Application of scale-down experiments in the study of kinetics of oxytetracycline biosynthesis

Scale-down experiments in antibiotic biosynthesis were performed by transferring the corresponding amounts of fermentation broth from industrial to laboratory and pilot-plant fermentors where the cultivation process was continued at different cultivation conditions. A previously proposed mathematical model was used to explain the experimental results. The effects of temperature, agitation-aeration intensity, and medium addition during the process were investigated. Computer simulation data were fitted to the experimental data, and good agreement was found. As a consequence of increasing temperature up to 37 degrees C, increases in the specific growth and autolysis rates as well as the specific rates of antibiotic synthesis and carbohydrate utilization were in evidence. Temperature increases of up to 40 degrees C caused a lower oxytetracycline yield. The effect of increased oxygen transfer rate on oxytetracycline biosynthesis was more pronounced at higher temperatures than at lower cultivation temperatures. Culture differentiation (strain segregation) was also studied; it was found that the increased cultivation temperature could be favorable for the growth of biomass active in oxytetracycline biosynthesis. Results of experiments at the pilot-plant scale showed that fed batch and repeated fed batch cultures could be successfully applied and the period of intensive antibiotic synthesis could be prolonged significantly.     

Polymyxin biosynthesis by Bacillus polymyxa during growth limitation by the nutritional sources

The synthesis of the antibiotic polymyxin M was studied under the conditions of batch and continuous cultivation of Bacillus polymyxa var. Ross whose growth was limited with glucose, phosphate and ammonium nitrogen. Polymyxin M was synthesized when the culture growth decelerated as a result of its limitation with the above compounds. Different amounts of the antibiotic were synthesized depending on the type of a limiting factor. The highest productiveness was found in the case of glucose limitation. The optimal conditions for polymyxin M synthesis were established under the conditions of one-step continuous cultivation.     

Kinetics of Streptomyces baarnensis growth and antibiotic synthesis in batch and dialysis cultures

The kinetics of biomass and antibiotic formation in batch and dialysis culture of Streptomyces baarnensis at various initial concentrations limiting the substrate growth (glucose) has been studied. The antibiotic substances were synthesized by actively growing culture, its concentration in the cultural media was maximum in the log-phase. In continuous dialysis culture on the background of biomass lianer growth in the course of time the constant antibiotic concentration in the media proportional to the glucose input concentration has been established. The inactivation (decomposition) of antibiotic was immediately initiated after discontinuation of substrate supply and followed first kinetics order. Observed features were used for construction of kinetical model of antibiotic biosynthesis. A conclusion has been made that the dialysis culture gives opportunity for more effective antibiotic synthesis as compared with the batch one.     

Effect of cerulenin on macromolecule synthesis in chemoheterotrophically and photoheterotrophically grown Rhodopseudomonas sphaeroides.

The antibiotic cerulenin causes the immediate cessation of phospholipid biosynthesis in both chemoheterotrophic and photoheterotrophic cultures of Rhodopseudomonas sphaeroides. Macromolecule biosynthesis in photoheterotrophic cells was unaffected by cerulenin for the first 2 h after antibiotic addition and then continued at a reduced rate for an additional 8 h. In contrast, macromolecule biosynthesis in chemoheterotrophic cells was severely affected by cerulenin within the first 2 h of treatment. Pulse-labeling of protein after cerulenin addition revealed that all subcellular fractions were equally affected by the action of cerulenin with chemoheterotrophic cell fractions more profoundly affected than those derived from photoheterotrophic cells. Protein insertion into the intracytoplasmic membrane of photoheterotrophic cells continued for up to 6 h after the onset of cerulenin treatment. Residual macromolecule synthesis was correlated with the presence of the photosynthetic membrane system under all conditions of growth.     

