Effect of environmental substances on the activity of arylamine N-acetyltransferases

Arylamine N-acetyltransferases (NAT) are xenobiotic-metabolizing enzymes responsible for the acetylation of many aromatic arylamine and heterocyclic amines, thereby playing an important role in both detoxification and activation of numerous drugs and carcinogens. Two closely related isoforms (NAT1 and NAT2) have been described in humans. NAT2 is mainly expressed in liver and gut, whereas NAT1 is found in a wide range of tissues. Interindividual variations in NAT genes have been shown to be a potential source of pharmacological and/or pathological susceptibility. In addition, there is now evidence that non genetic factors, such as substrate-dependent inhibition, drug interactions or cellular redox conditions may also contribute to NAT activity. The recent findings reviewed here provide possible mechanisms by which these environmental determinants may affect NAT activity. Interestingly, these data could contribute to the development of selective NAT inhibitors for the treatment of cancer and microbial diseases.     

尿苷二磷酸葡萄糖醛酸转移酶与内源性物质的相互作用

尿苷二磷酸葡萄糖醛酸转移酶(UGT)是人体重要的II相代谢酶,代谢药物的同时也代谢许多重要的内源性物质,如胆红素、甲状腺激素、雌激素、雄激素、胆汁酸和5-羟色胺等。该酶对许多内源性物质的代谢是灭活和清除这些内源性物质的关键步骤,能够防止内源性物质累积引发的毒性反应,或及时终止内源性激素的信号防止肿瘤的发生。然而,内源性物质对UGT酶也会产生影响,特别是在一些生理病理条件下,某些内源性物质能够抑制UGT酶活性,影响其参与的代谢反应。将就内源性物质和UGT酶的相互作用做一综述,以引起人们对UGT酶和内源性物质相互作用的关注。关键词:药物代谢;尿苷二磷酸葡萄糖醛酸转移酶;内源性物质     

Synthesis and structure-activity relationship of alpha-sulfonylhydroxamic acids as novel,orally active matrix metalloproteinase inhibitors for the treatment of osteoarthritis

The matrix metalloproteinases (MMPs) are a family of zinc-containing endopeptidases that play a key role in both physiological and pathological tissue degradation. These enzymes are strictly regulated by endogenous inhibitors such as tissue inhibitors of MMPs and alpha(2)-macroglobulins. Overexpression of these enzymes has been implicated in various pathological disorders such as arthritis, tumor metastasis, cardiovascular diseases, and multiple sclerosis. Developing effective small-molecule inhibitors to modulate MMP activity is one approach to treat these degenerative diseases. The present work focuses on the discovery and SAR of novel N-hydroxy-alpha-phenylsulfonylacetamide derivatives, which are potent, selective, and orally active MMP inhibitors.     

2-Bromoethylamine as a potent selective suicide inhibitor for semicarbazide-sensitive amine oxidase

Semicarbazide-sensitive amine oxidase (SSAO) catalyzes the deamination of methylamine and aminoacetone to produce toxic aldehydes, i.e. formaldehyde and methylglyoxal, as well as hydrogen peroxide and ammonia. An increase of SSAO activity was detected by different laboratories in patients suffering from vascular disorders, i.e. diabetes and myocardial infarction. The enzyme has been suggested to play a role in vascular endothelial damage and atherogenesis. To date, there are no selective SSAO inhibitors. In the present study, 2-bromoethylamine (2-BrEA) was found to be a highly effective and selective inhibitor of SSAO obtained from different sources. The inhibition was irreversible and time dependent. It was competitive when the enzyme was not preincubated with the inhibitor, but became noncompetitive after incubation of the enzyme with 2-BrEA. The aldehyde trapping agent o-phenylenediamine was capable of preventing 2-BrEA-induced inhibition of SSAO activity. An aldehyde product was detected to be an initial product of 2-BrEA after it was incubated with SSAO. The inhibition, therefore, is mechanism-based. The SSAO inhibitory effects of eight structural analogues of 2-BrEA were assessed. It was concluded that a bromine atom at the beta position is quite important for exerting high potency of SSAO inhibition. The inhibition of SSAO activity by 2-BrEA was also demonstrated in vivo. It increased the urinary excretion of methylamine, an endogenous substrate for SSAO, in mice. 2-BrEA can be employed as a very useful tool in the investigation of SSAO.     

