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Journal home Advance online publication Current issue Archive Press releases Free Association (blog) Supplements Focuses Guide to authors Online submission For referees Free online issue Contact the journal Subscribe Advertising work@npg Reprints and permissions About this site For librarians   NPG Resources Nature Nature Biotechnology Nature Cell Biology Nature Medicine Nature Methods Nature Reviews Cancer Nature Reviews Genetics Nature Reviews Molecular Cell Biology news@nature.com Nature Conferences RNAi Gateway NPG Subject areas Biotechnology Cancer Chemistry Clinical Medicine Dentistry Development Drug Discovery Earth Sciences Evolution & Ecology Genetics Immunology Materials Science Medical Research Microbiology Molecular Cell Biology Neuroscience Pharmacology Physics Browse all publications Article Nature Genetics  30, 66 - 72 (2001) Published online: 10 December 2001; | doi:10.1038/ng788 Efficient Cre-loxP−induced mitotic recombination in mouse embryonic stem cells Pentao Liu, Nancy A. Jenkins & Neal G. Copeland Mouse Cancer Genetics Program, Center for Cancer Research, National Cancer Institute at Frederick, Frederick, Maryland 21702, USA. Correspondence should be addressed to Neal G. Copeland copeland@ncifcrf.govFLP/FRT-induced mitotic recombination provides a powerful method for creating genetic mosaics in Drosophila and for discerning the function of recessive genes in a heterozygous individual. Here we show that mitotic recombination can be reproducibly induced in mouse embryonic stem (ES) cells, by Cre/loxP technology, at frequencies ranging from 4.2 10-5 (Snrpn) to 7.0 10-3 (D7Mit178) for single allelic loxP sites, and to 5.0 10-2 (D7Mit178) for multiple allelic lox sites, after transient Cre expression. Notably, much of the recombination occurs in G2 and is followed by X segregation, where the recombinant chromatids segregate away from each other during mitosis. It is X segregation that is useful for genetic mosaic analysis because it produces clones of homozygous mutant daughter cells from heterozygous mothers. Our studies confirm the predictions made from studies in Drosophila 1 that suggest that X segregation will not be limited to organisms with strong mitotic pairing, because the forces (sister-chromatid cohesion) responsible for X segregation are an elemental feature of mitosis in all eukaryotes. Our studies also show that genetic mosaic analysis in mice is feasible, at least for certain chromosomal regions. MORE ARTICLES LIKE THIS These links to content published by NPG are automatically generated RESEARCH Engineering a mouse balancer chromosome Nature Genetics Letters (01 Aug 1999)  Top Abstract Previous | Next Table of contents Full text Download PDF Send to a friend Save this link Open Innovation Challenges Single-cell Analysis Platform Deadline: Dec 02 2009 Reward: $5,000 USD This Challenge is looking for novel approaches to analyzing changes at a single-cell level. This is... Optimizing Sub-cellular Localization Tags Deadline: Jan 31 2010 Reward: $20,000 USD The Seeker is looking for methods to optimize sub-cellular localization tags for protein expression.... More Challenges Powered by: nature jobs Faculty Positions University of Texas Medical Branch Galveston, TX United States Sr. Scientific Manager / Chief Scientific Manager - Discovery Bioanalytical Research and Biotransformation Syngene International Bangalore, Karnataka 560099 India More science jobs Post a job for free Figures & Tables See also: News and Views by Adams & Bradley Export citation Search buyers guide:   ADVERTISEMENT

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