Biochemical mechanisms of aminoglycoside cell toxicity. I. The uptake of gentamicin by cultured skin fibroblasts and the alteration of lysosomal enzyme activities

In order to study the toxicity of aminoglycoside, human skin fibroblasts were used as a model for basic studies, since they are known to have a specific aminoglycoside-binding site and to translocate the drug into the cells. Following the exposure of fibroblasts to gentamicin for 3 days, the cells formed many osmiophilic lamellar materials (myeloid bodies) in the lysosomes, while the other cellular structures appeared to remain normal. Although gentamicin was intensively accumulated within the lysosomes, intralysosomal pH, determined by the fluorescence intensity ratio method using fluorescein-isothiocyanate-labeled dextran, did not alter. Among the lysosomal enzymes, the activities of six different glycosidases were unchanged. On the other hand, sphingomyelinase and acid lipase activities were greatly decreased, while phospholipase A activity was increased. These results indicate that the lipid metabolism of fibroblasts is altered by gentamicin treatment, and that perturbation of intralysosomal pH can not be the cause of the changes observed in cell lysosomal enzyme activities.     

Role of oxidative stress in lysosomal membrane permeabilization and apoptosis induced by gentamicin, an aminoglycoside antibiotic

Gentamicin, an aminoglycoside antibiotic used to treat severe bacterial infections, may cause acute renal failure. At therapeutic concentrations, gentamicin accumulates in lysosomes and induces apoptosis in kidney proximal tubular cells. In gentamicin-treated renal LLC-PK1 cells, acridine orange release from lysosomes, previously interpreted as lysosomal membrane permeabilization, precedes the apoptotic cascade that develops during incubation with gentamicin. However, the link between gentamicin lysosomal accumulation and apoptosis remains unclear. We here examined if reactive oxygen species (ROS) production could account for gentamicin-induced acridine orange release and apoptosis, and the implication of iron in these events. We found that gentamicin induced ROS production prior to, and at lower drug concentrations than required for, acridine orange release and apoptosis. ROS antioxidant or scavenger, catalase, and N-acetylcysteine largely prevented these events. Vital confocal imaging revealed that gentamicin-induced ROS production occurs in lysosomes. Deferoxamine, an iron chelator, which is endocytosed and accumulates in lysosomes, largely prevented gentamicin-induced ROS production as well as apoptosis. Direct evidence for gentamicin-induced permeabilization of lysosomal membrane was provided by showing the release into the cytosol of Lucifer yellow, a membrane-impermeant endocytic tracer with a comparable molecular weight as gentamicin. Altogether, our data demonstrate a key role of lysosomal iron and early ROS production in gentamicin-induced lysosomal membrane permeabilization and apoptosis.     

Morphological alterations in distal and collecting tubules of the rat renal cortex after aminoglycoside administration at low doses

Ultrastructural alterations in the cortical, distal and collecting tubules have been examined in female Sprague-Dawley rats treated with various aminoglycosides in clinical use. Gentamicin, dibekacin (10 mg/kg X day), netilmicin, tobramycin (4 or 10 mg/kg X day) or amikacin (37.5 mg/kg X day) were administered intraperitoneally twice a day over different periods of time, extending from 4 to 14 days. The kidney cortex was examined after 4, 7, 10 or 14 days of aminoglycoside administration by light (semithin sections) and electron microscopy. After 7 or more days of treatment, lysosomes in collecting tubular cells (and to a lesser extent in distal tubular cells) contained concentric lamellar material (myeloid bodies), an ultrastructural alteration typical of drug-induced lysosomal phospholipidosis. Although this alteration appeared qualitatively similar to that observed in proximal tubular cells, it was less conspicuous and occurred later during treatment. In addition, distal tubular cells occasionally showed marked vacuolization and disruption of the basal cell architecture. The possible relationship between these alterations and the urine hypo-osmolality characteristic of aminoglycoside-induced renal dysfunction is discussed.     

