DNA and RNA damage by Cu(II)-amikacin complex Małgorzata Je _ zzowska-Bojczuk 1 , Wojciech Szczepanik 1 , Wojciech Les ´ niak 1, *, Jerzy Ciesiołka 2 , Jan Wrzesin ´ ski 2 and Wojciech Bal 3 1 Faculty of Chemistry, University of Wrocław, Wrocław, Poland; 2 Institute of Bioorganic Chemistry, Polish Academy of Sciences, Poznan ´ , Poland; 3 Institute of Biochemistry and Biophysics, Polish Academy of Sciences, Warsaw, Poland The oxidation-promoting reactivity of copper(II) complex of aminoglycosidic antibiotic amikacin [Cu(II)-Ami] in the presence of hydrogen peroxide, was studied at pH 7.4, using 2¢-deoxyguanosine (dG), pBR322 plasmid DNA and yeast tRNA Phe as target molecules. The mixtures of complex with H 2 O 2 were found to be efficient oxidants, converting dG to its 8-oxo derivative, generating strand breaks in plasmid DNA and multiple cleavages in tRNA Phe .Thecomplex underwent autooxidation as well, with amikacin hydroper- oxides as likely major products. This reactivity pattern was found to be due to a combination of metal-bound and free hydroxyl radicals. Keywords: copper(II) complexes; amikacin; 2¢-deoxyguano- sine oxidation; plasmid DNA damage; tRNA cleavage. Amikacin (Ami) is a semisynthetic aminoglycoside, a derivative of kanamycin A, having the B1 amino group of 2-deoxystreptamine moiety modified by acylation with 4-amino-2-hydroxybutyric acid. Previous studies demon- strated that Ami is a strong chelator for Cu(II) ions [1,2]. Cu(II) is coordinated at B ring, which is in contrast with unsubstituted aminoglycosides, where terminal aminosugar rings are involved in the binding [3–11]. In the presence of H 2 O 2 the Cu(II)-Ami complex oxidizes 2¢-deoxyguanosine to its 8-oxo derivative [1]. Recently we presented the mechanism of such H 2 O 2 activation, which involves generation of hydroxyl radicals [12]. Antimicrobial action of Ami and other aminoglycosides is based on their interactions with ribosomal RNA [13] and also with cytoplasmic membrane [14,15]. Aminoglycosides also have severe toxic side-effects, on kidney and inner ear [16,17]. Fe(II) complexation and generation of hydroxyl radicals by another aminoglycoside, gentamicin has recently been implicated in the mechanism of its toxicity [18,19]. Aminoglycosides themselves, including Ami, are redox- inactive [12,20]. While intracellular copper is under very tight control in bacterial cells, exerted by specific chaperone proteins [21], extracellular copper in the human blood serum is coordinated in part by, a variety of low molecular mass ligands [22,23]. It is not controlled as tightly there, and is elevated in some pathological conditions, including cancer and inflammation [24]. It is not unlikely that some copper may be transferred to Ami, e.g. during treatment of sepsis. This physiological state also involves increased generation of hydrogen peroxide and oxygen radical species [25]. The ability of Cu(II) complexes of other aminoglycosides to cleave DNA and RNA was shown recently [11,26,27]. Here we present the interactions of Cu(II)-Ami with oxidation- susceptible biomolecules: 2¢-deoxyguanosine (dG), pBR322 plasmid DNA and yeast tRNA Phe in both presence and absence of hydrogen peroxide, as well as the complex autooxidation. Some of these reactions may play a role in toxic effects of amikacin. EXPERIMENTAL PROCEDURES Materials Amikacin and Tris buffer were obtained from Fluka (Buchs, Switzerland); CuCl 2 , methanol, 2¢-deoxyguano- sine (dG), H 2 O 2 , Chelex 100 resin, EDTA, and sodium and potassium phosphates were purchased from Sigma Chemical Co. (St Louis, MO). The reference sample of 7,8-dihydro-8-oxo-2¢-deoxyguanosine (8-oxo-dG) was syn- thesized and purified by HPLC according to a published procedure [28]. Low EEO agarose was purchased from AppliChem (Darmstadt, Germany). Bromophenol blue and glycerol were obtained from POCH (Gliwice, Poland). The plasmid pBR322 was isolated by J. Zakrzewska-Czewin ˜ ska (Institute of Immunology and Experimental Therapy, Polish Academy of Sciences, Wrocław, Poland). Bacterial alkaline phosphatase and T4 polynucleotide kinase were from MBI Fermentas (Vilnius, Lithuania) [c- 32 P]ATP was purchased from ICN (Costa Mesa, CA, USA). Electrophoretic reagents: boric acid, acrylamide, bis-acrylamide and urea were obtained from Serva (Heidelberg, Germany). Decomposition of