src/hg/makeDb/trackDb/human/encodeEgaspUpdate.html 8c2f7318d8d821de9b2a25750586a94ab5e8c1bb

8c2f7318d8d821de9b2a25750586a94ab5e8c1bb
lrnassar
  Fri Nov 15 18:50:19 2024 -0800
Giving the UI link cronjob some love by fixing all the 301 redirects. These are the bulk of the items listed on the cron. No RM.

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 <H2>Description</H2>
 <P>
 This track shows updated versions of gene predictions submitted for the 
 ENCODE Gene Annotation Assessment Project 
 (<A HREF="https://genome.crg.es/gencode/workshop2005.html"
 TARGET=_blank>EGASP</A>) Gene Prediction Workshop 2005.
 The following gene predictions are included:
 <UL>
 <LI>
 <A HREF="http://augustus.gobics.de/" TARGET=_blank>Augustus</A></LI>
 <LI> Exogean</LI>
 <LI>
 <A HREF="http://www.softberry.com/berry.phtml?topic=index&group=programs&subgroup=gfind"
 TARGET=_blank>FGenesh++</A></LI>
 <LI>
 <A HREF="https://genome.crg.es/software/geneid/index.html" 
 TARGET=_blank>GeneID</A>-U12 </LI>
 <LI>
-<A HREF="http://www.cbcb.umd.edu/software/jigsaw/" TARGET=_blank>Jigsaw</A></LI>
+<A HREF="https://www.cbcb.umd.edu/software/jigsaw/" TARGET=_blank>Jigsaw</A></LI>
 <LI>
 <A HREF="https://genome.crg.es/software/sgp2/index.html" 
 TARGET=_blank>SGP2</A>-U12</LI>
 <LI>
 <A HREF="http://www.pseudogenes.org" TARGET=_blank>Yale pseudogenes</A></LI>
 </UL>
 The original EGASP submissions are displayed in the companion tracks, 
 EGASP Full and EGASP Partial.</P>
 
 <H2>Display Conventions and Configuration</H2>
 <P>
 Data for each gene prediction method within this composite annotation track 
 are displayed in separate subtracks. See the top of the track description page 
 for a complete list of the subtracks available for this annotation. To display
 only selected subtracks, uncheck the boxes next to the tracks you wish to
 hide.  
 <P>
 The individual subtracks within this annotation follow the display conventions 
 for <A HREF="../goldenPath/help/hgTracksHelp.html#GeneDisplay">gene prediction
 tracks</A>. Display characteristics specific to individual subtracks are 
 described in the Methods section. The track description page offers the option 
 to color and label codons in a zoomed-in display of the subtracks to facilitate 
 validation and comparison of gene predictions. To enable this feature, select 
 the <em>genomic codons</em> option from the &quot;Color track by codons&quot;
 menu. Click the
 <A HREF="../goldenPath/help/hgCodonColoring.html">Help on codon coloring</A>
 link for more information about this feature. </P>
 <P>
 Color differences among the subtracks are arbitrary. They provide a
 visual cue for distinguishing the different gene prediction methods.</P>
 
 <H2>Methods</H2>
 
 <H3>Augustus</H3>
 <P>
 Augustus uses a generalized hidden Markov model (GHMM) that models 
 coding and non-coding sequence, splice sites, the branch point region, 
 the translation start and end, and the lengths of exons and introns. 
 This version has been trained on a set of 1284 human genes.
 The track contains four sets of predictions: <em>ab initio</em>,
 EST and protein-based, mouse homology-based, and those using
 EST/protein and mouse homology evidence as additional input to Augustus
 for the predictions.</P>
 <P>
 The EST and protein evidence was generated by aligning sequences from the dbEST 
 and nr databases to the ENCODE region using wublastn and wublastx.
 The resulting alignments were used to generate hints about putative splice 
 sites, exons, coding regions, introns, translation start and 
 translation stop.</P>
 <P>
 The mouse homology evidence was generated by aligning pairs of human and
 mouse genomic sequences using the program 
 <A HREF="http://dialign.gobics.de/chaos-dialign-submission"
 TARGET=_blank>DIALIGN</A>. Regions conserved at the peptide level were used to 
 generate hints about coding regions.</P>
 
