Biological evaluation of some selected cyclic imides: mitochondrial effects and in vitro cytotoxicity

Cyclic imides such as succinimides, maleimides, glutarimides, phthalimides and their derivatives contain an imide ring and a general structure -CO-N(R)-CO- that confers hydrophobicity and neutral characteristic. A diversity of biological activities and pharmaceutical uses have been attributed to them, such as antibacterial, antifungal, antinociceptive, anticonvulsant, antitumor. In spite of these activities, much of their action mechanisms at molecular and cellular levels remain to be elucidated. We now show the effects of several related cyclic imides: maleimides (S2, S2.1, S2.2, S3), glutarimides (S4, S5, S6), 4-aminoantipyrine derivatives (L1, F1, AL1, F1.14, F1.2) and sulfonated succinimides (RO1, FA, FE, FD, MC, DMC) on isolated rat liver mitochondria, B16-F10 melanoma cell line, peritoneal macrophages and different bacterial streams. The effects on mitochondrial respiratory parameters, cell viability and antibacterial activity were also evaluated. The results indicated that S3, S5 and S6 caused an increased oxygen consumption in the presence of ADP (state III) or its absence (state IV), while all other compounds decreased those parameters at different degrees of inhibition. All the compounds decreased the respiratory control coefficient (RCC). Loss of cell viability of peritoneal macrophages and the B16-F10 cell line was observed, L1 and S2.1 being more effective. S1, S2, S3, L1 and F1 compounds showed antibacterial activity at experimental concentrations.     

Succinimide hydroxamic acids as potent inhibitors of histone deacetylase (HDAC)

A series of succinimide hydroxamic acids was prepared and evaluated in vitro for HDAC inhibition and tumor cell antiproliferation. While the original macrocyclic analogue 6 was quite potent in both assays, several appropriately substituted non-macrocyclic succinimides, such as 23, were equipotent.     

Structural investigation of a phosphorylation-catalyzed, isoaspartate-free, protein succinimide: crystallographic structure of post-succinimide His15Asp histidine-containing protein

Aspartates and asparagines can spontaneously cyclize with neighboring main-chain amides to form succinimides. These succinimides hydrolyze to a mixture of isoaspartate and aspartate products. Phosphorylation of aspartates is a common mechanism of protein regulation and increases the propensity for succinimide formation. Although typically regarded as a form of protein damage, we hypothesize succinimides could represent an effective mechanism of phosphoaspartate autophosphatase activity, provided hydrolysis is limited to aspartate products. We previously reported the serendipitous creation of a protein, His15Asp histidine-containing protein (HPr), which undergoes phosphorylation-catalyzed formation of a succinimide whose hydrolysis is seemingly exclusive for aspartate formation. Here, through the high-resolution structure of postsuccinimide His15Asp HPr, we confirm the absence of isoaspartate residues and propose mechanisms for phosphorylation-catalyzed succinimide formation and its directed hydrolysis to aspartate. His15Asp HPr represents the first characterized protein example of an isoaspartate-free succinimide and lends credence to the hypothesis that intramolecular cyclization could represent a physiological mechanism of autophosphatase activity. Furthermore, this indicates that current strategies for succinimide evaluation, based on isoaspartate detection, underestimate the frequencies of these reactions. This is considerably significant for evaluation of protein stability and integrity.     

Identification of succinimide sites in proteins by N-terminal sequence analysis after alkaline hydroxylamine cleavage.

Under favorable conditions, Asp or Asn residues can undergo rearrangement to a succinimide (cyclic imide), which may also serve as an intermediate for deamidation and/or isoaspartate formation. Direct identification of such succinimides by peptide mapping is hampered by their lability at neutral and alkaline pH. We determined that incubation in 2 M hydroxylamine, 0.2 M Tris buffer, pH 9, for 2 h at 45 degrees C will specifically cleave on the C-terminal side of succinimides without cleavage at Asn-Gly bonds; yields are typically approximately 50%. N-terminal sequence analysis can then be used to identify an internal sequence generated by cleavage of the succinimide, hence identifying the succinimide site.     

