Cloning of antibiotic resistance and nutritional genes in streptomycetes

Novel aminoacylases from Streptomyces griseus DSM 40236 and their recombinant production in Streptomyces lividans

Amino acid-based surfactants are valuable compounds for cosmetic formulations. The chemical synthesis of acyl amino acids is conventionally performed by the Schotten-Baumann reaction using fatty acyl chlorides, but aminoacylases have also been investigated for use in biocatalytic synthesis with free fatty acids. Aminoacylases and their properties are diverse; they belong to different peptidase families and show differences in substrate specificity and biocatalytic potential. Bacterial aminoacylases capable of synthesis have been isolated from Burkholderia, Mycolicibacterium, and Streptomyces. Although several proteases and peptidases from S. griseus have been described, no aminoacylases from this species have been identified yet. In this study, we investigated two novel enzymes produced by S. griseus DSM 40236T . We identified and cloned the respective genes and recombinantly expressed an α-aminoacylase (EC3.5.1.14), designated SgAA, and an ε-lysine acylase (EC3.5.1.17), designated SgELA, in S. lividans TK23. The purified aminoacylase SgAA was biochemically characterized, focusing on its hydrolytic activity to determine temperature- and pH optima and stabilities. The aminoacylase could hydrolyze various acetyl amino acids at the Nα -position with a broad specificity regarding the sidechain. Substrates with longer acyl chains, like lauroyl amino acids, were hydrolyzed to a lesser extent. Purified aminoacylase SgELA specific for the hydrolysis of Nε -acetyl-l-lysine was unstable and lost its enzymatic activity upon storage for a longer period but could initially be characterized. The pH optimum of SgELA was pH 8.0. While synthesis of acyl amino acids was not observed with SgELA, SgAA catalyzed the synthesis of lauroyl-methionine.

Ectopic positioning of the cell division plane is associated with single amino acid substitutions in the FtsZ-recruiting SsgB in Streptomyces

In most bacteria, cell division begins with the polymerization of the GTPase FtsZ at mid-cell, which recruits the division machinery to initiate cell constriction. In the filamentous bacterium Streptomyces, cell division is positively controlled by SsgB, which recruits FtsZ to the future septum sites and promotes Z-ring formation. Here, we show that various amino acid (aa) substitutions in the highly conserved SsgB protein result in ectopically placed septa that sever spores diagonally or along the long axis, perpendicular to the division plane. Fluorescence microscopy revealed that between 3.3% and 9.8% of the spores of strains expressing SsgB E120 variants were severed ectopically. Biochemical analysis of SsgB variant E120G revealed that its interaction with FtsZ had been maintained. The crystal structure of Streptomyces coelicolor SsgB was resolved and the key residues were mapped on the structure. Notably, residue substitutions (V115G, G118V, E120G) that are associated with septum misplacement localize in the α2-α3 loop region that links the final helix and the rest of the protein. Structural analyses and molecular simulation revealed that these residues are essential for maintaining the proper angle of helix α3. Our data suggest that besides altering FtsZ, aa substitutions in the FtsZ-recruiting protein SsgB also lead to diagonally or longitudinally divided cells in Streptomyces.

Activation of Secondary Metabolite Gene Clusters in Streptomyces clavuligerus by the PimM Regulator of Streptomyces natalensis

Expression of non-native transcriptional activators may be a powerful general method to activate secondary metabolites biosynthetic pathways. PAS-LuxR regulators, whose archetype is PimM, activate the biosynthesis of polyene macrolide antifungals and other antibiotics, and have been shown to be functionally preserved across multiple Streptomyces strains. In this work we show that constitutive expression of pimM in Streptomyces clavuligerus ATCC 27064 significantly affected its transcriptome and modifies secondary metabolism. Almost all genes in three secondary metabolite clusters were overexpressed, including the clusters responsible for the biosynthesis of the clinically important clavulanic acid and cephamycin C. In comparison to a control strain, this resulted in 10- and 7-fold higher production levels of these metabolites, respectively. Metabolomic and bioactivity studies of S. clavuligerus::pimM also revealed deep metabolic changes. Antifungal activity absent in the control strain was detected in S. clavuligerus::pimM, and determined to be the result of a fivefold increase in the production of the tunicamycin complex.

The biosynthetic implications of late-stage condensation domain selectivity during glycopeptide antibiotic biosynthesis

Non-ribosomal peptide synthesis is a highly important biosynthetic pathway for the formation of many secondary metabolites of medical relevance. Due to the challenges associated with the chemical synthesis of many of the products of these assembly lines, understanding the activity and selectivity of non-ribosomal peptide synthetase (NRPS) machineries is an essential step towards the redesign of such machineries to produce new bioactive peptides. Whilst the selectivity of the adenylation domains responsible for amino acid activation during NRPS synthesis has been widely studied, the selectivity of the essential peptide bond forming domains - known as condensation domains - is not well understood. Here, we present the results of a combination of in vitro and in vivo investigations into the final condensation domain from the NRPS machinery that produces the glycopeptide antibiotics (GPAs). Our results show that this condensation domain is tolerant for a range of peptide substrates and even those with unnatural stereochemistry of the peptide C-terminus, which is in contrast to the widely ascribed role of these domains as a stereochemical gatekeeper during NRPS synthesis. Furthermore, we show that this condensation domain has a significant preference for linear peptide substrates over crosslinked peptides, which indicates that the GPA crosslinking cascade targets the heptapeptide bound to the final module of the NRPS machinery and reinforces the role of the unique GPA X-domain in this process. Finally, we demonstrate that the peptide bond forming activity of this condensation domain is coupled to the rate of amino acid activation performed by the subsequent adenylation domain. This is a significant result with implications for NRPS redesign, as it indicates that the rate of amino acid activation of modified adenylation domains must be maintained to prevent unwanted peptide hydrolysis from the NRPS due to a loss of the productive coupling of amino acid selection and peptide bond formation. Taken together, our results indicate that assessing condensation domain activity is a vital step in not only understanding the biosynthetic logic and timing of NRPS-mediated peptide assembly, but also the rules which redesign efforts must obey in order to successfully produce functional, modified NRPS assembly lines.

