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- All Subjects: Microbiology
- Creators: School of Life Sciences
- Creators: Wang, Xuan
- Status: Published
Description
Metabolic engineering of bacteria has become a viable technique as a sustainable and efficient method for the production of biochemicals. Two main goals were explored: investigating styrene tolerance genes in E. coli and engineering cyanobacteria for the high yield production of L-serine. In the first study, genes that were shown to be highly differentially expressed in E. coli upon styrene exposure were further investigated by testing the effects of their deletion and overexpression on styrene tolerance and growth. It was found that plsX, a gene responsible for the phospholipid formation in membranes, had the most promising results when overexpressed at 10 µM IPTG, with a relative OD600 of 706 ± 117% at 175 mg/L styrene when compared to the control plasmid at the same concentration. This gene is likely to be effective target when engineering styrene- and other aromatic-producing strains, increasing titers by reducing their cytotoxicity.In the second study, the goal is to engineer the cyanobacterium Synechococcus sp. PCC 7002 for the overproduction of L-serine. As a robust, photosynthetic bacteria, it has potential for being used in such-rich states to capture CO2 and produce industrially relevant products. In order to increase L-serine titers, a key degradation gene, ilvA, must be removed. While ilvA is responsible for degrading L-serine into pyruvate, it is also responsible for initiating the only known pathway for the production of isoleucine. Herein, we constructed a plasmid containing the native A0730 gene in order to investigate its potential to restore isoleucine production. If functional, a Synechococcus sp. PCC 7002 ΔilvA strain can then be engineered with minimal effects on growth and an expected increase in L-serine accumulation.
ContributorsAbed, Omar (Author) / Nielsen, David R (Thesis advisor) / Varman, Arul M (Committee member) / Wang, Xuan (Committee member) / Arizona State University (Publisher)
Created2021
Description
Little is known about the diversity and role of bacteriophages in carbon (C) rich ecosystems such as peatlands in tropical and temperate regions. In fact, there is no currently published assessment of phage abundance on diversity in a key tropical ecosystem such as Amazon peatlands. To better understand phage assemblages in terrestrial ecosystems and how bacteriophages influence organic C cycling to final products like CO2 and CH4, phage communities and phage-like particles were recovered, quantified, and viable phage particles were enriched from pore water from contrasting Amazon peatlands. Here we present the first results on assessing Amazon bacteriophages on native heterotrophic bacteria. Several steps to test for methodological suitability were taken. First, the efficiency of iron flocculation method was determined using fluorescent microscopy counts of phage TLS, a TolC-specific and LPS-specific bacteriophage, and Escherichia coli host pre- and post-extraction method. One-hundred percent efficiency and 0.15% infectivity was evidenced. Infectivity effects were determined by calculating plaque forming units pre and post extraction method. After testing these methods, fieldwork in the Amazon peatlands ensued, where phages were enriched from pore water samples. Phages were extracted and concentrated by in tandem filtering rounds to remove organic matter and bacteria, and then iron flocculation to bind the phages and allow for precipitation onto a filter. Phage concentrates were then used for overall counts, with fluorescent microscopy, as well as phage isolation attempts. Phage isolations were performed by first testing for lysis of host cells in liquid media using OD600 absorbance of cultures with and without phage concentrate as well as attempts with the cross-streaking methods. Forty-five heterotrophic bacterial isolates obtained from the same Amazon peatland were challenged with phage concentrates. Once a putative host was found, steps were taken to further propagate and isolate the phage. Several putative phages were enriched from Amazon peatland pore water and require further characterization. TEM imaging was taken of two phages isolated from two plaques. Genomes of selected phages will be sequenced for identification. These results provide the groundwork for further characterizing the role bacteriophage play in C cycling and greenhouse gas production from Amazon peatland soils.
ContributorsSpring, Jessica Lynette (Author) / Cadillo-Quiroz, Hinsby (Thesis director) / Haydel, Shelley (Committee member) / Misra, Rajeev (Committee member) / School of Life Sciences (Contributor) / Barrett, The Honors College (Contributor)
Created2016-05
Description
Persons with cystic fibrosis (CF) are highly susceptible to lung infections caused by the opportunistic pathogens Pseudomonas aeruginosa (PA) and Staphylococcus aureus (SA). By age 20, ~16% of CF patients have co-infections with these two bacteria, and this number grows as the patients age1. PA-SA co-infections are associated with worsened clinical outcomes in CF patients, but the reasons are not well understood. One hypothesis is that SA influences the production of PA virulence factors and other chronic infection phenotypes. Previous work in our lab investigated the effects of SA on PA quorum-regulated phenotypes when they are grown as planktonic co-cultures. We are expanding on this result by testing whether SA can influence PA phenotypes without being in direct contact, and without being able to exchange soluble secreted factors. In this study, we hypothesized that SA produces volatile organic compounds (VOCs) that cause changes in PA phenotypes leading to a down-regulation of motility and protease production, and increased antibiotic resistance. To test this hypothesis, we exposed two laboratory strains of PA to the VOCs produced by pre-grown lawns of two strains of SA, and measured PA motility by conducting swarming, swimming, and twitching assays, measuring protease production, as well as antibiotic sensitivity. After exposing PA to a pre-grown lawn of SA, there was a significant difference in some phenotypes compared to controls. There were significant decreases in swarming motility, twitching motility, and protease production, and an increase in a bright green pigment (possibly siderophores) when PA was exposed to SA. The degree of phenotypic alterations was dependent on both the PA strain and the SA strain being tested. Exposure to SA VOCs also altered PA sensitivity to ciprofloxacin, though one strain caused an increase in susceptibility while the other SA strain caused an increase in resistance. These data demonstrate that SA VOCs can influence PA phenotypes in vitro, which may have relevance for CF patients who are co-infected with these two bacteria.
ContributorsLopez, Brianna Marie (Author) / Bean, Heather (Thesis director) / Misra, Rajeev (Committee member) / School of Life Sciences (Contributor) / Barrett, The Honors College (Contributor)
Created2020-05