2WKV
BIOSYNTHETIC THIOLASE FROM Z. RAMIGERA. COMPLEX OF THE N316D MUTANT WITH COENZYME A.
Summary for 2WKV
| Entry DOI | 10.2210/pdb2wkv/pdb |
| Related | 1DLU 1DLV 1DM3 1M1O 1M1T 1M3K 1M3Z 1M4S 1M4T 1NL7 1OU6 1QFL 2VTZ 2VU0 2VU1 2VU2 2WKT 2WKU 2WL4 2WL5 2WL6 |
| Descriptor | ACETYL-COA ACETYLTRANSFERASE, SULFATE ION, SODIUM ION, ... (5 entities in total) |
| Functional Keywords | acyltransferase, phb biosynthesis, cytoplasm, transferase, thiolase fold |
| Biological source | ZOOGLOEA RAMIGERA |
| Cellular location | Cytoplasm: P07097 |
| Total number of polymer chains | 4 |
| Total formula weight | 166245.51 |
| Authors | Merilainen, G.,Poikela, V.,Kursula, P.,Wierenga, R.K. (deposition date: 2009-06-18, release date: 2009-11-03, Last modification date: 2023-12-13) |
| Primary citation | Merilainen, G.,Poikela, V.,Kursula, P.,Wierenga, R.K. The Thiolase Reaction Mechanism: The Importance of Asn316 and His348 for Stabilizing the Enolate Intermediate of the Claisen Condensation. Biochemistry, 48:11011-, 2009 Cited by PubMed Abstract: The biosynthetic thiolase catalyzes a Claisen condensation reaction between acetyl-CoA and the enzyme acetylated at Cys89. Two oxyanion holes facilitate this catalysis: oxyanion hole I stabilizes the enolate intermediate generated from acetyl-CoA, whereas oxyanion hole II stabilizes the tetrahedral intermediate of the acetylated enzyme. The latter intermediate is formed when the alpha-carbanion of acetyl-CoA enolate reacts with the carbonyl carbon of acetyl-Cys89, after which C-C bond formation is completed. Oxyanion hole II is made of two main chain peptide NH groups, whereas oxyanion hole I is formed by a water molecule (Wat82) and NE2(His348). Wat82 is anchored in the active site by an optimal set of hydrogen bonding interactions, including a hydrogen bond to ND2(Asn316). Here, the importance of Asn316 and His348 for catalysis has been studied; in particular, the properties of the N316D, N316A, N316H, H348A, and H348N variants have been determined. For the N316D variant, no activity could be detected. For each of the remaining variants, the k(cat)/K(m) value for the Claisen condensation catalysis is reduced by a factor of several hundred, whereas the thiolytic degradation catalysis is much less affected. The crystal structures of the variants show that the structural changes in the active site are minimal. Our studies confirm that oxyanion hole I is critically important for the condensation catalysis. Removing either one of the hydrogen bond donors causes the loss of at least 3.4 kcal/mol of transition state stabilization. It appears that in the thiolytic degradation direction, oxyanion hole I is not involved in stabilizing the transition state of its rate limiting step. However, His348 has a dual role in the catalytic cycle, contributing to oxyanion hole I and activating Cys89. The analysis of the hydrogen bonding interactions in the very polar catalytic cavity shows the importance of two conserved water molecules, Wat82 and Wat49, for the formation of oxyanion hole I and for influencing the reactivity of the catalytic base, Cys378, respectively. Cys89, Asn316, and His348 form the CNH-catalytic triad of the thiolase superfamily. Our findings are also discussed in the context of the importance of this triad for the catalytic mechanism of other enzymes of the thiolase superfamily. PubMed: 19842716DOI: 10.1021/BI901069H PDB entries with the same primary citation |
| Experimental method | X-RAY DIFFRACTION (2.5 Å) |
Structure validation
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