Yield enhancement strategies of rare pharmaceutical metabolites from endophytes

Endophytes are barely untapped as vital sources in the medicine. They are microorganisms which mostly exist in plants. As they are exploited, it is accepted that endophytes can produce active metabolites that possess same function as their hosts such as taxol, podophyllotoxin, hypericin, and azadirachtin. These metabolites have been promising potential usefulness in safety and human health concerns. We are supposed to adopt measures to raise production for the low yield of metabolites. This paper summarizes the latest advances in various bioprocess optimization strategies. These techniques can overcome the limitations associated with rare pharmaceutical metabolite-producing endophytic fungi. These strategies include strain improvement, genome shuffling, medium optimization, fermentation conditions optimization, addition of specific factor, addition of solid sorbent, and co-culturing. It will enable endophytes to produce high and sustainable production of rare pharmaceutical metabolites.

Halogenation of glycopeptide antibiotics occurs at the amino acid level during non-ribosomal peptide synthesis

Halogenation plays a significant role in the activity of the glycopeptide antibiotics (GPAs), although up until now the timing and therefore exact substrate involved was unclear. Here, we present results combined from in vivo and in vitro studies that reveal the substrates for the halogenase enzymes from GPA biosynthesis as amino acid residues bound to peptidyl carrier protein (PCP)-domains from the non-ribosomal peptide synthetase machinery: no activity was detected upon either free amino acids or PCP-bound peptides. Furthermore, we show that the selectivity of GPA halogenase enzymes depends upon both the structure of the bound amino acid and the PCP domain, rather than being driven solely via the PCP domain. These studies provide the first detailed understanding of how halogenation is performed during GPA biosynthesis and highlight the importance and versatility of trans-acting enzymes that operate during peptide assembly by non-ribosomal peptide synthetases.

Cleavage of phosphorothioated DNA and methylated DNA by the type IV restriction endonuclease ScoMcrA

Many taxonomically diverse prokaryotes enzymatically modify their DNA by replacing a non-bridging oxygen with a sulfur atom at specific sequences. The biological implications of this DNA S-modification (phosphorothioation) were unknown. We observed that simultaneous expression of the dndA-E gene cluster from Streptomyces lividans 66, which is responsible for the DNA S-modification, and the putative Streptomyces coelicolor A(3)2 Type IV methyl-dependent restriction endonuclease ScoA3McrA (Sco4631) leads to cell death in the same host. A His-tagged derivative of ScoA3McrA cleaved S-modified DNA and also Dcm-methylated DNA in vitro near the respective modification sites. Double-strand cleavage occurred 16–28 nucleotides away from the phosphorothioate links. DNase I footprinting demonstrated binding of ScoA3McrA to the Dcm methylation site, but no clear binding could be detected at the S-modified site under cleavage conditions. This is the first report of in vitro endonuclease activity of a McrA homologue and also the first demonstration of an enzyme that specifically cleaves S-modified DNA.

Bacteria frequently exchange genetic information among themselves. DNA from one species can be transferred efficiently to unrelated microbes. Bacteria have developed systems that restrict gene transfer. Many restriction systems recognize and destroy foreign DNA entering the cells, but there are also enzymes inducing suicide of cells that have been invaded by foreign genes that modify the host DNA. We describe a restriction endonuclease from an antibiotic-producing soil bacterium that cuts foreign methylated DNA and also foreign DNA containing sulfur. DNA sulfur modification occurs in diverse medically or industrially important microbes and has been shown to prevent cleavage of DNA. The most similar enzyme in the databases is the putative restriction endonuclease McrA from Escherichia coli which has not been observed to cleave DNA in a test tube. Our endonuclease showed no activity with magnesium, but it cleaved DNA in the presence of manganese ions. Therefore, we present two novelties: an unusual restriction endonuclease that cleaves sulfur-modified DNA and conditions that allow the study of the enzyme in a test tube.

Strain improvement for production of pharmaceuticals and other microbial metabolites by fermentation

Microbes have been good to us. They have given us thousands of valuable products with novel structures and activities. In nature, they only produce tiny amounts of these secondary metabolic products as a matter of survival. Thus, these metabolites are not overproduced in nature, but they must be overproduced in the pharmaceutical industry. Genetic manipulations are used in industry to obtain strains that produce hundreds or thousands of times more than that produced by the originally isolated strain. These strain improvement programs traditionally employ mutagenesis followed by screening or selection; this is known as 'brute-force' technology. Today, they are supplemented by modern strategic technologies developed via advances in molecular biology, recombinant DNA technology, and genetics. The progress in strain improvement has increased fermentation productivity and decreased costs tremendously. These genetic programs also serve other goals such as the elimination of undesirable products or analogs, discovery of new antibiotics, and deciphering of biosynthetic pathways.

Genetic improvement of processes yielding microbial products

Although microorganisms are extremely good in presenting us with an amazing array of valuable products, they usually produce them only in amounts that they need for their own benefit; thus, they tend not to overproduce their metabolites. In strain improvement programs, a strain producing a high titer is usually the desired goal. Genetics has had a long history of contributing to the production of microbial products. The tremendous increases in fermentation productivity and the resulting decreases in costs have come about mainly by mutagenesis and screening/selection for higher producing microbial strains and the application of recombinant DNA technology.

