Streptomycin inhibits splicing of group I introns by competition with the guanosine substrate.

Streptomycin is an aminocyclitol glycoside antibiotic, which interferes with prokaryotic protein synthesis by interacting with the ribosomal RNA. We report here that streptomycin is also able to inhibit self splicing of the group I intron of the thymidylate synthase gene of phage T4. The inhibition is kinetically competitive with the substrate guanosine. Streptomycin and guanosine have in common a guanidino group, which has been shown to undergo hydrogen bonds with the ribozyme (Bass & Cech, Biochemistry, 25, 1986, 4473). The inhibitory effect of streptomycin extends to other group I introns, but does not affect group II introns. Mutating the bulged nucleotide in the conserved P7 secondary structure element of the td intron alters the affinity of the ribozyme for both guanosine and streptomycin. Myomycin, an antibiotic with similar effects on protein synthesis as streptomycin, is also able to inhibit splicing. In contrast, bluensomycin, which is structurally related to streptomycin, but contains only one guanidino group does not inhibit splicing. We discuss these findings in support of an evolutionary model that stresses the antiquity of antibiotics (J. Davies, Molecular Microbiology 4, 1990, 1227).     

Interaction of streptidin-dependent Actinomyces streptomycini (Streptomyces griseus) mutants No. 170 and 145 with mutants having blocks at various stages of streptomycin biosynthesis]

In complementation analysis of low active streptidine dependent strains of Act. streptomycini, 170 and 145 with mutants having different blocks in biosynthesis of streptomycin it was found that these strains were the donors of some thermostable substances and could reduce the biosynthesis of streptomycin in the mutants having impairements in biosynthesis of streptidine and streptobiosamine, as well as in a number of strains with unknown blocks. It is supposed that the substances produced by mutants 170 and 145 were intermediate products in streptomycin biosynthesis.     

Self-cloning in Streptomyces griseus of an str gene cluster for streptomycin biosynthesis and streptomycin resistance.

An str gene cluster containing at least four genes (strR, strA, strB, and strC) involved in streptomycin biosynthesis or streptomycin resistance or both was self-cloned in Streptomyces griseus by using plasmid pOA154. The strA gene was verified to encode streptomycin 6-phosphotransferase, a streptomycin resistance factor in S. griseus, by examining the gene product expressed in Escherichia coli. The other three genes were determined by complementation tests with streptomycin-nonproducing mutants whose biochemical lesions were clearly identified. strR complemented streptomycin-sensitive mutant SM196 which exhibited impaired activity of both streptomycin 6-phosphotransferase and amidinotransferase (one of the streptomycin biosynthetic enzymes) due to a regulatory mutation; strB complemented strain SD141, which was specifically deficient in amidinotransferase; and strC complemented strain SD245, which was deficient in linkage between streptidine 6-phosphate and dihydrostreptose. By deletion analysis of plasmids with appropriate restriction endonucleases, the order of the four genes was determined to be strR-strA-strB-strC. Transformation of S. griseus with plasmids carrying both strR and strB genes enhanced amidinotransferase activity in the transformed cells. Based on the gene dosage effect and the biological characteristics of the mutants complemented by strR and strB, it was concluded that strB encodes amidinotransferase and strR encodes a positive effector required for the full expression of strA and strB genes. Furthermore, it was found that amplification of a specific 0.7-kilobase region of the cloned DNA on a plasmid inhibited streptomycin biosynthesis of the transformants. This DNA region might contain a regulatory apparatus that participates in the control of streptomycin biosynthesis.     

In vitro selection and characterization of streptomycin-binding RNAs: recognition discrimination between antibiotics.

As pathogens continue to evade therapeutical drugs, a better understanding of the mode of action of antibiotics continues to have high importance. A growing body of evidence points to RNA as a crucial target for antibacterial and antiviral drugs. For example, the aminocyclitol antibiotic streptomycin interacts with the 16S ribosomal RNA and, in addition, inhibits group I intron splicing. To understand the mode of binding of streptomycin to RNA, we isolated small, streptomycin-binding RNA aptamers via in vitro selection. In addition, bluensomycin, a streptomycin analogue that does not inhibit splicing, was used in a counter-selection to obtain RNAs that bind streptomycin with high affinity and specificity. Although an RNA from the normal selection (motif 2) bound both antibiotics, an RNA from the counter-selection (motif 1) discriminated between streptomycin and bluensomycin by four orders of magnitude. The binding site of streptomycin on the RNAs was determined via chemical probing with dimethylsulfate and kethoxal. The minimal size required for drug binding was a 46- and a 41-mer RNA for motifs 1 and 2, respectively. Using Pb2+ cleavage in the presence and absence of streptomycin, a conformational change spanning the entire mapped sequence length of motif 1 was observed only when both streptomycin and Mg2+ were present. Both RNAs require Mg2+ for binding streptomycin.     