dG and formation of 8-oxo-dG Solutions of dG (50 l M )in50m M sodium phosphate buffer, pH 7.4, were incubated in triplicate for 24 h at 25 °C or 37 °C in the presence of combinations of Ami, Cu(II) Correspondence to M. Je_zzowska-Bojczuk, Faculty of Chemistry, University of Wrocław, F. Joliot-Curie 14, 50–383 Wrocław, Poland. Fax: + 48 71 3282 348, Tel.: + 48 71 3757 281, E-mail: MJB@wchuwr.chem.uni.wroc.pl Abbreviations: Ami, amikacin; Cu(II)-Ami, cupric complex of amikacin; dG, 2¢-deoxyguanosine; 8-oxo-dG, 7,8-dihydro-8-oxo-2¢- deoxyguanosine; ESI, electrospray ionization; MS/MS, tandem mass spectrometry; D, dihydrouridine; Y, wybutosine. *Present address: Kriesge Hearing Research Institute, Ann Arbor, MI, USA. (Received 10 June 2002, revised 5 September 2002, accepted 16 September 2002) Eur. J. Biochem. 269, 5547–5556 (2002) Ó FEBS 2002 doi:10.1046/j.1432-1033.2002.03260.x (0 or 50 l M )andH 2 O 2 (0.5 m M ). At intervals, small aliquots were removed from the incubating mixtures and analyzed by HPLC without any additional pretreatment on a HP 1100 system (Hewlett-Packard, Palo Alto, CA, USA) with a Nucleosil 100 C 18 column (4.6 mm · 25 cm), using UV detection at 254 nm. The mobile phase was 50 m M KH 2 PO 4 solution in 12% aqueous methanol. Results were quantified with the use of standard solutions containing known amounts of dG and 8-oxo-dG. Mass spectrometry (MS) The mass spectra were obtained with a Finnigan Mat TSQ 700 instrument (Thermo-Finnigan, Bremen, Germany), using the ESI (electro-spray ionization) technique with N 2 as carrier gas, and flow of 2 lLÆmin )1 . Four kinds of samples were investigated at pH 7.4, adjusted with acetic acid and ammonium carbonate: free Ami, Ami-H 2 O 2 , Cu(II)-Ami and Cu(II)-Ami-H 2 O 2 . All samples were pre- pared as water solutions and incubated at 37 °Cfor5,20 and 40 min. Then methanol was added to a final concen- tration of 50%, in order to decrease surface tension during sample evaporation. Final sample concentrations were: Ami and Cu(II), 0.5 m M ;H 2 O 2 ,2.5m M . Further analysis of key peaks was carried out using tandem MS (MS/MS) experi- ments, using helium as a collision gas. Its pressure was adjusted so that the parent ion intensity was  45% of its initial abundance. DNA strand break analysis The ability of Cu(II)-Ami to induce strand breaks in plasmid DNA in the absence and presence of H 2 O 2 was tested with the use of pBR322 plasmid. Samples contained 15 l M DNA in 50 m M sodium phosphate buffer (pH 7.4) and combinations of amikacin, CuCl 2 and H 2 O 2 .The concentrations of these reagents were as follows: Ami, 0 or 50 l M ; Cu(II) 0 or 50 l M ,H 2 O 2 ,0,0.5,5or50l M .After 1hincubationsat37°C, reaction mixtures (20 lL) were mixedwith4lL of loading buffer (bromophenol blue in 30% glycerol) and loaded on 1% agarose gels, containing ethidium bromide, in Tris/borate/EDTA buffer (90 m M Tris/borate, 20 m M EDTA, pH 8.0). Gel electrophoresis was carried out at constant voltage of 100 V (4 VÆcm )1 ), for 20 min. As control for double strand breaks, reference plasmid samples were linearized with XhoI endonuclease. The procedure used in kinetic experiments was similar, with the use of Ami and H 2 O 2 ,Cu(II)andH 2 O 2 and Cu(II)-Ami and H 2 O 2 (each 50 l M ), incubated at 37 °C for time periods varied between 5 and 95 min, typically with 10 min intervals. The gels were photographed and processed with a Digital Imaging System (Syngen Biotech, Wrocław, Poland). Isolation of yeast tRNA Phe Yeast tRNA Phe of specific phenylalanine acceptance 1200–1400 pmol per A 260 unit was prepared from crude baker’s yeast tRNA by standard column chromatography procedures including benzoylated DEAE-cellulose and Sepharose-4B (Pharmacia, Sweden). Final purification was carried out by HPLC on TSK-gel DEAE 2SW column (Toyo Soda, Japan). Labeling of tRNA Phe Yeast tRNA Phe was dephosphorylated with bacterial alka- line phosphatase and subsequently 5¢-end-labeled with [c- 32 P]ATP and polynucleotide kinase. The tRNA was purified on a denaturing 12.5% polyacrylamide gel, located by autoradiography, excised and eluted from the gel with the 0.3 M potassium acetate buffer, pH 5.1, containing 1m M EDTA and 0.1% SDS. The eluted tRNA Phe was precipitated with ethanol, dissolved in water and stored at )20 °Cbeforeuse. TRNA Phe cleavage analysis