Translational attenuation control of ermSF, an inducible resistance determinant encoding rRNA N-methyltransferase from Streptomyces fradiae

uORF-mediated riboregulation controls transcription of whiB7/wblC antibiotic resistance gene

WhiB7/WblC is a transcriptional factor of actinomycetes conferring intrinsic resistance to multiple translation-inhibitory antibiotics. It positively autoregulates its own transcription in response to the same antibiotics. The presence of a uORF and a potential Rho-independent transcription terminator in the 5' leader region has suggested a possibility that the whiB7/wblC gene is regulated via a uORF-mediated transcription attenuation. However, experimental evidence for the molecular mechanism to explain how antibiotic stress suppresses the attenuator, if any, and induces transcription of the whiB7/wblC gene has been lacking. Here we report that the 5' leader sequences of the whiB7/wblC genes in sub-clades of actinomycetes include conserved antiterminator RNA structures. We confirmed that the putative antiterminator in the whiB7/wblC leader sequences of both Streptomyces and Mycobacterium indeed suppresses Rho-independent transcription terminator and facilitates transcription readthrough, which is required for WhiB7/WblC-mediated antibiotic resistance. The antibiotic-mediated suppression of the attenuator can be recapitulated by amino acid starvation, indicating that translational inhibition of uORF by multiple signals is a key to induce whiB7/wblC expression. Our findings of a mechanism leading to intrinsic antibiotic resistance could provide an alternative to treat drug-resistant mycobacteria.

Translational Attenuation Mechanism of ErmB Induction by Erythromycin Is Dependent on Two Leader Peptides

Ribosome stalling on ermBL at the tenth codon (Asp) is believed to be a major mechanism of ermB induction by erythromycin (Ery). In this study, we demonstrated that the mechanism of ermB induction by Ery depends not only on ermBL expression but also on previously unreported ermBL2 expression. Introducing premature termination codons in ermBL, we proved that translation of the N-terminal region of ermBL is the key component for ermB induced by Ery, whereas translation of the C-terminal region of ermBL did not affect Ery-induced ermB. Mutation of the tenth codon (Asp10) of ermBL with other amino acids showed that the degree of induction in vivo was not completely consistent with the data from the in vitro toe printing assay. Alanine-scanning mutagenesis of ermBL demonstrated that both N-terminal residues (R7-K11) and the latter part of ermBL (K20-K27) are critical for Ery induction of ermB. The frameshifting reporter plasmid showed that a new leader peptide, ermBL2, exists in the ermB regulatory region. Further, introducing premature termination mutation and alanine-scanning mutagenesis of ermBL2 demonstrated that the N-terminus of ermBL2 is essential for induction by Ery. Therefore, the detailed function of ermBL2 requires further study.

Phylogenetic relatedness determined between antibiotic resistance and 16S rRNA genes in actinobacteria

BACKGROUND

Distribution and evolutionary history of resistance genes in environmental actinobacteria provide information on intensity of antibiosis and evolution of specific secondary metabolic pathways at a given site. To this day, actinobacteria producing biologically active compounds were isolated mostly from soil but only a limited range of soil environments were commonly sampled. Consequently, soil remains an unexplored environment in search for novel producers and related evolutionary questions.

RESULTS

Ninety actinobacteria strains isolated at contrasting soil sites were characterized phylogenetically by 16S rRNA gene, for presence of erm and ABC transporter resistance genes and antibiotic production. An analogous analysis was performed in silico with 246 and 31 strains from Integrated Microbial Genomes (JGI_IMG) database selected by the presence of ABC transporter genes and erm genes, respectively. In the isolates, distances of erm gene sequences were significantly correlated to phylogenetic distances based on 16S rRNA genes, while ABC transporter gene distances were not. The phylogenetic distance of isolates was significantly correlated to soil pH and organic matter content of isolation sites. In the analysis of JGI_IMG datasets the correlation between phylogeny of resistance genes and the strain phylogeny based on 16S rRNA genes or five housekeeping genes was observed for both the erm genes and ABC transporter genes in both actinobacteria and streptomycetes. However, in the analysis of sequences from genomes where both resistance genes occurred together the correlation was observed for both ABC transporter and erm genes in actinobacteria but in streptomycetes only in the erm gene.

CONCLUSIONS

The type of erm resistance gene sequences was influenced by linkage to 16S rRNA gene sequences and site characteristics. The phylogeny of ABC transporter gene was correlated to 16S rRNA genes mainly above the genus level. The results support the concept of new specific secondary metabolite scaffolds occurring more likely in taxonomically distant producers but suggest that the antibiotic selection of gene pools is also influenced by site conditions.

