Nanocomplexes on the basis of Taunit associated with biocides as effective anti-cyanobacterial agents

Cyanobacteria are photoautotrophic bacteria that are known also as blue-green algae. They accumulate on different surfaces and objects and contribute to their biodegradation. Moreover, cyanobacteria produce toxins, which lead to harmful environmental and human health impacts. Hence, cyanobacterial growth control problem is very vital. The goal of the study was to obtain new nanocomplexes on the basis of a modern nanomaterial Taunit associated with antibiotic chloramphenicol and herbicide diuron and to test their antimicrobial effect against a model organism such as the unicellular cyanobacterium Synechocystis sp. PCC 6803. A nanomaterial made of multiwalled carbon nanotubes (MWCNTs) called Taunit was used for the first time to obtain nanocomplexes coupled either with herbicide diuron (DCMU (3-(3,4-dichlorophenyl)- 1,1-dimethylurea) or with antibiotic chloramphenicol. A small amount of Taunit (~1 mg) was needed to adsorb micrograms of diuron or chloramphenicol. The new formed nanocomplexes differentiate in their antimicrobial activity, which could be explained by the difference in their chemical mechanism of action. Taunit ? diuron complex showed a higher biocide action against cyanobacterium than the Taunit ? chloramphenicol complex. The results allow to discuss the prospects of research on the use of Taunit ? diuron complex as a coating for various surfaces exposed to cyanobacteria fouling.     

Gramicidin S identified as a potent inhibitor for cytochrome bd-type quinol oxidase

Gramicidin S, a cationic cyclic decapeptide, exhibits the potent antibiotic activity through perturbation of lipid bilayers of the bacterial membrane. From the screening of natural antibiotics, we identified gramicidin S as a potent inhibitor for cytochrome bd-type quinol oxidase from Escherichia coli. We found that gramicidin S inhibited the oxidase with IC(50) of 3.5 microM by decreasing V(max) and the affinity for substrates but showed the stimulatory effect at low concentrations. Our findings would provide a new insight into the development of gramicidin S analogs, which do not share the target and mechanism with conventional antibiotics.     

Lyophilization of the spores and vegetative cells of Bacillus brevis var. G-B.--producer of gramicidin S

Viability, antibiotic properties and variation of 4 variants of Bac. brevis var. G.-B. were studied after lyophilization and storage for a year in the lyophilized state. It was shown that the spores and vegetative cells of S and P- variants not synthesizing gramicidin S were somewhat more stable than the spores and cells of R and P+ variants producing the antibiotic. The latter dissociated by 10 per cent towards the cells producing and not producing gramicidin. The developmental rate of the lyophilized vegetative cells was higher than that of the lyophilized spores. Under analogous cultivation conditions they produced higher amounts of the biomass and antibiotic. The lyophilization method described may be recommended for the maintenance of viability and stability of the spores and vegetative cells of Bacillus brevis var. G.-B. producing gramicidin S.     

Production of teicoplanin by valine analogue-resistant mutant strains of Actinoplanes teichomyceticus

Teicoplanin is a glycopeptide antibiotic produced by Actinoplanes teichomyceticus. A strain improvement to increase the productivity of the major component, teicoplanin A2-2, was carried out. As the fatty moiety of teicoplanin A2-2 is derived from L-valine, L-valine analogue (valine hydroxamate)-resistant mutants were derived. One of the mutants, 98-1-227, overproduced valine and produced a higher titer of total teicoplanin with higher A2-2 content. In a pilot fermentor (7 m3), the total productivity of teicoplanin was 1,800 units/ml and the A2-2 content was 58%.     

Localization of gramicidin S on the cytoplasmic membrane of Bacillus brevis and its effect on the activity of membrane enzymes

It was shown that malate dehydrogenase of isolated membranes of the gramicidin S producer Bacillus brevis var. G.-B. (R.-form) is completely inhibited by the antibiotic (approximately 200 mkg/mg of protein). Succinate and NADH dehydrogenases at concentration up to 1 mg per mg of protein are insensitive to it, while corresponding oxidases are inhibited by the antibiotic not more than by 65 -- 75% apparently due to partial damage of the terminal parts of the respiratory chain. The respiration of the producer intact cells is inhibited by exogenous gramicidin S by not more than 55 -- 60%, while the respiration of antibiotic-sensitive cells of M.lysodeikticus is inhibited completely. It was shown that phosphatidyl ethanolamine (50%), phosphatidyl glycerol (15% and diphosphatidyl glycerol (25%) are the major phospholipid components of the membranes of the given strain of Bac. brevis. It was assumed that the resistance of Bac. brevis cells to gramicidin S is partly due to the constant ratio of the charged and amphoteric phospholipids. Using 31P-NMR spectroscopy, the kinetics of free phosphoric compounds in the cells and cell extracts of Bac. brevis during culture growth and gramicidin S synthesis were studied. The content of carbohydrate monophosphate, remained unaffected, while that of nucleoside di- and triphosphates and dinucleotides was low and at definite density and gramicidin S content (above 100 mkg/ml) fell down below the resolution capacity of the method employed. Evidence for gramicidin S localization of the Bac. brevis membrane and possible causes for the manifestation of the NADH dehydrogenase activity at a certain stage of culture growth are discussed.     