Prior to the reaction, the 32 P labeled tRNA Phe was supplemented with carrier tRNA Phe to the final RNA concentration of 1 l M and subjected to denaturation/ renaturation procedure by heating the samples at 65 °C for 2 min and slow cooling to 25 °C. Cleavage reactions induced by Ami and Cu(II)-Ami complexes (1–100 l M ) were performed in 10 m M sodium phosphate buffer at pH 7.4, in the absence or presence of H 2 O 2 (50 or 100 l M ). Further details of the reaction conditions are specified in figure legends. All reactions were stopped by mixing with equal volume of 8 M urea/dyes/20 m M EDTA solu- tion and loaded on a 15% polyacrylamide, 7 M urea gel. Electrophoresis was carried out at 1500 V for 3 h, followed by autoradiography at )80 °C with an intensifying screen. In order to assign the cleavage sites, products of cleavage reaction were run along with the products of alkaline degradation and limited T 1 nuclease digestion of the same tRNA Phe . The alkaline hydrolysis ladder was generated by incubation of 32 PlabeledtRNA Phe with 5 volumes of formamide in boiling water for 10 min. Partial T 1 nuclease digestion was performed in denaturing conditions (50 m M sodium citrate, pH 4.5, 7 M urea) with 0.1 unit of the enzyme. The reaction mixture was incubated for 10 min at 50 °C. RESULTS Mass spectrometry of the Cu(II)-Ami-H 2 O 2 system Figure 1 presents the molecule of Cu(II)-amikacin complex with the possible places of breakage indicated, and Fig. 2 provides typical mass spectra for the antibiotic and its complex both in presence and absence of hydrogen perox- ide. According to the data presented in Table 1, the solution containing Ami alone can be characterized by signals at m/z of 587 and 294 (predominant), corresponding to single- and double-charged Ami ions, respectively. Several peaks of low intensity were also observed, resulting from dimerization and fragmentation of the Ami molecule during the ioniza- tion process. No differences were observed between the mass-spectra of the samples of Ami and Ami + H 2 O 2 . Detection of the signals at m/z of 647 and 324 in the Cu(II) + Ami samples (Cu(II)-Ami complex ions, carrying charges of +1 and +2, respectively) confirmed the presence of 1 : 1 complexes in solution at pH 7.4. New peaks were also seen in the high m/z region, at m/z of 1232 and 1294. They can be assigned to single-charged molecules of Cu(II)- Ami 2 and Cu(II) 2- Ami 2 , respectively. Also, two additional 5548 M. Je_zzowska-Bojczuk et al. (Eur. J. Biochem. 269) Ó FEBS 2002 peaks at m/z 710 and 355 appeared in the spectrum, suggesting the formation of a Cu(II) 2 Ami complex. The signal at m/z of 385 belongs to a complex decomposition product. The samples consisting of Cu(II), amikacin and H 2 O 2 gave signal-rich mass-spectra. There were no qualitative differences between the samples at various incubation times. Novel, high intensity signals at m/z values of 617, 600, 308 and 300 indicate the formation of Ami-oxygen adducts (single and double-protonated Ami-O and Ami-O 2 mole- cules). Another set of weaker signals, at m/z values of 679, 662, 340 and 331 likely represents Cu(II) complexes of these adducts (see Table 1). Also, many low intensity peaks appeared in the m/z region of 439–512. In order to assign them and to gain better understanding of the oxidation products, the MS/MS experiments were performed for peaks at m/z 586 (Ami), 600 (Ami + O) and 617 (Ami + 2O). The results are presented in Table 2. Only the peaks with m/z higher than c. 400 were resolved to a degree allowing assignments. Oxidation of 2¢-deoxyguanosine We previously found that Cu(II)-Ami has a particular ability to oxidize dG to 8-oxo-dG [1]. The kinetics of this process at 37 °C was investigated here. The reactions of decomposition of dG and formation of 8-oxo-dG are illustrated on Fig. 3A and B, respectively. The shapes of kinetic curves indicate that both these reactions are in the second-order mode at times longer than 10 min. Still, the kinetic constants of first-order reactions could be calculated from the first 10 min, to be 1.836 ± 0.039 · 10 )3 min )1 for dG decomposition and 2.084 ± 0.061 · 10 )1 min )1 for 8-oxo-dG formation. For comparison with previous experi- ments [1], data at 24 h were also recorded for 25 and 37 °C, and were found to fall within the same ranges (data not