Characterisation, Manipulation and Directed Evolution of Non-Ribosomal Peptide Synthetase Enzymes

<p><b>Non-ribosomal peptide synthetases (NRPS) are large, modular enzymes that synthesisebiologically active secondary metabolites from amino acid precursors without the need for anucleic acid template. NRPS play an integral role in microbial physiology and also havepotential applications in the synthesis of novel peptide molecules. Both of these aspects areexamined in this thesis.</b></p> <p>Under conditions of iron starvation Pseudomonas syringae synthesises siderophores for activeuptake of iron. The primary siderophore of P. syringae is pyoverdine, a fluorescent moleculethat is assembled from amino acid (aa) precursors by NRPS. Five putative pyoverdine NRPSgenes in P. syringae pv. phaseolicola 1448a (Ps1448a) were identified and characterised insilico and their role in pyoverdine biosynthesis was confirmed by gene knockout. Creation ofpyoverdine null Ps1448a enabled identification of a previously uncharacterised temperatureregulatedsecondary siderophore, achromobactin, which is NRPS independent and has loweraffinity for iron. Pyoverdine and achromobactin null mutants were characterised in regard toiron uptake, virulence and growth in iron-limited conditions. Determination of the substratespecificity for the seven adenylation (A) domains of the Ps1448a pyoverdine sidechain NRPSwas also attempted. Although ultimately unsuccessful, these attempts provided a rigorousassessment of methods for the expression, purification and biochemical characterisation of Adomains.</p> <p>The Ps1448a NRPS were subsequently employed in domain swapping experiments to testcondensation (C) domain specificity for aa substrates during peptide formation in vivo.</p> <p>Experiments in which the terminal C- and/or A-domain of the Pseudomonas aeruginosa(PAO1) pyoverdine NRPS system were replaced with alternative domains from Ps1448a andPAO1 were consistent with previous in vitro observations that C-domains exhibit strongsidechain and stereo-selectivity at the downstream aa position, but only stereo-selectivity atthe upstream aa position.</p> <p>These results prompted investigation into the role of inter-domain communication in NRPSfunction, to test the hypothesis that the thiolation (T) domain enters into specific interactionswith other domains, which might provide an alternative explanation for the diminished activityof recombinant NRPS enzymes. A recently characterised single-module NRPS, bpsA, waschosen as a reporter gene for these experiments based on its ability to generate blue pigment inEscherichia coli. Substitution of the native bpsA T-domain consistently impaired function,consistent with the hypothesis. It was shown that directed evolution could be applied to restorefunction in substituted T-domains. Mutations that restored function were mapped in silico, anda structural model for interaction between the thioester (TE) and T-domain of BpsA wasderived.</p> <p>The utility of bpsA for discovery and characterisation of phosphopantetheinyl transferase(PPTase) enzymes was also investigated. In vivo and in vitro assays for determination ofPPTase activity were developed and a high-throughput screen for discovery of new PPTases inenvironmental DNA libraries was successfully implemented.</p>

Characterisation, Manipulation and Directed Evolution of Non-Ribosomal Peptide Synthetase Enzymes

