Your search keyword '"Genetic transformation -- Physiological aspects"' showing total 4 results

1. Mechanism of chromosomal transfer of Enterococcus faecalis pathogenicity island, capsule, antimicrobial resistance, and other traits

Author

Manson, Janet M., Hancock, Lynn E., and Gilmore, Michael S.

Subjects

Enterococcus -- Genetic aspects, Plasmids -- Properties, Drug resistance in microorganisms -- Genetic aspects, Genetic transformation -- Physiological aspects, Science and technology

Abstract

The Enterococcus faecalis pathogenicity island (PAI) encodes known virulence traits and >100 additional genes with unknown roles in enterococcal biology. Phage-related integration and excision genes, and direct repeats flanking the island, suggest it moves as an integrative conjugative element (ICE). However, transfer was observed not to require these genes. Transfer only occurred from donors possessing a pheromone responsive-type of conjugative plasmid, and was invariably accompanied by transfer of flanking donor chromosome sequences. Deletion of plasmid transfer functions, including the cis-acting origin of transfer (oriT), abolished movement. In addition to demonstrating PAl movement by a mechanism involving plasmid integration, we observed transfer of a selectable marker placed virtually anywhere on the chromosome. Transfer of this selectable marker was observed to be accompanied by chromosome-chromosome transfer of vancomycin resistance, MLST markers, and capsule genes as well. Plasmid mobilization therefore appears to be a major mechanism for horizontal gene transfer in the evolution of antibiotic resistant E. faecalis strains capable of causing human infection. antibiotic resistance | horizontal gene transfer | plasmid mobilization doi/10.1073/pnas.1000139107

Published

2010

2. Repeated horizontal transfer of a DNA transposon in mammals and other tetrapods

Author

Pace, John K., II, Gilbert, Clement, Clark, Marlena S., and Feschotte, Cedric

Subjects

Vertebrates -- Genetic aspects, Genetic transformation -- Physiological aspects, Transposons -- Physiological aspects, Science and technology

Abstract

Horizontal transfer (HT) is central to the evolution of prokaryotic species. Selfish and mobile genetic elements, such as phages, plasmids, and transposons, are the primary vehicles for HT among prokaryotes. In multicellular eukaryotes, the prevalence and evolutionary significance of HT remain unclear. Here, we identified a set of DNA transposon families dubbed SPACE INVADERS (or SPIN) whose consensus sequences are [approximately equal to] 96% identical over their entire length (2.9 kb) in the genomes of murine rodents (rat/mouse), bushbaby (prosimian primate), little brown bat (laurasiatherian), tenrec (afrotherian), opossum (marsupial), and two non-mammalian tetrapods (anole lizard and African clawed frog). In contrast, SPIN elements were undetectable in other species represented in the sequence databases, including 19 other mammals with draft whole-genome assemblies. This patchy distribution, coupled with the extreme level of SPIN identity in widely divergent tetrapods and the overall lack of selective constraint acting on these elements, is incompatible with vertical inheritance, but strongly indicative of multiple horizontal introductions. We show that these germline infiltrations likely occurred around the same evolutionary time (15-46 mya) and spawned some of the largest bursts of DNA transposon activity ever recorded in any species lineage (nearly 100,000 SPIN copies per haploid genome in tenrec). The process also led to the emergence of a new gene in the murine lineage derived from a SPIN transposase. In summary, HT of DNA transposons has contributed significantly to shaping and diversifying the genomes of multiple mammalian and tetrapod species. genome evolution | lateral gene transfer | transposable elements | transposase

Published

2008

3. Efficient production by sperm-mediated gene transfer of human decay accelerating factor (hDAF) transgenic pigs for xenotransplantation

Author

Lavitrano, Marialuisa, Bacci, Maria Laura, Forni, Monica, Lazzereschi, Davide, Di Stefano, Carla, Fioretti, Daniela, Giancotti, Paola, Marfe, Gabriella, Pucci, Loredana, Renzi, Luigina, Wang, Hongjun, Stoppacciaro, Antonella, Stassi, Giorgio, Sargiacomo, Massimo, Sinibaldi, Paola, Turchi, Valeria, Giovannoni, Roberto, Della Casa, Giacinto, Seren, Eraldo, and Rossi, Giancarlo

Subjects

Genetic transformation -- Physiological aspects, Xenotransplantation -- Genetic aspects, Xenotransplantation -- Physiological aspects, Science and technology

Abstract

A large number of hDAF transgenic pigs to be used for xenotransplantation research were generated by using sperm-mediated gene transfer (SMGT). The efficiency of transgenesis obtained with SMGT was much greater than with any other method. In the experiments reported, up to 80% of pigs had the transgene integrated into the genome. Most of the pigs carrying the hDAF gene transcribed it in a stable manner (64%). The great majority of pigs that transcribed the gene expressed the protein (83%). The hDAF gene was transmitted to progeny. Expression was stable and found in caveolae as it is in human cells. The expressed gene was functional based on in vitro experiments performed on peripheral blood mononuclear cells. These results show that our SMGT approach to transgenesis provides an efficient procedure for studies involving large animal models. SMGT | hyperacute rejection | swine

Published

2002

4. High efficiency genetic modification of hair follicles and growing hair shafts

Author

Saito, Norimitsu, Zhao, Ming, Li, Lingna, Baranov, Eugene, Yang, Meng, Ohta, Yukinori, Katsuoka, Kensei, Penman, Sheldon, and Hoffman, Robert M.

Subjects

Epididymitis -- Observations, Epididymitis -- Genetic aspects, Collagenases -- Physiological aspects, Collagenases -- Research, Genetic transformation -- Physiological aspects, Genetic transformation -- Observations, Science and technology

Abstract

A technique for genetic modification of hair follicles was developed which results in efficient alteration of the hair shaft phenotype. High-level in vivo transgene expression was maintained in hair follicles such that growing hair shafts were phenotypically altered. Mouse anagen skin fragments, maintained in histoculture, were genetically modified at high efficiency with adenoviral-GFP. The histocultured skin fragments were treated with collagenase which made hair follicles accessible to the adenoviral GFP gene, allowing high-efficiency transduction. These skin fragments were subsequently grafted on to nude mice where GFP was readily visualized in as many as 75% of hair follicles. Most follicles produced GFP-fluorescent growing hair shafts. This technique has produced efficient genetic modification of the hair shaft. gene transfer | histoculture | collagenase | green fluorescent protein

Published

2002