Rational design of soluble expressed human aldehyde dehydrogenase 2 with high stability and activity in pepsin and trypsin.

Acetaldehyde dehydrogenase 2 (ALDH2) is a crucial enzyme in alcohol metabolism, and oral administration of ALDH2 is a promising method for alcohol detoxification. However, recombinant ALDH2 is susceptible to hydrolysis by digestive enzymes in the gastrointestinal tract and is expressed as inactive inclusion bodies in E. coli. In this study, we performed three rounds of rational design to address these issues. Specifically, the surface digestive sites of pepsin and trypsin were replaced with other polar amino acids, while hydrophobic amino acids were incorporated to reshape the catalytic cavity of ALDH2. The resulting mutant DE2-852 exhibited a 45-fold increase in soluble expression levels, while its stability against trypsin and pepsin increased by eightfold and twofold, respectively. Its catalytic efficiency (kcat/Km) at pH 7.2 and 3.2 improved by more than four and five times, respectively, with increased Vmax and decreased Km values. The enhanced properties of DE2-852 were attributed to the D457Y mutation, which created a more compact protein structure and facilitated a faster collision between the substrate and catalytic residues. These results laid the foundation for the oral administration and mass preparation of highly active ALDH2 and offered insights into the oral application of other proteins.

Novel Disulfiram Derivatives as ALDH1a1-Selective Inhibitors.

Aldehyde dehydrogenase-1a1 (ALDH1a1), the enzyme responsible for the oxidation of retinal into retinoic acid, represents a key therapeutic target for the treatment of debilitating disorders such as cancer, obesity, and inflammation. Drugs that can inhibit ALDH1a1 include disulfiram, an FDA-approved drug to treat chronic alcoholism. Disulfiram, by carbamylation of the catalytic cysteines, irreversibly inhibits ALDH1a1 and ALDH2. The latter is the isozyme responsible for important physiological processes such as the second stage of alcohol metabolism. Given the fact that ALDH1a1 has a larger substrate tunnel than that in ALDH2, replacing disulfiram ethyl groups with larger motifs will yield selective ALDH1a1 inhibitors. We report herein the synthesis of new inhibitors of ALDH1a1 where (hetero)aromatic rings were introduced into the structure of disulfiram. Most of the developed compounds retained the anti-ALDH1a1 activity of disulfiram; however, they were completely devoid of inhibitory activity against ALDH2.

Development of new disulfiram analogues as ALDH1a1-selective inhibitors.

Disulfiram is an FDA-approved drug used to treat chronic alcoholism. This drug works by blocking the second step of ethanol metabolism by inhibiting aldehyde dehydrogenase-2 (ALDH2), the enzyme responsible for acetaldehyde oxidation into acetic acid. This leads to the accumulation of acetaldehyde in the blood following alcohol ingestion and to highly unpleasant symptoms known as acetaldehyde syndrome. Disulfiram also inhibits ALDH1a1, another member of the aldehyde dehydrogenases that catalyzes the oxidation of retinal into retinoic acid. ALDH1a1 represents a key therapeutic target for the treatment of important diseases such as cancer and obesity. The substrate tunnel is larger in ALDH1a1 than in ALDH2; therefore. Thus, replacing disulfiram ethyl groups with larger groups will yield selective ALDH1a1 inhibitors. In this work, we successfully synthesized derivative 2b, in which two ethyl groups were replaced by two para fluorobenzyl groups. The 2b derivative showed a comparable activity to disulfiram against ALDH1a1; however, it was completely devoid of inhibitory activity against ALDH2.

Novel and prevalent non-East Asian ALDH2 variants; Implications for global susceptibility to aldehydes' toxicity.

