工程改造龟裂链霉菌提高土霉素产量

土霉素是由龟裂链霉菌合成的一类广谱性抗生素,前期研究工作证明其生物合成受其自身途径特异性调控蛋白OtcR的直接调节,OtcR能够激活和促进土霉素合成基因簇的转录表达。在龟裂链霉菌M4018宿主内利用强启动子单独过表达OtcR蛋白,使土霉素的产量提高到原来产量的4倍;为了进一步提高土霉素产量,在M4108宿主内表达乙酰辅酶A羧化酶基因,提高其胞内土霉素合成的前体物丙二酸单酰辅酶A的含量。对出发菌株M4018进行工程改造,同时过表达途径特异性调控蛋白OtcR和乙酰辅酶A羧化酶,发酵检测改造后的重组工程菌株土霉素的产量由1.37g/L提高到9.09g/L,该研究策略对工程改造龟裂链霉菌提高土霉素的产量具有重要的指导意义。     

Ablation of the otcC gene encoding a post-polyketide hydroxylase from the oxytetracyline biosynthetic pathway in Streptomyces rimosus results in novel polyketides with altered chain length

Oxytetracycline (OTC) is a 19-carbon polyketide antibiotic made by Streptomyces rimosus. The otcC gene encodes an anhydrotetracycline oxygenase that catalyzes a hydroxylation of the anthracycline structure at position C-6 after biosynthesis of the polyketide backbone is completed. A recombinant strain of S. rimosus that was disrupted in the genomic copy of otcC synthesized a novel C-17 polyketide. This result indicates that the absence of the otcC gene product significantly influences the ability of the OTC "minimal" polyketide synthase to make a polyketide product of the correct chain length. A mutant copy of otcC was made by site-directed mutagenesis of three essential glycine codons located within the putative NADPH-binding domain. The mutant gene was expressed in Escherichia coli, and biochemical analysis confirmed that the gene product was catalytically inactive. When the mutant gene replaced the ablated gene in the chromosome of S. rimosus, the ability to make a 19-carbon backbone was restored, indicating that OtcC is an essential partner in the quaternary structure of the synthase complex.     

Improvement of oxytetracycline production mediated via cooperation of resistance genes in Streptomyces rimosus

Increasing the self-resistance levels of Streptomyces is an effective strategy to improve the production of antibiotics.To increase the oxytetracycline(OTC) production in Streptomyces rimosus,we investigated the cooperative effect of three co-overexpressing OTC resistance genes:one gene encodes a ribosomal protection protein(otrA) and the other two express efflux proteins(otrB and otrC).Results indicated that combinational overexpression of otrA,otrB,and otrC(MKABC) exerted a synergetic effect.OTC production increased by 179%in the recombinant strain compared with that of the wild-type strain M4018.The resistance level to OTC was increased by approximately two-fold relative to the parental strain,thereby indicating that applying the cooperative effect of self-resistance genes is useful to improve OTC production.Furthermore,the previously identified cluster-situated activator OtcR was overexpressed in MKABC in constructing the recombinant strain MKRABC;such strain can produce OTC of approximately7.49 g L~((-1)),which represents an increase of 19%in comparison with that of the OtcR-overexpressing strain alone.Our work showed that the cooperative overexpression of self-resistance genes is a promising strategy to enhance the antibiotics production in Streptomyces.     

Molecular cloning and functional characterization of an ATP-binding cassette transporter OtrC from Streptomyces rimosus

ABSTRACT: BACKGROUND: The otrC gene of Streptomyces rimosus was previously annotated as an oxytetracycline (OTC) resistance protein. However, the amino acid sequence analysis of OtrC shows that it is a putative ATP-binding cassette (ABC) transporter with multidrug resistance function. To our knowledge, none of the ABC transporters in S. rimosus have yet been characterized. In this study, we aimed to characterize the multidrug exporter function of OtrC and evaluate its relevancy to OTC production. RESULTS: In order to investigate OtrC's function, otrC is cloned and expressed in E. coli The exporter function of OtrC was identified by ATPase activity determination and ethidium bromide efflux assays. Also, the susceptibilities of OtrC-overexpressing cells to several structurally unrelated drugs were compared with those of OtrC-non-expressing cells by minimal inhibitory concentration (MIC) assays, indicating that OtrC functions as a drug exporter with a broad range of drug specificities. The OTC production was enhanced by 1.6-fold in M4018 (P = 0.000877) and 1.4-fold in SR16 (P = 0.00973) duplication mutants, while it decreased to 80% in disruption mutants (P = 0.0182 and 0.0124 in M4018 and SR16, respectively). CONCLUSIONS: The results suggest that OtrC is an ABC transporter with multidrug resistance function, and plays an important role in self-protection by drug efflux mechanisms. This is the first report of such a protein in S. rimosus, and otrC could be a valuable target for genetic manipulation to improve the production of industrial antibiotics.     