<p><b>Non-ribosomal peptide synthetases (NRPS) are large, modular enzymes that synthesisebiologically active secondary metabolites from amino acid precursors without the need for anucleic acid template. NRPS play an integral role in microbial physiology and also havepotential applications in the synthesis of novel peptide molecules. Both of these aspects areexamined in this thesis.</b></p> <p>Under conditions of iron starvation Pseudomonas syringae synthesises siderophores for activeuptake of iron. The primary siderophore of P. syringae is pyoverdine, a fluorescent moleculethat is assembled from amino acid (aa) precursors by NRPS. Five putative pyoverdine NRPSgenes in P. syringae pv. phaseolicola 1448a (Ps1448a) were identified and characterised insilico and their role in pyoverdine biosynthesis was confirmed by gene knockout. Creation ofpyoverdine null Ps1448a enabled identification of a previously uncharacterised temperatureregulatedsecondary siderophore, achromobactin, which is NRPS independent and has loweraffinity for iron. Pyoverdine and achromobactin null mutants were characterised in regard toiron uptake, virulence and growth in iron-limited conditions. Determination of the substratespecificity for the seven adenylation (A) domains of the Ps1448a pyoverdine sidechain NRPSwas also attempted. Although ultimately unsuccessful, these attempts provided a rigorousassessment of methods for the expression, purification and biochemical characterisation of Adomains.</p> <p>The Ps1448a NRPS were subsequently employed in domain swapping experiments to testcondensation (C) domain specificity for aa substrates during peptide formation in vivo.</p> <p>Experiments in which the terminal C- and/or A-domain of the Pseudomonas aeruginosa(PAO1) pyoverdine NRPS system were replaced with alternative domains from Ps1448a andPAO1 were consistent with previous in vitro observations that C-domains exhibit strongsidechain and stereo-selectivity at the downstream aa position, but only stereo-selectivity atthe upstream aa position.</p> <p>These results prompted investigation into the role of inter-domain communication in NRPSfunction, to test the hypothesis that the thiolation (T) domain enters into specific interactionswith other domains, which might provide an alternative explanation for the diminished activityof recombinant NRPS enzymes. A recently characterised single-module NRPS, bpsA, waschosen as a reporter gene for these experiments based on its ability to generate blue pigment inEscherichia coli. Substitution of the native bpsA T-domain consistently impaired function,consistent with the hypothesis. It was shown that directed evolution could be applied to restorefunction in substituted T-domains. Mutations that restored function were mapped in silico, anda structural model for interaction between the thioester (TE) and T-domain of BpsA wasderived.</p> <p>The utility of bpsA for discovery and characterisation of phosphopantetheinyl transferase(PPTase) enzymes was also investigated. In vivo and in vitro assays for determination ofPPTase activity were developed and a high-throughput screen for discovery of new PPTases inenvironmental DNA libraries was successfully implemented.</p>

Systematic identification of molecular mediators underlying sensing of Staphylococcus aureus by Pseudomonas aeruginosa

Bacteria typically exist in dynamic, multispecies communities where polymicrobial interactions influence fitness. Elucidating the molecular mechanisms underlying these interactions is critical for understanding and modulating bacterial behavior in natural environments. While bacterial responses to foreign species are frequently characterized at the molecular and phenotypic level, the exogenous molecules that elicit these responses are understudied. Here we outline a systematic strategy based on transcriptomics combined with genetic and biochemical screens of promoter-reporters to identify the molecules from one species that are sensed by another. We utilized this method to study interactions between the pathogens Pseudomonas aeruginosa and Staphylococcus aureus that are frequently found in co-infections. We discovered that P. aeruginosa senses diverse staphylococcal exoproducts including the metallophore staphylopine, intermediate metabolites citrate and acetoin, and multiple molecules that modulate its iron starvation response. Further, we show that staphylopine inhibits biofilm formation and that P. aeruginosa can utilize citrate and acetoin for growth, revealing that these interactions have both antagonistic and beneficial effects. Our screening approach thus identified multiple S. aureus secreted molecules that are sensed by P. aeruginosa and affect its physiology, demonstrating the efficacy of this approach, and yielding new insight into the molecular basis of interactions between these two species.

Hemin-dependent siderophore utilization promotes iron-restricted growth of the Staphylococcus aureus hemB small colony variant

