Architecture of the Streptomyces lividans DnaA protein-replication origin complexes.

The Streptomyces oriC region contains two clusters of 19 DnaA boxes separated by a spacer (134 bp). The Streptomyces DnaA protein consists, like all other DnaA proteins, of four domains: domain III and the carboxyterminal part (domain IV) are responsible for binding of ATP and DNA, respectively. Binding of the DnaA protein to the entire oriC region analysed by electron microscopy showed that the DnaA protein forms separate complexes at each of the clusters of DnaA boxes, but not at the spacer separating them. In vivo mutational analysis revealed that the number of DnaA boxes and the presence of the spacer linking both groups of DnaA boxes seem to be important for a functional Streptomyces origin. We suggest that the arrangement of DnaA boxes allows the DNA-bound DnaA protein to induce bending and looping of the oriC region. As it was shown by electrophoretic mobility shift assay and "one hybrid system", two domains, I and III, facilitate interactions between DnaA molecules. We postulate that domain I and domain III could be involved in cooperativity at distant and at closely spaced DnaA boxes, respectively. The long domain II extends the range over which N termini (domain I) of DNA-bound DnaA protein can form dimers. Thus, interactions between DnaA molecules may bring two clusters of DnaA boxes separated by the spacer into functional contact by loop formation. Removal of the spacer region or deletion of domains I and II resulted, respectively, in nucleoprotein complexes which are not fully developed, or huge nucleoprotein aggregates.

Exploring the open pore of the potassium channel from Streptomyces lividans.

The tetrameric potassium channel from Streptomyces lividans (KcsA) embedded in planar bilayers exhibits the following electrophysiological characteristics: (i) K+ ions can cross the pore in a highly hydrated state (nH2O > or = 6), (ii) the selectivity for K+ exceeds that for Na+ ions by 11 times, and both Ca2+ and Mg2+ are permeant, (iii) the internal side is blocked by Ba2+ ions in a voltage-dependent manner, (iv) intrinsic rectification is due to gating, depending on the direction of the electric field, (v) the internal side is pH-sensitive, and (vi) the open pore has a diameter of approximately 5.8 A. In conclusion, our results show that ion conduction and selectivity of KcsA cannot easily be reconciled with the properties deduced from the rigid crystal structure [Doyle et al., Science 280 (1998) 69-77], which must be concluded to have the pore trapped in its closed state.

Pore mutations affecting tetrameric assembly and functioning of the potassium channel KcsA from Streptomyces lividans.

Designed mutations within the Streptomyces lividans kcsA gene resulted in a set of mutant proteins, which were characterized in respect to their assembly and channel activities. (i) The amino acid residue leucine 81 located at the external side of KcsA was found to be exchangeable by a cysteine residue without affecting the channel characteristics. (ii) Substitution of the first glycine (G77) residue within the GYG motif by an alanine or substitution of the tyrosine (Y) residue 78 by a phenylalanine (F) led to mutant proteins which form tetramers of reduced stability. In contrast to the AYG mutant protein, GFG functions as an active K(+) channel whose characteristics correspond to those of the wild-type KcsA channel. (iii) The investigated mutant proteins, which carry different mutations (T72A, T72C, V76A, V76E, G77E, Y78A, G79A, G79D, G79E) within the signature sequence of the pore region, do not at all or only to a very small degree assemble as tetramers and lack channel activity.

Characteristics of chitin-binding proteins from Streptomycetes.