Increase of sensitivity to aminoglycoside antibiotics by polyamine-induced protein (oligopeptide-binding protein) in Escherichia coli.

The sensitivity of Escherichia coli to several aminoglycoside antibiotics was examined with E. coli DR112 transformed by the gene for polyamine-induced protein (oligopeptide-binding [OppA] protein) or polyamine transport proteins. The results clearly showed that sensitivity to aminoglycoside antibiotics (gentamicin, isepamicin, kanamycin, neomycin, paromomycin, and streptomycin) increased due to the highly expressed OppA protein. When the gene for OppA protein was deleted, sensitivity to aminoglycoside antibiotics was greatly decreased. It was also shown that isepamicin could bind to OppA protein with a binding affinity constant of 8.5 x 10(3) M-1 under the ionic conditions of 50 mM K+ and 1 mM Mg2+ at pH 7.5, and isepamicin uptake into cells was greatly stimulated by the OppA protein. These results, taken together, show that the OppA protein increases the uptake of aminoglycoside antibiotics. In addition, the OppA protein increased the transport of spermidine and an oligopeptide (Gly-Leu-Tyr). The uptake of isepamicin into cells was partially inhibited by spermidine, suggesting that the binding site for isepamicin overlaps that for spermidine on the OppA protein. Spermidine uptake activity by the OppA protein was less than 1% of that of the ordinary spermidine uptake system. Aminoglycoside antibiotics neither stimulated the synthesis of OppA protein nor increased spermidine uptake.     

An aminoglycoside sensing riboswitch controls the expression of aminoglycoside resistance acetyltransferase and adenyltransferases

The emergence of antibiotic resistance in human pathogens is an increasing threat to public health. The fundamental mechanisms that control the high levels of expression of antibiotic resistance genes are not yet completely understood. The aminoglycosides are one of the earliest classes of antibiotics that were introduced in the 1940s. In the clinic aminoglycoside resistance is conferred most commonly through enzymatic modification of the drug although resistance through enzymatic modification of the target rRNA through methylation or the overexpression of efflux pumps is also appearing. An aminoglycoside sensing riboswitch has been identified that controls expression of the aminoglycoside resistance genes that encode the aminoglycoside acetyltransferase (AAC) and aminoglycoside nucleotidyltransferase (ANT) (adenyltransferase (AAD)) enzymes. AAC and ANT cause resistance to aminoglycoside antibiotics through modification of the drugs. Expression of the AAC and ANT resistance genes is regulated by aminoglycoside binding to the 5′ leader RNA of the aac/aad genes. The aminoglycoside sensing RNA is also associated with the integron cassette system that captures antibiotic resistance genes. Specific aminoglycoside binding to the leader RNA induces a structural transition in the leader RNA, and consequently induction of resistance protein expression. Reporter gene expression, direct measurements of drug RNA binding, chemical probing and UV cross-linking combined with mutational analysis demonstrated that the leader RNA functioned as an aminoglycoside sensing riboswitch in which drug binding to the leader RNA leads to the induction of aminoglycoside antibiotic resistance. This article is part of a Special Issue entitled: Riboswitches.     

Chloroquine-induced phospholipid fatty liver. Measurement of drug and lipid concentrations in rat liver lysosomes

A method has been developed to measure the concentration of chloroquine in lysosomes isolated from the liver of rats. It employs 3H2O and [U-14C]sucrose to determine the intralysosomal water volume of purified lysosomes obtained by free flow electrophoresis. Twelve h after a single dose, the concentration of chloroquine in lysosomes was 6.3 mM and at 24 h it rose to 16.5 mM. With continued treatment, lysosomal chloroquine concentrations were 61 and 74 mM at 48 and 72 h. The lysosomal concentrations of chloroquine attained were sufficient to block intralysosomal phospholipase A1 activity. The lysosomal content of phospholipid rises 1.7-fold and 2.6-fold over that of control at 12 and 24 h, respectively. At 72 h, lysosomal phospholipid was 3.7-fold greater than that of control. Lysosomes show an increased negative surface charge with chloroquine administration which is due in part to an increased ratio of acidic to neutral phospholipids in the lysosomal membrane. The phosphatidylinositol content of lysosomes rose rapidly with chloroquine treatment and accounted for the early increase in the ratio. Bis(monoacylglycero)phosphate, an acidic phospholipid synthesized only in lysosomes, increased later in the course of chloroquine treatment and accounted for the continued increase in acidic phospholipids.     

