A putative proteinase gene is involved in regulation of landomycin E biosynthesis in Streptomyces globisporus 1912

The prx gene, which is highly homologous to putative proteinases, has been identified by sequencing in the vicinity of the biosynthetic gene cluster for landomycin E (LaE) biosynthesis (lnd) in Streptomyces globisporus 1912. The S. globisporus Pro6 gene, deficient in prx, produced fivefold less LaE than the parental strain. The expression of prx in S. globisporus Pro6 restored LaE production to wild-type levels, whereas expression of the pathway-specific regulatory gene lndI did not. The introduction of additional copies of prx into the wild-type strain using a pSG5-based plasmid, pKC1139, led to a 2.7-fold increase in LaE production. These results indicate that prx is a novel regulatory gene for LaE biosynthesis.     

Proton-dependent transporter gene lndJ confers resistance to landomycin E in Streptomyces globisporus

Sequence analysis of 2 kb BamHI-SmaI fragment of landomycin E (LaE) gene cluster in S. globisporus 1912 revealed one complete ORF marked as lndJ. Analysis of putative LndJ aminoacid sequence allowed us to suppose that it is proton-dependent antiporter which could be involved in resistance to LaE in the producing strain. Although disruption of lndJ had no significant influence on LaE production and resistance, it's overexpression in wild type and LaE overproducing strains led to qualitative changes in landomycins biosynthesis and increased resistance to LaE. These data support the hypothesis about involvement of lndJ gene in landomycins export.     

The use of PCR for detecting genes that encode type I polyketide synthases in genomes of actinomycetes

PCR screening of type I polyketidesynthase genes (PKS) was conducted in genomes of actinomycetes, producers of antibiotics. Some DNA fragments from the Streptomyces globisporus 1912 strain, a producer of a novel angucycline antibiotic landomycin E, were amplified. These fragments shared appreciable homology with type I PKS controlling the biosynthesis of polyene antibiotics (pymaricin and nistatin). The cloned regions were used to inactivate putative type I PKS genes in S. globisporus 1912. Strains with inactivated genes of PKS module do not differ from the original strain in the spectrum of synthesized polyketides. Apparently, these are silent genes, which require specific induction for their expression. The method of PCR screening can be used in a large-scale search for producers of new antibiotics.     

Generation of landomycin D-producing strainStreptomyces globisporus LD3

Rhodinosyl transferase gene lndGT4, governing the conversion of the disaccharide oligoketide ('polyketide') landomycin D into a trisaccharide derivative landomycin E, was deleted in Streptomyces globisporus 1912 genome. Possible resistance mechanisms that protect the resulting landomycin D-producing mutant strain S. globisporus LD3 against the toxic action of landomycins were determined.     

Proton-dependent transporter gene <Emphasis Type="Italic">lndJ</Emphasis> confers resistance to landomycin E in <Emphasis Type="Italic">Streptomyces globisporus</Emphasis> 1912

Sequence analysis of 2 kb BamHI-SmaI fragment of landomycin E (LaE) gene cluster in Streptomyces globisporus 1912 revealed one complete ORF marked as lndJ. Analysis of putative lndJ aminoacid sequence allowed us to suppose that it is proton-dependent antiporter which could be involved in resistance to LaE in the producing strain. Although disruption of lndJ had no significant influence on LaE production and resistance, its overexpression in wild type and LaE overproducing strains led to qualitative changes in landomycins biosynthesis and increased resistance to LaE. These data support the hypothesis about involvement of lndJ gene in landomycins export. The text was submitted by the authors in English.     

Interspecies conjugation of Escherichia coli-Streptomyces globisporus 1912 using integrative plasmid pSET152 and its derivatives]

Streptomyces globisporus 1912 produces a novel angucycline antitumor antibiotic landomycin E (LE). To study the LE biosynthetic gene cluster in detail, a system for the conjugal transfer of the integrative plasmid pSET152 from Escherichia coli into S. globisporus 1912 has been developed. It was shown that this plasmid integrates into two sites of the S. globisporus chromosome and is stably inherited under nonselective conditions. pSET152+ exconjugants of the strain 1912 are characterized by a significant decrease in LE synthesis (by 50-90%). A negative effect of pSET152 integration on antibiotic production was observed even upon the use of the recipient strain with increased LE synthesis, although in this case, the level of LE production in ex-conjugants was 120-150% of that in the original strain 1912. Based on pSET152, a vector system for gene knockouts in S. globisporus was developed. The effectivity of this system was shown in the example of disruption of the lndA gene encoding the key enzyme of LE synthesis (beta-ketoacylsynthase). Inactivation of this gene was shown to lead to the cessation of LE biosynthesis.     