Programmed drug-dependent ribosome stalling

The ribosome has the intrinsic capacity to monitor the sequence and structure of the nascent peptide. This fundamental property of the ribosome is often exploited in regulation of gene expression, in particular, for activation of expression of genes conferring resistance to ribosome-targeting antibiotics. Induction of expression of these genes is controlled by the programmed stalling of the ribosome at a regulatory open reading frame located upstream of the resistance cistron. Formation of the stalled translation complex depends on the presence of an antibiotic in the ribosome exit tunnel and the sequence of the nascent peptide. In this review, we summarize our current understanding of the molecular mechanisms of drug- and nascent peptide-dependent ribosome stalling.

Macrolide resistance

The macrolides have evolved through four chemical generations since erythromycin became available for clinical use in 1952. The first generation, the 14-membered ring macrolide erythromycin, induced resistance and was replaced by the second generation 16-membered ring macrolides which did not. The inability to induce came at the price of mutation, in the pathogenic target strain, to constitutive expression of resistance. A third generation of macrolides improved the acid-stability, and therefore the pharmacokinetics of erythromycin, extending the clinical use of macrolides to Helicobacter pylori and Mycobacterium tuberculosis. Improved pharmacokinetics resulted in the selection of intrinsically resistant mutant strains with rRNA structural alterations. Expression of resistance in these strains was unexpected, explainable by low rRNA gene copy number which made resistance dominant. A fourth generation of macrolides, the 14-membered ring ketolides are the most recent development. Members of this generation are reported to be effective against inducibly resistant strains, and ketolide resistant strains have not yet been reported. In this review we discuss details of the ways in which bacteria have become resistant to the first three generations of macrolides, both with respect to their biochemistry, and the genetic mechanisms by which their expression is regulated.

Antibiotics and the ribosome

The ribosome is one of the main antibiotic targets in the cell. Recent years brought important insights into the mode of interaction of antibiotics with the ribosome and mechanisms of antibiotic action. Ribosome crystallography provided a detailed view of the interactions between antibiotics and rRNA. Advances in biochemical techniques let us better understand how the binding of small organic molecules can interfere with functions of an enzyme four orders of magnitude larger than the inhibitor. These and other achievements paved the way for the development of new ribosome-targeting antibiotics, some of which have already entered medical practice. The recent progress, problems and new directions of research of ribosome-targeting antibiotics are discussed in this review.

Development of recombinant Streptomyces for biotechnological and environmental uses

Recombinant DNA techniques for manipulation of genes in Streptomyces are well developed, and currently there is a high level of activity among researchers interested in applying molecular cloning and protoplast fusion techniques to strain development within this commercially important group of bacteria. A number of efficient plasmid and phage vector systems are being used for the molecular cloning of genes, primarily those encoding antibiotic biosynthesis enzymes, but also for a variety of other bioactive proteins and enzymes of known or potential commercial value. In addition, cloning aimed at constructing specialized bioconversion strains for use in the production of chemicals from organic carbon substrates is underway in numerous laboratories. This review discusses the current status of research involving recombinant DNA technologies applied to biotechnological applications using Streptomyces. The topic of potential environmental uses of recombinant Streptomyces is also reviewed, as is the status of current research aimed at assessing the fate and effects of recombinant Streptomyces in the environment. Also summarized is recent research that has confirmed that genetic exchange occurs readily among Streptomyces in the soil environment and which has shown the potential for exchange between recombinant Streptomyces and native soil bacteria.

Purification and biochemical characterization of the ErmSF macrolide-lincosamide-streptogramin B resistance factor protein expressed as a hexahistidine-tagged protein in Escherichia coli