Effect of liquid culture requirements on antifungal antibiotic production by Streptomyces rimosus MY02

Streptomyces rimosus MY02 was isolated from a soil sample which was collected from the northeast of China. The effect of medium components (i.e. carbon and nitrogen sources) and other culture requirements (i.e. initial pH and temperature) on production of antifungal antibiotics by S. rimosus MY02 was investigated in our work. The best conditions for the strain MY02 in 250-ml Erlenmeyer flask, for example, initial pH, temperature, medium capacity, agitation rate, seed age, inoculum size and growth period, were 6.0, 28 degrees C, 50 ml, 180 rpm, 4 days, 10% (v/v) and 120 h, respectively. Components and dosage of the medium, which effect antibiotic production, were determined by uniform design combined with regression analysis; meanwhile, a regression model was established. The components and dosage of the best medium were starch, 53.313 g; defatted peanut powder, 9.376 g; (NH(4))(2)SO(4), 6.244 g; and NaCl, 5.836 g; in 1l of distilled water. Residual values obtained between the observed values by experiments and predicted values by the model are very low, and this result showed that the experimental results were well in consistence with the calculation results via the model. The antifungal antibiotic production by S. rimosus MY02 was improved by optimization of the components and culture requirements. The diameter of inhibition zone of the culture supernatant from S. rimosus MY02 against Fusarium oxysporium f sp. cucumarinum was 33.19 mm.     

Determinant of resistance to kanamycin in Streptomycin rimosus: amplification in the chromosome and reversible genetic instability

The study on the kanamycin resistance determinant (Kanr) in an oxytetracycline--producing strain of S. rimosus showed that it was capable of amplifying in the chromosome during selection for increasing the antibiotic resistance level. The amplification of the DNA fragment with a molecular weight of 10.3 MDa containing Kanr amounted to 300 copies per genome, which resulted in a more than 1000-fold increase in kanamycin resistance level. Cloning of the Kanr determinant on plasmid SLP1.2 in S. lividans strain 66 was performed. In Streptomyces lividans strain 66 the Kanr determinant preserved the capacity for amplification in the hybrid plasmid pSU10 integrated into the chromosome. The Kanr determinant in the strains of S. rimosus and S. lividans was characterized by transfers Kanr in equilibrium Kans with a frequency of 1 X 10(-3). It was shown that the mutation in S. lividans strain 66 resulting in phenotype Kans was not connected with the structural Kanr gene on plasmid pSU10 but was localized on the chromosome. Phenotype Kans was promoted by a decrease in the number of the copies of the regulatory genetic element designated RES1. The reverse to phenotype Kanr might be due to one of the following events: amplification to the initial level of RES1 and amplification up to 200 copies per the genome of the hybrid plasmid pSU10 containing the Kanr determinant. Amplification of the Kanr determinant with preserved initial level of RES1 element resulted in a more than 1000 times increase in the resistance level.     

Determinants of resistance to chlortetracycline and other antibiotics in chlortetracycline-producing strain of Streptomyces aureofaciens

Data are presented on resistance of Streptomyces aureofaciens strain TB-633 FU--the producer of chlortetracycline (CTC) to autogenous antibiotics and a number of other antibiotics. It is demonstrated that resistance to CTC is specified by ctr genes of constitutive expression as well as by inducible genes. CTC and ethidium bromide may serve as efficient inductors of inducible ctr genes. The induction process is accompanied by increase in antibiotic biosynthesis level. Genes responsible for strain resistance to a number of macrolide antibiotics and thiostrepton are inducible and only function in the presence of appropriate antibiotics in the medium. The action of inducible mtr gene(s) is described in detail. The gene(s) simultaneously ensure increase in resistance to CTC and a number of macrolide antibiotics in the presence of exogenous inductors in media, such as both CTC and macrolide antibiotics. Mutants have been isolated which provide constitutive level of resistance to these antibiotics. A series of ctr and mtr mutants have increased CTC biosynthesis as compared to the initial level. Data on comparative analysis of the results obtained from hybridization of fragments of S. aureofaciens and S. rimosus DNAs to actI and actIII genes, responsible for polyketide synthases' synthesis, demonstrate that genes for CTC and OTC biosynthesis are situated on DNA fragments of similar size. This determines the strategy for cloning ctr and mtr genes as well as genes for CTC biosynthesis from S. aureofaciens.     