BACKGROUND: Aldehyde dehydrogenase 2 (ALDH2) catalyzes the detoxification of aliphatic aldehydes, including acetaldehyde. About 45% of Han Chinese (East Asians), accounting for 8% of humans, carry a single point mutation in ALDH2*2 (E504K) that leads to accumulation of toxic reactive aldehydes. METHODS: Sequencing of a small Mexican cohort and a search in the ExAC genomic database for additional ALDH2 variants common in various ethnic groups was set to identify missense variants. These were evaluated in vitro, and in cultured cells expressing these new and common variants. FINDINGS: In a cohort of Hispanic donors, we identified 2 novel mutations in ALDH2. Using the ExAC genomic database, we found these identified variants and at least three other ALDH2 variants with a single point mutation among Latino, African, South Asian, and Finnish ethnic groups, at a frequency of >5/1000. Although located in different parts of the ALDH2 molecule, these common ALDH2 mutants exhibited a significant reduction in activity compared with the wild type enzyme in vitro and in 3T3 cells overexpressing each of the variants, and a greater ethanol-induced toxicity. As Alda-1, previously identified activator, did not activate some of the new mutant ALDH2 enzymes, we continued the screen and identified Alda-64, which is effective in correcting the loss of activity in most of these new and common ALDH2 variants. INTERPRETATION: Since ~80% of the world population consumes ethanol and since acetaldehyde accumulation contributes to a variety of diseases, the identification of additional inactivating variants of ALDH2 in different ethnic groups may help develop new 'precision medicine' for carriers of these inactive ALDH2.

An integrative bioinformatics pipeline to demonstrate the alteration of the interaction between the ALDH2*2 allele with NAD+ and Disulfiram.

Alcohol use disorder (AUD) is a multifactorial psychiatric behavior disorder. Disulfiram is the first approved drug by the Food and Drug Administration for alcohol-dependent patients, which targets the ALDH2 enzyme. Several genes are known to be involved in alcohol metabolism; mutations in any of these genes are known to be associated with AUD. The E504K mutation in the ALDH2 of the precursor protein or the E487K of the mature protein (E504K/E487K; ALDH2*2 allele) is carried by approximately 8% of the world population. In this study, we aimed to test the known inactive allele ALDH2*2, to validate the use of our extensive computational pipeline (in silico tools, molecular modeling, and molecular docking) for testing the interaction between the ALDH2*2 allele, NAD+, and Disulfiram. In silico predictions showed that the E504K variant of ALDH2 to be pathogenic and destabilizing with the maximum number of prediction in silico tools. Consequently, we studied the effect of this mutation mainly on the interaction between NAD+ -E504K and Disulfiram-E504K complexes using molecular docking technique, and molecular dynamics (MD) analysis. From the molecular docking analysis with NAD+ , we observed that the interaction affinity of the NAD+ decreases with the impact of E504K variant. On the other hand, the drug Disulfiram showed similar interaction in both the native and mutant ALDH2 proteins. Further, the comprehensive MD analysis predicted that the E504K destabilizes the protein and influences the NAD+ and Disulfiram interactions. Our findings reveal that the interaction of NAD+ to the protein is disturbed by the E504K/E487K variant whereas the drug Disulfiram has a similar effect as both native ALDH2 and ALDH2 bearing E504K/E487K variant. This study provides a platform to understand the effect of E504K/E487K on the molecular interaction with NAD+ and Disulfiram.

Alcohol Metabolic Inefficiency: Structural Characterization of Polymorphism-Induced ALDH2 Dysfunctionality and Allosteric Site Identification for Design of Potential Wildtype Reactivators.

Liver mitochondrial aldehyde dehydrogenase 2 (ALDH2) enzyme is responsible for the rapid conversion of acetaldehyde to acetic acid. ALDH2 (E487K) polymorphism results in an inactive allele (ALDH2*2) which cause dysfunctional acetaldehyde metabolism. The 3D structure of an enzyme is crucial to its functionality and a disruption in its structural integrity could result in its metabolic inefficiency and dysfunctionality. Allosteric targeting of polymorphs could facilitate the restoration of wildtype functionalities in ALDH2 polymorphs and serve as an advancement in the treatment of associated diseases. Therefore, structural insights into ALDH2*2 polymorph could reveal the varying degree of alterations which occur at its critical domains and accounts for enzymatic dysfunctionality. In this study, we report the structural characterization of ALDH2*2 polymorph and its critical domains using computational tools. Our findings revealed that the polymorph exhibited significant alterations in stability and flexibility at the catalytic and co-enzyme-binding domain. Moreover, there was an increase in the solvent-exposed surface residues and this indicates structural perturbations. Analysis of the interaction network at ALDH2*2 catalytic domain revealed residual displacement and interaction loss when compared to the wildtype thereby providing insight into the catalytic inefficiency of the polymorph. Interestingly, perturbations induced by ALDH2 polymorphism involves the re-orientation of surface residues, which resulted in the formation of surface exposed pockets. These identified pockets could be potential sites for allosteric targeting. The findings from this study will aid the design of novel site-specific small molecule reactivators with the propensity of restoring wildtype activities for treatment of polymorphic ALDH2 related diseases.