The erm proteins confer resistance to the MLS (macrolide-lincosamide-streptogramin B) antibiotics in various microorganisms, including pathogens, through dimethylation of a single adenine residue (A2085: Bacillus subtilis coordinate) of the 23S rRNA to reduce the affinity of antibiotics, thereby enabling the cells to escape from the antibiotics' action, and this mechanism is predominantly adopted by microorganisms resistant to MLS antibiotics. ErmSF methyltransferase is one of the four gene products synthesized by Streptomyces fradiae NRRL 2338 to be resistant to its autogenous antibiotic, tylosin. In order to have a convenient source for the purification of milligram amounts, we expressed ErmSF in Escherichia coli using a T7 promoter-driven expression vector system, pET 23b, and the protein was expressed with a carboxy-terminal addition of six histidine residues in order to facilitate purification. Expression at 22 degrees C reduced the formation of insoluble aggregate, inclusion body, and resulted in accumulation of soluble hexahistidine-ErmSF up to 30% of total cell protein after 18 h. Metal-chelation chromatography yielded 126 mg of hexahistidine-ErmSF per liter of culture with a purity slightly greater than 95%. To examine the function of ErmSF in vivo and in vitro, its activity in E. coli (antibiotic susceptibility assay) andin vitro methyltransferase activity using in vitro-produced B. subtilis domain V, 434-, 257-, and 243-nt RNAs were investigated. The ErmSF in E. coli conferred resistance to erythromycin, whereas E. coli harboring an empty vector, pET23b, was susceptible. The purified recombinant protein successfully methylated domain V of 23S rRNA, which is known to contain all of the substrate elements recognized and to be methylated by erm proteins. However, the truncated substrates were methylated with decreased efficiencies. Almost all of domain V was monomethylated with less than 0.2 pM S-[methyl-(3)H]adenosylmethionine concentration. The roles of three structurally divided regions of domain V in recognition and methylation by ErmSF are proposed through kinetic studies using RNA substrates, in which each region is deleted, under the monomethylation condition.

The tylosin resistance gene tlrB of Streptomyces fradiae encodes a methyltransferase that targets G748 in 23S rRNA

tlrB is one of four resistance genes encoded in the operon for biosynthesis of the macrolide tylosin in antibiotic-producing strains of Streptomyces fradiae. Introduction of tlrB into Streptomyces lividans similarly confers tylosin resistance. Biochemical analysis of the rRNA from the two Streptomyces species indicates that in vivo TlrB modifies nucleotide G748 within helix 35 of 23S rRNA. Purified recombinant TlrB retains its activity and specificity in vitro and modifies G748 in 23S rRNA as well as in a 74 nucleotide RNA containing helix 35 and surrounding structures. Modification is dependent on the presence of the methyl group donor, S-adenosyl methionine. Analysis of the 74-mer RNA substrate by biochemical and mass spectrometric methods shows that TlrB adds a single methyl group to the base of G748. Homologues of TlrB in other bacteria have been revealed through database searches, indicating that TlrB is the first member to be described in a new subclass of rRNA methyltransferases that are implicated in macrolide drug resistance.

The macrolide-lincosamide-streptogramin B resistance determinant from Clostridium difficile 630 contains two erm(B) genes

The ErmB macrolide-lincosamide-streptogramin B (MLS) resistance determinant from Clostridium difficile 630 contains two copies of an erm(B) gene, separated by a 1.34-kb direct repeat also found in an Erm(B) determinant from Clostridium perfringens. In addition, both erm(B) genes are flanked by variants of the direct repeat sequence. This genetic arrangement is novel for an ErmB MLS resistance determinant.

Dispensable ribosomal resistance to spiramycin conferred by srmA in the spiramycin producer Streptomyces ambofaciens

Streptomyces ambofaciens produces the macrolide antibiotic spiramycin, an inhibitor of protein synthesis, and possesses multiple resistance mechanisms to the produced antibiotic. Several resistance determinants have been isolated from S. ambofaciens and studies with one of them, srmA, which hybridized with ermE (the erythromycin-resistance gene from Saccharopolyspora erythraea), are detailed here. The nucleotide sequence of srmA was determined and the mechanism by which its product confers resistance was characterized. The SrmA protein is a methyltransferase which introduces a single methyl group into A-2058 (Escherichia coli numbering scheme) in the large rRNA, thereby conferring an MLS (macrolide-lincosamide-streptogramin type B) type I resistance phenotype. A mutant of S. ambofaciens in which srmA was inactivated was viable and still produced spiramycin, indicating that srmA is dispensable, at least in the presence of the other resistance determinants.