Oxidation of 2-t-butyl-4-methoxyphenol (BHA) by horseradish and mammalian peroxidase systems

Di-BHA, 2,2'-dihydroxy-3,3'-di-t-butyl-5,5'-dimethoxy-diphenyl, was isolated as the product of the reaction of either commercial horseradish peroxidase or partially purified rat intestine peroxidase (Donor-H₂O₂ oxidoreductase, EC 1.11.1.7.) and hydrogen peroxide with 2-t-butyl-4-methoxyphenol (BHA). BHA, Di-BHA and other cyclic compounds possessing a hydroxyl group in the ring were found to be competitive inhibitors with respect to guaiacol, and non-competitive inhibitors with respect to hydrogen peroxide in a system containing guaiacol, hydrogen peroxide and peroxidase. A free radical intermediate generated during peroxidatic oxidation of BHA was detected and identified by means of EPR spectroscopy. It was estimated that during one hour incubation the peroxidase activity present in the rat ileum mucosa is able to oxidise 12μmoles BHA at a saturating concentration. It is suggested that peroxidative oxidation at the intestinal wall may represent a contribution to the inactivation of some phenol derivatives potentially toxic to mammals.     

Aldehyde toxicity and metabolism: the role of aldehyde dehydrogenases in detoxification,drug resistance and carcinogenesis

Aldehydes are carbonyl compounds found ubiquitously in the environment, derived from both natural and anthropogenic sources. As the aldehydes are reactive species, therefore, they are generally toxic to the body. To reduce the toxicity and pathogenesis related to aldehydes, the human body contains several aldehyde metabolizing enzyme systems including aldehyde oxidases, cytochrome P450 enzymes, aldo-ketoreductases, alcohol dehydrogenases, short-chain dehydrogenases/reductases and aldehyde dehydrogenases (ALDHs). These enzyme systems maintain a low level of aldehydes in the body by catalytically converting them into less-harmful and easily excreted products. The human ALDH (hALDH) superfamily consists of 20 functional ALDH genes identified so far at distinct chromosomal locations, expressing 20 ALDH proteins, which belong to 11 different ALDH families. They are involved in the NAD(P)⁺-dependent oxidation of a wide range of exogenous and endogenous aldehydes to their corresponding carboxylic acids. The hALDHs are present in all sub-cellular locations and have a wide tissue distribution. This review gives an account of aldehydes; their source, toxicity and metabolism, different aldehyde metabolizing enzymes with special emphasis on ALDHs including their biochemical, physiological and pathophysiological roles in the body.     

Contribution of serum and cellular semicarbazide-sensitive amine oxidase to amine metabolism and cardiovascular toxicity.

Semicarbazide-sensitive amine oxidase (SSAO) plays a role in the in vivo and in vitro toxicity of several environmental and endogenous amines. We investigated the role of SSAO as a component of cell culture medium (through addition of fetal calf serum (FCS)) compared to intracellular SSAO in the in vitro cytotoxicity of three amines and metabolites. Smooth muscle cells and beating cardiac myocytes were grown in 96-well plates and exposed to various concentrations and combinations of FCS in medium, amines (allylamine, AA; benzylamine, BZA; and methylamine, MA), and amine metabolites (aldehydes: acrolein, benzaldehyde, and formaldehyde; hydrogen peroxide, H2O2; ammonia, NH3). Amine and amine metabolite cytotoxicity was quantified by monitoring cell viability. SSAO activity was measured in FCS, cardiovascular cells, or rat plasma by a radioenzymatic assay using [14C]BZA. Our data show that AA and its aldehyde metabolite, acrolein, were the most toxic compounds to both cell types. However, AA toxicity was FCS-dependent in both cell types, while BZA, MA, and amine metabolite (i.e., aldehydes, H2O2, and NH3) cytotoxicity showed little FCS dependence. In these experiments, medium containing 10% FCS had a calculated amine metabolic capacity that was 30- to 50-fold that of the cultured smooth muscle cellular content in a single well of a 96-well plate. Our study demonstrates that SSAO in FCS contributes to amine metabolism and cytotoxicity to rat cardiovascular cells in vitro and how critical it is to evaluate serum for its role in mechanisms of amine toxicity in vitro and in vivo.     