Efficient transformation procedure of a newly isolated Streptomyces sp. TN58 strain producing antibacterial activities

A new aerobic Gram-positive bacterium designated TN58 producing antibacterial activities against Gram-positive and Gram-negative bacteria was isolated from Tunisian soil. The nucleotide sequence of the 16S rRNA gene (1516 bp) of the TN58 strain showed high similarity (96-98%) to the Streptomyces 16S rRNA genes, especially with that of Streptomyces lavendulae which produces the anti-tumor compound mitomycin C, and the cyclic peptide antibiotic, complestatin. Cultural characteristic studies, alignment data of the 16S rRNA gene, and analysis of the nucleotide sequence of a 2.2 kb genomic DNA fragment from TN58 strongly suggested that this strain could be an actinomycete and most probably belongs to the genus Streptomyces. Study of the influence of different nutritional compounds on antibiotic production showed that the highest antibacterial activities were obtained when glycerol at 1% (w/v) was used as sole carbon source in the presence of potassium. In analytical conditions, the application to supernatant culture of the TN58 strain of various extraction and purification steps led to the isolation of two pure active molecules having a retention time of 38.6 and 50.2 min, respectively. TN58 strain was untransformable with the Streptomyces cloning vector pIJ702 via classical polyethylene glycol (PEG) protoplast transformation and previously described Streptomyces electroporation procedures. Transformation was rendered possible by the electroporation technique only after utilization of a preculture medium without sucrose and a regeneration plate containing a low sucrose concentration.

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.

Development of cloning vectors and transformation methods for Amycolatopsis

The genus Amycolatopsis is of industrial importance, as its species are known to produce commercial antibiotics. It belongs to the family Pseudonocardiaceae and has an eventful taxonomic history. Initially strains were identified as Streptomyces, then later as Nocardia. However, based on biochemical, morphological and molecular features, the genus Amycolatopsis, containing seventeen species, was created. The development of molecular genetic techniques for this group has been slow. The scarcity of molecular genetic tools including stable plasmids, antibiotic resistance markers, transposons, reporter genes, cloning vectors, and high efficiency transformation protocols has made progress slow, but efforts in the past decade have led to the development of cloning vectors and transformation methods for these organisms. Some of the cloning vectors have broad host range (pRL series) whereas others have limited host range (pMEA300 and pMEA100). The cloning vector pMEA300 has been completely sequenced, while only the minimal replicon (pA- rep) has been sequenced from pRL plasmids. Direct transformation of mycelia and electroporation are the most widely applicable methods for transforming species of Amycolatopsis. Conjugational transfer from Escherichia coli has been reported only in the species A. japonicum, and gene disruption and replacements using homologous recombination are now possible in some strains.

Specialized osmotic stress response systems involve multiple SigB-like sigma factors in Streptomyces coelicolor

Whereas in Bacillus subtilis, a general stress response stimulon under the control of a single sigma factor (SigB) is induced by different physiological and environmental stresses (heat, salt or ethanol shock), in Streptomyces coelicolor, these environmental stresses induce independent sets of proteins, and its genome encodes nine SigB paralogues. To investigate possible functions of multiple sigB-like genes in S. coelicolor, Pctc, a promoter routinely used to assay SigB activity in vivo, was analysed as a heterologous reporter. The fact that Pctc was activated by osmotic shock, but not by heat or ethanol, confirmed that stress response system(s) could operate independently in S. coelicolor. Pctc was also induced transiently during growth of liquid cultures, presumably by nutritional signals. We purified an RNA polymerase holoenzyme from crude extracts that catalysed specific transcription of Pctc in vitro. Its sigma subunit was identified as a product of the sigH gene, which is co-transcribed downstream of a putative antisigma factor gene (prsH). Although the sigH function was not needed for normal colony morphology, prsH was conditionally required for both aerial hyphae formation and regulation of antibiotic biosynthesis. Levels of two different sigH-encoded proteins were growth phase dependent but not significantly changed by osmotic stress, implying the important roles of post-translational regulatory elements such as PrsH. In addition, synthesis of three other SigH-like proteins was induced by osmotic stress, but not by ethanol or heat. Two of them were genetically assigned to sigH homologous loci sigI and sigJ and shown to be independently regulated. This family of SigH-like proteins displayed different osmotic response kinetics. Thus, in contrast to many other bacteria, S. coelicolor uses an osmotic sensory system that can co-ordinate the activity of multiple paralogues to control the relative activity of promoters within the same stress stimulon. Such specialized stress response systems may reflect adaptive functions needed for colonial differentiation.

Transformation using in vivo and in vitro methylation in Streptomyces griseus

Streptomyces griseus does not readily take up foreign DNA isolated from other Streptomyces species or Escherichia coli, presumably due to its unique restriction-modification systems that function as a barrier for interspecific DNA transfer. To efficiently transform S. griseus by avoiding the restriction barriers, we methylated incoming DNA in vivo and in vitro and treated protoplasts with heat prior to transformation. Whereas heat treatment of protoplasts or methylation of the E. coli-Streptomyces shuttle vectors (pXE4 and pKK1443) did not prominently improve the transformation efficiency, HpaII methylation of the vectors from any E. coli strains tested in this study highly increased the transformation efficiency. The highest transformation efficiency was observed when the shuttle vectors were isolated from the dam, hsd strain of E. coli (GM161) and methylated by AluI and HpaII methyltransferases, and the efficiency was approximately the same as that of the vectors from S. griseus. We identified several restriction-modification systems that decrease the transformation efficiency. This research also led us to understand methylation profiles and restriction-modification systems in S. griseus.