 <H3>Exogean</H3>
 <P>
 Exogean produces alternative transcripts by combining mRNA and cross-species 
 sequence alignments using heuristic rules. The program implements a generic 
 framework based on directed acyclic colored multigraphs (DACMs). In Exogean, 
 DACM nodes represent biological objects (mRNA or protein HSPs/transcripts) and
 multiple edges between nodes represent known relationships between these 
 objects derived from human expertise. Exogean DACMs are succesively built and 
 reduced, leading to increasingly complex objects. This process
 enables the production of alternative transcripts from initial HSPs.</P>
 
 <H3>FGenesh++</H3>
 <P>
 FGenesh++ predictions are based on hidden Markov models and protein similarity to
 the NR database.  For more information, see the reference below.
 
 <H3>GeneID-U12</H3>
 <P>
 The GeneID program predicts genes in anonymous genomic sequences 
 designed with a hierarchical structure.
 In the first step, splice sites, start and stop codons are predicted and scored 
 along the sequence using position weight arrays (PWAs).
 Next, exons are built from the sites. Exons are scored as the sum of the scores 
 of the defining sites plus the the log-likelihood ratio of a Markov model for 
 coding DNA.
 Finally, the gene structure is assembled from the set of predicted exons, 
 maximizing the sum of the scores of the assembled exons.
 The modified version of GeneID used to generate the predictions in this track 
 incorporates models for U12-dependent splice signals in addition to U2 splice 
 signals.</P>
 <P>
 The GeneID subtrack shows all GeneID genes. Only U12 introns
 and their flanking exons are displayed in the GeneID U12 subtrack.
 Exons flanking predicted U12-dependent introns are assigned a type
 attribute reflecting their splice sites, displayed on
 the details page of the GeneID U12 subtrack as the &quot;Alternate Name&quot; 
 of the item composed of the intron plus flanking exons.</P>
 
 <H3>Jigsaw</H3>
 <P>
 Jigsaw is a gene prediction program that determines genes based on 
 target genomic sequence and output from a gene structure annotation database.
 Data downloaded from UCSC's annotation database is 
 used as input and includes the following tracks of evidence:
 Known Genes, Ensembl, RefSeq, GeneID, Genscan, SGP, Twinscan, Human mRNAs,
 TIGR Gene Index, UniGene, Most Conserved Elements and Non-human RefSeq Genes.
 <A HREF="http://ccb.jhu.edu/software/glimmerhmm/"
 TARGET=_blank>GlimmerHMM</A> and <A HREF="http://genezilla.org"
 TARGET=_blank>GeneZilla</A>, two open source <em>ab initio</em> gene-finding 
 programs based on GHMMs, are also used.</P>
 
 <H3>SGP2-U12</H3>
 <P>
 To predict genes in a genomic query, SGP2 combines GeneID predictions with 
 tblastx comparisons of the genomic query against other genomic sequences.
 This modified version of SGP2 uses models for U12-dependent splice signals 
 in addition to U2 splice signals. The reference genomic sequence for this data 
 set is the Oct. 2004 release of mouse sequence syntenic to ENCODE regions.</P>
 <P>
 The SGP2 and SGP2 U12 tracks follow the same display conventions as the 
 GeneID and GeneID U12 subtracks described above.</P>
 