shown). The efficacy of dG conversion into 8-oxo-dG was  50% for 25 °Cand 25% for 37 °C. Interaction with pBR322 plasmid Figure 4 presents the strand break assays of pBR322, performed by means of agarose gel electrophoresis. The plasmid can be detected in one of three forms: supercoiled (I), nicked/relaxed (II) or linear (III). Part A of Fig. 4 shows DNA cleavage by Cu(II)-Ami complex both in the presence and absence of H 2 O 2 (50 l M ), part B – in two different, lower concentrations of H 2 O 2 :5and0.5l M .Inthefirst experiment (part A) the samples, dissolved in 50 m M phosphate buffer of pH 7.4, contained combinations of 50 l M Cu(II), Ami and H 2 O 2 . At these conditions 55% of Cu(II) was present as CuHAmi, 35% as CuAmi, and the remaining 10% as Cu(II) aqua ion [1]. Cu(II) alone (lane 7) and H 2 O 2 alone (lane 3) increased the amount of form (II), but only marginally under those conditions. The presence of Ami alone (lane 8), with Cu(II) (lane 9) or with H 2 O 2 (lane 5) resulted in a higher conversion to form (II). The combination of Cu(II) and H 2 O 2 (lane 4) was more active, yielding mostly form (II) and also a trace of linear form (III), while the mixture of all three compo- nents (the Cu(II)-Ami complex in the presence of H 2 O 2 (lane 6) destroyed form (I) completely in these conditions, yielding  2/3 of form (II) and 1/3 of form (III). Another effect, seen specifically for samples containing Ami, was a faint smear between the well and the band of form II. It had the highest intensity for Cu(II)-free samples, both with and without H 2 O 2 (lanes 5 and 8). Having established the requirement of H 2 O 2 presence for complex-mediated DNA cleavage, we checked its reactivity at H 2 O 2 concentrations 10 and hundred times lower than the initial 50 l M (Fig. 4 part B). The effects of lower concentrations of H 2 O 2 alone (lanes 3 and 7) were at the background level. The activity of the mixture of Ami and H 2 O 2 was maintained at the constant level, independently of H 2 O 2 concentration. The activity of the Cu(II) and H 2 O 2 combination was found to be roughly proportional to the logarithm of H 2 O 2 concentration. The same can be estimated for the Cu(II)-Ami-H 2 O 2 system, but at a higher level of activity (lanes 6, 10). Figure 5 present the kinetics of pBR322 cleavage with Ami + H 2 O 2 (part A), Cu(II) + H 2 O 2 (part B), and Ami + Cu(II) + H 2 O 2 (part C) for incubation times between 5 and 95 min. As clearly seen, Ami + H 2 O 2 did not produce form (III), and the ratio of forms (I) and (II) remained constant throughout the experiment. In the presence of Cu(II) and the complex, the degradation process proceeded from decomposition of form (I) (almost complete at  90minincaseofCu(II)aquaionand 15 min for the complex), through the relaxed form II, to the linear form III. In the Cu(II) + H 2 O 2 system, the amount of form II increased during the duration of the experiment. Only for the complex in the presence of hydrogen peroxide a further degradation of both forms II and III was seen, to a smear of short DNA fragments at times longer than 75 min. Cleavage of yeast tRNA Phe induced by the Cu(II)-Ami-H 2 O 2 system Figure 6 shows the results of the strand-break assay of yeast tRNA Phe in the presence of Ami, Cu(II)-Ami and the Cu(II)-Ami-H 2 O 2 system, performed by means of poly- acrylamide gel electrophoresis. Strikingly, in the presence of Fig. 1. The schematic drawing of the Cu(II)-amikacin complex at pH 7.4, with the sites of breakage indicated by ESI-MS and MS/MS experiments. Arrows indicate the positions of breakages occurring in: ligand molecule, in the absence of Cu(II), Þ; Cu(II)-Ami complex, dottedarrow;inbothcases, fi . Ó FEBS 2002 DNA and RNA damage by Cu(II) amikacin complex (Eur. J. Biochem. 269) 5549 Ami or Cu(II)-Ami highly specific cleavages occurred in the anticodon loop, at Y37 (Fig. 7). These cleavages were already observed with 5-fold molar excess of the antibiotic or its copper(II) complex over tRNA Phe (lanes 4 and 9, Fig. 6). The cleavage intensities increased with the concen- tration of Ami and Cu(II)-Ami gradually, up to their Fig. 2. Typical ESI-MS spectra of amikacin (A), its Cu(II) complex in the absence (B) and presence (C) of H 2 O 2 , as well as the MS/MS experiment on the 587 m/z peak of amikacin (D). 