Resveratrol attenuates excessive ethanol exposure induced insulin resistance in rats via improving NAD+ /NADH ratio.

SCOPE: Resveratrol has been shown to improve insulin resistance via activating the NAD+ -dependent deacetylase SIRT1, but the effects of resveratrol on ethanol-induced insulin resistance remain unclear. This study was designed to explore the potential mechanism by which resveratrol ameliorated ethanol-induced insulin resistance, focusing on its regulations on the ratio of NAD+ /NADH and SIRT1 expression. METHODS AND RESULTS: Male Sprague-Dawley rats were fed either control or ethanol liquid diets containing 0.8, 1.6 and 2.4 g/kg·bw ethanol with or without 100 mg/kg·bw resveratrol for 22 weeks. Resveratrol improved ethanol (2.4 g/kg·bw) induced reductions in insulin sensitivity, SIRT1 expression (51%, P < 0.05), NAD+ /NADH ratio (196%, P < 0.01) as well as the expression and activity of ALDH2 while decreased the augmentations in the expression and activity of ADH and CYP2E1. In primary rat hepatocytes, ethanol exposure (25 mmol/L, 24 h) similarly decreased SIRT1 expression and NAD+ /NADH ratio (33%, P < 0.05; 32%, P < 0.01), and 0.1 µmol/L resveratrol treatment reversed these decreases and inhibited the expressions of ADH and CYP2E1. CONCLUSION: Resveratrol exhibits benefits against ethanol-induced insulin resistance via improving the ratio of NAD+ /NADH to regulate SIRT1, which is associated with the modulation of ethanol metabolism enzymes.

Aldehyde dehydrogenase 2 activation and coevolution of its εPKC-mediated phosphorylation sites.

BACKGROUND: Mitochondrial aldehyde dehydrogenase 2 (ALDH2) is a key enzyme for the metabolism of many toxic aldehydes such as acetaldehyde, derived from alcohol drinking, and 4HNE, an oxidative stress-derived lipid peroxidation aldehyde. Post-translational enhancement of ALDH2 activity can be achieved by serine/threonine phosphorylation by epsilon protein kinase C (εPKC). Elevated ALDH2 is beneficial in reducing injury following myocardial infarction, stroke and other oxidative stress and aldehyde toxicity-related diseases. We have previously identified three εPKC phosphorylation sites, threonine 185 (T185), serine 279 (S279) and threonine 412 (T412), on ALDH2. Here we further characterized the role and contribution of each phosphorylation site to the enhancement of enzymatic activity by εPKC. METHODS: Each individual phosphorylation site was mutated to a negatively charged amino acid, glutamate, to mimic a phosphorylation, or to a non-phosphorylatable amino acid, alanine. ALDH2 enzyme activities and protection against 4HNE inactivation were measured in the presence or absence of εPKC phosphorylation in vitro. Coevolution of ALDH2 and its εPKC phosphorylation sites was delineated by multiple sequence alignments among a diverse range of species and within the ALDH multigene family. RESULTS: We identified S279 as a critical εPKC phosphorylation site in the activation of ALDH2. The critical catalytic site, cysteine 302 (C302) of ALDH2 is susceptible to adduct formation by reactive aldehyde, 4HNE, which readily renders the enzyme inactive. We show that phosphomimetic mutations of T185E, S279E and T412E confer protection of ALDH2 against 4HNE-induced inactivation, indicating that phosphorylation on these three sites by εPKC likely also protects the enzyme against reactive aldehydes. Finally, we demonstrate that the three ALDH2 phosphorylation sites co-evolved with εPKC over a wide range of species. Alignment of 18 human ALDH isozymes, indicates that T185 and S279 are unique ALDH2, εPKC specific phosphorylation sites, while T412 is found in other ALDH isozymes. We further identified three highly conserved serine/threonine residues (T384, T433 and S471) in all 18 ALDH isozymes that may play an important phosphorylation-mediated regulatory role in this important family of detoxifying enzymes. CONCLUSION: εPKC phosphorylation and its coevolution with ALDH2 play an important role in the regulation and protection of ALDH2 enzyme activity.