Effect of polymyxins on Bacillus polymyxa sporogenesis

Bacillus polymyxa var. Ross. producing polymyxin M and Bacillus polymyxa 153 producing polymyxin B form spores during submerged cultivation when the rate of biosynthesis of antibiotic peptides is low and when the production of antibiotics is over. However, sporogenesis is stimulated if polymyxins are added at the early stage of cultural growth. Inhibition of the synthesis of antibiotics suppresses the formation of spores. Substances other than polymyxins do not exhibit such a specific effect on sporogenesis. The fact that the culture requires endogenous polymyxins which are most effective in the period prior to the appearance of spores in the culture suggests the regulatory action of these peptides at the stage between vegetative growth and spore formation in Bacillus polymyxa.     

Cyclic adenosine-3',5-monophosphate in Streptomyces antibioticus and its possible role in regulating oleandomycin biosynthesis and the growth of the culture

When glucose is substituted for sucrose in the fermentation medium for Streptomyces antibioticus, the pH of the cultural broth becomes more acidic, the rate of protein synthesis in the mycelium rises, and the rate of oleandomycin synthesis decreases abruptly. The dynamics of cAMP (cyclic monophosphate) accumulation was studied in the process of biosynthesis by the culture in different media. Most of the synthesized cAMP (80-90%) was shown to be excreted into the medium. Glucose stimulates cAMP synthesis and excretion from the mycelium by a factor of 1.5-3. No distinct correlation was found between cAMP content in S. antibioticus cells and the level of oleandomycin biosynthesis. A correlation between changes in the concentration of exocellular cAMP and protein synthesis in the mycelium suggests that the excreted cAMP may be involved in regulating the growth of the culture producing the antibiotic.     

Effect of the culture medium composition on bacitracin synthesis and sporulation in Bacillus lichenformis 28 KA

The effect of the culture medium composition on the bacitracin synthesis and sporulation in Bacillus licheniformis 28 KA was being studied. During the producer's growth on a medium with tripton a biphasic pattern of the process was observed, i.e. a rapid growth of the bacterial biomass was accompanied by the production of insignificant amounts of the antibiotic. The maximum efficiency of the antibiotic synthesis coincides with the end of the exponential growth phase and the onset of sporification. The efficiency of sporification amounts up to 95% when the above mentioned medium is used. The substitution of glutamate for trypton results in a dramatic deceleration of the bacterial growth and biomass accumulation, and the process of the antibiotic biosynthesis ceases to be biphasic, i. e. the antibiotic is synthesized during the trophophase. Under the conditions when the antibiotic production drops to zero by the middle of the exponential growth phase, sporulation is virtually suppressed.     

Chemistry and biology of the ramoplanin family of peptide antibiotics

The peptide antibiotic ramoplanin factor A2 is a promising clinical candidate for treatment of Gram-positive bacterial infections that are resistant to antibiotics such as glycopeptides, macrolides, and penicillins. Since its discovery in 1984, no clinical or laboratory-generated resistance to this antibiotic has been reported. The mechanism of action of ramoplanin involves sequestration of peptidoglycan biosynthesis Lipid intermediates, thus physically occluding these substrates from proper utilization by the late-stage peptidoglycan biosynthesis enzymes MurG and the transglycosylases (TGases). Ramoplanin is structurally related to two cell wall active lipodepsipeptide antibiotics, janiemycin, and enduracidin, and is functionally related to members of the lantibiotic class of antimicrobial peptides (mersacidin, actagardine, nisin, and epidermin) and glycopeptide antibiotics (vancomycin and teicoplanin). Peptidomimetic chemotherapeutics derived from the ramoplanin sequence may find future use as antibiotics against vancomycin-resistant Enterococcus faecium (VRE), methicillin-resistant Staphylococcus aureus (MRSA), and related pathogens. Here we review the chemistry and biology of the ramoplanins including its discovery, structure elucidation, biosynthesis, antimicrobial activity, mechanism of action, and total synthesis.     

