HP17, a new pigment-like antibiotic produced by a new strain of Spirillospora

Spirillospora strain 719 produces several antibiotics. On solid and liquid media, a deep red pigment is formed and diffuses throughout the culture. It was extracted with methanol from the mycelium cake and from the fermentation broth after precipitation at pH 2 and purified using TLC and HPLC. Its u.v. absorption spectrum and its physicochemical characteristics place this antibiotic in the 3.3.2.2.8 of the Berdy et al. classification. In most respects, it resembles proteinaceous pigment from Spirillospora 1655 and 1309-b that was studied and named spirillomycin. However, HP17 differs from spirillomycin principally in molecular weight and chemical nature.     

H107, a new aminoglycoside anti-Pseudomonas antibiotic produced by a new strain of Spirillospora

Spirillospora spp. (strain 719) has been the source of several antibiotics. One of these designated H107 is produced as a trace. Compared with other antibiotics produced by the same strain, it was obtained only from the broth filtrate after precipitation with acetic acid followed by extraction with n-butanol. It was a water soluble metabolite active against Gram-negative bacteria and especially Pseudomonas spp., and was identified as an aminoglycoside compound. This is the first report of aminoglycoside anti-Pseudomonas production by Spirillospora.     

A new streptomycete and a new polyene antibiotic,acmycin

A new antifungal antibiotic named acmycin was isolated from a soil streptomycete. Detailed comparative taxonomic studies showed that the organism differed from three related species of streptomycetes. The organism was referred to asStreptomyces sp. AC₂. The isolated antibiotic appears to be of polyene nature.     

Effect of a polyene antibiotic on growth and phosphate uptake by Candida albicans.

The polyene antibiotic, amphotericin, inhibited phosphate uptake in Candida albicans more strongly than it inhibited growth. Cultures grown from an inoculum of young (2 h) cells were more affected than those inoculated with old (24 h) cells. Thus, the polyene displays a double effect on C. albicans (and presumably on other eukaryotic cells): it interferes with membrane sterols and also inhibits synthesis of a factor (or factors) during growth. Whether this factor(s) interferes with the uptake of the polyene antibiotic or neutralizes its effect by reacting with it remains unsolved.     

Roflamycoin--a new channel-forming antibiotic

Ion permeability of lipid bilayers was studied in the presence of a new antifungal pentaene antibiotic, roflamycoin, the structure of which differs considerably from that of the well-known polyene channel-former amphotericin B. Both of them, however, show the property of increasing the membrane permeability only in the case of sterol-containing membrane when added on both its sides. The conductance is strongly dependent on the concentration of the antibiotic in the solutions and of sterol in the membrane. Unlike the amphotericin B channels, roflamycoin channels are potential-dependent and have short lifetime (approx. 1 s) and high conductance (approx. 100 ps in 1 M KCl), which increases linearly with the salt concentration and is not blocked by the familiar blockers of amphotericin B channels. The two antibiotics seem to have a common mechanism of channel formation, viz. the formation starts from two semi-pores assembled in the opposite monolayers from several molecules of the antibiotic and sterol. However, the inner diameter of the roflamycoin channel is larger because of the different antibiotic-to-sterol ratio in the channel aggregate. It is believed that the difference in the ratio is due to the presence of the methyl group in the polyene chain of roflamycoin, and the considerable difference in lifetimes of the two types of channels depends on the terminal groups of the antibiotics.     

Biological properties of acmycin,a new polyene antibiotic

Acmycin, a new polyene antibiotic, was fungistatic at low and fungicidal at high concentrations. It produced malformations in conidia of Helminthosporium oryzae and Curvularia lunata and caused leakage of yeast cells. Acmycin was fairly nontoxic to germinating seeds. The intravenous LD50 was 300-400 and intraperitoneal maximum tolerated dose 100-500 mg/kg body mass of mice.     

Isolation,taxonomic and fermentation studies on a new strain of Streptomyces arenae var ukrainiana producing a tetraene antibiotic

A Streptomyces strain UK10 was isolated from Ukrainian soil and identified by taxonomical studies as Streptomyces arenae var ukrainiana. HA-2-91 was isolated from the biomass of S. arenae var ukrainiana and is supposedly a polyene macrolide antibiotic belonging to the tetraene group. HA-2-91 showed promising antifungal activity (in vitro) against yeasts and filamentous fungi, including plant pathogens and dermatophytes and was found to be less toxic in mice than nystatin and rimocidin.     