 <H3>Yale Pseudogenes</H3>
 <P>
 For this analysis, pseudogenes were defined as genomic sequences similar 
 to known human genes and with various disablements (premature stop codons or
 frameshifts) in their &quot;putative&quot; protein-coding regions.</P>
 <P>
 The protein sequences of known human genes (as annotated by ENSEMBL) were used
 to search for similar nongenic sequences in ENCODE regions.  The matching
 sequences were assessed as disabled copies of genes based on the occurrences of
 premature stop codons or frameshifts.  The intron-exon structure of the
 functional gene was further used to infer whether a pseudogene was duplicated
 or processed (a duplicated pseudogene keeps the intron-exon structure of its
 parent functional gene). Small pseudogene sequences were labeled as fragments or
 other types.</P>
 <P>
 All pseudogenes in this track were manually curated.
 In the browser, the track details page shows the pseudogene type.</P>
 
 <H2>Credits</H2>
 <P>
 Augustus was written by Mario Stanke at the
 <A HREF="http://gobics.de/department/" TARGET=_blank>Department of 
 Bioinformatics</A> of the University of Göttingen in Germany.</P>
 <P>
 Exogean was developed by Sarah Djebali and Hugues Roest Crollius from the
 Dyogen Lab, <A HREF="https://www.ens.psl.eu/" TARGET=_blank>Ecole 
 Normale Supérieure</A> (Paris, France) and Franck Delaplace
 from the Laboratoire de Méthodes Informatiques 
 (<A HREF="https://www.sigles.net/sigle/lami-laboratoire-des-methodes-informatiques" TARGET=_blank>LaMI</A>), (Evry, 
 France).</P>
 <P>
 The FGenesh++ gene predictions were provided by Victor Solovyev of
 <A HREF="http://www.softberry.com/" TARGET=_blank>Softberry Inc.</A>
 <P>
 The GeneID-U12 and SGP2-U12 programs were developed by the
 Grup de Recerca en Informàtica Biomèdica 
-(<A HREF="http://grib.imim.es" TARGET=_blank>GRIB</A>) at 
+(<A HREF="https://grib.upf.edu/" TARGET=_blank>GRIB</A>) at 
 the Institut Municipal d'Investigació Mèdica (IMIM) in Barcelona.
 The version of GeneID on which GeneID-U12 is based (geneid_v1.2) was written by 
 Enrique Blanco and Roderic Guigó.
 The parameter files were constructed by Genis Parra and Francisco Camara.
 Additional contributions were made by Josep F. Abril, Moises Burset and Xavier 
 Messeguer. Modifications to GeneID that allow for the prediction of 
 U12-dependent splice sites and incorporation of U12 introns into gene models 
 were made by Tyler Alioto.</P>
 <P>
 Jigsaw was developed at The Institute for Genomic Research 
 (<A HREF="https://www.jcvi.org/" TARGET=_blank>TIGR</A>)
 by Jonathan Allen and Steven Salzberg,
 with computational gene-finder contributions from Mihaela Pertea and William 
 Majoros.  Continued maintenance and development of Jigsaw will
 be provided by the Salzberg group at the Center for Bioinformatics 
 and Computational Biology 
-(<A HREF="http://www.cbcb.umd.edu" TARGET=_blank>CBCB</A>) at the 
+(<A HREF="https://www.cbcb.umd.edu/" TARGET=_blank>CBCB</A>) at the 
 University of Maryland, College Park.</P>
 <P>
 The Yale Pseudogenes were generated by the pseudogene annotation group of 
 <A HREF="http://bioinfo.mbb.yale.edu/" TARGET=_blank>Mark Gerstein</A> at Yale 
 University.</P>
 
 <H2>References</H2>
 
 <H3>Augustus</H3>
 <P>
 Stanke, M. 
 <A HREF="https://ediss.uni-goettingen.de/handle/11858/00-1735-0000-0006-B3F8-4"
 TARGET=_blank>Gene prediction with a hidden Markov model</A>.
 <em>Ph.D. thesis</em>, Universit&auml;t G&ouml;ttingen, Germany (2004).</P>
 <P>
 Stanke, M. and Waack, S. 
 <A HREF="https://academic.oup.com/bioinformatics/article/19/suppl_2/ii215/180603"
 TARGET=_blank>Gene prediction with a hidden Markov model and a new intron 
 submodel</A>.
 <em>Bioinformatics</em>, <B>19</B>(Suppl. 2), ii215-ii225 (2003).</P>
 <P>
 Stanke, M., Steinkamp, R., Waack, S. and Morgenstern, B. 
 <A HREF="https://academic.oup.com/nar/article/32/suppl_2/W309/1040489"
 TARGET=_blank>AUGUSTUS: a web server for gene finding in eukaryotes</A>.
 <em>Nucl. Acids Res.</em>, <B>32</B>, W309-W312 (2004).</P>
 