Therapeutic applications of organosulfur compounds as novel hydrogen sulfide donors and/or mediators

Hydrogen sulfide, once considered as toxic gas, is now recognized as an important biological mediator. The deficiency of hydrogen sulfide could lead to various pathological changes, such as arterial and pulmonary hypertension, Alzheimer's disease, gastric mucosal injury and liver cirrhosis. However, excessive production of hydrogen sulfide, by using inorganic hydrogen sulfide donors such as NaHS, may contribute to the pathogenesis of inflammatory diseases, septic shock, cerebral stroke and mental retardation in patients with Down syndrome. Therefore, an increasing interest in organic molecules that are capable of regulating the formation of hydrogen sulfide has extended in recent years. Allium vegetables are one natural source of organic sulfur-containing compounds and have been widely investigated regarding their therapeutic applications, and it has been proven that the ingredients of garlic, such as diallyl disulfide, diallyl trisulfide and S-ally cysteine act as hydrogen sulfide donors or mediators in pharmaceutical studies. In addition, S-propargyl cysteine (ZYZ-802) and S-propyl cysteine, two synthetic cysteine analogs, have been examined and could be used to treat ischemic heart disease via modulation of the hydrogen sulfide pathway. In addition, drugs containing hydrogen sulfide-releasing moieties have been synthesized and widely reported in recent years, such as S-nonsteroidal anti-inflammatory drugs and the derivative of Lawesson's reagents, which exhibit varied biological effects in experiments. As cystathionine β-synthase and cystathionine γ-lyase are the enzymes that are able to catalyze the production of endogenous hydrogen sulfide from cysteine, their inhibitors, such as dl-propylargylglycine and β-cyanoalanine, have been frequently used in studies on the biological mechanism of hydrogen sulfide. All these hydrogen sulfide donors, mediators and inhibitors have provided useful tools in the research of a variety of biological effects and are promising drug candidates of hydrogen sulfide.     

Structure and regulation of the drug-metabolizing enzymes arylamine N-acetyltransferases

Arylamine N-acetyltransferases (NAT) are xenobiotic-metabolizing enzymes responsible for N-acetylation of many arylamines. They are also important for O-acetylation of N-hydroxylated heterocyclic amines. These enzymes play thus an important role in the detoxification and activation of numerous therapeutic drugs and carcinogens. Two closely related polymorphic isoforms (NAT1 and NAT2) have been described in humans and interindividual variations in NAT genes have been shown to be a potential source of adverse drug reaction. In addition, NAT1 and/or NAT2 phenotypes may modulate the risk of certain cancers in people exposed to aromatic amine carcinogens. Recent advances on the regulation of human NAT1 activity has shown that hydroxylamine and/or nitroso intermediates of NAT1 substrates inhibit the enzyme through direct irreversible interaction with its catalytic cysteine residue. Oxidative molecules such as hydrogen peroxide, S-nitrosothiols and peroxynitrite have also been shown to inactivate reversibly or irreversibly the enzyme in a similar manner. In this review, after summarizing the general background on human NAT enzymes, we focus on the recent developments on the regulation of the activity of these drug-metabolizing enzymes by substrate-intermediates and by oxidant molecules. The recent findings reviewed here provide possible mechanisms by which these non genetic determinants inhibit NAT1 activity and thereby may affect drug efficacy/toxicity.     

Calpain inhibition: a therapeutic strategy targeting multiple disease states

The calpains represent a well-conserved family of calcium-dependent cysteine proteases. They consist of several ubiquitous and tissue specific isoforms and exhibit broad substrate specificity influencing many aspects of cell physiology including migration, proliferation and apoptosis. Calpain activity in vivo is tightly regulated by its natural endogenous inhibitor calpastatin. Calpastatin specifically inhibits calpain and not other cysteine proteases by interaction with several sites on the calpain molecule. Inappropriate regulation of the calpain-calpastatin proteolytic system is associated with several important human pathological disorders including muscular dystrophy, cancer, Alzheimer's disease, neurological injury, ischaemia/reperfusion injury, atherosclerosis, diabetes and cataract formation. Recent advances in elucidating the tertiary structures of calpain 2 and its regulatory domain calpain 4, together with identification of new modes of regulating calpain activity provide new opportunities for the design of novel calpain inhibitors. Several classes of inhibitors, including peptidyl epoxide, aldehyde, and ketoamide inhibitors, targeting the active site have proven effective against the calpains and are in the process of evaluation in animal models of human disease. However, a major limitation to the clinical use of such inhibitors is their lack of specificity among cysteine proteases and other proteolytic enzymes. The development of a new class of calpain inhibitors that interact with domains outside of the catalytic site of calpain may provide greater specificity and therapeutic potential.     