Phosphate inhibition of secondary metabolism in Streptomyces hygroscopicus and its reversal by cyclic AMP

Inorganic phosphate inhibited the biosynthesis of the macrolide antibiotic turimycin in different strains of Streptomyces hygroscopicus. In the wild type strain a depression was observed with increasing phosphate concentrations. A total inhibition was found at 0.1 M phosphate. In a high producing mutant a minimum of turimycin production occured when the phosphate concentration was between 5 mM and 10 mM. Above this concentration the antibiotic synthesis increased again but the production period shifted to a later period of cultivation. Addition of inorganic phosphate resulted in an initial increase of intracellular cyclic AMP content. But a second elevation characterizing the normal level of cyclic AMP throughout the growth phase was prevented by phosphate. Exogenous cyclic AMP as well as positive effectors of the adenylyl cyclase system were able to overcome the phosphate suppression. Cyclic AMP abolished the reduction of protein synthesis following phosphate addition and caused the reappearance of a protein band which may be responsible for the turimycin biosynthesis.     

Production of cell mass and pertussis toxin by Bordetella pertussis.

The cultivation of Bordetella pertussis affects production of pertussis toxin and biomass. Comparison of batch mode, chemostat operation and pHstat-turbidostatic control showed that productivities for the continuous process were greater than that for the batch operation. Continuous operation in balanced growth at the maximum specific growth rate, provided by the pHstat, resulted in the maximum specific production rate. Because of the strong association of pertussis toxin synthesis and cell growth, the concentration of toxin in the effluent of the continuous processes was greater than the maximum obtained in the batch bioprocess. An expanded Luedeking-Piret model of product formation kinetics fits the observed chemostat data and demonstrates that the production of pertussis toxin from the culture of B. pertussis is predominantly growth associated.     

Express-method of obtaining protease ECP32, a unique instrument in actin investigations

In studies of actin, the basic protein of muscles and cytoskeleton, protease ECP32 is of particular significance. This enzyme originates from the natural enterobacteria strain that accumulates minor amounts of the protease intracellularly at the post-exponential growth phase. The limiting factor for this biosynthesis is the amount of oxygen that enters the medium. The highly efficient method of the two-phase cultivation with vigorous aeration at the exponential growth phase was recommended. Due to the studied enzyme properties, the use of either the affinity or one-stage purification methods results in a rather decreased potential for success. To overcome the obstacles of the above methods, we developed a simple method for the ECP32 preparation and storage with purity and activity levels that satisfy the requirements of the actin structure and function investigations.     

Dynamics of the changes in microelement composition (cations of iron, copper and arsenic) during the biosynthesis of nystatin

The dynamics of changes in the microelemental composition during cultivation of the nystatin-producing organisms and synthesis of the antibiotic was studied. The microelemental composition of the raw materials and media used for the cultivation was also studied. Interrelation between the dynamics of the changes in the microelemental composition and the main parameters of the process of the antibiotic production were analyzed. It was revealed that during the first stage of the culture development characterized by the maximum rate of the biomass accumulation the ions of ferrum, cuprum and arsenic were consumed along with consumption of the main nutrients (carbohydrates, nitrogen and phosphorus). During the second stage of the culture development i.e. after 36 hours the ferrum ions were liberated into the fermentation broth while the content of cuprum and arsenic continued to decrease though at a lower rate. Marked shifts in the specific rates of the changes in the contents of ferrum and cuprum ions in the fermentation broth were also observed at the beginning of the second phase of the culture development. It was shown possible to control the process of nystatin biosynthesis by the microelemental composition of the media for cultivation of the antibiotic-producing organism.     

Phospholipid biosynthesis and poliovirus genome replication, two coupled phenomena.