 <H3>FGenesh++</H3>
 <P>
 Solovyev V.V. 
 &quot;Statistical approaches in Eukaryotic gene prediction&quot;.
 In <em>Handbook of Statistical Genetics</em> (eds. Balding D. et al.)
 (John Wiley & Sons, Inc., 2001). p. 83-127.</P>
 
 <H3>GeneID</H3>
 <P>
 Blanco, E., Parra, G.  and Guigó, R. 
 &quot;Using geneid to identify genes&quot;. 
 In <em>Current Protocols in Bioinformatics</em>, Unit 4.3. (ed. Baxevanis, A.D.)
 (John Wiley & Sons, Inc., 2002).</P>
 <P>
 Guigó, R. 
 <A HREF="https://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=PubMed&list_uids=10072084&dopt=Abstract"
 TARGET=_blank>Assembling genes from predicted exons in linear time with 
 dynamic programming</A>. 
 J Comput Biol. <B>5</B>(4), 681-702 (1998).</P>
 <P>
 Guigó, R., Knudsen, S., Drake, N. and Smith, T.
 <A HREF="https://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=Abstract&list_uids=1619647&query_hl=5"
 TARGET=_blank>Prediction of gene structure</A>. 
 J Mol Biol. <B>226</B>(1), 141-57 (1992).</P>
 <P>
 Parra, G., Blanco, E. and Guigó, R. 
 <A HREF="https://genome.cshlp.org/content/10/4/511.full"
 TARGET=_blank>GeneID in <em>Drosophila</em></A>. 
 <em>Genome Research</em> <B>10</B>(4), 511-515 (2000).</P>
 
 <H3>Jigsaw</H3>
 <P>
 Allen, J.E., Pertea, M.  and Salzberg, S.L.
 <A HREF="https://genome.cshlp.org/content/14/1/142.full"
 TARGET=_blank>Computational gene prediction using multiple sources of 
 evidence</A>. 
 <em>Genome Res.</em>, <B>14</B>(1), 142-8 (2004). </P> 
 <P>
 Allen, J.E. and Salzberg, S.L.
 <A HREF="https://academic.oup.com/bioinformatics/article/21/18/3596/202486"
 TARGET=_blank>JIGSAW: integration of multiple sources of evidence for gene 
 prediction</A>.
 <em>Bioinformatics</em> <B>21</B>(18), 3596-3603 (2005).</P>
 
 <H3>SGP2</H3>
 <P>
 Guigó, R., Dermitzakis, E.T., Agarwal, P., Ponting, C.P., Parra, G., 
 Reymond, A., Abril, J.F., Keibler, E., Lyle, R., Ucla, C. <em>et al</em>. 
 <A HREF="https://www.pnas.org/content/100/3/1140.full"
 TARGET=_blank>Comparison of mouse and human genomes followed by experimental 
 verification yields an estimated 1,019 additional genes</A>. 
 <em>Proc Natl Acad Sci U S A</em> <B>100</B>(3), 1140-5 (2003).</P>
 <P>
 Parra, G., Agarwal, P., Abril, J.F., Wiehe, T., Fickett, J.W. and Guigó, R. 
 <A HREF="https://genome.cshlp.org/content/13/1/108.full"
 TARGET=_blank>Comparative gene prediction in human and mouse</A>. 
 <em>Genome Res.</em> <B>13</B>(1), 108-17 (2003). </P>