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<HTML>

<HEAD>
  <TITLE>
  EMBOSS: octanol
  </TITLE>
</HEAD>
<BODY BGCOLOR="#FFFFFF" text="#000000">

<table align=center border=0 cellspacing=0 cellpadding=0>
<tr><td valign=top>
<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>
</td>
<td align=left valign=middle>
<b><font size="+6">
octanol
</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>
Draw a White-Wimley protein hydropathy plot

<H2>
    Description
</H2>



<p><b>octanol</b> draws a hydropathy plot for an input protein sequence.  This plots the free energy difference calculated for windows over the protein sequence, of the residues in water compared to two lipid environments: i. Octanol (equivalent to inside a lipid bilayer). ii. The interface of a synthetic lipid bilayer. Free energy differences are calculated for each position in a window of 19 residues by default, about the size of a membrane spanning alpha-helix. The energy values for each residue are summed to get two values for each window.  By default, the value plotted is the free energy difference between the interface and octanol environments, which is the best indicator of the location of probable transmembrane regions.  Command line options allow the display of the octanol and interface values, or hiding the difference values. The experimental free energy values for the water-interface and water-octanol transitions are read from a datafile (<tt>Ewhite-wimley.dat</tt>)</p>

<H2>
    Usage
</H2>
Here is a sample session with <b>octanol</b>
<p>

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

% <b>octanol </b>
Draw a White-Wimley protein hydropathy plot
Input protein sequence: <b>tsw:opsd_human</b>
Graph type [x11]: <b>ps</b>

Created octanol.ps

</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>


<H2>
    Command line arguments
</H2>
<table CELLSPACING=0 CELLPADDING=3 BGCOLOR="#f5f5ff" ><tr><td>
<pre>
Draw a White-Wimley protein hydropathy plot
Version: EMBOSS:6.6.0.0

   Standard (Mandatory) qualifiers:
  [-sequence]          sequence   Protein sequence filename and optional
                                  format, or reference (input USA)
  [-graph]             xygraph    [$EMBOSS_GRAPHICS value, or x11] Graph type
                                  (ps, hpgl, hp7470, hp7580, meta, cps, x11,
                                  tek, tekt, none, data, xterm, png, gif, pdf,
                                  svg)

   Additional (Optional) qualifiers:
   -datafile           datafile   [Ewhite-wimley.dat] White-Wimley data file
   -width              integer    [19] Window size (Integer from 1 to 200)
   -plotoctanol        boolean    [N] Display the octanol plot
   -plotinterface      boolean    [N] Display the interface plot
   -[no]plotdifference boolean    [Y] Display the difference plot

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

   "-sequence" 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

   "-graph" associated qualifiers
   -gprompt2           boolean    Graph prompting
   -gdesc2             string     Graph description
   -gtitle2            string     Graph title
   -gsubtitle2         string     Graph subtitle
   -gxtitle2           string     Graph x axis title
   -gytitle2           string     Graph y axis title
   -goutfile2          string     Output file for non interactive displays
   -gdirectory2        string     Output directory

   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>[-sequence]<br>(Parameter 1)</td>
<td>sequence</td>
<td>Protein sequence filename and optional format, or reference (input USA)</td>
<td>Readable sequence</td>
<td><b>Required</b></td>
</tr>

<tr bgcolor="#FFFFCC">
<td>[-graph]<br>(Parameter 2)</td>
<td>xygraph</td>
<td>Graph type</td>
<td>EMBOSS has a list of known devices, including ps, hpgl, hp7470, hp7580, meta, cps, x11, tek, tekt, none, data, xterm, png, gif, pdf, svg</td>
<td><i>EMBOSS_GRAPHICS</i> value, or x11</td>
</tr>

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

<tr bgcolor="#FFFFCC">
<td>-datafile</td>
<td>datafile</td>
<td>White-Wimley data file</td>
<td>Data file</td>
<td>Ewhite-wimley.dat</td>
</tr>

<tr bgcolor="#FFFFCC">
<td>-width</td>
<td>integer</td>
<td>Window size</td>
<td>Integer from 1 to 200</td>
<td>19</td>
</tr>

<tr bgcolor="#FFFFCC">
<td>-plotoctanol</td>
<td>boolean</td>
<td>Display the octanol plot</td>
<td>Boolean value Yes/No</td>
<td>No</td>
</tr>

<tr bgcolor="#FFFFCC">
<td>-plotinterface</td>
<td>boolean</td>
<td>Display the interface plot</td>
<td>Boolean value Yes/No</td>
<td>No</td>
</tr>

