We investigated the efficiency of a benthic diatom-associated bacteria in removing benzo(a)pyrene (BaP) and fluoranthene (Flt). The diatom, isolated from a PAH-contaminated sediment of the Bizerte ...Lagoon (Tunisia), was exposed in axenic and non-axenic cultures to PAHs over 7 days. The diversity of the associated bacteria, both attached (AB) and free-living bacteria (FB), was analyzed by the 16S rRNA amplicon sequencing. The diatom, which maintained continuous growth under PAH treatments, was able to accumulate BaP and Flt, with different efficiencies between axenic and non-axenic cultures. Biodegradation, which constituted the main process for PAH elimination, was enhanced in the presence of bacteria, indicating the co-metabolic synergy of microalgae and associated bacteria in removing BaP and Flt. Diatom and bacteria showed different capacities in the degradation of BaP and Flt. Nitzschia sp. harbored bacterial communities with a distinct composition between attached and free-living bacteria. The AB fraction exhibited higher diversity and abundance relative to FB, while the FB fraction contained genera with the known ability of PAH degradation, such as Marivita, Erythrobacter, and Alcaligenes. Moreover, strains of Staphylococcus and Micrococcus, isolated from the FB community, showed the capacity to grow in the presence of crude oil. These results suggest that a “benthic Nitzschia sp.-associated hydrocarbon-degrading bacteria” consortium can be applied in the bioremediation of PAH-contaminated sites.
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•An indigenous benthic diatom accumulated BaP and Flt, but biodegradation played the main role in the removal of PAH.•The biodegradation was enhanced by the presence of the diatom and its associated bacteria.•The diatom harbored bacterial genera identified as potential PAH degraders.•Strains isolated from the associated bacteria were able to grow in the presence of crude oil.
The screening of bacteria and archaea from Chott El Jerid, a hypersaline lake in the south of Tunisia, led to the isolation of 68 extremely halophilic prokaryotes growing in media with 15–25% of ...salt. Assessment of 68 partial 16S rRNA analyzed by amplified rDNA restriction analysis (ARDRA) revealed 15 different bacterial and archaeal taxonomic groups. Based on ARDRA results, phenotypic and hydrolytic activity tests, 20 archaeal and 6 bacterial isolates were selected for sequencing. The halophilic isolates were identified as members of the genera:
Salicola, Bacillus, Halorubrum, Natrinema
and
Haloterrigena
. Most of these isolates are able to produce hydrolytic enzymes such as amylase, protease, lipase, cellulase, xylanase, pectinase and some of them showed combined activities.
Natrinema
genus is an excellent candidate for lipase production. These results indicated that the extremely halophilic archaea and bacteria from Chott El Jerid are a potential source of hydrolytic enzymes and may possess commercial value.
Chott El Jerid is the largest hypersaline ephemeral lake in southern Tunisian Sahara desert and is one of the biggest depressions at the North of Africa. This study aimed to investigate the diversity ...and abundance of microbial communities inhabiting Chott El Jerid during wet season (when it was flooded), using molecular methods Illumina Miseq sequencing, DGGE and qPCR (qPCR). 16S rRNA gene analyses revealed that bacterial community was dominated by
Proteobacteria
(especially
Ralstonia
species), followed by
Firmicutes
,
Bacteroidetes
,
Cyanobacteria
,
Actinobacteria
and
Verrucomicrobia
. The results obtained using prokaryotic universal primers showed low relative abundance of
Archaea
dominated by few OTUs related to
Methanosarcinaceae
and
Methanomassiliicoccaceae
families and the presence of sulfate-reducing
Archaea
affiliated with
Archaeoglobus
. However, the results obtained using
Archaea
-specific primers showed that archaeal community was mainly composed of aerobic
Halobacteria
(especially
Halorubrum
species) and anaerobic members of
Methanomicrobia
. These results also provided evidence for the presence of members of the genus
Halohasta
in this environment. qPCR results revealed that
Archaea
were more abundant in studied samples than
Bacteria
. The sulfate-reducing
Bacteria
were also found abundant (~ one-third of the bacterial community) and outnumbered methanogens, suggesting their potential important role in this sulfate-rich and hypersaline ecosystem.