During growth in the presence of chitin-containing substrates, many Streptomyces strains have been shown to secrete formerly unknown, small chitin-binding proteins (CHBs) which lack enzymatic activity, specifically target and invade, like a glue, alpha-chitin, but not beta-chitin or other polysaccharides. CHBs were purified, and their N-terminal amino acids were determined. Deduced oligonucleotides were used to identify the corresponding genes, which were then sequenced. The deduced CHB1 and CHB2 proteins contain 201 and 200 amino acids, respectively, 77.7% of which are identical. Several motifs, including the relative location and spacing of four tryptophan residues, are conserved in CHB1 and CHB2. The affinity of CHB1 to crab shell chitin is two times higher than that of CHB2. Comparative studies of various generated mutant CHB1 proteins led to the conclusion that mainly one of the exposed tryptophan residues directly contributed to the interaction with chitin. Using CHB doupled with FITC (fluoresceine isothiocyanate), a highly specific and rapid assay was developed to visualize the location of crystalline alpha-chitin within native samples by fluorescence or confocal laser microscopy. In contrast, the N-terminal domain (12 kDa) of the S. olivaceoviridis exochitinase can be used to detect alpha- and beta-chitin. The structural parameters inducing the recognition and possible loosening of alpha-chitin or of alpha- and beta-chitin are at present being investigated.

Characterization of a linear extrachromosomal DNA element (pBL1) isolated after interspecific mating between Streptomyces bambergiensis and S. lividans.

Streptomyces bambergiensis S712 harbours a giant linear plasmid PSB1 of 640 kb. After mating with the plasmidless S. lividans strain TK64, conjugants carrying a smaller extrachromosomal DNA element, pBL1, were identified. pBL1 is a 43-kb linear DNA molecule bound to a protein which protects it from attack by both 3'- and 5'-exonucleases. The absence of this protein drastically reduces the transforming efficiency of pBL1. pBL1 shares homology with linear plasmids and chromosomal DNA from S. bambergiensis strains.

Binding characteristics of CebR, the regulator of the ceb operon required for cellobiose/cellotriose uptake in Streptomyces reticuli.

The Streptomyces reticuli Avicelase (cellulase, Cell) hydrolyzes crystalline cellulose to cellooligomers, cellobiose and cellotriose which are taken up by mycelia via an ABC transport system (Ceb) induced during growth with cellobiose or cellulose. The cebR gene located upstream of the cebEFG operon was cloned in Escherichia coli in frame with six histidine-encoding codons. The resulting purified fusion protein was shown to bind to a motif of 23 bp, including a perfect 18-bp palindrome situated upstream of the cebEFG. Cytoplasmic extracts of induced, but not of uninduced S. reticuli protected the same DNA motif. Release of the CebR regulator from its operator occurs upon addition of cellopentaose which can be assumed to act as inducer within the mycelia.

Synthesis of the Streptomyces lividans maltodextrin ABC transporter depends on the presence of the regulator MalR.

During growth with maltotriose or amylose, Streptomyces lividans and Streptomyces coelicolor A3(2) synthesize a maltodextrin uptake system with highest specificity for maltotriose. The transport activity is absent in mutants of S. coelicolor A3(2) lacking a functional MalE binding protein. Cloning and sequencing data suggest that the mal operon of S. coelicolor A3(2) corresponds to the one of S. lividans and that the deduced S. lividans Reg1 amino acid sequence is identical to that of MalR from S. coelicolor A3(2). It can be concluded that both strains have the same ABC transport system for maltodextrins. The S. lividans malR was cloned in Escherichia coli in frame with six histidine-encoding codons. The resulting, purified 6HisMalR(SI) was shown to bind to two motifs within the S. lividans malR-malE intergenic region and to dissociate in the presence of maltopentaose.

Histidine aminotransferase activity in Streptomyces tendae and its correlation with nikkomycin production.

Streptomyces tendae Tü901 produces nikkomycins belonging to the nucleoside peptide antibiotics. Mutants defective in histidine catabolism were isolated and characterized with regard to their histidine ammonium-lyase activity and antibiotic synthesis. In the histidine ammonialyase-negative mutant hut-11 which was unimpaired in nikkomycin production histidine aminotransferase activity was detected as an additional histidine metabolizing enzyme. A protein exhibiting histidine aminotransferase activity could be demonstrated on non-denaturing gels of hut-11 crude extracts. Using optimized assay conditions, histidine aminotransferase activity was investigated in the strain hut-11 during growth in nikkomycin production medium. Maximal activity was reached at the end of exponential growth prior to nikkomycin production. In the presence of bromopyruvate, an effective inhibitor of histidine aminotransferase activity in vitro, production of nikkomycin Z and X was markedly reduced in hut-11.

