Involvement of 16S ribosomal RNA in resistance of the aminoglycoside-producers Streptomyces tenjimariensis, Streptomyces tenebrarius and Micromonospora purpurea

Basic and applied research on multiple aminoglycoside antibiotic resistance of actinomycetes: an old-timer's recollection

A list of our research achievements on multiple aminoglycoside antibiotic (AG) resistance in AG-producing actinomycetes is outlined. In 1979, the author discovered a novel AG (istamycin)-producing Streptomyces tenjimariensis SS-939 by screening actinomycetes with kanamycin (KM)-resistance and plasmid profiles. This discovery directed our biochemical and genetic approaches to multiple AG resistance (AGR) of AG producers. In this article, the following discoveries will be outlined: (1) AGR profiles correlating with the productivity of AGs in AG-producers, (2) Wide distribution of multiple AG resistance in AG-nonproducing actinomycetes, (3) Involvement of ribosomal resistance and AG-acetylating enzymes as underlying AGR factors, (4) Activation by single nucleotide substitution of a silent gene coding for aminoglycoside 3-N-acetyltransferase, AAC(3), in S. griseus, (5) Discovery of a novel antibiotic indolizomycin through protoplast fusion treatment between S. tenjimariensis and S. griseus strains with different AGR phenotypes, and (6) Double stage-acting activity of arbekacin (ABK; an anti-MRSA semisynthetic AG) discovered by acetylation of ABK with cloned AACs; that is both ABK and its acetylated derivatives showed remarkable antibiotic activities.

Overexpression of sgm 5’ UTR mRNA reduces gentamicin resistance in both Escherichia coli and Micromonospora melanosporea cells

The 16S rRNA methylases are expressed by most of the antibiotic producing bacteria in order to protect themselves against antibiotics by methylation of 16S rRNA at positions which are crucial for their action. The sgm sisomicin-gentamicin resistance gene from Micromonospora zionensis methylates G1405 positioned in the A site of 16S rRNA, which includes a CCGCCC hexanucleotide. The same hexanucleotide is also present 14 nucleotides in front of the ribosome binding site of sgm mRNA. The model proposed for translational regulation of sgm assumes that Sgm binds to this motif, both on 16S rRNA and on the 5? untranslated region (UTR) of its own mRNA. The 5? UTR mRNA sequence was overexpressed on 3?-truncated sgm mRNA, and the effect on gentamicin resistance conferred by Sgm was tested in Escherichia coli and in Micromonospora melanosporea. Overexpression of the sgm mRNA regulatory region decreases the resistance to gentamicin in both E. coli and M. melanosporea. This effect is likely to be due to titration of Sgm molecules by the overexpressed 5? UTR.

Acquired gentamicin resistance by permeability impairment in Enterococcus faecalis

Enterococci are intrinsically resistant to low levels of aminoglycosides. We previously selected in vitro and in vivo Enterococcus faecalis with intermediate-level resistance to gentamicin that did not abolish synergism with a cell-wall-active agent (E. Aslangul et al., Antimicrob. Agents Chemother. 49:4144-4148, 2005). The aim of this study was to investigate the mechanism of resistance to gentamicin in the 1688-G3 third-step mutant (MIC, 512 microg/ml) of E. faecalis JH2-2. No mutations were found in the genes for L6 ribosomal protein and the four copies of 16S rRNA. Production of a known aminoglycoside-modifying enzyme was unlikely due to the distinct resistance phenotype and absence of the corresponding genes. Efflux was also unlikely since ethidium bromide MICs were similar for JH2-2 and 1688-G3 and since the pump inhibitors reserpine and verapamil had no effect on gentamicin resistance in both strains. To study gentamicin accumulation, we developed a nonisotopic method based on a fluorescent polarization immunoassay. Impaired gentamicin accumulation was observed in 1688-G3 compared to JH2-2 and was only partially reversible by the N,N'-dicyclohexylcarbodiimide (DCCD) uncoupler agent. The lower sensitivity of 1688-G3 to DCCD suggested alteration of the FoF1-ATPase. However, no mutations were detected in the structural genes (atp) for the Fo channel and no difference in transcript levels of atpB and atpE was found between 1688-G3 and JH2-2. Our data are compatible with acquisition of intermediate-level gentamicin resistance by uptake impairment in E. faecalis.