Respiration deficient S. aureus small colony variants (SCVs) frequently cause persistent infections, which necessitates they acquire iron, yet how SCVs obtain iron remains unknown. To address this, we created a stable hemB mutant in S. aureus USA300 strain LAC. The hemB SCV utilized exogenously supplied hemin but was attenuated for growth under conditions of iron starvation. RNA-seq showed that both WT S. aureus and the hemB mutant sense and respond to iron starvation, however, growth assays show that the hemB mutant is defective for siderophore-mediated iron acquisition. Indeed, the hemB SCV demonstrated limited utilization of endogenous staphyloferrin B or exogenously provided staphyloferrin A, Desferal, and epinephrine. Direct measurement of intracellular ATP in hemB and WT S. aureus revealed that both strains can generate comparable levels of ATP during exponential growth suggesting defects in ATP production cannot account for the inability to efficiently utilize siderophores. Defective siderophore utilization by hemB bacteria was also evident in vivo , as administration of Desferal failed to promote hemB bacterial growth in every organ analyzed except for the kidneys. In support of the hypothesis that S. aureus accesses heme in kidney abscesses, in vitro analyses revealed that increased hemin availability enables hemB bacteria to utilize siderophores for growth when iron availability is restricted. Taken together, our data support the conclusion that hemin is not only used as an iron source itself, but as a nutrient that promotes utilization of siderophore-iron complexes. Importance S. aureus small colony variants (SCVs) are associated with chronic recurrent infection and worsened clinical outcome. SCVs persist within the host despite administration of antibiotics. This study yields insight into how S. aureus SCVs acquire iron which, during infection of a host, is a difficult-to-acquire metal nutrient. Under hemin-limited conditions, hemB S. aureus is impaired for siderophore-dependent growth and, in agreement, murine infection indicates that hemin-deficient SCVs meet their nutritional requirement for iron through utilization of hemin. Importantly, we demonstrate that hemB SCVs rely upon hemin as a nutrient to promote siderophore utilization. Therefore, perturbation of heme biosynthesis and/or utilization represents a viable to strategy to mitigate the ability of SCV bacteria to acquire siderophore-bound iron during infection.

Tumor cell-imposed iron restriction drives immunosuppressive polarization of tumor-associated macrophages

Background Tumor-associated macrophages (TAM) are immunosuppressive cells that contribute to impaired anti-cancer immunity. Iron plays a critical role in regulating macrophage function. However, it is still elusive whether it can drive the functional polarization of macrophages in the context of cancer and how tumor cells affect the iron-handing properties of TAM. In this study, using hepatocellular carcinoma (HCC) as a study model, we aimed to explore the effect and mechanism of reduced ferrous iron in TAM. Methods TAM from HCC patients and mouse HCC tissues were collected to analyze the level of ferrous iron. Quantitative real-time PCR was used to assess M1 or M2 signature genes of macrophages treated with iron chelators. A co-culture system was established to explore the iron competition between macrophages and HCC cells. Flow cytometry analysis was performed to determine the holo-transferrin uptake of macrophages. HCC samples from The Cancer Genome Atlas (TCGA) were enrolled to evaluate the prognostic value of transferrin receptor (TFRC) and its relevance to tumor-infiltrating M2 macrophages. Results We revealed that ferrous iron in M2-like TAM is lower than that in M1-like TAM. In vitro analysis showed that loss of iron-induced immunosuppressive M2 polarization of mouse macrophages. Further experiments showed that TFRC, the primary receptor for transferrin-mediated iron uptake, was overexpressed on HCC cells but not TAM. Mechanistically, HCC cells competed with macrophages for iron to upregulate the expression of M2-related genes via induction of HIF-1α, thus contributing to M2-like TAM polarization. We further clarified the oncogenic role of TFRC in HCC patients by TCGA. TFRC is significantly increased in varieties of malignancies, including HCC, and HCC patients with high TFRC levels have considerably shortened overall survival. Also, TFRC is shown to be positively related to tumor-infiltrating M2 macrophages. Conclusions Collectively, we identified iron starvation through TFRC-mediated iron competition drives functional immunosuppressive polarization of TAM, providing new insight into the interconnection between iron metabolism and tumor immunity.