Characteristics of the binding of aminoglycoside antibiotics to teichoic acids. A potential model system for interaction of aminoglycosides with polyanions

The binding of the aminoglycoside antibiotic dihydrostreptomycin to defined cell-wall teichoic acids and to lipoteichoic acid isolated from various gram-positive eubacteria was followed by equilibrium dialysis. Dihydrostreptomycin was used at a wide range of concentration under different conditions of ionic strength, concentration of teichoic acid, presence of cationic molecules like Mg2+, spermidine, other aminoglycoside antibiotics (gentamicin, neomycin, paromomycin). Interaction of dihydrostreptomycin with teichoic acid was found to be a cooperative binding process. The binding characteristics seem to be dependent on structural features of teichoic acid and are influenced by cationic molecules. Mg2+, spermidine and other aminoglycosides antibiotics inhibit the binding of dihydrostreptomycin to teichoic acid competitively. The binding of aminoglycosides to teichoic acids is considered as a model system for the interaction of aminoglycoside antibiotics with cellular polyanions. Conclusions of physiological significance are drawn.     

Characterization of Saccharomyces cerevisiae mutants supersensitive to aminoglycoside antibiotics.

We describe mutants of Saccharomyces cerevisiae that are more sensitive than the wild type to the aminoglycoside antibiotics G418, hygromycin B, destomycin A, and gentamicin X2. In addition, the mutants are sensitive to apramycin, kanamycin B, lividomycin A, neamine, neomycin, paromomycin, and tobramycin--antibiotics which do not inhibit wild-type strains. Mapping studies suggest that supersensitivity is caused by mutations in at least three genes, denoted AGS1, AGS2, and AGS3 (for aminoglycoside antibiotic sensitivity). Mutations in all three genes are required for highest antibiotic sensitivity; ags1 ags2 double mutants have intermediate antibiotic sensitivity. AGS1 was mapped 8 centimorgans distal from LEU2 on chromosome III. Analyses of yeast strains transformed with vectors carrying antibiotic resistance genes revealed that G418, gentamicin X2, kanamycin B, lividomycin A, neamine, and paromomycin are inactivated by the Tn903 phosphotransferase and that destomycin A is inactivated by the hygromycin B phosphotransferase. ags strains are improved host strains for vectors carrying the phosphotransferase genes because a wide spectrum of aminoglycoside antibiotics can be used to select for plasmid maintenance.     

Lysosomal cystine transport. Effect of intralysosomal pH and membrane potential

The regulation of lysosomal cystine transport was studied using cystine dimethyl ester-loaded lysosomes isolated from human diploid fibroblasts. Net efflux from normal fibroblast lysosomes was compared to that from lysosomes of cystinotic fibroblasts, which contain an inherited mutation decreasing lysosomal cystine transport. This exodus of cystine from normal fibroblast lysosomes was greater than from cystinotic fibroblast lysosomes. When lysosomes were incubated with both 5 mM MgCl2 and 2 mM ATP (Mg/ATP), the amount of lysosomal cystine lost from normal lysosomes doubled, but the amount of cystine lost from cystinotic lysosomes remained small. This effect of Mg/ATP on cystine loss from lysosomes isolated from normal fibroblasts was abolished when either carbonyl cyanide m-chlorophenylhydrazone or N-ethylmaleimide was present, suggesting that the effect of Mg/ATP was mediated by the action of a lysosomal proton-translocating ATPase. Addition of KCl, RbCl, or NaCl to normal lysosomes caused smaller increases in cystine exodus. A variety of experimental conditions altered lysosomal pH, membrane potential, and the cystine lost from normal fibroblast lysosomes. These same experimental conditions produced similar alterations in the lysosomal pH and membrane potential of cystinotic fibroblast lysosomes without a comparable alteration in cystine loss. These results have led us to propose a model in which the transport of cystine out of the normal lysosome is regulated by both the lysosomal membrane potential gradient and the transmembrane pH gradient.     