Neurotoxicity and metabolism of the catecholamine-derived 3,4-dihydroxyphenylacetaldehyde and 3,4-dihydroxyphenylglycolaldehyde: the role of aldehyde dehydrogenase

Aldehydes are highly reactive molecules formed during the biotransformation of numerous endogenous and exogenous compounds, including biogenic amines. 3,4-Dihydroxyphenylacetaldehyde is the aldehyde metabolite of dopamine, and 3,4-dihydroxyphenylglycolaldehyde is the aldehyde metabolite of both norepinephrine and epinephrine. There is an increasing body of evidence suggesting that these compounds are neurotoxic, and it has been recently hypothesized that neurodegenerative disorders may be associated with increased levels of these biogenic aldehydes. Aldehyde dehydrogenases are a group of NAD(P)+ -dependent enzymes that catalyze the oxidation of aldehydes, such as those derived from catecholamines, to their corresponding carboxylic acids. To date, 19 aldehyde dehydrogenase genes have been identified in the human genome. Mutations in these genes and subsequent inborn errors in aldehyde metabolism are the molecular basis of several diseases, including Sj?gren-Larsson syndrome, type II hyperprolinemia, gamma-hydroxybutyric aciduria, and pyridoxine-dependent seizures, most of which are characterized by neurological abnormalities. Several pharmaceutical agents and environmental toxins are also known to disrupt or inhibit aldehyde dehydrogenase function. It is, therefore, possible to speculate that reduced detoxification of 3,4-dihydroxyphenylacetaldehyde and 3,4-dihydroxyphenylglycolaldehyde from impaired or deficient aldehyde dehydrogenase function may be a contributing factor in the suggested neurotoxicity of these compounds. This article presents a comprehensive review of what is currently known of both the neurotoxicity and respective metabolism pathways of 3,4-dihydroxyphenylacetaldehyde and 3,4-dihydroxyphenylglycolaldehyde with an emphasis on the role that aldehyde dehydrogenase enzymes play in the detoxification of these two aldehydes.     

Lactoperoxidase-catalyzed activation of carcinogenic aromatic and heterocyclic amines

Lactoperoxidase, an enzyme secreted from the human mammary gland, plays a host defensive role through antimicrobial activity. It has been implicated in mutagenic and carcinogenic activation in the human mammary gland. The potential role of heterocyclic and aromatic amines in the etiology of breast cancer led us to examination of the lactoperoxidase-catalyzed activation of the most commonly studied arylamine carcinogens: 2-amino-1-methyl-6-phenylimidazo[4,5-b]-pyridine (PhIP), benzidine, 4-aminobiphenyl (ABP), 2-amino-3-methylimidazo[4,5-f]quinoline (IQ), and 2-amino-3,8-dimethylimidazo[4,5-f]quinoxaline (MeIQx). In vitro activation was performed with lactoperoxidase (partially purified from bovine milk or human milk) in the presence of hydrogen peroxide and calf thymus DNA. Products formed during enzymatic activation were monitored by HPLC with ultraviolet and radiometric detection. Two of these products were characterized as hydrazo and azo derivatives by means of mass spectrometry. The DNA binding level of 3H- and 14C-radiolabeled amines after peroxidase-catalyzed activation was dependent on the hydrogen peroxide concentration, and the highest levels of carcinogen binding to DNA were observed at 100 microM H2O2. Carcinogen activation and the level of binding to DNA were in the order of benzidine > ABP > IQ > MeIQx > PhIP. One of the ABP adducts was identified, and the level at which it is formed was estimated to be six adducts/10(5) nucleotides. The susceptibility of aromatic and heterocyclic amines for lactoperoxidase-catalyzed activation and the binding levels of activated products to DNA suggest a potential role of lactoperoxidase-catalyzed activation of carcinogens in the etiology of breast cancer.     

