Role of the carbon source in regulating chloramphenicol production by Streptomyces venezuelae: studies in batch and continuous cultures

Both carbon- and nitrogen-limited media that supported a biphasic pattern of growth and chloramphenicol biosynthesis were devised for batch cultures of Streptomyces venezuelae. Where onset of the idiophase was associated with nitrogen depletion, a sharp peak of arylamine synthetase activity coincided with the onset of antibiotic production. The specific activity of the enzyme was highest when the carbon source in the medium was also near depletion at the trophophase-idiophase boundary. In media providing a substantial excess of carbon source through the idiophase, the peak specific activity was reduced by 75%, although the timing of enzyme synthesis was unaltered. Moreover, chemostat cultures in which the growth rate was limited by the glucose concentration in the input medium failed to show a decrease in specific production of chloramphenicol as the steady-state intracellular glucose concentration was increased. The results suggest that a form of "carbon catabolite repression" regulates synthesis of chloramphenicol biosynthetic enzymes during a trophophase-idiophase transition induced by nitrogen starvation. However, this regulatory mechanism does not establish the timing of antibiotic biosynthesis and does not function during nitrogen-sufficient growth in the presence of excess glucose.     

Growth and ultrastructure of Streptomyces venezuelae during chloramphenicol production.

Streptomyces venezuelae (3022a) was grown in flask cultures and fermentors, using three media having differential effects on chloramphenicol production. Micromorphology, ultrastructure and chloramphenicol concentrations were studied during the growth cycle in each medium. Chloramphenicol production was greatest in the glycerol-serine-lactate (GSL) medium, less in the glycerol-nutrient broth-yeast extract (GNY) medium and very low in glucose-mineral salts (GA) medium. In GSL and GA, much growth was in the form of microcolonies, especially in flask cultures, while short hyphal fragments predominated in GNY. The major ultrastructural features were the high frequency of mesosomes in fragmenting hyphae in GNY, and electron-transparent zones which appeared during chloramphenicol synthesis in GSL. None of the structural abnormalities induced by chloramphenicol in sensitive organisms were observed in S. venezuelae despite high levels of the antibiotic in GSL medium.     

Structural basis for chloramphenicol tolerance in Streptomyces venezuelae by chloramphenicol phosphotransferase activity

Streptomyces venezuelae synthesizes chloramphenicol (Cm), an inhibitor of ribosomal peptidyl transferase activity, thereby inhibiting bacterial growth. The producer escapes autoinhibition by its own secondary metabolite through phosphorylation of Cm by chloramphenicol phosphotransferase (CPT). In addition to active site binding, CPT binds its product 3-phosphoryl-Cm, in an alternate product binding site. To address the mechanisms of Cm tolerance of the producer, the crystal structures of CPT were determined in complex with either the nonchlorinated Cm (2-N-Ac-Cm) at 3.1 A resolution or the antibiotic's immediate precursor, the p-amino analog p-NH(2)-Cm, at 2.9 A resolution. Surprisingly, p-NH(2)-Cm binds CPT in a novel fashion. Additionally, neither 2-N-Ac-Cm nor p-NH(2)-Cm binds to the secondary product binding site.     

Plasmid and chloramphenicol production inStreptomyces venezuelae

A strain ofStreptomyces venezuelae described as having been cured of chloramphenicol production, was mutagenised with ultraviolet light and chloramphenicol-producing clones were obtained from the surviving population. Since this suggests that the supposed cured strain has not lost the genetic capacity of chloramphenicol synthesis, alternative explanations are offered.     