Phospholipid enrichment of Saccharomyces cerevisiae and its effect on polyene sensitivity

Sensitivity to polyene antibiotics, e.g., nystatin, amphotericin B, and filipin, was determined in phosphatidylcholine (PC) or phosphatidylethanolamine (PE) or phosphatidylserine (PS) enriched Saccharomyces cerevisiae cells, using glutamic acid, phenylalanine, glycine, and lysine transport as an index of polyene antibiotic action. As compared with normal cells, phospholipid-enriched cells acquired resistance towards different polyenes. However, the sensitivity of glutamic acid transport towards nystatin remained unaffected in PC-, PE-, or PS-enriched cells. In contrast to nystatin, the other two polyenes were more effective in checking the influx of amino acids. Results demonstrated that the specific enrichment of PC, PE, or PS could selectively protect S. cerevisiae cells from polyene antibiotic action.     

Conformation and self-assembly of a nystatin nitrobenzoxadiazole derivative in lipid membranes

Nystatin is a polyene (tetraene) macrolide antibiotic presenting antifungal activity that acts at the cellular membrane level. In the present study, we report the interaction of this antibiotic labelled at its amine group with 7-nitrobenz-2-oxa-1,3-diazole (NBD-Nys) with sterol-free and ergosterol- and cholesterol-containing 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC) large unilamellar vesicles (LUV). The mean tetraene to NBD separating distance determined from fluorescence energy transfer measurements increased from 18 to 25.6 A upon antibiotic binding to the lipid vesicles, indicating that the monomeric labelled antibiotic adopts a more extended conformation in its lipid-bound state than in aqueous solution. The oligomeric state of membrane-bound NBD-Nys was also studied by resonance energy homotransfer between the NBD fluorophores. The decrease measured in its steady state fluorescence anisotropy upon increasing the surface concentration of the NBD-Nys is shown to be consistent with a random distribution of molecules on the surface of the liposomes. This data contradicts the sharp increase measured for nystatin mean fluorescence lifetime in the presence of 10 mol% ergosterol-containing POPC LUV within the same antibiotic concentration range and which is known to report nystatin oligomerization in the lipid vesicles. Therefore, we conclude that the amine group of nystatin is an essential requisite for the supramolecular organization/pore formation of this antibiotic.     

多烯类抗生素合成基因簇中ABC转运蛋白研究进展

ABC转运蛋白家族是一个广泛存在于不同生物细胞中且功能保守的膜蛋白亚家族;它们是一类单向底物转运泵,通常以主动转运方式完成多种分子的跨膜转运。随着抗生素合成基因簇相关研究的开展,越来越多的簇内ABC转运蛋白被鉴定出来,对其生物学功能的研究正逐渐成为热点。多烯类抗生素作为一类重要的抗真菌药物,能够有效避免真菌产生耐药性,具有非常重要的临床价值。本文以多烯类抗生素合成基因簇为对象,综述了在其中所发现的ABC转运蛋白的研究进展,综合分析了其结构特性与功能间的关系,并对研究应用进行了展望。     

Mutations in a new Streptomyces coelicolor locus which globally block antibiotic biosynthesis but not sporulation

Streptomyces coelicolor produces four known antibiotics. To define genetic elements that regulate antibiotic synthesis, we screened for mutations that visibly blocked synthesis of the two pigmented antibiotics and found that the mutant strains which we recovered were of two classes--double mutants and mutants in which all four antibiotics were blocked. The mutations in these multiply blocked strains define a new locus of S. coelicolor which we have named absA. The genetic location of absA, at 10 o'clock, is distinct from the locations of the antibiotic gene clusters and from other known mutations that affect antibiotic synthesis. The phenotype of the absA mutants suggests that all S. coelicolor antibiotic synthesis genes are subject to a common global regulation that is at least in part distinct from sporulation and that absA is a genetic component of the regulatory mechanism.     