Mechanisms of bacterial resistance to macrolide antibiotics

Macrolides have been used in the treatment of infectious diseases since the late 1950s. Since that time, a finding of antagonistic action between erythromycin and spiramycin in clinical isolates1 led to evidence of the biochemical mechanism and to the current understanding of inducible or constitutive resistance to macrolides mediated by erm genes containing, respectively, the functional regulation mechanism or constitutively mutated regulatory region. These resistant mechanisms to macrolides are recognized in clinically isolated bacteria. (1) A methylase encoded by the erm gene can transform an adenine residue at 2058 (Escherichia coli equivalent) position of 23S rRNA into an 6N, 6N-dimethyladenine. Position 2058 is known to reside either in peptidyltransferase or in the vicinity of the enzyme region of domain V. Dimethylation renders the ribosome resistant to macrolides (MLS). Moreover, another finding adduced as evidence is that a mutation in the domain plays an important role in MLS resistance: one of several mutations (transition and transversion) such as A2058G, A2058C or U, and A2059G, is usually associated with MLS resistance in a few genera of bacteria. (2) M (macrolide antibiotics)- and MS (macrolide and streptogramin type B antibiotics)- or PMS (partial macrolide and streptogramin type B antibiotics)-phenotype resistant bacteria cause decreased accumulation of macrolides, occasionally including streptogramin type B antibiotics. The decreased accumulation, probably via enhanced efflux, is usually inferred from two findings: (i) the extent of the accumulated drug in a resistant cell increases as much as that in a susceptible cell in the presence of an uncoupling agent such as carbonylcyanide-m-chlorophenylhydrazone (CCCP), 2,4-dinitrophenol (DNP), and arsenate; (ii) transporter proteins, in M-type resistants, have mutual similarity to the 12-transmembrane domain present in efflux protein driven by proton-motive force, and in MS- or PMS-type resistants, transporter proteins have mutual homology to one or two ATP-binding segments in efflux protein driven by ATP. (3) Two major macrolide mechanisms based on antibiotic inactivation are dealt with here: degradation due to hydrolysis of the macrolide lactone ring by an esterase encoded by the ere gene; and modification due to macrolide phosphorylation and lincosamide nucleotidylation mediated by the mph and lin genes, respectively. But enzymatic mechanisms that hydrolyze or modify macrolide and lincosamide antibiotics appear to be relatively rare in clinically isolated bacteria at present. (4) Important developments in macrolide antibiotics are briefly featured. On the basis of information obtained from extensive references and studies of resistance mechanisms to macrolide antibiotics, the mode of action of the drugs, as effectors, and a hypothetical explanation of the regulation of the mechanism with regard to induction of macrolide resistance are discussed.

Essential role of endogenously synthesized tylosin for induction of ermSF in Streptomyces fradiae

We compared ermSF induction in wild-type Streptomyces fradiae NRRL B-2702 and that in GS-14, a tylA mutant which cannot synthesize tylosin. Our findings suggest that (i) endogenously synthesized tylosin plays an obligatory role in ermSF induction and (ii) tylosin, or a biosynthetic intermediate beyond tylactone, has an "autocrine" function that induces ErmSF synthesis, thereby enabling S. fradiae to resist higher levels of tylosin.

Induction of ermSV by 16-membered-ring macrolide antibiotics

The erm family of 23S rRNA adenine-N6-methyltransferases confers resistance to all macrolide-lincosamide-streptograminB (MLS) antibiotics, but not all MLS antibiotics induce synthesis of Erm methyltransferase with equal efficiency in a given organism. The induction efficiency of a test panel of MLS antibiotics was studied by using two translational attenuator-lac reporter gene fusion constructs, one based on ermSV from Streptomyces viridochromogenes NRRL 2860 and the other based on ermC from Staphylococcus aureus RN2442. Four types of responses which were correlated with the macrolide ring size were seen, as follows: group 1, both ermSV and ermC were induced by the 14-membered-ring macrolides erythromycin, lankamycin, and matromycin, as well as by the lincosamide celesticetin; group 2, neither ermSV nor ermC was induced by the 12-membered-ring macrolide methymycin or by the lincosamide lincomycin or the streptogramin type B antibiotic ostreogrycin B; group 3, ermSV was selectively induced over ermC by the 16-membered-ring macrolides carbomycin, chalcomycin, cirramycin, kitasamycin, maridomycin, and tylosin; and group 4, ermC was selectively induced over ermSV by the 14-membered-ring macrolide megalomicin. These data suggest that the leader peptide determines the specificity of induction by different classes of MLS antibiotics and that for a given attenuator, a major factor which determines whether a given macrolide induces resistance is its size.

Molecular analysis of tlrD, an MLS resistance determinant from the tylosin producer, Streptomyces fradiae

The macrolide antibiotic, tylosin (Ty), is produced by Streptomyces fradiae. Two resistance determinants (tlrA, synonym ermSF, and tlrD) conferring resistance to macrolide, lincosamide and streptogramin B type (MLS) antibiotics were previously isolated from this strain, and their products shown to methylate 23S ribosomal RNA (rRNA) at a common site, thereby rendering the ribosomes MLS resistant. However, the TlrA and TlrD proteins differ in their action; the former dimethylates, and the latter monomethylates, the target nucleotide. Here, 2.2 kb of DNA from the tylLM region of the tylosin biosynthetic gene cluster of S. fradiae has been sequenced and shown to encompass tlrD. Comparison of the sequences of tlrA and tlrD (and of their deduced products) with those of related ('erm-type') genes from other actinomycetes suggests that the combined presence of tlrA and tlrD in S. fradiae is not the result of recent gene duplication.