Analysis of antibiotic susceptibility and extrachromosomal DNA content of Ruminococcus albus and Ruminococcus flavefaciens

Seventeen Ruminococcus albus and Ruminococcus flavefaciens strains have been screened for naturally occurring antibiotic resistance, as determined by zones of inhibition from antibiotic disks. These strains were also examined for extrachromosomal DNA content. All strains screened are resistant to low levels (10-200 micrograms/mL) of streptomycin. In contrast to the previously reported data, we have found that R. flavefaciens C-94 is now susceptible to both kanamycin and tetracycline. However, R. flavefaciens FD-1 is not susceptible to kanamycin (minimum inhibitory concentration (MIC) = 40 micrograms/mL). Furthermore, R. albus 8 is resistant to tetracycline (MIC = 40 micrograms/mL), and erythromycin (MIC = 100 micrograms/mL). Six freshly isolated strains showed resistance to tetracycline (35-70 micrograms/mL), and all tetracycline-resistant strains also showed resistance to minocycline. None of these Ruminococcus determinants share homology with the streptococcal tetL, tetM, or tetN determinants. All 17 strains were screened for extrachromosomal DNA content. Nine different techniques for the detection and isolation of extrachromosomal DNA were tested. However, owing to difficulties in demonstrating or isolating plasmid DNA, it has not been possible to determine if these antibiotic resistance genes are plasmid borne. Evidence is presented to suggest that the presence of oxygen may affect the quality of the DNA obtained from Ruminococcus.     

Oxytetracycline inactivation by putative reactive oxygen species released to nutrient medium of Helianthus annuus hairy root cultures

When subjected to stress, plants produce reactive oxygen species (ROS) as a part of the defense response. The oxidative response is also used to degrade organic pollutants. Hairy roots of Helianthus annuus (sunflower) are shown to oxidize oxytetracycline (OTC) through the action of the ROS released to the nutrient medium by the hairy root cultures. Methyl jasmonate (MeJA) elicits ROS formation in the hairy root cultures. The activities of the antioxidant enzymes, ascorbate peroxidase (APX), catalase (CAT), and guaiacol peroxidase (GPX), are reported for hairy root cultures treated with increasing concentrations of MeJA. A bioassay using Enterococcus hirae as the test microorganism demonstrates the root-catalyzed oxidation process results in conversion of OTC into product(s) devoid of antibiotic activity. Direct evidence for putative ROS oxidation of OTC is obtained by mass spectrometry (MS) and HPLC/MS showing first quinone formation followed possibly by ring cleavage, which disrupts UV absorption and destroys antibiotic activity.     

Preliminary investigations into possible resistance to oxytetracycline in Melissococcus plutonius,a pathogen of honeybee larvae

AIMS: To investigate the occurrence of oxytetracycline (OTC) resistance in Melissococcus plutonius, which causes European foulbrood in honeybee colonies. METHODS AND RESULTS: Strains of M. plutonius were isolated from diseased colonies in England and Wales and tested for resistance to OTC. The minimum inhibitory concentration (MIC) of OTC was also determined for selected isolates. No resistance to the antibiotic was found in any isolate and the average MIC was found to be 3.9 microg ml-1. Melissococcus plutonius was found to be susceptible to both chlortetracycline and tetracycline. CONCLUSIONS: No resistance to OTC was found in M. plutonius. SIGNIFICANCE AND IMPACT OF THE STUDY: This study demonstrated that OTC can continue to be used to treat European foulbrood and that resistance may not explain why some treatments fail.     

Study of certain carbohydrate metabolism enzymes in an active oxytetracycline producer strain and in an inactive mutant in relation to antibiotic biosynthesis]

The activity of the glycolysis enzymes, i.e. aldolase and pyruvate decarboxylase and the enzymes of the pentose cycle, i.e. transketolase were investigated in the process of cultivation of an active strain and inactive mutant of Act. rimosus under conditions favourable for oxytetracycline biosynthesis on starch medium and under unfavourable conditions on glucose medium. It was shown that the aldolase and transketolase activity in the inactive mutant was higher on the starch medium as compared to the active strain, while the activity of pyruvate dekarboxylase was lower. The above difference between the both strains was preserved on the glucose medium and the activity of aldolase and transketolase in both strains increased, while the activity of pyruvate dekarboxylase remained at the same level.     

