Andriy Luzhetskyy

Type II polyketide synthases: gaining a deeper insight into enzymatic teamwork

This review covers advances in understanding of the biosynthesis of polyketides produced by type II PKS systems at the genetic, biochemical and structural levels.

SimReg1 is a master switch for biosynthesis and export of simocyclinone D8 and its precursors

Analysis of the simocyclinone biosynthesis (sim) gene cluster of Streptomyces antibioticus Tü6040 led to the identification of a putative pathway specific regulatory gene simReg1. In silico analysis places the SimReg1 protein in the OmpR-PhoB subfamily of response regulators. Gene replacement of simReg1 from the S. antibioticus chromosome completely abolishes simocyclinone production indicating that SimReg1 is a key regulator of simocyclinone biosynthesis. Results of the DNA-shift assays and reporter gene expression analysis are consistent with the idea that SimReg1 activates transcription of simocyclinone biosynthesis, transporter genes, regulatory gene simReg3 and his own transcription. The presence of extracts (simocyclinone) from S. antibioticus Tü6040 × pSSimR1-1 could dissociate SimReg1 from promoter regions. A preliminary model for regulation of simocyclinone biosynthesis and export is discussed.

β-Glucuronidase as a Sensitive and Versatile Reporter in Actinomycetes

ABSTRACT Here we describe a versatile and sensitive reporter system for actinomycetes that is based on gusA, which encodes the β-glucuronidase enzyme. A series of gusA-containing transcriptional and translational fusion vectors were constructed and utilized to study the regulatory cascade of the phenalinolactone biosynthetic gene cluster. Furthermore, these vectors were used to study the efficiency of translation initiation at the ATG, GTG, TTG, and CTG start codons. Surprisingly, constructs using a TTG start codon showed the best activity, whereas those using ATG or GTG were approximately one-half or one-third as active, respectively. The CTG fusion showed only 5% of the activity of the TTG fusion. A suicide vector, pKGLP2, carrying gusA in its backbone was used to visually detect merodiploid formation and resolution, making gene targeting in actinomycetes much faster and easier. Three regulatory genes, plaR1, plaR2, and plaR3, involved in phenalinolactone biosynthesis were efficiently replaced with an apramycin resistance marker using this system. Finally, we expanded the genetic code of actinomycetes by introducing the nonproteinogenic amino acid N-epsilon-cyclopentyloxycarbonyl-l-lysine with the GusA protein as a reporter.

Design, construction and characterisation of a synthetic promoter library for fine-tuned gene expression in actinomycetes.

We developed a synthetic promoter library for actinomycetes based on the -10 and -35 consensus sequences of the constitutive and widely used ermEp1 promoter. The sequences located upstream, in between and downstream of these consensus sequences were randomised using degenerate primers and cloned into an integrative plasmid upstream of the gusA reporter gene. Using this system, we created promoters with strengths ranging from 2% to 319% compared with ermEp1. The strongest synthetic promoter was used in a proof-of-principle approach to achieve the overexpression of a natural type III polyketide synthase. We observed high correlation between the number of gusA reporter gene RNA-Seq reads and the GusA reporter protein activity, indicating that GusA is indeed a transcription-level reporter system.

Glycosyltransferases, Important Tools for Drug Design

An increasing appreciation of carbohydrates as components of natural products has uncovered new opportunities in carbohydrate-based drug design. Glycosylated natural products produced by microorganisms contain a variety of different sugars. Usually the biosynthetic pathways to deoxysugars start from a monosacchride-1-phosphate which is converted to a NDP-hexose by a nucleotidyltransferase. Modification of this intermediate by different enzymes (e.g. dehydratases, epimerases, aminotransferases) yields the final sugar. In contrast to microorganisms, plant products mostly contain glucose, galactose, rhamnose and xylose as structural elements. In all organisms the nucleotide-activated sugar is attached to an aglycon by a glycosyltransferrase (GT). As no single universal GT has been uncovered yet, accomplishing the generation of novel glycosylated compounds requires a deep understanding of the function of glycosyltransferases (GTs) and its specificity. In this review we will present important drugs that contain sugar components. We will give an overview about the existing natural product GTs and we will discuss the structural features of GTs. Through specific examples within different compound classes, we will highlight recent examples of metabolic and combinatorial engineering approaches successfully applied to the production of novel glycosylated compounds.

