Resistance to macrolides, lincosamides and streptogramin type B antibiotics due to a mutation in an rRNA operon of Streptomyces ambofaciens.

Streptomyces ambofaciens produces spiramycin, a macrolide antibiotic and expresses an inducible resistance to macrolides, lincosamides and streptogramin B antibiotics (MLS). From a mutant of S.ambofaciens exhibiting a constitutive MLS resistance phenotype a resistance determinant was cloned on a low copy number vector (pIJ61) through its expression in Streptomyces lividans. Further characterization has shown that this determinant corresponded to a mutant rRNA operon with a mutation in the 23S rRNA gene. In different organisms, mutations leading to MLS resistance have been located at a position corresponding to the adenine 2058 of Escherichia coli 23S rRNA. In the 23S rRNA from S.ambofaciens a similar position for the mutation has been postulated and DNA sequencing of this region has shown an adenine to guanine transition at a position corresponding to 2058. S.ambofaciens possesses four rRNA operons which we have cloned. In Streptomyces, contrary to other bacteria, a mutation in one among several rRNA operons confers a selectable MLS resistance phenotype. Possible reasons for this difference are discussed.     

Effect of cloned DNA fragment from Streptomyces chrysomallus No.2 on metabolism in Streptomyces strains

The effects on cloned DNA fragment carrying an actinomycin resistance determinant on physiological processes in streptomyces strains with various potencies in producing this antibiotic, their inactive mutants, and model strain of Streptomyces lividans 66 were studied. This fragment was shown to modulate bacterial resistance to actinomycin and biosynthesis of antibiotics.     

Effect of a Cloned DNA Fragment from Streptomyces chrysomallusNo. 2 on the Metabolism of Certain Streptomyces Strains

The effects on a cloned DNA fragment carrying an actinomycin resistance determinant on physiological processes in strains of streptomycetes with various potencies in producing this antibiotic, their inactive mutants, and the model strain ofStreptomyces lividans66 were studied. This fragment was shown to modulate bacterial resistance to actinomycin and biosynthesis of antibiotics.     

Genetic mapping of unstable chloramphenicol resistance determinant in Streptomyces coelicolor A3(2)

The results indicative of chromosomal localization of the unstable chloramphenicol resistance determinant in Streptomyces coelicolor A3(2) have been obtained. Independent mutations specifying chloramphenicol sensitivity in different strains of S. coelicolor A3(2), S18 and A617M are localized in the same region flanked by markers argA1 and cysD18 on the genetic map. Mutations restoring chloramphenicol resistance are also localized in this region. Different locations of the genetically unstable determinant of chloramphenicol resistance detected in various laboratories are discussed, in relation to the results showing that transfer to chloramphenicol sensitivity is due to a set of various rearrangements (deletions, amplifications, deamplifications, etc.), differing in separate variants.     

Unstable genetic determinant of A-factor biosynthesis in streptomycin-producing organisms: cloning and characterization.

We cloned a DNA fragment directing synthesis of A-factor from the total cellular DNA of streptomycin-producing Streptomyces bikiniensis on the plasmid vector pIJ385 . Introduction of the recombinant plasmid ( pAFB1 ) into A-factor-deficient S. bikiniensis and Streptomyces griseus mutants led to A-factor production in the host cells, as a result of which streptomycin production, streptomycin resistance, and spore formation of these mutants were simultaneously restored. The plasmid pAFB1 also complemented both afsA and afsB mutations of Streptomyces coelicolor A3(2). These results indicated that the cloned DNA fragment contained the genetic determinant of A-factor biosynthesis. The cloned fragment, when carried on a multicopy vector plasmid, induced production of a large amount of A-factor in several Streptomyces hosts. In Southern blot DNA/DNA hybridization analyses with a trimmed 5-kilobase fragment containing the intact A-factor determinant as probe, total cellular DNA from A-factor-deficient mutants gave no positive hybridization. The DNA blot experiment also showed a wide distribution of sequences homologous to the S. bikiniensis A-factor determinant among most, but not all, A-factor-producing actinomycetes with a varying extent of homology and the absence of these sequences from most A-factor nonproducers .     

Cloning of a lincosamide resistance determinant from Streptomyces caelestis, the producer of celesticetin, and characterization of the resistance mechanism.

