Optimized arylomycins are a new class of Gram-negative antibiotics

Smith, Peter A.; Koehler, Michael F. T.; Girgis, Hany S.; Yan, Donghong; Chen, Yongsheng; Chen, Yuan; Crawford, James J.; Durk, Matthew R.; Higuchi, Robert I.; Kang, Jing; Murray, J.M.; Paraselli, Prasuna; Park, Summer; Phung, Wilson; Quinn, John; Roberts, Tucker C.; Rougé, Lionel; Schwarz, Jacob B.; Skippington, Elizabeth; Wai, John S.; Xu, Min; Yu, Zhilin; Zhong, Hua; Tan, Man‐Wah; Heise, Christopher E.

doi:10.1038/s41586-018-0483-6

Cited by 294 publications

(274 citation statements)

References 29 publications

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“…[4] Especially in the field of antibiotics,covalent inhibitors are prevalent as exemplified by b-lactams, [3] fosfomycin, [5] showdomycin, [6] and optimized arylomycins. [7] Recently,m ethods have emerged to globally identify the exact interaction site of covalent inhibitors in ac ompetitive fashion. [2a,b,8] In this way,many pockets that can bind covalent ligands are identified in parallel using as mall library of covalently reactive molecules.T his technology is especially well established for profiling cysteine residues using methods based on the isoTOP-ABPP (isotopic tandem orthogonal proteolysis activity-based protein profiling) platform (Figure 1a).…”

Section: Introductionmentioning

confidence: 99%

Isotopically Labeled Desthiobiotin Azide (isoDTB) Tags Enable Global Profiling of the Bacterial Cysteinome

2020

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Rapid development of bacterial resistance has led to an urgent need to find new druggable targets for antibiotics.In this context, residue-specific chemoproteomic approaches enable proteome-wide identification of binding sites for covalent inhibitors.D escribed here are easily synthesized isotopically labeled desthiobiotin azide (isoDTB) tags that shortened the chemoproteomic workflowa nd allowed an increased coverage of cysteines in bacterial systems.They were used to quantify 59 %o fa ll cysteines in essential proteins in Staphylococcus aureus and enabled the discovery of 88 cysteines that showed high reactivity,w hichc orrelates with functional importance.F urthermore,2 68 cysteines that are engaged by covalent ligands were identified. Inhibition of HMG-CoA synthase was verified and will allow addressing the bacterial mevalonate pathway through an ew target. Overall, ab road map of the bacterial cysteinome was obtained, which will facilitate the development of antibiotics with novel modesof-action.

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Section: Introductionmentioning

confidence: 99%

Isotopically Labeled Desthiobiotin Azide (isoDTB) Tags Enable Global Profiling of the Bacterial Cysteinome

2020

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“…There are more challenges for antibiotic discovery for multi-drug resistant Gram-negative pathogens, since they have a double cell wall, which prevents antibiotic molecules from reaching their intracellular targets. Despite extensive efforts, there have been no new classes of antibiotics approved against Gram-negative pathogens in over fifty years 39 . Since our approach is based on the presence of a putative self-resistance gene within the cluster, it suggests that molecules produced by these clusters would target the host organism.…”

Section: Extending the Pipeline To Novel Antibacterial Drug Targetsmentioning

confidence: 99%

Identification of polyketide biosynthetic gene clusters that harbor self-resistance target genes

Ga¹,

Nivina²,

Khosla³

et al. 2020

Preprint

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Background: Polyketide secondary metabolites have been a rich source of antibiotic discovery for decades. Thousands of novel polyketide synthase (PKS) gene clusters have been identified in recent years with advances in DNA sequencing. However, experimental characterization of novel and useful PKS activities remains complicated. As a result, computational tools to analyze sequence data are essential to identify and prioritize potentially novel PKS activities. Here we exploit the concept of geneticallyencoded self-resistance to identify and rank biosynthetic gene clusters for their potential to encode novel antibiotics. Results:To identify PKS genes that are likely to produce an antibacterial compound, we developed an automated method to identify and catalog clusters that harbor potential selfresistance genes. We manually curated a list of known self-resistance genes and searched all NCBI genome databases for homologs of these self-resistance genes in biosynthetic gene clusters. The algorithm takes into account (1) the distance of the potential selfresistance gene to a core enzyme in the biosynthetic gene cluster; (2) the presence of a duplicated housekeeping copy of the self-resistance gene; (3) the presence of close homologs of the biosynthetic gene cluster in diverse species also harboring the putative self-resistance gene; (4) evidence for coevolution of the self-resistance gene and core biosynthetic gene; and (5) self-resistance gene ubiquity. We generated a catalog of 190 unique PKS clusters whose products likely target known enzymes of antibacterial importance. We also present an expanded set of putative self-resistance genes that may be useful in identifying small molecules active against novel microbial targets. Conclusions:We developed a bioinformatic approach to identify and rank biosynthetic gene clusters that likely harbor self-resistance genes and may produce compounds with antibacterial properties. We compiled a list of putative self-resistance genes for novel antibacterial targets, and of orphan PKS clusters harboring these targets. These catalogues are a resource for discovery of novel antibiotics.