Characterization of a phosphate transport system in human fibroblast lysosomes.

The uptake of [32P]KH2PO4 by Percoll-purified human fibroblast lysosomes at pH 7.0 was investigated to determine if lysosomes contain a transport system recognizing phosphate. Lysosomal phosphate uptake was linear for the first 2 min, attained a steady state by 8-10 min at 37 degrees C, and was not Na+ or K+ dependent. Upon entering lysosomes, [32P]phosphate was rapidly metabolized to trichloroacetic acid-soluble and trichloroacetic acid-insoluble products. After 1-min incubations, 50% of the radioactivity recovered from lysosomes was in the form of inorganic phosphate; and after a 2.5-min incubation, 27% of the radioactivity was recovered as inorganic phosphate. When lysosomes are loaded with radioactivity by incubation with 0.03 mM [32P]KH2PO4 for 25 min and then washed at 4 degrees C, lysosomes fail to release the accumulated radioactivity during a subsequent incubation at 37 degrees C. Lysosomal phosphate uptake gave linear Arrhenius plots (Q10 = 1.8) and was inversely proportional to medium osmolarity. Phosphate uptake was maximal at pH 5-6, half-maximal at pH 7.1, with little transport activity at pH greater than 8, suggesting that the transport system recognizes the monobasic form of phosphate. Lysosomal phosphate uptake is saturable, displaying a Km of 5 microM at pH 7.0 and 37 degrees C. High specificity for phosphate is demonstrated since large concentrations of Na2SO4, NaHCO3, KCl, NaCl, 5'-AMP, or the anion transport inhibitor, 4,4'-diisothiocyanatostilbene-2,2'-disulfonate, have no effect on lysosomal phosphate transport. In contrast, the phosphate analog, arsenate, strongly inhibits lysosomal phosphate uptake in a competitive manner with a Ki of 7 microM. Pyridoxal phosphate, CTP, adenosine 5'-(beta,gamma-imino)triphosphate (AMP-PNP), and glucose 6-phosphate were found to be noncompetitive inhibitors of lysosomal phosphate uptake displaying Ki values of 80-250 microM. When lysosomes are incubated with [gamma-32P]ATP, the lysosomal membrane ATPase hydrolyzes the ATP to form inorganic phosphate which then enters lysosomes by this lysosomal phosphate transport route.     

Hairpin ribozyme cleavage catalyzed by aminoglycoside antibiotics and the polyamine spermine in the absence of metal ions.

The hairpin ribozyme is a small catalytic RNA that achieves an active configuration by docking of its two helical domains in an antiparallel fashion. Both docking and subsequent cleavage are dependent on the presence of divalent metal ions, such as magnesium, but there is no evidence to date for direct participation of such ions in the chemical cleavage step. We show that aminoglycoside antibiotics inhibit cleavage of the hairpin ribozyme in the presence of metal ions with the most effective being 5-epi-sisomicin and neomycin B. In contrast, in the absence of metal ions, a number of aminoglycoside antibiotics at 10 mM concentration promote hairpin cleavage with rates only 13-20-fold lower than the magnesium-dependent reaction. We show that neomycin B competes with metal ions by ion replacement with the postively charged amino groups of the antibiotic. In addition, we show that the polyamine spermine at 10 mM promotes efficient hairpin cleavage with rates similar to the magnesium-dependent reaction. Low concentrations of either spermine or the shorter polyamine spermidine synergize with 5 mM magnesium ions to boost cleavage rates considerably. In contrast, at 500 microM magnesium ions, 4 mM spermine, but not spermidine, boosts the cleavage rate. The results have significance both in understanding the role of ions in hairpin ribozyme cleavage and in potential therapeutic applications in mammalian cells.     