Kanamycin acetyltransferase gene from kanamycin-producing Streptomyces kanamyceticus IFO 13414

A kanamycin producer, Streptomyces kanamyceticus IFO 13414 is highly resistant to kanamycin. Cloning of the kanamycin resistance genes in S. lividans 1326 with pIJ702 gave several kanamycin resistant transformants. Two transformants, S. lividans SNUS 90041 and S. lividans SNUS 91051 showed similar resistance patterns to various aminoglycoside antibiotics. Gene mapping experiments revealed that plasmids pSJ5030 and pSJ2131 isolated from the transformants have common resistant gene fragments. Subcloning of pSJ5030 gave a 1.8 Kb gene fragment which showed resistance to kanamycin. Cell free extracts of S. lividans SNUS 90041, S. lividans SNUS 91051 and subclone a S. lividans SNUS 91064 showed kanamycin acetyltransferase activity. The detailed gene map is included.

rRNA chemical groups required for aminoglycoside binding

Through an affinity chromatography based modification-interference assay, we have identified chemical groups within Escherichia coli 16S ribosomal RNA sequence that are required for binding the aminoglycoside antibiotic paromomycin. Paromomycin was covalently linked to solid support via a nine atom spacer from the 6"'-amine of ring IV, and chemical modifications to an A-site oligonucleotide that disrupted binding were identified. Positions in the RNA oligonucleotide that correspond to G1405(N7), G1491(N7), G1494(N7), A1408(N7), A1493(N7), A1408(N1), A1492(N1), and A1493(N1), as well as the pro-R phosphate oxygens of A1492 and A1493 in 16S rRNA are chemical groups that are essential for a high-affinity RNA-paromomycin interaction. These data are consistent with genetic, biochemical, and structural studies related to neomycin-class antibiotics and provide additional information for establishing an exact model for their interaction with the ribosome.

Mechanism of resistance to the antibiotic trichothecin in the producing fungi

Trichothecium roseum, an imperfecti fungus producer of the translation inhibitor trichothecin, is constitutively resistant to its product. Fusarium oxysporum, a fungi not described as a toxin producer, is sensitive to trichothecin but becomes resistant when grown in the presence of the drug. In both cases, the resistance occurs at the level of the ribosomes. In cell-free polypeptide polymerization systems, trichothecin resistance is associated with the presence of 60S subunits from the resistant organisms. Resistant ribosomes can be prepared in vitro by incubating sensitive ribosomes, from either non-induced F. oxysporum or Saccharomyces cerevisiae, with cell extracts from the resistant cells in the presence of S-adenosylmethionine. An in-vitro specific differential methylation is detected in the sensitive ribosomes but not in resistant particles using radioactive S-adenosylmethionine. The results indicate for the first time the existence in eukaryotic organisms of an antibiotic-resistance mechanism involving a ribosomal methylation similar to that described previously in prokaryotic systems.

In vitro measurement of translation accuracy of ribosomes isolated from streptomycin-resistant mutant of Streptomyces granaticolor

Accuracy of activity of ribosome isolated from UV-light-induced streptomycin-resistant R-21 mutant of Streptomyces granaticolor was measured in an E. coli-derived system translating poly(U) with a high rate and accuracy. Ribosomes from the R-21 mutant strain were shown to be resistant to streptomycin and about two-fold more accurate than those from the wild type. The mutant strain was found to be resistant to 1000 mg/L streptomycin (Stm) during vegetative growth while it sporulated on agar plates containing only up to 200 mg/L of Stm. The growth rate of the R-21 mutant in complex liquid medium was indistinguishable from that of the wild-type strain.

Cloning and characterization of an aminoglycoside resistance determinant from Micromonospora zionensis

The sisomicin-gentamicin resistance methylase (sgm) gene was isolated from Micromonospora zionensis and cloned in Streptomyces lividans. The sgm gene was expressed in Micromonospora melanosporea, where its own promoter was active, and also in Escherichia coli under the control of the lacZ promoter. The complete nucleotide sequence of 1,122 bp and a transcription start point were determined. The sequence contains an open reading frame that encodes a polypeptide of 274 amino acids. The methylation of 30S ribosomal subunits by Sgm methylase accounts adequately for all known resistance characteristics of M. zionensis, but expression of high-level resistance to hygromycin B is background dependent. A comparison of the amino acid sequence of the predicted Sgm protein with the deduced amino acid sequences for the 16S rRNA methylases showed extensive similarity of Grm and significant similarity to KgmB but not to KamB methylase.

