Phytanoyl-CoA dioxygenase Sequence and Evolution: Difference between revisions
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== Phylogenetic Trees == | == Phylogenetic Trees == | ||
[[Image:rootedtreecol1.jpg|center|framed|'''Figure 2.1'''<Br> Rooted Phylogenetic Tree obtained from Phylip <br> Drawn using Phylodendron <br> http://iubio.bio.indiana.edu/treeapp/]]<Br> | |||
[[Image:unrootedtree1.jpg|center|framed|'''Figure 2.1'''<Br> Unrooted Phylogenetic Tree obtained from Phylip <br> Drawn using Phylodendron <br> http://iubio.bio.indiana.edu/treeapp/]]<Br> | |||
*Both trees show animals and fungi most highly conserved and plants least conserved | *Both trees show animals and fungi most highly conserved and plants least conserved | ||
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*Monosiga brevicollis and tetrahymena thermophila both have low bootstrap values but some possibility of lateral gene transfer in the case of tetrahymena | *Monosiga brevicollis and tetrahymena thermophila both have low bootstrap values but some possibility of lateral gene transfer in the case of tetrahymena | ||
[[Image:rootedtreecol2.jpg|center|framed|'''Figure 3'''<Br> Rooted Consensus Tree with bootstrap values obtained from Phylip <br> Drawn using Phylodendron <br> http://iubio.bio.indiana.edu/treeapp/]]<Br> | [[Image:rootedtreecol2.jpg|center|framed|'''Figure 3'''<Br> Rooted Consensus Tree with bootstrap values obtained from Phylip <br> Drawn using Phylodendron <br> http://iubio.bio.indiana.edu/treeapp/]]<Br> | ||
Latest revision as of 01:11, 10 June 2008
Fasta Sequence
>gi|134105315|pdb|2OPW|A Chain A, Crystal Structure Of Human Phytanoyl-Coa Dioxygenase Phyhd1 (Apo) MACLSPSQLQKFQQDGFLVLEGFLSAEECVAMQQRIGEIVAEMDVPLHCRTEFSTQEEEQLRAQGSTDYF LSSGDKIRFFFEKGVFDEKGNFLVPPEKSINKIGHALHAHDPVFKSITHSFKVQTLARSLGLQMPVVVQS MYIFKQPHFGGEVSPHQDASFLYTEPLGRVLGVWIAVEDATLENGCLWFIPGSHTSGVSRRMVRAPVGSA PGTSFLGSEPARDNSLFVPTPVQRGALVLIHGEVVHKSKQNLSDRSRQAYTFHLMEASGTTWSPENWLQP TAELPFPQLYT
Multiple Sequence Alignment
- 46 analogous sequence compared using ClustalX
- Multiple Sequence Alignment is of high quality and conservation
- Fe2+ and 2-Oxogylterate binding sites shown
Figure 1.1
Multiple Sequence Alignment obtained from ClustalX
Multiple Sequence Alignment obtained from ClustalX
Figure 1.2
Multiple Sequence Alignment obtained from ClustalX
Multiple Sequence Alignment obtained from ClustalX
Figure 1.3
Multiple Sequence Alignment obtained from ClustalX
Multiple Sequence Alignment obtained from ClustalX
Phylogenetic Trees
Figure 2.1
Rooted Phylogenetic Tree obtained from Phylip
Drawn using Phylodendron
http://iubio.bio.indiana.edu/treeapp/
Rooted Phylogenetic Tree obtained from Phylip
Drawn using Phylodendron
http://iubio.bio.indiana.edu/treeapp/
Figure 2.1
Unrooted Phylogenetic Tree obtained from Phylip
Drawn using Phylodendron
http://iubio.bio.indiana.edu/treeapp/
Unrooted Phylogenetic Tree obtained from Phylip
Drawn using Phylodendron
http://iubio.bio.indiana.edu/treeapp/
- Both trees show animals and fungi most highly conserved and plants least conserved
- PhyD required for the breakdown of fatty acids in the diet of animals and fungi
- Original tree similar to consensus tree except for two protozoans
- Monosiga brevicollis and tetrahymena thermophila both have low bootstrap values but some possibility of lateral gene transfer in the case of tetrahymena
Figure 3
Rooted Consensus Tree with bootstrap values obtained from Phylip
Drawn using Phylodendron
http://iubio.bio.indiana.edu/treeapp/
Rooted Consensus Tree with bootstrap values obtained from Phylip
Drawn using Phylodendron
http://iubio.bio.indiana.edu/treeapp/