Membranes of bacteria and mechanism of action of the antibiotic gramicidin S]

The cyclopeptide antibiotic gramicidin S taken at a concentration of 100--200 mkg/mg membrane protein rapidly increases the permeability of M. lysodeikticus protoplast membranes for substrates of respiratory chain and exogenous cytochromes c. Prolonged incubation of gramicidin S with protoplasts results in their lysis which is more fast at low temperatures. In contrast to natural gramicidin, a derivative of gramicidin S with acetylated amino groups does not inhibit either the micrococcus membrane dehydrogenase or the whole of respiratory chain and does not affect the osmotic barrier of protoplasts. Aliphatic diamines (at concentrations up to 0.1 M) and Ca2+ ions (10(-2) M) do not affect the functioning of the respiratory chain in isolated micrococcus membranes. Another derivative of the antibiotic with an increased distance of loaded amino groups from the cyclopeptide framework (diglycyl gramicidin S) affects the membrane in a way similar to that of natural gramicidin. Washing of gramicidin-treated membranes with NaCl enhances the inhibitory effect of the antibiotic on membrane enzymes. The data obtained suggest that in addition to ionic interactions some hydrophobic interactions also occur during gramicidin S binding to the bacterial membrane, probably at the expense of a hydrophobic peptide ring. It is assumed that gramicidin S, similar to Ca2+ and some other membranotropic agents provides for phase separation of negatively charged phospholipids from other groups of phospholipids, manifesting itself in an appearance of "frozen" sites on the membrane which destroys its barrier properties. This is due to the formation of ionic bonds of negatively charged phospholipids. Simultaneously, unlike Ca2+, gramicidin S, when interacting with membrane proteins, prevents their redistribution in more liquid parts of the membrane, which results in a situation when the respiratory enzymes become surrounded by alkyl chains with restricted motion.     

Cell wall components in Staphylococcus aureus with double resistance to gramicidin S and actinomycin D]

Cell walls of Staphylococcus aureus R9/80 resistant to gramicidin S and actinomycin D were investigated. The strain was isolated after passages of a previously isolated strain of S. aureus with resistance to gramicidin and definite changes in the cell walls, a medium with increasing concentrations of actinomycin being used for the passages. The data on the study of the cell walls of the strain with the double resistance were compared with the results of the investigation of the cell walls of the strain susceptible to gramicidin, the gramicidin resistant strain (initial for strain R9/80) and the actinomycin adapted strain that also showed changes in the cell walls. The cell walls of the resistant strains had no significant changes in the peptidoglycane and glucosamine levels, as well as in the peptidoglycane amino acid composition. Teichoic acids of all the strains had different levels of substitution of ribite by D-alanine (a factor influencing the negative charge of teichoic acids and the wall at large). It was noted that all the strains resistant to the tested antibiotics had lower levels of teichoic acids in the cell walls. The resistant cells showed some increase of the lipid component in the walls: from 1.6% in the susceptible strain to 2.1-2.9% in the resistant cells. The main trend of the changes in the resistance development was revealed to be the thickening of the cell wall and its consolidation. The development of resistance to gramicidin, actinomycin and to both the antibiotics provoked respectively a 2.4-, 4- and 5.4-fold increase of the content of the main cell component. i.e. peptidoglycane in the cell biomass. The barrier role of the cell walls in the resistant strains and their ability to bind the antibiotic is discussed.     

Acidity and solubility of gramicidin S in water

The acid-base transformations of the gramicidin S molecule in water were studied. The protonization constants of the antibiotic amino group were calculated by the data of the potentiometric titration and the antibiotic distribution in the system of chloroform-water: K1 1.55 X 10(10), K2 1.38 X 10(6), the logarithm of the distribution coefficient of gramicidin S in the system of chloroform-water (1:1) lg alpha G 4.10. By the same data the constants of water solubility of gramicidin S base (1.02 X 10(7) mol/l), gramicidin S monohydrate (1.06 X 10(-4) mol/l) and gramicidin S dihydrochloride (2.08 X 10(-4) mol/l) were calculated.     