Osmotic regulation of the Streptomyces lividans thiostrepton-inducible promoter, ptipA

Transcriptional activation of the thiostrepton-inducible promoter, ptipA, in Streptomyces lividans is mediated by TipAL. This transcriptional activator belongs to the MerR/SoxR family that characteristically binds an operator sequence located between the -10 and -35 hexamers normally occupied by RNA polymerase. As for the Escherichia coli merT promoter, the ptipA hexamers are separated by a long 19 bp spacer and hence a topological transition of the DNA is likely to be a requisite for alignment with RNA polymerase. Growth conditions that could facilitate this conformational change were investigated using transcriptional fusions of ptipA with reporter genes. Adjustment of growth medium osmolarity led to increased and prolonged TipAL-dependent expression, both with and without the inducer, thiostrepton. These effects correlated with increases in negative DNA supercoiling. Moreover, an inability to induce the promoter with thiostrepton in strain TK64 was corrected by increasing the concentration of osmolyte, compensating for an apparent reduced level of negative DNA supercoiling in the strain. Prolonging the time of activation of tipA in the wild-type by manipulating growth conditions revealed that mycelial autolysis could be induced by thiostrepton in 4-d-old cultures.

The pdx genetic marker adjacent to the chloramphenicol biosynthesis gene cluster in Streptomyces venezuelae ISP5230: functional characterization

The pdx-4 mutation in Streptomyces venezuelae ISP5230 confers a growth requirement for pyridoxal (pdx) and is a marker for the genetically mapped cluster of genes associated with chloramphenicol biosynthesis. A gene regulating salvage synthesis of vitamin B6 cofactors in S. venezuelae was cloned by transforming a pdx-4 mutant host with the plasmid vector pDQ101 carrying a library of wild-type genomic DNA fragments, and by selecting for complementation of the host's pdx requirement. However, the corresponding replicative plasmid could not be isolated. Southern hybridizations and transduction analysis indicated that the complementing plasmid had integrated into the chromosome; after excision by a second crossover, the plasmid failed to propagate. To avoid loss of the recombinant vector, a pdx-dependent Streptomyces lividans mutant, KAA1, with a phenotype matching that of S. venezuelae pdx-4, was isolated for use as the cloning host. Introduction of pIJ702 carrying an S. venezuelae genomic library into S. lividans KAA1, and selection of prototrophic transformants, led to the isolation of a stable recombinant vector containing a 2.5 kb S. venezuelae DNA fragment that complemented requirements for pdx in both S. venezuelae and S. lividans mutants. Sequence analysis of the cloned DNA located an intact ORF with a deduced amino acid sequence that, in its central and C-terminal regions resembled type-I aminotransferases. The N-terminal region of the cloned DNA fragment aligned closely with distinctive helix-turn-helix motifs found near the N termini of GntR family transcriptional regulators. The overall deduced amino acid sequence of the cloned DNA showed 73% end-to-end identity to a putative GntR-type regulator cloned in cosmid 6D7 from the Streptomyces coelicolor A3(2) genome. This location is close to that of pdxA, the first pdx marker in S. coelicolor A3(2) identified and mapped genetically in Sir David Hopwood's laboratory. The S. venezuelae gene and S. coelicolor pdxA are postulated to be homologues regulating vitamin B6 coenzyme synthesis from pdx.

The restriction-modification system in Streptomyces flavopersicus

To clone bifunctional vectors in streptomycetes, it was necessary to define the restriction-modification system of Streptomyces flavopersicus. Plasmid DNA from bifunctional vectors pIJ699 and pXED3-13, isolated from E. coli strains with different methylation systems: E. coli DH5 alpha (dam+ dcm+), E. coli MB5386 (dam dcm), E. coli CB51 (dam dcm+), E. coli NM544 (dam+ dcm), was used for transformation of protoplasts from strain S. flavopersicus. Restriction of dcm-methylated DNA from S. flavopersicus was established. As a host in the intermediate cloning strain E. coli NM544 (dam+ dcm) should be used, as the dcm-transmethylase-dependent strain S. flavopersicus does not process DNA from this strain.

Characterization of a vanillic acid non-oxidative decarboxylation gene cluster from Streptomyces sp. D7

The genetics of non-oxidative decarboxylation of aromatic acids are poorly understood in both prokaryotes and eukaryotes. Although such reactions have been observed in numerous micro-organisms acting on a variety of substrates, the genes encoding enzymes responsible for these processes have not, to our knowledge, been reported in the literature. Here, the isolation of a streptomycete from soil (Streptomyces sp. D7) which efficiently converts 4-hydroxy-3-methoxybenzoic acid (vanillic acid) to 2-methoxyphenol (guaiacol) is described. Protein two-dimensional gel analysis revealed that several proteins were synthesized in response to vanillic acid. One of these was characterized by partial amino-terminal sequencing, leading to the cloning of a gene cluster from a genomic DNA lambda phage library, consisting of three ORFs, vdcB (602 bp), vdcC (1424 bp) and vdcD (239 bp). Protein sequence comparisons suggest that the product of vdcB (201 aa) is similar to phenylacrylate decarboxylase of yeast; the putative products of vdcC (475 aa) and vdcD (80 aa) are similar to hypothetical proteins of unknown function from various micro-organisms, and are found in a similar cluster in Bacillus subtilis. Northern blot analysis revealed the synthesis of a 2.5 kb mRNA transcript in vanillic-acid-induced cells, suggesting that the cluster is under the control of a single inducible promoter. Expression of the entire vdc gene cluster in Streptomyces lividans 1326 as a heterologous host resulted in that strain acquiring the ability to decarboxylate vanillic acid to guaiacol non-oxidatively. Both Streptomyces sp. strain D7 and recombinant S. lividans 1326 expressing the vdc gene cluster do not, however, decarboxylate structurally similar aromatic acids, suggesting that the system is specific for vanillic acid. This catabolic system may be useful as a component for pathway engineering research focused towards the production of valuable chemicals from forestry and agricultural by-products.

