Substituted benz[a]acridines and benz[c]acridines as mammalian topoisomerase poisons

Coralyne and several other synthetic benzo[a,g]quinolizium derivatives related to protoberberine alkaloids have exhibited activity as topoisomerase poisons. These compounds are characterized by the presence of a positively charged iminium group, which has been postulated to be associated with their pharmacological properties. The objective of the present study was to devise stable noncharged bioisosteres of these compounds. Several similarly substituted benz[a]acridine and benz[c]acridine derivatives were synthesized and their relative activity as topoisomerase poisons was determined. While the benz[c]acridine derivatives evaluated as part of this study were devoid of topoisomerase poisoning activity, several dihydrobenz[a]acridines were able to enhance DNA cleavage in the presence of topo I. In contrast to certain protoberberine derivatives that did exhibit activity as topo II poisons, none of the benz[a]acridines derivatives enhanced DNA cleavage in the presence of topo II. Among the benz[a]acridines studied, 5,6-dihydro-3,4-methylenedioxy-9,10-dimethoxybenz[a]acridine, 13e, was the most potent topo I poison, with comparable potency to coralyne. These data suggest that heterocyclic compounds structurally related to coralyne can exhibit potent topo I poisoning activity despite the absence of an iminium cation within their structure. In comparison to coralyne or other protoberberine derivatives, these benz[a]acridine derivatives possess distinctly different physicochemical properties and represent a novel series of topo I poisons.     

Differences in the interactions of liver alcohol dehydrogenases with probes binding into the substrate pocket

The interactions of three groups of probes (berberine alkaloids, tricyclic psychopharmaca and acridine derivatives) with isoenzymes of horse liver alcohol dehydrogenase and with rat liver alcohol dehydrogenase have been examined. These compounds inhibit the activity of the EE isoenzyme of horse liver alcohol dehydrogenase but differ in their behaviour towards the steroid-active enzymes (i.e. the ES isoenzyme of horse liver alcohol dehydrognase and alcohol dehydrogenase from rat liver): psychopharmaca inhibit, acridines activate and berberines do not bind. The ligands differ also in their influence on the modification of the EE isoenzyme by iodoacetate. Polarities (expressed as Kosower's Z values) of the respective binding sites on the EE isoenzyme were estimated from optical properties of bound probes. Berberines bind into a very hydrophobic area of the enzyme molecule, the binding site for psychopharmaca is moderately hydrophobic and that for acridines is rather polar. Steric arrangements of the binding sites are also discussed. The data presented confirm the existence of three distinct binding sites for these ligands in the substrate pocket of liver alcohol dehydrogenase.     

Antiprion activity of functionalized 9-aminoacridines related to quinacrine

A library of functionalized 6-chloro-2-methoxy-(N(9)-substituted)acridin-9-amines structurally related to quinacrine were synthesized and evaluated for antiprion activity on four different cell models persistently infected with scrapie prion strains (ScN2a, N167, Ch2) or a human disease prion strain (F3). Most of the compounds were distinguished by the side chain attached to 9-amino of the acridine ring. These were dialkylaminoalkyl and phenyl with basic groups on the phenyl ring. The most promising compound was 6-chloro-2-methoxy-N-(4-(4-methylpiperazin-1-yl)phenyl)acridin-9-amine (15) which had submicromolar EC(50) values (0.1-0.7microM) on all cell models, was able to clear PrP(Sc) at non-toxic concentrations of 1.2-2.5microM, and was more active than quinacrine in terms of EC(50) values. Other promising compounds were 14 (a regioisomer of 15) and 17 which had a 1-benzylpiperidin-4-yl substituent attached to the 9-amino function. Activity was strongly dependent on the presence of a substituted acridine ring, which in this library comprised 6-chloro-2-methoxy substituents on the acridine ring. The side chains of 14, 15, and 17 have not been previously associated with antiprion activity and are interesting leads for further optimization of antiprion activity.     