Structuro-functional properties of the bacteria Bacillus brevis in relation to the accumulation of gramicidin S in cells

The culture of Bacillus brevis var. G-B R-form was grown in the presence of beta-phenyl-beta-alanine, the inhibitor of gramicidin S synthesis, is characterized by enhanced endogenous respiration and the DPI-reductase activity as compared to the culture synthezising antibiotic. The increased synthesis of the antibiotic in the region of the culture transition from the logarithmic growth phase to the linear one is associated with a decrease in the number of viable cells despite the fact that the culture on the whole does not die but continues to grow. The membranes prepared from young gramicidin S-free cells and from the cells enriched with the antibiotic possess identical electron micrograph images, IR spectra and protein sets as determined by polyacrylamide gel electrophoresis in a Na-DS system. However, in young cell membranes NADH and succinate dehydrogenase are insensitive to gramicidin S and only malate dehydrogenase is inhibited by this antibiotic. In aged cell membranes the activities of all mentioned dehydrogenases are suppressed. Malate dehydrogenase from young cells is weakly inhibited by thyrotrycin obtained from Bac. brevis ATCC 10068; succinate dehydrogenase is entirely insensitive to this antibiotic, while NADH-dehydrogenase is almost completely inhibited by it. The specificity of action on the respiratory chain of peptide antibiotics synthesized by the cells of one strain of Bac. brevis is suggestive of a possible regulatory role of these peptides in the metabolism of the producent. Hence the accumulation of gramicidin S which is adsorbed on the membrane and destroys the respiratory chain function to the cause of the low rate of oxygen uptake by the culture of Bac. brevis var. G-B R-form and of the low activities of DPI-reductases.     

Induction of sporulation in Bacillus brevis. 2. Dependence on the presence of the peptide antibiotics tyrocidine and linear gramicidin

This paper presents evidence that the two peptide antibiotics tyrocidine and linear gramicidin, produced by Bacillus brevis ATCC 8185, are required for the induction of sporulation in the producer organism. When tyrocidine synthesis was specifically blocked with 2-amino-3-hydroxy-3-phenylpropanoic acid [Mach, B., Reich, E., and Tatum, E. L. (1963) Proc. Natl Acad. Sci. USA, 50, 175-181], sporulation and gramicidin synthesis were inhibited, but both processes could be restored by the addition of tyrocidine. Certain other amino acids such as L-tyrosine inhibited both sporulation and peptide antibiotic synthesis in nitrogen-limited cultures. When either tyrocidine or linear gramicidin was added together with L-tyrosine, neither sporulation nor peptide antibiotic synthesis was restored. On the other hand, the addition of both tyrocidine and linear gramicidin effectively reversed the inhibition of sporulation by L-tyrosine. These experiments demonstrate that sporulation of B. brevis depends on either the endogenous synthesis or the addition of both tyrocidine and linear gramicidin. The fact that endogenous as well as exogenous peptides could effect sporulation argues against the involvement of artifacts, such as the depletion of intracellular nucleotide pools caused by the surfactant properties of added peptide antibiotics.     

Interaction of salts of transition metals with gramicidin S in chloroform

Extraction of CuCl2, NiCl2, CoCl2 and MnCl2 from the aqueous phase to the organic gramicidin S containing phase (the phase ratio of 1:1) was studied with the method of molar ratios at constant concentrations of the salts and changing concentrations of the antibiotic. The composition of the forming intracomplex compounds was determined with the equilibrium shift method. It was shown that 2 ions of chlorine and 2 molecules of gramicidin S bound with 1 ion of the metals. The extraction constants were measured. The complex compounds of gramicidin S with copper chloride were the most stable.     