PP2A Methylation is Necessary for Broad Stress Tolerance

Background: LEUCINE CARBOXYL METHYL TRANSFERASE 1 (LCMT1) transfers a methyl group from the methyl donor S-adenosylmethionine (SAM) to the catalytic subunit of PROTEIN PHOSPHATASE 2A (PP2A). This post-translational modification of PP2A is manifested throughout eukaryotes from yeast to plants and animals. Although highly conserved, the importance of the methylation is poorly understood. Since Arabidopsis plants with knocked out LCMT1 grow and develop fairly normally, we decided to search for conditions that may reveal the benefits of this regulation. We compared the effects of various stressful conditions on Arabidopsis wild type (WT) and a lcmt1 mutant possessing only non-methylated PP2A. Results: Seedlings were grown in Petri dishes for 5-12 days, or in rock wool and soil for up to 7 weeks. A significant increase in sodium concentration was found for lcmt1 relative to WT, but this was not linked with stressful conditions. Plants were exposed to variable levels of the chelator EDTA, iron, zinc, aluminium, heat, and hydrogen peroxide. The lcmt1 mutant was clearly more sensitive than WT to all the various stresses, as demonstrated by effects on seedling root growth and on shoots of rosette stage plants on rock wool. When omitting EDTA, expression of genes known as signature genes for iron deficiency, FIT1, bHLH100, IMA1, IRT1 was strongly enhanced in lcmt1. Although an iron starvation response was induced, Fe homeostasis was apparently maintained by slowed growth in lcmt1 and the Fe level related to tissue dry weight was not changed. Among genes induced in lcmt1 were also the Zn induced gene ZIF1, and heat shock protein HSP90-1. Concentrations of non-iron transition metals, Cu, Mn and Zn, increased significantly in response to lack of EDTA for both lcmt1 and WT tissue, and especially the growth of lcmt1 was strongly hampered. Conclusions: Presence of the LCMT1 gene was necessary to cope efficiently with an imbalance in the micronutrients, heat stress, and oxidative stress. Methylation of PP2A appears important to ameliorate the toxic effects of metals present in unfavourable high concentrations as well as heat or oxidative stress. The experiments establish LCMT1 as a key component in broad stress tolerance.

Correlated transcriptional responses provide insights into the synergy mechanisms of the furazolidone, vancomycin and sodium deoxycholate triple combination in Escherichia coli

Effective therapeutic options are urgently needed to tackle antibiotic resistance. Furazolidone (FZ), vancomycin (VAN), and sodium deoxycholate (DOC) show promise as their combination can synergistically inhibit the growth of, and kill, multidrug-resistant Gram-negative bacteria that are classified as critical priority by the World Health Organization. Here, we investigated the mechanisms of action and synergy of this drug combination using a transcriptomics approach in the model bacterium Escherichia coli. We show that FZ and DOC elicit highly similar gene perturbations indicative of iron starvation, decreased respiration and metabolism, and translational stress. In contrast, VAN induced envelope stress responses, in agreement with its known role in peptidoglycan synthesis inhibition. FZ induced the SOS response consistent with its DNA damaging effects, but we demonstrate that using FZ in combination with the other two compounds enables use of lower dosages and largely mitigates its mutagenic effects. Based on the gene expression changes identified, we propose a synergy mechanism where the combined effects of FZ, VAN, and DOC amplify damage to Gram-negative bacteria while simultaneously suppressing antibiotic resistance mechanisms.

Loss of RND-type multidrug efflux pumps triggers iron starvation and lipid A modifications in Pseudomonas aeruginosa