5550 M. Je_zzowska-Bojczuk et al. (Eur. J. Biochem. 269) Ó FEBS 2002 50-fold molar excess (lanes 6, 7 and 11, 12, Fig. 6). This may reflect a saturation effect of a tight antibiotic binding site. Remarkably, the intensities of cleavages induced by free Ami were slightly higher than those induced by its Cu(II) complex. Cleavages generated in the presence of Cu(II)-Ami-H 2 O 2 system were more numerous. Two cleavages with similar intensities were observed at Y37 and A36 in the anticodon loop (lanes 13–19, Fig. 6). Moreover, several cleavages appeared also in the D -arm and their intensities increased with H 2 O 2 concentration. The most prominent cleavage site was localized at D17. The cleavages were weaker when the Cu(II)-Ami-H 2 O 2 system was prepared one hour before incubation with tRNA Phe (lanes 20 and 21, Fig. 6). In this case, three major cleavages were observed, at Y37, A36 and D17. It has to be noted, however, that the cleavage at D17 and in the D and anticodon loops occurred to some extent already in the presence of 10 l M Cu(II) ions and 50 l M H 2 O 2 (data not shown). No cleavage was observed, however, at Y37 in the absence of Ami or its Cu(II)-complex. Interest- ingly, in another RNA molecule, the 3¢ product of the genomic delta ribozyme, Ami and its Cu(II) complex induced no specific cleavages. Only upon the addition of H 2 O 2 several weak, nonspecific cleavages were found. DISCUSSION The initial target of oxidations promoted by Cu(II)-Ami is the complexed aminoglycoside molecule (Fig. 1). Two kinds of reactions were seen in the presence of Cu(II) and H 2 O 2 . Fragmentations occurred predominantly at glycosidic bonds between the rings and in the amide bond, linking the aglycon to ring B (see arrows at Fig. 1 and spectra at Fig. 2). Single and double oxygen additions were also seen (Table 1). The fragmentation experiments performed on the MS peaks of these adducts indicated their heterogeneity. The majority of secondary peaks are identical to those found for unmodified Ami (Table 2). This suggests that labile forms, perhaps hydroperoxides, constitute the major- ity of adducts, rather than products of hydroxylation. But even those two peaks which could be assigned to stable oxygen adducts (at m/z 528 and 436, Table 2) originate from two different molecules – the former from an adduct on one of the terminal rings and the latter from an adduct on the aglycon chain. Such a lack of specificity is charac- teristic for hydroxyl radical-like agents, and in this case can be ascribed to the reactivity of an activated oxygen atom, bound at the copper atom coordinated to the Ami molecule. All the peaks with Cu(II)/Ami ratios different than 1 : 1 are Table 1. Summary of the observed ESI-MS ions (m/z)atpH 7.4.Concentrations:Cu(II),Ami,0.5 m M and H 2 O 2 ,2.5 m M . w, weak, i, intermediate, s, strong signal; agl, aglycon chain; pep., aglycon chain broken at peptide bond; CO – NH, C a , aglycon chain broken between CO and C a . Components of the solution m/z Assignment Ami and Ami + H 2 O 2 1172 i Ami 2 +H + 587 s Ami + H + 425 i Ami – ring A or C – OH + H + 408 w Ami – ring A or C with O (glycosidic bond) + H + 315 w Ami – ring A or C – agl. C a – 2OH + H + 294 s Ami + 2H + 263 w Ami – ring A – ring C + H + 177 w ring A or C with O (glycosidic bond) + H + 162 w ring A or C + H + 147 w ring A or C – NH 2 +H + Cu(II)-Ami 1294 w Cu(II) 2 -Ami 2 +H + 1232 i Cu(II)-Ami 2 +H + 710 w Cu(II) 2 -Ami + H + 647 i Cu(II)-Ami + H + 385 i Cu(II)-Ami – ring A or C – agl. pep. + H + 355 w Cu(II) 2 -Ami + 2H + 324 i Cu(II)-Ami + 2H + and all the peaks seen for Ami Cu(II)-Ami-H 2 O 2 678 w Cu(II)-Ami + 2O + H + 663 w Cu(II)-Ami + O + H + 617 s Ami + 2O + H + 600 s Ami+O+H + 542 w Ami + 2O – agl. C a +H + 528 w Ami + O – agl. C a +H + 512 i Ami – (agl. C a )+H + 496 i Ami – agl. C a –OH+H + 484 w Ami – agl. pep. + H + 453 w Ami – agl. pep. – 2NH 2 +H + 439 w Ami + O – ring A or C + H + 339 w Cu(II)-Ami + 2O + 2H + 331 w Cu(II)-Ami + O + 2H + 308 s Ami + 2O + 2H + 300 s Ami+O+2H + and all the peaks seen for Ami and Cu(II)-Ami Ó FEBS 2002 DNA and RNA damage by Cu(II) amikacin complex (Eur. J. Biochem. 269) 5551 due to the decomposition of the Cu 2 Ami 2 dimer, which is formed during reduction of droplet volume in the process of injection into the MS instrument (see [12] for the studies of Cu 2 Ami 2 dimer formation). 