Conservation of the C5a peptidase genes in group A and B streptococci

The chromosome of group B streptococci (GBS) contains a gene which is related to the C5a peptidase gene (scpA) of group A streptococci (GAS). scpA encodes a surface-associated peptidase (group A streptococcal C5a peptidase [SCPA]) which specifically cleaves C5a, a major chemoattractant generated in serum by activation of complement. The entire scpA-like gene (scpB) was cloned from a GBS strain and sequenced. The gene encodes an open reading frame of 3,450 bp, which corresponds to a deduced protein (SCPB) of 1,150 amino acids with a molecular weight of 126,237 Da. Nucleotide and deduced amino acid sequences of SCPB were found to be highly homologous to those of SCPAs from GAS. Unexpectedly, scpA12 is more similar to scpB than to another GAS gene, scpA49. The sequence 5' of the open reading frame, including transcription start and a termination site in the signal sequence, is also similar to that of scpA, although less conserved than the coding sequences. The near identity of GBS and GAS peptidases is consistent with horizontal transmission of the scp gene between these species. Recombinant SCPB was expressed in Escherichia coli by using the expression vector plasmid pGEX-4T-1 and was shown to be identical in size to the enzyme extracted from the parental GBS strain 78-471.

The macrolide-lincosamide-streptogramin B resistance phenotypes characterized by using a specifically deleted, antibiotic-sensitive strain of Streptomyces lividans

Genes conferring resistance to macrolide, lincosamide, and streptogramin B (MLS) antibiotics via ribosomal modification are widespread in bacteria, including clinical isolates and MLS-producing actinomycetes. Such erm-type genes encode enzymes that mono- or dimethylate residue A-2058 of 23S rRNA. The different phenotypes resulting from monomethylation (MLS-I phenotype, conferred by erm type I genes) or dimethylation (MLS-II phenotype due to erm type II genes) have been characterized by introducing tlrD or ermE, respectively, into an MLS-sensitive derivative of Streptomyces lividans TK21. This strain (designated OS456) was generated by specific replacement of the endogenous resistance genes lrm and mgt. The MLS-I phenotype is characterized by high-level resistance to lincomycin with only marginal resistance to macrolides such as chalcomycin or tylosin, whereas the MLS-II phenotype involves high-level resistance to all MLS drugs. Mono- and dimethylated ribosomes were introduced into a cell-free protein-synthesizing system prepared from S. lividans and compared with unmodified particles in their response to antibiotics. There was no simple correlation between the relative potencies of MLS drugs at the level of the target site (i.e., the ribosome) and their antibacterial activities expressed as MICs.

Transcriptional attenuation control of the tylosin-resistance gene tlrA in Streptomyces fradiae

The tylosin producer Streptomyces fradiae contains four known resistance genes, two of which (tlrA and tlrD) encode methyltransferases that act on ribosomal RNA at a common site. Expression of tlrA is regulated via transcriptional attenuation. A short transcript, only 411 nucleotides long, terminates 27 nucleotides into the methylase-coding sequence in the uninduced state. Induction of tlrA is proposed to involve a ribosome-mediated conformational change within the mRNA leader that allows transcription to continue beyond the attenuation site, resulting in a transcript about 1450 nucleotides long. Transplantation of tlrD and/or tlrA into Streptomyces albus revealed that the induction specificity of tlrA depends upon the state of the ribosomes and is significantly altered in strains also expressing tlrD.

23S rRNA domain V, a fragment that can be specifically methylated in vitro by the ErmSF (TlrA) methyltransferase

The DNA sequence that encodes 23S rRNA domain V of Bacillus subtilis, nucleotides 2036 to 2672 (C. J. Green, G. C. Stewart, M. A. Hollis, B. S. Vold, and K. F. Bott, Gene 37:261-266, 1985), was cloned and used as a template from which to transcribe defined domain V RNA in vitro. The RNA transcripts served as a substrate in vitro for specific methylation of B. subtilis adenine 2085 (adenine 2058 in Escherichia coli 23S rRNA) by the ErmSF methyltransferase, an enzyme that confers resistance to the macrolide-lincosamide-streptogramin B group of antibiotics on Streptomyces fradiae NRRL 2702, the host from which it was cloned. Thus, neither RNA sequences belonging to domains other than V nor the association of 23S rRNA with ribosomal proteins is needed for the specific methylation of adenine that confers resistance to the macrolide-lincosamide-streptogramin B group of antibiotics.