Inactivation of fusidic acid by resistant Streptomyces strains.

Streptomyces lividans and several other Streptomyces species are resistant to the steroid-like antibiotic fusidic acid. This resistance is mediated by structural modification of the antibiotic. Using TLC, CD, UV, IR, NMR and mass spectroscopy the structure of one of the resulting inactive compounds was determined. It is derived from fusidic acid by the loss of an acetyl group and the formation of a lactone ring between C-21 and C-16. In addition, helvolic acid, a compound closely related to fusidic acid, has been shown to be modified.

Isolation of Streptomyces tendae mutants with an altered nikkomycin spectrum.

To isolate Streptomyces tendae mutants blocked in the biosynthesis of the nikkomycin nucleoside base 4-formyl-4-imidazoline-2-one, an assay was developed to detect the formation of nikkomycins containing this base during growth on solid medium. The assay is based on the reaction of the 4-formylimidazolone structure of nikkomycins with the aldehyde reagent barbituric acid leading to red-colored products. Among 18,000 N-methyl-N'-nitro-N-nitrosoguanidine treated clones tested in the barbituric acid assay, we isolated one mutant which was incapable of forming any nikkomycins containing the 4-formylimidazolone base (nikkomycins Cx, X and I) but instead produced nikkomycins containing uracil (nikkomycins C, Z and J). In addition, we isolated strains with mutations affecting the biosynthesis of 2-amino-4-hydroxy-4-(5-hydroxy-2-pyridyl)-3-methylbutyric acid, the unusual amino acid of nikkomycins Z, X, J and I. By analyzing colonies derived from single spores or protoplasts of S. tendae Tü901/395, a mutant producing besides nikkomycins Z, X, J and I, also nikkomycins Kz/Kx and Oz/Ox, we obtained strains which only formed nikkomycins Kz/Kx and Oz/Ox with 2-amino-4-hydroxy-4-(2-pyridyl)butyric acid and 2-amino-4-hydroxy-4-(5-hydroxy-2-pyridyl)-butyric acid as amino acids. Mutation of such a strain (Tü901/395-11) by UV365nm in the presence of 8-methoxypsoralen and selection of S-2-aminoethyl-L-cysteine-resistant clones led to the isolation of Tü901/AEC1 and AEC2 which produced exclusively nikkomycins Kz and Kx. According to their nikkomycin spectrum, these strains were blocked at the hydroxylation step occurring at the pyridyl residue during biosynthesis of the nikkomycin amino acid.

The cellulolytic system of Streptomyces reticuli.

The bacterium Streptomyces reticuli produces an unusual mycelia-associated cellulase (Avicelase, Cel1) which is solely sufficient to degrade crystalline cellulose to cellobiose. The enzyme consists of a binding domain, one adjoining region with unknown function, and a catalytic domain belonging to the cellulase family E. During cultivation, the strain produces a specific protease which processes the Avicelase to a truncated enzyme lacking the binding domain. The cellulase synthesis is regulated by induction (Avicel) and repression (metabolizable sugars and glycerol).

Polyphosphate at the Streptomyces lividans cytoplasmic membrane is enhanced in the presence of the potassium channel KcsA.

The distribution of polyphosphate (polyP) within the cytoplasmic membrane of Streptomyces lividans hyphae or protoplasts has been determined at high spatial resolution by elemental mapping using energy-filtered electron microscopy (EFTEM). The results revealed that polyP was best traceable after its interaction with lead ions followed by their precipitation as lead sulphide. Concomitant studies of the S.lividans wildtype (WT) strain and its co-embedded mutant DeltaK (lacking a functional kcsA gene) were conducted by labelling as the surface matrix of either one was labelled by cationic colloidal thorium dioxide. Within the WT strain, additional polyP was found to accumulate distinctly at the inner face of the cytoplasmic membrane. After removal of the cell wall (within protoplasts), the polyP-derived lead-sulphide (PbS) precipitate formed clusters of fibrillar material extending up to 50 nm into the cytoplasm. This feature was absent in the DeltaK mutant strain. Together the results revealed that the presence of the KcsA channel and the structured polyP coincide.