Identification of stsC, the gene encoding the l-glutamine:scyllo-inosose aminotransferase from streptomycin-producing Streptomycetes

Eight new genes, strO-stsABCDEFG, were identified by sequencing DNA in the gene cluster that encodes proteins for streptomycin production of Streptomyces griseus N2-3-11. The StsA (calculated molecular mass 43.5 kDa) and StsC (45.5 kDa) proteins – together with another gene product, StrS (39.8 kDa), encoded in another operon of the same gene cluster – show significant sequence identity and are members of a new class of pyridoxal-phosphate-dependent aminotransferases that have been observed mainly in the biosynthetic pathways for secondary metabolites. The aminotransferase activity was demonstrated for the first time by identification of the overproduced and purified StsC protein as the l-glutamine:scyllo-inosose aminotransferase, which catalyzes the first amino transfer in the biosynthesis of the streptidine subunit of streptomycin. The stsC and stsA genes each hybridized specifically to distinct fragments in the genomic DNA of most actinomycetes tested that produce diaminocyclitolaminoglycosides. In contrast, only stsC, but not stsA, hybridized to the DNA of Streptomyces hygroscopicus ssp. glebosus, which produces the monoaminocyclitol antibiotic bluensomycin; this suggests that both genes are specifically used in the first and second steps of the cyclitol transamination reactions. Sequence comparison studies performed with the deduced polypeptides of the genes adjacent to stsC suggest that the enzymes encoded by some of these genes [strO (putative phosphatase gene), stsB (putative oxidoreductase gene), and stsE (putative phosphotransferase gene)] also could be involved in (di-)aminocyclitol synthesis. Received: 7 January 1997 / Accepted: 24 March 1997     

An approach for cloning biosynthetic genes of 2-deoxystreptamine-containing aminocyclitol antibiotics: isolation of a biosynthetic gene cluster of tobramycin from Streptomyces tenebrarius

Genes homologous to 2-deoxystreptamine (DOS) biosynthetic genes were isolated from aminoglycoside producers, Micromonospora and Streptomyces spp., using PCR primers based on the core sequences of 2-deoxy-scyllo-inosose (DOI) synthase and L-glutamine: scyllo-inosose aminotransferase (GIA). Identities of 40-45% were observed for DOI synthases, and 65-75% were observed for GIAs. The gene cluster of tobramycin biosynthesis was isolated from the genomic library of Streptomyces tenebrarius using DOI synthase as a probe. Sequencing of 33.9 kb revealed 24 putative open reading frames including the tobramycin biosynthetic gene cluster (13.8 kb) and a transport protein. This cluster encodes proteins homologous to 2-deoxystreptamine biosynthetic enzymes, glycosyltransferase and other aminocyclitols biosynthetic enzymes. Sequence analysis revealed the evolution of DOI synthases from 3-dehydroquinate (DHQ) synthases in actinomycetes. DOI synthases and GIA are therefore useful for cloning biosynthetic genes of DOS-containing aminocyclitol antibiotics or for screening such metabolites producers.     

Preliminary studies on streptomutin A

Summary Supplementation of the culture medium with 2-deoxystreptidine allowsStreptomyces griseus MIT-5, an idiotrophic mutant, to produce an antibiotic which we have called streptomutin A. Degradation studies on the antibiotic showed that the aminocyclitol moiety is different from streptidine. Streptomutin A also is distinct from streptomycin in having a much different ratio of biological to chemical activity.This paper is Contribution No. 2746 from the Department of Nutrition and Food Science, Massachusetts Institute of Technology, Cambridge, Massachusetts 02139, U.S.A.     