Resistance to macrolides and lincosamides in Streptomyces lividans and to aminoglycosides in Micromonospora purpurea

Ribosomal (r) resistance to gentamicin in clones containing DNA from the producing organism Micromonospora purpurea is determined by grmA, and not by kgmA as originally reported. The kgmA gene originated in Streptomyces tenebrarius and is identical to kgmB. Both grmA and kgm encode enzymes that methylate single specific sites within 16S rRNA, although the site of action of the grmA product has not yet been determined. In either case, the methylated nucleoside is 7-methyl G. Inducible resistance to lincomycin (Ln) and macrolides in Streptomyces lividans TK21 results from expression of two genes: lrm, encoding an rRNA methyltransferase and mgt, encoding a glycosyl transferase (MGT), that specifically inactivates macrolides. The lrm product monomethylates residue A2058 within 23S rRNA (Escherichia coli numbering scheme) and confers high-level resistance to Ln with much lower levels of resistance to macrolides. Substrates for MGT, which utilises UDP-glucose as cofactor, include macrolides with 12-, 14-, 15- or 16-atom cyclic polyketide lactones (as in methymycin, erythromycin, azithromycin or tylosin, respectively) although spiramycin and carbomycin are not apparently modified. The enzyme is specific for the 2'-OH group of saccharide moieties attached to C5 of the 16-atom lactone ring (corresponding to C5 or C3 in 14- or 12-atom lactones, respectively). The lrm and mgt genes have been cloned and sequenced. The deduced lrm product is a 26-kDa protein, similar to other rRNA methyltransferases, such as the carB, tlrA and ermE products, whereas the mgt product (deduced to be 42 kDa) resembles a glycosyl transferase from barley.(ABSTRACT TRUNCATED AT 250 WORDS)

Analysis of a ribosomal RNA methylase gene from Streptomyces tenebrarius which confers resistance to gentamicin

Resistance to the aminoglycoside gentamicin in the nebramycin producer, Streptomyces tenebrarius, occurs at the level of the ribosome. A resistance determinant isolated from this actinomycete was previously shown to encode a methylase enzyme which modifies residue G-1405 of 16S ribosomal RNA. This gene (kgmB) has been sequenced and expressed in Escherichia coli using lacZ transcriptional signals since, like many other actinomycete genes, kgmB is not expressed in E. coli from its own promoter. The 5' end of the kgmB transcript has been mapped revealing a single promoter which does not obviously conform to the prokaryotic consensus.

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.

Cloning and characterization of gentamicin-resistance genes from Micromonospora purpurea and Micromonospora rosea

Aminoglycoside-resistance genes (grm) were cloned from a gentamicin producer Micromonospora purpurea and a sisomicin producer Micromonospora rosea. The nucleotide (nt) sequences of both genes were determined and the similarity between them was very high (90.4% identity). In either case, the transcription start point was localised to about 11 nt upstream from the likely translation start codons of grm, which is expressed as a polycistronic transcript. In studies to be reported elsewhere, it has been established that the M. purpurea grm gene encodes a ribosomal RNA methyltransferase. Here, we confirmed that the similarity of the two genes exists not only at the structural but also at the functional level.

Isolation and nucleotide sequencing of an aminocyclitol acetyltransferase gene from Streptomyces rimosus forma paromomycinus

A gene (aacC7) encoding an aminocyclitol 3-N-acetyltransferase type VII [AAC(3)-VII] from Streptomyces rimosus forma paramomycinus NRRL 2455 was cloned in the Streptomyces plasmid pIJ702 and expressed in Streptomyces lividans 1326. Subcloning experiments located the aacC7 structural gene on a 1.05-kilobase DNA sequence. The direction of transcription of aacC7 was determined by using riboprobes synthesized in vitro from a DNA fragment internal to the gene. A DNA segment encoding the AAC(3)-VII activity and comprising 1,495 base pairs was sequenced. The aacC7 gene was located in an open reading frame of 864 base pairs that encoded a polypeptide of Mr 31,070, consistent with the Mr (32,000) of the AAC(3)-VII enzyme as determined by physicochemical methods. High-resolution S1 nuclease mapping suggested that transcription starts at or near the A residue of the ATG initiator codon. A DNA fragment from the 5' region of aacC7 had promoter activity in the promoter-probe plasmid pIJ486. The -10 and -35 regions of this fragment showed limited sequence resemblance to other Streptomyces promoters. The primary structure of the AAC(3)-VII enzyme showed strong homology with those of the AAC(3)-III and AAC(3)-IV enzymes encoded by plasmids in gram-negative bacterial genera. Upstream of the aacC7 gene was an open reading frame of 357 nucleotides which did not appear to be involved in controlling the expression of the aacC7 gene.

