Free energy analysis of ω-transaminase reactions to dissect how the enzyme controls the substrate selectivity

ω-Transaminase (ω-TA) is the only naturally occurring enzyme allowing asymmetric amination of ketones for production of chiral amines. The active site of the enzyme was proposed to consist of two differently sized substrate binding pockets and the stringent steric constraint in the small pocket has presented a significant challenge to production of structurally diverse chiral amines. To provide a mechanistic understanding of how the (S)-specific ω-TA from Paracoccus denitrificans achieves the steric constraint in the small pocket, we developed a free energy analysis enabling quantification of individual contributions of binding and catalytic steps to changes in the total activation energy caused by structural differences in the substrate moiety that is to be accommodated by the small pocket. The analysis exploited kinetic and thermodynamic investigations using structurally similar substrates and the structural differences among substrates were regarded as probes to assess how much relative destabilizations of the reaction intermediates, i.e. the Michaelis complex and the transition state, were induced by the slight change of the substrate moiety inside the small pocket. We found that ≈80% of changes in the total activation energy resulted from changes in the enzyme-substrate binding energy, indicating that substrate selectivity in the small pocket is controlled predominantly by the binding step (K_M) rather than the catalytic step (k_cat). In addition, we examined the pH dependence of the kinetic parameters and the pH profiles of the K_M and k_cat values suggested that key active site residues involved in the binding and catalytic steps are decoupled. Taken together, these findings suggest that the active site residues forming the small pocket are mainly engaged in the binding step but not significantly involved in the catalytic step, which may provide insights into how to design a rational strategy for engineering of the small pocket to relieve the steric constraint toward bulky substituents.     

Specific inhibition of the aspartate aminotransferase of Plasmodium falciparum

Aspartate aminotransferases (AspATs; EC 2.6.1.1) catalyze the conversion of aspartate and α-ketoglutarate into oxaloacetate and glutamate and are key enzymes in the nitrogen metabolism of all organisms. Recent findings suggest that the plasmodial enzyme [Plasmodium falciparum aspartate aminotransferase (PfAspAT)] may also play a pivotal role in energy metabolism and in the de novo biosynthesis of pyrimidines. However, while PfAspAT is a potential drug target, the high homology between the active sites of currently available AspAT structures hinders the development of specific inhibitors of these enzymes. In this article, we report the X-ray structure of the PfAspAT homodimer at a resolution of 2.8 Å. While the overall fold is similar to the currently available structures of other AspATs, the structure presented shows a significant divergence in the conformation of the N-terminal residues. Deletion of these divergent PfAspAT N-terminal residues results in a loss of activity for the recombinant protein, and addition of a peptide containing these 13 N-terminal residues results in inhibition both in vitro and in a lysate isolated from cultured parasites, while the activity of human cytosolic AspAT is unaffected. The finding that the divergent N-terminal amino acids of PfAspAT play a role in catalytic activity indicates that specific inhibition of the enzyme may provide a lead for the development of novel compounds in the treatment of malaria. We also report on the localization of PfAspAT to the parasite cytosol and discuss the implications of the role of PfAspAT in the supply of malate to the parasite mitochondria.     

Influence of over-expression of cytosolic aspartate aminotransferase on amino acid metabolism and defence responses against Botrytis cinerea infection in Arabidopsis thaliana

Arabidopsis possesses several genes encoding aspartate aminotransferase, which catalyzes the bidirectional conversion of aspartate into glutamate. These amino acids together with asparagine and glutamine play an important role in N storage and distribution. In addition, they act as precursors for other amino acids. The gene encoding cytosolic aspartate aminotransferase, Asp2, was found to be induced upon infection with the necrotrophic pathogen Botrytis cinerea in Arabidopsis. Asp2 over-expression lines and a T-DNA insertion mutant were used to study the role of aspartate aminotransferase in Arabidopsis defence responses. Over-expression of Asp2 led to changes in aspartate content and aspartate-derived amino acids. The Asp2 knockout mutant was also slightly affected in its amino acid composition. Under standard growth conditions, the Asp2 transgenic lines did not show morphological changes in comparison with the wild-type. However, transgenic lines with the highest Asp2 expression displayed more spreading lesions when infected with B. cinerea. We discuss how this gene involved in amino acid metabolism might interact with plant defence responses.     

