Identification of Streptomyces violaceoruber Tü22 genes involved in the biosynthesis of granaticin

A 50 kb region of DNA fromStreptomyces violaceoruber Tü22, containing genes encoding proteins involved in the biosynthesis of granaticin, was isolated. The DNA sequence of a 7.3 kb fragment from this region, located approximately 10 kb from the genes that encode the polyketide synthetase responsible for formation of the benzoisochromane quinone skeleton, revealed five open reading frames (ORF1-ORF5). The deduced amino acid sequence of GraE, encoded by ORF2, shows 60.8% identity (75.2% similarity) to a dTDP-glucose dehydratase (StrE) fromStreptomyces griseus. Cultures ofEscherichia coli containing plasmids with ORF2, on a 2.1 kbBamHI fragment, were able to catalyze the formation of dTDP-4-keto-6-deoxy-d-glucose from dTDP-glucose at 5 times the rate of control cultures, confirming that ORF2 encodes a dTDP-glucose dehydratase. The amino acid sequence encoded by ORF3 (GraD) is 51.4% identical (69.9% similar) to that of StrD, a dTDP-glucose synthase fromStreptomyces griseus. The amino acid sequence encoded by ORF4 shares similarities with proteins that confer resistance to tetracycline and methylenomycin, and is suggested to be involved in transporting granaticin out of the cells by an active efflux mechanism. Dedicated to Professor Satoshi Ōmura, a pioneer in the field of antibiotics, on the occasion of his 60th birthday     

A strategy for cloning glycosyltransferase genes involved in natural product biosynthesis

The soil-borne and marine gram-positive Actinomycetes are a particularly rich source of carbohydrate-containing metabolites. With the advent of molecular tools and recombinant methods applicable to Actinomycetes, it has become feasible to investigate the biosynthesis of glycosylated compounds at genetic and biochemical levels, which has finally set the basis for engineering novel natural product derivatives. Glycosyltransferases (GT) are key enzymes for the biosynthesis of many valuable natural products that contain sugar moieties and they are most important for drug engineering. So far, the direct cloning of unknown glycosyltransferase genes by polymerase chain reaction (PCR) has not been described because glycosyltransferases do not share strongly conserved amino acid regions. In this study, we report a method for cloning of novel so far unidentified glycosyltransferase genes from different Actinomycetes strain. This was achieved by designing primers after a strategy named consensus-degenerate hybrid oligonucleotide primer (CODEHOP). Using this approach, 22 novel glycosyltransferase encoding genes putatively involved in the decoration of polyketides were cloned from the genomes of 10 Actinomycetes. In addition, a phylogenetic analysis of glycosyltransferases from Actinomycetes is shown in this paper.     

A novel dark-inducible protein, LeDI-2, and its involvement in root-specific secondary metabolism in Lithospermum erythrorhizon

Lithospermum erythrorhizon produces red naphthoquinone pigments that are shikonin derivatives. They are accumulated exclusively in the roots of this plant. The biosynthesis of shikonin is strongly inhibited by light, even though other environmental conditions are optimized. Thus, L. erythrorhizon dark-inducible genes (LeDIs) were isolated to investigate the regulatory mechanism of shikonin biosynthesis. LeDI-2, showing the strict dark-specific expression, was further characterized by use of cell suspension cultures and hairy root cultures as model systems. Its mRNA accumulation showed a similar pattern with that of shikonin. In the intact plants LeDI-2 expression was observed solely in the root, and the longitudinal distribution of its mRNA was also in accordance to that of shikonin. LeDI-2 encoded a very hydrophobic polypeptide of 114 amino acids that shared significant similarities with some root-specific polypeptides such as ZRP3 (maize) and RcC3 (rice). Reduction of LeDI-2 expression by its antisense DNA in hairy roots of L. erythrorhizon decreased the shikonin accumulation, whereas other biosynthetic enzymes, e.g. p-hydroxybenzoic acid:geranyltransferase, which catalyzed a critical biosynthetic step, showed similar activity as the wild-type clone. This is the first report of the gene that is involved in production of secondary metabolites without affecting biosynthetic enzyme activities.     

Complete genome sequence of producer of the glycopeptide antibiotic Aculeximycin Kutzneria albida DSM 43870T,a representative of minor genus of Pseudonocardiaceae

Background

Kutzneria is a representative of a rarely observed genus of the family Pseudonocardiaceae. Kutzneria species were initially placed in the Streptosporangiaceae genus and later reconsidered to be an independent genus of the Pseudonocardiaceae. Kutzneria albida is one of the eight known members of the genus. This strain is a unique producer of the glycosylated polyole macrolide aculeximycin which is active against both bacteria and fungi. Kutzneria albida genome sequencing and analysis allow a deeper understanding of evolution of this genus of Pseudonocardiaceae, provide new insight in the phylogeny of the genus, as well as decipher the hidden secondary metabolic potential of these rare actinobacteria.

