| Literature DB >> 20886006 |
Håkan Carlsson1, Ebbe Nordlander.
Abstract
In order to elucidate aspects of the mechanism of the hydrolytic enzymeEntities:
Year: 2010 PMID: 20886006 PMCID: PMC2945649 DOI: 10.1155/2010/364891
Source DB: PubMed Journal: Bioinorg Chem Appl Impact factor: 7.778
Figure 1Schematic depiction of the structure of the active site of Bacillus pasteurii urease [11].
Figure 2Schematic depiction of two proposed mechanisms for urease, A [11] and B [15].
Energy results from the calculation of the resting structure.
| Structure | Calculated energy (Hartree) | Added small molecules | Adjusted energy (Hartree) | Relative energy (kJ/mol) |
|---|---|---|---|---|
|
| −13.6629 | Urea and water | −15.9521 | 0 |
|
| −13.6446 | Urea, water and H+ | −15.9134 | 101. |
|
| −13.6300 | Urea, water and −H+ | −15.9395 | 32.9 |
Figure 3Structure of complex 2—depicting the initial coordination of urea. The program Molden (see [27]) was used to generate the graphics.
Energy results from the calculation of the first coordination of urea.
| Structure | Calculated energy (Hartree) | Added small molecules | Adjusted energy (Hartree) | Relative energy (kJ/mol) |
|---|---|---|---|---|
|
| −14.8816 | 2 water | −15.9376 | 0 |
|
| −14.3368 | 3 water | −15.9209 | 82.0 |
|
| −14.8821 | 2 water | −15.9381 | 36.7 |
Figure 4Structure of complex 3. One of the urea nitrogen atoms is coordinated to Ni2, thus replacing the water molecule on Ni2.
Figure 5A reaction diagram showing the calculated energies of the intermediates found in the computational simulation of the urease reaction with the structures and added small molecules in boxes below (see text for detailed description of the intermediates).
Energy results from the calculation of the mechanism involving a tetrahedral intermediate (mechanism A, Figure 2).
| Structure | Calculated energy (Hartree) | Added small molecules | Adjusted energy (Hartree) | Relative energy (kJ/mol) |
|---|---|---|---|---|
|
| −13.6629 | urea and water | − 15.9521 | 0 |
|
| −14.8816 | 2 water | −15.9376 | 38.0 |
|
| −14.3532 | 3 water | −15.9373 | 38.9 |
|
| −14.3315 | 3 water and one H+ | −15.8951 | 150 |
|
| −14.3150 | 3 water | −15.8991 | 139 |
|
| −13.6828 | ammonia and 3 water | −15.8981 | 142 |
|
| −13.6629 | ammonia and carbamic acid | −15.9505 | −33.9 |
|
| −13.6629 | 2 ammonia and carbon dioxide | −15.9451 | 18.3 |
Figure 6Structure of complex 4—the tetrahedral intermediate. The bridging hydroxide and the urea have moved closer together so that a bond is formed. This was found to release the proton associated with the hydroxide bridge.