Diacridines: bifunctional intercalators. II. The biological effects of putrescine, sperimidine and spermine diacridines on HeLa cells and on the L-1210 and P-388 leukemia cells.

The effect of putrescine, spermidine and spermine diacridines on the growth of HeLa cells and of P-388 and L-1210 leukemia cells has been evaluated and compared to that of the parent compound, 9-aminoacridine. The diacridines are more effective growth inhibitors than 9-aminoacridine. The primary site of action appears to be the inhibition of RNA synthesis.     

Intracellular DNA damage produced by a series of diacridines.

The intracellular DNA damage produced by a series of diacridines after a 2 h pulse treatment of L1210 cells in culture was investigated by using the alkaline-elution technique. Like other intercalating agents, diacridines produce single-strand breaks and protein-DNA links. There is a large increase in both types of damage as the alkane chain linking the two 9-aminoacridine residues is increased beyond five methylene groups, which is consistent with the previously observed change from monofunctional to bifunctional intercalation [Wakelin, Romanos, Chen, Glaubiger, Canellakis & Waring (1978) Biochemistry 17, 5057-5063]. For linker chains of less than six methylene groups these agents produce less DNA damage than does the parent 9-aminoacridine at the same drug concentration. Unlike the monofunctional intercalators previously investigated [Ross, Glaubiger & Kohn (1979) Biochim. Biophys. Acta 562, 41-50; Zwelling, Michaels, Erickson, Ungerleider, Nichols & Kohn (1981) Biochemistry 20, 6553-6563; Zwelling, Kerrigan & Michaels (1982) Cancer Res. 42, 2687-2691; Zwelling, Michaels, Kerrigan, Pommier & Kohn (1982) Biochem. Pharmacol. 31, 3261-3267], there is no correlation between the number of single-strand breaks and protein-DNA links produced by these diacridines.     

The mutagenic effects of diacridines and diquinolines in microbial systems

Two series of difunctional DNA-intercalating agents (diacridines and diquinolines) were tested for mutagenic properties in Salmonella typhimurium strain TA1537, and for 'petite' mutagenesis activity in Saccharomyces cerevisiae, and also compared in terms of their structural, lipophilic and DNA-binding properties. Diacridines with only a short chain length were monointercalators, while those with an alkyl linker chain longer than C6 were bisintercalators. Although the bisintercalators especially bound very tightly to DNA, none of these compounds was as effective a frameshift mutagen in TA1537 as the parent chromophore 9-aminoacridine. However, the two (monointercalating) diacridines of shortest chain length were still able to cause frameshifts, and this ability returned (albeit weakly) in the bisintercalators of longest chain length. Although 9-aminoacridine showed no ability for 'petite' mutagenesis, the diacridines of longer chain length were very effective in causing this mitochondrial event. In the quinoline series, both the parent chromophore (4-aminoquinoline) and all the diquinolines were weak monointercalators. None of these compounds showed any ability for frameshift mutagenesis, although some were very weak mitochondrial mutagens. It is concluded that linking two acridines produces compounds whose mutagenic properties might have been predicted from our current knowledge of the parent molecules. However, despite a similar ability to intercalate DNA, the diquinolines show no resemblance to acridines in their mutagenic properties.     

Structural limitations on the bifunctional intercalation of diacridines into DNA

An homologous series of diacridines containing two 9-aminoacridine chromophores linked via a simple methylene chain has been studied in order to investigate the minimum interchromophore separation required to permit bifunctional intercalation. Viscometric, sedimentation, and electric dichroism experiments show that compounds having one to four methylene groups in the linker are restricted to monofunctional intercalation, whereas the interaction becomes bifunctional when the chain length is increased to six carbons or more. The results indicate that bifunctional reaction occurs with an interchromophore distance not exceeding 8.8 A, implying that intercalation by these compounds is not subject to neighbor exclusion if the mode of binding is of the classical intercalation type.     