Mediated calcium transport by isolated human fibroblast lysosomes

Lysosomes purified by Percoll gradient from normal human fibroblasts (GM0010A) show uptake of Ca2+ in a mediated manner. The uptake is linear over the first 1.5 min and approaches a steady state by 10 min. Uptake is saturable, displaying a Vmax of about 10 pmol/min/unit hexosaminidase at 20 mM Ca2+ (7 nmol/min/mg protein), and a Km of 5.7 mM. Ca2+ uptake increases with increasing extralysosomal pH from 5.0 to 8.5. The Q10 is 1.6, and Ea 8.7 kcal/mol. Uptake of 0.1 mM Ca2+ was inhibited to the extent indicated by 1.0 mM of the following: Cd2+, 100%; Hg2+, 100%; Zn2+, 89%; Mg2+, 77%; Ba2+, 60%; Sr2+, 37%; Fe2+, 20%; Cu2+, 0%. Mono- and trivalent cations had no effect. ATP (1.0 mM) inhibited uptake by 80%, and chloroquine (0.1 mM) inhibited by 60%, as did 1.0 mM L-cystine. Cysteamine, N-ethylmaleimide, and the anions Cl-, SO(2-)4, and acetate had no effect. The calcium ionophore A23187 augmented uptake by 10-fold at 10 microM. Surprisingly, Pb2+ greatly augmented lysosomal Ca2+ uptake in a concentration-dependent manner. Pb2+, however, adversely affected lysosomal latency. Lysosomal calcium uptake was not affected by inositol 1,4,5-triphosphate, and calcium-induced calcium release from lysosomes was not observed. A role for lysosomes in cellular calcium homeostasis has not been previously suggested. This work shows that Ca2+ can be transported into and out of lysosomes and could assist in lysosomal proteolysis. The extent of further lysosomal participation in cellular calcium regulation is unclear.     

Uptake of aminoglycoside antibiotics into brush-border membrane vesicles and inhibition of (Na+ + K+)-ATPase activity of basolateral membrane

The effects of aminoglycoside antibiotics on plasma membranes were studied using rat renal basolateral and brush-border membrane vesicles. 3',4'-Dideoxykanamycin was bound to the basolateral membrane and brush-border membrane vesicles. They had a single class of binding sites with nearly the same constant, and the basolateral membrane vesicles had more binding sites than those of the brush-border membrane. Dideoxykanamycin B was transported into the intravesicular space of brush-border membrane vesicles, but not into that of basolateral membrane vesicles. The (Na+ + K+)-ATPase activity of the plasma membrane fraction prepared from the kidney of rat administered with dideoxykanamycin B intravenously decreased significantly. Aminoglycoside antibiotics entrapped in the basolateral membrane vesicles inhibited (Na+ + K+)-ATPase activity, but those added to the basolateral membrane vesicles externally failed to do so. The activity of (Na+ + K+)-ATPase was non-competitively inhibited by gentamicin. It is thus concluded that aminoglycoside antibiotics are taken up into the renal proximal tubular cells across the brush-border membrane and inhibit the (Na+ + K+)-ATPase activity of basolateral membrane. This inhibition may possibly disrupt the balance of cellular electrolytes, leading to a cellular dysfunction, and consequently to the development of aminoglycoside antibiotics' nephrotoxicity.     

Herpes simplex virus and human cytomegalovirus replication in WI-38 cells. III. Cytochemical localization of lysosomal enzymes in infected cells.