AH7, a non-polyenic antifungal antibiotic produced by a new strain of Streptosporangium roseum

An antibiotic (AH7) produced by Streptosporangium roseum strain 214 was investigated. This compound was extracted with chloroform from the filtrate culture and purified using thin-layer chromatography and high pressure liquid chromatography procedures. The antibiotic strongly inhibited the growth of several strains of fungi and bacteria known to be plant and human pathogens. This compound differed from all other antibiotics known to be synthesized by Streptosporangium spp. Some of its chemical and physical properties resembled those of maytansines produced by Nocardia but the antibiotic AH7 has only antibacterial and antitumoral activities.     

Biological abilities and identification of the polyene antifungal antibiotic,perspective for protection from fungi biodeterioration

The producer of the antifungal polyene antibiotic, aimed to protect against fungial biodeterioration, has been isolated from the soil due to a target search. Based on the morphological, cultural, and biochemical abilities, the producer is related to the Streptomyces genus. It has been shown by chromatographic, spectral, physical, and chemical methods that the antibiotic synthesized by the isolated culture consists of two main components—the polyene hexaene antibiotic with a high antifungal activity and a non-polyene antibiotic with antibacterial activity. The antifungal activity of the low purified hexaene antibiotic is comparable with the antifungal activity of the well-known highly purified antibiotics—amphotericin B, clotrimazole, and itrakonazol. This antibiotic inhibits the synthesis of the biodeterioration factors in fungi, i.e., pigments and organic acids.     

How do the polyene macrolide antibiotics affect the cellular membrane properties?

In the 1970's great strides were made in understanding the mechanism of action of amphotericin B and nystatin: the formation of transmembrane pores was clearly demonstrated in planar lipid monolayers, in multilamellar phospholipid vesicles and in Acholeplasma laidlawii cells and the importance of the presence and of the nature of the membrane sterol was analyzed. For polyene antibiotics with shorter chains, a mechanism of membrane disruption was proposed. However, recently obtained data on unilamellar vesicles have complicated the situation. It has been shown that: membranes in the gel state (which is not common in cells), even if they do not contain sterols may be made permeable by polyene antibiotics, several mechanisms may operate, simultaneously or sequentially, depending on the antibiotic/lipid ratio, the time elapsed after mixing and the mode of addition of the antibiotic, there is a rapid exchange of the antibiotic molecules between the vesicles. Although pore formation is apparently involved in the toxicity of amphotericin B and nystatin, it is not the sole factor which contributes to cell death, since K+ leakage induced by these antibiotics is separate from their lethal action. The peroxidation of membrane lipids, which has been demonstrated for erythrocytes and Candida albicans cells in the presence of amphotericin B, may play a determining role in toxicity concurrently with colloid osmotic effect. On the other hand, it has been shown that the action of polyene antibiotics on cells is not always detrimental: at sub-lethal concentrations these drugs stimulate either the activity of some membrane enzymes or cellular metabolism. In particular, some cells of the immune system are stimulated. Furthermore, polyene antibiotics may act synergistically with other drugs, such as antitumor or antifungal compounds. This may occur either by an increased incorporation of the drug, under the influence of a polyene antibiotic-induced change of membrane potential, for example, or by a direct interaction of both drugs. That fungal membranes contain ergosterol while mammalian cell membranes contain cholesterol, has generally been considered the basis for the selective toxicity of amphotericin B and nystatin for fungi. Actually, in vitro studies have not always borne out this assumption, thereby casting doubt on the use of polyene antibiotics as antifungal agents in mammalian cell culture media.(ABSTRACT TRUNCATED AT 400 WORDS)     

Characterization and regulation of p-aminobenzoic acid synthase from Streptomyces griseus

p-Aminobenzoic acid synthase (PABA synthase) of Streptomyces griseus catalyses the conversion of chorismic acid to p-aminobenzoic acid (PABA), a precursor of the aromatic p-aminoacetophenone moiety of candicidin, a polyene macrolide antibiotic. This enzyme uses glutamine or ammonia as amino donors for PABA formation. Enzyme extracts converted [14C]chorismic acid to labelled PABA. PABA synthase was present in S. griseus IMRU 3570 only during the antibiotic producing phase. No detectable levels of the enzyme were found in cell-free extracts of nonproducing mutants of S. griseus obtained after UV mutagenesis. PABA synthase activity was found also in Streptomyces coelicolor var. aminophilus, producer of the polyene macrolide antibiotic fungimycin, but it was not present in extracts of several other streptomycetes that do not produce aromatic polyene macrolide antibiotics. PABA synthase (amidotransferase) activity was partially purified by DEAE-Bio-gel and Sephacryl S-200 filtrations. The estimated molecular weight was 50000. PABA synthase was repressed by aromatic amino acids and PABA but not by anthranilic acid. Inorganic phosphate strongly repressed but did not inhibit PABA synthase activity.     