Coevolution of antibiotic production and counter‐resistance in soil bacteria

We present evidence for the coexistence and coevolution of antibiotic resistance and biosynthesis genes in soil bacteria. The distribution of the streptomycin (strA) and viomycin (vph) resistance genes was examined in Streptomyces isolates. strA and vph were found either within a biosynthetic gene cluster or independently. Streptomyces griseus strains possessing the streptomycin cluster formed part of a clonal complex. All S. griseus strains possessing solely strA belonged to two clades; both were closely related to the streptomycin producers. Other more distantly related S. griseus strains did not contain strA. S. griseus strains with only vph also formed two clades, but they were more distantly related to the producers and to one another. The expression of the strA gene was constitutive in a resistance‐only strain whereas streptomycin producers showed peak strA expression in late log phase that correlates with the switch on of streptomycin biosynthesis. While there is evidence that antibiotics have diverse roles in nature, our data clearly support the coevolution of resistance in the presence of antibiotic biosynthetic capability within closely related soil dwelling bacteria. This reinforces the view that, for some antibiotics at least, the primary role is one of antibiosis during competition in soil for resources.     

Streptomycin biosynthesis in Streptomyces griseus I. Characterization of streptomycin-idiotrophic mutants

Abstract A total of 16 idiotrophic mutants unable to produce the aminoglycoside antibiotic streptomycin ( smi ) were isolated from Streptomyces griseus N2-3-11. Cosynthesis of streptomycin, its formation from various precursors and analysis of accumulated intermediates allowed grouping of the mutants in 3 classes, blocked: (I) in the first transamination step of the streptidine pathway; (II) in later steps of the streptidine pathway; or (III) outside streptidine biosynthesis.     

Isolation and characterization of bluensomycin biosynthetic genes from Streptomyces bluensis

The biosynthetic gene cluster for bluensomycin, a member of the aminoglycoside family of antibiotics, was isolated and characterized from the bluensomycin producing strain, Streptomyces bluensis ATCC27420. PCR primers were designed specifically to amplify a segment of the dTDP-glucose synthase gene based on its conserved sequences among several actinomycete strains. By screening a cosmid library using amplified PCR fragments, a 30-kb DNA fragment was isolated. Sequence analysis identified 15 open reading frames (ORFs), eight of which had previously been identified by Piepersberg et al. But seven are novel to this study. We demonstrated that one of these ORFs, blmA, confers resistance against the antibiotic dihydrostreptomycin, and another, blmD, encodes a dTDP-glucose synthase. These findings suggest that the isolated gene cluster is very likely to be responsible for the biosynthesis of bluensomycin.     

Vestibular histofluorescence could be due to accumulation of both the antibiotic and its derivative, streptidine, after acute streptomycin treatment in the guinea pig

Acute treatment with 300 mg/kg of pigmented guinea pigs with streptomycin sulfate induces an elevation of endogenous fluorescence in vestibular ampullary cristae. Fluorescence accumulates in all compartments of the epithelium, i.e., vestibular sensory and supporting cells and nerve fibers of the stroma and it was very intense 1 and 12 hours after its administration. Fluorescence decreased to control levels 24 hours following streptomycin injection. Fluorescence levels were very low either in untreated animals or in animals injected with saline physiological solution. To investigate whether this fluorescence was an intrinsic property of the antibiotic or whether it was due to a derivative of it, or both, an in vitro fluorescence spectrum was performed with 100 microM solutions of streptomycin or streptidine, or both, dissolved in various buffer solutions at 488 nm of excitation. A discrete level of fluorescence was observed in the spectrum regardless of media when separate solutions of both streptomycin or streptidine were studied. Fluorescence notably increased at 522-532 nm when the solutions contained both streptomycin and streptidine together. These results suggest that streptidine putatively derived from streptomycin may contribute to the observed fluorescence accumulation in vestibular preparations after acute treatment. Thus, these metabolic properties of the inner ear which transform streptomycin into streptidine, something never considered earlier, could be claimed as partially responsible for converting a therapeutic agent into a compound which could be as harmful as STP to the inner ear.     