Self-resistance has been investigated in Streptomyces caelestis (producer of the lincosamide antibiotic celesticetin), from which a lincosamide resistance determinant (clr) has been isolated on a 1-kilobase DNA fragment and cloned in Streptomyces lividans. The clr product is a specific methylase which produces a single residue of N6-monomethyladenine in 23S rRNA at position 2058, thereby rendering the 50S ribosmal subunit resistant to the action of lincosamides.     

Cloning of an aminoglycoside-resistance-encoding gene, kamC, from Saccharopolyspora hirsuta: comparison with kamB from Streptomyces tenebrarius.

An aminoglycoside-resistance-encoding gene (kamC) has been isolated from the sporaricin producer, Saccharopolyspora (Sac.) hirsuta, and expressed both in Streptomyces lividans and Escherichia coli. The pattern of resistance conferred by this gene was identical to that given by another gene (kamB) previously isolated from Streptomyces tenebrarius. In accordance with the known action of the kamB product, the Sac, hirsuta determinant also encodes a methyltransferase that modifies 16S rRNA, thereby rendering ribosomes refractory to certain aminoglycosides. The nucleotide sequences of both genes have been determined and comparison of the deduced amino acid sequences reveals a high degree of similarity.     

An ABC-transporter from Streptomyces longisporoflavus confers resistance to the polyether-ionophore antibiotic tetronasin

Streptomyces longisporoflavus produces the poly-ketide-polyether antibiotic, tetronasin, which acts as an ionophore and depolarizes the membrane of bacteria sensitive to the drug. A genomic library of S. longisporoflavus DN A was cloned in Streptomyces Uvldans and screened to identify tetronasin-resistance determinants. The inclusion of 0.2 M NaCl in the growth medium with tetronasin markedly improved the sensitivity of the screen. Two different resistance determinants, designated tnrB (ptetR51) and tnrA (ptetR11) respectively, were identified. The determinant tnrB (ptetR51) but not tnrA (ptetR11), also conferred resistance to tetronasin when cloned into Streptomyces albus. The tnrB determinant was further localized, by subcloning, to a 2.8 kb Kpnl fragment. DNA sequence analysis of this insert revealed one incomplete and two complete open reading frames (ORFs 1, 2 and 3). The deduced sequence of the gene product of ORF2 (TnrB2) revealed significant similarity to the ATP-binding domains of the ABC (A TP b inding c assette) superfamily of transport-related proteins. The adjacent gene, ORF3, is translationally coupled to ORF2 and would encode a hydrophobic protein (TnrB3) with six transmembrane helices which probably constitutes the integral membrane component of the transporter. The mechanism of tetronasin resistance mediated by tnrB is probably an ATP-dependent efflux system.     

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.     

Streptomyces antibioticus contains at least three oleandomycin-resistance determinants, one of which shows similarity with proteins of the ABC-transporter superfamily

Three different DNA fragments of an oleandomycin producer, Streptomyces antibioticus, conferring oleandomycin resistance were cloned in plasmid pIJ702 and expressed in Streptomyces lividans and in Streptomyces albus. These oleandomycin resistance determinants were designated as oleA (pOR400), oleB (pOR501) and oleC (pOR800). oleA and oleC are closely linked in the chromosome as they were both obtained together in two cosmid clones that were isolated from a genomic library. Sequencing of the oleC resistance determinant revealed four complete open reading frames (ORFs) and the C-terminal end of a fifth. The functions of orf1 and orf2 are unknown since they did not show significant similarity with other sequences in the data bases. The orf3 gene product has similarity with some proteins involved in iron and vitamin B₁₂ uptake in bacteria. The orf4 gene product had a hydrophilic profile and showed important similarity with proteins containing typical ATP-binding domains characteristic of the ABC-transporter superfamily and involved in membrane transport and, particularly, with several genes conferring resistance to various macrolide antibiotics and anticancer drugs. The last gene, orf5, is translationally coupled to orf4 and codes for a hydrophobic polypeptide containing several trans-membrane domains characteristic of integral membrane proteins. Subcloning and deletion experiments limited the resistance determinant to a 0.9kb Pst1-Sph1 fragment and only orf4 is included in this fragment. These results suggest that resistance to oleandomycin conferred by oleC (orf4) is probably due to an efflux transport system of the ABC-transporter superfamily.     