8-Oxo-dG is the first relatively stable product of dG oxidation, used as a simple chemical model for introductory assessment of promutagenic/procarcinogenic properties of the agents studied [29–31]. Further oxidation products of dG are easily formed in vitro, because 8-oxo-dG has a lower oxidation potential than dG [32–34]. The main final products of oxidative dG destruction are more hydrophilic than dG and absorb UV weaker than either dG or 8-oxo- dG [35]. Therefore, they cannot be quantified in the same HPLC assay, and the loss of dG should be used instead, as an overall measure of reactivity. The susceptibility of 8-oxo-dG to further oxidation usually leads to a low steady-state abundance of 8-oxo-dG in model experiments in vitro. Thus, the yield of as much as 27% of 8-oxo-dG vs. total dG loss at 37 °Candasmuchas 53% at 25 °C, indicates a dG-specific, and thus a relatively mild oxidizing agent. Our study of the mechanism of H 2 O 2 activation by Cu(II)-Ami suggests the presence of a copper- bound oxygen radical [12]. DNA cleavage is another type of genotoxic activity. The initial experiment (Fig. 4) indicated that the ability of uncomplexed Ami to generate form (II) of the pBR322 plasmid equaled that of the complex at 0 or 0.5 l M H 2 O 2 , while Cu(II) alone in these conditions did not have such activity The lack of effects of H 2 O 2 suggested a nonredox process, especially as Ami itself is redox-inactive [12]. Form (II) is the relaxed form of the plasmid, devoid of super- helicity, therefore we speculated whether its formation was due to single-strand nicking or superhelix unwinding. Further experiments, aimed at finding out which of these options is true, demonstrated the lack of effect of incubation time and the lack of concentration effect of Ami between 5 l M and 25 m M , and differences in the extent of formation of form II between experiments (compare lanes 5 and 8 in Fig.4Aandlanes5and9inFig.4BwiththoseinFig. 5A), while the cleavage results for Cu(II) and Cu(II)-Ami were reproducible. This suggests the occasional presence of an Fig. 3. The experimental curves of the kinetic of dG decomposition (A) and 8-oxo-dG (B) formation caused by Cu(II)-Ami complexes in the presence of hydrogen peroxide. Solution contained sodium phosphate buffer, 50 m M ;AmiandCu(II),50l M ;H 2 O 2 ,0.5m M ;dG,50l M . Incubation at 37 °C. Fig. 4. Agarose gel electrophoresis of pBR322 plasmid cleavage by Cu(II)-Ami complex. The samples, incubated for 1 h at 37 °C, were ran on a 1% agarose gel, containing ethidium bromide for 1 h at 4 VÆcm )1 in Tris/borate/EDTA buffer. (A) Lane 1, plasmid; lane 2, plasmid linearized with XhoI endonuclease; lane 3, plasmid + 50 l M H 2 O 2 ; lane 4, plasmid + 50 l M CuCl 2 +50l M H 2 O 2 ;lane5,plasmid+ 50 l M Ami + 50 l M H 2 O 2 ;lane6,plasmid+50l M complex + 50 l M H 2 O 2 ;lane7,plasmid+50 l M CuCl 2 ;lane8,plasmid+50 l M Ami; lane 9, plasmid + 50 l M complex. (B) Lane 1, plasmid; lane 2, plasmid linearized with XhoI endonuclease; lane 3, plasmid + 5 l M H 2 O 2 ;lane4,plasmid+50l M CuCl 2 +5l M H 2 O 2 ; lane 5, plasmid +50l M Ami + 5 l M H 2 O 2 ;lane6,plasmid+50l M complex + 5 l M H 2 O 2 ; lane 7, plasmid + 0.5 l M H 2 O 2 ;lane8,plasmid+50l M CuCl 2 +0.5l M H 2 O 2 ;lane9,plasmid+50l M Ami + 0.5 l M H 2 O 2 ; lane 10, plasmid + 50 l M complex + 0.5 l M H 2 O 2 . Table 2. Results of MS/MS experiments. w; weak, i-intermediate, s-strong signal agl.; aglycon chain pep.; aglycon chain broken at peptide bond, CO – NH; C a ; aglycon chain broken between CO and C a ;C b ; aglycon chain broken between C a and C b ;C c ; aglycon chain broken between C b and C c . Observed m/z Assignment Amikacin (Ami + H + , m/z 587) 556 w Ami- agl. C c +H + 542 i Ami – agl. C b +H + 512 i Ami – agl. C a +H + 485 w Ami – agl. pep. + H + 467 w Ami – agl. + H + 453 i Ami – agl. pep. – 2 NH 2 +H + 425 s Ami – ring A or C + H + Cu(II)-amikacin-oxygen adduct (Ami + O + H + , m/z 600) 583 w Ami + H + 528 w Ami + O – agl. C a +H + 485 w Ami – agl. pep. + H + 467 w Ami – agl. + H + 453 i Ami- agl. pep. – 2 NH 2 +H + 425 s Ami – ring A or C + H + Cu(II)-amikacin-dioxygen adduct (Ami + 2O + H + , m/z 617) 585 i Ami + H + 573 i Ami – agl. C b +H + 481 i Ami – agl. pep. + H + 454 w Ami – agl. pep. – 2NH 2 +H + 436 i Ami + O – ring A or C + H + 422 i Ami – ring A or C + H + 5552 M. Je_zzowska-Bojczuk et al. (Eur. J. Biochem. 