The surface membrane charge of bacteria and its role in serine proteinase secretion by Bacillus subtilis cells

Univalent, bivalent and trivalent metal cations increase the fluorescence yield of 9-aminoacridine in the suspensions of chromatophores of the purple nonsulfur bacterium Rhodospirillum rubrum isolated thylakoid membranes and cells of cyanobacterium Anabaena variabilis, cells Bacillus subtilis. The active cation concentrations increase about in 10 times with the decrease of their valency by one. It points to the fact that the changes in 9-aminoacridine fluorescence serve for the monitoring of the surface charge of bacterial membranes. The negative surface charge of B. subtilis cells increases before the onset of the serine protease secretion. The metal cations stimulate the serine protease secretion by B. subtilis cells, the stimulating effect correlates with the action of cations on the 9-aminoacridine fluorescence yield. It is suggested that the surface charge of cytoplasmic membrane regulates the formation and release of serine protease by the cells of B. subtilis.     

Diacridines: bifunctional intercalators. I. Chemistry, physical chemistry and growth inhibitory properties.

The synthesis, as well as the rationale for synthesis of diacridines, double intercalators, as potential inhibitors of nucleic acid synthesis is presented. The syntheses of (9-acridyl)-putrescine and -spermine, and bis(-9-acridyl)-putrescine, -spermidine, -spermine diamines and of bis(6-chloro-2-methoxy-9-acridyl)-putrescine and -spermine diamines, all substituted on the terminal NH2 groups are described. In addition, the homologous series of diacridines connected by the amino groups of the diamines NH2(CH2)nNH2 (where n = 2,3,4,6,8,10,12,14,16,18) to the C-9 of the diacridines has been synthesized. The chemical properties of these compounds as well as their molecular relationship to DNA are presented. The effect of the double intercalators on the Tm of DNA and of (A)n - (U)n, (dA)n - (dT)n, (G)n - (C)n and on (dG)n - (dC)n have been determined. The double acridine intercalators produce a much greater increase of the Tm of these nucleic acids than do the single acridine intercalators. They also profoundly affect the Tm of DNA in physiological salt concentrations; under these latter conditions the single intercalators have no effect. The relationship between the length of the chain connecting the two acridine rings and the inhibition of the growth of P-388 cells in vitro and vivo is presented. Their growth inhibitory properties appear, in general, to parallel their intercalative abilities.     

The role of inhibitors in the fluorescent staining of benign naevus and malignant melanoma cells with 9-amino acridine and acridine orange

Guanidinobenzoatase is a trypsin-like protease capable of degrading fibronectin. An inactive form of guanidinobenzoatase is present on the surface of benign naevus cells and these cells stain very weakly with 9-aminoacridine, a known competitive inhibitor of guanidinobenzoatase. Malignant melanoma and metastatic malignant melanoma cells exhibit strong surface staining with 9-aminoacridine and also exhibit strong staining of cytoplasmic RNA with acridine orange. These simple fluorescent techniques have been used to distinguish benign naevus cells from malignant melanoma cells in human skin sections. This difference in cell surface staining with 9-aminoacridine has been demonstrated to be caused by the presence or absence of an inhibitor. The inhibitor can be displaced from the cell surface enzyme and then replaced by an affinity purified inhibitor obtained from fresh liver homogenates. It is proposed that the inhibition or control of cell surface guanidinobenzoatase may be one of the regulatory mechanisms by which benign naevus cells are prevented from developing into malignant melanoma cells.     

The binding of binuclear platinum(II)-terpyridine complexes to DNA.