Draft genome sequence of Streptomyces globisporus C-1027, which produces an antitumor antibiotic consisting of a nine-membered enediyne with a chromoprotein

Streptomyces globisporus C-1027 is the producer of antitumor antibiotic C-1027, a nine-membered enediyne-containing compound. Here we present a draft genome sequence of S. globisporus C-1027 containing the intact biosynthetic gene cluster for this antibiotic. The genome also carries numerous sets of genes for the biosynthesis of diverse secondary metabolites.     

Expression of the landomycin biosynthetic gene cluster in a PKS mutant of Streptomyces fradiae is dependent on the coexpression of a putative transcriptional activator gene

The formation of landomycin A or one of its derivatives (5,6-anhydrolandomycin A) in a heterologous strain has never been achieved. It has now been made possible by the coexpression of a cosmid containing all biosynthetic genes necessary to produce landomycin A together with a pathway-specific regulatory gene. As host we used a polyketide synthase-defective mutant strain of Streptomyces fradiae Tü2717 which is not able to produce urdamycin A. Our results indicate that four glycosyltransferases are responsible for the formation of the hexasaccharide side chain of landomycin A.     

Coordination of export and glycosylation of landomycins in Streptomyces cyanogenus S136

In Streptomyces cyanogenus S136 gene cluster for biosynthesis of polyglycosylated angucycline landomycin A (LaA), a divergently oriented gene pair for a TetR-family regulator ( lanK ) and an efflux protein ( lanJ ) is located, whose functions remained obscure. Overexpression and disruption studies showed that lanK and lanJ genes control LaA resistance. Also, a constitutive lanK overexpression led to predominant accumulation of LaA precursors bearing shorter glycoside chains. These data as well as the results of in vitro and in vivo assays of LanK activity are consistent with the idea that LanK represses lanJ and some downstream genes involved in conversion of landomycin D (a disaccharide LaA precursor) into LaA. LaA and some of its precursors accumulate in the producing cell and relieve repression by LanK, thus amplifying the biosynthesis and export of landomycins with long glycoside chains. Therefore, the main biological role of LanK appears to be the inhibition of premature extrusion of early LaA precursors from the cells, which in turn creates the optimal conditions for accumulation of LaA as the major landomycin in S. cyanogenus S136.     

Differences in the substrate specificity of glycosyltransferases involved in landomycins A and E biosynthesis

A lanGT4 mutant of the landomycin A producer Streptomyces cyanogenus S136 was constructed, leading to the production of landomycin D with two deoxy sugars in the side chain and proving that LanGT4 is responsible for attaching the third deoxy sugar of the hexasaccharide side chain. Heterologous expression of lndGT4 of the landomycin E producer Streptomyces globisporus 1912 in the lanGT4 mutant restored landomycin A production, indicating that LndGT4, like LanGT4, also has the ability to work iteratively. A S. cyanogenus S136 mutant with a mutation in lanGT1, encoding a d-olivosyltransferase, was shown to produce landomycin I with one deoxy sugar and, surprisingly, a new landomycin derivative (landomycin L) containing a d-olivose followed by an l-rhodinose. Heterologous expression of lndGT1 of S. globisporus 1912 in the lanGT1 mutant did not restore landomycin A production but led to the formation of a second new landomycin derivative (landomycin K) containing an unusual pentasaccharide chain (d-olivose–d-olivose–l-rhodinose–d-olivose–l-rhodinose). The formation of landomycin L and landomycin K is most probably attributed to the high substrate flexibility of the rhodinosyltransferase LanGT4. A. Erb and C. Krauth contributed equally to this work.     

