only report only the single (optimal) match. The default number of alignments output is 1, but can be increased to (for example) the 10 best alignments by using the <tt>-alternatives 10</tt> command-line qualifier. In some cases, for example multidomain proteins or cDNA and genomic DNA comparisons, there may be many interesting and significant alignments.</p>

<p><b>matcher</b> will not produce an alignment that is guaranteed to be optimal in the same way that <b>water</b> does, which implements the Needleman & Wunsch algorith.  <b>water</b> will generate the single, optimal local alignment and uses memory in the order of the product of the lengths of the sequences to be aligned. If you require an optimal alignment you should use <b>water</b>. If you run out of memory or want several possible good alignments, use <b>matcher</b>.</p>



<H2>
    References
</H2>


<ol>
<li>
X. Huang and W. Miller (1991) Adv. Appl. Math. 12:373-381
<li>
M.  S.  Waterman and M.  Eggert (J. Mol.  Biol.  197:723-728).  
</ol>

<H2>
    Warnings
</H2>

None.

<H2>
    Diagnostic Error Messages
</H2>

None.

<H2>
    Exit status
</H2>

   0 upon successful completion. 

<H2>
    Known bugs
</H2>

None.

<h2><a name="See also">See also</a></h2>
<table border cellpadding=4 bgcolor="#FFFFF0">
<tr><th>Program name</th>
<th>Description</th></tr>
<tr>
<td><a href="seqmatchall.html">seqmatchall</a></td>
<td>All-against-all word comparison of a sequence set</td>
</tr>

<tr>
<td><a href="supermatcher.html">supermatcher</a></td>
<td>Calculate approximate local pair-wise alignments of larger sequences</td>
</tr>

<tr>
<td><a href="water.html">water</a></td>
<td>Smith-Waterman local alignment of sequences</td>
</tr>

<tr>
<td><a href="wordfinder.html">wordfinder</a></td>
<td>Match large sequences against one or more other sequences</td>
</tr>

<tr>
<td><a href="wordmatch.html">wordmatch</a></td>
<td>Find regions of identity (exact matches) of two sequences</td>
</tr>

</table>

<p>

<b>water</b> will give a single best rigorous local alignment.  It will
use memory of the order of the product of the lengths of the sequences
to be aligned.  If you wish the 'best' local alignment you should use
<b>water</b>.  If you run out of memory or want several possible good
alignments, use <b>matcher</b>. 

<H2>
    Author(s)
</H2>


This program was originally written by Bill Pearson as part of the
FASTA package under the name 'lalign'.
<p>

This application was modified for inclusion in EMBOSS by 
Ian Longden formerly at:
<br>
Sanger Institute, Wellcome Trust Genome Campus, Hinxton,
Cambridge, CB10 1SA, UK.                      

<p>
Please report all bugs to the EMBOSS bug team (emboss-bug&nbsp;&copy;&nbsp;emboss.open-bio.org) not to the original author.

<H2>
    History
</H2>

 Completed 11th May 1999.

<H2>
    Target users
</H2>

This program is intended to be used by everyone and everything, from naive users to embedded scripts.


<H2>
    Comments
</H2>
None

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