Site-Specific Recombination Strategies for Engineering Actinomycete Genomes

ABSTRACT The feasibility of using technologies based on site-specific recombination in actinomycetes was shown several years ago. Despite their huge potential, these technologies mostly have been used for simple marker removal from a chromosome. In this paper, we present different site-specific recombination strategies for genome engineering in several actinomycetes belonging to the genera Streptomyces, Micromonospora, and Saccharothrix. Two different systems based on Cre/loxP and Dre/rox have been utilized for numerous applications. The activity of the Cre recombinase on the heterospecific loxLE and loxRE sites was similar to its activity on wild-type loxP sites. Moreover, an apramycin resistance marker flanked by the loxLERE sites was eliminated from the Streptomyces coelicolor M145 genome at a surprisingly high frequency (80%) compared to other bacteria. A synthetic gene encoding the Dre recombinase was constructed and successfully expressed in actinomycetes. We developed a marker-free expression method based on the combination of phage integration systems and site-specific recombinases. The Cre recombinase has been used in the deletion of huge genomic regions, including the phenalinolactone, monensin, and lipomycin biosynthetic gene clusters from Streptomyces sp. strain Tü6071, Streptomyces cinnamonensis A519, and Streptomyces aureofaciens Tü117, respectively. Finally, we also demonstrated the site-specific integration of plasmid and cosmid DNA into the chromosome of actinomycetes catalyzed by the Cre recombinase. We anticipate that the strategies presented here will be used extensively to study the genetics of actinomycetes.

Marker removal from actinomycetes genome using Flp recombinase

We report here a system for the functional expression of the Flp recombinase in several actinomycetes: Streptomyces coelicolor, S. lividans, and Saccharotrix espanaensis. We have constructed a synthetic gene encoding the Flp recombinase with a GC content of 60.6% optimized for expression in high-GC bacteria. Using the synthetic flp(a) gene, we have removed an apramycin resistance gene flanked by FRT sites from the chromosome of actinomycetes with an efficiency of 40%. Sequencing the region of chromosome showed that excision of the apramycin cassette by Flp recombinase was specific.

Functional expression of the Cre recombinase in actinomycetes

Site-specific recombinases revolutionized “in vivo” genetic engineering because they can catalyze precise excisions, integrations, inversions, or translocations of DNA between their distinct recognition target sites. We have constructed a synthetic gene encoding Cre recombinase with the GC content 67.7% optimized for expression in high-GC bacteria and demonstrated this gene to be functional in Streptomyces lividans. Using the synthetic cre(a) gene, we have removed an apramycin resistance gene flanked by loxP sites from the chromosome of S. lividans with 100% efficiency. Sequencing of the chromosomal DNA part showed that excision of the apramycin cassette by Cre recombinase was specific.

Generation of novel landomycins M and O through targeted gene disruption.

Two genes from Streptomyces cyanogenous S136 that encode the reductase LanZ4 and the hydroxylase LanZ5, which are involved in landomycin A biosynthesis, were characterized by targeted gene inactivation. Analyses of the corresponding mutants as well as complementation experiments have allowed us to show that LanZ4 and LanZ5 are responsible for the unique C‐11‐hydroxylation that occurs during landomycin biosynthesis. Compounds accumulated by the lanZ4/Z5 mutants are the previously described landomycin F and the new landomycins M and O.

LanGT2 Catalyzes the First Glycosylation Step during landomycin A biosynthesis.

The glycosyltransferase LanGT2 is involved in the biosynthesis of the hexasaccharide side chain of the angucyclic antibiotic landomycin A. Its function was elucidated by targeted gene inactivation of lanGT2. The main metabolite of the obtained mutant was identified as tetrangulol (4), the progenitor of the landomycin aglycon (7). The lack of the sugar side chain indicates that LanGT2 catalyzes the priming glycosyl transfer in the hexasaccharide biosynthesis: the attachment of a D‐olivose to O‐8 of the polyketide backbone. Heterologous expression of urdGT2 from S. fradiae Tü2717 in this mutant resulted in the production of a novel C‐glycosylated angucycline (6).