Reprogramming Nonribosomal Peptide Synthetases for “Clickable” Amino Acids

Kries, Hajo; Wachtel, Rudolf; Pabst, Anja; Wanner, Benedikt; Niquille, David L.; Hilvert, Donald

doi:10.1002/ange.201405281

Cited by 33 publications

(23 citation statements)

References 46 publications

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“…Our model can easily be adapted to peptides with variability in their Aaa positions, for example the related steptocidines, loloatins and laterocidin, as well as the co‐produced gramicidins. This rapid method of culture manipulation, combined with our mathematical modelling can be used for understanding and manipulation of the production of other nonribosomally produced peptides as well as bioengineered enzyme systems where the synthetase enzymes have been mutated to produce novel analogues (Calcott and Ackerley ; Kries et al ; Kries ; Niquille et al ; Bozhüyük et al ). Moreover, our mathematical modelling can be incorporated into the computational design (Stevens et al ; Jiang et al ; Rothlisberger et al ; Privett et al ) and genome‐mining approach in the design of novel antimicrobial peptides and antibiotics produced by nonribosomal synthesis (Nguyen et al ; Gaudelli et al ; Weber et al ; Kries ; Baltz ).…”

Section: Discussionmentioning

confidence: 99%

“…Computational algorithms are used to predict mutation of the synthetase enzyme modules (Stevens et al ), however, mutations may also disrupt the interaction of proteins in the synthetase complex resulting in low yields (Stachelhaus et al , ; Schneider et al ; Trauger et al ; Wilkinson and Micklefield ; Winn et al ). Successful modification was reported for the D‐Phe 1 binding module which was induced to accept modified analogues through mutation in the active site (Kries et al ; Niquille et al ). To our knowledge no full‐length tyrocidine has been produced via recombinant technology, although a shortened dipeptide analogue was produced by expression of the first two modules in Escherichia coli (Gruenewald et al ).…”

Section: Introductionmentioning

confidence: 99%

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Modelling the variable incorporation of aromatic amino acids in the tyrocidines and analogous cyclodecapeptides

2019

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Aims A mathematical model of the nonribosomal synthesis of tyrocidines and analogues by Brevibacillus parabrevis was constructed using a competitive binding mechanism (CBM) for the incorporation of the three variable aromatic amino acid (Aaa) residues in their sequence. These antimicrobial peptides have a conserved structure (D‐Phe1‐Pro2‐Aaa3‐D‐Aaa4‐Asn5‐Gln6‐Aaa7‐Val8‐Orn9‐Leu10), apart from the Aaa in positions 3, 4 and 7 containing either Phe, Trp or Tyr. Methods and Results Ultra‐performance liquid chromatography linked mass spectrometry was used to profile peptides from extracts of cultures grown in media with various Phe : Trp ratios. The CBM model describes the production of peptides as a function of growth medium Aaa concentration. The model accounts for variable Aaa incorporation by simultaneously considering the influence of maximal incorporation rate and cooperativity, despite similar KM’s of synthetase modules. Conclusions Our CBM model can be utilized to predict the Aaa composition of produced peptides from the concentration of Aaas in the growth medium. Significance and Impact of the Study Subtly exploiting the inherent promiscuity of the nontemplate coded peptide synthesis allows for external control of peptide identity, without using genetic manipulation. Such versatility is exploitable in the production of targeted peptide complexes and rare peptides where production processes are reliant on nonribosomal synthesis.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Modelling the variable incorporation of aromatic amino acids in the tyrocidines and analogous cyclodecapeptides

2019

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“…A. We have introduced a single W239S mutation into the A domain to reprogram specificity of a diketopiperazine synthetase for O‐propargyl‐Tyr . The active site of the A domain is shown with Phe bound (green spheres) .…”

Section: Engineering Nrps Specificitymentioning

confidence: 99%

Biosynthetic engineering of nonribosomal peptide synthetases

Kries

2016

Journal of Peptide Science

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From the evolutionary melting pot of natural product synthetase genes, microorganisms elicit antibiotics, communication tools, and iron scavengers. Chemical biologists manipulate these genes to recreate similarly diverse and potent biological activities not on evolutionary time scales but within months. Enzyme engineering has progressed considerably in recent years and offers new screening, modelling, and design tools for natural product designers. Here, recent advances in enzyme engineering and their application to nonribosomal peptide synthetases are reviewed. Among the nonribosomal peptides that have been subjected to biosynthetic engineering are the antibiotics daptomycin, calcium-dependent antibiotic, and gramicidin S. With these peptides, incorporation of unnatural building blocks and modulation of bioactivities via various structural modifications have been successfully demonstrated. Natural product engineering on the biosynthetic level is not a reliable method yet. However, progress in the understanding and manipulation of biosynthetic pathways may enable the routine production of optimized peptide drugs in the near future. Copyright © 2016 European Peptide Society and John Wiley & Sons, Ltd.

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“…Recently, the Phe‐incorporating A domain of gramicidin synthetase (GrsA) has been successfully re‐engineered to introduce azide‐ and alkyne‐substituted AA (Kries et al. ). Attempts to drastically change the substrate specificity have resulted in a decrease in the A domain activity (Chen et al.…”

Section: Introductionmentioning

confidence: 99%

Systematic analysis of the kalimantacin assembly line NRPS module using an adapted targeted mutagenesis approach

et al. 2015

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Kalimantacin is an antimicrobial compound with strong antistaphylococcal activity that is produced by a hybrid trans‐acyltransferase polyketide synthase/nonribosomal peptide synthetase system in Pseudomonas fluorescens BCCM_ID9359. We here present a systematic analysis of the substrate specificity of the glycine‐incorporating adenylation domain from the kalimantacin biosynthetic assembly line by a targeted mutagenesis approach. The specificity‐conferring code was adapted for use in Pseudomonas and mutated adenylation domain active site sequences were introduced in the kalimantacin gene cluster, using a newly adapted ligation independent cloning method. Antimicrobial activity screens and LC‐MS analyses revealed that the production of the kalimantacin analogues in the mutated strains was abolished. These results support the idea that further insight in the specificity of downstream domains in nonribosomal peptide synthetases and polyketide synthases is required to efficiently engineer these strains in vivo.

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Reprogramming Nonribosomal Peptide Synthetases for “Clickable” Amino Acids

Cited by 33 publications

References 46 publications

Modelling the variable incorporation of aromatic amino acids in the tyrocidines and analogous cyclodecapeptides

Modelling the variable incorporation of aromatic amino acids in the tyrocidines and analogous cyclodecapeptides

Biosynthetic engineering of nonribosomal peptide synthetases

Systematic analysis of the kalimantacin assembly line NRPS module using an adapted targeted mutagenesis approach

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