Pleiotropic effects of cAMP on germination, antibiotic biosynthesis and morphological development in Streptomyces coelicolor

In wild-type Streptomyces coelicolor MT1110 cultures, cyclic adenosine 3',5' monophosphate (cAMP) was synthesized throughout the developmental programme with peaks of accumulation both during germination and later when aerial mycelium and actinorhodin were being produced. Construction and characterization of an adenylate cyclase disruption mutant (BZ1) demonstrated that cAMP facilitated these developmental processes. Although pulse-labelling experiments showed that a similar germination process was initiated in BZ1 and MT1110, germ-tube emergence was severely delayed in BZ1 and never occurred in more than 85% of the spores. Studies of growth and development on solid glucose minimal medium (SMMS, buffered or unbuffered) showed that MT1110 and BZ1 produced acid during the first rapid growth phase, which generated substrate mycelium. Thereafter, on unbuffered SMMS, only MT1110 resumed growth and produced aerial mycelium by switching to an alternative metabolism that neutralized its medium, probably by reincorporating and metabolizing extracellular acids. BZ1 was not able to neutralize its medium or produce aerial mycelium on unbuffered SMMS; these defects were suppressed by high concentrations (>1 mM) of cAMP during early growth or on buffered medium. Other developmental mutants (bldA, bldB, bldC, bldD, bldG) also irreversibly acidified this medium. However, these bald mutants were not suppressed by exogenous cAMP or neutralizing buffer. BZ1 also differentiated when it was cultured in close proximity to MT1110, a property observed in cross-feeding experiments between bald mutants and commonly thought to reflect diffusion of a discrete positively acting signalling molecule. In this case, MT1110 generated a more neutral pH environment that allowed BZ1 to reinitiate growth and form aerial mycelium. The fact that actinorhodin synthesis could be induced by concentrations of cAMP (< 20 microM) found in the medium of MT1110 cultures, suggested that it may serve as a diffusible signalling molecule to co-ordinate antibiotic biosynthesis.

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.

Cloning and analysis of a peptide synthetase gene of the balhimycin producer Amycolatopsis mediterranei DSM5908 and development of a gene disruption/replacement system

A gene cloning system for Amycolatopsis mediterranei DSM5908, the producer of the glycopeptide antibiotic balhimycin, was developed for analysis of peptide synthetase genes. A modified direct transformation procedure was used to introduce DNA. The efficiency of DNA uptake depended on the age of the culture: mycelium of early stationary phase (52-55 h) cultures resulted in optimal transformation frequencies. Using the novel non-replicative integration vector pSP1, gene disruption plasmids were constructed. Highest integration frequencies were observed when the DNA was isolated from the dam/dcm Escherichia coli strain JM110. The efficiency of integration depended directly on the size of the cloned insert. Plasmids with fragments smaller than 1 kilobase (kb) were difficult to integrate. In gene replacement experiments a high double cross-over rate (31%) was demonstrated. Oligonucleotides derived from conserved regions of peptide synthetases were designed to identify balhimycin biosynthesis genes. Using these gene probes in plaque hybridization experiments, we identified peptide synthetase homologous DNA fragments in a lambda library of A. mediterranei. One peptide synthetase gene fragment was characterized by DNA sequencing and the results revealed a complete amino acid activating domain of a peptide synthetase gene, designated aps. The disruption of aps neither influenced balhimycin biosynthesis nor generated another apparent phenotype.

Nucleotide sequence of a nicking site of the Streptomyces plasmid pSN22 replicating by the rolling circle mechanism

A putative nicking site in the double strand origin (DSO) of the Streptomyces plasmid pSN22 was identified by comparing the nucleotide sequence of the DSO region with those of two other Streptomyces plasmids, pIJ101 and pJVI. A 7-bp sequence of this putative nicking site, 5'-CTTGGGA-3', was similar to the consensus sequence of the nicking site of the pC194 group of plasmids. When several point mutations were introduced into this 7-bp sequence, the transformation abilities of the mutant plasmid molecules for Streptomyces lividans were either reduced or lost. Southern hybridization analysis indicated that these mutant plasmids could not replicate in S. lividans, but were integrated into the chromosomal DNA.

Antibiotic resistance gene cassettes derived from the omega interposon for use in E. coli and Streptomyces

Three antibiotic resistance gene cassettes, derived from the omega interposon (Prentki and Krisch (1984) Gene 29, 303-313) were constructed. These cassettes carry different antibiotic resistance genes, conferring resistance to geneticin, hygromycin or viomycin, flanked by short inverted repeats containing transcription and translation termination signals and synthetic polylinkers. These cassettes were designated omega aac, omega hyg and omega vph. Resistance phenotypes conferred by these constructions are selectable in E. coli and Streptomyces. These cassettes can be used for insertional mutagenesis or for vector construction.

