Renin: Difference between revisions
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==Structure== | ==Structure== | ||
The precursor of renin is a 406 amino acid residue protein. <scene name='Sandbox_Reserved_489/Signal_domain/1'>Residues 1-23</scene> are a signal peptide sequence and residues 24-66 are cleaved to produce the mature 340 amino acid residue <scene name='Sandbox_Reserved_489/Mature_renin/1'>mature renin</scene>. The secondary structural elements of renin include 29 <scene name='Sandbox_Reserved_489/Betasheetscolors/1'> antiparallel β sheets</scene>, 3 <scene name='Sandbox_Reserved_489/Betabridges/1'> β bridges</scene>, 4 <scene name='Sandbox_Reserved_489/Alphahelixes/1'> α helices</scene>, <scene name='Sandbox_Reserved_489/310heleices/1'> 2 </scene>3<sub>10</sub><scene name='Sandbox_Reserved_489/310heleices/1'> helices</scene>, and <scene name='Sandbox_Reserved_489/Turns/1'>18 turns</scene>. The most impressive structural feature of renin is the antiparallel <scene name='Sandbox_Reserved_489/Betasheetspiral/1'> β sheet</scene> that forms the two similar lobes of renin. <scene name='Sandbox_Reserved_489/Hydrophobichydrophillic/1'>Hydrophilic (blue) and hydrophobic (red) residues</scene> are located primarily on the outside and inside portions of renin respectively. The most important structure is the <scene name='Sandbox_Reserved_489/Hydrophobicactivesite/1'>hydrophobic pocket</scene> located in the active site that allows substrate binding. The active site of renin contains two essential <scene name='Sandbox_Reserved_489/Activesiteasps2/2'>aspartate residues</scene>. Renin has <scene name='Sandbox_Reserved_489/Catalyticmotifs/1'>two catalytic motifs</scene> after each of the two aspartate residues. Renin also uses a <scene name='Sandbox_Reserved_489/Activesiteflap/1'>active site flap</scene>, a β hairpin structure, that open and closes to uncover or cover the active site. | The precursor of renin '''prorenin''' is a 406 amino acid residue protein. <scene name='Sandbox_Reserved_489/Signal_domain/1'>Residues 1-23</scene> are a signal peptide sequence and residues 24-66 are cleaved to produce the mature 340 amino acid residue <scene name='Sandbox_Reserved_489/Mature_renin/1'>mature renin</scene>. The secondary structural elements of renin include 29 <scene name='Sandbox_Reserved_489/Betasheetscolors/1'> antiparallel β sheets</scene>, 3 <scene name='Sandbox_Reserved_489/Betabridges/1'> β bridges</scene>, 4 <scene name='Sandbox_Reserved_489/Alphahelixes/1'> α helices</scene>, <scene name='Sandbox_Reserved_489/310heleices/1'> 2 </scene>3<sub>10</sub><scene name='Sandbox_Reserved_489/310heleices/1'> helices</scene>, and <scene name='Sandbox_Reserved_489/Turns/1'>18 turns</scene>. The most impressive structural feature of renin is the antiparallel <scene name='Sandbox_Reserved_489/Betasheetspiral/1'> β sheet</scene> that forms the two similar lobes of renin. <scene name='Sandbox_Reserved_489/Hydrophobichydrophillic/1'>Hydrophilic (blue) and hydrophobic (red) residues</scene> are located primarily on the outside and inside portions of renin respectively. The most important structure is the <scene name='Sandbox_Reserved_489/Hydrophobicactivesite/1'>hydrophobic pocket</scene> located in the active site that allows substrate binding. The active site of renin contains two essential <scene name='Sandbox_Reserved_489/Activesiteasps2/2'>aspartate residues</scene>. Renin has <scene name='Sandbox_Reserved_489/Catalyticmotifs/1'>two catalytic motifs</scene> after each of the two aspartate residues. Renin also uses a <scene name='Sandbox_Reserved_489/Activesiteflap/1'>active site flap</scene>, a β hairpin structure, that open and closes to uncover or cover the active site. | ||
Post translational modifications of renin include; precursor cleavage of propetide to produce active mature renin, disulfide bond formation, and glycosylation of certain residues. Disulfide bonds are formed to connect serine residues <scene name='Sandbox_Reserved_489/Disulfidebond1/2'>51 to 58</scene>, <scene name='Sandbox_Reserved_489/Disulfidebond2/2'>217 to 221</scene>, and <scene name='Sandbox_Reserved_489/Disulfidebond3/2'>259 to 296</scene>. <scene name='Sandbox_Reserved_489/Glycosylated/2'>Two asparagine residues</scene> at positions 14 and 75 can be glycosylated. The asparagine residue at postion 75 is glycosylated (2-(acetylamino)-2-deoxy-A-D-glucopyranose) in mature renin whereas the residue at postion 14 is not glycosylated.<ref>Margrane M. and the UnitProt consortium, '''Uniprot Knowledgebase: a hub of integrated protein data''', Database, 2012: bar009 (2011). Public Accession Number P00797 </ref> | Post translational modifications of renin include; precursor cleavage of propetide to produce active mature renin, disulfide bond formation, and glycosylation of certain residues. Disulfide bonds are formed to connect serine residues <scene name='Sandbox_Reserved_489/Disulfidebond1/2'>51 to 58</scene>, <scene name='Sandbox_Reserved_489/Disulfidebond2/2'>217 to 221</scene>, and <scene name='Sandbox_Reserved_489/Disulfidebond3/2'>259 to 296</scene>. <scene name='Sandbox_Reserved_489/Glycosylated/2'>Two asparagine residues</scene> at positions 14 and 75 can be glycosylated. The asparagine residue at postion 75 is glycosylated (2-(acetylamino)-2-deoxy-A-D-glucopyranose) in mature renin whereas the residue at postion 14 is not glycosylated.<ref>Margrane M. and the UnitProt consortium, '''Uniprot Knowledgebase: a hub of integrated protein data''', Database, 2012: bar009 (2011). Public Accession Number P00797 </ref> | ||