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Analysis of Exoelectrogenic Bacterial Communities Present in Different Brine Pools of the Red SeaOrtiz Medina, Juan F. 05 1900 (has links)
One contemporary issue experienced worldwide is the climate change due to the
combustion of fossil fuels. Microbial Electrochemical Systems pose as an alternative
for energy generation. In this technology, microorganisms are primarily responsible
for electricity production. To improve the performance it is reasonable to think
that bacteria from diverse environments, such as the brine pools of the Red Sea,
can be utilized in these systems. Samples from three brine pools: Atlantis II, Valdivia,
and Kebrit Deeps, were analyzed using Microbial Electrochemical Cells, with a
poised potential at +0.2 V (vs. Ag/AgCl) and acetate as electron donor, to evaluate
the exoelectrogenic activity by the present microorganisms. Only samples from Valdivia
Deep were able to produce a noticeable current of 6 A/m2. This result, along
with acetate consumption and changes on the redox activity measured with cyclic
voltammetry, provides arguments to con rm the presence of exoelectrogenic bacteria
in this environment. Further characterization using microscopy and molecular biology
techniques is required, to obtain the most amount of information about these
microorganisms and their potential use in bioelectrochemical technologies.
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Microbial Diversity and Ecology in the Interfaces of the Deep-sea Anoxic Brine Pools in the Red SeaHikmawan, Tyas I. 05 1900 (has links)
Deep-sea anoxic brine pools are one of the most extreme ecosystems on Earth, which are
characterized by drastic changes in salinity, temperature, and oxygen concentration. The
interface between the brine and overlaying seawater represents a boundary of oxic-anoxic
layer and a steep gradient of redox potential that would initiate favorable conditions for
divergent metabolic activities, mainly methanogenesis and sulfate reduction. This study
aimed to investigate the diversity of Bacteria, particularly sulfate-reducing communities,
and their ecological roles in the interfaces of five geochemically distinct brine pools in
the Red Sea. Performing a comprehensive study would enable us to understand the
significant role of the microbial groups in local geochemical cycles. Therefore, we
combined culture-dependent approach and molecular methods, such as 454
pyrosequencing of 16S rRNA gene, phylogenetic analysis of functional marker gene
encoding for the alpha subunits of dissimilatory sulfite reductase (dsrA), and single-cell
genomic analysis to address these issues. Community analysis based on 16S rRNA gene
sequences demonstrated high bacterial diversity and domination of Bacteria over Archaea
in most locations. In the hot and multilayered Atlantis II Deep, the bacterial communities
were stratified and hardly overlapped. Meanwhile in the colder brine pools, sulfatereducing
Deltaproteobacteria were the most prominent bacterial groups inhabiting the interfaces. Corresponding to the bacterial community profile, the analysis of dsrA gene
sequences revealed collectively high diversity of sulfate-reducing communities.
Desulfatiglans-like dsrA was the prevalent group and conserved across the Red Sea brine
pools. In addition to the molecular studies, more than thirty bacterial strains were
successfully isolated and remarkably were found to be cytotoxic against the cancer cell
lines. However, none of them were sulfate reducers. Thus, a single-cell genomic analysis
was used to study the metabolism of uncultured phyla without having them in culture.
We analysed ten single-cell amplified genomes (SAGs) of the uncultivated euryarchaeal
Marine Benthic Group E (MBGE), which contain a key enzyme for sulfate reduction.
The results showed the possibility of MBGE to grow autotrophically only with carbon
dioxide and hydrogen. In the absence of adenosine 5’-phosphosulfate reductase, we
hypothesized that MBGE perform sulfite reduction rather than sulfate reduction to
conserve energy.
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Red Sea Physicochemical Gradients as Drivers of Microbial Community AssemblyBarozzi, Alan 02 1900 (has links)
Environmental gradients exist at global and local scales and the variable conditions they
encompass allow the coexistence of different microbial assemblages. Studying gradients
and the selection forces they enclose can reveal the spatial succession and interactions of
microorganisms and, therefore, how they are assembled in functionally stable
communities. By combining high-throughput sequencing technology and laboratory
experimental approaches, I investigated the factors that influence the microbial community
assemblages in two types of environmental gradients in the Red Sea. I have studied the
communities in the chemoclines occurring at the transition zones along the interfaces
between seawater and the Deep Hypersaline Anoxic Brines (DHABs) at the bottom of the
Red Sea. Across these chemoclines salinity increases of 5-10 times respect to the overlying
seawater. I compared the microbial community diversity and metabolisms in the
chemoclines of five different DHABs, finding different microbial community
compositions due to the different DHABs characteristics, but the same succession of
metabolisms along the five interfaces. From the Suakin Deep brine, I assembled the
genome of a novel bacterial phylum and revealed the metabolic features that allow this
organism to cope with the challenging variable conditions along the chemocline. In an
alternative environmental system, I studied the effect of different thermal regimes on the
microbiome of coastal sediment exposed to different yearly ranges of temperature
variation. Sediment bacterial communities living under larger temperature variations are
more flexible and can grow under a larger range of thermal conditions than communities
experiencing narrower temperature ranges. My results highlight the large metabolic
flexibility of microorganisms and their capacity to efficiently self-organize in complex
functional assemblages under extreme ranges of environmental conditions.
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