Nucleotide sequence analysis of the gene specifying the bifunctional 6''-aminoglycoside acetyltransferase 2"-aminoglycoside phosphotransferase enzyme in Streptococcus faecalis and identification and cloning of gene regions specifying the two activities.

The gene specifying the bifunctional 6'-aminoglycoside acetyltransferase [AAC(6')] 2"-aminoglycoside phosphotransferase [APH(2")] enzyme from the Streptococcus faecalis plasmid pIP800 was cloned in Escherichia coli. A single protein with an apparent molecular weight of 56,000 was specified by this cloned determinant as detected in minicell experiments. Nucleotide sequence analysis revealed the presence of an open reading frame capable of specifying a protein of 479 amino acids and with a molecular weight of 56,850. The deduced amino acid sequence of the bifunctional AAC(6')-APH(2") gene product possessed two regions of homology with other sequenced resistance proteins. The N-terminal region contained a sequence that was homologous to the chloramphenicol acetyltransferase of Bacillus pumilus, and the C-terminal region contained a sequence homologous to the aminoglycoside phosphotransferase of Streptomyces fradiae. Subcloning experiments were performed with the AAC(6')-APH(2") resistance determinant, and it was possible to obtain gene segments independently specifying the acetyltransferase and phosphotransferase activities. These data suggest that the gene specifying the AAC(6')-APH(2") resistance enzyme arose as a result of a gene fusion.     

Molecular cloning of tetracycline resistance genes from Streptomyces rimosus in Streptomyces griseus and characterization of the cloned genes.

Two tetracycline resistance genes of Streptomyces rimosus, an oxytetracycline producer, were cloned in Streptomyces griseus by using pOA15 as a vector plasmid. Expression of the cloned genes, designated as tetA and tetB was inducible in S. griseus as well as in the donor strain. The tetracycline resistance directed by tetA and tetB was characterized by examining the uptake of tetracycline and in vitro polyphenylalanine synthesis by the sensitive host and transformants with the resultant hybrid plasmids. Polyphenylalanine synthesis with crude ribosomes and the S150 fraction from S. griseus carrying the tetA plasmid was resistant to tetracycline, and, by a cross-test of ribosomes and S150 fraction coming from both the sensitive host and the resistant transformant, the resistance directed by tetA was revealed to reside mainly in crude ribosomes and slightly in the S150 fraction. However, the resistance in the crude ribosomes disappeared when they were washed with 1 M ammonium chloride. These results suggest that tetA specified the tetracycline resistance of the machinery for protein synthesis not through ribosomal subunits, but via an unidentified cytoplasmic factor. In contrast, S. griseus carrying the tetB plasmid accumulated less intracellular tetracycline than did the host, and the protein synthesis by reconstituting the ribosomes and S150 fraction was sensitive to the drug. Therefore, it is conceivable that tetB coded a tetracycline resistance determinant responsible for the reduced accumulation of tetracycline.     

Molecular characterization of a gene from Saccharopolyspora erythraea (Streptomyces erythraeus) which is involved in erythromycin biosynthesis

A 7.3 kbp DNA fragment, encompassing the erythromycin (Em) resistance gene (ermE) and a portion of the gene cluster encoding the biosynthetic genes for erythromycin biosynthesis in Saccharopolyspora erythraea (formerly Streptomyces erythraeus) has been cloned in Streptomyces lividans using the plasmid vector pIJ702, and its nucleotide sequence has been determined using a modified dideoxy chain-termination procedure. In particular, we have examined the region immediately 5′ of the resistance determinant, where the tandem promoters for ermE overlap the promoters for a divergently transcribed coding sequence (ORF). Disruption of this ORF using an integrational pIJ702-based plasmid vector gave mutants which were specifically blocked in erythromycin biosynthesis, and which accumulated 3-O-α-L-mycarosylerythronolide B: this behaviour is identical to that of previously described eryC1 mutants. The eryC1-gene product, a protein of subunit M_r 39200, is therefore involved either as a structural or as a regulatory gene in the formation of the deoxyamino-sugar desosamine or in its attachment to the macro-lide ring.     