Thromboxane synthase inhibition potentiates washed platelet activation by endogenous and exogenous arachidonic acid

The effect of the thromboxane (TX) synthase inhibitors dazoxiben and imidazole on platelet activation by endogenous and exogenous arachidonic acid (AA) was tested with human washed platelets. Dazoxiben (1-20 microM) inhibited the formation of TXB2 and markedly enhanced the shape change, aggregation, and (3H)serotonin release induced by added AA or when prostaglandin synthesis from endogenous AA was triggered by collagen, hydrogen peroxide or methyl mercury chloride (methyl-Hg). Platelet activation by hydrogen peroxide (20-1200 microM) or methyl-Hg (1-5 microM) was entirely dependent on endogenous prostaglandin (PG) synthesis since acetylsalicylic acid (ASA), indomethacin or the cyclic endoperoxide/TXA2-antagonist BM 13.177 counteracted these stimulants with and without dazoxiben. Apparently, the potentiation is due to accumulating cyclic endoperoxides which during TX synthase inhibition reach greater platelet-activating potency than TXA2. Albumin or human platelet-poor plasma inhibited the platelet activation by hydrogen peroxide and methyl-Hg and suppressed the potentiation by dazoxiben. The latter effect of albumin may result from its PGD isomerase activity which redirects the cyclic endoperoxide metabolism to the platelet-inhibitory PGD2. The results show that non-platelet factors such as albumin are necessary to prevent a potentiating effect of TX synthase inhibitors on platelet activation.     

Contribution of aldehyde oxidase, xanthine oxidase, and aldehyde dehydrogenase on the oxidation of aromatic aldehydes

Aliphatic aldehydes have a high affinity toward aldehyde dehydrogenase activity but are relatively poor substrates of aldehyde oxidase and xanthine oxidase. In addition, the oxidation of xenobiotic-derived aromatic aldehydes by the latter enzymes has not been studied to any great extent. The present investigation compares the relative contribution of aldehyde dehydrogenase, aldehyde oxidase, and xanthine oxidase activities in the oxidation of substituted benzaldehydes in separate preparations. The incubation of vanillin, isovanillin, and protocatechuic aldehyde with either guinea pig liver aldehyde oxidase, bovine milk xanthine oxidase, or guinea pig liver aldehyde dehydrogenase demonstrated that the three aldehyde oxidizing enzymes had a complementary substrate specificity. Incubations were also performed with specific inhibitors of each enzyme (isovanillin for aldehyde oxidase, allopurinol for xanthine oxidase, and disulfiram for aldehyde dehydrogenase) to determine the relative contribution of each enzyme in the oxidation of these aldehydes. Under these conditions, vanillin was rapidly oxidized by aldehyde oxidase, isovanillin was predominantly metabolized by aldehyde dehydrogenase activity, and protocatechuic aldehyde was slowly oxidized, possibly by all three enzymes. Thus, aldehyde oxidase activity may be a significant factor in the oxidation of aromatic aldehydes generated from amines and alkyl benzenes during drug metabolism. In addition, this enzyme may also have a role in the catabolism of biogenic amines such as dopamine and noradrenaline where 3-methoxyphenylacetic acids are major metabolites.     

Does more MnSOD mean more hydrogen peroxide?

Superoxide dismutases (SODs) are a family of important antioxidant enzymes that catalyze the conversion of superoxide to hydrogen peroxide and oxygen. Hydrogen peroxide is then detoxified by a host of antioxidant enzymes. A common misconception is that the increased MnSOD levels will result in increased hydrogen peroxide levels. Herein we offer some potential reasons for this confusion, as well as some potential resolutions. Data are offered that demonstrate the ability of MnSOD, in the presence of nitric oxide, to utilize hydrogen peroxide to produce superoxide and the more toxic oxidant, peroxynitrite.     

凋亡抑制蛋白的研究进展

近年来新发现的凋亡抑制蛋白(inhibitor of apoptosis proteins,IAPs),是一类高度保守的内源性抗凋亡基因家族表达产物,广泛存在于许多物种如病毒、真核生物、哺乳动物中,起着抑制细胞凋亡的作用.IAPs主要通过抑制caspase,参与TNFR介导的信号转导等途径发挥抗凋亡作用,与恶性肿瘤、神经系统病变等密切相关.该文就IAPs的结构、抑制凋亡的机制及其在临床疾病中的研究现状作一综述.     