Cloning and sequences of two macrolide-resistance-encoding genes from mycinamicin-producing Micromonospora griseorubida

Two macrolide-resistance determinants were cloned from a mycinamicin (Mm)-producing Micromonospora griseorubida strain in Streptomyces lividans and Streptomyces parvulus. One of the cloned genes, designated myrA, was cloned as a gene which conferred strong resistance to Mm and tylosin (Ty), but not to erythromycin (Er) or josamycin (Jm) on S. lividans. Another gene, named myrB, was cloned as an ErR-encoding gene which conferred MLS resistance (to macrolide, lincosamide and streptogramine B antibiotics) on S. parvulus. Both myrA and myrB were sequenced and the corresponding ORFs were determined. The deduced amino acid (aa) sequence of myrA showed no similarity to proteins in the available databases, suggesting that an unknown mechanism of macrolide resistance is exerted by the MyrA protein. The deduced aa sequence of myrB exhibited high similarity to 23S rRNA methyltransferases (MTases), such as ErmE and CarB, from a variety of microorganisms.

Antibiotic preparations contain DNA: a source of drug resistance genes?

Fluorescence measurements and polymerase chain reaction amplification of streptomycete 16S ribosomal DNA sequences were used to show that a number of antibiotic preparations employed for human and animal use are contaminated with chromosomal DNA of the antibiotic-producing organism. The DNA contains identifiable antibiotic resistance gene sequences; the uptake of this DNA by bacteria and its functional incorporation into bacterial replicons would lead to the generation of antibiotic resistance determinants. We propose that the presence of DNA encoding drug resistance in antibiotic preparations has been a factor in the rapid development of multiple antibiotic resistance in bacteria.

Identification of nodSUIJ genes in Nod locus 1 of Azorhizobium caulinodans: evidence that nodS encodes a methyltransferase involved in Nod factor modification

The Azorhizobium caulinodans strain ORS571 nodulation genes nodSUIJ were located downstream from nodABC. Complementation data and transcriptional analysis suggest that nodABCSUIJ form a single operon. Mutants with Tn5 insertions in the genes nodS, nodU, and nodJ were delayed in nodulation of Sesbania rostrata roots and stems. The NodS amino acid sequences of ORS571, Bradyrhizobium japonicum, and Rhizobium sp. strain NGR234, contain a consensus with similarity to S-adenosylmethionine (SAM)-utilizing methyltransferases. A naringenin-inducible nodS-dependent protein of approximately 25 kDa could be cross-linked to radiolabelled SAM. By applying L-[methyl-3H]-methionine in vivo, Nod factors of ORS571, known to be N-methylated, could be labelled in wild type and nodU mutants but not in nodS mutants. Therefore, we propose that NodS is a SAM-utilizing methyltransferase involved in Nod factor synthesis.

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)

The Streptomyces glaucescens TcmR protein represses transcription of the divergently oriented tcmR and tcmA genes by binding to an intergenic operator region

Preliminary evidence has been presented by Guilfoile and Hutchinson (J. Bacteriol. 174:3651-3658, 1992) suggesting that the Streptomyces glaucescens TcmR protein is a transcriptional repressor. Here, we extend that work by showing that transcription of the S. glaucescens tcmA gene is inducible by tetracenomycin C and that inactivation of the tcmR gene results in constitutive transcription of the tcmA gene. Gel retardation studies show that the TcmR protein binds to the tcmA-tcmR intergenic region in vitro and that this binding is inhibited by tetracenomycin C. Footprinting experiments demonstrate that the TcmR protein binds to an operator region that encompasses both the tcmA and the tcmR promoters. This genetic and biochemical evidence strongly supports the model of the TcmR protein acting as a repressor in inhibiting transcription of both the tcmA and the tcmR genes, in much the same way that TetR from Tn10 inhibits transcription of tetA and tetR.

Compilation and analysis of DNA sequences associated with apparent streptomycete promoters

The DNA sequences associated with 139 apparent streptomycete transcriptional start sites are compiled and compared. Of these, 29 promoters appeared to belong to a group which are similar to those recognized by eubacterial RNA polymerases containing sigma 70-like subunits. The other 110 putative promoter regions contain a wide diversity of sequences; several of these promoters have obvious sequence similarities in the -10 and/or -35 regions. The apparent Shine-Dalgarno regions of 44 streptomycete genes are also examined and compared. These were found to have a wide range of degree of complementarity to the 3' end of streptomycete 16S rRNA. Eleven streptomycete genes are described and compared in which transcription and translation are proposed to be initiated from the same or nearby nucleotide. An updated consensus sequence for the E sigma 70-like promoters is proposed and a potential group of promoter sequences containing guanine-rich -35 regions also is identified.

