Unveiling the Pool of Metallophores in Native Environments and Correlation with Their Potential Producers

Calderón Celis, Francisco; González-Álvarez, Ivan; Fabjanowicz, Magdalena; Godin, Simon; Ouerdane, Laurent; Lauga, Béatrice; Łobiński, Ryszard

doi:10.1021/acs.est.3c04582

Cited by 3 publications

(2 citation statements)

References 68 publications

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“…The presence of a putative BGC not only provides evidence that a siderophore is being produced but also can be used to predict the chemical structure of the molecule and dereplicate it against known compounds. Several platforms have been developed for the automated detection of BGCs in a genome, and two of the most popular are antiSMASH and PRISM. , AntiSMASH is a rapid and reliable source for finding gene clusters responsible for the biosynthesis of secondary metabolites and has been widely applied to the discovery of new and known siderophores. − The antiSMASH analysis pipeline, designed for bacterial genomes, and its recent counterpart, fungiSMASH for fungal genomes, share a common codebase. Both pipelines offer specific options through their respective web submission forms.…”

Section: Genomic Approach and Bioinformatic Toolsmentioning

confidence: 99%

“… 121 , 122 AntiSMASH is a rapid and reliable source for finding gene clusters responsible for the biosynthesis of secondary metabolites and has been widely applied to the discovery of new and known siderophores. 123 − 125 The antiSMASH analysis pipeline, designed for bacterial genomes, and its recent counterpart, fungiSMASH for fungal genomes, share a common codebase. Both pipelines offer specific options through their respective web submission forms.…”

Section: Genomic Approach and Bioinformatic Toolsmentioning

confidence: 99%

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A Practical Toolkit for the Detection, Isolation, Quantification, and Characterization of Siderophores and Metallophores in Microorganisms

Gomes,

Sousa,

Resende

2024

ACS Omega

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Section: Genomic Approach and Bioinformatic Toolsmentioning

confidence: 99%

Section: Genomic Approach and Bioinformatic Toolsmentioning

confidence: 99%

A Practical Toolkit for the Detection, Isolation, Quantification, and Characterization of Siderophores and Metallophores in Microorganisms

Gomes,

Sousa,

Resende

2024

ACS Omega

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Transforming Agro-Industrial Waste into Bioplastic Coating Films

Castillo-Patiño,

Rosas-Mejía,

Albalate-Ramírez

et al. 2024

ACS Omega

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Addressing the environmental impact of agro-industrial waste, this study explores the transformation of banana, potato, and orange peels into bioplastics suitable for thin coating films. We prepared six extracts at 100 g/L, encompassing individual (banana peel, BP; orange peel, OP; and potato peel, PP) and combined [BP/OP, BP/PP, and BP/OP/PP] formulations, with yeast mold (YM) medium serving as the control. Utilizing the spin-coating method, we applied 1 mL of each sample at 1000 rpm for 1 min to create the films. Notably, the OP extract demonstrated a twofold increase in bioplastic yield (860.33 mg/L) compared to the yields of BP (391.43 mg/L), PP (357.67 mg/L), BP/OP (469.40 mg/L), BP/PP (382.50 mg/L), BP/OP/PP (272.67 mg/L), and YM (416.33 mg/L) extracts. Atomic force microscopy analysis of the film surfaces revealed a roughness under 8 nm, with the OP extract recording the highest at 7.0275 nm, whereas the BP/OP mixture exhibited the lowest roughness at 0.2067 nm and also formed the thinnest film at 6.5 nm. With R 2 trend values exceeding 0.9950, the films exhibited water vapor permeability values ranging from 3.05 × 10 −3 to 4.44 × 10 −3 , with the OP film being the least permeable and the BP/PP films the most permeable. The OP film demonstrated the lowest solubility in both water and ethanol with values of 64.71 and 1.05%, respectively. The solubilities of all films were above 60% in water and below 4% in ethanol. Furthermore, the films exhibited antimicrobial efficacy against both Gram-positive and Gram-negative bacteria. Our findings confirm the potential of utilizing banana, orange, and potato peels as viable substrates for eco-friendly bioplastics in thin-film applications.

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The Extracellular Metallometabolome: Metallophores, Metal Ionophores, and Other Chelating Agents as Natural Products

Maret

2024

Natural Product Communications

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Natural products include inorganic as well as organic compounds. Living organisms face constant challenges in acquiring essential metal ions and getting rid of non-essential ones with toxic actions. They employ an extracellular biochemistry in these tasks and use it to engage in a chemical warfare against invaders and competitors by either increasing or decreasing the availability of metal ions for maintaining their welfare in aquatic or terrestrial ecological niches. To control mutualistic, cambialistic or parasitic symbiosis with other organisms they use a remarkably rich suite of secreted bioactive molecules with ligand donor atoms for metal binding. This overview discusses the interactions of these extracellular natural products with a multitude of metal ions in the periodic system of the elements. It focuses mainly on metallophores and metal ionophores secreted from bacteria, fungi, and plants, but metal-carrying cofactors and other chelating agents will also be mentioned in the context of related functions and with an intent to categorize. The intracellular fate of the metal ions and the controlled pathways for the biosynthesis, secretion, uptake, biodegradation or recycling of the secreted natural products that interact with metal ions will not be covered. Metallophores make extracellular metal ions available via delivery to specific transporters and unavailable to competing organisms, especially pathogens, though some invaders have developed ways to compete efficiently for metal ions. The classic concept of siderophores, carriers of iron(III) ions, is extended here to specific and broad-band metallophores for metal ions such as copper (chalkophores), zinc (zincophores), and yet others. Metal ionophores, in contrast, transport metal ions through biological membranes. There is a wide variety of chemical structures for either metallophores or metal ionophores. Together with physicochemical investigations of metal complexation und conditions mimicking the natural environment, “omics” mining and mapping the diversity of chemotypes is an on-going effort with analytic, genetic, and bioinformatic tools and comes together in defining the metallometabolome, which combines the metabolome and the metallome. Investigations are highly multidisciplinary, include an important, but academically infrequently crossed bridge between the biosciences (biochemistry) and the earth sciences (geochemistry), define significant applications in the pharmaceutical/medical sciences regarding immune modulation and the control of virulence at the host-pathogen interface, and have implications for the nutritional/toxicological and environmental/ecological sciences.

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Unveiling the Pool of Metallophores in Native Environments and Correlation with Their Potential Producers

Cited by 3 publications

References 68 publications

A Practical Toolkit for the Detection, Isolation, Quantification, and Characterization of Siderophores and Metallophores in Microorganisms

A Practical Toolkit for the Detection, Isolation, Quantification, and Characterization of Siderophores and Metallophores in Microorganisms

Transforming Agro-Industrial Waste into Bioplastic Coating Films

The Extracellular Metallometabolome: Metallophores, Metal Ionophores, and Other Chelating Agents as Natural Products

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