New Genetically Engineered Derivatives of Antibacterial Darobactins Underpin Their Potential for Antibiotic Development

Seyfert, Carsten E.; Müller, Alison V.; Walsh, Danica J.; Birkelbach, Joy; Kany, Andreas M.; Porten, Christoph; Yuan, Biao; Krug, Daniel; Herrmann, Jennifer; Marlovits, Thomas C.; Hirsch, Anna K. H.; Müller, Rolf

doi:10.1021/acs.jmedchem.3c01660

Cited by 10 publications

(13 citation statements)

References 31 publications

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“…The darobactins were shown to bind to an open form of the BamA lateral gate by mimicking a β-strand − which was at an earlier assembly stage compared to MRL-494 ( 34 ) and the tethered murepavadin and colistin derivative . Mutasynthetic work has led to the identification of more active analogs such as darobactin B ( 36 ) and D9 ( 37 ). − Recent total syntheses of darobactin A ( 35 ) have also laid the groundwork for access to new analogs. − Finally, a computational approach that searched for genes related to the darobactin operon, facilitated the identification of another new BamA inhibitor, dynobactin ( 38 ), from Photorhabdus australis …”

Section: Compounds With New Antibacterial Modes Of Actionmentioning

confidence: 99%

A Review of Antibacterial Candidates with New Modes of Action

Butler,

Vollmer,

Goodall

et al. 2024

ACS Infect. Dis.

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There is a lack of new antibiotics to combat drugresistant bacterial infections that increasingly threaten global health. The current pipeline of clinical-stage antimicrobials is primarily populated by "new and improved" versions of existing antibiotic classes, supplemented by several novel chemical scaffolds that act on traditional targets. The lack of fresh chemotypes acting on previously unexploited targets (the "holy grail" for new antimicrobials due to their scarcity) is particularly unfortunate as these offer the greatest opportunity for innovative breakthroughs to overcome existing resistance. In recognition of their potential, this review focuses on this subset of high value antibiotics, providing chemical structures where available. This review focuses on candidates that have progressed to clinical trials, as well as selected examples of promising pioneering approaches in advanced stages of development, in order to stimulate additional research aimed at combating drug-resistant infections.

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Section: Compounds With New Antibacterial Modes Of Actionmentioning

confidence: 99%

A Review of Antibacterial Candidates with New Modes of Action

Butler,

Vollmer,

Goodall

et al. 2024

ACS Infect. Dis.

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“…50,51 Manipulating the darobactin gene cluster and expressing it heterologously resulted in the production of various darobactin analogues. [31][32][33]52 Groß et al substituted F7 → W (D9) and observed a 2−4 times more potent activity compared to DA. 31 Encouraged by the potency of D9, the same research group explored substituting the other amino acids while maintaining F7 → W. Following this, Seyfert et al biosynthetically produced D22, which bears structural resemblance to DB but includes an additional substitution of F7 → W. 33 The antibacterial activity of D22/DB9 is two to four times more potent than D9 against multidrug-resistant Acinetobacter strains, and it exhibits two-fold better activity than DB against various P. aeruginosa isolates.…”

Section: Biological Activity Of Various Darobactinsmentioning

confidence: 99%

“…50 Subsequent biosynthetic modifications led to the discovery of D69, which exhibited activity similar to that of D22. 32 Notably, DA exhibited promising efficacy in murine infection models against both drug-sensitive and drug-resistant Gram-negative bacteria including P. aeruginosa, K. pneumoniae and E. coli with no observed toxicity. 29 The elimination half-life of DA was reported to be 1 h in mice models, and darobactins exhibit good plasma stability.…”

Section: Biological Activity Of Various Darobactinsmentioning

confidence: 99%

Exploring the Darobactin Class of Antibiotics: A Comprehensive Review from Discovery to Recent Advancements

Dutta,

Sharma,

Dass

et al. 2024

ACS Infect. Dis.