Synthesis and antileishmanial activities of 4,5-di-substituted acridines as compared to their 4-mono-substituted homologues

Newly synthesized 4,5-di-substituted acridines were assessed for in vitro antileishmanial activities as compared to those of their 4-mono-substituted homologues. Mono-substituted acridines exhibited a weak specificity for Leishmania parasites. Di-substituted acridines, on the contrary, displayed interesting amastigote-specific activities through a mechanism of action that might not involve intercalation to DNA. This antileishmanial property, associated with a low antiproliferative activity towards human cells, led to the identification of a new class of promising acridine derivatives such as 4,5-bis(hydroxymethyl)acridine with a nonclassical mechanism of action based on the inhibition of Leishmania internalization within macrophages. In the meantime, the effects of experimental lighting on the biological properties of acridines were assessed: experimental lighting did not significantly improve the antileishmanial activity of the compounds since it produced a greater toxicity against human cells.     

The action of acridine derivatives on penicillinase production by staphylococcus aureus]

A study was made of a possibility of inhibition of biosynthesis of penicillinase in Staph. aureus by acridine derivatives. Acetone preparations of penicillinase were obtained from the cultures of staphylococcus strains 16/160 and 8325 (p11(147) pen 1220) grown in the presence of various subbacterial concentrations of acridine derivatives. The activity of the enzyme was studied in experiment and control by the microiodometric method. Acriflavine and proflavine inhibited the penicillinase biosynthesis from the 4th hour of growth, and rivanol, acrichine, acridines No. 27 and 37--from the 12th hour of the culture growth.     

1H NMR study of the binding of Bis(acridines) to d(AT)5.d(AT)5. 1. Mode of binding

1H NMR has been used to investigate the mode of binding to d(AT)5.d(AT)5 of a series of bis(acridine) derivatives connected by different types of linker chains. The length and character (ionic, aliphatic, rigid, and flexible) of the linker chains are found to have a profound effect on the binding of these derivatives to the DNA. Bis(acridine) derivatives with linker chains shorter than 9 A monointercalate under the conditions used in the NMR study, whereas those bis(acridines) with chains of 9.8 A or longer bisintercalate. We find no evidence for the violation of the so-called neighbor exclusion principle. Although all of the bis(acridines) contain the same chromophores, their NMR spectra clearly demonstrate that they form complexes with d(AT)5.d(AT)5 which have different structures. This emphasizes the important effect that the linker chain has on the structure of the intercalation complex.     

The effect on sister-chromatid exchanges of drugs and dyes by intercalation and photoactivation.

Intercalating dyes (acridine orange, proflavin and methylene blue) and drugs (chlorpromazine, promazine and chlorprothixene) were tested for their ability to induce sister-chromatid exchanges (SCEs) with and without photoactivation by visible light. Whereas in the dark all substances tested increased the frequency of SCEs, a superimposed effect of visible light on SCE formation was observed for the acridines proflavin and acridine orange, but not for the pheneothiazine derivatives methylene blue and chlorpromazine. These results are discussed in connection with the known mutagenic effects of these substances and with the factors that may be involved in SCE formation induced by intercalating molecules in the absence and presence of visible light.     

Effect of Deoxyribonucleic Acid Ligands on Deoxyribonucleases and Deoxyribonucleic Acid Polymerase I of Escherichia coli K-12

Endonuclease I, exonuclease I, and exonuclease II-deoxyribonucleic acid (DNA) polymerase I activities are not vital functions in Escherichia coli, although the latter two enzymes have been indirectly shown to be involved in DNA repair processes. Acridines such as acridine orange and proflavine interfere with repair in vivo, and we find that such compounds inhibit the in vitro activity of exonuclease I and DNA polymerase I but stimulate endonuclease I activity and hydrolysis of p-nitrophenyl thymidine-5′-phosphate by exonuclease II. Another acridine, 10-methylacridinium chloride, binds strongly to DNA but is relatively inert both in vivo and in vitro. These experiments suggest that acridines affect enzyme activity by interacting with the enzyme directly as well as with DNA. Resulting conformational changes in the DNA-dependent enzymes might explain why similar acridines which form similar DNA complexes have such a wide range of physiological effects. Differential sensitivity of exonuclease I and DNA polymerase I to acridine inhibition relative to other DNA-dependent enzymes may contribute to the acridine sensitivity of DNA repair.     