Cytochemical localization of the lysosomal enzymes acid phosphatase and arylsulfatase in cells infected by herpes simplex virus (HSV) or human cytomegalovirus (CMV) showed the following interactions between viruses and host cell lysosomes: (i) many enveloped progeny viruses were located within cytoplasmic vacuoles containing lysosomal enzyme activity; (ii) naked cytoplasmic capsids appeared to acquire an envelope by budding directly into lysosomes; and (iii) many of the cytoplasmic dense bodies that are characteristic of CMV-infected cells and are thought to represent noninfectious aggregates of CMV structural proteins (I. Sarov and I. Abady, Virology 66:464-473, 1975) also acquired a limiting membrane by budding into lysosomes. Autophagy of other cytoplasmic elements was not observed, suggesting that there is some specificity involved in the association of viral particles and CMV dense bodies with lysosomes. Despite the presence of potentially destructive hydrolases, there was little evidence of significant morphological damage to intralysosomal viruses, and high titers of infectious particles were released into the medium. It would therefore appear that significant levels of HSV and CMV infectivity normally persist even though many progeny particles are directly exposed to lysosomal enzymes.     

The interaction of cephaloridine with model membrane systems and rat kidney lysosomes.

The antibiotic cephaloridine has been shown to interact with phospholipid structures, using the techniques of ultraviolet difference spectroscopy, surface pressure measurements and liposome models. The results indicate that this interaction is at least partly hydrophobic in nature and help explain the disruptive effects of high concentrations of cephaloridine on both artificial and natural phospholipid structures (lysosomes). Low concentrations of cephaloridine were shown to inhibit a lysosomal membrane-bound phospholipase 2 and it is suggested that such an inhibition may explain the cephaloridine-induced stabilization of rat-kidney lysosomes.     

Interactions of aminoglycoside antibiotics with phospholipids. A deuterium nuclear magnetic resonance study.

The effect of several aminoglycoside (AG) antibiotics on aqueous multilamellar dispersions of mixtures of phosphatidylinositol (PI) and deuterated phosphatidylcholine (PC) has been studied by deuterium (2H) NMR. Isepamicin and amikacin gave rise to no significant changes in 2H-NMR lineshape relative to that of the lipid mixture without antibiotic. Both kanamycin A and B, which have a greater affinity for PI than the other two antibiotics examined in this study, induced temperature-dependent changes in 2H-NMR lineshapes and associated spectral moments. The results are consistent with an antibiotic-induced lateral phase separation giving rise to PC-enriched domains free of drug and PI-AG domains. These effects are correlated with the inhibitory potency of aminoglycosides towards PC degradation.     

Effect of solvent and protein dynamics in ligand recognition and inhibition of aminoglycoside adenyltransferase 2″‐Ia

The aminoglycoside modifying enzyme (AME) ANT(2″)‐Ia is a significant target for next generation antibiotic development. Structural studies of a related aminoglycoside‐modifying enzyme, ANT(3″)(9), revealed this enzyme contains dynamic, disordered, and well‐defined segments that modulate thermodynamically before and after antibiotic binding. Characterizing these structural dynamics is critical for in situ screening, design, and development of contemporary antibiotics that can be implemented in a clinical setting to treat potentially lethal, antibiotic resistant, human infections. Here, the first NMR structural ensembles of ANT(2″)‐Ia are presented, and suggest that ATP‐aminoglycoside binding repositions the nucleotidyltransferase (NT) and C‐terminal domains for catalysis to efficiently occur. Residues involved in ligand recognition were assessed by site‐directed mutagenesis. In vitro activity assays indicate a critical role for I129 toward aminoglycoside modification in addition to known catalytic D44, D46, and D48 residues. These observations support previous claims that ANT aminoglycoside sub‐class promiscuity is not solely due to binding cleft size, or inherent partial disorder, but can be controlled by ligand modulation on distinct dynamic and thermodynamic properties of ANTs under cellular conditions. Hydrophobic interactions in the substrate binding cleft, as well as solution dynamics in the C‐terminal tail of ANT(2″)‐Ia, advocate toward design of kanamycin‐derived cationic lipid aminoglycoside analogs, some of which have already shown antimicrobial activity in vivo against kanamycin and gentamicin‐resistant P. aeruginosa. This data will drive additional in silico, next generation antibiotic development for future human use to combat increasingly prevalent antimicrobial resistance.     