269) Ó FEBS 2002 unknown DNA-cleaving impurity in our samples, rather than a specific effect of uncomplexed Ami towards plasmid DNA. The Cu(II)-Ami complex was a superior DNA cleavage agent at 5 and 50 l M H 2 O 2 (Fig. 4). Only plasmid linearization, but not further degradation to short DNA fragments, was seen in this initial experiment. To obtain further information, the reaction kinetics was followed. As shown in Fig. 5A, the Ami-H 2 O 2 system was not able to convert the plasmid to form (III), even at long incubation times, and the ratio of forms (I) and (II) remained constant. In contrast, the extension of incubation times for the Cu(II)- Ami-H 2 O 2 system clearly demonstrated the gradual degra- dation of superhelical DNA to its linear form, and further, to a continuum of short DNA fragments (Fig. 5C). The relative persistence of form (II) and the stepwise character of plasmid DNA degradation through all the forms suggest that the DNA fragmentation is a result of accumulation of random single strand breaks in the plasmid, rather than the immediate formation of double strand breaks which was proposed previously for Cu(II) aqua ion interacting with DNA [36,37], but which would lead to the direct formation of form III from form I. In fact, our control mixture of Cu(II) ions and H 2 O 2 (Fig. 5B), also produced double strand scission in a stepwise fashion, degrading form I to form II and then to form III, but much slower than the complex. Altogether, our results indicate that Ami strongly activates Cu(II) ions to cleave plasmid DNA on a redox mechanism. As proposed previously, Ami complexation makes the both Cu(I)/Cu(II) and Cu(II)/Cu(III) redox pairs available, while the DNA-interacting Cu(II) aqua ion can only access the Cu(I)/Cu(II) redox pair [12]. This additional redox mechanism is clearly more efficient in exerting DNA strand breaks. It should be noted that the metal-bound rather than free oxygen radicals are the cleaving species in both systems [12,36]. Aminoglycoside antibiotics are known to interact with a variety of RNA targets including ribosomal RNAs [38], group I introns [39] and ribozymes [40]. In order to evaluate the ability of Cu(II)-Ami-H 2 O 2 system to promote cleavage of RNA we have chosen yeast tRNA Phe as a model substrate. Ami and Cu(II)-Ami complex induced highly specific cleavage in the anticodon loop, at the hipermodified base Y37 (wybutine) (Figs 6 and 7). Also other amino- glycosides, as kanamycin A, neomycin B and a synthetic neomycin-neomycin dimer have been shown to induce fragmentation of tRNA Phe at Y37 and additionally at m 7 G46 in the variable loop region [41]. Although no specific chemical mechanism was determined, two different types of Fig. 5. Kinetics of cleavage of pBR322 plasmid (15 l M per DNA bp) in 50 m M sodium phosphate buffer, pH 7.4, with 50 l M H 2 O 2 ,followedby agarose gel electrophoresis, in the presence of Ami alone (A), Cu(II) ions alone (B), and Cu(II)-Ami complex (C). The samples were incubated at 37 °C and then ran for 1 h on a 1% agarose gel, containing ethidium bromide, at 4 V cm )1 in Tris/borate/EDTA buffer. (A) Lane 1, plas- mid; lane 2, plasmid linearized with XhoI endonuclease; lanes 3–12, plasmid + 50 l M Ami + 50 l M H 2 O 2 incubated for 5, 15, 25, 35, 45, 55, 65, 75, 85, 95 min, respectively. (B) Lane 1, plasmid; lane 2, plasmid linearized with XhoI endonuclease; lanes 3–12, plasmid + 50 l M Cu(II) + 50 l M H 2 O 2 incubated for 5, 15, 25, 35, 45, 55, 65, 75, 85, 95 min, respectively. (C) Lane 1, plasmid; lane 2, plasmid linearized with XhoI endonuclease; lanes 3–12, plasmid + 50 l M Cu(II) + 50 l M Ami + 50 l M H 2 O 2 incubated during 5, 15, 25, 35, 45, 55, 65, 75, 85, 95 min, respectively. Fig. 6. Specificity of cleavages in yeast tRNA Phe , induced by Ami and its Cu(II) complex. 5¢-end-labeled tRNA Phe was mixed with unlabeled tRNA Phe to obtain final concentration of 1 l M . Lane 1, untreated tRNA Phe ,lane2,tRNA Phe +50l M Cu(II) ions; lanes 3–7, tRNA Phe +1,5,20,50,100l M amikacin, respectively; lanes 8–12, tRNA Phe + 1, 5, 20, 50, 100 l M complex, respectively; lane 13, tRNA Phe +20l M complex + 50 l M H 2 O 2 ; lane 14, tRNA Phe +50l M complex + 50 l M H 2 O 2 ; lane 15, tRNA Phe + 100 l M complex + 50 l M H 2 O 2 ; lane 16, tRNA Phe +50 l M complex + 10 l M H 2 O 2 ; lane 17, tRNA Phe +50l M complex + 20 l M H 2 O 2 ; lane 18, tRNA Phe +50l M com- plex + 50 l M H 2 O 2 ;lane19,tRNA Phe +50l M complex + 100 l M H 2 O 2 ; lane 20, tRNA Phe +50l M complex + 50 l M H 2 O 2 ,prepared 1 h before incubation with RNA; lane 21, tRNA Phe +50l M complex + 100 l M H 2 O 2 prepared 1 h before incubation with RNA; L, formamide ladder. Ó FEBS 2002 DNA and RNA damage by Cu(II) amikacin complex (Eur. J. Biochem. 