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“…Although the replacement of succinate by cyclohexane-1,2-dicarboxylic acid produces a prodrug (6) with rather low activity (MIC > 200 M), the conjugation of GG to 6 significantly increases the activity of the prodrug (7, MIC = 50 M). Because the ciprofloxacin derivative, with the diglycine conjugated at the carboxylic acid of ciprofloxacin, hardly shows activity against E. coli (Scheme S5 and Figure S7), we made a ciprofloxacin derivative (8), which has 2-hydroxyacetic acid attach to the piperazine end of ciprofloxacin, for conjugating GG to ciprofloxacin. While 9, the succinate derivative of 8, exhibits lower antibacterial activity (MIC = 1.0 M) than that of 8 (MIC = 0.5 M), the conjugation of GG to 9 results in 10 (MIC = 0.5 M), which is as potent as 8 against E. coli.…”

Section: Scheme 1 Illustration Of Diglycine Speeding Up the Regeneramentioning

confidence: 99%

“…4 Thus, there is an urgent need for developing new antimicrobial approaches against MDR bacterial pathogens. Besides investigating novel agents against new targets in bacteria [6][7][8][9] via previously unexplored mechanisms, another strategy is to enhance the efficacy and safety of the existing antibiotics via drug combinations or increasing specificity. For example, Kahne et al demonstrated that the use of novobiocin analogs greatly lower the dose of polymyxins against Gram-negative bacteria via inhibiting DNA gyrase, binding LptB, and disrupting outer membrane.…”

mentioning

confidence: 99%

Rapid Intrabacterial Hydrolysis for Activating Antibiotics against Gram-negative Bacteria

Wang¹,

Zhan²,

Wu³

et al. 2019

Preprint

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Antimicrobial drug resistance demands novel approaches for improving the efficacy of antibiotics, especially against Gram-negative bacteria. Here we report that conjugating a diglycine (GG) to a prodrug of antibiotics drastically accelerates intrabacterial hydrolysis of ester bond for regenerating the antibiotics against E. coli. Specifically, the attachment of GG to chloramphenicol succinate (CLsu) generates a novel conjugate (CLsuGG), which exhibits about an order of magnitude higher inhibitory efficacy than CLsu against E. coli. Further studies reveal that CLsuGG undergoes rapid hydrolysis catalyzed by intrabacterial esterases (e.g., BioH and YjfP) for generating chloramphenicol (CL) in E. coli. More importantly, the conjugate exhibits lower cytotoxicity to bone marrow stromal cells that CL does. The structural analogs of CLsuGG indicate that the conjugation of GG is an effective strategy for accelerating hydrolysis catalyzed by esterases and enhancing antibacterial efficacy of antibiotics. This work, for the first time, illustrates that dipeptide conjugation modulates intrabacterial hydrolysis for increasing antibiotic efficacy and reducing adverse drug effects.Infectious disease remains a major threat to public health.

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Optimized arylomycins are a new class of Gram-negative antibiotics

Cited by 294 publications

References 29 publications

Isotopically Labeled Desthiobiotin Azide (isoDTB) Tags Enable Global Profiling of the Bacterial Cysteinome

Isotopically Labeled Desthiobiotin Azide (isoDTB) Tags Enable Global Profiling of the Bacterial Cysteinome

Identification of polyketide biosynthetic gene clusters that harbor self-resistance target genes

Rapid Intrabacterial Hydrolysis for Activating Antibiotics against Gram-negative Bacteria

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