The expression of Streptomyces and Escherichia coli drug-resistance determinants cloned into the Streptomyces phage phi C31

Lysogens obtained by infecting Streptomyces albus G with a phi C31-pBR322 chimaeric prophage or its delta W12 deletion derivative had increased tetracycline resistance. The ability of the delta W12 derivative to transduce tetracycline resistance was inactivated by inserting a viomycin resistance determinant (vph) into the BamHI site of the pBR322 tet gene, and restored by excising the vph gene. Another deletion mutant (delta W17) of the chimaera, carrying an intact tet gene, was normally unable to transduce tetracycline resistance. This inability was correlated with the finding, by Southern hybridisation analysis, that the att site required for insertion of phi C31 prophage into the host chromosome was located within the delta W17 deletion. Use of phi C31 lysogenic recipient permitted the integration of the att-deleted phage, presumably by homologous recombination, giving tetracycline-resistant double lysogens. This technique was extended to S. coelicolor A3(2) in the detection of derivatives of the att-deleted phage into which a thiostrepton-resistance determinant (tsr) had been inserted in vitro. Phage released from double lysogens were mainly recombinants. One such recombinant is a PstI vector for DNA cloning, able to accommodate up to 6 kb of introduced DNA.     

Autonomous selection of differentiation mutants of Streptomyces lividans TK24 in continuous culture

Summary Streptomyces lividans TK24 strains transformed with different recombinat derivatives of the vector plasmid pIJ487 were continuously cultivated in a chemostat. The first plasmid derivative contained the determinant for human interferon-alpha-1 (IFN) and the expression-secretion-unit (ESU) for this protein. In the second one a nourseothricin resistance determinant (ntc) was inserted additionally. The chemostat operated mainly at glucose limitation and low dilution rates. The structural and functional stabilities of the plasmids were shown to depend on the selection pressure. The host mutants enriched in the chemostat differed from the parental strain with respect to the growth pattern of aerial and submerged mycelium, the spore formation, and the formation and secretion of pigments and enzymes. Some highly stable host-vector systems could be selected. The plasmids' genotype influenced the growth pattern of the host mutants enriched in the chemostat in dependence on the limitation conditions as well as the stability of plasmid inheritance, plasmid structure and pigment formation in these mutants.     

Spectinomycin resistance and associated DNA amplification in Streptomyces achromogenes subsp. rubradiris.

Streptomyces achromogenes subsp. rubradiris plated at low density on 1,000 micrograms of spectinomycin per ml initially produces slow-growing, bald colonies from which arise, in a spatially and temporally random fashion, foci of rapidly growing aerial mycelium-forming cells whose DNA contains an approximately 200- to 300-fold amplification of an 8-kilobase (kb) sequence. This sequence was cloned in Escherichia coli on pBR322 and physically characterized. It was separately cloned also in Streptomyces lividans as a BglII fragment and shown to impart high-level resistance to spectinomycin in an orientation-independent manner when present in either the high-copy-number vector pIJ702 or the unit-copy-number vector pIJ943. A spectinomycin resistance determinant was shown to reside on a 1.7-kb SphI-BglII subfragment. Analysis of Southern blots of restriction enzyme digests of wild-type S. achromogenes DNA probed with the labeled 8-kb DNA sequence resulted in the identification and subsequent cloning in S. lividans of a 10.4-kb BamHI fragment which probably includes the complete 8.8-kb amplifiable unit of DNA. This unit is present in wild-type S. achromogenes and in the initially slow-growing, bald colonies arising on 1,000 micrograms of spectinomycin per ml as a single copy. It carries two 0.8-kb direct repeats at its termini as well as the spectinomycin resistance determinant close to one of these termini. About 5% of protoplast regenerants from wild-type S. achromogenes and 77% of protoplast regenerants from the rapidly growing strains lost both the ability to grow on spectinomycin at 10 micrograms/ml and the sequences that hybridize with the 8-kb probe DNA. The 1.7-kb Bg/II-SphI resistance fragment, when introduced via the vector pIJ702 into an S. achromogenes strain sensitive to 10 microgram of spectinomycin per ml, permitted its vigorous growth on 1,000 micrograms of the antibiotic per ml.