Source:http://linkedlifedata.com/resource/pubmed/id/12773149
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| Predicate | Object |
|---|---|
| rdf:type | |
| lifeskim:mentions | |
| pubmed:issue |
Pt 3
|
| pubmed:dateCreated |
2003-5-29
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| pubmed:abstractText |
The conformational agenda harnessed by different glycosidases along the reaction pathway has been mapped by X-ray crystallography. The transition state(s) formed during the enzymic hydrolysis of glycosides features strong oxocarbenium-ion-like character involving delocalization across the C-1-O-5 bond. This demands planarity of C-5, O-5, C-1 and C-2 at or near the transition state. It is widely, but incorrectly, assumed that the transition state must be (4)H(3) (half-chair). The transition-state geometry is equally well supported, for pyranosides, by both the (4)H(3) and (3)H(4) half-chair and (2,5)B and B(2,5) boat conformations. A number of retaining beta-glycosidases acting on gluco -configured substrates have been trapped in Michaelis and covalent intermediate complexes in (1)S(3) (skew-boat) and (4)C(1) (chair) conformations, respectively, pointing to a (4)H(3)-conformed transition state. Such a (4)H(3) conformation is consistent with the tight binding of (4)E- (envelope) and (4)H(3)-conformed transition-state mimics to these enzymes and with the solution structures of compounds bearing an sp (2) hybridized anomeric centre. Recent work reveals a (1)S(5) Michaelis complex for beta-mannanases which, together with the (0)S(2) covalent intermediate, strongly implicates a B(2,5) transition state for beta-mannanases, again consistent with the solution structures of manno -configured compounds bearing an sp (2) anomeric centre. Other enzymes may use different strategies. Xylanases in family GH-11 reveal a covalent intermediate structure in a (2,5)B conformation which would also suggest a similarly shaped transition state, while (2)S(0)-conformed substrate mimics spanning the active centre of inverting cellulases from family GH-6 may also be indicative of a (2,5)B transition-state conformation. Work in other laboratories on both retaining and inverting alpha-mannosidases also suggests non-(4)H(3) transition states for these medically important enzymes. Three-dimensional structures of enzyme complexes should now be able to drive the design of transition-state mimics that are specific for given enzymes, as opposed to being generic or merely fortuitous.
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| pubmed:language |
eng
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| pubmed:journal | |
| pubmed:citationSubset |
IM
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| pubmed:chemical | |
| pubmed:status |
MEDLINE
|
| pubmed:month |
Jun
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| pubmed:issn |
0300-5127
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| pubmed:author | |
| pubmed:issnType |
Print
|
| pubmed:volume |
31
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| pubmed:owner |
NLM
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| pubmed:authorsComplete |
Y
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| pubmed:pagination |
523-7
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| pubmed:dateRevised |
2006-11-15
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| pubmed:meshHeading |
pubmed-meshheading:12773149-Cellulases,
pubmed-meshheading:12773149-Crystallography, X-Ray,
pubmed-meshheading:12773149-Endo-1,4-beta Xylanases,
pubmed-meshheading:12773149-Glycoside Hydrolases,
pubmed-meshheading:12773149-Hydrolysis,
pubmed-meshheading:12773149-Protein Conformation,
pubmed-meshheading:12773149-beta-Mannosidase
|
| pubmed:year |
2003
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| pubmed:articleTitle |
Mapping the conformational itinerary of beta-glycosidases by X-ray crystallography.
|
| pubmed:affiliation |
Structural Biology Laboratory, Department of Chemistry, University of York, Heslington, York YO10 5YW, UK. davies@ysbl.york.ac.uk
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| pubmed:publicationType |
Journal Article,
Review,
Research Support, Non-U.S. Gov't
|