Chemical reactivity and antimicrobial activity of N-substituted maleimides

Several N-substituted maleimides containing substituents of varying bulkiness and polarity were synthesised and tested for antimicrobial and cytostatic activity. Neutral maleimides displayed relatively strong antifungal effect minimum inhibitory concentrations (MICs in the 0.5-4 μg ml(-1) range); their antibacterial activity was structure dependent and all were highly cytostatic, with IC(50) values below 0.1 μg ml(-1). Low antimicrobial but high cytostatic activity was noted for basic maleimides containing tertiary aminoalkyl substituents. Chemical reactivity and lipophilicity influenced antibacterial activity of neutral maleimides but had little if any effect on their antifungal and cytostatic action. N-substituted maleimides affected biosynthesis of chitin and β(1,3)glucan, components of the fungal cell wall. The membrane enzyme, β(1,3)glucan synthase has been proposed as a putative primary target of N-ethylmaleimide and some of its analogues in Candida albicans cells.     

Anti-Barnacle Activities of Isothiocyanates Derived from β-Citronellol and Their Structure–Activity Relationships

Antifouling agents with low toxicity are in high demand for sustaining marine industries and the environment. This study aimed to synthesize 15 isothiocyanates derived from β-citronellol and evaluate their antifouling activities and toxicities against cypris larvae of the barnacle Amphibalanus amphitrite. The synthesized isothiocyanates exhibited effective antifouling activities (EC₅₀=0.10–3.33 μg mL⁻¹) with high therapeutic ratios (LC₅₀/EC₅₀ >30). Four isothiocyanates with an amide or isocyano group showed great potential as effective antifouling agents (EC₅₀=0.10–0.32 μg mL⁻¹, LC₅₀/EC₅₀=104–833). The enantiomers of the isothiocyanates only slightly differed in their antifouling activities. These results may serve as a basis for further research and development of β-citronellol-derived isothiocyanates as effective low-toxic antifouling agents. To the best of our knowledge, this study is the first to report the antifouling activities of isothiocyanates derived from accessible natural products.     

Highly Enantioselective Michael Addition Promoted by a New Diterpene‐Derived Bifunctional Thiourea Catalyst: A Doubly Stereocontrolled Approach to Chiral Succinimide Derivatives

A doubly stereocontrolled organocatalytic asymmetric Michael addition to the synthesis of substituted succinimides is described. Starting from aldehydes and maleimides, both enantiomers of the succinimides could be obtained in high to excellent yields (up to 98%) and enantioselectivities (up to 99%) when one of the two special chiral diterpene‐derived bifunctional thioureas was individually used as a catalyst. Moreover, these catalysts can be efficiently used in large‐scale catalytic synthesis with the same level of yield and enantioselectivity. Chirality 00:000–000, 2014. © 2014 Wiley Periodicals, Inc.     

Substituted cyclic imides as potential anti-gout agents

N-substituted cyclic imides of phthalimide, 2,3-dihydrohalazine-1,4-dione, and diphenimide were shown to reduce the serum uric acid levels in normal and hyperuric mice at 20 mg/kg/day I.P. for 14 days. The agents were potent inhibitors of commercial xanthine dehydrogenase and xanthine oxidase enzyme activities with IC50 values from 10(-7) to 10(-8) M concentrations of drug.     

N-substituted maleimide inactivation of the response to taste cell stimulation.