Heavy metal cation-induced increase in the antimicrobial activity of gramicidin S. Increased sensitivity of metal-resistant mutants of Escherichia coli B to the antibiotic]

Gramicidin S response of metal resistant mutants of E. coli B and the effect of concentrations of Cu2+, Ag+, Co2+ and Cd2+ on the growth and sensitivity of E. coli B to cationic antibiotics, i.e. gramicidin S2+ and streptomycin2+, were studied. It was shown that the metal-cumulating mutants of E. coli B with two different mechanisms of cross resistance to Cu2+, Cd2+ and Ag+ had higher sensitivity to gramicidin S than the initial wild type strain of E. coli B. It was found that in the threshold or higher doses the salts of Cu, Ag, Co and Cd increased the gramicidin S antimicrobial action on actively metabolizing cells of E. coli B. Analysis of the experimental data as well as the literature ones suggested that the synergic action of gramicidin S and the heavy metals stemmed from an increase in the cationic conductivity of the cytoplasma membrane modified by the metals in the threshold doses which induced an increase in the transport and accumulation of the cations in the bacterial cells by the electric field gradient (with the negative sign inside). Withdrawal of Ca2+ and Mg2+ from the E. coli outer structures into the cytoplasm impaired the barrier properties of the outer membrane and promoted binding of the gramicidin S cations to the liberated anionic groups of the E. coli outer structures and potentiation of the gramicidin S antimicrobial activity as was shown in our experiments.     

Gramicidin S synthetase. Temperature dependence and thermodynamic parameters of substrate amino acid activation reactions

In the biosynthesis of the cyclic decapeptide antibiotic gramicidin S, the constituent amino acids are activated by a two-step mechanism involving aminoacyl adenylate and thio ester formation which are both reversible processes. The dissociation constants (KD) for the gramicidin S synthetase-substrate amino acid-thio ester complexes are 100-1000-fold lower compared to the KM data of the preceding aminoacyl adenylate reactions. The affinity for these substrates is appreciably higher at the thio template sites than at the aminoacyl adenylate reaction centers. Therefore, the activation equilibria are quantitatively shifted toward thio ester formation. A set of thermodynamic parameters for the activation processes was determined from the temperature dependence of the KM and KD data. Reaction enthalpies were obtained from a van't Hoff analysis of these constants. delta G degree for the substrate activation reactions of the heavy enzyme of gramicidin S synthetase (GS 2) is predominantly controlled by entropy contributions. In contrast, the overall activation and concomitant racemization of phenylalanine by phenylalanine racemase (GS 1) are exothermic processes which are distinguished by a small negative reaction entropy.     

Stability of Escherichia coli to the membranotropic antibiotic gramicidin S]

The work was aimed at studying the effect of gramicidin S on the intact cells, spheroplasts and membrane specimens of Escherichia coli K12S with the natural resistance to this antibiotic. The resistance was shown to be caused by the barrier properties of the cell wall: the spheroplasts were highly sensitive to the lytic action of gramicidin S. The differences in the sensitivity to gramicidin S of substrate oxidation carried by the membranes of E. coli and Micrococcus luteus, a sensitive organism, were not of crucial significance for the manifestation of the resistance. The resistance was not associated with the decrease of gramicidin S adsorption: the cells were capable of binding large quantities of the antibiotic and remaining viable. Gramicidin S appeared to be attached to the cell walls (most likely, the outer membranes) rather than the cytoplasmic membranes.     

Interaction of neomycin with other antibiotics on selected bacterial strains

Antimicrobial combinations are used most frequently to provide broad-spectrum empirical coverage in the treatment of bacterial infections. However, combination of two antibiotics may not influence their activity, may lead to synergy or antagonism in the activity. Neomycin may be combined with one of the following antibiotics: ampicillin, procaine penicillin, gramicidin, bacitracin, polymyxin B, lincomycin, oxytetracycline, and erythromycin in some human and veterinary multiantibiotic drugs distributed in Poland. The checkerboard method has been one of the traditional assays for the measurement of antibiotic interactions. The aim of this study was to analyse the activity interaction of neomycin with second antibiotic in multiantibiotic drugs distributed in Poland on standards and clinical bacterial strains. Checkerboard results for all strains demonstrated synergism for 2.5% of combinations, only for standards strains. In one case Salmonella Enteritidis, in combination of neomycin with bacitracin, inhibition effect was observed. Additive effects were predominant--49%. In 18% neutral effects were shown, but in 26% of combinations FIC indexes were not possible to calculate, because of the resistance of clinical strains to the highest concentration of at least one antibiotic. In combination of aminoglycoside (neomycin) with beta-lactams antibiotics (ampicillin, procaine penicillin) in vitro, no synergy was observed for all examined strains. The best results were achieved for combinations of neomycin with peptide antibiotics (polymyxin, gramicidin and bacitracin)--5 for all 6 synergy effect observed.     

Ferric iron reductase of Rhodopseudomonas sphaeroides.