Deletion and amplification of DNA sequences in melanin-negative variants of Streptomyces reticuli.

The sporulating wild type of Streptomyces reticuli produces the pigment melanin. Though the ability to synthesize tyrosinase is frequently lost, it was demonstrated, that the structural gene coding for this enzyme is not located on the extrachromosomal DNA of the wild type strain or melanin-positive variants. Melanin negative variants were found to have lost this gene and to contain amplified nucleotide sequences within their genomes.

Plasmid loss and changes within the chromosomal DNA of Streptomyces reticuli.

The sporulating wild-type strain of Streptomyces reticuli, which produces a melanin pigment and the macrolide leucomycin, contains plasmid DNA of 48 to 49 megadaltons. Plasmidless variants had an altered secondary metabolism and a changed antibiotic resistance pattern. By using a new colony hybridization technique developed for streptomycetes, it could be shown that plasmidless variants could be transformed with the wild-type plasmid DNA, which, however, is quickly lost from regenerated mycelium. In contrast to the wild-type strain, the plasmidless variants contain amplified nucleotide sequences within the chromosomal DNA. The number and size of these sequences vary with the strain tested. Hybridization studies revealed that the reiterated sequences are neither amplified ribosomal nor plasmid genes, but are present in small concentrations within the wild-type chromosome. Some of them share extensive homologies with each other and are located at different positions within the chromosome. It is assumed that alterations in secondary metabolism are due to changes within both the chromosomal and the extrachromosomal DNAs of S. reticuli.

Recognition and degradation of chitin by streptomycetes.

Chitin is the second most abundant renewable polysaccharide, as it is a component of the exoskeleton of many organisms and of the cell walls of numerous fungi. Most streptomycetes secrete a number of chitinases, hydrolyzing chitin to oligomers, chitobiose or N-acetylglucosamine which can be utilized as carbon or nitrogen source. The chitinases of several streptomycetes have been shown to have a modular arrangement comprising catalytic, substrate binding as well as linker domains. Moreover, during growth in the presence of chitin-containing substrates, many Streptomyces strains have been shown to secrete formerly unknown, small (about 200 aa) chitin binding proteins (CHBs) which lack enzymatic activity and specifically target and invade chitin. Several motifs, including the relative location and spacing of four tryptophan residues, are conserved in the investigated CHB types, CHB1 and CHB2. The affinity of CHB1 to crab shell chitin is two times higher than that of CHB2. Comparative studies of various generated mutant CHB1 proteins led to the conclusion that it is one of the exposed tryptophan residues that directly contributes to the interaction with chitin. On the basis of immunological, biochemical and physiological studies, it can be concluded that the CHBs act like a glue with which streptomycetes target chitin-containing samples or organisms. The ecological implications of these findings are discussed.

A Simple and Rapid Method of Transformation of Streptomyces rimosus R6 and Other Streptomycetes by Electroporation.