The binding of platinum (II)-terpyridine complexes to DNA was studied by using equilibrium dialysis. Optical absorption methods were used to measure the ability of the ligands to aggregate in aqueous buffer. Scatchard plots for the binding of the monomeric [Pt(terpy)SC4H9]+ cation to DNA at I0.01 are curvilinear, concave upwards, suggesting two modes of binding. The association constant decreases at higher ionic strengths, consistent with polyelectrolyte theory, and 1.1 cations are released per bound ligand molecule. The association constants of the binuclear ligands [Pt(terpy)S[CH2]4S(terpy)Pt]2+ and [Pt(terpy)S[CH2]6S(terpy)Pt]2+ are 8 and 23 times larger respectively than the affinity of the monomer. For the latter binuclear derivative the increase may be ascribed to bifunctional reaction. Differential dialysis experiments with DNAs of differing base composition show that [Pt(terpy)SC4H9]+ has a requirement for a single G X C base-pair at the highest-affinity site. However, in the binuclear ligands chromophore specificity is severely compromised. Similar experiments indicate that 9-aminoacridine and selected methylene-linked diacridines show no significant sequence selectivity.     

9-Aminoacridine- and tetraethylammonium-induced reduction of the potassium permeability in pancreatic B-cells. Effects on insulin release and electrical properties.

The effects of 9-aminoacridine and tetraethylammonium on insulin release and rubidium efflux from perifused rat islets were investigated and correlated with their effects on the electrical properties of mouse B cells studied with microelectrode techniques. 9-Aminoacridine (0.05--1 mmol/l) and tetraethylammonium (2--40 mmol/l) produced a dose-dependent, reversible potentiation of glucose-stimulated insulin release. This effect was rapid, affected both phases of secretion and was maximum in the presence of 6 mmol/l glucose, but no longer significant at 20 mmol/l glucose. It was unaltered by atropine or propanolol, and abolished by mannoheptulose or omission of extracellular calcium. 9-Aminoacridine, but not tetraethylammonium, also induced insulin release in the absence of glucose stimulation. Neither drug modified glucose metabolism in islet cells and only 9-aminoacridine increased 45Ca2+ uptake. In the presence of 0, 3 or 6 mmol/l glucose, but no longer at 20 mmol/l glucose, 9-aminoacridine and tetraethylammonium reduced the rate of 86Rb+ efflux from the islets. Both drugs also slightly reduced 86Rb+ uptake by islet cells. In the presence of 11 mmol/l glucose, 9-aminoacridine reduced the amplitude and the duration of the polarization phases between the bursts of electrical activity; concomitantly these periods of spike activity were markedly prolonged. At lower glucose concentrations (3 or 7 mmol/l), 9-aminoacridine progressively depolarized B cells and induced electrical activity in otherwise silent cells. Tetraethylammonium also suppressed the repolarization phases between the bursts of spikes in the presence of a stimulating concentration of glucose. At low glucose, tetraethylammonium produced only a limited and not maintained depolarization. These results show that a reduction of the potassium permeability in pancreatic B cells potentiates the insulin-releasing effect of glucose and may even stimulate secretion. They also suggest that the initial depolarizing effect of glucose is due to a reduction of the potassium permeability, whereas the repolarization at the end of each burst of electrical activity is mediated, at least in part, by an increase in the potassium permeability of B cells.     

9-Aminoacridine, a fluorescent probe of the thiamine carrier in yeast cells

The uptake of 9-aminoacridine is studied in the yeast Saccharomyces cerevisiae by fluorescence and absorbance measurements of the dye. Uptake of the dye proceeds via two pathways. One pathway consists of a diffusion of the non-protonated form. At high pH (7.5) this pathway is the predominant one, and the dye distributes between the cell inner and the medium according to the ratio of the proton concentrations in the two compartments. In other words, at high pH 9-aminoacridine behaves as a probe of the H⁺ gradient across the yeast cell membrane. At low external pH (4.5) a second pathway is involved. Much greater accumulation ratios for the dye are observed than can be accounted for by the H⁺ gradient across the membrane. The transport system predominantly responsible for the great accumulation of the dye appears to be inducible, to require metabolic energy and to be saturable. This transport system is competitively inhibited by thiamine, and also by dibenzyldimethylammonium and thiaminedisulfide, two specific inhibitors of the thiamine carrier in the yeast. On the other hand, the thiamine uptake by the yeast cells is competitively inhibited by 9-aminoacridine. In addition, uptake of 9-aminoacridine is greatly reduced in the thiamine transport-negative mutant of S. cerevisiae, PT-R2. It is concluded that at low pH 9-aminoacridine is taken up by yeast via the thiamine carrier of the cell and that, consequently, the dye may be applied as a probe of this transport system.     

