Identification and occurrence of the hydroxamate siderophores aerobactin, putrebactin, avaroferrin and ochrobactin C as virulence factors from entomopathogenic bacteria

Hirschmann, Merle; Grundmann, Florian; Bode, Helge B.

doi:10.1111/1462-2920.13845

Cited by 24 publications

(25 citation statements)

References 60 publications

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“…This led us to conclude that DesD shares with AvbD ar elaxeds ubstrate specificityf or different lengths of the diamino alkyl spacer and that product formation is again dictated via the availables ubstrate pool. 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: 70%

“…For example, by the production of avaroferrin, Shewanella algae strain B516t hwarts iron piracy of Vibrio alginolyticus and inhibitsi ts swarming behavior. [19] Avaroferrin and putrebactin are also discussed as virulence factorsi ni nsectp athogenic bacteria [4] and bisucaberin may be associated with cold-water vibriosis of the fish pathogen Aliivibrio salmonicidae. [20] Desferrioxamines are widespread among environmental bacteria [21] and desferrioxamine Bi smarketed as Desferal, av aluabled rug against iron overloadw ith potential applications in antitumor therapy [22] and for treatment of Alzheimer's disease.…”

Section: Discussionmentioning

confidence: 99%

“…Surprisingly,A vbD and DesD exhibitedf or this substrate qualitativelyi dentical product profiles. Re-examining the reaction with HS [6]A revealed that in addition to the macrocyclict rimer [6+ +6+ +6] also large quantities of the dimeric macrocycle [6+ +6] were formed, while the native substrate HS [5]A gave with DesD exclusively the cyclic trimer [5+ +5+ +5] and with AvbD exclusively the cyclic dimer [5+ +5].W hen we incubated the shorter substrate HS [4]A with DesD, we also obtained the cyclic dimer [4+ +4] in considerable amounts, suggesting that affinity to the Cs ite and not merely length of the linear dimer determines the number of oligomerization steps. In contrast, HS [3]A did not yield any product with DesD( Figure S15), as has also been the case with AvbD.…”

Section: Substrate Affinity To the As Ite Distinguishesa Vbd And Desdmentioning

confidence: 99%

“…[15] Structural changes in the N-terminus of the substrate thus have am ajor impact on the oligomerization steps carriedo ut by DesD but not on the iterativity of AvbD. While substrates closely relatedt ot he native one such as HS [4]A and HS [6]A still yieldedc yclic trimers with DesDf ollowed by smaller amountso fc yclic dimers,t he structurally more unrelated HS[8]A only gave cyclic dimer.T hese results confirm our model prediction that linear dimers of N-terminals ubstrate variants with native C-terminus may in DesD swap their affinity towards the Cs ite for the As ite, causing the cyclizationo fd imers. In contrast,f or AvbD which does not bind linear dimers in its C site the number of oligomerization steps remained unaffected.…”

Section: Substrate Affinity To the As Ite Distinguishesa Vbd And Desdmentioning

confidence: 99%

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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: Desd Exhibits Relaxed Substrate Specificitysupporting

confidence: 70%

Section: Discussionmentioning

confidence: 99%

Section: Substrate Affinity To the As Ite Distinguishesa Vbd And Desdmentioning

confidence: 99%

Section: Substrate Affinity To the As Ite Distinguishesa Vbd And Desdmentioning

confidence: 99%

See 2 more Smart Citations

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 Shewanella algae , bisucaberin is simultaneously produced with avaroferrin and putrebactin via the same BGC and ratios of these compounds were controlled by substrate availability (Böttcher and Clardy, 2014; Rütschlin et al, 2017). Interestingly, entomopathogenic Xenorhabdus szentirmaii only produced putrebactin and avaroferrin (Hirschmann et al, 2017), while in our analysis of E. anophelis Ag1 only bisucaberin was detected, suggesting great diversity and fine control of the ratio of these siderophores by different species. Overall, all of the siderophores identified by MS were putatively assigned to a BGC ( Data Set S1E ) and then prioritized for bioactivity studies.…”

Section: Resultsmentioning

confidence: 58%

A Systematic Analysis of Mosquito-Microbiome Biosynthetic Gene Clusters Reveals Antimalarial Siderophores that Reduce Mosquito Reproduction Capacity

