Mixing Up the Pieces of the Desferrioxamine B Jigsaw Defines the Biosynthetic Sequence Catalyzed by DesD

Telfer, Thomas J.; Gotsbacher, Michael P.; Soe, Cho Zin; Codd, Rachel

doi:10.1021/acschembio.6b00056

Cited by 31 publications

(74 citation statements)

References 41 publications

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“…This is in accordance with recent results from the Codd group, who established that the biosynthesis of endcapped desferrioxamine Bp roceeds via activation of the monomeric substrate HS [5]A and not via activation of the dimeric precursor pre[5+ +5]. [16] Since AvbD only produces [5+ +ab] but not [5+ +5+ +ab],i tc an be concluded that the Cs ite of AvbD in contrast to DesDi su nable to bind [5+ +ab].B ased on these results, we propose that the Cs ite of AvbD is more restrictivei n substrate acceptance than that of DesDa nd thus may only accept monomeric substrates. This difference between the C sites of DesD and AvbD may determine the number of oligomerization steps for each enzyme.…”

Section: Substrate Affinity To the Cs Ite Directs Oligomerization Stepssupporting

confidence: 91%

“…Thisi si nl ine with resultsf rom the Codd group who reportedi ncorporation of an unsaturated HS [4]A precursor into desferrioxamine B. [16] Since both AvbD and DesD accept non-natural substrates, we reasoned that this promiscuity for synthetic substrates may provideameans to dissect and investigate the mechanism of type CN IS synthetases in greater detail.…”

Section: Desd Exhibits Relaxed Substrate Specificitysupporting

confidence: 67%

“…[15] It has also been reported that unsaturated precursors have been incorporated into dimerica nd trimerich ydroxamates by PubC and DesD, respectively. [16,25] We have now confirmed ab road spectrum multi-specificity for various synthetic substrates for DesD, which allowedt oe mploy ac hemical biology approach for dissecting and interrogating the mechanism of this enzyme class on the example of AvbD and DesD.…”

Section: Discussionmentioning

confidence: 68%

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Dissecting the Mechanism of Oligomerization and Macrocyclization Reactions of NRPS‐Independent Siderophore Synthetases

Rütschlin

Böttcher

2018

Chemistry A European J

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Macrocyclic and linear hydroxamate siderophores produced by NRPS-independent siderophore (NIS; NRPS=nonribosomal peptide synthetase) synthetases are important in the bacterial competition for iron, as virulence factors, and as drugs for medical use in humans. Despite their importance, the mechanistic details of NIS synthetases have so far remained obscure. Using synthetic substrate analogues as tools allowed for an interrogation of the mechanism of the two closely related NIS synthetases AvbD and DesD. While AvbD produces macrocyclic homo- and heterodimers as native products, DesD is responsible for the synthesis of trimeric desferrioxamines. These enzymes comprise two adjacent binding sites with different substrate selectivities, which direct oligomerization and macrocyclization steps. Exploiting this difference, synthetic substrates were used to invert the native affinities for the sites resulting in switching from trimerization to dimerization reactions for DesD. Based on this work, a comprehensive model explaining the mechanistic details of the reactions and the differences between trimerizing and dimerizing enzymes was developed. Finally, a DesD mutant demonstrated the tuneability of the enzyme's substrate selectivity by only minor changes in the protein sequence. This finding confirms the affinity-directed mechanism responsible for the iterativity of oligomerization and macrocyclization steps.