N-Ethylmaleimide (NEM) irreversibly inactivates the response of gustatory cells to stimulation by NaCl, sucrose and hydrogen ions. The rate of inactivation can be measured by monitoring the decay of NaCl-stimulated summated electrophysiological activity at the chorda tympani nerve in the presence of NEM. The observed pseudo first-order rate constants are linear with NEM concentration, and the second-order rate constant is 0.38 M-1 sec-1. Other N-substituted maleimides, such as N-methylmaleimide and N-butylmaleimide, which have ether:water partition coefficient and is essentially ineffective as an inactivator of the NaCl response. These results, together with the observation that the inactivation rate is independent of pH between 4.5 and 7.0, indicate the inactivation site is either intracellular or buried within the cell membrane at a locus inaccessible to most extracellular fluids. The rate of inactivation of the sucrose and HCl responses were measured indirectly and found to be comparable to the NaCl-stimulated inactivation rate, indicating the inhibited event is common to the transduction of the response for all of the stimuli examined. Possible sites of inactivation by N-substituted maleimides are considered in the context for and characterizing receptor-specific as well as other classes of taste cell inhibitors.     

Cyclic-imide-hydrolyzing activity of D-hydantoinase from Blastobacter sp. strain A17p-4.

The cyclic-imide-hydrolyzing activity of a prokaryotic cyclic-ureide-hydrolyzing enzyme, D-hydantoinase, was investigated. The enzyme hydrolyzed cyclic imides with bulky substituents such as 2-methylsuccinimide, 2-phenylsuccinimide, phthalimide, and 3,4-pyridine dicarboximide to the corresponding half-amides. However, simple cyclic imides without substituents, which are substrates of imidase (ie.g., succinimide, glutarimide, and sulfur-containing cyclic imides such as 2,4-thiazolidinedione and rhodanine), were not hydrolyzed. The combined catalytic actions of bacterial D-hydantoinase and imidase can cover the function of a single mammalian enzyme, dihydropyrimidinase. Prokaryotic D-hydantoinase also catalyzed the dehyrative cyclization of the half-amide phthalamidic acid to the corresponding cyclic imide, phthalimide. The reversible hydrolysis of cyclic imides shown by prokaryotic D-hydantoinase suggested that, in addition to pyrimidine metabolism, it may also function in cyclic-imide metabolism.     

Novel Metabolic Transformation Pathway for Cyclic Imides in Blastobacter sp. Strain A17p-4

The metabolic transformation pathway for cyclic imides in microorganisms was studied in Blastobacter sp. strain A17p-4. This novel pathway involves, in turn, hydrolytic ring opening of a cyclic imide to yield a monoamidated dicarboxylate, hydrolytic deamidation of the monoamidated dicarboxylate to yield a dicarboxylate, and dicarboxylate transformation similar to that in the tricarboxylic acid cycle. The initial step is catalyzed by a novel enzyme, imidase. Imidase and subsequent enzymes involved in this metabolic pathway are induced by some cyclic imides, such as succinimide and glutarimide. Induced cells metabolize various cyclic imides.     

A marine bacterial adhesion microplate test using the DAPI fluorescent dye: a new method to screen antifouling agents

AIMS: To develop a method to screen antifouling agents against marine bacterial adhesion as a sensitive, rapid and quantitative microplate fluorescent test. METHODS AND RESULTS: Our experimental method is based on a natural biofilm formed by mono-incubation of the marine bacterium Pseudoalteromonas sp. D41 in sterile natural sea water in a 96-well polystyrene microplate. The 4'6-diamidino-2-phenylindole dye was used to quantify adhered bacteria in each well. The total measured fluorescence in the wells was correlated with the amount of bacteria showing a detection limit of one bacterium per 5 microm(2) and quantifying 2 x 10(7) to 2 x 10(8) bacteria adhered per cm(2). The antifouling properties of three commercial surface-active agents and chlorine were tested by this method in the prevention of adhesion and also in the detachment of already adhered bacteria. The marine bacterial adhesion inhibition rate depending on the agent concentration showed a sigmoid shaped dose-response curve. CONCLUSIONS: This test is well adapted for a rapid and quantitative first screening of antifouling agents directly in seawater in the early steps of marine biofilm formation. Significance AND IMPACT OF THE STUDY: In contrast to the usual screenings of antifouling products which detect a bactericidal activity, this test is more appropriate to screen antifouling agents for bacterial adhesion removal or bacterial adhesion inhibition activities. This screening test focuses on the antifouling properties of the products, especially the initial steps of marine biofilm formation.     