Accumulation of indigestible substances reduces fusion competence of macrophage lysosomes

It is well known that mouse macrophages loaded with indigestible substances become highly vacuolated. However, why this vacuolization occurs and its effect on lysosome function and intracellular transport during endocytosis remain unknown. Here, macrophage vacuoles were formed by incubation with sucrose or a tripeptide of the D-isomer of alanine and were determined to be lysosomal in origin by staining with the lysosomal glycoproteins and lysosomal hydrolases. However, as indicated by confocal and electron microscopy, subsequent delivery of both fluid phase (lucifer yellow, horse-radish peroxidase) and receptor-bound ligands (IgG complexes) was significantly reduced, suggesting that indigestible material reduced the ability of the loaded lysosomes to fuse with endosomes containing newly internalized tracers. Nevertheless, ligands internalized by the vacuolated cells were degraded at almost the normal rate, indicating that degradation occurs in the absence of delivery to the loaded lysosomes. We have also found that this fusion inhibition occurs in human alveolar macrophages loaded with physiologic debris from smoking and asbestos. These results suggest that indigestible material within lysosomes, such as is present in residual bodies in vivo, may affect their fusion competence.     

Detection of broad-spectrum aminoglycoside antibiotics through fluorescence-labeling aminoglycoside acetyltransferase(6')-Ii

Aminoglycosides are among the most commonly used antibiotics. The intensive use of aminoglycoside antibiotics has led to the problem of food contamination and the development of antibiotic-resistant bacteria. In the present study, we developed an effective method for easy sensitive detection of broad-spectrum aminoglycoside antibiotics. Aminoglycoside 6′-N-acetyltransferase family catalyzes the transfer of an acetyl group from acetyl coenzyme A (acetyl-CoA) to the 6′ amino group of the aminoglycoside, which is one of the most widespread determinants of aminoglycoside resistance. Because acetyl-CoA is naturally present only in living organisms, it is expected that the enzyme can bind with aminoglycoside antibiotics without catalysis in vitro. The enzyme was mutated for the introduction of a cysteine residue to flexible loops close to the binding site, which was then labeled with thio-labeling reagent fluorescein-5-maleimide. The labeled enzymes were characterized with kinetic and binding studies of various known aminoglycoside antibiotics. The binding of the labeled enzyme with aminoglycoside antibiotics causes a conformational change of the enzyme, which subsequently changes the hydrophobicity and hydrophilicity environment of fluorescent labeling reagent resulting in emission of fluorescence. This study provides a sensitive detection method for residual aminoglycoside antibiotics and strategies to screen and discover new effective aminoglycoside antibiotics.     

On the interaction between heparin and some aminoglycoside antibiotics

An interaction between the aminoglycoside antibiotics and heparin wherein charge transfer complexes are formed has been investigated to determine the degree of inhibition of antibacterial function of the antibiotic in the complexed form.Minimum inhibitory concentration (MIC) values have been obtained for the action of the aminoclycoside antibiotics tobramycin, gentamicin, amikacin, kanamycin, and streptomycin, on a sensitive strain ofE. coli. Growth curves ofE. coli determined at concentrations of these antibiotics just below the MIC demonstrated significant lengthening of the lag phase relative to control growth curves generated in the absence of antibiotic. Heparin (1 U ml^–1 and 10 U ml^–1) had no effect on control growth curves; however, particularly at the higher concentration, it reduced the effect on the lag phase produced by the aminoglycoside antibiotics. Thus kanamycin, gentamicin, and tobramycin were most affected, while amikacin and streptomycin were least affected. The rank order of inhibition of antibiotic activity by interaction with heparin was in qualitative agreement with previously published figures for the degree of complexation between antibiotics and heparin.