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Placenta-specific gene activation and inactivation using integrase-defective lentiviral vectors with the Cre/LoxP system. Morioka Yuka,Isotani Ayako,Oshima Robert G,Okabe Masaru,Ikawa Masahito Genesis (New York, N.Y. : 2000) Transgenic and knockout studies have advanced our understanding of the genetic control of embryonic development over the past decades. However, interpretation of the phenotype of mutant mice is potentially complicated, since the commonly used knockout approach modifies both the fetal and placental genome. To circumvent this problem, we previously developed a placenta-specific gene manipulation system by lentiviral vector transduction of embryos at the blastocyst stage. In the present study, by combination with the Cre/LoxP system, we successfully demonstrate placenta-specific gene activation and inactivation in EGFP reporter mice and Ets2 floxed mice, respectively. Transient expression using integrase-defective lentiviral (IDLV) vectors diminished the toxic effect of Cre expression and solved the dilemma of mosaic recombination with lower concentrations and toxic effects with higher concentrations of Cre recombinase. We also show that placenta-specific Ets2 disruption causes embryonic lethality and reconfirmed the critical role of Ets2 during placentation. This technology facilitates both gain and loss of gene function analyses in placental development during pregnancy. Since IDLV vectors can efficiently transduce a variety of cell types similarly to wild-type vectors, our IDLV-Cre strategy is potentially useful for a wide range of applications. 10.1002/dvg.20563
Trophoblast-specific gene manipulation using lentivirus-based vectors. Georgiades Pantelis,Cox Brian,Gertsenstein Marina,Chawengsaksophak Kallayanee,Rossant Janet BioTechniques The trophoblast layers of the mammalian placenta carry out many complex functions required to pattern the developing embryo and maintain its growth and survival in the uterine environment. Genetic disruption of many gene pathways can result in embryonic lethality because of placental failure, potentially confusing the interpretation of mouse knockout phenotypes. Development of tools to specifically and efficiently manipulate gene expression in the trophoblast lineage would greatly aid understanding of the relative roles of different genetic pathways in the trophoblast versus embryonic lineages. We show that short-term lentivirus-mediated infection of mouse blastocysts can lead to rapid expression of a green fluorescent protein (GFP) transgene specifically in the outer trophoblast progenitors and their later placental derivatives. Efficient trophoblast-specific gene knockdown can also be produced by lentivirus-mediated pol III-driven short hairpin RNA (shRNA) and efficient trophoblast-specific gene knockout by pol II-driven Cre recombinase lentiviral vectors. This lentivirus lineage-specific infection system thus facilitates both gain and loss of function studies during placental development in the mouse and potentially other mammalian species. 10.2144/000112341
Complementation of placental defects and embryonic lethality by trophoblast-specific lentiviral gene transfer. Okada Yuka,Ueshin Yuko,Isotani Ayako,Saito-Fujita Tomoko,Nakashima Hisako,Kimura Kazushi,Mizoguchi Akira,Oh-Hora Masatsugu,Mori Yoshiko,Ogata Masato,Oshima Robert G,Okabe Masaru,Ikawa Masahito Nature biotechnology Placental dysfunction underlies many complications during pregnancy, and better understanding of gene function during placentation could have considerable clinical relevance. However, the lack of a facile method for placenta-specific gene manipulation has hampered investigation of placental organogenesis and the treatment of placental dysfunction. We showed previously that transduction of fertilized mouse eggs with lentiviral vectors leads to transgene expression in both the fetus and the placenta. Here we report placenta-specific gene incorporation by lentiviral transduction of mouse blastocysts after removal of the zona pellucida. All of the placentas analyzed, but none of the fetuses, were transgenic. Application of this method substantially rescued mice deficient in Ets2, Mapk14 (also known as p38alpha) and Mapk1 (also known as Erk2) from embryonic lethality caused by placental defects. Ectopic expression of Mapk11 also complemented Mapk14 deficiency during placentation. 10.1038/nbt1280