Catalytic reaction mechanism of goose egg-white lysozyme by molecular modelling of enzyme-substrate complex

Despite the low similarity between their amino acid sequences, the core structures of the fold between chicken-type and goose-type lysozymes are conserved. However, their enzymatic activities are quite different. Both of them exhibit hydrolytic activities, but the goose-type lysozyme does not exhibit transglycosylation activity. The chicken-type lysozyme has a retaining-type reaction mechanism, while the reaction mechanism of the goose-type lysozyme has not been clarified. To clarify the latter mechanism, goose egg-white lysozyme (GEL)-N-acetyl-D-glucosamine (GlcNAc)6 complexes were modelled and compared with hen egg-white lysozyme (HEL)-(GlcNAc)6 complexes. By systematic conformational search, 48 GEL-(GlcNAc)6 complexes were modelled. The right and left side, and the amino acid residues in subsites E-G were identified in GEL. The GlcNAc residue D could bind towards the right side without distortion and there was enough room for a water molecule to attack the C1 carbon of GlcNAc residue D from alpha-side in the right side and not for acceptor molecule. The result of molecular dynamics simulation suggests that GEL would be an inverting enzyme, and Asp97 would act as a second carboxylate and that the narrow space of the binding cleft at subsites E-G in GEL may prohibit the sugar chain to bind alternative site that might be essential for transglycosylation.     

Prevention of thermal inactivation and aggregation of lysozyme by polyamines.

Proteins tend to form inactive aggregates at high temperatures. We show that polyamines, which have a relatively simple structure as oligoamids, effectively prevent thermal inactivation and aggregation of hen egg lysozyme. In the presence of additives, including arginine and guanidine (100 microM), more than 30% of 0.2 mg x mL(-1) lysozyme in sodium phosphate buffer (pH 6.5) formed insoluble aggregates by heat treatment (98 degrees C for 30 min). However, in the presence of 50 mm spermine or spermidine, no aggregates were observed after the same heat treatment. The residual activity of lysozyme after this heat treatment was very low (< 5%), even in the presence of 100 microM arginine and guanidine, while it was maintained at approximately 50% in the presence of 100 microM spermine and spermidine. These results imply that polyamines are new candidates as molecular additives for preventing the thermal aggregation and inactivation of heat-labile proteins.     

Factors influencing transduction of genetic determinants of penicillinase activity and pathogenicity in staphylococcus aureua. II. Antiphage activity of acridine derivatives]

Acridine dyes examined earlier (acrichine, acridine orange, proflavine and rivanol) and newly-synthesized preparations (acridines No. No. 37--40) were studied in the capacity of nonspecific agents influencing the lytic cycle in development of staphylococcus phages. Acrichine and acridine No. 37 failed to prevent lysis of the indicator staphylococcus cultures (strains 16/160 and 8325) by bacteriophages; proflavine, rivanol, acridines No. No. 39--40 produced a marked inhibitory effect; acridine orange and acridine No. 38 inhibited the staphylococcus lysis completely. Some preparations could be used to investigate the transduction phenomenon.     

