Acyltransferase domain substitutions in erythromycin polyketide synthase yield novel erythromycin derivatives

Ruan, Xiaoan; Pereda, Ana; Stassi, Diane L.; Zeidner, David; Summers, Richard G.; Jackson, Marianna; Shivakumar, A. G.; Kakavas, Stephan J.; Staver, Michael J.; Donadio, Stefano; Katz, Leonard

doi:10.1128/jb.179.20.6416-6425.1997

Cited by 134 publications

(104 citation statements)

References 44 publications

(36 reference statements)

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“…PKS reassembly can be manipulated on the levels of domain, module, and PKS gene. To date, there are a number of successful precedents for structural modification through manipulation of domains (25)(26)(27)(28) and modules (29,30), but structural modifications through PKS gene replacement are little reported. In fact, domain/module swaps are often only marginally successful or entirely unsuccessful, leading to only very small amounts of the desired compound or no product at all (26-28, 31, 32).…”

Section: Discussionmentioning

confidence: 99%

Gene Replacement for the Generation of Designed Novel Avermectin Derivatives with Enhanced Acaricidal and Nematicidal Activities

Huang

Chen²,

Zhang

et al. 2015

Appl Environ Microbiol

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c Avermectin (AVM) and ivermectin (IVM) are potent pesticides and acaricides which have been widely used during the past 30 years. As insect resistance to AVM and IVM is greatly increasing, alternatives are urgently needed. Here, we report two novel AVM derivatives, tenvermectin A (TVM A) and TVM B, which are considered a potential new generation of agricultural and veterinary drugs. The molecules of the TVMs were designed based on structure and pharmacological property comparisons among AVM, IVM, and milbemycin (MBM). To produce TVMs, a genetically engineered strain, MHJ1011, was constructed from Streptomyces avermitilis G8-17, an AVM industrial strain. In MHJ1011, the native aveA1 gene was seamlessly replaced with milA1 from Streptomyces hygroscopicus. The total titer of the two TVMs produced by MHJ1011 reached 3,400 mg/liter. Insecticidal tests proved that TVM had enhanced activities against Tetranychus cinnabarinus and Bursaphelenchus xylophilus, as desired. This study provides a typical example of exploration for novel active compounds through a new method of polyketide synthase (PKS) reassembly for gene replacement. The results of the insecticidal tests may be of use in elucidating the structure-activity relationship of AVMs and MBMs.A vermectins (AVMs) are a series of 16-membered macrocyclic lactone derivatives with potent anthelmintic and insecticidal properties (1, 2). Ivermectin (IVM), a hydrogenated product of AVM B1, has been one of the best-selling antiparasitics since 1981 (3). However, as insect resistance to AVM (4) and IVM (5-7) is on the rise, alternatives or new products with enhanced potency and expanded spectra of activity are urgently needed.Milbemycins (MBMs) are another group of 16-membered macrolides that share similar structures with AVMs. The insecticidal activity of milbemectin (a mixture of MBMs A3 and A4) against some parasites is higher than those of AVM and IVM, while the toxicity is significantly lower (8).The structural differences among AVM, IVM, and MBM are in C-25, C-22-23, and C-13 ( Fig. 1) (9). IVM differs from AVM in C-22-23 (the former has a saturated bond, whereas the latter has a double bond in that position), but its toxicity is lower than that of AVM (10), implying that the single bond in C-22-23 should be the better structure in terms of safety. The major structural difference between IVM and MBM is a bisoleandrosyloxy substituent attached at C-13 of IVM, whereas that position is unsubstituted in MBM. Also, there are different alkyl substituents at C-25: in IVM, the substituent can be isopropyl or secondary butyl, while in MBM, it can be methyl or ethyl. However, MBM is more potent against some parasites and is safer than IVM, suggesting that one or both of the moieties in C-25 and C-13 of MBM is (are) the better structure(s) in these ways than that (those) of IVM. Another conclusion is that the two oleandroses in C-13 are important to the antiparasitic activity of IVM, since their removal will reduce the activity significantly, about 30-fold (10). Based on the curr...

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Section: Discussionmentioning

confidence: 99%

Gene Replacement for the Generation of Designed Novel Avermectin Derivatives with Enhanced Acaricidal and Nematicidal Activities

Huang

Chen²,

Zhang

et al. 2015

Appl Environ Microbiol

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“…Domain replacements within the erythromycin PKS have been shown to result in the production of novel bioactive compounds (11,22,25). The ethylmalonyl AT domain (AT5) and the methoxy AT domain (AT6) of the niddamycin cluster could conceivably be used to replace the mmAT domains in the erythromycin PKS to generate erythromycin derivatives with novel polyketide backbone structures that would be difficult to produce by chemical methods.…”

Section: Discussionmentioning

confidence: 99%

Identification and characterization of the niddamycin polyketide synthase genes from Streptomyces caelestis