Cloning and characterization of two genes from Streptomyces lividans that confer inducible resistance to lincomycin and macrolide antibiotics

Inducible resistance to lincomycin and macrolides in Streptomyces lividans TK21 results from expression of two linked genes: lrm, encoding a ribosomal RNA methyltransferase that confers high-level resistance to lincomycin with lower levels of resistance to macrolides, and mgt, encoding a glycosyl transferase that specifically inactivates macrolides using UDP-glucose as cofactor. The lrm and mgt genes have been cloned and sequenced. The deduced lrm product is a 26-kDa protein with much similarity to other ribosomal RNA methyltransferases, such as the carB, tlrA and ermE products, whereas the mgt product (predicted to be 42 kDa) resembles a eukaryotic glycosyl transferase. Macrolides that induce the lrm-mgt gene pair are substrates for inactivation by the mgt product, and the lrm product confers ribosomal resistance to such inducers.

Cloning vectors, mutagenesis, and gene disruption (ermR) for the erythromycin-producing bacterium Aeromicrobium erythreum

Genetic systems for study of Aeromicrobium erythreum, a gram-positive, G + C-rich (72%) bacterium with the capacity for erythromycin biosynthesis, are described. High-copy-number plasmids suitable as gene cloning vectors include derivatives of the Streptomyces plasmids pIJ101, pVE1, and pJV1. pIJ101 derivatives with missense substitutions at the rep gene BamHI site do not replicate in A. erythreum. Ethyl methanesulfonate treatment generated several amino acid auxotrophs and non-erythromycin-producing (Ery-) strains. Using the Ery- strain AR1807 as a recipient for plasmid-directed integrative recombination, the chromosomal ermR gene (encoding 23S rRNA methyltransferase) was disrupted. Phenotypic characterizations demonstrated that ermR is the sole determinant of macrolide antibiotic resistance in A. erythreum.

Transcriptional attenuation control of ermK, a macrolide-lincosamide-streptogramin B resistance determinant from Bacillus licheniformis

ermK instructs bacteria to synthesize an erythromycin-inducible 23S rRNA methylase that confers resistance to the macrolide, lincosamide, and streptogramin B antibiotics. Expression of ermK is regulated by transcriptional attenuation, in contrast to other inducible erm genes, previously described, which are regulated translationally. The ermK mRNA leader sequence has a total length of 357 nucleotides and encodes a 14-amino-acid leader peptide together with its ribosome binding site. Additionally, the mRNA leader sequence can fold in either of two mutually exclusive conformations, one of which is postulated to form in the absence of induction and to contain two rho factor-independent terminators. Truncated transcription products ca. 210 and 333 nucleotides long were synthesized in the absence of induction, both in vivo and in vitro, as predicted by the transcriptional attenuation model; run-off transcription in vitro with rITP favored the synthesis of the full-length run-off transcript over that of the 210- and 333-nucleotide truncated products. Northern (RNA) blot analysis of transcripts synthesized in vivo in the absence of erythromycin indicated that transcription terminated at either of the two inverted complementary repeat sequences in the leader that were postulated to serve as rho factor-independent terminators; moreover, no full-length transcripts were detectable in the uninduced samples. In contrast, full-length (ca. 1,200-nucleotide) transcripts were only detected in RNA samples synthesized in vivo in the presence of erythromycin. Full-length transcripts formed in the absence of induction from transcriptional readthrough past the two proposed transcription terminators would fold in a way that would sequester the ribosome binding site together with the first two codons of the ErmK methylase, reducing its efficiency in translation. This feature could therefore provide additional control of expression in the absence of induction; however, such regulation, if operative, would act only secondarily, both in time and place, relative to transcriptional control. Analysis by reverse transcriptase mapping of in vivo transcripts from two primers that bracket the transcription terminator responsible for the 210-nucleotide truncated fragment supports the transcriptional attenuation model proposed and suggests further that the synthesis of the ermK message is initiated constitutively upstream of the proposed terminator but completed inductively downstream of this site.