Three single-strand origins located on both strands of the Streptomyces rolling circle plasmid pSN22

pSN22 is an 11-kbp, high-copy-number Streptomyces plasmid which replicates via a single-stranded intermediate by the rolling circle replication (RCR) mechanism. We identified an unidirectional single-strand origin (SSO) of pSN22, sso1, where the initiation of second-strand synthesis takes place, located between the spdA and traR genes in a noncoding region which is functional in its natural orientation. The nucleotide sequence of sso1 is similar over 170 bp to the SSOs of the Streptomyces plasmids pIJ101 and pJV1. A previous report described that a 548-bp BglII-SmaI fragment has an SSO activity (ori2; Kataoka et al., Mol. Gen. Genet. 242, 130-136, 1994). To our surprise, we discovered that on pSN22, the SSO in the BglII-SmaI fragment is in the wrong, inactive, orientation and thus cannot be involved in the conversion of the single-stranded pSN22 replication intermediate to the double-stranded form of the plasmid. We revealed that this BglII-SmaI fragment contains two SSO fragments. Secondary structure analysis of these two SSOs showed similarity to the consensus TAGCGT which is conserved in SSOs of RCR plasmids from Staphylococcus and the other several Gram-positive bacteria. Deletion of these hexanucleotide sequences caused loss of SSO activities. Our result shows that two types of SSOs, Streptomyces type and Staphylococcus-like type, can function in Streptomyces lividans.

Cloning and sequence analysis of the highly expressed melanin-synthesizing gene operon from Streptomyces castaneoglobisporus

Streptomyces castaneoglobisporus HUT6202 overproduces a diffusible melanin-like pigment. An operon, designated mel, containing a gene that encodes tyrosinase, which is involved in the synthesis of melanin pigment, was cloned from the chromosomal DNA of the microorganism into the high-copy plasmid pAK114 and expressed in S. lividans. The tyrosinase activity of the transformed cells was at approximately a 110-fold higher level than that of the same host carrying the plasmid pIJ702, which has the same replication origin as pAK114 and carries the mel operon from S. antibioticus. The sequence analysis of the S. castaneoglobisporus mel operon revealed that an open-reading frame consisting of 378 base pairs(bp), designated ORF378, was found upstream of the tyrosinase gene (TYRC) consisting of 819 bp. In the present study, we constructed a chimeric mel operon consisting of ORF378 from S. castaneoglobisporus and the tyrosinase gene (TYRA) from S. antibioticus. The chimeric mel operon or the S. antibioticus mel operon, which consists of ORF438 and TYRA, expressed the tyrosinase activity in Escherichia coli intracellularly when located under the control of lacZ promoter, and the tyrosinase activity from the former was at a 30-fold higher level than that from the latter. This suggests that the gene contributing to the high expression of the tyrosinase activity in S. castaneoglobisporus is ORF378, rather than TYRC.

Cloning and nucleotide sequence of fosfomycin biosynthetic genes of Streptomyces wedmorensis

The biosynthetic pathway for production of the antibiotic fosfomycin by Streptomyces wedmorensis consists of four steps including the formation of a C-P bond and an epoxide. Fosfomycin production genes were cloned from genomic DNA using S. wedmorensis mutants blocked at different steps of the biosynthetic pathway. Four genes corresponding to each of the biosynthetic steps were found to be clustered in a DNA fragment of about 5 kb. Nucleotide sequencing of a large fragment revealed the presence of ten open reading frames, including the four biosynthetic genes and six genes with unknown functions.

Nucleotide sequence, transcriptional analysis, and glucose regulation of the phenoxazinone synthase gene (phsA) from Streptomyces antibioticus

The nucleotide sequence of a 2.3-kb SphI fragment containing the structural gene (phsA) for phenoxazinone synthase (PHS) of Streptomyces antibioticus was determined. The sequence was found to contain an open reading frame (ORF) with a G+C content of 71.5% oriented in the direction of transcription that was confirmed by primer extension. The ORF encodes a protein with an M(r) of 70,223 consisting of 642 amino acids and is preceded by a potential ribosome-binding site. The codon usage pattern is in agreement with the general pattern for streptomycete genes, with a 92.5 mol% G+C content in the third position. The N-terminal sequence of the mature PHS subunit corresponds exactly to that predicted from the nucleotide sequence. Neither ATG nor GTG initiator codons were identified for the protein. However, a TTG codon was located near the amino terminus of the mature protein and is a good candidate for the initiator codon. The transcriptional start point of phsA was located 36 bp upstream of the start codon by primer extension. The -10 region of the putative promoter showed some similarity to the consensus sequence for the major class of prokaryotic promoters, but the -35 region was less similar. Comparison of the primary amino acid sequence of PHS of S. antibioticus with other amino acid sequences indicated that PHS is a blue copper protein with copper binding domains in the N-terminal and C-terminal regions of the polypeptide chain. A BsrBI fragment containing the promoter region of phsA and a portion of the ORF was shown to promote xylE expression when cloned in the streptomycete promoter probe vector pIJ2843. This phsA promoter-dependent xylE expression could be repressed by glucose in S. antibioticus when the organism was grown on glucose or galactose plus glucose. Thus, the cloned promoter region appears to contain the sequences responsible for catabolite repression of PHS production.

ccrA1: a mutation in Streptomyces coelicolor that affects the control of catabolite repression

The regulation of carbon utilization is of central importance in the gene expression pathways for both morphological development and antibiotic production in Streptomyces species. We report the identification and characterization of a mutation in Streptomyces coelicolor, ccrA1, that affects the expression of several catabolite-controlled promoters. ccrA1 mutants are altered in expression of galP1, the glucose-sensitive, galactose-dependent promoter of the galactose utilization operon; in expression of the glycerol utilization operon, which is glucose sensitive and glycerol dependent; and in expression of chi63, the glucose-sensitive chitin-dependent promoter of a gene involved in chitin utilization. ccrA1 has no effect on the expression of galP2, a promoter that directs constitutive transcription of the galE and galK genes. ccrA1 maps to a region of the S. coelicolor genome which distinguishes it from other mutations known to be involved in catabolite control. We suggest that ccrA1 identifies a gene whose product may be involved in the general regulation of carbon catabolite repression in this complex bacterium.