1997

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The genes encoding the polyketide synthase (PKS) portion of the niddamycin biosynthetic pathway were isolated from a library of Streptomyces caelestis NRRL-2821 chromosomal DNA. Analysis of 40 kb of DNA revealed the presence of five large open reading frames (ORFs) encoding the seven modular sets of enzymatic activities required for the synthesis of a 16-membered lactone ring. The enzymatic motifs identified within each module were consistent with those predicted from the structure of niddamycin. Disruption of the second ORF of the PKS coding region eliminated niddamycin production, demonstrating that the cloned genes are involved in the biosynthesis of this compound.Niddamycin is a macrolide antibiotic which is able to bind 50S ribosomal subunits to inhibit protein synthesis. The compound was first discovered as a secondary metabolite of Streptomyces djakartensis (16) and was later found to be produced by Streptomyces caelestis NRRL-2821 (11a). The structure of niddamycin ( Fig. 1) suggests that the polyketide backbone of the macrolide ring is formed through the ordered condensation of carboxylic acid residues derived from acetate, propionate, butyrate, and perhaps glycolate (24). The disaccharide, mycaminose-isobutyrylmycarose, is attached to the macrolide ring at C-5.Macrolides belong to a class of molecules referred to as complex polyketides, which are synthesized on large, multifunctional enzymes called polyketide synthases (PKSs). The synthesis of polyketides is mechanistically similar to that of fatty acids; however, a greater variety of starter and extender carboxylic acid residues are incorporated into the growing polyketide chain, and the ␤-keto groups formed after each condensation step undergo various degrees of reduction (15,20).PKSs, in general, contain all of the enzymatic activities necessary for the sequential condensation of acyl thioesters (␤-ketoacyl acyl carrier protein synthases [KS]), acyltransferases [AT], and acyl carrier proteins [ACP]), the subsequent reduction of the ␤-keto groups (dehydratases [DH], enoylreductases [ER], and ketoreductases [KR]), and the release of the completed chain from the PKS (thioesterases [TE]). Analysis of the erythromycin PKS genes revealed that these enzymatic domains are organized into modules, each of which is responsible for one round of condensation and reduction (5, 7, 9, 10). As a result, there is a direct correlation between the number of modules contained within the erythromycin PKS and the length of the polyketide chain. In addition, the genetic order of the erythromycin PKS modules was found to be colinear with the order of biochemical reactions, allowing directed genetic alterations which produce predicted novel erythromycin derivatives (9, 11).The polyketide portion of the 16-membered macrolide niddamycin is predicted to be synthesized by a complex (type 1) PKS (15) comprising seven modules, each catalyzing one condensation reaction. It had previously been suggested that the choice of the extender coenzyme A (CoA)-thioester is determined by the ...

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“…For example, a single enzyme, malonyl-CoA synthetase, can be used to synthesize numerous ␣-carboxylated CoA thioesters from their corresponding exogenously supplied 1,3-dicarboxylic acids (N. Pohl and C. Khosla, unpublished data). Fourth, the modularity of many PKSs makes it feasible to tailor their substrate preferences to the available intracellular pool of CoA thioesters in a given host (48,65,73). A similar approach can also be used to constrain the substrate range of NRPSs, if desired.…”

Section: Substrate Availabilitymentioning

confidence: 99%

Biosynthesis of Polyketides in Heterologous Hosts

Pfeifer¹,

Khosla

2001

Microbiol Mol Biol Rev

236

137

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Polyketide natural products show great promise as medicinal agents. Typically the products of microbial secondary biosynthesis, polyketides are synthesized by an evolutionarily related but architecturally diverse family of multifunctional enzymes called polyketide synthases. A principal limitation for fundamental biochemical studies of these modular megasynthases, as well as for their applications in biotechnology, is the challenge associated with manipulating the natural microorganism that produces a polyketide of interest. To ameliorate this limitation, over the past decade several genetically amenable microbes have been developed as heterologous hosts for polyketide biosynthesis. Here we review the state of the art as well as the difficulties associated with heterologous polyketide production. In particular, we focus on two model hosts, Streptomyces coelicolor and Escherichia coli. Future directions for this relatively new but growing technological opportunity are also discussed

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Acyltransferase domain substitutions in erythromycin polyketide synthase yield novel erythromycin derivatives

Cited by 134 publications

References 44 publications

Gene Replacement for the Generation of Designed Novel Avermectin Derivatives with Enhanced Acaricidal and Nematicidal Activities

Gene Replacement for the Generation of Designed Novel Avermectin Derivatives with Enhanced Acaricidal and Nematicidal Activities

Identification and characterization of the niddamycin polyketide synthase genes from Streptomyces caelestis

Biosynthesis of Polyketides in Heterologous Hosts

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