Pre-resonance Raman spectra and conformations of nystatin in powder,solution and phospholipid-cholesterol multilayers

A Raman scattering study of the channel-forming polyene antibiotic nystatin, is reported in the solid state, in organic and aqueous solutions as well as in phospholipid and phospholipid-cholesterol multilayers. Measurements of the solid and solution spectra as a function of excitation wavelengths in the 459.7–514.5 nm range, and the phospholipid spectra as a function of temperature in the 10–60°C range, have also been made. The spectral features indicate a pre-resonance-enhanced Raman spectrum in which the CC and CC stretching modes of the polyene segment of nystatin are dominant. However, in contrast to previously published results on the nearly isostructural polyene antibiotic amphotericin B, a line at 1610 cm^?1 assignable to the CO stretching mode is also observed to be strongly resonance enhanced. This is explained by a postulated ground-state conformation model in which a twisting of the molecule is facilitated by the break in the polyene chain. This allows the CO group at one end of the molecule to be aligned along the polyene unit at the other end, and the CC stretching vibration, which is strongly modulated by the polyene π → π1 excited state, to mix with the CO stretching vibration. The peak frequencies and intensities of the CC and CC stretching modes in nystatin, however, remain essentially unchanged compared with amphotericin B, indicating that the polyene units in nystatin remain planar and trans both in the ground and excited states.The intensity of the CO mode with respect to the CC stretching mode was observed to vary appreciably with nystatin environment, indicating a     

Biosynthesis of 2'-O-methylmyxalamide D in the myxobacterium Cystobacter fuscus: a polyketide synthase-nonribosomal peptide synthetase system for the myxalamide D skeleton and a methyltransferase for the final O-methylation

The biosynthetic gene cluster for the polyene antifungal antibiotic, 2'-O-methylmyxalamide D, was cloned from myxobacterium Cystobacter fuscus AJ-13278. A sequence analysis of the 12.8-kb region in the gene cluster revealed the presence of two type I polyketide synthase genes, mmxB and mmxC. The involvement of these two genes in the biosynthesis of 2'-O-methylmyxalamide D was confirmed by a gene disruption experiments. In addition, an S-adenosylmethionine-dependent methyltransferase gene (mmxM) was found downstream of the gene cluster and demonstrated, by a gene disruption analysis, to be responsible for converting the known unmethylated precursor, myxalamide D, into 2'-O-methylmyxalamide D.     

Spectrophotometric assay of yeast sterols using a polyene antibiotic

Spectral changes resulting from specific interaction between sterols and the polyene antibiotic filipin have been exploited in a simple sterol assay that is not subject to interference. This can be employed to measure the sterol content of brewing yeast prior to use thus permitting improved control of the fermentation process. It may also be applicable to quantification of fungal biomass.     

The polyene antibiotic amphotericin B inhibits the Na+/K+ pump of human erythrocytes

The polyene antibiotic Amphotericin B is known to induce K+ loss from human erythrocytes. In the present study it is shown that this efflux is not solely due to the formation of pores through the membrane but also to the inhibition of the Na+/K+ pump. At 5 microM this inhibition is total. The interaction of Amphotericin B with membrane enzymes is therefore to be taken into consideration when trying to explain its mechanism of action.     

Alteration of sea urchin embryo cell surface properties by mycostatin, a sterol binding antibiotic

Sea urchin embryos incubated in sea water containing mycostatin (MST), a polyene antibiotic, dissociate into single cells. Reaggregation of dissociated sea urchin embryo cells, and uptake of labeled precursors by these cells are also greatly inhibited although O₂ consumption is only slightly affected by this compound. It is known that mycostatin binds primarily to membrane sterols and affects only cells containing membrane sterols. Sea urchin cell membranes contain sterols. The effects of mycostatin on cell adhesion, reaggregation, and permeability seen in this study may be a result of an interaction with cell membrane sterols or sterol-associated molecules.