Structure and mechanism of a cysteine sulfinate desulfinase engineered on the aspartate aminotransferase scaffold

The joint substitution of three active-site residues in Escherichia colil-aspartate aminotransferase increases the ratio of l-cysteine sulfinate desulfinase to transaminase activity 10⁵-fold. This change in reaction specificity results from combining a tyrosine-shift double mutation (Y214Q/R280Y) with a non-conservative substitution of a substrate-binding residue (I33Q). Tyr214 hydrogen bonds with O3 of the cofactor and is close to Arg374 which binds the α-carboxylate group of the substrate; Arg280 interacts with the distal carboxylate group of the substrate; and Ile33 is part of the hydrophobic patch near the entrance to the active site, presumably participating in the domain closure essential for the transamination reaction. In the triple-mutant enzyme, k_cat′ for desulfination of l-cysteine sulfinate increased to 0.5 s^− 1 (from 0.05 s^− 1 in wild-type enzyme), whereas k_cat′ for transamination of the same substrate was reduced from 510 s^− 1 to 0.05 s^− 1. Similarly, k_cat′ for β-decarboxylation of l-aspartate increased from < 0.0001 s^− 1 to 0.07 s^− 1, whereas k_cat′ for transamination was reduced from 530 s^− 1 to 0.13 s^− 1. l-Aspartate aminotransferase had thus been converted into an l-cysteine sulfinate desulfinase that catalyzes transamination and l-aspartate β-decarboxylation as side reactions. The X-ray structures of the engineered l-cysteine sulfinate desulfinase in its pyridoxal-5′-phosphate and pyridoxamine-5′-phosphate form or liganded with a covalent coenzyme-substrate adduct identified the subtle structural changes that suffice for generating desulfinase activity and concomitantly abolishing transaminase activity toward dicarboxylic amino acids. Apparently, the triple mutation impairs the domain closure thus favoring reprotonation of alternative acceptor sites in coenzyme-substrate intermediates by bulk water.     

Mechanism of substrate recognition and PLP-induced conformational changes in LL-diaminopimelate aminotransferase from Arabidopsis thaliana

LL-Diaminopimelate aminotransferase (LL-DAP-AT), a pyridoxal phosphate (PLP)-dependent enzyme in the lysine biosynthetic pathways of plants and Chlamydia, is a potential target for the development of herbicides or antibiotics. This homodimeric enzyme converts L-tetrahydrodipicolinic acid (THDP) directly to LL-DAP using L-glutamate as the source of the amino group. Earlier, we described the 3D structures of native and malate-bound LL-DAP-AT from Arabidopsis thaliana (AtDAP-AT). Seven additional crystal structures of AtDAP-AT and its variants are reported here as part of an investigation into the mechanism of substrate recognition and catalysis. Two structures are of AtDAP-AT with reduced external aldimine analogues: N-(5'-phosphopyridoxyl)-L-glutamate (PLP-Glu) and N-(5'-phosphopyridoxyl)- LL-Diaminopimelate (PLP-DAP) bound in the active site. Surprisingly, they reveal that both L-glutamate and LL-DAP are recognized in a very similar fashion by the same sets of amino acid residues; both molecules adopt twisted V-shaped conformations. With both substrates, the alpha-carboxylates are bound in a salt bridge with Arg404, whereas the distal carboxylates are recognized via hydrogen bonds to the well-conserved side chains of Tyr37, Tyr125 and Lys129. The distal C(epsilon) amino group of LL-DAP is specifically recognized by several non-covalent interactions with residues from the other subunit (Asn309*, Tyr94*, Gly95*, and Glu97* (Amino acid designators followed by an asterisk (*) indicate that the residues originate in the other subunit of the dimer)) and by three bound water molecules. Two catalytically inactive variants of AtDAP-AT were created via site-directed mutagenesis of the active site lysine (K270N and K270Q). The structures of these variants permitted the observation of the unreduced external aldimines of PLP with L-glutamate and with LL-DAP in the active site, and revealed differences in the torsion angle about the PLP-substrate bond. Lastly, an apo-AtDAP-AT structure missing PLP revealed details of conformational changes induced by PLP binding and substrate entry into the active site.     

AspC基因导入前后E.coli BL21蛋白质组的解析

为了考察表达天冬氨酸转氨酶工程菌在转基因前后蛋白质水平的差异变化,采用固相pH梯度-SDS聚丙烯酰胺双向凝胶电泳对转基因前后的大肠杆菌（E．coli BL21）的总蛋白进行分离,银染、显色后,使用2D蛋白质图象分析系统Image Master 2D Platinum 5．0和SWISS-2D PAGE蛋白质组数据库对双向电泳图谱进行分析,识别了近600个蛋白点,比较分析了与苯丙氨酸合成途径相关的关键蛋白的差异,初步探讨了AspC基因的导入后大肠杆菌蛋白质水平的精细调控。