9-aminoacridine- and tetraethylammonium -induced reduction of the potassium permeability in pancreatic B-cells: Effects on insulin release and electrical properties

The effects of 9-aminoacridine and tetraethylammonium on insulin release and rubidium efflux from perifused rat islets were investigated and correlated with their effects on the electrical properties of mouse B cells studied with microelectrode techniques. 9-Aminoacridine (0.05–1 mmol/1) and tetraethylammonium (2–40 mmol/l) produced a dose-dependent, reversible potentiation of glucose-stimulated insulin release. This effect was rapid, affected both phases of secretion and was maximum in the presence of 6 mmol/l glucose, but no longer significant at 20 mmol/l glucose. It was unaltered by atropine or propanolol, and abolished by mannoheptulose or omission of extracellular calcium. 9-Aminoacridine, but not tetraethylammonium, also induced insulin release in the absence of glucose stimulation. Neither drug modified glucose metabolism in islet cells and only 9-aminoacridine increased ⁴⁵Ca²⁺ uptake. In the presence of 0, 3 or 6 mmol/l glucose, but no longer at 20 mmol/l glucose, 9-aminoacridine and tetraethylammonium reduced the rate of ⁸⁶Rb⁺ efflux from the islets. Both drugs also slightly reduced ⁸⁶Rb⁺ uptake by islet cells. In the presence of 11 mmol/l glucose, 9-aminoacridine reduced the amplitude and the duration of the polarization phases between the bursts of electrical activity; concomitantly these periods of spike activity were markedly prolonged. At lower glucose concentrations (3 or 7 mmol/l), 9-aminoacridine progressively depolarized B cells and induced electrical activity in otherwise silent cells. Tetraethylammonium also suppressed the repolarization phases between the bursts of spikes in the presence of a stimulating concentration of glucose. At low glucose, tetraethylammonium produced only a limited and not maintained depolarization.These results show that a reduction of the potassium permeability in pancreatic B cells potentiates the insulin-releasing effect of glucose and may even stimulate secretion. They also suggest that the initial depolarizing effect of glucose is due to a reduction of the potassium permeability, whereas the repolarization at the end of each burst of electrical activity is mediated, at least in part, by an increase in the potassium permeability of B cells.     

The Role of Inhibitors in the Fluorescent Staining of Benign Naevus and Malignant Melanoma Cells with 9-Amino Acridine and Acridine Orange

Abstract

Guanidinobenzoatase is a trypsin-like protease capable of degrading fibronectin. An inactive form of guanidinobenzoatase is present on the surface of benign naevus cells and these cells stain very weakly with 9-aminoacridine, a known competitive inhibitor of guanidinobenzoatase. Malignant melanoma and metastatic malignant melanoma cells exhibit strong surface staining with 9-aminoacridine and also exhibit strong staining of cytoplasmic RNA with acridine orange. These simple fluorescent techniques have been used to distinguish benign naevus cells from malignant melanoma cells in human skin sections. This difference in cell surface staining with 9-aminoacridine has been demonstrated to be caused by the presence or absence of an inhibitor. The inhibitor can be displaced from the cell surface enzyme and then replaced by an affinity purified inhibitor obtained from fresh liver homogenates. It is proposed that the inhibition or control of cell surface guanidinobenzoatase may be one of the regulatory mechanisms by which benign naevus cells are prevented from developing into malignant melanoma cells.     