269) 5553 mechanisms could explain the observed cleavages. One possibility is that Ami or Cu(II)-Ami complex binds to the RNA molecule and provides the basic functional group responsible for deprotonation of the critical 2¢-hydroxyl group and subsequent cleavage of the RNA chain via transesterification mechanism. A second possible mechan- ism involves the binding of the antibiotic to the RNA such that the resulting complex adopts a conformation more conducive to polynucleotide chain scission at these specific sites. The cleavages observed in the presence of Ami or Cu(II)-Ami were, however, exceptionally specific and effi- cient. This clearly suggests that Ami and its copper(II) complex bind tightly to the anticodon loop of tRNA Phe ,in the vicinity of Y37, which might be directly involved in the binding, especially as no specific cleavages were detected for the genomic delta ribozyme lacking modified bases in the presence of Ami or Cu(II)-Ami complex (our unpublished data). Hydrated Mg 2+ ion is bound directly to wybutine in the crystal structure of yeast tRNA Phe [42,43] and the presence of a tight metal-ion-binding site in the anticodon loop was also confirmed in solution by means of Eu 3+ - induced cleavage method [44]. Specific cleavages at U33 and A36 were observed and they disappeared after removing wybutine. Interestingly, enhancement of wybutine fluores- cence was observed after addition of neomycin B or kanamycin A to tRNA Phe and the effect was similar to that one caused by magnesium ions [41]. Occupation of the same binding site for metal ions and aminoglycoside antibiotics is often observed in RNA and, for example, displacement of metal ions by antibiotics inhibits catalytic properties of ribozymes [39,40]. The decrease of tRNA cleavage upon the addition of Cu(II) simply reflects the lowered affinity of Ami to the nucleic acid in the complex, due to electrostatic and/or conformational reasons, same as with DNA. Different cleavage patterns of yeast tRNA Phe obtained in the presence of Cu(II)-Ami and the Cu(II)-Ami- H 2 O 2 system can be explained by different mechanisms of these reactions. The addition of H 2 O 2 resulted in the appearance of additional cleavages in several new positions, near the putative complex binding site, but also in the D-arm. The increase of H 2 O 2 concentration resulted in multiple cleavages and a gradual loss of specificity (Fig. 6). This pattern suggests that, in addition to copper-bound active oxygen, also free radicals are generated as side- reaction and confer further damage. These results are in excellent agreement with the mechanism of H 2 O 2 activation by Cu(II)-Ami [12]. One can speculate that the binding of Cu(II)-Ami to wybutine is enhanced by the formation of a coordination bond between Ami-complexed Cu(II), which is coordina- tively unsaturated at pH 7.4 [1,12], and the secondary amine nitrogen present in the wybutine residue. CONCLUSIONS The processes of dG, DNA and RNA oxidation clearly demonstrate that Cu(II)-Ami is a potentially dangerous genotoxic agent. Cu(II)-coordinated Ami retains the ability to bind to nucleic acids and cleave phosphodiester bonds. The complex activates H 2 O 2 , producing both metal bound and diffusible radical species, capable of conferring various kinds of oxidative damage to nucleic acids and their components. Ami hydroperoxides, formation of which was suggested by MS experiments, may also be involved in these reactions. Concentrations of amikacin used in all experiments were comparable to its therapeutic ones, which are in the range of 50–70 l M in blood serum [45–48]. The issue of intracellular copper bioavailability is currently debated [49–51]. However, there is a mobile pool of copper in blood serum, which may be additionally increased by deleterious oxidative events [52]. 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