3bsqA Discussion: Difference between revisions
No edit summary |
No edit summary |
||
Line 1: | Line 1: | ||
'''Multiple sequence alighment''' (MSA) revealed several conserved residues throughput the whole sulfatase family; more of them in the N-terminal region of the sequence. As mentioned in introduction, ASA and ASB are lysosomal enzymes while ASC is a microsomal enzyme. Litrerature search revealed that arylsulfatases D, E, F, G, H, J and K are localized in ER and golgi compartments of the cell | '''Multiple sequence alighment''' (MSA) revealed several conserved residues throughput the whole sulfatase family; more of them in the N-terminal region of the sequence. As mentioned in introduction, ASA and ASB are lysosomal enzymes while ASC is a microsomal enzyme. Litrerature search revealed that arylsulfatases D, E, F, G, H, J and K are localized in ER and golgi compartments of the cell | ||
N-acetylgalascosamine -4- sulfatase, ASA and STS were shown to be most similar in structure to ASK, by 'DALI' results. Therefore the literature was searched to find the mechanism of catalytic action of these enzymes. Only STS is fully functionally characterised. STS posseses a set of nine residues which are essential for function. ([[http://www.ncbi.nlm.nih.gov/pubmed/17558559?ordinalpos=2&itool=EntrezSystem2.PEntrez.Pubmed.Pubmed_ResultsPanel.Pubmed_RVDocSum]] [1]). However STS is a membrane bound protein which consists of a globular domain bearing the catalytic site and a transmembrane domain made up of two antiparallel hydrophobic alpha helices. The three dimentional stucture of ASK is not indicative of a transmembrane domain; therefore it | N-acetylgalascosamine -4- sulfatase, ASA and STS were shown to be most similar in structure to ASK, by 'DALI' results. Therefore the literature was searched to find the mechanism of catalytic action of these enzymes. Only STS is fully functionally characterised. STS posseses a set of nine residues which are essential for function. ([[http://www.ncbi.nlm.nih.gov/pubmed/17558559?ordinalpos=2&itool=EntrezSystem2.PEntrez.Pubmed.Pubmed_ResultsPanel.Pubmed_RVDocSum]] [1]). However STS is a membrane bound protein which consists of a globular domain bearing the catalytic site and a transmembrane domain made up of two antiparallel hydrophobic alpha helices. The three dimentional stucture of ASK is not indicative of a transmembrane domain; therefore it is probably a water soluble enzyme found in ER [1]. | ||
Evidence from previous experiments states that ASA is localysed in lysosomes [2], which is different in pH conditions to ER and golgi. Therefore STS was chosen to study the structure and function of the catalytic site. Nine key catalytic residues in STS are D35, D36, D342, G343, C75, R79, K134, K368, H136 and H290. First four residues provide oxygen ligands for the divalent cation binding while others participate in hydrolysis of the substrate. It should be noticed that cystine is post translationally modified to a formyleglycine (FG). | Evidence from previous experiments states that ASA is localysed in lysosomes [2], which is different in pH conditions to ER and golgi. Therefore STS was chosen to study the structure and function of the catalytic site. Nine key catalytic residues in STS are D35, D36, D342, G343, C75, R79, K134, K368, H136 and H290. First four residues provide oxygen ligands for the divalent cation binding while others participate in hydrolysis of the substrate. It should be noticed that cystine is post translationally modified to a formyleglycine (FG). | ||
Line 6: | Line 6: | ||
MSA '''showed''' that these STS catalytic residues are conserved generally all through the enzyme family and especially in ASA and STS. These residues were marked on the crystal structure of ASK on PyMol, they made up a very similar catalytic site to that of STS. Five out of nine STS key residues were located on '''exactly the same position''' of the sequence; however D36 and C75 seemd to have substituted with histidine and serine, while K368 occurred a few positions earlier and H290 was lost. | MSA '''showed''' that these STS catalytic residues are conserved generally all through the enzyme family and especially in ASA and STS. These residues were marked on the crystal structure of ASK on PyMol, they made up a very similar catalytic site to that of STS. Five out of nine STS key residues were located on '''exactly the same position''' of the sequence; however D36 and C75 seemd to have substituted with histidine and serine, while K368 occurred a few positions earlier and H290 was lost. | ||
When these residues were marked in the 3D-structure, a histidine was found in the same position fo catalytic site as in STS, but occurred at position 284 of ASK sequence. It is marked in ‘cyan’ on figure 2. The STS-K368-like residue in ASK (K296) seemed to have conserved all throught the MSA. | When these residues were marked in the 3D-structure, a histidine was found in the same position fo catalytic site as in STS, but occurred at position 284 of ASK sequence. It is marked in ‘cyan’ on figure 2. The STS-K368-like residue in ASK (K296) seemed to have conserved all throught the MSA. | ||
As mentionaed earlier, there are four residues which provide electronegative oxygen ligands to hold the divalent cation in the catalytic site. Three of these residues (D24, D283 and G284) are conserved in ASK, but D36 in STS is replaced by a histidine in ASK. However considering either of nitrogen on histidine side chain could donate a lone pair to form a coordinate bond with ‘the divalent cation’ this region may still function as the oxygrn ligand in aspartic acid. Finally, the C75 of STS | As mentionaed earlier, there are four residues which provide electronegative oxygen ligands to hold the divalent cation in the catalytic site. Three of these residues (D24, D283 and G284) are conserved in ASK, but D36 in STS is replaced by a histidine in ASK. However considering either of nitrogen on histidine side chain could donate a lone pair to form a coordinate bond with ‘the divalent cation’ this region may still function as the oxygrn ligand in aspartic acid. | ||