Sporulation of Streptomyces venezuelae in submerged cultures

Shaken cultures of Streptomyces venezuelae ISP5230 in minimal medium with galactose and ammonium sulphate as carbon and nitrogen sources, respectively, showed extensive sporulation after 72 h incubation at 37 degrees C. The spores formed in these cultures resembled aerial spores in their characteristics. The ability of the spores to withstand lysozyme treatment was used to monitor the progress of sporulation in cultures and to determine the physiological requirements for sporulation. In media containing ammonium sulphate as the nitrogen source, galactose was the best of six carbon sources tested. With galactose S. venezuelae ISP5230 sporulated when supplied with any of several nitrogen sources; however, an excess of nitrogen source was inhibitory. In cultures containing galactose and ammonium sulphate, sporulation was suppressed by a peptone supplement. The onset of sporulation was accompanied by a drop in intracellular GTP content. When decoyinine, an inhibitor of GMP synthase, was added to a medium containing starch and ammonium sulphate, a slight increase in sporulation was seen after 2 d. The suppression of sporulation by peptone in liquid or agar cultures was not reversed by addition of decoyinine. A hypersporulating mutant of S. venezuelae ISP5230 was altered in its ability to assimilate sugars. In cultures containing glucose the mutant sporulated more profusely than did the wild-type and did not acidify the medium to the same extent. However, the suppressive effect of glucose on sporulation was not merely a secondary result of acid accumulation.     

A plasmid involved in chloramphenicol production in Streptomyces venezuelae: evidence from genetic mapping.

To test the hypothesis that chloramphenicol production in Streptomyces venezuelae depends on the presence of a plasmid, mapping analysis was carried out by using eight markers in addition to chloramphenicol production and melanoid pigment formation. The sequence of the eight markers was determined on a circular linkage map as follows: -his-ade-str-leu-lys-met-ilv-pro-(his-). This sequence resulted in the frequency of quadruple crossover (q.c.o.) recombinants having the lowest value, 3-2 to 4-9%. However, the character of chloramphenicol non-production, which was obtained by incubating mycelia with acriflavin, was not required to explain the results. From these results and other tests, it is concluded that chloramphenicol production is controlled by a plasmid. This plasmid appeared to be non-transferable in conjugation.     

Transductional analysis of chloramphenicol biosynthesis genes in Streptomyces venezuelae.

Auxotrophs isolated from two chloramphenicol-nonproducing mutants of Streptomyces venezuelae included three requiring pyridoxal (Pxl-), VS248 (cml-11 pdx-2), VS253 (cml-11 pdx-3), and VS258 (cml-12 pdx-4), and one requiring thiosulfate, VS263 (cml-12 cys-28). Results of SV1-mediated transductions were consistent with the relative marker order cys-28-cml-12-cml-11-pdx-2,3,4,5, all of which were cotransducible and must therefore span less than 45 kilobases of DNA, the approximate length of DNA packaged by SV1. cys-28 was also cotransducible with arg-4 and arg-6, but arg and pdx were not cotransducible. Results of crosses with donors carrying any one of 11 cml mutations were consistent with the location of all cml mutations between cys-28 and pdx markers. Also, a new Pxl- auxotroph (pdx-6) and two new Cml- mutants were recovered after localized hydroxylamine mutagenesis of a cys-28 cml+ strain derived from VS263 by transduction.     

Isolation and characterization of Streptomyces venezuelae mutants blocked in chloramphenicol biosynthesis

Twelve Streptomyces venezuelae mutants blocked in chloramphenicol biosynthesis were isolated. Two of these (Cm1-1 and Cm1-12) were apparently blocked in the conversion of chorismic acid to p-aminophenylalanine and three (Cm1-4, Cm1-5 and Cm1-8) accumulated p-aminophenylalanine and may have been blocked in the hydroxylation reaction that converted this intermediate to p-aminophenylserine. One mutant (Cm1-2) accumulated D-threo-1-p-nitrophenyl-2-propionamido-1,3-propanediol and D-threo-1-p-nitrophenyl-2-isobutyramido-1,3-propanediol, indicating that chlorination of the alpha-N-acyl group of chloramphenicol was blocked. The remaining six strains did not excrete any detectable chloramphenicol pathway intermediates.     