Ganley

Pandey

Sylvester³

et al. 2020

Preprint

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21 22 23 24 25 26 2 ABSTRACT 27Advances in infectious disease control strategies through genetic manipulation of insect 28 microbiomes have heightened interest in microbially produced small molecules within 29 mosquitoes. Herein, 33 mosquito-associated bacterial genomes were mined and over 700 30 putative biosynthetic gene clusters (BGCs) were identified, 135 of which belong to known 31 classes of BGCs. After an in-depth analysis of the 135 BGCs, iron-binding siderophores 32 were chosen for further investigation due to their high abundance and well-characterized 33 bioactivities. Through various metabolomic strategies, eight siderophore scaffolds were 34 identified in six strains of mosquito-associated bacteria. Among these, serratiochelin A 35 and pyochelin were found to reduce female Anopheles gambiae overall fecundity likely by 36 lowering their blood feeding rate. Serratiochelin A and pyochelin were further found to 37 inhibit the Plasmodium parasite asexual blood and liver stages in vitro. Our work supplies 38 a bioinformatic resource for future mosquito microbiome studies and highlights an 39 understudied source of bioactive small molecules. 40 41 KEYWORDS 42 Mosquito-Microbiome; Biosynthetic Gene Clusters; Siderophores; Anopheles; 43 Plasmodium 44 45 46 100 transmit avian malaria, P. gallinaceum (Alavi et al., 2003), as well as human infectious 101 agents including dengue virus, Zika virus, and others (2016). As a relevant disease vector,102 Aedes-associated bacteria were also included in our data set. Due to the limited amount 103 of genome sequencing data on mosquito-associated bacteria, especially when compared 104 5 to human microbiomes, our sample size is smaller than analogous studies (Aleti et al., 105 2019; Donia et al., 2014; Helfrich et al., 2018), however this enabled an in-depth 106 bioinformatic analysis. Despite this size, our data set well-represents the unique gut 107 microbiome of mosquitoes. Our previous metagenomic study demonstrated that within the 108 gut microbiota of field-caught A. gambiae mosquitoes four days post blood-meal, 5 109 bacterial genera (Serratia, Elizabethkingia, Acinetobacter, Enterobacter, and 110 Pseudomonas) constitute 84 % of the 16S rRNA reads (Wang et al., 2011), all of which 111 are represented within our sample set. 112 A phylogenetic tree comparing the 33 bacterial strains was generated (Figure 113 1). The best-represented bacterial phylum in our sample set was Proteobacteria (16 γ-114 Proteobacteria, 1 β-Proteobacteria, and 3 α-Proteobacteria), consistent with reports 115 showing Proteobacteria are often the overwhelming microbial phylum in the midgut of 116 field-caught Anopheles mosquitoes (Wang et al., 2011). Species in the Bacteroidetes 117 phylum, which include Elizabethkingia spp., were the second most recurrent group (4 118 Elizabethkingia spp. and 1 Sphingobacterium sp.) in our analysis. Elizabethkingia spp. are 119 well-established mosquito symbionts that are the dominant species within midguts 4-and 120 7-days post-blood meal (PBM) as well as 7-day...

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The chemical biology and coordination chemistry of putrebactin, avaroferrin, bisucaberin, and alcaligin

et al. 2018

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Dihydroxamic acid macrocyclic siderophores comprise four members: putrebactin (putH), avaroferrin (avaH), bisucaberin (bisH), and alcaligin (alcH). This mini-review collates studies of the chemical biology and coordination chemistry of these macrocycles, with an emphasis on putH. These Fe(III)-binding macrocycles are produced by selected bacteria to acquire insoluble Fe(III) from the local environment. The macrocycles are optimally pre-configured for Fe(III) binding, as established from the X-ray crystal structure of dinuclear [Fe(alc)] at neutral pH. The dimeric macrocycles are biosynthetic products of two endo-hydroxamic acid ligands flanked by one amine group and one carboxylic acid group, which are assembled from 1,4-diaminobutane and/or 1,5-diaminopentane as initial substrates. The biosynthesis of alcH includes an additional diamine C-hydroxylation step. Knowledge of putH biosynthesis supported the use of precursor-directed biosynthesis to generate unsaturated putH analogues by culturing Shewanella putrefaciens in medium supplemented with unsaturated diamine substrates. The X-ray crystal structures of putH, avaH and alcH show differences in the relative orientations of the amide and hydroxamic acid functional groups that could prescribe differences in solvation and other biological properties. Functional differences have been borne out in biological studies. Although evolved for Fe(III) acquisition, solution coordination complexes have been characterised between putH and oxido-V(IV/V), Mo(VI), or Cr(V). Retrosynthetic analysis of 1:1 complexes of [Fe(put)], [Fe(ava)], and [Fe(bis)] that dominate at pH < 5 led to a forward metal-templated synthesis approach to generate the Fe(III)-loaded macrocycles, with apo-macrocycles furnished upon incubation with EDTA. This mini-review aims to capture the rich chemistry and chemical biology of these seemingly simple compounds.

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Identification and occurrence of the hydroxamate siderophores aerobactin, putrebactin, avaroferrin and ochrobactin C as virulence factors from entomopathogenic bacteria

Cited by 24 publications

References 60 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

A Systematic Analysis of Mosquito-Microbiome Biosynthetic Gene Clusters Reveals Antimalarial Siderophores that Reduce Mosquito Reproduction Capacity

The chemical biology and coordination chemistry of putrebactin, avaroferrin, bisucaberin, and alcaligin

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