Acridine dimers: influence of the intercalating ring and of the linking-chain nature on the equilibrium and kinetic DNA-binding parameters

The rigidity of the linking chain of bifunctional intercalators in the ditercalinium series was shown to be critical for antitumor activity. In order to study the influence of the rigidity of the linking chain on the DNA-binding properties of DNA bifunctional intercalators, fluorescent 9-aminoacridine and 2-methoxy-6-chloro-9-aminoacridine analogues with chains of variable rigidity were synthesized. 1H-NMR studies show that the conformation of 9-aminoacridine dimers is almost independent of the nature of the linking chain. A strong self-stacking of the aromatic rings of the 2-methoxy-6-chloro-9-aminoacridine is observed for dimers with flexible chains but not for those with rigid chains. All the dimers having a linking chain long enough to bisintercalate in DNA according to the excluded site model are indeed bisintercalators. The kinetic association constant of all monomers and dimers for poly[d(A-T)].poly[d(A-T)] are in the same range (2-4 x 10(7) M-1 s-1). The large increase of DNA binding affinity observed for the dimers is always associated with the expected decrease of the dissociation rate constant. The effect of chain rigidity and pH on the calf thymus DNA binding of 9-aminoacridine and 2-methoxy-6-chloro-9-aminoacridine dimers is quite different. In the series of 9-aminoacridine the pKa of the dimers remains high and therefore no difference of DNA-binding affinity is observed between pH 5 and 7.4. The rigidity of the linking chain does not significantly alter the DNA-binding affinity. In the 2-methoxy-6-chloro-9-aminoacridine series, the pKa of all dimers became smaller than the physiological pH and a dramatic decrease of DNA-binding affinity is observed when the pH is increased from pH 5 to 7.4. This decrease appears significantly smaller for dimers with rigid chains. A similar dramatic decrease of binding affinity at pH 7.4 is not observed for poly[d(A-T)].poly[d(A-T)]. This factor makes these dimers strongly specific for the alternating polymer at pH 7.4.     

Molecular mechanisms of chemical mutagenesis: 9-aminoacridine inhibits DNA replication in vitro by destabilizing the DNA growing point and interacting with the DNA polymerase

9-Aminoacridine was found to inhibit dNTP incorporation into DNA homopolymer duplexes by phage T4 DNA polymerase in vitro. Systematic variation of the molar ratio of 9-aminoacridine to DNA, to DNA polymerase, and to DNA precursors demonstrated that this inhibition at 9-aminoacridine concentrations below 10 microM was mainly due to interaction of 9-aminoacridine with the DNA and suggested that the basis for the preferential inhibition of incorrect precursor incorporation was destabilization of the DNA growing point. Consistent with destabilization, 9-aminoacridine stimulated the hydrolysis of correctly base paired DNA by the 3'-5' exonuclease activity of phage T4 DNA polymerase. This is the first indication to my knowledge that an intercalating dye destabilizes the DNA growing point, whereas it raises the overall Tm of the DNA. At 9-aminoacridine concentrations above 10 microM overall incorporation of dNTPs was inhibited by 9-aminoacridine interaction with the DNA polymerase. A possible explanation for the induction of both deletion and addition frameshift mutations by 9-aminoacridine during DNA biosynthesis is discussed in light of growing-point destabilization.     

Induction of deletion and insertion mutations by 9-aminoacridine. An in vitro model

The ability of 9-aminoacridine to induce mutagenic lesions during DNA replication in vitro was investigated. The ampicillinase gene of pBR322 was replicated in vitro in the presence of 9-aminoacridine. Transfection of the replicated DNA into Escherichia coli gave Amps mutants. Determination of the base changes in 76 of these mutants indicated that the spectrum of mutations induced by 9-aminoacridine was consistent with its action in vivo. Both large (407-base) and small (1- and 2-base) deletions were induced at repetitive sequences. The frequency of deletion mutations depended on the identity of the base deleted and sequences surrounding the deletions. The characteristics of the frameshift mutations induced were consistent with the interactions of 9-aminoacridine with DNA. These results establish that 9-aminoacridine can induce frameshift mutations during the replication process and provide an in vitro model of frameshift induction for mechanistic studies.     