Design of Streptomyces nogalater LV65 strains with higher synthesis of nogalamicin using regulatory genes

Influence of cloned regulatory genes on biosynthesis of nogalamicin by Streptomyces nogalater LV65 strains has been studied. Gene snorA from the S. nogalater genome was cloned in multicopy replicative plasmid pSOKA and integrative plasmid pR3A. Introduction of these plasmids into the cells of wild type strain of S. nogalater LV65 resulted in higher synthesis of nogalamicin. A similar effect was observed at heterologous expression of gene ppGpp of synthetase relA cloned in S. coelicolor A3(2). Heterologous expression of genes absA2from S. ghanaensis ATCC14672 and lndyR from genome S. globisporus 1912 decreased synthesis of antibiotic. The study results indicate the presence of homologs of these genes in chromosome of S. nogalater, their possible participation in regulation of nogalamicin biosynthesis, and provide us with a possibility for genetic design of the strains with higher synthesis of this antibiotic.     

Targeted disruption of<Emphasis Type="Italic">Streptomyces globisporus lndF</Emphasis> and<Emphasis Type="Italic">lndL</Emphasis> cyclase genes involved in landomycin E biosynthesis

Streptomyces globisporus strains with knockouts in lndF and lndL genes, previously identified as possibly encoding cyclases governing cyclization of the nascent oligoketide ('polyketide') chain during the biosynthesis of the antitumor angucycline landomycin E, were prepared. On combining the results of sequence analysis and HPLC of extracts from mutant strains, lndL was suggested to control the first cyclization-aromatization event and lndF to be responsible for the 3rd-4th ring formation.     

埃莎霉素Ⅰ组分高含量、高产量基因工程菌WSJ-IA及其原株的鉴定

【目的】利用调节基因acyB2激活异戊酰基转移酶(ist)基因表达的特点,将ist与调节基因acyB2在异戊酰螺旋霉素(埃莎霉素)Ⅰ产生菌菌株中共表达,获得埃莎霉素Ⅰ单组分的高含量及高产量菌株WSJ-IA。对其及原始螺旋霉素产生菌菌株Streptomyces spiramyceticus F21进行了初步鉴定。【方法】从形态学、培养和生理生化特征、细胞壁化学组成、16S rRNA基因序列、5个看家基因(atpD、gyrB、rpoB、recA和trpB)蛋白分析和系统发育树构建等方面对该菌株及其原株进行了鉴定。【结果】两株菌在形态培养特征、生理生化特征、细胞壁化学组成、16S rRNA基因序列和5个看家基因蛋白水平基本一致,在系统发育树分析中同处在一个分支中。而在16S rRNA基因序列和5个看家基因蛋白水平在系统发育上它们均与已知相近菌株处于不同的分支上,并且与不同基因的相近菌株各有不同,其中无一报道产生螺旋霉素。【结论】Streptomyces spira-myceticus F21可能是一个产生螺旋霉素的链霉菌新种,16S rRNA基因序列和5个看家基因蛋白序列分析可以作为埃莎霉素Ⅰ基因工程菌生产过程中进行鉴别的分子标志。     

The Use of PCR for Detecting Genes That Encode Type I Polyketide Synthases in Genomes of Actinomycetes

PCR screening of type I polyketidesynthase genes (PKS) was conducted in genomes of actinomycetes, producers of antibiotics. Some DNA fragments from the Streptomyces globisporus 1912 strain, a producer of a novel angucycline antibiotic landomycin E, were amplified. These fragments shared appreciable homology with type I PKS controlling the biosynthesis of polyene antibiotics (pymaricin and nistatin). The cloned regions were used to inactivate putative type I PKS genes in S. globisporus 1912. Strains with inactivated genes of PKS modular do not differ from the original strain in the spectrum of synthesized polyketides. Apparently, these are silent genes, which require specific induction for their expression. The method of PCR screening can be used in a large-scale search for producers of new antibiotics.__________Translated from Genetika, Vol. 41, No. 5, 2005, pp. 595–600.Original Russian Text Copyright © 2005 by Ostash, Ogonyan, Luzhetskyy, Bechthold, Fedorenko.