Poliovirus infection leads to an increase of phospholipid synthesis and the proliferation of new membranes, giving rise to a great number of cytoplasmic vesicles in the infected cells. Viral RNA replication is physically associated with these newly-synthesized membranes. Cerulenin, an inhibitor of lipid biosynthesis, effectively blocks the growth of poliovirus in HeLa cells. The presence of cerulenin after virus entry prevents the synthesis of poliovirus proteins. However, if this antibiotic is added at later stages of the virus replication cycle, it has no effect on viral translation itself, nor on the proteolytic processing and myristoylation of poliovirus proteins. The synthesis of viral, but not cellular RNA is selectively inhibited by cerulenin. Analysis of the viral RNA made in poliovirus-infected cells by specific minus-or plus-stranded RNA probes suggests a selective blockade by cerulenin of plus-strand RNA synthesis. Finally, the synthesis of phospholipids and the proliferation of membranes does not take place if cerulenin is added to the culture medium. These findings indicate that continuous phospholipid synthesis is required for efficient poliovirus genome replication and provide new insights towards the understanding of the molecular events that occur during poliovirus growth.     

Dependence of betaine stimulation of vitamin b(12) overproduction on protein synthesis

The betaine-stimulated differential synthesis of vitamin B(12), i.e., the increase in B(12) per increase in dry cell weight, by Pseudomonas denitrificans was inhibited by rifampin and chloramphenicol but not by benzylpenicillin and carbenicillin at concentrations of antibiotic that inhibit growth. The level of the first enzyme of corrin (and porphyrin) biosynthesis, delta-aminolevulinic acid synthetase, was decreased to a much greater degree by rifampin and chloramphenicol than by the penicillins. These data support the concept that betaine stimulation of B(12) synthesis is a result of its stimulation of synthesis of delta-aminolevulinic acid synthetase, a labile and presumably rate-limiting enzyme of corrin formation requiring continuous induction. In further support of this hypothesis, it was found that chloramphenicol immediately interfered with both vitamin B(12) and delta-aminolevulinic acid synthetase formation, no matter when it was added to the system.     

Conditions of the biosynthesis of an extracellular subtilisin-like proteinase by Bacillus pumilus KMM 62

The influence of the cultivation conditions on Bacillus pumilus KMM 62 growth and effectiveness of the production of a subtilisin-like serine proteinase were investigated. Enzyme accumulation in the culture fluid reached the maximum value after 32 and 46-48 h of growth; it depends on the composition of the nutrient medium. The ratio of the concentrations of two main components of the medium, peptone and inorganic phosphate, which was optimal for enzyme biosynthesis was determined by multifactor experiments. Ammonium salts, when introduced as an additional nitrogen source, had different effects on the proteinase biosynthesis at different growth stages: they suppress enzyme production at the early stationary growth phase and stimulate the biosynthesis of the enzyme after 46-48 h of growth. Complex organic substrates (albumin, casein, hemoglobin, and gelatin) have a repressive effect on the biosynthesis of the enzyme. The effect of amino acids on culture growth and enzyme biosynthesis during the early and late stationary growth phase is different. Hydrophilic amino acids, glutamine, and glutamic acid exhibit the most pronounced repressive action on biosynthesis. The activity of different regulatory mechanisms for the synthesis of this proteinase is assumed at the early and late stationary stages of growth.     

Processes of spore formation and gramicidin C formation by Bacillus brevis var. G.B.]

Correlation between gramidicin C biosynthesis and sporulation in the process of Bac. brevis var. G.B. cultivation under various aeration conditions was studied. It was shown that biosynthesis of gramicidin C was characteristic of the young cells and its level was the highest during the culture active growth. The time of the sporulating forms appearance depended on the aeration rate which defined the quantitative composition of the population during the phase of the culture active growth and the stationary phase. Under the optimal aeration conditions the spore formation started during the phase of the culture active growth after some decrease in the maximum level of the cell productivity with respect to the antibiotic. When the aeration rate was increased the spore formation was shifted to later periods of the culture development, i.e. the stationary phase and the phase of the cell autolysis, the gap between the highest levels of gramicidin C buosynthesis and the beginning of sporulation being increased. Under certain aeration conditions the spore formation was not observed, while gramicidin C was synthesized. A conclusion has been made that there is no correlation between gramacidine C biosynthesis and sporualtion in Bacillus brevis var. G.B.     

