Mutational analysis of substrate recognition by human arginase type I − agmatinase activity of the N130D variant

Alarcón, Rubén; Orellana, Marı́a S.; Neira, Benita; Uribe, Elena; García, José Renán; Carvajal, Nelson

doi:10.1111/j.1742-4658.2006.05551.x

Cited by 26 publications

(27 citation statements)

References 36 publications

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“…It is interesting to compare these results with those reported in previous studies of the more conservative N130D and N130Q mutants of human arginase I (48). Presuming that the D130 side chain can function in the protonated form as a carboxylic acid, both D130 and Q130 could preserve a hydrogen bond interaction with the α-carboxylate of the substrate.…”

Section: Resultsmentioning

confidence: 54%

“…Perhaps this reflects the evolutionary potential of N130 and its associated loop 4 as a “hot spot” in the evolution of substrate specificity as noted by Carvajal (48), given that the arginase fold is shared by agmatinase (31). Intriguingly, Carvajal further reports that although N130D human arginase I exhibits 9-fold diminished substrate affinity with l -arginine, this mutation confers agmatinase activity with K M and k cat values of 1.4 mM and 3 s −1 , respectively (48). These values compare with K M and k cat values values of 1.5 mM and 140 s −1 , respectively, measured for wild-type agmatinase from Escherichia coli (51).…”

Section: Discussionmentioning

confidence: 75%

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Probing the Specificity Determinants of Amino Acid Recognition by Arginase

et al. 2008

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Arginase is a binuclear manganese metalloenzyme that serves as a therapeutic target for the treatment of asthma, erectile dysfunction, and atherosclerosis. In order to better understand the molecular basis of inhibitor affinity, we have employed site-directed mutagenesis, enzyme kinetics, and X-ray crystallography to probe the molecular recognition of the amino acid moiety (i.e., the α-amino and α-carboxylate groups) of substrate l-arginine and inhibitors in the active site of human arginase I. Specifically, we focus on: (1) a water-mediated hydrogen bond between the substrate α-carboxylate and T135, (2) a direct hydrogen bond between the substrate α-carboxylate and N130, and (3) a direct charged hydrogen bond between the substrate α-amino group and D183. Amino acid substitutions for T135, N130, and D183 generally compromise substrate affinity as reflected by increased KM values, but have less pronounced effects on catalytic function as reflected by minimal variations of kcat. As with substrate KM values, inhibitor Kd values increase for binding to enzyme mutants and suggest that the relative contribution of intermolecular interactions to amino acid affinity in the arginase active site is: water-mediated hydrogen bond < direct hydrogen bond < direct charged hydrogen bond. Structural comparisons of arginase with the related binuclear manganese metalloenzymes agmatinase and proclavaminic acid amidinohydrolase suggest that the evolution of substrate recognition in the arginase fold occurs by mutation of residues contained in specificity loops flanking the mouth of the active site (especially loops 4 and 5), thereby allowing diverse guanidinium substrates to be accommodated for catalysis.

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Section: Resultsmentioning

confidence: 54%

Section: Discussionmentioning

confidence: 75%

Probing the Specificity Determinants of Amino Acid Recognition by Arginase

et al. 2008

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“…The question remains as to what effects, if any, these polypeptide insertions have on arginase structure and function? Kinetic measurements on a PFA construct bearing a C-terminal streptavidin affinity tag initially suggested that malarial arginase is less catalytically efficient than the mammalian arginases, with k cat / K M = 7.4 × 10 3 M −1 s −1 (21) (compared with k cat / K M = 2.0 × 10 5 M −1 s −1 for rat arginase I (27) or 1.27 × 10 5 M −1 s −1 for hAI (28)).…”

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confidence: 99%

Crystal Structure of Arginase from Plasmodium falciparum and Implications for l-Arginine Depletion in Malarial Infection,

et al. 2010

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The 2.15 Å resolution crystal structure of arginase from Plasmodium falciparum, the parasite that causes cerebral malaria, is reported in complex with the boronic acid inhibitor 2(S)-amino-6-boronohexanoic acid (ABH; Kd = 11 μM). This is the first crystal structure of a parasitic arginase. Various protein constructs were explored to identify an optimally active enzyme form for inhibition and structural studies, and to probe the structure and function of two polypeptide insertions unique to malarial arginase: a 74-residue low complexity region contained in loop L2, and a 11-residue segment contained in loop L8. Structural studies indicate that the low complexity region is largely disordered and is oriented away from the trimer interface; its deletion does not significantly compromise enzyme activity. The loop L8 insertion is located at the trimer interface and makes several intra- and intermolecular interactions important for enzyme function. In addition, we also demonstrate that arg- P. berghei sporozoites show significantly decreased liver infectivity in vivo. Therefore, inhibition of malarial arginase may serve as a possible candidate for antimalarial therapy against liver-stage infection, and ABH may serve as a lead for the development of inhibitors.

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“…Of the 19 rate constants in our model, we have explicit literature values for k C 2-IR , k A 1-IR , and γ C (Mansuy and Boucher 2004; Alarcón et al 2006; Kolodziejski et al 2004). Additionally there exist literature values for k C 1-IRrep , K C 1rep , K C 2 , K A 1 , and K i (Mansuy and Boucher 2004; Alarcón et al 2006; Boucher et al 1999; Moali et al 1998, 2000; Santhanam et al 2008).…”

Section: Model Formulationmentioning

confidence: 99%

“…Additionally there exist literature values for k C 1-IRrep , K C 1rep , K C 2 , K A 1 , and K i (Mansuy and Boucher 2004; Alarcón et al 2006; Boucher et al 1999; Moali et al 1998, 2000; Santhanam et al 2008). Literature values for the rate constants are found in Table 3.…”

Section: Model Formulationmentioning

confidence: 99%

From Inflammation to Wound Healing: Using a Simple Model to Understand the Functional Versatility of Murine Macrophages

et al. 2011

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Macrophages are fundamental cells of the innate immune system. Their activation is essential for such distinct immune functions as inflammation (pathogen-killing) and tissue repair (wound healing). An open question has been the functional stability of an individual macrophage cell: whether it can change its functional profile between different immune responses such as between the repair pathway and the inflammatory pathway. We studied this question theoretically by constructing a rate equation model for the key substrate, enzymes and products of the pathways; we then tested the model experimentally. Both our model and experiments show that individual macrophages can switch from the repair pathway to the inflammation pathway but that the reverse switch does not occur.

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Mutational analysis of substrate recognition by human arginase type I − agmatinase activity of the N130D variant

Cited by 26 publications

References 36 publications

Probing the Specificity Determinants of Amino Acid Recognition by Arginase

Probing the Specificity Determinants of Amino Acid Recognition by Arginase

Crystal Structure of Arginase from Plasmodium falciparum and Implications for l-Arginine Depletion in Malarial Infection,

From Inflammation to Wound Healing: Using a Simple Model to Understand the Functional Versatility of Murine Macrophages

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