SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2028753722> ?p ?o ?g. }

Showing items 1 to 100 of ±131 with 100 items per page.

W2028753722 endingPage "307" @default.
W2028753722 startingPage "279" @default.
W2028753722 abstract "The relations among geochemical parameters and sediment microbial communities were examined at three shoreline sites in the Prince William Sound, Alaska, which display varying degrees of impact by acid-rock drainage (ARD) associated with historic mining of volcanogenic massive sulfide deposits. Microbial communities were examined using total fatty acid methyl esters (FAMEs), a class of compounds derived from lipids produced by eukaryotes and prokaryotes (bacteria and Archaea); standard extraction techniques detect FAMEs from both living (viable) and dead (non-viable) biomass, but do not detect Archaeal FAMEs. Biomass and diversity (as estimated by FAMEs) varied strongly as a function of position in the tidal zone, not by study site; subtidal muds, Fe oxyhydroxide undergoing biogenic reductive dissolution, and peat-rich intertidal sediment had the highest values. These estimates were lowest in acid-generating, intertidal zone sediment; if valid, the estimates suggest that only one or two bacterial species predominate in these communities, and/or that Archeal species are important members of the microbial community in this sediment. All samples were dominated by bacterial FAMEs (median value >90%). Samples with the highest absolute abundance of eukaryotic FAMEs were biogenic Fe oxyhydroxides from shallow freshwater pools (fungi) and subtidal muds (diatoms). Eukaryotic FAMEs were practically absent from low-pH, sulfide-rich intertidal zone sediments. The relative abundance of general microbial functional groups such as aerobes/anaerobes and gram(+)/gram(−) was not estimated due to severe inconsistency among the results obtained using several metrics reported in the literature. Principal component analyses (PCAs) were performed to investigate the relationship among samples as separate functions of water, sediment, and FAMEs data. PCAs based on water chemistry and FAMEs data resulted in similar relations among samples, whereas the PCA based on sediment chemistry produced a very different sample arrangement. Specifically, the sediment parameter PCA grouped samples with high bulk trace metal concentration regardless of whether the metals were incorporated into secondary precipitates or primary sulfides. The water chemistry PCA and FAMEs PCA appear to be less prone to this type of artifact. Signature lipids in sulfide-rich sediments could indicate the presence of acid-tolerant and/or acidophilic members of the genus Thiobacillus or they could indicate the presence of SO4-reducing bacteria. The microbial community documented in subtidal and offshore sediments is rich in SRB and/or facultative anaerobes of the Cytophaga–Flavobacterium group; both could reasonably be expected in PWS coastal environments. The results of this study provide evidence for substantial feedback between local (meter to centimeter-scale) geochemical variations, and sediment microbial community composition, and show that microbial community signatures in the intertidal zone are significantly altered at sites where ARD drainage is present relative to sites where it is not, even if the sediment geochemistry indicates net accumulation of ARD-generated trace metals in the intertidal zone." @default.
W2028753722 created "2016-06-24" @default.
W2028753722 creator A5000044573 @default.
W2028753722 creator A5024668058 @default.
W2028753722 creator A5027406123 @default.
W2028753722 creator A5031876319 @default.
W2028753722 creator A5084542168 @default.
W2028753722 date "2008-02-01" @default.
W2028753722 modified "2023-09-26" @default.
W2028753722 title "Relationships between microbial communities and environmental parameters at sites impacted by mining of volcanogenic massive sulfide deposits, Prince William Sound, Alaska" @default.
W2028753722 cites W1487313274 @default.
W2028753722 cites W1489164720 @default.
W2028753722 cites W1508431936 @default.
W2028753722 cites W157217960 @default.
W2028753722 cites W1924378188 @default.
W2028753722 cites W1972035091 @default.
W2028753722 cites W1975878087 @default.
W2028753722 cites W1976322364 @default.
W2028753722 cites W1983549579 @default.
W2028753722 cites W2005152450 @default.
W2028753722 cites W2008477463 @default.
W2028753722 cites W2013623894 @default.