Cell proliferation-cephamycin biosynthesis relationship in the culture of Streptomyces lactamdurans L 2/6: phosphate regulation

During batch cultivation of Streptomyces lactamdurans a diauxic growth has been shown taking into consideration dry cell mass, protein, and DNA determination. This phenomenon was connected with substantial changes in environmental conditions such as concentrations of ammonia and amino nitrogen, soluble inorganic phosphate and pH. The antibiotic production was preceded by the preparatory phase occurring at the beginning of the second growth phase. A hypothetical pattern of cell physiology in the curse of cephamycin fermentation is discussed. An essential part in the biphasic cell growth and the induction of antibiotic synthesis in this model is played by phosphate depletion in the medium.     

Conditions of the biosynthesis of an extracellular subtilisin-like proteinase by <Emphasis Type="Italic">Bacillus pumilus</Emphasis> KMM 62

The influence of the cultivation conditions on Bacillus pumilus KMM 62 growth and effectiveness of the production of a subtilisin-like serine proteinase were investigated. Enzyme accumulation in the culture fluid reached the maximum value after 32 and 46–48 h of growth; it depends on the composition of the nutrient medium. The ratio of the concentrations of two main components of the medium, peptone and inorganic phosphate, which was optimal for enzyme biosynthesis was determined by multifactor experiments. Ammonium salts, when introduced as an additional nitrogen source, had different effects on the proteinase biosynthesis at different growth stages: they suppress enzyme production at the early stationary growth phase and stimulate the biosynthesis of the enzyme after 46–48 h of growth. Complex organic substrates (albumin, casein, hemoglobin, and gelatin) have a repressive effect on the biosynthesis of the enzyme. The effect of amino acids on culture growth and enzyme biosynthesis during the early and late stationary growth phase is different. Hydrophilic amino acids, glutamine, and glutamic acid exhibit the most pronounced repressive action on biosynthesis. The involvement of different regulatory mechanisms of the synthesis of this proteinase is assumed in the early and late stationary phases of growth.     

Mucidin-nonproducing mutants ofOudemansiella mucida

Mutants ofOudemansiella mucida, blocked in the biosynthesis of the antibiotic mucidin, were obtained at a 0.28 % frequency after the application of N-methyl-N’-nitro-N-nitrosoguanidine (MNG) to basidiospores under conditions leading to 0.5–5.0 % survival rates. Loss of antibiotic activity was in most isolates accompanied by a decrease in mycelium growth rate and a suppression of dikaryotizing and fructification ability. Recombination analysis of two stable mutants revealed that the block in mucidin synthesis is the result of mutation in the same chromosomal gene(muc). In contrast to the action of MNG, UV-irradiation leads neither to the loss of biosynthetic activity nor to any morphological change.     

Catabolite repression in Streptomyces venezuelae. Induction of beta-galactosidase, chloramphenicol production, and intracellular cyclic adenosine 3',5'-monophosphate concentrations

Chloramphenicol production was studied in cultures of Streptomyces venezuelae growing in a simple buffered medium with ammonia as the nitrogen source and glucose, lactose, or a glucose-lactose mixture as the sole source of carbon. With each carbon source the antibiotic was formed during growth. In the glucose-lactose medium, the production pattern was biphasic; a marked decrease in the rate of synthesis was associated with depletion of glucose from the medium and a corresponding diauxie pause in growth. Cells of S. venezuelae contained an inducible beta-galactosidase. Induction by lactose was suppressed by glucose. Measurement of the concentration of intracellular adenosine 3',5'-cyclic monophosphate during growth of cultures with glucose or a glucose-lactose mixture as the source of carbon showed no appreciable changes coinciding with depletion of glucose or the onset of chloramphenicol biosynthesis. It is concluded that the cyclic nucleotide does not mediate selective nutrient utilization or control antibiotic biosynthesis in this organism.