Streptomyces
Over the last century, Streptomyces bacteria – and their metabolic products – have revolutionized modern medicine. These little pharmaceutical factories produce a vast array of natural products that have been co-opted for medical and agricultural therapies. In addition to their metabolic sophistication, Streptomyces also exhibit remarkable developmental and regulatory complexity.
Guest-edited by Dr Marie Elliot, this collection of keynote research articles will highlight fascinating aspects of Streptomyces biology, and the advances that are providing us with newfound insight and appreciation for these extraordinary bacteria.
Collection Contents
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Isolation and antimicrobial activities of actinobacteria closely associated with liquorice plants Glycyrrhiza glabra L. and Glycyrrhiza inflate BAT. in Xinjiang, China
A total of 218 actinobacteria strains were isolated from wild perennial liquorice plants Glycyrrhiza glabra L. and Glycyrrhiza. inflate BAT. Based on morphological characteristics, 45 and 32 strains from G. inflate and G. glabra, respectively, were selected for further analyses. According to 16S rRNA sequence analysis, most of the strains belonged to genus Streptomyces and a few strains represented the rare actinobacteria Micromonospora, Rhodococcus and Tsukamurella. A total of 39 strains from G. inflate and 27 strains from G. glabra showed antimicrobial activity against at least one indicator organism. The range of the antimicrobial activity of the strains isolated from G. glabra and G. inflate was similar. A total of 34 strains from G. inflate and 29 strains from G. glabra carried at least one of the genes encoding polyketide synthases, non-ribosomal peptide synthetase and FADH2-dependent halogenase. In the type II polyketide synthase KSα gene phylogenetic analysis, the strains were divided into two major clades: one included known spore pigment production-linked KSα sequences and other sequences were linked to the production of different types of aromatic polyketide antibiotics. Based on the antimicrobial range, the isolates that carried different KSα types were not separated from each other or from the isolates that did not carry KSα. The incongruent phylogenies of 16S rRNA and KSα genes indicated that the KSα genes were possibly horizontally transferred. In all, the liquorice plants were a rich source of biocontrol agents that may produce novel bioactive compounds.
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Isolation of the biosynthetic gene cluster for tautomycetin, a linear polyketide T cell-specific immunomodulator from Streptomyces sp. CK4412
More LessThe bacterial genus Streptomyces has long been appreciated for its ability to produce various kinds of medically important secondary metabolites, such as antibiotics, anti-tumour agents, immunosuppressants and enzyme inhibitors. Tautomycetin (TMC), which is produced by Streptomyces sp. CK4412, is a novel activated T cell-specific immunosuppressive compound with an ester bond linkage between a terminal cyclic anhydride moiety and a linear polyketide chain bearing an unusual terminal alkene. Using a Streptomyces polyketide methylmalonyl-CoA acyltransferase gene as a probe, three overlapping cosmids were isolated from the genomic library of TMC-producing Streptomyces sp. CK4412. Sequence information of an approximately 70 kb contiguous DNA region revealed two multi-modular type I polyketide synthases (PKSs), and 12 additional gene products presumably involved in TMC biosynthesis. The deduced roles for most of the TMC PKS catalytic domains were consistent with the expected functions necessary for TMC chain elongation and processing. In addition, disruption of a putative TMC acyl-CoA transferase gene, located upstream of the PKS gene locus, completely abolished TMC biosynthesis. Taken together, these data provide strong supporting evidence that the cloned gene cluster identified in this study is responsible for TMC biosynthesis in Streptomyces sp. CK4412, and set the stage for detailed genetic and biochemical studies of the biosynthesis of this important metabolite.
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Inactivation of the 20S proteasome in Streptomyces lividans and its influence on the production of heterologous proteins
More LessProteasomes are self-compartmentalizing proteases first discovered in eukaryotes but also occurring in archaea and in bacteria belonging to the order Actinomycetales. In bacteria, proteasomes have so far no known function. In order to evaluate the influence of the 20S proteasome on the production of heterologous proteins by Streptomyces lividans TK24, the production of a number of heterologous proteins, including soluble human tumour necrosis factor receptor II (shuTNFRII) and salmon calcitonin (sCT), was compared with the wild-type TK24, a proteasome-deficient mutant designated PRO41 and a strain complemented for the disrupted proteasome genes (strain PRO41R). S. lividans cells lacking intact proteasome genes are phenotypically indistinguishable from the wild-type or the complemented strain containing functional proteasomes. Using the expression and secretion signals of the subtilisin inhibitor of Streptomyces venezuelae CBS762.70 (Vsi) for shuTNFRII and those of tyrosinase of Streptomyces antibioticus (MelC1) for the production of sCT, both proteins were secreted in significantly higher amounts in the strain PRO41 than in the wild-type S. lividans TK24 or the complemented strain PRO41R. However, the secretion of other heterologous proteins such as shuTNFRI was not enhanced in the proteasome-deficient strain. This suggests that S. lividans TK24 can degrade some heterologous proteins in a proteasome-dependent fashion. The proteasome-deficient strain may therefore be useful for the efficient production of these heterologous proteins.
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Isolation and Characterization of Actinophages Infecting Streptomyces Species and Their Interaction with Host Restriction-Modification Systems
More LessNine different phages, øA1 to øA9, were isolated from soil samples on Streptomyces antibioticus ATCC 11891, a strain which produces the macrolide antibiotic oleandomycin. Each phage displayed a different host-range which did not extend beyond Streptomyces species. Host-range was mainly limited by adsorption specificity and host-controlled restriction-modification systems. All the phages except øA3 and øA9 formed turbid plaques on S. antibioticus, but did not lysogenize this host. However, three of the phages (øA5, øA7 and øA8) were identified as temperate, since they were able to lysogenize other Streptomyces strains. All of the phages were morphologically similar and belonged to group B of Bradley’s classification. They had polyhedral heads and long, non-contractile tails. øA5, øA6 and øA7 had a base plate at the terminal end of the tail. Analysis with restriction endonucleases indicated that the nine phages contained double-strandpd DNA. Hybridization studies between the phage genomes, together with results on genome structure, allowed classification of the phages into five groups: (I) øA2, øA4 and øA9, (II) øA3 and øA8, (III) øA7, (IV) øA5 and øA6, and (V) øA1.
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