Evidence for a chromosomal location of the genes coding for chloramphenicol production in Streptomyces venezuelae.

Of seven chloramphenicol-producing actinomycetes examined, only Streptomyces venezuelae strain 13s contained extrachromosomal DNA detectable by agarose gel electrophoresis and cesium chloride-ethidium bromide density gradient centrifugation. The single 17-megadalton plasmid present in this strain was indistinguishable from plasmid pUC3 previously isolated from mutagenized cultures. Strains selected for their inability to produce chloramphenicol after treatment with acriflavine or ethidium bromide still contained a plasmid that had the same electrophoretic mobility as plasmid pUC3 and yielded similar fragments when digested with restriction endonucleases. By regenerating protoplasts of strain 13s and screening for isolates lacking extrachromosomal DNA, strain PC51-5 was obtained. The absence of plasmid pUC3 sequences in this strain was confirmed by Southern hybridization using 32P-labeled plasmid as a probe. Since the plasmidless strain produced as much chloramphenicol as did the parent strain, pUC3 contains neither structural nor regulatory genes for antibiotic production. Evidence from electrophoretic analysis of BamHI digests of total cellular DNA from wild-type and dye-treated nonproducing progeny indicated that acriflavine caused structural changes in the chromosome.     

Effects of addition of chloramphenicol on the growth and ultrastructure of Streptomyces venezuelae

The effects of adding chloramphenicol before inoculation and during exponential growth of Streptomyces venezuelae (3022a) in fermentors were studied. The responses of the organism during synthesis of chloramphenicol (in a glycerol-serine-lactate medium) were compared with those in media supporting less (glycerol-nutrient broth-yeast extract) or no synthesis (glucosemineral salts). In systems where little or no synthesis of the chloramphenicol occurred, addition of the antibiotic induced micromorphological and ultrastructural abnormalities similar to those reported for sensitive bacteria. There was also an increase in the frequency of mesosomes and electron-light areas. It was suggested that the former may be associated with activity of chloramphenicol hydrolase and the latter with storage and/or excretion of the breakdown product; N-acetyl p-nitro-phenylserinol. When chloramphenicol synthesis occurred, addition of the antibiotic had less effect on the micromorphology or ultrastructure of S. venezuelae as permeability barriers to external chloramphenicol had been established. Electron-light areas were frequent, possibly being associated with storage and excretion of precursors of chloramphenicol.     

Enhancement of kasugamycin production by pH shock in batch cultures of Streptomyces kasugaensis

Biosynthesis of kasugamycin could be greatly enhanced by applying a nonnutritional stress of pH shock, that is, sequential pH changes from a neutral pH to an acidic condition and then back to the neutral condition. During the acidic period, cell growth decreased to nil. After recovery of the neutral condition, the cell growth resumed after a time lag concurrently with the biosynthesis of kasugamycin at a greatly enhanced rate compared with the control case without a pH shock. In a series of experiments performed to identify the optimal length of pH shock, four different lengths (6, 12, 24, and 48 h) of pH shock were applied. The best result was obtained when pH shock was applied for 24 h, with kasugamycin productivity approximately 7-fold higher than that of the control.     

Chloramphenicol resistance in Streptomyces: cloning and characterization of a chloramphenicol hydrolase gene from Streptomyces venezuelae

A 6.5 kb DNA fragment containing a chloramphenicol-resistance gene of Streptomyces venezuelae ISP5230 was cloned in Streptomyces lividans M252 using the high-copy-number plasmid vector pIJ702. The gene was located within a 2.4 kb KpnI-SstI fragment of the cloned DNA and encoded an enzyme (chloramphenicol hydrolase) that catalysed removal of the dichloroacetyl moiety from the antibiotic. The deacylated product, p-nitrophenylserinol, was metabolized to p-nitrobenzyl alcohol and other compounds by enzymes present in S. lividans M252. Examination of the genomic DNA from several sources using the cloned 6.5 kb SstI fragment from S. venezuelae ISP5230 as a probe showed a hybridizing region in the DNA from S. venezuelae 13s but none in the DNA from another chloramphenicol producer, Streptomyces phaeochromogenes NRRLB 3559. The resistance phenotype was not expressed when the 6.5 kb SstI fragment or a subfragment was subcloned behind the lac-promoter of plasmid pTZ18R in Escherichia coli.     