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The prevalence of antimicrobial resistance in Gramnegative bacteria poses a greater challenge due to their intrinsic resistance to many antibiotics. Recently, darobactins have emerged as a novel class of antibiotics originating from previously unexplored Gram-negative bacterial species such as Photorhabdus, Vibrio, Pseudoalteromonas and Yersinia. Darobactins belong to the ribosomally synthesized and post-translationally modified peptide (RiPP) class of antibiotics, exhibiting selective activity against Gram-negative bacteria. They target the β-barrel assembly machinery (BAM), which is crucial for the maturation and insertion of outer membrane proteins in Gram-negative bacteria. The dar operon in the producer's genome encodes for the synthesis of darobactins, which are characterized by a fused ring system connected via an alkyl−aryl ether linkage (C−O−C) and a C−C cross-link. The enzyme DarE, using the radical S-adenosyl-L-methionine (rSAM), facilitates the formation of these bonds. Biosynthetic manipulation of the darobactin gene cluster, along with its expression in a surrogate host, has enabled access to diverse darobactin analogues with variable antibiotic activities. Recently, two independent research groups successfully achieved the total synthesis of darobactin, employing Larock heteroannulation to construct the bicyclic structure. This paper presents a comprehensive review of darobactins, encompassing their discovery through to the most recent advancements.

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“…Most of the reported variants, however, involve substitution of the nonmodified residues of the DarA core region (i.e., positions 2, 4, 6, 7), which collectively showed minimal impact on forming fused bicyclic products. 38,41,44,49,50 In contrast, less is known about enzymatic tolerance to core positions that are modified (i.e., positions 1, 3, and 5). DarE can tolerate substitution of Lys5 with either Arg or Ala to produce darobactins D and 15, respectively.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Many naturally occurring and engineered darobactin variants have been characterized, which have begun to define the substrate tolerance of DarE. Most of the reported variants, however, involve substitution of the nonmodified residues of the DarA core region (i.e., positions 2, 4, 6, 7), which collectively showed minimal impact on forming fused bicyclic products. ,,,, In contrast, less is known about enzymatic tolerance to core positions that are modified (i.e., positions 1, 3, and 5). DarE can tolerate substitution of Lys5 with either Arg or Ala to produce darobactins D and 15, respectively. ,, Until recently, no experimental data were available regarding the impact of substitutions on DarA core positions 1 and 3.…”

Section: Introductionmentioning

confidence: 99%

Darobactin Substrate Engineering and Computation Show Radical Stability Governs Ether versus C–C Bond Formation

Woodard,

Peccati,

Navo

et al. 2024

J. Am. Chem. Soc.

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The Gram-negative selective antibiotic darobactin A has attracted interest owing to its intriguing fused bicyclic structure and unique targeting of the outer membrane protein BamA. Darobactin, a ribosomally synthesized and post-translationally modified peptide (RiPP), is produced by a radical S-adenosyl methionine (rSAM)-dependent enzyme (DarE) and contains one ether and one C–C cross-link. Herein, we analyze the substrate tolerance of DarE and describe an underlying catalytic principle of the enzyme. These efforts produced 51 enzymatically modified darobactin variants, revealing that DarE can install the ether and C–C cross-links independently and in different locations on the substrate. Notable variants with fused bicyclic structures were characterized, including darobactin W3Y, with a non-Trp residue at the twice-modified central position, and darobactin K5F, which displays a fused diether ring pattern. While lacking antibiotic activity, quantum mechanical modeling of darobactins W3Y and K5F aided in the elucidation of the requisite features for high-affinity BamA engagement. We also provide experimental evidence for β-oxo modification, which adds support for a proposed DarE mechanism. Based on these results, ether and C–C cross-link formation was investigated computationally, and it was determined that more stable and longer-lived aromatic Cβ radicals correlated with ether formation. Further, molecular docking and transition state structures based on high-level quantum mechanical calculations support the different indole connectivity observed for ether (Trp-C7) and C–C (Trp-C6) cross-links. Finally, mutational analysis and protein structural predictions identified substrate residues that govern engagement to DarE. Our work informs on darobactin scaffold engineering and further unveils the underlying principles of rSAM catalysis.

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New Genetically Engineered Derivatives of Antibacterial Darobactins Underpin Their Potential for Antibiotic Development

Cited by 10 publications

References 31 publications

A Review of Antibacterial Candidates with New Modes of Action

A Review of Antibacterial Candidates with New Modes of Action

Exploring the Darobactin Class of Antibiotics: A Comprehensive Review from Discovery to Recent Advancements

Darobactin Substrate Engineering and Computation Show Radical Stability Governs Ether versus C–C Bond Formation

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