Transporters belonging to the Resistance-Nodulation-Division (RND) superfamily of proteins are invariably present in the genomes of Gram-negative bacteria and are largely responsible for the intrinsic antibiotic resistance of these organisms. The number of genes encoding RND transporters per genome vary from one to sixteen and correlates with environmental versatilities of bacterial species. Pseudomonas aeruginosa PAO1 strain, a ubiquitous nosocomial pathogen, possesses twelve RND pumps, which are implicated in development of clinical multidrug resistance and known to contribute to virulence, quorum sensing and many other physiological functions. In this study, we analyzed how P. aeruginosa physiology adapts to the lack of RND-mediated efflux activities. A combination of transcriptomics, metabolomics, genetic and analytical approaches showed that the P. aeruginosa PΔ6 strain lacking six best characterized RND pumps activates a specific adaptation response that involves significant changes in abundance and activities of several transport systems, quorum sensing, iron acquisition and lipid A modifications. Our results demonstrate that these cells accumulate large quantities of pseudomonas quorum signal (PQS), which triggers iron starvation and activation of siderophore biosynthesis and acquisition pathways. The accumulation of iron in turn activates lipid A modification and membrane protection pathways. A transcriptionally regulated RND pump MuxABC-OpmB contributes to these transformations by controlling concentrations of coumarins. Our results suggest that these changes reduce the permeability barrier of the outer membrane and are needed to protect the cell envelope of efflux-deficient P. aeruginosa .

CYB561A3 is the Key Lysosomal Iron Reductase Required for Burkitt B-cell Growth and Survival

Epstein-Barr virus (EBV) causes endemic Burkitt lymphoma, the leading childhood cancer in sub-Saharan Africa. Burkitt cells retain aspects of germinal center B-cell physiology with MYC-driven B-cell hyperproliferation, yet little is presently known about their iron metabolism. CRISPR/Cas9 analysis highlighted the little studied ferrireductase CYB561A3 as critical for Burkitt proliferation, but not for that of closely related EBV-transformed lymphoblastoid cells or nearly all other Cancer Dependency Map cell lines. Burkitt CYB561A3 knockout induced profound iron starvation, despite ferritinophagy and plasma membrane transferrin upregulation. Elevated concentrations of ascorbic acid, a key CYB561 family electron donor or the labile iron source ferrous citrate rescued Burkitt CYB561A3 deficiency. CYB561A3 knockout caused catastrophic lysosomal and mitochondrial damage and impaired mitochondrial respiration. By contrast, lymphoblastoid B-cells with the transforming EBV latency III program were instead dependent on the STEAP3 ferrireductase. These results highlight CYB561A3 it as an attractive therapeutic Burkitt lymphoma target.

Heme-dependent siderophore utilization promotes iron-restricted growth of the Staphylococcus aureus hemB small colony variant

The ability to acquire iron is essential for Staphylococcus aureus to cause infection. Respiration deficient S. aureus small colony variants (SCVs) frequently cause persistent infections, which necessitates they too acquire iron. How SCVs obtain iron remains unknown and so here we addressed this outstanding question by creating a stable hemB mutant in S. aureus USA300 strain LAC. The mutant, auxotrophic for hemin, was assessed for its ability to grow under iron-restriction and with various iron sources. The hemB SCV utilizes exogenously supplied heme but was attenuated for growth under conditions of iron starvation. RNA-seq analyses showed that both WT S. aureus and the hemB mutant sense and respond to iron starvation, however, growth assays show that the hemB mutant is defective for siderophore-mediated iron acquisition. Indeed, the hemB SCV demonstrates limited utilization of endogenous staphyloferrin B or exogenously provided staphyloferrin A, Desferal, and epinephrine, which enabled the SCV to sustain only minimal growth in iron deplete media. Direct measurement of intracellular ATP in hemB and WT S. aureus revealed that both strains can generate comparable levels of ATP during exponential growth suggesting defects in ATP production cannot account for the inability to efficiently utilize siderophores. Defective siderophore utilization by hemB bacteria was also evident in vivo. Indeed, the administration of Desferal failed to promote hemB bacterial growth in vivo, in contrast to WT, in every organ analyzed except for the murine kidney where growth was enhanced. In support of the hypothesis that S. aureus accesses heme in kidney abscesses, in vitro analyses revealed that increased heme availability enables hemB bacteria to utilize siderophores for growth when iron availability is restricted. Taken together, our data support the conclusion that heme is not only used as an iron source itself, but as a nutrient that promotes utilization of siderophore-iron complexes.