Enzymatic synthesis of aminoglycoside antibiotics: novel adenosylmethionine:2-deoxystreptamine N-methyltransferase activities in hygromycin B- and spectinomycin-producing Streptomyces spp. and uses of the methylated products

Aminocyclitols structurally related to streptamine, a 1,3-diaminocyclitol, are common components of the RNA-binding aminoglycoside antibiotics. The respective aminocyclitol cores of hygromycin B and spectinomycin are N(3)-methyl-2-deoxy-D-streptamine and N(1),N(3)-dimethyl-2-epi-streptamine. Adenosyl[methyl-(14)C]methionine:2-deoxystreptamine N-methyltransferase activities were detected in extracts of early-stationary-phase mycelia of the hygromycin B producer Streptomyces hygroscopicus subsp. hygroscopicus ATCC 27438 and the spectinomycin producer Streptomyces flavopersicus ATCC 19756. Extracts of both strains methylated the N(1)- and N(3)-amino groups of 2-deoxystreptamine, streptamine, and 2-epi-streptamine; the N(1)-amino group of N(3)-methyl-2-deoxy-D-streptamine, and the N(3)-amino group of N(1)-ethyl-2-deoxy-D-streptamine, the semisynthetic aminocyclitol of netilmicin. The mono[(14)C]methyl derivatives of 2-deoxystreptamine, streptamine, and 2-epi-streptamine were excellent substrates for L-glutamine:aminocyclitol aminotransferase and thereby provided a sensitive assay for derepression of this key enzyme, a generic biosynthetic marker that we have shown to be the only enzyme common to the biosyntheses of all major aminoglycoside antibiotics. Other prospective uses for these methyl-labeled 2-deoxystreptamine analogs are also described.     

Cloning and characterization of the tetrocarcin A gene cluster from Micromonospora chalcea NRRL 11289 reveals a highly conserved strategy for tetronate biosynthesis in spirotetronate antibiotics

Tetrocarcin A (TCA), produced by Micromonospora chalcea NRRL 11289, is a spirotetronate antibiotic with potent antitumor activity and versatile modes of action. In this study, the biosynthetic gene cluster of TCA was cloned and localized to a 108-kb contiguous DNA region. In silico sequence analysis revealed 36 putative genes that constitute this cluster (including 11 for unusual sugar biosynthesis, 13 for aglycone formation, and 4 for glycosylations) and allowed us to propose the biosynthetic pathway of TCA. The formation of D-tetronitrose, L-amicetose, and L-digitoxose may begin with D-glucose-1-phosphate, share early enzymatic steps, and branch into different pathways by competitive actions of specific enzymes. Tetronolide biosynthesis involves the incorporation of a 3-C unit with a polyketide intermediate to form the characteristic spirotetronate moiety and trans-decalin system. Further substitution of tetronolide with five deoxysugars (one being a deoxynitrosugar) was likely due to the activities of four glycosyltransferases. In vitro characterization of the first enzymatic step by utilization of 1,3-biphosphoglycerate as the substrate and in vivo cross-complementation of the bifunctional fused gene tcaD3 (with the functions of chlD3 and chlD4) to Delta chlD3 and Delta chlD4 in chlorothricin biosynthesis supported the highly conserved tetronate biosynthetic strategy in the spirotetronate family. Deletion of a large DNA fragment encoding polyketide synthases resulted in a non-TCA-producing strain, providing a clear background for the identification of novel analogs. These findings provide insights into spirotetronate biosynthesis and demonstrate that combinatorial-biosynthesis methods can be applied to the TCA biosynthetic machinery to generate structural diversity.     

Structural basis for dual functionality of isoflavonoid O-methyltransferases in the evolution of plant defense responses