W2028753722 cites W2024173332 @default.
W2028753722 cites W2027167494 @default.
W2028753722 cites W2046559488 @default.
W2028753722 cites W2050425822 @default.
W2028753722 cites W2055784913 @default.
W2028753722 cites W2058603385 @default.
W2028753722 cites W2074492610 @default.
W2028753722 cites W2081213267 @default.
W2028753722 cites W2095589143 @default.
W2028753722 cites W2098321812 @default.
W2028753722 cites W2109865955 @default.
W2028753722 cites W2116798320 @default.
W2028753722 cites W2117742746 @default.
W2028753722 cites W2118464635 @default.
W2028753722 cites W2121316598 @default.
W2028753722 cites W2122319775 @default.
W2028753722 cites W2133600437 @default.
W2028753722 cites W2137437404 @default.
W2028753722 cites W2138361239 @default.
W2028753722 cites W2146703683 @default.
W2028753722 cites W2148937292 @default.
W2028753722 cites W2149283314 @default.
W2028753722 cites W2165136056 @default.
W2028753722 cites W4213045799 @default.
W2028753722 cites W4214869545 @default.
W2028753722 doi "https://doi.org/10.1016/j.apgeochem.2007.10.012" @default.
W2028753722 hasPublicationYear "2008" @default.
W2028753722 type Work @default.
W2028753722 sameAs 2028753722 @default.
W2028753722 citedByCount "15" @default.
W2028753722 countsByYear W20287537222012 @default.
W2028753722 countsByYear W20287537222016 @default.
W2028753722 countsByYear W20287537222017 @default.
W2028753722 countsByYear W20287537222019 @default.
W2028753722 countsByYear W20287537222020 @default.
W2028753722 countsByYear W20287537222021 @default.
W2028753722 crossrefType "journal-article" @default.
W2028753722 hasAuthorship W2028753722A5000044573 @default.
W2028753722 hasAuthorship W2028753722A5024668058 @default.
W2028753722 hasAuthorship W2028753722A5027406123 @default.
W2028753722 hasAuthorship W2028753722A5031876319 @default.
W2028753722 hasAuthorship W2028753722A5084542168 @default.
W2028753722 hasConcept C107872376 @default.
W2028753722 hasConcept C115540264 @default.
W2028753722 hasConcept C122325731 @default.
W2028753722 hasConcept C127313418 @default.
W2028753722 hasConcept C130452526 @default.
W2028753722 hasConcept C151730666 @default.
W2028753722 hasConcept C17409809 @default.
W2028753722 hasConcept C174580923 @default.
W2028753722 hasConcept C178790620 @default.
W2028753722 hasConcept C185592680 @default.
W2028753722 hasConcept C18903297 @default.
W2028753722 hasConcept C194356953 @default.
W2028753722 hasConcept C2779669040 @default.
W2028753722 hasConcept C2780596425 @default.
W2028753722 hasConcept C2816523 @default.
W2028753722 hasConcept C39432304 @default.
W2028753722 hasConcept C523546767 @default.
W2028753722 hasConcept C53657456 @default.
W2028753722 hasConcept C550995028 @default.
W2028753722 hasConcept C77077793 @default.
W2028753722 hasConcept C81407943 @default.
W2028753722 hasConcept C86803240 @default.
W2028753722 hasConcept C89944131 @default.
W2028753722 hasConceptScore W2028753722C107872376 @default.
W2028753722 hasConceptScore W2028753722C115540264 @default.
W2028753722 hasConceptScore W2028753722C122325731 @default.
W2028753722 hasConceptScore W2028753722C127313418 @default.
W2028753722 hasConceptScore W2028753722C130452526 @default.
W2028753722 hasConceptScore W2028753722C151730666 @default.
W2028753722 hasConceptScore W2028753722C17409809 @default.
W2028753722 hasConceptScore W2028753722C174580923 @default.
W2028753722 hasConceptScore W2028753722C178790620 @default.
W2028753722 hasConceptScore W2028753722C185592680 @default.
W2028753722 hasConceptScore W2028753722C18903297 @default.