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dc.contributor.advisor El Dorry, Hamza Mofeed, Norhan Mohammed Magdy
dc.creator Mofeed, Norhan Mohammed Magdy 2012-06-03T07:43:56Z 2013-06-03T16:00:04Z 2012 Spring 2012-06-03T07:43:56Z
dc.description.abstract Atlantis II is the largest brine pool in the Red Sea. It lies at 2,200m deep with an area of about 60km2. The lower convective layer of the Atlantis II brine pool (ATII-LCL) is characterized by extreme conditions, the temperature reaches 68.2°C, salinity of 270 psu, and there is high concentration of heavy metals. Microbial communities inhabiting this harsh environment are expected to have enzymes and proteins that are adapted to these conditions. Such proteins and enzymes would be very attractive candidates not just to understand the structural alteration that lead to their adaptation to these abiotic factors, but also for their potential use in industrial and biotechnological applications. In this work we established an ATII-LCL metagenomics dataset of potential biomass and cell wall degrading enzymes. Out of 1,337,597 pyrosequencing reads, a total of 28,547 contigs were assembled using Newbler GS assembler version 2.6. A total of 58,124 predicted open reading frames (ORFs) were identified using Metagene Annotator program. We searched the 58,124 ORFs for domains that matched to cell wall and biomass degrading enzymes using the Pfam database Version 26. The 53 matched sequences were confirmed by BLASTx search against NCBI nr database. Upstream regulatory elements, ribosome binding sequence, and secretory signal peptide sequences for secretion were checked for their presence. Additionally, halophilicity based on high prevalence of aspartic and glutamic acids was checked. Out of the 53 potential ORFs, only 14 presented a full-length coding sequence. We selected 4 ORFs with high similarities to cellulases, alpha galactosidase and cell wall lytic enzyme for further investigation. The four proteins have traditional signal peptide for secretion, and high occurrences of aspartic and glutamic amino acids when compared with non-halophilic orthologues. Moreover, the 3D structures of the four proteins were predicted and the relevant acidic amino acid residues were located on the surface of the molecules. Based on these features, we believe that the four proteins should have unique properties regarding stability in high saline solution, high temperature, and elevated concentration of heavy metals. Thus, this work established a dataset of the most abundant glycosyl hydrolases present in the microbial community of the ATII-LCL environment, and selected the most promising candidates for further molecular and catalytic characterization. en
dc.description.sponsorship I would like to thank my mentor, Professor Dr. Hamza El Dorry for advising me and supervising my thesis, Dr. Mohammed Ghazy for his continuous help and support throughout my work. I would like as well to thank Dr. Rania Siam for her support and guidance throughout my studying. I would also like to thank Dr. Ari Ferreira, Mr. Hazem Sharaf, Mr. Mustafa Adel and Ms Mariam RizkAllah for their help in the computational work. And I would like to extend my thanks to Mr. Mohamed Maged who helped me with everything. I would also like to thank KAUST for providing us with the funds necessary to do this work. And I would extend my thanks to the Alfi foundation which provided me with a fellowship and enabled me to complete my thesis. en
dc.format.medium theses en
dc.language.iso en en
dc.rights Author retains all rights with regard to copyright. en
dc.subject Metagenomics en
dc.subject Genomics en
dc.subject Genetics en
dc.subject Red Sea Region en
dc.subject.lcsh Thesis (M.S.)--American University in Cairo en
dc.subject.lcsh Biotechnology -- Red Sea -- Egypt.
dc.subject.lcsh Microbiology -- Red Sea -- Egypt.
dc.subject.lcsh Genetic engineering -- Red Sea -- Egypt.
dc.subject.lcsh Molecular biology -- Red Sea -- Egypt.
dc.title In silico identification of potential biomass and cell wall degrading enzymes in the microbial community of the Red Sea Atlantis-II brine pool using metagenomic approach en
dc.type Text en
dc.subject.discipline Biotechnology en
dc.rights.access This item is restricted for 1 year from the date issued en
dc.contributor.department American University in Cairo. Dept. of Biology en
dc.description.irb American University in Cairo Institutional Review Board approval is not necessary for this item, since the research is not concerned with living human beings or bodily tissue samples. en

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    This collection includes theses and dissertations authored by American University in Cairo graduate students.

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