In leguminous plants such as pea (Pisum sativum), alfalfa (Medicago sativa), barrel medic (Medicago truncatula), and chickpea (Cicer arietinum), 4'-O-methylation of isoflavonoid natural products occurs early in the biosynthesis of defense chemicals known as phytoalexins. However, among these four species, only pea catalyzes 3-O-methylation that converts the pterocarpanoid isoflavonoid 6a-hydroxymaackiain to pisatin. In pea, pisatin is important for chemical resistance to the pathogenic fungus Nectria hematococca. While barrel medic does not biosynthesize 6a-hydroxymaackiain, when cell suspension cultures are fed 6a-hydroxymaackiain, they accumulate pisatin. In vitro, hydroxyisoflavanone 4'-O-methyltransferase (HI4'OMT) from barrel medic exhibits nearly identical steady state kinetic parameters for the 4'-O-methylation of the isoflavonoid intermediate 2,7,4'-trihydroxyisoflavanone and for the 3-O-methylation of the 6a-hydroxymaackiain isoflavonoid-derived pterocarpanoid intermediate found in pea. Protein x-ray crystal structures of HI4'OMT substrate complexes revealed identically bound conformations for the 2S,3R-stereoisomer of 2,7,4'-trihydroxyisoflavanone and the 6aR,11aR-stereoisomer of 6a-hydroxymaackiain. These results suggest how similar conformations intrinsic to seemingly distinct chemical substrates allowed leguminous plants to use homologous enzymes for two different biosynthetic reactions. The three-dimensional similarity of natural small molecules represents one explanation for how plants may rapidly recruit enzymes for new biosynthetic reactions in response to changing physiological and ecological pressures.     

Initiation of actinorhodin export in Streptomyces coelicolor

Many microorganisms produce molecules having antibiotic activity and expel them into the environment, presumably enhancing their ability to compete with their neighbours. Given that these molecules are often toxic to the producer, mechanisms must exist to ensure that the assembly of the export apparatus accompanies or precedes biosynthesis. Streptomyces coelicolor produces the polyketide antibiotic actinorhodin in a multistep pathway involving enzymes encoded by genes that are clustered together. Embedded within the cluster are genes for actinorhodin export, two of which, actR and actA resemble the classic tetR and tetA repressor/efflux pump-encoding gene pairs that confer resistance to tetracycline. Like TetR, which represses tetA, ActR is a repressor of actA. We have identified several molecules that can relieve repression by ActR. Importantly (S)-DNPA (an intermediate in the actinorhodin biosynthetic pathway) and kalafungin (a molecule related to the intermediate dihydrokalafungin), are especially potent ActR ligands. This suggests that along with the mature antibiotic(s), intermediates in the biosynthetic pathway might activate expression of the export genes thereby coupling export to biosynthesis. We suggest that this could be a common feature in the production of many bioactive natural products.     

The biosynthesis of streptomycin. The origin of the C-formyl group of streptose

1. The biosynthesis of streptomycin in Streptomyces griseus has been studied by adding d-[3,4-(14)C(2)]glucose or d-[1,3-(14)C(2)]glucose to the growth medium and degrading the streptomycin produced. 2. The results suggest that the C-3' branch carbon atom of l-streptose arises from C-3 of d-glucose. 3. The mechanism of biosynthesis of streptose from glucose is discussed. It probably involves an intramolecular rearrangement of a 6-deoxy-4-oxyhexose derivative, and it is suggested that the nucleoside diphosphate sugar derivative hitherto recognized as an intermediate in the biosynthesis of l-rhamnose might participate in such a rearrangement.     

In vitro evidence for the dual function of Alg2 and Alg11: essential mannosyltransferases in N-linked glycoprotein biosynthesis

The biosynthesis of asparagine-linked glycoproteins utilizes a dolichylpyrophosphate-linked glycosyl donor (Dol-PP-GlcNAc(2)Man(9)Glc(3)), which is assembled by the series of membrane-bound glycosyltransferases that comprise the dolichol pathway. This biosynthetic pathway is highly conserved throughout eukaryotic evolution. While complementary genetic and bioinformatic approaches have enabled identification of most of the dolichol pathway enzymes in Saccharomyces cerevisiae, the roles of two of the mannosyltransferases in the pathway, Alg2 and Alg11, have remained ambiguous because these enzymes appear to catalyze only two of the remaining four unannotated transformations. To address this issue, a biochemical approach was taken using recombinant Alg2 and Alg11 from S. cerevisiae and defined dolichylpyrophosphate-linked substrates. A cell-membrane fraction isolated from Escherichia coli overexpressing thioredoxin-tagged Alg2 was used to demonstrate that this enzyme actually carries out an alpha1,3-mannosylation, followed by an alpha1,6-mannosylation, to form the first branched pentasaccharide intermediate of the pathway. Then, using thioredoxin-tagged Alg2 for the chemoenzymatic synthesis of the dolichylpyrophosphate pentasaccharide, it was thus possible to define the biochemical function of Alg11, which is to catalyze the next two sequential alpha1,2-mannosylations. The elucidation of the dual function of each of these enzymes thus completes the identification of the entire ensemble of glycosyltransferases that comprise the dolichol pathway.     