Renin inhibitors. Dipeptide analogues of angiotensinogen utilizing a dihydroxyethylene transition-state mimic at the scissile bond to impart greater inhibitory potency

The synthesis of diol-containing renin inhibitors has revealed that a simple vicinal diol functionality corresponding to the scissile Leu-Val bond in human angiotensinogen is capable of imparting inhibitory activity at a comparable or higher level than either the corresponding aldehyde or hydroxymethyl functionality (compare inhibitors 2a-c or 3a-c). This finding has led to the further optimization of a series of small transition-state analogue inhibitors by the inclusion of a second hydroxyl group in the Leu-Val surrogate to give compounds that inhibited human renin in the 200-700-pM range (e.g. 43, 45, 63, 66). The magnitude of effect of the second hydroxyl group on potency is not only dictated by the absolute stereochemistry of the diol but also by the side chain of the P1 residue. Molecular modeling of the diol-containing inhibitors suggests that one of the hydroxyl groups hydrogen bonds to Asp 32 and Asp 215, while the second hydrogen bonds to Asp 215. These diol inhibitors are extremely selective for human renin over the related enzymes cathepsin D, pepsin, and gastricsin. At high concentrations, compounds containing a leucine or phenylalanine rather than a histidine at the P2 position gave only minor amounts of inhibition of the other enzymes. Inhibitor 43 suppressed plasma renin activity completely and lowered mean blood pressure in monkeys after both intravenous and intraduodenal administration, but the blood pressure drop lasted less than 1 h. Monitoring the blood levels of 43 by enzyme inhibition assay after intraduodenal administration to monkeys or oral administration to rats revealed low absorption and rapid clearance. While intratracheal administration to dogs gave approximately 50% bioavailability, rapid clearance was still a problem. After examination of inhibitor 45 in a sensitive primate model in which monkeys were rendered both hypertensive and hyperreninemic, the effects on lowering systolic but not diastolic pressure were apparent even after 22 h postdosing. Details on the synthesis, in vitro structure-activity relationships, molecular modeling, in vivo activity, and metabolism of these inhibitors are described.     

Novel marine and microbial natural product inhibitors of vacuolar ATPase

Vacuolar-ATPase (V-ATPase) has been proposed as a drug target in osteoporosis due to its involvement in bone resorption, and as a target in cancer due to potential involvement in tumor invasion and metastasis. The classical selective inhibitors of V-ATPase are microbial macrolides of the bafilomycin and concanamycin class. These inhibitors have proven to be too toxic for therapeutic use, however recent structure-activity studies on bafilomycins, and the isolation of novel macrolide structures from marine sources, have provided new avenues for development of potentially less toxic V-ATPase inhibitors. The novel salicylihalamide and lobatamide series of compounds were predicted to share a common mechanism of action based on the patterns of cytotoxicity produced in the NCI 60-cell cancer screen. They have subsequently been shown to selectively interact with mammalian V-ATPases, but not with fungal V-ATPases. With the recent achievement of total syntheses of salicylihalamide, lobatamide, and related compounds, the elaboration of congeners with specificity for particular enzyme isoforms may provide drug candidates which are less toxic. This review summarizes recent advances in V-ATPase inhibition and the prospects for further progress.     

Methylamine but not mafenide mimics insulin-like activity of the semicarbazide-sensitive amine oxidase-substrate benzylamine on glucose tolerance and on human adipocyte metabolism

It has been reported that benzylamine reduces blood glucose in rabbits, stimulates hexose uptake, and inhibits lipolysis in mouse, rabbit, and human adipocytes. In the presence of vanadate, benzylamine is also able to improve glucose disposal in normoglycaemic and diabetic rats. Such insulin-mimicking properties are the consequence of hydrogen peroxide production during benzylamine oxidation by semicarbazide-sensitive amine oxidase (SSAO). The aim of the study was to determine whether other SSAO-substrates could share such potential antidiabetic properties. Thus, mafenide, a synthetic antimicrobial sulfonamide structurally related to benzylamine, and which has been recently reported to interact with SSAO, was tested in the above mentioned models, in parallel with methylamine, a proposed endogenous SSAO-substrate. All tested amines stimulated glucose uptake and inhibited lipolysis in rat and mouse fat cells. Methylamine and benzylamine, but not mafenide, reduced the hyperglycaemic response during a glucose tolerance test in rabbits while the three amines tested were devoid of insulin-releasing activity under both in vivo and in vitro conditions. In human adipocytes, mafenide did not stimulate glucose transport since it was not a high-affinity substrate for SSAO and generated less hydrogen peroxide than benzylamine or methylamine. Therefore, mafenide could not be considered as an antidiabetic drug despite being oxidized and exhibiting insulin-mimicking effects in rat and mouse adipocytes. By contrast, the endogenous substrate methylamine improved glucose utilization in all in vitro and in vivo models, leading to consider novel SSAO substrates as drugs with potential anti-hyperglycaemic properties.