Efficient Transformation of the Cephamycin C Producer Nocardia lactamdurans and Development of Shuttle and Promoter-Probe Cloning Vectors

A high transformation efficiency (1 × 10 5 to 7 × 10 5 transformants per μg of DNA) of Nocardia lactamdurans LC411 was obtained by direct treatment of mycelium with polyethylene glycol 1000 and cesium chloride. A variety of vectors from Streptomyces lividans, Brevibacterium lactofermentum, Rhodococcus fascians , and a Nocardia (Amycolatopsis) sp. were tested; transformants could be obtained only with vectors derived from an endogenous plasmid of the Amycolatopsis sp. strain DSM 43387. Vectors carrying the kanamycin resistance gene ( kan ) as a selective marker were constructed. The transformation procedure has been optimized by using one of these vectors (pULVK1) and studying the influence of the age of the culture, concentrations of cesium chloride and polyethylene glycol, amount of plasmid DNA, and nutrient supplementations of the growth medium. Versatile shuttle cloning vectors (pULVK2 and pULVK3) have been developed by subcloning the pBluescript KS(+) multiple cloning site or a synthetic polylinker containing several unique restriction sites ( Eco RV, Dra I, Bam HI, Sst I, Eco RI, and Hind III). A second marker, the apramycin resistance gene ( amr ) has been added to the vectors (pULVK2A), allowing insertional inactivation of one of the markers while using the second one for selection. An alternative marker, the amy gene of Streptomyces griseus (pULAM2), which is easily detected by the release of extracellular amylase in transformants of N. lactamdurans carrying this vector, has been added. Two promoter-probe plasmids, pULVK4 and pULVK5, have been constructed, with the promoterless xylE gene as a reporter, for utilization in N. lactamdurans .

Recent trends in rifamycin research

Rifamycin is a clinically useful macrolide antibiotic produced by the gram positive bacterium Amycolatopsis mediterranei. This antibiotic is primarily used against Mycobacterium tuberculosis and Mycobacterium leprae, causative agents of tuberculosis and leprosy, respectively. In these bacteria, rifamycin treatment specifically inhibits the initiation of RNA synthesis by binding to beta-subunit of RNA polymerase. Apart from its activity against the bacteria, rifamycin has also been reported to inhibit reverse transcriptase (RT) of certain RNA viruses. Recently, rifamycin derivatives have been discovered that are effective against Mycobacterium avium, which is associated with the AIDS complex. Consequently, the importance of and demand for rifamycin has increased tremendously, the world over. In this article, recent trends in rifamycin research and accessibility of recombinant DNA techniques to increase rifamycin production are reviewed.

Soluble forms of the human T cell receptor CD4 are efficiently expressed by Streptomyces lividans

We have developed a new gene expression and secretion system for Streptomyces lividans and used it to produce soluble forms of a human T-cell receptor CD4 at levels greater than 300 mg/l. The system uses the transcription, translation and secretion signals of the serine protease inhibitor gene STI-II which is naturally produced by S. longisporus. Using these signals, soluble derivatives of CD4 were secreted directly into the culture supernatant as correctly processed soluble, biologically active proteins. High level expression of the CD4 proteins depended on the transcription initiation signal, the amino acid sequence surrounding the signal peptide cleavage site and temporally controlled protease activities. We discuss these results in the context of the potential of this system for producing other eukaryotic proteins in Streptomyces.

Localization and nucleotide sequences of genes mediating site-specific recombination of the SLP1 element in Streptomyces lividans

SLP1 is a 17.2-kbp genetic element indigenous to the Streptomyces coelicolor chromosome. During conjugation, SLP1 can undergo excision and subsequent site-specific integration into the chromosomes of recipient cells. We report here the localization, nucleotide sequences, and initial characterization of the genes mediating these recombination events. A region of SLP1 adjacent to the previously identified site of integration, attP, was found to be sufficient to promote site-specific integration of an unrelated Streptomyces plasmid. Nucleotide sequence analysis of a 2.2-kb segment of this region reveals two open reading frames that are adjacent to and transcribed toward the attP site. One of these, the 1,365-bp int gene of SLP1, encodes a predicted 50.6-kDa basic protein having substantial amino acid sequence similarity to a family of site-specific recombinases that includes the Escherichia coli bacteriophage lambda integrase. A linker insertion in the 5' end of the cloned int gene prevents integration, indicating that Int is essential for promoting integration. An open reading frame (orf61) lying immediately 5' to int encodes a predicted 7.1-kDa basic peptide showing limited sequence similarity to the excisionase (xis) genes of other site-specific recombination systems.

Identification of a complex operator for galP1, the glucose-sensitive, galactose-dependent promoter of the Streptomyces galactose operon

The galP1 promoter is responsible for galactose-dependent, glucose-sensitive transcription of the galactose utilization operon of Streptomyces coelicolor and Streptomyces lividans. We describe the characterization of mutations that were positioned directly upstream of the apparent transcription start site of galP1 and that resulted in deregulated expression. Certain combinations of base changes within a series of hexamers that lie within two pairs of direct repeat sequences resulted in significant expression from galP1 in the absence of inducer. These motifs are further implicated in regulation by the observation that DNA fragments containing the hexamers and direct repeat sequences resulted in increased transcription from the chromosomal copy of galP1 on multicopy plasmids in the absence of galactose. We suggest that these hexamers and direct repeat sequences constitute an operator for the negative regulation of the Streptomyces gal operon.

