Browsing by Subject "plasmid construction"
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Item Crucial Optimization of Translational Components towards Efficient Incorporation of Unnatural Amino Acids into Proteins in Mammalian Cells(PLOS One, 2013-07-12) Xiang, Liang; Monciviais, Kathryn; Jiang, Faqin; Williams, Blake; Alfonta, Lital; Zhnag, Zhiwen J.The ability to site-specifically incorporate unnatural amino acids (UAAs) into proteins is a powerful tool in protein engineering. While dozens of UAAs have been successfully introduced into proteins expressed by Escherichia coli cells, it has been much more challenging to create tRNA and tRNA-Synthetase pairs that enable UAAs incorporation, for use in mammalian systems. By altering the orthogonality properties of existing unnatural pairs, previously evolved pairs for use in E. coli could be used in mammalian cells. This would bypass the cumbersome step of having to evolve mutant synthetases and would allow for the rapid development of new mammalian pairs. A major limitation to the amount of UAA-containing proteins that can be expressed in the cell is the availability of UAA-charged orthogonal suppressor tRNA. By using a natural mammalian tRNA promoter, the amount of functional suppressor tRNA can be greatly increased. Furthermore, increasing recognition of the suppressor tRNA by the mutant synthetase will ultimately lead to the appearance of more UAA-charged tRNA.Item A Targetron System for Gene Targeting in Thermophiles and Its Application in Clostridium thermocellum(PLOS One, 2013-07-09) Mohr, Georg; Hong, Wei; Zhang, Jie; Cui, Gu-zhen; Yang, Yunfeng; Cui, Qiu; Liu, Ya-jun; Lambowitz, Alan M.Background: Targetrons are gene targeting vectors derived from mobile group II introns. They consist of an autocatalytic intron RNA (a “ribozyme”) and an intron-encoded reverse transcriptase, which use their combined activities to achieve highly efficient site-specific DNA integration with readily programmable DNA target specificity. -- Methodology/Principal Findings: Here, we used a mobile group II intron from the thermophilic cyanobacterium Thermosynechococcus elongatus to construct a thermotargetron for gene targeting in thermophiles. After determining its DNA targeting rules by intron mobility assays in Escherichia coli at elevated temperatures, we used this thermotargetron in Clostridium thermocellum, a thermophile employed in biofuels production, to disrupt six different chromosomal genes (cipA, hfat, hyd, ldh, pta, and pyrF). High integration efficiencies (67–100% without selection) were achieved, enabling detection of disruptants by colony PCR screening of a small number of transformants. Because the thermotargetron functions at high temperatures that promote DNA melting, it can recognize DNA target sequences almost entirely by base pairing of the intron RNA with less contribution from the intron-encoded protein than for mesophilic targetrons. This feature increases the number of potential targetron-insertion sites, while only moderately decreasing DNA target specificity. Phenotypic analysis showed that thermotargetron disruption of the genes encoding lactate dehydrogenase (ldh; Clo1313_1160) and phosphotransacetylase (pta; Clo1313_1185) increased ethanol production in C. thermocellum by decreasing carbon flux toward lactate and acetate. -- Conclusions/SignificanceThermotargetron provides a new, rapid method for gene targeting and genetic engineering of C. thermocellum, an industrially important microbe, and should be readily adaptable for gene targeting in other thermophiles.Item Transposable Prophage Mu Is Organized as a Stable Chromosomal Domain of E. coli(PLOS Genetics, 2013-11-07) Saha, Rudra P.; Lou, Zheng; Meng, Luke; Harshey, Rasika M>The E. coli chromosome is compacted by segregation into 400–500 supercoiled domains by both active and passive mechanisms, for example, transcription and DNA-protein association. We find that prophage Mu is organized as a stable domain bounded by the proximal location of Mu termini L and R, which are 37 kbp apart on the Mu genome. Formation/maintenance of the Mu ‘domain’ configuration, reported by Cre-loxP recombination and 3C (chromosome conformation capture), is dependent on a strong gyrase site (SGS) at the center of Mu, the Mu L end and MuB protein, and the E. coli nucleoid proteins IHF, Fis and HU. The Mu domain was observed at two different chromosomal locations tested. By contrast, prophage λ does not form an independent domain. The establishment/maintenance of the Mu domain was promoted by low-level transcription from two phage promoters, one of which was domain dependent. We propose that the domain confers transposition readiness to Mu by fostering topological requirements of the reaction and the proximity of Mu ends. The potential benefits to the host cell from a subset of proteins expressed by the prophage may in turn help its long-term stability.