Results

To explore the biosynthetic potential of Kutzneria albida to its full extent, the complete genome was sequenced. With a size of 9,874,926 bp, coding for 8,822 genes, it stands alongside other Pseudonocardiaceae with large circular genomes. Genome analysis revealed 46 gene clusters potentially encoding secondary metabolite biosynthesis pathways. Two large genomic islands were identified, containing regions most enriched with secondary metabolism gene clusters. Large parts of this secondary metabolism “clustome” are dedicated to siderophores production.

Conclusions

Kutzneria albida is the first species of the genus Kutzneria with a completely sequenced genome. Genome sequencing allowed identifying the gene cluster responsible for the biosynthesis of aculeximycin, one of the largest known oligosaccharide-macrolide antibiotics. Moreover, the genome revealed 45 additional putative secondary metabolite gene clusters, suggesting a huge biosynthetic potential, which makes Kutzneria albida a very rich source of natural products. Comparison of the Kutzneria albida genome to genomes of other actinobacteria clearly shows its close relations with Pseudonocardiaceae in line with the taxonomic position of the genus.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2164-15-885) contains supplementary material, which is available to authorized users.     

IncP plasmids are most effective in mediating conjugation between Escherichia coli and streptomycetes

Mobilizable shuttle plasmids containing the origin of transfer (oriT) region of plasmid F (IncFI), ColIb-P9 (IncI1), and RP4/RP1 (IncPalpha) were constructed to test the ability of the cognate conjugation system to mediate gene transfer from Escherichia coli to Streptomyces. The conjugative system of the IncPalpha plasmids was shown to be most effective in conjugative transfer, giving peak values of (2.7 +/- 0.2) x 10(-2) S. lividans TK24 exconjugants per recipient cell. To assess whether the mating-pair formation system or the DNA-processing apparatus of the IncPalpha plasmids is crucial in conjugative transfer, an assay with an IncQ-based mobilizable plasmid (RSF1010) specifying its own DNA-processing system was developed. Only the IncPalpha plasmid mobilized the construct to S. lividans indicating that the mating-pair formation system is primarly responsible for the promiscuous transfer of the plasmids between E. coli and Streptomyces. Dynamic of conjugative transfer from E. coli to S. lividans was investigated and exconjugants starting from the first hour of mating were obtained.     

The active conformation of avilamycin A is conferred by AviX12, a radical AdoMet enzyme

The antibiotic avilamycin A is produced by Streptomyces viridochromogenes Tü57. Avilamycin belongs to the family of orthosomycins with a linear heptasaccharide chain linked to a terminal dichloroisoeverninic acid as aglycone. The gene cluster for avilamycin biosynthesis contains 54 open reading frames. Inactivation of one of these genes, namely aviX12, led to the formation of a novel avilamycin derivative named gavibamycin N1. The structure of the new metabolite was confirmed by mass spectrometry (MS) and NMR analysis. It harbors glucose as a component of the heptasaccharide chain instead of a mannose moiety in avilamycin A. Antibacterial activity tests against a spectrum of Gram-positive organisms showed that the new derivative possesses drastically decreased biological activity in comparison to avilamycin A. Thus, AviX12 seems to be implicated in converting avilamycin to its bioactive conformation by catalyzing an unusual epimerization reaction. Sequence comparisons grouped AviX12 in the radical S-adenosylmethionine protein family. AviX12 engineered with a His tag was overexpressed in Escherichia coli and purified by affinity chromatography. The iron sulfur cluster [Fe-S] present in radical AdoMet enzymes was detected in purified AviX12 by means of electron paramagnetic resonance spectroscopy.     

Genome sequence of Streptomyces sp. strain Tü6071

Streptomyces sp. Tü6071 is a soil-dwelling bacterium which has a highly active isoprenoid biosynthesis. Isoprenoids are important precursors for biopharmaceutical molecules such as antibiotics or anticancer agents, e.g., landomycin. Streptomyces sp. Tü6071 produces the industrially important terpene glycosides phenalinolactones, which have antibacterial activity against several Gram-positive bacteria. The availability of the genome sequence of Streptomyces sp. Tü6071 allows for understanding the biosynthesis of these pharmaceutical molecules and will facilitate rational genome modification to improve industrial use.