Jiequn Wu

Genetic Modulation of the Overexpression of Tailoring Genes eryK and eryG Leading to the Improvement of Erythromycin A Purity and Production in Saccharopolyspora erythraea Fermentation

ABSTRACT Erythromycin A (Er-A) is the most potent and clinically important member in the Er family produced by Saccharopolyspora erythraea. Er-B and Er-C, which are biologically much less active and cause greater side effects than Er-A, serve as the intermediates for Er-A biosynthesis and impurities in fermentation processes of many industrial strains. In this study, systematical modulation of the amounts of tailoring enzymes EryK (a P450 hydroxylase) and EryG (an S-adenosylmethionine-dependent O-methyltransferase) was carried out by genetic engineering in S. erythraea, including alterations of gene copy number ratio and organization and integrating the locus on the chromosome by homologous recombination. Introduction of additional eryK and eryG genes into S. erythraea showed significant impacts on their transcription levels and enhanced the biotransformation process from Er-D to Er-A with gene dose effects. At the eryK/eryG copy number ratio of 3:2 as well as their resultant transcript ratio of around 2.5:1 to 3.0:1, Er-B and Er-C were nearly completely eliminated and accordingly converted to Er-A, and the Er titer was improved by around 25% in the recombinant strain ZL1004 (genotype PermK*-K-K-G + PermE*-K + PermA*-G) and ZL1007 (genotype PermK*-K-G-K + PermE*-K + PermA*-G). This study may contribute to the continuous efforts toward further evaluation of the Er-producing system, with the aims of improving Er-A purity and production at the fermentation stage and lowering the production costs and environmental concerns in industry.

Toward improvement of erythromycin A production in an industrial Saccharopolyspora erythraea strain via facilitation of genetic manipulation with an artificial attB site for specific recombination.

ABSTRACT Large-scale production of erythromycin A (Er-A) relies on the organism Saccharopolyspora erythraea, in which lack of a typical attB site largely impedes the application of phage ΦC31 integrase-mediated recombination into site-specific engineering. We herein report construction of an artificial attB site in an industrial S. erythraea strain, HL3168 E3, in an effort to break the bottleneck previously encountered during genetic manipulation mainly from homologous or unpredictable nonspecific integration. Replacement of a cryptic gene, nrps1-1, with a cassette containing eight attB DNA sequences did not affect the high Er-producing ability, setting the stage for precisely engineering the industrial Er-producing strain for foreign DNA introduction with a reliable conjugation frequency. Transfer of either exogenous or endogenous genes of importance to Er-A biosynthesis, including the S-adenosylmethionine synthetase gene for positive regulation, vhb for increasing the oxygen supply, and two tailoring genes, eryK and eryG, for optimizing the biotransformation at the late stage, was achieved by taking advantage of this facility, allowing systematic improvement of Er-A production as well as elimination of the by-products Er-B and Er-C in fermentation. The strategy developed here can generally be applicable to other strains that lack the attB site.

Insight into bicyclic thiopeptide biosynthesis benefited from development of a uniform approach for molecular engineering and production improvement

The ribosomal origin of thiopeptide antibiotics, a class of sulfur-rich and highly modified poly(thi)azolyl natural products, has recently been uncovered and features complex post-translational modifications (PTMs) of a precursor peptide. Based on molecular engineering and production improvement, we report insight into the biosynthesis of two bicyclic thiopeptide compounds, thiostrepton and nosiheptide. The PTMs of thiostrepton tolerate variations in the first two amino acids of the core peptide part of the precursor peptide: (1) the mutation of Ile1 to Val had no apparent effect on molecular maturation, suggesting that attachment of the quinaldic moiety at position 1 is not residue-dependent for the construction of the side ring system; and (2) the change of Ala2 to Ser led exclusively to the production of an analog that bears a corresponding dehydroamino acid residue, indicating that dehydration at position 2 is site-selective or that the oxazoline formed by cyclodehydration is inaccessible for maturation. For nosiheptide biosynthesis in particular, we provide the first structural evidence that construction of the specific side ring system precedes formation of the common central heterocycle domain and therefore propose that formation of a characteristic thiopeptide framework interweaves both common and specific PTMs that are interdependent. The above efforts benefited from the development of a uniform approach to examine the effectiveness for trans expression of gene encoding precursor peptides and associated PTM capacity. This approach is independent of knowledge regarding organism-specific regulatory mechanisms and potentially applicable to other systems that produce ribosomally synthesized peptide natural products.

Effect of Stereochemistry of Avermectin-Like 6,6-Spiroketals on Biological Activities and Endogenous Biotransformations in Streptomyces avermectinius

Natural avermectins (AVEs) share a 6,6‐spiroketal moiety with an exclusive R configuration at the C21 spirocyclic junction. Herein, we report the characterization of nine AVE‐like spiroketals of two types (C21 S and R) in a mutant strain that lacks spirocyclase activity. Comparative analysis of their structures facilitated evaluation of the effect of stereochemistry on endogenous biotransformations and biological activities of the spiroketals.