Inhibition of guanidinobenzoatase: evidence for multiple forms of this protease on different tumour cells

Guanidinobenzoatase is a proteolytic enzyme capable of degrading fibronectin and is a tumour associated enzyme. 9-Aminoacridine is a competitive inhibitor of this enzyme and has been used to locate cells possessing this enzyme in wax embedded sections by means of fluorescent microscopy. Naturally occurring inhibitors of guanidinobenzoatase can be extracted from different tissues. These inhibitors show selectivity in their ability to inhibit the binding of 9-aminoacridine to different types of tumour cells which have invaded human liver tissue. Inhibition is non-competitive and reversible. The results indicate that guanidinobenzoatase exists in a number of different forms on the surface of different tumour cells. These different forms of the enzyme were recognised by inhibitors obtained from different organs. It is suggested that these inhibitors may have a regulatory role in tumour cell migration.     

Azido analogs of acridine: Photoaffinity probes for frameshift mutagenesis in Salmonella typhimurium

In order to identify a photoaffinity probe for 9-aminoacridine frameshift mutagenesis, 20 azido analogs of acridine were synthesized and tested in Ames' Salmonella tester strains, TA1535, TA1537, TA1538 and their corresponding excision-repair-proficient strains TA1975, TA1977, and TA1978, to determine their mutagenicity and toxicity relative to 9-aminoacridine. The substituent-mutagenicity patterns observed for these compounds agree very well with those obtained previously for non-azidoacridines. The results presented here show that the 2-azido-analog of 9-aminoacridine demonstrates biological activity similar to 9-aminoacridine prior to photolytic activation. With light activation, however, the 9-amino-2-azido derivative becomes more effective at producing frameshift mutations characteristics of 9-aminoacridine. Furthemore, this photolytic enhancement of mutagenesis appears to be due to the repairable lesion suggesting that covalent attachment of the drug occurs.     

Mutagenicity of some intercalating agents in Chinese hamster V79 cells

ICR 170 and ICR 191, but not 9-aminoacridine or chloroquine, induced both 6-thioguanine- and, to a smaller extent, ouabain-resistance in Chinese hamster V79 cells. These results indicate that covalent binding to DNA is necessary for intercalating agents to induce mutation in this cell line, and that this assay can distinguish potential carcinogens from non-carcinogenic analogues of this chemical type. The induction of ouabain-resistance by both ICR 170 and ICR 191 indicates that these frameshift mutagens induce base-pair substitution to some extent in V79 cells.     

The sequence selectivity of DNA-targeted 9-aminoacridine cisplatin analogues in a telomere-containing DNA sequence

In this study, the detailed DNA sequence specificity of four acridine Pt complexes was examined and compared with that of cisplatin. The DNA sequence specificity was determined in a telomere-containing DNA sequence using a polymerase stop assay, with a fluorescent primer and an automated capillary DNA sequencer. The Pt compounds included an acridine intercalating moiety that was modified to give a 9-aminoacridine derivative, a 7-methoxy-9-aminoacridine derivative, a 7-fluoro-9-aminoacridine derivative and a 9-ethanolamine-acridine derivative. Compared with cisplatin, the DNA sequence specificity was most altered for the 7-methoxy-9-aminoacridine compound, followed by the 9-aminoacridine derivative, the 7-fluoro-9-aminoacridine compound and the 9-ethanolamine-acridine derivative. The DNA sequence selectivity for the four acridine Pt complexes was shifted away from runs of consecutive guanines towards single guanine bases, especially 5′-GA dinucleotides and sequences that contained 5′-CG. The sequence specificity was examined in telomeric and non-telomeric DNA sequences. Although it was found that telomeric DNA sequences were extensively damaged by the four acridine Pt complexes, there was no extra preference for telomeric sequences.