Streptomycin action to the mammalian inner ear vestibular organs: comparison between pigmented guinea pigs and rats

Streptomycin is the antibiotic of choice to treat tuberculosis and other infectious diseases but it causes vestibular malfunction and hipoacusia. Rodents are usually employed as models of drug action to the inner ear and results are extrapolated to what happens in humans. In rats, streptomycin destroys macular sensory cells and does not affect cochlear ones, whereas in guinea pigs the contrary is true. Action on the vestibular cristae cells involved in vestibulo-ocular reflex integrity is less clear. Thus, we compared this response in both pigmented guinea pigs (Cavia cobaya) and rats (Rattus norvegicus) after parallel streptomycin chronic treatment. In guinea pigs, the reflex was obliterated along treatment time; in rats this behavior was not observed, suggesting that the end organ target was diverse. In recent studies, streptidine, a streptomycin derivative found in the blood of humans and rats treated with streptomycin, was the actual ototoxic agent. The putative streptomycin vestibular organ target observed in humans corresponds with the guinea pig observations. Results observed in rats are controversial: streptidine did not cause any damage either to vestibular cristae nor auditory cells. We hypothesize differential drug metabolism and distribution and conclude that results in laboratory animals may not always be applicable in the human situation.     

Enzymes of triacylglycerol synthesis and their regulation

Since the pathways of glycerolipid biosynthesis were elucidated in the 1950's, considerable knowledge has been gained about the enzymes that catalyze the lipid biosynthetic reactions and the factors that regulate triacylglycerol biosynthesis. In the last few decades, in part due to advances in technology and the wide availability of nucleotide and amino acid sequences, we have made enormous strides in our understanding of these enzymes at the molecular level. In many cases, sequence information obtained from lipid biosynthetic enzymes of prokaryotes and yeast has provided the means to search the genomic and expressed sequence tag databases for mammalian homologs and most of the genes have now been identified. Surprisingly, multiple isoforms appear to catalyze the same chemical reactions, suggesting that each isoform may play a distinct functional role in the pathway of triacylglycerol and phospholipid biosynthesis. This review focuses on the de novo biosynthesis of triacylglycerol in eukaryotic cells, the isoenzymes that are involved, their subcellular locations, how they are regulated, and their putative individual roles in glycerolipid biosynthesis.     

Functional expression and extension of staphylococcal staphyloxanthin biosynthetic pathway in Escherichia coli

The biosynthetic pathway for staphyloxanthin, a C(30) carotenoid biosynthesized by Staphylococcus aureus, has previously been proposed to consist of five enzymes (CrtO, CrtP, CrtQ, CrtM, and CrtN). Here, we report a missing sixth enzyme, 4,4'-diaponeurosporen-aldehyde dehydrogenase (AldH), in the staphyloxanthin biosynthetic pathway and describe the functional expression of the complete staphyloxanthin biosynthetic pathway in Escherichia coli. When we expressed the five known pathway enzymes through artificial synthetic operons and the wild-type operon (crtOPQMN) in E. coli, carotenoid aldehyde intermediates such as 4,4'-diaponeurosporen-4-al accumulated without being converted into staphyloxanthin or other intermediates. We identified an aldH gene located 670 kilobase pairs from the known staphyloxanthin gene cluster in the S. aureus genome and an aldH gene in the non-staphyloxanthin-producing Staphylococcus carnosus genome. These two putative enzymes catalyzed the missing oxidation reaction to convert 4,4'-diaponeurosporen-4-al into 4,4'-diaponeurosporenoic acid in E. coli. Deletion of the aldH gene in S. aureus abolished staphyloxanthin biosynthesis and caused accumulation of 4,4'-diaponeurosporen-4-al, confirming the role of AldH in staphyloxanthin biosynthesis. When the complete staphyloxanthin biosynthetic pathway was expressed using an artificial synthetic operon in E. coli, staphyloxanthin-like compounds, which contained altered fatty acid acyl chains, and novel carotenoid compounds were produced, indicating functional expression and coordination of the six staphyloxanthin pathway enzymes.