<tr bgcolor="#FFFFCC">
<td>-[no]plotdifference</td>
<td>boolean</td>
<td>Display the difference plot</td>
<td>Boolean value Yes/No</td>
<td>Yes</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>"-sequence" associated sequence qualifiers
</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -sbegin1<br>-sbegin_sequence</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_sequence</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_sequence</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_sequence</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_sequence</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_sequence</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_sequence</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_sequence</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_sequence</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_sequence</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_sequence</td>
<td>string</td>
<td>Input sequence format</td>
<td>Any string</td>
<td>&nbsp;</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -iquery1<br>-iquery_sequence</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_sequence</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_sequence</td>
<td>string</td>
<td>Database name</td>
<td>Any string</td>
<td>&nbsp;</td>
</tr>

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

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

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

<tr bgcolor="#FFFFCC">
<td> -fopenfile1<br>-fopenfile_sequence</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>"-graph" associated xygraph qualifiers
</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -gprompt2<br>-gprompt_graph</td>
<td>boolean</td>
<td>Graph prompting</td>
<td>Boolean value Yes/No</td>
<td>N</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -gdesc2<br>-gdesc_graph</td>
<td>string</td>
<td>Graph description</td>
<td>Any string</td>
<td>&nbsp;</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -gtitle2<br>-gtitle_graph</td>
<td>string</td>
<td>Graph title</td>
<td>Any string</td>
<td>White-Wimley Plot</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -gsubtitle2<br>-gsubtitle_graph</td>
<td>string</td>
<td>Graph subtitle</td>
<td>Any string</td>
<td>&nbsp;</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -gxtitle2<br>-gxtitle_graph</td>
<td>string</td>
<td>Graph x axis title</td>
<td>Any string</td>
<td>&nbsp;</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -gytitle2<br>-gytitle_graph</td>
<td>string</td>
<td>Graph y axis title</td>
<td>Any string</td>
<td>Total Free Energy (Kcal/mol)</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -goutfile2<br>-goutfile_graph</td>
<td>string</td>
<td>Output file for non interactive displays</td>
<td>Any string</td>
<td>&nbsp;</td>
</tr>

<tr bgcolor="#FFFFCC">
<td> -gdirectory2<br>-gdirectory_graph</td>
<td>string</td>
<td>Output directory</td>
<td>Any string</td>
<td>&nbsp;</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>octanol</b> reads a single protein sequence.
<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:opsd_human' is a sequence entry in the example protein database 'tsw'
<p>
<p><h3>Database entry: tsw:opsd_human</h3>
<table width="90%"><tr><td bgcolor="#FFCCFF">
<pre>
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   13-JUN-2012, entry version 145.
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.";


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

FT                                /FTId=VAR_004816.
FT   VARIANT     209    209       V -&gt; M (effect not known).
FT                                /FTId=VAR_004817.
FT   VARIANT     211    211       H -&gt; P (in RP4; dbSNP:rs28933993).
FT                                /FTId=VAR_004818.
FT   VARIANT     211    211       H -&gt; R (in RP4).
FT                                /FTId=VAR_004819.
FT   VARIANT     216    216       M -&gt; K (in RP4).
FT                                /FTId=VAR_004820.
FT   VARIANT     220    220       F -&gt; C (in RP4).
FT                                /FTId=VAR_004821.
FT   VARIANT     222    222       C -&gt; 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 -&gt; L (in RP4).
FT                                /FTId=VAR_004825.
FT   VARIANT     267    267       P -&gt; R (in RP4).
FT                                /FTId=VAR_004826.
FT   VARIANT     292    292       A -&gt; E (in CSNBAD1).
FT                                /FTId=VAR_004827.
FT   VARIANT     296    296       K -&gt; E (in RP4; dbSNP:rs29001653).
FT                                /FTId=VAR_004828.
FT   VARIANT     297    297       S -&gt; R (in RP4).
FT                                /FTId=VAR_004829.
FT   VARIANT     342    342       T -&gt; M (in RP4).
FT                                /FTId=VAR_004830.
FT   VARIANT     345    345       V -&gt; L (in RP4).
FT                                /FTId=VAR_004831.
FT   VARIANT     345    345       V -&gt; M (in RP4).
FT                                /FTId=VAR_004832.
FT   VARIANT     347    347       P -&gt; A (in RP4).
FT                                /FTId=VAR_004833.
FT   VARIANT     347    347       P -&gt; L (in RP4; common variant).
FT                                /FTId=VAR_004834.
FT   VARIANT     347    347       P -&gt; Q (in RP4).
FT                                /FTId=VAR_004835.
FT   VARIANT     347    347       P -&gt; R (in RP4; dbSNP:rs29001566).
FT                                /FTId=VAR_004836.
FT   VARIANT     347    347       P -&gt; 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
//
</pre>
</td></tr></table><p>

<H2>
    Output file format
</H2>

<p>

The output is to the specified graphics device.

<p>

The results can be output in one of several formats by using the
command-line qualifier <b>-graph xxx</b>, where 'xxx' is replaced by
the name of the required device. Support depends on the availability
of third-party software packages.