Usually plasmid DNA is introduced into Streptomyces strains by polyethylene glycol-mediated transformation of protoplasts. However, many Streptomyces strains are only poorly or not at all transformable via protoplasts. Therefore, we have optimized the parameters critical for the application of electrotransformation of plasmid DNA into Streptomyces species. The most critical parameters evaluated for electrotransformation of the model strain Streptomyces rimosus R6 were the pretreatment of mycelia, buffer composition, and electric field strength. The electrocompetent mycelia were prepared from 24-h-old cultures, treated mildly with lysozyme, resuspended in sucrose-glycerol-polyethylene glycol buffer, and stored in aliquots at -70 deg C. The electric field strength of 10 kV/cm at 400 (Omega) and a capacitance of 25 (mu)F was applied. The method is simple and rapid, yielding transformant colonies in 48 to 72 h. Efficiencies of 10(sup5) to 10(sup6) transformants per (mu)g of plasmid DNA were reproducibly achieved for S. rimosus R6 and its mutants, and these numbers were 10(sup2) to 10(sup3) higher than those attained by polyethylene glycol-assisted transformation of protoplasts. In addition, we show that electroporation can be applied to other Streptomyces species, such as S. lividans 66, S. coelicolor A3(2), and an S. venezuelae strain. This last one could not be transformed by the standard protoplast procedure. Our data suggest that, because of the diversity of streptomycetes, the conditions have to be optimized for each strain.

Visualization of alpha-chitin with a specific chitin-binding protein (CHB1) from Streptomyces olivaceoviridis.

Recently we identified a so far unique protein (CHB1) which interacts specifically with crystalline alpha-chitin. Having optimized the binding conditions for CHB1 coupled with fluorescein isothiocyanate (FITC), we succeeded in developing a highly sensitive assay to detect alpha-chitin. CHB1-FITC interacted neither with beta- or colloidal chitin nor with chitooligomers or cellulose. With the help of fluorescence or confocal laser microscopy, the relative location of crystalline alpha-chitin within various native samples of fungi and other organisms can be clearly and rapidly visualized.

The synthesis of the Streptomyces reticuli cellulase (avicelase) is regulated by both activation and repression mechanisms.

The Streptomyces reticuli cellulase (Cell, Avicelase) hydrolyzes crystalline cellulose (Avicel) efficiently to cellobiose. The synthesis of the enzyme is induced by Avicel and repressed by glucose. DNA-binding proteins were purified from induced S. reticuli mycelia by affinity chromatography using the upstream region of the cell gene linked to Sepharose. The enriched protein(s) provoked a gel electrophoresis mobility shift of the upstream region, irrespective of the presence or absence of a 14-bp palindromic sequence, and enhanced the transcription of the cell gene by the S. reticuli RNA polymerase in vitro. The binding site (GTGACTGAGCGCCG) for the protein(s) was located in the vicinity of a DNA bend upstream of the transcriptional start site. Results of physiological studies, deletion and gel-shift analyses lead to the conclusion that a 14-bp palindrome (TGGGAGCGCTCCCA)--situated between the transcriptional start site and the structure gene--is the operator for a repressor protein. The data presented suggest that the two identified cis-acting elements, in cooperation with an activator and a repressor, mediate regulation of cell transcription.

Genetic instability and DNA amplification in Streptomyces lividans 66.

Streptomyces lividans 66 exhibits genetic instability, involving sequential loss of resistance to chloramphenicol (Cams) and subsequent mutation of argG. Associated with this instability is the amplification of a 5.7-kilobase (kb) amplified DNA sequence (ADS). We have characterized a second, independent pathway of genetic instability, involving sequential loss of resistance to tetracycline (Tets) followed by mutation in nitrogen assimilation (Ntr). We detected DNA amplification in many of these mutant strains, as well as other reiterations coresident with the 5.7-kb ADS in Cams Arg mutants. However, in contrast to the 5.7-kb ADS, none of the novel elements were observed to amplify at high frequency. The mutation of argG is due to a deletion, one endpoint of which is defined by the 5.7-kb ADS. This amplification derives from a structure, the tandemly duplicated amplifiable unit of DNA (AUD), present in the wild-type genome. We found that progenitor strains containing just a single-copy AUD failed to reproducibly generate amplification of this element in Cams argG mutants, and DNA deletion endpoints proximal to the element were found to be unspecific. These results suggest that a duplicated AUD structure is required for high-frequency amplification and that this reiteration can subsequently buffer the extent of deletion formation in the relevant chromosomal region.