Kinetic studies of streptomycin uptake implicated in self-resistance in a streptomycin producer

Summary Streptomycin (SM)-producingStreptomycesgriseus was permeable to extracellular SM during exponential growth, and less permeable during the stationary phase when antibiotic production was maximal. Uptake of [³H] dihydrostreptomycin ([³H]DSM) by the producer organism was abolished by inhibitors of electron transport, sulfhydryl reagents and an uncoupler of oxidative phosphorylation, and it was competitively inhibited by spermidine. These results indicate that SM was taken up by an active transport process via a polyamine transport system. A mutant with lower SM-resistance showed the same level of SM 6-phosphotransferase as the parent strain. It is suggested that selfresistance in the SM-producers is at least partly determined by transport and permeability mechanisms.     

Roles of streptomycin 6 -kinase and ribosomal affinity to streptomycin in self-protection of streptomycin producer

Summary In streptomycin (SM)-producing organisms, the lower affinity of ribosomes for SM gives rise to a lower susceptibility of protein synthesis to SM. But, even in a strain with considerably low affinity of ribosomes for SM, phosphorylation of SM in the cells by SM 6-kinase is necessary for the protein synthesis to be fully tolerant to SM.     

Resistance to oleandomycin in Streptomyces antibioticus, the producer organism

Resistance to oleandomycin in Streptomyces antibioticus, the producer organism, was studied. The organism was highly resistant in vivo to the antibiotic but sensitive to other macrolides and lincosamides. Protein synthesis in vivo by mycelium of S. antibioticus was more resistant to oleandomycin than that by mycelium of Streptomyces albus G, an oleandomycin-sensitive strain, and this resistance was dependent on the age of the culture, older mycelium of S. antibioticus being more resistant to oleandomycin than young mycelium. [3H]Oleandomycin was capable of binding to the same extent to the 50S subunits of the ribosomes of both organisms. Oleandomycin also inhibited in vitro protein synthesis by ribosomes obtained from an oleandomycin-production medium at the time when maximum levels of oleandomycin were being produced. A clear difference between the ability of the two organisms to incorporate exogenous oleandomycin was observed. Thus, while S. albus G took up oleandomycin, S. antibioticus showed a decreased permeability to the antibiotic, suggesting a role for cell permeability in self-resistance.     

The nucleotide sequence of a streptomycin streptomycin phosphotransferase (streptomycin kinase) [corrected] gene from a streptomycin producer

The nucleotide sequence of the DNA fragment containing the streptomycin phosphotransferase (streptomycin kinase) [corrected] gene from the streptomycin-producer Streptomyces griseus strain HUT 6037 was determined. Analysis of the sequence revealed an open reading frame which could encode 325 amino acid residues. A biased codon usage pattern, reflecting the high G + C composition (approximately 74%) of Streptomyces DNA, was observed in the gene.     

Characterization of versilin-sensitive sites in self-sensitive producer and sensitive non-producer or unrelated organism

Studies on self-sensitivity of producer mutant vs. sensitivity of non-producer parent and unrelated organism showed that versilin inhibited spore germination and sporulation in the self-sensitive producer mutant, non-producer parent Aspergillus versicolor N₅ and the unrelated sensitive Trichophyton rubrum . Sporulation appeared to be more sensitive than spore germination. The inhibition of in vivo synthesis of protein was very marked, but inhibition of RNA and DNA was slight and moderate, respectively. Thus versilin was not specific in its action, but the principal sensitive site was protein synthesis, as further suggested by inhibition of polyU-directed in vitro synthesis of polyphenylalanine. The activation of leucine was unaffected, but the formation of leucyl-tRNA was severely inhibited in all three strains. The differences in sensitivities between the strains were the same, whether as whole cells or as cell-free extracts. Thus the nature of the sensitive site appeared to be identical in the self-sensitive producer and sensitive non-producer or unrelated organism.     

Characterization of versilin-sensitive sites in self-sensitive producer and sensitive non-producer or unrelated organism

Studies on self-sensitivity of producer mutant vs. sensitivity of non-producer parent and unrelated organism showed that versilin inhibited spore germination and sporulation in the self-sensitive producer mutant, non-producer parent Aspergillus versicolor N5 and the unrelated sensitive Trichophyton rubrum. Sporulation appeared to be more sensitive than spore germination. The inhibition of in vivo synthesis of protein was very marked, but inhibition of RNA and DNA was slight and moderate, respectively. Thus versilin was not specific in its action, but the principal sensitive site was protein synthesis, as further suggested by inhibition of polyU-directed in vitro synthesis of polyphenylalanine. The activation of leucine was unaffected, but the formation of leucyl-tRNA was severely inhibited in all three strains. The differences in sensitivities between the strains were the same, whether as whole cells or as cell-free extracts. Thus the nature of the sensitive site appeared to be identical in the self-sensitive producer and sensitive non-producer or unrelated organism.     

The study of the growth of tylosin producer using differential centrifugation of mycelium in a sucrose density gradient

The mycelium of Streptomyces fradiae was fractionated by differential centrifugation in a sucrose density gradient (SDG) using various samples of the inoculation material and aliquots of the cultural broth taken in the course of tylosin production. The mode of mycelium distribution in SDG made it possible to select the most active inoculation material. The mycelium was redistributed from sucrose layers with a high density to those with a lower density in the course of fermentation. The fractions differed in the antibiotic activity but none of them had an activity higher than in the control centrifuged in 30% sucrose and washed off just like the fractions. Therefore, mycelium fractionation in SDG would not elevate its antibiotic activity. The paper presents the cytological characteristics of different fractions changing in the course of fermentation.     

Improving nisin production by increasing nisin immunity/resistance genes in the producer organism Lactococcus lactis

The effect on nisin production of increasing nisin immunity/resistance genes in Lactococcus lactis subsp. lactis MG1363 was investigated. The 60-kb nisin immunity/resistance plasmid pND300, which was isolated from a non-nisin-producing strain, encodes five genes involved in nisin immunity/resistance, which are very similar to those of the immunity/resistance system encoded by the nisin-production transposon. The introduction of pND300 into MG1363(TnNip) resulted in the construct being able to produce significantly more nisin than the parent MG1363(TnNip). The introduction of pND314, which contains the nisin immunity/resistance genes subcloned into pSA3, into MG1363(TnNip) allowed the strain to grow more rapidly than the parent MG1363(TnNip) with a concomitant increase in the rate of nisin production. This work illustrates that introduction of pND300 and a derivative containing the nisin immunity/resistance system of pND300 into MG1363 (TnNip) can result in significant alterations to the kinetics of nisin production. These observations indicate approaches that may be used successfully to improve the economics of nisin production. Received: 11 February 1998 / Received revision: 25 June 1998 / Accepted: 27 June 1998