Alda-1 modulates the kinetic properties of mitochondrial aldehyde dehydrogenase (ALDH2).

Mitochondrial aldehyde dehydrogenase (ALDH2) has been proposed as a key enzyme in cardioprotection during ischemia-reperfusion processes. This proposal led to the search for activators of ALDH2 with the aim to develop cardioprotective drugs. Alda-1 was the first activator of ALDH2 identified and its cardioprotective effect has been extensively proven in vivo; however, the mechanism of activation is not fully understood. A crystallographic study showed that Alda-1 binds to the entrance of the aldehyde-binding site; therefore, Alda-1 should in essence be an inhibitor. In the present study, kinetic experiments were performed to characterize the effect of Alda-1 on the properties of ALDH2 (kinetic parameters, determination of the rate-limiting step, reactivity of the catalytic cysteine) and on the kinetic mechanism (type of kinetics, sequence of substrates entering, and products release). The results showed that Alda-1 dramatically modifies the properties of ALDH2, the Km for NAD+ decreased by 2.4-fold, and the catalytic efficiency increased 4.4-fold; however, the Km for the aldehyde increased 8.6-fold, thus, diminishing the catalytic efficiency. The alterations in these parameters resulted in a complex behavior, where Alda-1 acts as inhibitor at low concentrations of aldehyde and as an activator at high concentrations. Additionally, the binding of Alda-1 to ALDH2 made the deacylation less limiting and diminished the pKa of the catalytic cysteine. Finally, NADH inhibition patterns indicated that Alda-1 induced a change in the sequence of substrates entry and products release, in agreement with the proposal of both substrates entering ALDH2 by the NAD+ entrance site.

Understanding the Structural Basis of ALDH-2 Inhibition by Molecular Docking.

BACKGROUND: The ALDH-2 enzyme has been identified as an important therapeutic target for the development of new drugs for the treatment of cocaine addiction. Several studies involving the synthesis, the design and pharmacological evaluation of daidzin (isoflavonoid inhibitor of ALDH-2) analogs were conducted. METHODS: In this study, we used two in silico approaches effective to understand the mechanism of inhibition of ALDH-2 enzyme, the molecular docking and constructing a pharmacophore model, and we established a correlation between the inhibitory profiles of daidzin and its analog for ALDH-2 and their interaction profiles to understand the structural basis for their inhibitory activities. RESULTS: Docking is efficient and opportune tool to guide the design of new inhibitors of ALDH-2. From the results of the molecular docking studies performed herein and their relationships with the inhibitory profiles of some daidzin analogs described previously in the literature, pharmacophore groups associated with ALDH-2 enzyme recognition were identified. Summarizing our findings, the presence of a linear alkyl chain with a terminal hydrogen bond acceptor group in position 7 is important for the interaction with the Gln-289 residue. Additionally, the presence of a group that is capable of performing hydrogen bonding interactions as either a donor or acceptor in the 4' position is important for the interaction with the Glu-268 residue; this group is the primary pharmacophore that should be attached to the scaffold of the aromatic nucleus of an ideal inhibitor of ALDH-2. CONCLUSION: The structure inhibitory activity relationships among daidzin analogs were established using a molecular docking tool, thus identifying the structural reasons for the inhibition of the ALDH-2 enzyme. We defined the key pharmacophore groups required for enzyme inhibition and the maintenance of interactions with the amino acids Gln-289 and Glu-268, which are related to the potency of the ALDH-2 inhibitors. This study is highly relevant for the design of new ALDH-2 inhibitors using different medicinal chemistry tools to develop novel therapies for controlling cocaine addiction.