Partially digested chromosomal DNA of Bacillus brevis ATCC 9999, a producer of the cyclic peptide antibiotic gramicidin S, was ligated into the BamHI site of the Escherichia coli expression vector pUR2-Bam. The ligated molecules were used to transfer E. coli to ampicillin resistance. Of 5 X 10(3) colonies tested by in situ immunoassay for a cross-reaction with antibodies against the gramicidin S synthetase 2, 6 colonies were found to be immunoreactive. A clone designated MK2, which had a 3.9-kilobase insert of B. brevis DNA, directed in E. coli under the lac promoter control the synthesis of polypeptides that were cross-reactive with the antibody to the gramicidin S synthetase 2. Partial purification of the gene products by gel filtration revealed a major fraction with an approximate molecular weight of 140,000 and with specific ornithine-dependent ATP-32PPi and 2'-dATP-32PPi exchange activities. These unique activities of the gramicidin S synthetase 2 were not detected in the E. coli strain harboring the vector.     

Susceptibility to selected chemotherapeutics of Staphylococcus aureus strains resistant to methycyline isolated from clinical materials in the years 1991-1992 and 1997

The susceptibility to selected chemotherapeutic agents was determined in 100 strains of Staphylococcus aureus methicillin-resistant (MRSA) isolated from clinical materials in 1991-1992 (50 strains) and in 1997 (50 strains). Two methods were used for the determination: disc method and antibiotic dilution in agar. The minimal inhibitory concentration (MIC) was determined for vancomycin, teicoplanin, furazolidone, nitrofurantoin, ofloxacin, gentamicin, netilmicin and trimethoprim. The concentrations of the chemotherapeutics in the substrate ranged from 0.125 to 512 mg/l. The obtained results served for drawing of the following conclusions: all studied MRSA strains isolated in 1991-1992 and in 1997 were sensitive to glycopeptide antibiotics: vancomycin and teicoplanin, to nitrofurans: nitrofurantoin and furazolidone, and to fusidic acid. MRSA strains isolated in 1991-1992 were sensitive to ofloxacin, but in 1997 about 80% of the strains were resistant to that antibiotic, and this resistance was noted in S. aureus strains with homogeneous resistance to methicillin. Increasing frequency of resistance to mupirocin was found, in 1991-1992 4% of the strains were resistant, and in 1997 the resistance of MRSA to that antibiotic was found in 12%. No changes occurred in the sensitivity of staphylococci to trimethoprim/sulfamethoxazole (cotrimoxazole). About 94% of strains in 1991-1992 and 1997 were sensitive to that drug. The sensitivity to cotrimoxazole is connected with one of its components (trimethoprim), with 94% of MRSA strains sensitive to it.     

Effects of antibiotics and other inhibitors on ATP-dependent protein translocation into membrane vesicles.

The effects of several membrane antibiotics and other agents on ATP-dependent protein translocation were examined in membrane vesicles under conditions where no significant proton motive force was present. The membrane perturbants ethanol and procaine abolished ATP-dependent protein translocation. Phenethyl alcohol at low concentrations abolished translocation, whereas at high concentrations it allowed precursors to be translocated but inhibited their processing. Translocation of precursors promoted by phenethyl alcohol was temperature dependent and occurred without an added energy source but was enhanced by ATP. However, such precursors could not be further processed to mature forms upon removal of the alcohol. The membrane-active antibiotics polymyxin B and gramicidin S were strong inhibitors of translocation, whereas gramicidin D, cerulenin, and mycobacillin had no effect even at higher concentrations, indicating some specificity in interference with protein translocation. Duramycin, an antibiotic previously shown to affect protein-lipid interaction, severely impaired protein translocation. These results showed that membrane structures play important roles, either directly or indirectly, in protein translocation. Chelating agents 1,10-phenanthroline and EDTA, but not EGTA [ethylene glycol-bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid], also abolished protein translocation.     

Proline residue-modified polycationic analogs of gramicidin S with high antibacterial activity against both Gram-positive and Gram-negative bacteria and low hemolytic activity.

Novel polycationic analogs of the cyclic decapeptide antibiotic, gramicidin S, possessing NH(2), D/L-Phe-NH or L-Lys-NH groups at the 4alpha- or 4beta-positions of the L-Pro residues, were synthesized. While L-Pro(4alpha/beta-NH(2))-containing analogs exhibited much weaker antibacterial activity, the D/L-Phe and L-Lys-substituted analogs exhibited higher antibacterial activity against Gram-negative bacteria than the parent gramicidin S. All of these additional amino group-containing analogs showed substantially reduced toxicity against human blood cells.