Finally, the C75 of STS has been replaced by a serine in the bacterial ASK, but this serine could easily be converted to a formylglycine. | |||
C-terminus of sulfatases | The crystal structure of ASK at 2.4 A resolution woudn't pick the difference between a serine and a formylglycine, where the differences are lose of one hydrogen and formation of slightly chorter double bond between carbon to oxygen. An experiment carried out on ASK found in ''Klebsiella pneumoneae’’, reveals that ASK polypeptides posseses FG in the place of serine as a result of a different post translational modification mechanism to that of eukaryotes [[http://www.jbc.org/cgi/reprint/273/9/4835]]. | ||
The C-terminus of sulfatases contain a substrate binding site, hence weakly conserved throughout the family due to the variation of types of substrates used. However, when the C-terminal regions in two sequence alignment of ASK and STN was looked at, the level of conservation was very high (27.9%). Based on this evidence it is predicted, that STS and ASK shair substrates. | |||
'''Possible function and likely substrates of ASK''' | '''Possible function and likely substrates of ASK''' | ||
STS is a membrane bound enzyme | STS is a membrane bound enzyme mostly found in the human placenta and skin fibroblasts. It converts sex-stroid precursors to ative estrogen and androgen, therefore provides a localised supply of these hormones (Ghosh, D., 2007). ASK is a water soluble enzyme localysed in ER of the cell. No tissue localization is specified to date. Based on all the above evidence, the possible function ASK may be binding and activation of stroids in the ER lumen. |
Revision as of 14:02, 8 June 2008
Multiple sequence alighment (MSA) revealed several conserved residues throughput the whole sulfatase family; more of them in the N-terminal region of the sequence. As mentioned in introduction, ASA and ASB are lysosomal enzymes while ASC is a microsomal enzyme. Litrerature search revealed that arylsulfatases D, E, F, G, H, J and K are localized in ER and golgi compartments of the cell N-acetylgalascosamine -4- sulfatase, ASA and STS were shown to be most similar in structure to ASK, by 'DALI' results. Therefore the literature was searched to find the mechanism of catalytic action of these enzymes. Only STS is fully functionally characterised. STS posseses a set of nine residues which are essential for function. ([[1]] [1]). However STS is a membrane bound protein which consists of a globular domain bearing the catalytic site and a transmembrane domain made up of two antiparallel hydrophobic alpha helices. The three dimentional stucture of ASK is not indicative of a transmembrane domain; therefore it is probably a water soluble enzyme found in ER [1].
Evidence from previous experiments states that ASA is localysed in lysosomes [2], which is different in pH conditions to ER and golgi. Therefore STS was chosen to study the structure and function of the catalytic site. Nine key catalytic residues in STS are D35, D36, D342, G343, C75, R79, K134, K368, H136 and H290. First four residues provide oxygen ligands for the divalent cation binding while others participate in hydrolysis of the substrate. It should be noticed that cystine is post translationally modified to a formyleglycine (FG).
MSA showed that these STS catalytic residues are conserved generally all through the enzyme family and especially in ASA and STS. These residues were marked on the crystal structure of ASK on PyMol, they made up a very similar catalytic site to that of STS. Five out of nine STS key residues were located on exactly the same position of the sequence; however D36 and C75 seemd to have substituted with histidine and serine, while K368 occurred a few positions earlier and H290 was lost. When these residues were marked in the 3D-structure, a histidine was found in the same position fo catalytic site as in STS, but occurred at position 284 of ASK sequence. It is marked in ‘cyan’ on figure 2. The STS-K368-like residue in ASK (K296) seemed to have conserved all throught the MSA. As mentionaed earlier, there are four residues which provide electronegative oxygen ligands to hold the divalent cation in the catalytic site. Three of these residues (D24, D283 and G284) are conserved in ASK, but D36 in STS is replaced by a histidine in ASK. However considering either of nitrogen on histidine side chain could donate a lone pair to form a coordinate bond with ‘the divalent cation’ this region may still function as the oxygrn ligand in aspartic acid. Finally, the C75 of STS has been replaced by a serine in the bacterial ASK, but this serine could easily be converted to a formylglycine.
The crystal structure of ASK at 2.4 A resolution woudn't pick the difference between a serine and a formylglycine, where the differences are lose of one hydrogen and formation of slightly chorter double bond between carbon to oxygen. An experiment carried out on ASK found in Klebsiella pneumoneae’’, reveals that ASK polypeptides posseses FG in the place of serine as a result of a different post translational modification mechanism to that of eukaryotes [[2]].
The C-terminus of sulfatases contain a substrate binding site, hence weakly conserved throughout the family due to the variation of types of substrates used. However, when the C-terminal regions in two sequence alignment of ASK and STN was looked at, the level of conservation was very high (27.9%). Based on this evidence it is predicted, that STS and ASK shair substrates.
Possible function and likely substrates of ASK
STS is a membrane bound enzyme mostly found in the human placenta and skin fibroblasts. It converts sex-stroid precursors to ative estrogen and androgen, therefore provides a localised supply of these hormones (Ghosh, D., 2007). ASK is a water soluble enzyme localysed in ER of the cell. No tissue localization is specified to date. Based on all the above evidence, the possible function ASK may be binding and activation of stroids in the ER lumen.