Energy-dependent endocytosis in erythrocyte ghosts. 3. Hydrophobic character of maleimide inactivation sites of ATPase and of endocytosis

The effects of a variety of reactive compounds on endocytosis in erythrocyte ghosts were observed. Of these reagents, only alkylating reagents were effective at low concentrations. This suggested that an alkylatable site, probably a sulfhydryl group, was important in endocytosis. In a series of N -substituted maleimides, effectiveness of the alkylating agent in inactivating both ATPase and endocytosis correlated very well with a high value of the partition coefficient between octanol and water. This suggested that a hydrophobic region was present at the site of inactivation, so that strongly hydrophobic alkylating agents were bound more firmly by this site. The action of the N -substituted maleimides was clearly due to the reactivity of the carbon-carbon double bond in the heterocyclic ring, since saturation of this bond completely destroyed the effectiveness of the inhibitor. Statistical analysis of the dependence of the effectiveness of N-substituted maleimides upon partition coefficient and Hammett sigma parameters showed that the partition coefficient was by far the most important factor which controlled the effectiveness of these inhibitors. The sigma parameter played a lesser role. The dependence of the effectiveness of the maleimides on these two parameters was the same, within the statistical error, for both the ATPase activity and endocytosis activity. This suggested that inhibition of endocytosis was due to reaction with the same site responsible for inhibition of ATPase.     

Evaluation of apoptotic effect of cyclic imide derivatives on murine B16F10 melanoma cells

Cyclic imides are a large class of compounds obtained by organic synthesis including several sub-classes (succinimides maleimide, glutarimide, phthalimides naphtalimides, and its derivatives). Recently, some cyclic imide derivatives have shown important results as potential antitumor agents, as a Mitonafide and Amonafide. Based on this fact, we have studied antitumoral properties of nine cyclic imide derivatives, four of which are unpublished compounds, against Murine Melanoma Cells (B16F10). Initially, the MTT assay was used to select the compound with the best cytotoxic potential. After this selection, the compound 2-benzyl-1H-benzo[de]isoquinoline-1,3(2H)-dione (4), which showed the best cytotoxic effects, was evaluated by flow cytometry, and a significant increase was observed in the proportion of cells in the subG0/G1, S and G2/M phases accompanied by a significant decrease in the G0/G1 phases. Then the mechanism involved on the death route (necrosis or apoptosis) was evaluated the by bromide and acridine orange method and by an Annexin V-FITC Apoptosis Detection kit. These results confirm that the percentage of B16F10 cells observed in the sub G0/G1 phase were undergoing apoptosis. The biological effects observed in the current study for the cyclic imide derivatives suggested promising applications, especially for the prototype compound 4.     