Effect of the aeration conditions on the biosynthesis of oxytetracycline and the formation of organic acids by a culture of Actinomyces rimosus]

The effect of the aeration conditions on oxytetracycline biosynthesis and production of organic acids by Act. rimosus was studied. Intensive biosynthesis of oxytetracycline in shaken flasks with concentrated complex media was observed at the rate of oxygen dissolution in the liquid ranging from 14 to 25 mg/1/min. Lower rates of the oxygen dissolution up to 7 mg/1/min resulted in decreased rates of the culture growth and the medium component consumption, decreased antibiotic levels, production of significant amounts of pyruvic and acetic acids.     

龟裂链霉菌zwf2基因阻断提高土霉素生物合成

葡萄糖-6-磷酸脱氢酶(G6PDH)是链霉菌磷酸戊糖途径中第一个酶("看家"酶),也是形成NADPH的关键酶,由zwf1和zwf2基因编码.以温敏型质粒pKC1139为基础构建了用于阻断龟裂链霉菌zwf2的重组质粒pKC1139-zwf2',通过大肠杆菌GM2929去甲基化pKC1139-zwf2'后电转至原始龟裂链霉菌M4018感受态细胞,筛选得到转化子.转化子进一步通过PCR鉴定和点杂交印迹分析鉴定,证明是zwf2基因阻断的阳性突变子命名为M4018-△zwf2.以原始菌株为对照,突变子摇瓶发酵结果表明:突变子的葡萄糖-6-磷酸脱氢酶酶活是原始菌的50%左右,但土霉素生物合成水平则提高了27%;在细胞生长方面,二者均在第4d进入生长稳定期而开始大量合成土霉素,发酵结束时细胞菌体浓度基本相同,但突变子的单位菌丝体土霉素生物合成能力则提高了31%.因此,zwf2的阻断有利于土霉素的生物合成,而对细胞生长没有明显影响.     

Mutagenic action of N-nitrosodimethylurea on Actinomyces rimosus and Penicillium chrysogenum]

High mutagenic activity of N-nitrozodimethylurea (NDMU), an agent of the group of the nitrozo compounds not studied in detail was shown with respect to prototrophic and auxotrophic strains of Actinomyces rimosus, an organism producing oxytetracycline and Penicillium chrysogenum, an organism producing penicillin. The rate of direct and back mutations in the auxotrophic strain of Act. rimosus under the effect of NDMU was many times higher than that of spontaneous mutations. NDMU was used at one of the selection stages at which a more active variant of Act. rimosus was obtained. This is evident of a possible use of the mutagen for induction of variation with respect to the quantitative feature of oxytetracycline production. A great number of morphologically changed forms and biochemical mutants of Pen. chrysogenum formed under the effect of this substance. NDMU induced a mutant of Pen. chrysogenum capable of selective synthesis of 6-aminopenicillinic acid without addition of the precursor.     

Selection of the optimal conditions for the procurement and regeneration of protoplasts of the industrial strain of Streptomyces rimosus, the producer of oxytetracycline, and the effect of the protoplasting process on the antibiotic activity]

Optimal conditions for protoplasting of the Streptomyces rimosus industrial strain No. 1 producing oxytetracycline were developed. Observation of the early stages of the protoplast regeneration in microchambers showed that there were two regeneration types: normal and anomalous. The latter was likely defined by the glycine effect on cell wall synthesis. It was accompanied by the stage in which the protoplasts had the form of multiplying protoplast-like cells. The protoplasting of the S. rimosus culture producing oxytetracycline resulted in an increase in the variability of an antibiotic producing property and the frequency of low active variants.     

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.     

Study of the chemical makeup of the mycelium from an active strain of Act. rimosus and from an inactive mutant in relaiton to oxytetracycline biosynthesis]

Chemical composition of the mycelium of the active and inactive mutants of Act. rimosus grown under conditions favourable for oxytetracycline biosynthesis on the starch or maltose medium and under favourable conditions on the glucose medium was studied. It was shown that according to its chemical composition the above strains did not practically differ. When grown on the starch medium the mycelium of both strains contained great amounts of carbohydrates and comparatively small amounts of nucleic acids and nitrogen. Replacement of starch in the medium by glucose or maltose induced significant changes in the mycelium composition: the synthesis of intracellular polysaccharides was markedly suppressed and the synthesis of nucleic acids and nitrogen containing compounds increased. RNA was the main nucleic acid in both strains on starch and glucose media. The content of DNA was low and did not practically change. The mycelium of both strains contained small amounts of lipids which did not significantly change during the process of cultivation and did not correlate with the antibiotic activity.