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Section: Substrate Affinity To the Cs Ite Directs Oligomerization Stepssupporting

confidence: 91%

Section: Desd Exhibits Relaxed Substrate Specificitysupporting

confidence: 67%

Section: Discussionmentioning

confidence: 68%

See 1 more Smart Citation

Dissecting the Mechanism of Oligomerization and Macrocyclization Reactions of NRPS‐Independent Siderophore Synthetases

Rütschlin

Böttcher

2018

Chemistry A European J

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“…In the first step, DesA catalyzes the decarboxylation of l ‐lysine to produce 1,5‐diaminopentane (DP) for downstream processing by DesBCD. Subsequent steps involve mono‐ N ‐hydroxylation of DP to produce N ‐hydroxy‐DP (HDP; DesB), acetylation or succinylation of the N ‐hydroxy group of HDP to produce N ‐acetyl‐ N ‐hydroxy‐DP (AHDP) or N ‐succinyl‐ N ‐hydroxy‐DP (SHDP), respectively (DesC), and assembly of an AHDP‐SHDP heterodimer (DesD, round 1) with the condensation of a final SHDP unit to AHDP‐SHDP to form trimeric 1 (DesD, round 2) . The exogenous supply of diamine substrates to S. pilosus culture medium bypasses DesA and requires only functional DesBCD.…”

Section: Introductionmentioning

confidence: 99%

“…DP is the major native diamine substrate used in the biosynthesis of 1 and of other DFO‐type siderophores. 1,4‐Diaminobutane (DB), produced through the decarboxylation of l ‐ornithine, is a minor native diamine substrate used solely or in combination with DP to assemble DFOA‐type siderophores (Schemes and B) …”

Section: Introductionmentioning

confidence: 99%

Azido‐Desferrioxamine Siderophores as Functional Click‐Chemistry Probes Generated in Culture upon Adding a Diazo‐Transfer Reagent

Gotsbacher

Codd

2020

ChemBioChem

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Scheme1.Structures of DFOB (1), azido-DFOB( 2), DFON 1 ,DFOA 1-3 ,a nd membersoffour classes of PDB substrates used to augment culturesofS. pilosus. ( 1), together with its observed MS 2 fragmentationpattern, B) DFOA-constitutional isomers 3-9,g enerated by usingP DB with DB as substrate, and the corresponding azido analogues 10-16,a nd C) putative dimeric and monomeric compounds that could be generated by using PDB with 5APAa ssubstrate. Scheme2.Structures of:A)DFOB

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On the origin of amphi-enterobactin fragments produced by Vibrio campbellii species

Jelowicki

Butler

2022

J Biol Inorg Chem

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Amphi-enterobactin is an amphiphilic siderophore isolated from a variety of microbial Vibrio species. Like enterobactin, amphi-enterobactin is a triscatecholate siderophore; however, it is framed on an expanded tetralactone core comprised of four l-Ser residues, of which one l-Ser is appended by a fatty acid and the remaining l-Ser residues are appended by 2,3-dihydroxybenzoate (DHB). Fragments of amphi-enterobactin composed of 2-Ser-1-DHB-FA and 3-Ser-2-DHB-FA have been identified in the supernatant of Vibrio campbellii species. The origin of these fragments has not been determined, although two distinct isomers could exist for 2-Ser-1-DHB-FA and three distinct isomers could exist for 3-Ser-2-DHB-FA. The fragments of amphi-enterobactin could originate from hydrolysis of the amphi-enterobactin macrolactone, or from premature release due to an inefficient biosynthetic pathway. Unique masses in the tandem MS analysis establish that certain fragments isolated from the culture supernatant must originate from hydrolysis of the amphi-enterobactin macrolactone, while others cannot be distinguished from premature release during biosynthesis or hydrolysis of amphi-enterobactin. Graphical abstract

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Mixing Up the Pieces of the Desferrioxamine B Jigsaw Defines the Biosynthetic Sequence Catalyzed by DesD

Cited by 31 publications

References 41 publications

Dissecting the Mechanism of Oligomerization and Macrocyclization Reactions of NRPS‐Independent Siderophore Synthetases

Dissecting the Mechanism of Oligomerization and Macrocyclization Reactions of NRPS‐Independent Siderophore Synthetases

Azido‐Desferrioxamine Siderophores as Functional Click‐Chemistry Probes Generated in Culture upon Adding a Diazo‐Transfer Reagent

On the origin of amphi-enterobactin fragments produced by Vibrio campbellii species

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