Effect of cross-linking agents on insulin associated responses in adipocytes

The effect of 10 bifunctional cross-linking agents and four monofunctional analogues was studied on isolated adipocytes. [125I]Insulin binding and degradation, basal and insulin-stimulated glucose oxidation, and 3-O-methyl glucose uptake were measured. Two cross-linkers, which possess succinimide ester residues (disuccinimidyl suberate and dithiobis(succinimidyl propionate)) and react selectively with amino groups, appeared to react relatively specifically with the insulin receptor. Both produced a slight stimulation of basal glucose transport and metabolism, a marked inhibition of insulin-stimulated glucose transport and metabolism, and a marked decrease in insulin binding. Pretreatment of cells with unlabelled insulin partially blocked the effect of disuccinimidyl suberate, and as has been previously shown, disuccinimidyl suberate cross-linked insulin to its receptor. A monofunctional analogue of these compounds was 100-fold less active in altering cellular metabolic activity. Bisimidates, such as dimethyl suberimidate, dimethyl adipimidate, and dimethyl dithiobispropionimidate, also react with free amino groups but are more hydrophilic. These agents produced similar effects on glucose oxidation as the succinimide esters, but had little or no effect on insulin binding. The effects of these agents are not blocked by insulin and they do not cross-link insulin to its receptor. Mixed bifunctional reagents containing either a succinimide ester or an imidate and a group which reacts with thiols produced effects similar to the cross-linkers containing two succinimide groups or bisimidates, respectively. The bifunctional arylating agents difluorodinitrobenzene and bis(fluoronitrophenyl)sulfone produce marked effects on insulin binding and glucose oxidation at micromolar concentrations, but the monofunctional analogue fluorodinitrobenzene is almost equally active suggesting that with these compounds chemical modifications and not cross-linking was important. With neither the mixed bifunctional reagents, nor the arylating agents, did insulin pretreatment alter the effect of cross-linker and none of these agents cross-linked [125I]insulin to its receptor. These data suggest that the insulin receptor possesses a free amino group in a hydrophobic environment in its active site. A reactive amino group in a hydrophilic environment as well as other reactive groups are also present in some component of the insulin receptor-effector complex. Chemical modification or cross-linking of these functional groups results in an inhibition or mimicking of insulin action. Further study will be required to identify the exact locus of these sites.     

Isolation and characterization of a succinimide variant of methionyl human growth hormone.

Deamidation of asparagine and glutamine residues, isomerization of aspartic acid side chains, and racemization of the L- to the D-form of the amino acids are common spontaneous chemical reactions known to occur in proteins. Previous studies have implicated succinimides as intermediates in these reactions; however, the evidence has been indirect. Our results demonstrate, for the first time, the presence of a succinimide intermediate in an intact protein. The succinimide (cyclic imide) variant was isolated from thermally stressed recombinant methionyl human growth hormone (hGH) by high performance anion-exchange chromatography, further purified by reversed-phase high performance liquid chromatography, and analyzed by tryptic mapping. A later eluting tryptic peptide, compared with the native T12 peptide (residues 128-134, Leu-Glu-Asp-Gly-Ser-Pro-Arg), was analyzed by mass spectrometry (MS). This variant had a protonated molecular mass of 755.3 atomic mass units (u), as compared with 773.3 u for the native T12 peptide. A difference of 18 u, a loss of water, is consistent with the formation of a succinimide intermediate at Asp-130 of methionyl hGH. MS/MS analysis of the cyclic imide-containing peptide verified that the modification occurred at Asp-130. A difference of 18 u was also observed for the intact cyclic imide methionyl hGH variant (22,238 u), as measured by electrospray mass spectrometry, compared with native methionyl hGH (22,256 u).     

Inhibition by ADP of prostaglandin induced accumulation of cyclic AMP in intact human platelets

The influence of extracellular ADP on cyclic AMP accumulation within intact human platelets was studied. ADP inhibited the increase in cyclic AMP which occurs when platelets are exposed to prostaglandin E1 or I2. The degree of inhibition varied in the range 70-95% , and was half maximal at ADP concentrations of between 0.3 and 2 microM. Other naturally occurring diphosphates, i.e. GDP, IDP and UDP, were at least 100 fold less effective than ADP, and UDP at 1mM partially reversed the effect of ADP. The effect by ADP was completely reversed by ATP, but only attenuated to a minor degree of 10 mM EDTA. Increasing concentrations of ADP caused a progressive degree of inhibition of cyclic AMP accumulation, and the kinetics of this inhibition were compatible with a simple saturable process with no cooperativity. ADP added 10 seconds after prostaglandin E1 blocked cyclic AMP accumulation within 1-2 seconds, and addition of ATP after ADP and prostaglandin I2 relieved the inhibition due to ADP within 2-3 seconds. The action of ADP was blocked by sulphydryl reagents including N-substituted maleimides, cytochalasin A, NBD chloride and p-mercuribenzene sulphonate. The data were considered to be consistent with mediation of the ADP effect through a sulphydryl-bearing specific extracellular receptor coupled to the adenylate cyclase.     