RRP1, a Saccharomyces cerevisiae gene affecting rRNA processing and production of mature ribosomal subunits

The Saccharomyces cerevisiae mutant ts351 had been shown to affect processing of 27S pre-rRNA to mature 25S and 5.8S rRNAs (C. Andrew, A. K. Hopper, and B. D. Hall, Mol. Gen. Genet. 144:29-37, 1976). We showed that this strain contains two mutations leading to temperature-sensitive lethality. The rRNA-processing defect, however, is a result of only one of the two mutations. We designated the lesion responsible for the rRNA-processing defect rrp1 and showed that it is located on the right arm of chromosome IV either allelic to or tightly linked to mak21. This rrp1 lesion also results in hypersensitivity to aminoglycoside antibiotics and a reduced 25S/18S rRNA ratio at semipermissive temperatures. We cloned the RRP1 gene and provide evidence that it encodes a moderately abundant mRNA which is in lower abundance and larger than most mRNAs encoding ribosomal proteins.

Sites of action of two ribosomal RNA methylases responsible for resistance to aminoglycosides

Methylation of either of two residues (G-1405 or A-1408) within bacterial 16 S ribosomal RNA results in high level resistance to specific combinations of aminoglycoside antibiotics. The product of a gene that originated in Micromonospora purpurea (an actinomycete that produces gentamicin) gives resistance to kanamycin plus gentamicin by converting residue G-1405 to 7-methylguanosine. Resistance to kanamycin plus apramycin results from conversion of residue A-1408 to 1-methyladenosine catalysed by the product of a gene from Streptomyces tenjimariensis.

Construction and characterization of new cloning vectors derived from Streptomyces griseobrunneus plasmid pBT1 and containing amikacin and sulfomycin resistance genes

Three cryptic plasmids, designated pBT1 (5.6 kb), pBT2 (9.7 kb), and pBT3 (16.6 kb), were isolated from Streptomyces griseobrunneus ISP5066 and physically characterized. pBT1 and pBT2, which differ by a 4.1-kb segment, are high copy-number plasmids (40-100 copies per chromosome) that coexist with each other. pBT3 is a low copy-number plasmid. Vectors containing amikacin (or kanamycin) and sulfomycin (or thiostrepton) resistance genes from Streptomyces litmocidini ISP5164 and Streptomyces viridochromogenes subsp. sulfomycini ATCC 29776, respectively, were constructed from pBT1. One such vector, pBT37, has unique restriction sites for cloning, including BglII, XhoI, PvuII, ClaI, and SacI, with the PvuII and ClaI sites allowing clone recognition by insertional inactivation of sulfomycin resistance. Since many Streptomyces species were very sensitive to amikacin and sulfomycin, these resistance genes serve as useful selective markers. pBT37 could transform several Streptomyces strains that produce antibiotics such as tetracyclines, macrolides, beta-lactams, and aminoglycosides. This plasmid is a potentially useful vector for cloning antibiotic biosynthetic genes.

Methylation of 16S ribosomal RNA and resistance to the aminoglycoside antibiotics gentamicin and kanamycin determined by DNA from the gentamicin-producer, Micromonospora purpurea

When DNA fragments from Micromonospora purpurea (the producer of gentamicin) were cloned in Streptomyces lividans, a gentamicin-resistant strain was obtained in which the ribosomes were highly resistant both to gentamicin and to kanamycin. Reconstitution analysis revealed that such resistance resulted from some property of their 16S RNA. Extracts from the clone contained methylase activity which acted on 16S RNA within E. coli 30S ribosomal subunits and rendered them resistant to gentamicin and kanamycin.

Methylation of 16S ribosomal RNA and resistance to aminoglycoside antibiotics in clones of Streptomyces lividans carrying DNA from Streptomyces tenjimariensis

A single gene from Streptomyces tenjimariensis, conferring resistance to kanamycin, apramycin and sisomicin, has been cloned in Streptomyces lividans. The mechanism of resistance involves methylation of 16S RNA in the 30S ribosomal subunit.