The extracellular chaperone clusterin potently inhibits human lysozyme amyloid formation by interacting with prefibrillar species

We have studied the effects of the extracellular molecular chaperone, clusterin, on the in vitro aggregation of mutational variants of human lysozyme, including one associated with familial amyloid disease. The aggregation of the amyloidogenic variant I56T is inhibited significantly at clusterin to lysozyme ratios as low as 1:80 (i.e. one clusterin molecule per 80 lysozyme molecules). Experiments indicate that under the conditions where inhibition of aggregation occurs, clusterin does not bind detectably to the native or fibrillar states of lysozyme, or to the monomeric transient intermediate known to be a key species in the aggregation reaction. Rather, it seems to interact with oligomeric species that are present at low concentrations during the lag (nucleation) phase of the aggregation reaction. This behavior suggests that clusterin, and perhaps other extracellular chaperones, could have a key role in curtailing the potentially pathogenic effects of the misfolding and aggregation of proteins that, like lysozyme, are secreted into the extracellular environment.     

Chaperone-like effect of ceftriaxone on HEWL aggregation: A spectroscopic and computational study

Background

Lysozyme is a widely distributed enzyme present in a variety of tissue and body fluids. Human and hen egg white lysozyme are used as validated model to study protein folding and stability and to understand protein misfolding and aggregation. We recently found that ceftriaxone, a β-lactam antibiotic able to overcome the blood-brain barrier, successfully eliminated the cellular toxic effects of misfolded proteins as Glial Fibrillary Acidic Protein (GFAP) and α-synuclein. To further understand the anti-amyloidogenic properties of ceftriaxone, we studied its activity towards lysozyme aggregation with the aim to investigate a possible chaperone-like activity of this molecule.

The genetic toxicology of acridines

Acridine and its derivatives are planar polycyclic aromatic molecules which bind tightly but reversibly to DNA by intercalation, but do not usually covalently interact with it. Acridines have a broad spectrum of biological activities, and a number of derivatives are widely used as antibacterial, antiprotozoal and anticancer drugs. Simple acridines show activity as frameshift mutagens, especially in bacteriophage and bacterial assays, by virtue of their intercalative DNA-binding ability. Acridines bearing additional fused aromatic rings (benzacridines) show little activity as frameshift mutagens, but interact covalently with DNA following metabolic activation (forming predominantly base-pair substitution mutations). Compounds where the acridine acts as a carrier to target alkylating agents to DNA (e.g. the ICR compounds) cause predominantly frameshift as well as base-pair substitution mutations in both bacterial and mammalian cells. Nitroacridines may act as simple acridines or (following nitro group reduction) as alkylating agents, depending upon the position of the nitro group. Acridine-based topoisomerase II inhibitors, although frameshift mutagens in bacteria and bacteriophage systems, are primarily chromosomal mutagens in mammalian cells. These mutagenic activities are important, since the compounds have considerable potential as clinical antitumour drugs. Although evidence suggests that simple acridines are not animal or human carcinogens, a number of the derived compounds are highly active in this capacity.     

Photodynamic mutagenic action of acridine compounds on yeast Saccharomyces cerevisiae

The photodynamically produced mutagenicity and toxicity of 8 acridine compounds were compared in Saccharomyces cerevisiae under resting and growing conditions. Without irradiation none of the acridines induced respiratory-deficient ('petite') colonies, indicative of mitochondrial DNA damage, in resting cells; and only acriflavine and proflavine induced 'petites' in growing cells. Also, without irradiation none of the acridines were significantly toxic or mutagenic for nuclear DNA under resting or growing conditions. However, with irradiation, acriflavine, proflavine, acridine yellow and rivanol became effective 'petite'-inducing mutagens and highly toxic for resting cells, while acriflavine, proflavine, and acridine orange became effective nuclear mutagens for resting cells. Acridine, quinacrine and 9-aminoacridine were not at all biologically effective with irradiation for resting cells. The results presented here indicate that singlet oxygen is generated by a photodynamic mechanism when acriflavine is irradiated, and further, that acridine, quinacrine and 9-aminoacridine are ineffective photosensitizers, because they are incapable of generating singlet oxygen with irradiation.     