Antifungal, cytotoxic and SAR studies of a series of N-alkyl, N-aryl and N-alkylphenyl-1,4-pyrrolediones and related compounds

The synthesis, in vitro evaluation and SAR studies of 67 maleimides and derivatives acting as antifungal agents are reported. A detailed SAR study supported by theoretical calculations led us to determine that: an intact maleimido ring appears to be necessary for a strong antifungal activity, dissimilarly affected by the substituents in positions 2 and 3. The best activities were shown by 2,3-nonsubstituted followed by 2,3 dichloro- and 2-methyl-substituted maleimides. They all were fungicide rather than fungistatic enhancing the importance of their antifungal activity. 2,3-Dimethyl and 2,3-diphenyl-maleimides possessed marginal or null activity. The presence of a flexible connecting chain in N-phenylalkyl maleimides appears not to be essential for antifungal activity, although its length shows a correlation with the antifungal behavior, displaying maleimides with alkyl chains of n=3 and n=4 the best antifungal activities in most fungi. Different substituents on the benzene ring did not have a clear influence on the activity. Values of chemical potential properties as well as of energy do not sufficiently discriminate between active and inactive compounds. Nevertheless, it was found that, although logP alone is not strong enough to properly predict the antifungal activity, the comparison of its values for compounds within the same sub-type, showed an enhancement of antifungal activity along with an increment of lipophilicity. In addition, the LUMO's electronic clouds of the highly active compounds showed to be concentrated on the imido ring, indicating that their carbon atoms are potential sites for nucleophilic attack. Same results were obtained from MEPs. Most of the active compounds did not show cytotoxic activity against human cancer cell lines and no one possessed hemolytic activity, indicating that their activity is selective to pathogenic fungi and that they are not toxic at MIC concentrations.     

Evidence for the Existence of Two Essential and Proximal Cysteinyl Residues in NADP-Malic Enzyme from Maize Leaves

Incubation of maize (Zea mays) leaf NADP-malic enzyme with monofunctional and bifunctional N-substituted maleimides results in an irreversible inactivation of the enzyme. Inactivation by the monofunctional reagents, N-ethylmaleimide (NEM) and N-phenylmaleimide, followed pseudo-first-order kinetics. The maximum inactivation rate constant for phenylmaleimide was 10-fold higher than that for NEM, suggesting a possible hydrophobic microenvironment of the residue(s) involved in the modification of the enzyme. In contrast, the inactivation kinetics with the bifunctional maleimides, ortho-, meta-, and para-phenylenebismaleimide, were biphasic, probably due to different reactivities of the groups reacting with the two heads of these bifunctional reagents, with a possible cross-linking of two sulfhydryl groups. The inactivation by mono and bifunctional maleimides was partially prevented by Mg²⁺ and l-malate, and NADP prevented the inactivation almost totally. Determination of the number of reactive sulfhydryl groups of the native enzyme with [³H]NEM in the absence or presence of NADP showed that inactivation occurred concomitantly with the modification of two cysteinyl residues per enzyme monomer. The presence of these two essential residues was confirmed by titration of sulfhydryl groups with [³H]NEM in the enzyme previously modified by o-phenylenebismaleimide in the absence or presence of NADP.     

The Mechanism of Cleavage Under Basic Conditions of Succinyl-Anchored Oligonucleotides

Abstract

Studies with a model compound provide direct evidence that cleavage of succinyl-anchored oligonucleotides takes place by intramolecular nucleophilic attack of the conjugate base of the succinamide at the ester carbonyl group. An N-substituted succinimide is exclusively formed with piperidine, DBU and TBAF, but when ammonia is used-this general mechanism seems to coexist with ammonolysis of the succinate ester. Cleavage with TBAF is extremely fast.