Homology between proteins controlling Streptomyces fradiae tylosin resistance and ATP-binding transport

A tylosin(Ty)-producing strain of Streptomyces fradiae contains at least three genes, tlrA, tlrB, tlrC, specifying resistance to Ty (TyR). The complete nucleotide sequence of the TyR-encoding gene, tlrC, and the transcription start point of the gene were determined. The sequence contains an open reading frame coding for a protein of 548 amino acids (aa) with an Mr of 59129. The TlrC protein was identified by expression of the cloned gene by in vitro coupled transcription and translation in cell-free extracts derived from Streptomyces lividans. The N- and C-terminal halves of TlrC share extensive homology, suggesting that the protein evolved through tandem gene duplication. Each half of the deduced TlrC aa sequence also shows significant homology to numerous eukaryotic and prokaryotic membrane-associated, active-transport protein subunits. The homologous proteins include examples from the systems responsible for efflux of cytotoxic drugs from multidrug-resistant human cells and for export of hemolysin from Escherichia coli. The greatest similarity to TlrC is in regions containing the ATP-binding sites found in these proteins. These results suggest a role for the tlrC gene product as part of a multiple component, ATP-dependent transport system for the active excretion of Ty from the producing organism.

Cloning of tlrD, a fourth resistance gene, from the tylosin producer, Streptomyces fradiae

In addition to tlrA, tlrB and tlrC, which were previously cloned by others, a fourth antibiotic-resistance gene (tlrD) has been isolated from Streptomyces fradiae, a producer of tylosin (Ty), and cloned in Streptomyces lividans. Like tlrA, tlrD encodes an enzyme that methylates the N6-amino group of the A2058 nucleoside within 23S ribosomal RNA. However, whereas the tlrA protein dimethylates that nucleoside, the tlrD product generates N6-monomethyladenosine. The genes also differ in their mode of expression: tlrA is inducible, whereas tlrD is apparently expressed constitutively, and it has been confirmed that the tlrA-encoded enzyme can add a second methyl group to 23S rRNA that has already been monomethylated by the tlrD-encoded enzyme. Presumably, that is what happens in S. fradiae.

The ermC leader peptide: amino acid alterations leading to differential efficiency of induction by macrolide-lincosamide-streptogramin B antibiotics

The inducibility of ermC by erythromycin, megalomicin, and celesticetin was tested with both wild-type ermC and several regulatory mutants altered in the 19-amino-acid-residue leader peptide, MGIFSIFVISTVHYQP NKK. In the model test system that was used, the ErmC methylase was translationally fused to beta-galactosidase. Mutational alterations that mapped in the interval encoding Phe-4 through Ile-9 of the leader peptide not only affected induction by individual antibiotics, but did so differentially. The subset of mutations that affected inducibility by the two macrolides erythromycin and megalomicin overlapped and were distinct from the subset of mutations that affected induction by celesticetin. These studies provide a model system for experimentally varying the relative efficiencies with which different antibiotics induce the expression of ermC. The possibility that antibiotics with inducing activity interact directly with the nascent leader peptide was tested by using a chemically synthesized decapeptide, MGIFSIFVIS--, attached at its C-terminus to a solid-phase support. This peptide, however, failed to bind erythromycin in vitro.

A repeated decapeptide motif in the C-terminal domain of the ribosomal RNA methyltransferase from the erythromycin producer Saccharopolyspora erythraea

Re-analysis of the primary structure of the ribosomal RNA N-methyltransferase that confers self-resistance on the erythromycin-producing bacterium Saccharopolyspora erythraea has confirmed the presence of a C-terminal domain containing extensive repeat sequences. Nine tandem repeats can be discerned, with a decapeptide consensus sequence GGRx(H/R)GDRRT, although no single residue is wholly invariant. This highly polar, potentially flexible domain, which is predicted to adopt either a random coil or a structure with beta turns, has a counterpart in the erythromycin methyltransferase of an erythromycin-producing species of Arthrobacter. It also significantly resembles a portion of the C-terminal region of the eukaryotic protein nucleolin, which is unusually rich in dimethylarginine and glycine, and which is also predicted to behave as a random coil in solution. This resemblance, despite the very different roles of these proteins in ribosome biogenesis, strengthens the idea that in both rRNA methyltransferases and nucleolin these C-terminal sequences might contribute to rRNA binding.

Methylation of 23S rRNA caused by tlrA (ermSF), a tylosin resistance determinant from Streptomyces fradiae

Ribosomes from Streptomyces griseofuscus expressing tlrA, a resistance gene isolated from the tylosin producer Streptomyces fradiae, are resistant to macrolide and lincosamide antibiotics in vitro. The tlrA product was found to be a methylase that introduces two methyl groups into a single base within 23S rRNA, generating N6,N6-dimethyladenine at position 2058. This activity is therefore similar to the ermE resistance mechanism in Saccharopolyspora erythraea (formerly Streptomyces erythraeus).