Expression of the Bacillus subtilis sacB gene leads to sucrose sensitivity in the gram-positive bacterium Corynebacterium glutamicum but not in Streptomyces lividans

The expression of the structural gene (sacB) encoding Bacillus subtilis levansucrase in two gram-positive soil bacteria, Corynebacterium glutamicum ATCC 13032 and Streptomyces lividans 1326, was investigated. sacB expression in the presence of sucrose is lethal to C. glutamicum but not to S. lividans. While S. lividans secretes levansucrase into the medium, we could show that the enzyme is retained by C. glutamicum cells. Our results imply that the sacB gene can be used as a positive selection system in coryneform bacteria.

Transformation of Streptomyces lincolnensis protoplasts with plasmid vectors

A method for the preparation and regeneration of protoplasts of Streptomyces lincolnensis is described. Mycelium in the early exponential phase appeared to be most suitable for this purpose and yielded up to 25% regenerated intact cells. Transformation of S. lincolnensis protoplasts was achieved using broad-host-range streptomycete plasmid vectors pIJ622, pMP66, pRS410 and pIJ943 constructed from replicons pIJ101, pSLG33 and SCP2. The efficiency of transformation was 3.10(3) transformants per micrograms plasmid DNA when (2-5).10(7) recipient protoplasts were used. Interspecific transformations showed that there is no efficient restriction system in S. lincolnensis that would limit the transfer of genetic information from S. lividans or E. coli.

Global changes in gene expression related to antibiotic synthesis in Streptomyces hygroscopicus

Two-dimensional gel electrophoresis was used to follow changes in gene expression associated with antibiotic (bialaphos) biosynthesis in Streptomyces hygroscopicus. Cultures were pulse-labelled with [35S]-methionine before, during, and after the switch from primary to secondary metabolism in order to compare kinetic profiles of bialaphos (antibiotic) production (bap) genes during this metabolic transition. Separation of gene products on two-dimensional gels revealed that 27 were dependent on brpA for optimal expression and were activated as the culture approached stationary phase. Genes which encoded 10 brpA-dependent proteins were mapped to a 10 kb SstI fragment of the 35 kb bap gene cluster by expressing them in Streptomyces lividans using the thiostrepton-inducible tipA promoter. N-terminal amino acid sequences of two brpA-dependent proteins, obtained by direct microsequencing of protein spots excised from two-dimensional gels, identified them as gene products mapping to the same region and involved in secondary metabolic conversions of the bap pathway. The kinetics of synthesis of 16 brpA-dependent gene products were characterized using QUEST computer software. Cluster analysis performed on the kinetics of synthesis of 346 of the most highly expressed gene products of HP5-29, including 16 brpA-dependent ones, identified 75 families having distinct patterns of expression. Many brpA-dependent proteins were clustered together; 10 were found in one kinetic family. These kinetic families also included brpA-independent gene products perhaps subject to similar regulatory mechanisms and thus possibly involved in bialaphos biosynthesis. The activation/derepression of bap expression took place as cultures approached stationary phase and was temporally related to synthesis of ppGpp.

Role of glycosylation and deglycosylation in biosynthesis of and resistance to oleandomycin in the producer organism, Streptomyces antibioticus

Cell extracts of Streptomyces antibioticus, an oleandomycin producer, can inactivate oleandomycin in the presence of UDP-glucose. The inactivation can be detected through the loss of biological activity or by alteration in the chromatographic mobility of the antibiotic. This enzyme activity also inactivates other macrolides (rosaramicin, methymycin, and lankamycin) which contain a free 2'-OH group in a monosaccharide linked to the lactone ring (with the exception of erythromycin), but not those which contain a disaccharide (tylosin, spiramycin, carbomycin, josamycin, niddamycin, and relomycin). Interestingly, the culture supernatant contains another enzyme activity capable of reactivating the glycosylated oleandomycin and regenerating the biological activity through the release of a glucose molecule. It is proposed that these two enzyme activities could be an integral part of the oleandomycin biosynthetic pathway.

Review of the Streptomyces lividans/vector pIJ702 system for gene cloning

Interest in the biology of the Streptomyces and application of these soil bacteria to production of commercial antibiotics and enzymes has stimulated the development of efficient cloning techniques and a variety of streptomycete plasmid and phage vectors. Streptomyces lividans is routinely employed as a host for gene cloning, largely because this species recognizes a large number of promoters and appears to lack a restriction system. Vector pIJ702 was constructed from a variant of a larger autonomous plasmid and is often used as a cloning vehicle in conjunction with S. lividans. The host range of vector pIJ702 extends beyond Streptomyces spp., and its high copy number has been exploited for the overproduction of cloned gene products. This combination of host and vector has been used successfully to investigate antibiotic biosynthesis, gene structure and expression, and to map various Streptomyces mutants.

Analysis of the promoter region of saf, a Streptomyces griseus gene that increases production of extracellular enzymes

The product of the saf gene of Streptomyces griseus ATCC10137 mediated an increase in the production of several extracellular enzymes and retarded the formation of pigments and spores in Streptomyces [Daza et al., Mol. Gen. Genet. 222 (1990) 384-392]. A promoter upstream from saf was identified by subcloning a DNA fragment in the promoter probe pIJ486. Using the Escherichia coli-Brevibacterium lactofermentum promoter-probe shuttle vector, pULMJ51, we determined that the saf promoter region is also active in E. coli. The transcription start points (tsp) of the saf promoter in Streptomyces and E. coli have been determined using high-resolution S1 mapping. The tsp are at the same position in both microorganisms. Expression from the saf promoter region was negatively regulated by phosphate in Streptomyces, but not in E. coli. The amplification of the saf promoter lacking the saf coding region did not increase the production of extracellular enzymes and did not reduce sporulation or pigmentation in Streptomyces (i.e., it does not titrate out a putative repressor of the genes encoding extracellular enzymes). Several structural features of the saf promoter region and saf mRNA are studied in relation to the regulation of the saf gene expression.