Heterologous production of epothilones B and D in Streptomyces venezuelae

Epothilones, produced from the myxobacterium Sorangium cellulosum, are potential anticancer agents that stabilize microtubules in a similar manner to paclitaxel. The entire epothilone biosynthetic gene cluster was heterologously expressed in an engineered strain of Streptomyces venezuelae bearing a deletion of pikromycin polyketide synthase gene cluster. The resulting strains produced approximately 0.1 μg/l of epothilone B as a sole product after 4 days cultivation. Deletion of an epoF encoding the cytochrome P450 epoxidase gave rise to a mutant that selectively produces 0.4 μg/l of epothilone D. To increase the production level of epothilones B and D, an additional copy of the positive regulatory gene pikD was introduced into the chromosome of both S. venezuleae mutant strains. The resulting strains showed enhanced production of corresponding compounds (approximately 2-fold). However, deletion of putative transport genes, orf3 and orf14 in the epothilone D producing S. venezuelae mutant strain, led to an approximately 3-fold reduction in epothilone D production. These results introduce S. venezuelae as an alternative heterologous host for the production of these valuable anticancer agents and demonstrate the possibility of engineering this strain as a generic heterologous host for the production of polyketides and hybrid polyketide-nonribosomal peptides.     

Enhanced flavonoid production in Streptomyces venezuelae via metabolic engineering

Metabolic engineering of plant-specific phenylpropanoid biosynthesis has attracted an increasing amount of attention recently, owing to the vast potential of flavonoids as nutraceuticals and pharmaceuticals. Recently, we have developed a recombinant Streptomyces venezuelae as a heterologous host for the production of flavonoids. In this study, we successfully improved flavonoid production by expressing two sets of genes predicted to be involved in malonate assimilation. The introduction of matB and matC encoding for malonyl-CoA synthetase and the putative dicarboxylate carrier protein, respectively, from Streptomyces coelicolor into the recombinant S. venezuelae strains expressing flavanone and flavone biosynthetic genes resulted in enhanced production of both flavonoids.     

Extracellular xylanase production by two thermophilic alkali-tolerant Bacillus strains in batch and continuous cultures

Xylanase production of newly isolated thermophilic alkali-tolerant Bacillus sp. strain SP and strain BC was investigated in batch and continuous cultures. Enzyme synthesis was inducible with both strains and was observed only in xylan-containing media. Xylan from oat spelt is a better inducer than xylan from birch for strain Bacillus sp. BC while such difference was not observed for strain SP. Compared with batch cultures xylanase production of both strains increased about two times and its rate became more than four times faster in continuous cultures at a dilution rate of 0.2 h(-1).     

Physiological factors affecting streptomycin production by Streptomyces griseus ATCC 12475 in batch and continuous culture

Abstract Conditions of growth are described for the production of streptomycin by Streptomyces griseus ATCC 12475 using chemically defined minimal medium and complex medium. It was found using batch cultures that early synthesis of the antibiotic occurred during growth in minimal medium but was delayed until the onset of stationary phase in complex medium. This effect was independent of whether spores or vegetative cells were used as inoculum. Stability of streptomycin biosynthesis in continuous culture was dependent on dilution rate and medium employed. Cultures were highly unstable when grown on complex medium but could be maintained in steady states in continuous culture using minimal medium when the dilution rate was increased in a stepwise manner, starting at a dilution rate of 0.02 h⁻¹ (15% of μ _max). The effect of changing dilution rate on growth, streptomycin production and the level of streptomycin phosphotransferase was examined using this technique.