<p>
The device names that output to a file are:
ps (postscript), cps (colourps), png, gif, pdf, svg, hpgl, hp7470,
hp7580, das, data.

<p> The other available device names are: meta, x11 (xwindows), tek
(tek4107t), tekt (tektronix), xterm, text.

<p>
Output can be turned off by specifying none (null).

<p>

See:
<A href="http://emboss.sf.net/docs/themes/GraphicsDevices.html">
http://emboss.sf.net/docs/themes/GraphicsDevices.html</A>
for further information on supported devices.

<p>

<b>octanol</b> draws a graph showing the
free energy calcuated over a sliding window.

<p>


<a name="output.1"></a>
<h3>Output files for usage example </h3>
<p><h3>Graphics File: octanol.ps</h3>
<p><img src="octanol.1.octanol.gif" alt="[octanol results]">

<p>

The line on the default plot is the difference between the interface
and octanol free energy calculations. Command line options allow the
display of the interface and octanol values, or hiding the difference
values.

<p>

In the example, the human opsin protein has 7 transmembrane
regions: 37-61, 74-98, 114-133, 153-176, 203-230, 253-276 and 285-309.
Each is about 20 residues in length, which is also the gap between tick
marks on the sequence axis. All have energetic preferences for being
in the lipid (octanol) enviroment - shown as being above the zero
line - or have at least no clear preference.

<p>

Running octanol with all three plots:

<pre>

% octanol -interface -octanol
Input sequence: tsw:opsd_human
   Graph type [x11]: 

</pre>

gives a graph with the water-interface and water-octanol plots.

<p>

For those regions where the diference plot is close to zero, both the
other two plots are above the line, showing a preference for either
the octanol or the interface membrane environments rather than water.



<H2>
    Data files
</H2>

File <b>Ewhite-wimley.dat</b> contains the experimental free energy values
for the water-interface and water-octanol transitions.

<p>
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.

<p>

To see the available EMBOSS data files, run:
<p>
<pre>
% embossdata -showall
</pre>
<p>
To fetch one of the data files (for example 'Exxx.dat') into your
current directory for you to inspect or modify, run:

<pre>

% embossdata -fetch -file Exxx.dat

</pre>
<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>
<p>

<H2>
    Notes
</H2>

<p>Protein sequences that form transmembrane regions are assumed to have a thermodynamic preference for a hydrophobic environment (inside the membrane lipid bilayer), rather than an aqueous environment in water.  The free energy change for each amino acid residue between a lipid and a water environment can be measured experimentally, and the values for peptides can be shown to be additive (White and Wimley 1999).</p>

<p>For each amino acid residue in the protein, the free energy difference of the residue in lipid and water environments is measured in two ways.  The first is the free energy difference between the protein in water and the protein associated with the interface (glycerol group) of a POPC (palmitoyloleoylphosphocholine) bilayer.  The second is the free energy difference of the protein in water and the protein in octanol, equivalent to the environment inside a lipid bilayer.</p>

<p>Residues which can be buried inside a lipid bilayer must be in a region of the peptide where most residues show a free energy difference in favour of being in an octanol environment or at least being in the lipid/water interface region.  White and Wimley (1999) showed that a sliding window of either free energy difference will indicate the location of probable transmembrane regions, but that the best indicator is the difference between the two values, which is the free energy difference between the interface and octanol environments.</p>





<H2>
    References
</H2>

<ol>

<li>
White S.H. and Wimley W.C. (1999)
"Membrane protein folding and stability: physical principles"
Ann. Rev.Biophys. Biomol. Struct. 28:319-365.

</ol>

<H2>
    Warnings
</H2>

None.

<H2>
    Diagnostic Error Messages
</H2>

None.

<H2>
    Exit status
</H2>

It always exits with status 0.

<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="charge.html">charge</a></td>
<td>Draw a protein charge plot</td>
</tr>

<tr>
<td><a href="hmoment.html">hmoment</a></td>
<td>Calculate and plot hydrophobic moment for protein sequence(s)</td>
</tr>

<tr>
<td><a href="iep.html">iep</a></td>
<td>Calculate the isoelectric point of proteins</td>
</tr>

<tr>
<td><a href="pepinfo.html">pepinfo</a></td>
<td>Plot amino acid properties of a protein sequence in parallel</td>
</tr>

<tr>
<td><a href="pepstats.html">pepstats</a></td>
<td>Calculate statistics of protein properties</td>
</tr>

<tr>
<td><a href="pepwindow.html">pepwindow</a></td>
<td>Draw a hydropathy plot for a protein sequence</td>
</tr>

<tr>
<td><a href="pepwindowall.html">pepwindowall</a></td>
<td>Draw Kyte-Doolittle hydropathy plot for a protein alignment</td>
</tr>

</table>


<H2>
    Author(s)
</H2>


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>



<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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