FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W3208352771> ?p ?o ?g. }

• W3208352771 endingPage "132712" @default.
• W3208352771 startingPage "132712" @default.
• W3208352771 abstract "Strains of the genus Mucilaginibacter, belonging to the phylum Bacteroidetes, have been noted for exhibiting high genome plasticity and for the vigorous production of extracellular polymeric substances (EPS). Here we analyzed the composition and properties of EPS generated by M. rubeus P2, isolated from a gold-copper mine and exhibiting extremely high resistance to multiple heavy metals. Production of EPS increased significantly upon exposure to elevated concentrations of Cu(II) and Zn(II), but not Au(III). In addition, the EPS produced by M. rubeus P2 displayed extremely high bio-adsorption of As(III), Cu(II) and Au(III), but not of Zn(II). Moreover, EPS production in Mucilaginibacter rubeus P2 exposed to 1 mM of Cu(II) was 8.5 times higher than EPS production in the same strain without metal (loid)-exposure. These findings constitute the basis for a future use of these EPS-overproducing bacteria in bioremediation of heavy metal contaminated environments. The functional groups, especially -SH, CO, and N-H/C-N in the fingerprint zone of glutathione (GSH) and polysaccharides-like components of EPS, were the main components of EPS involved in both Zn(II) and Cu(II) binding and removal. Around 31.22% and 5.74% of Cu(II)-treated EPS was shown to exist as (CO) structures and these structures were converted into C-OH and O-C-O upon exposure to Cu(II), respectively. In contrast, (C-OH/C-O-C/P-O-C) groups in EPS were observed to be positively correlated to increasing concentrations of Zn(II) in strain P2. Furthermore, the complete genome of M. rubeus P2 helped us to identify 350 genes involved in carbohydrate metabolism, some of which are predicted to be involved in EPS production and modification. This work describes the first detailed biochemical and biophysical analysis of EPS from any strain of Mucilaginibacter with unique heavy metal binding properties. The results will be useful for a better understanding of how microorganisms such as M. rubeus P2 adapt to heavy metal polluted environments and how this knowledge can potentially be harnessed in biotechnological applications such as industrial waste water purification, bioremediation of heavy metal contaminated soil and beneficial plant microbe interactions. The toolbox provided in this paper will provide a valuable basis for future studies." @default.
• W3208352771 created "2021-11-08" @default.
• W3208352771 creator A5002746612 @default.
• W3208352771 creator A5054696469 @default.
• W3208352771 creator A5056231336 @default.
• W3208352771 creator A5058346848 @default.
• W3208352771 creator A5058597533 @default.
• W3208352771 creator A5061046773 @default.
• W3208352771 creator A5066551452 @default.
• W3208352771 creator A5074402988 @default.
• W3208352771 creator A5075731050 @default.
• W3208352771 date "2022-03-01" @default.
• W3208352771 modified "2023-10-16" @default.
• W3208352771 title "Extrapolymeric substances (EPS) in Mucilaginibacter rubeus P2 displayed efficient metal(loid) bio-adsorption and production was induced by copper and zinc" @default.
• W3208352771 cites W1959259592 @default.
• W3208352771 cites W1987213952 @default.
• W3208352771 cites W2013825980 @default.
• W3208352771 cites W2028664630 @default.
• W3208352771 cites W2030935566 @default.
• W3208352771 cites W2043023252 @default.
• W3208352771 cites W2050711776 @default.
• W3208352771 cites W2070300719 @default.
• W3208352771 cites W2091105628 @default.
• W3208352771 cites W2097951502 @default.
• W3208352771 cites W2099139884 @default.
• W3208352771 cites W2122559203 @default.
• W3208352771 cites W2136189294 @default.
• W3208352771 cites W2317200742 @default.
• W3208352771 cites W2320627798 @default.
• W3208352771 cites W2583481107 @default.
• W3208352771 cites W2597506409 @default.
• W3208352771 cites W2621127270 @default.
• W3208352771 cites W2756416645 @default.
• W3208352771 cites W2770990758 @default.
• W3208352771 cites W2783912323 @default.
• W3208352771 cites W2788880212 @default.
• W3208352771 cites W2799292336 @default.
• W3208352771 cites W2810174411 @default.
• W3208352771 cites W2896186944 @default.
• W3208352771 cites W2902322224 @default.
• W3208352771 cites W2919323325 @default.
• W3208352771 cites W2920863521 @default.
• W3208352771 cites W2922178022 @default.
• W3208352771 cites W2954047626 @default.
• W3208352771 cites W2963262999 @default.
• W3208352771 cites W2964098286 @default.
• W3208352771 cites W2976079448 @default.
• W3208352771 cites W2980596195 @default.
• W3208352771 cites W2990651768 @default.
• W3208352771 cites W3009450966 @default.
• W3208352771 cites W3096829057 @default.
• W3208352771 cites W3118411522 @default.
• W3208352771 cites W3159641884 @default.
• W3208352771 cites W4293247451 @default.
• W3208352771 doi "https://doi.org/10.1016/j.chemosphere.2021.132712" @default.
• W3208352771 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/34715104" @default.
• W3208352771 hasPublicationYear "2022" @default.
• W3208352771 type Work @default.
• W3208352771 sameAs 3208352771 @default.
• W3208352771 citedByCount "6" @default.
• W3208352771 countsByYear W32083527712022 @default.
• W3208352771 countsByYear W32083527712023 @default.
• W3208352771 crossrefType "journal-article" @default.
• W3208352771 hasAuthorship W3208352771A5002746612 @default.
• W3208352771 hasAuthorship W3208352771A5054696469 @default.
• W3208352771 hasAuthorship W3208352771A5056231336 @default.
• W3208352771 hasAuthorship W3208352771A5058346848 @default.
• W3208352771 hasAuthorship W3208352771A5058597533 @default.
• W3208352771 hasAuthorship W3208352771A5061046773 @default.
• W3208352771 hasAuthorship W3208352771A5066551452 @default.
• W3208352771 hasAuthorship W3208352771A5074402988 @default.
• W3208352771 hasAuthorship W3208352771A5075731050 @default.
• W3208352771 hasConcept C100817775 @default.
• W3208352771 hasConcept C107872376 @default.
• W3208352771 hasConcept C129968341 @default.
• W3208352771 hasConcept C13965031 @default.
• W3208352771 hasConcept C150394285 @default.
• W3208352771 hasConcept C178790620 @default.
• W3208352771 hasConcept C185592680 @default.
• W3208352771 hasConcept C2124996 @default.
• W3208352771 hasConcept C2994085863 @default.
• W3208352771 hasConcept C523546767 @default.
• W3208352771 hasConcept C535196362 @default.
• W3208352771 hasConcept C54355233 @default.
• W3208352771 hasConcept C544153396 @default.
• W3208352771 hasConcept C544778455 @default.
• W3208352771 hasConcept C55493867 @default.
• W3208352771 hasConcept C58123911 @default.
• W3208352771 hasConcept C86803240 @default.
• W3208352771 hasConceptScore W3208352771C100817775 @default.
• W3208352771 hasConceptScore W3208352771C107872376 @default.
• W3208352771 hasConceptScore W3208352771C129968341 @default.
• W3208352771 hasConceptScore W3208352771C13965031 @default.
• W3208352771 hasConceptScore W3208352771C150394285 @default.
• W3208352771 hasConceptScore W3208352771C178790620 @default.
• W3208352771 hasConceptScore W3208352771C185592680 @default.
• W3208352771 hasConceptScore W3208352771C2124996 @default.
• W3208352771 hasConceptScore W3208352771C2994085863 @default.

• next