Lysozyme refolding with cyclodextrins: structure-activity relationship

Cyclodextrins (CDs), in the presence or absence of detergents, have been reported to suppress aggregate formation during the refolding of a number of proteins. A structure-activity relationship study between CD chemistry and refolding of lysozyme was performed and compared to carbonic anhydrase, in order to better understand the mechanism of CD-assisted protein refolding and to identify CDs that could function as good protein folding agents. Among the natural CDs, which have only hydroxyl groups, alpha-CD, with a smaller cavity size was more effective than the oligosaccharide with a larger cavity, gamma-CD. Replacement of the hydroxyls with other functional groups did not improve, but could seriously interfere, with the lysozyme refolding ability of alpha-CD. In case of gamma-CD, substitution of its hydroxyls with other groups either enhanced or diminished its refolding capability towards lysozyme. In general, neutral CDs were better refolding agents than the charged sugars. The presence of anionic substituents like carboxyl and phosphate groups actually promoted aggregate formation and completely abolished the sugar's refolding ability. This effect was more pronounced with lysozyme than with carbonic anhydrase. CDs with cationic functional groups did not show any significant effects on lysozyme refolding. The presence of both anionic and cationic substituents on the same CD molecule was found to partially restore its renaturation ability. Electrophoresis data indicate that CDs, which promoted lysozyme refolding, arrested aggregation at the stage of smaller soluble aggregates. Interestingly, the structure-activity relationship observed with lysozyme was quite similar to that reported for a non-disulfide protein, carbonic anhydrase. These results suggest that the effects of CDs on protein refolding are attributed to their ability to suppress aggregation of proteins. CDs may show properties similar to chaotropic agents, which may help explain their anti-aggregation and protein refolding ability. Besides alpha-CD, a number of other neutral CDs were found to be effective protein folding aids.     

Cysteine inhibits amyloid fibrillation of lysozyme and directs the formation of small worm‐like aggregates through non‐covalent interactions

In this article, we discuss the effects of amino acids on amyloid aggregation of lysozyme. l ‐cysteine (Cys) dramatically inhibited fibrillation of lysozyme, whereas other amino acids (including l ‐arginine) did not. In the presence of Cys, the aggregation pathway of lysozyme shifted from fibrillation to the formation of the small worm‐like aggregates with unfolding. The interaction between Cys and lysozyme was observed to be non‐covalent, suggesting that the thiophilic interaction between the thiol group on the side chain of Cys and the core sequence of lysozyme significantly contributes to the inhibition of amyloid aggregation. These findings provide a new basis for the design of a biocompatible additive to prevent amyloid fibrillation. © 2014 American Institute of Chemical Engineers Biotechnol. Prog., 30:470–478, 2014     

An Analysis of the Interaction of Sodium Dodecyl Sulfate with Lysozyme

The interaction of SDS with lysozyme was analyzed with enzyme activity and with NMR, fluorescence, and UV difference spectroscopies using various alkyl sulfates and variously modified lysozymes. SDS formed a stable complex with lysozyme without causing a gross conformational change in the enzyme molecule. Some SDS molecules bound to the active site cleft of lysozyme and therefore strongly inhibited the activity of lysozyme. Hydrophobic regions and positive charges for protein side, and a hydrophobic tail (possibly more than 8 carbons in alkyl chain) and a negative charge for detergent side were required for the formation of the complex.     

Genetic effects of acridine compounds.

Acridines and a very large number of acridine derivatives are used in enormous quantities both in medicine and industry. The mutagenic action of these compounds has been demonstrated in a wide variety of organisms and is known to occur both in the dark as well as in the presence of light (photodynamic action). At the molecular level, acridines have been shown to cause frameshift mutations of both the addition and deletion types, a characteristic which has been of tremendous help in elucidating the nature of the genetic code. These and various other biological effects of acridines, such as inhibition of DNA repair, curing of plasmids and cell-growth inhibition, are examined in this review.