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  1. 1.   Probing Cellular Processes with Oligo-Mediated Recombination and Using the Knowledge Gained to Optimize Recombineering
  2. Sawitzke, J. A.; Costantino, N.; Li, X. T.; Thomason, L. C.; Bubunenko, M.; Court, C.; Court, D. L.
  3. Journal of Molecular Biology. 2011, Mar; 407(1): 45-59.
  1. 2.   Advantages of q-PCR as a method of screening for gene targeting in mammalian cells using conventional and whole BAC-based constructs
  2. Gomez-Rodriguez, J.; Washington, V.; Cheng, J.; Dutra, A.; Pak, E.; Liu, P. T.; McVicar, D. W.; Schwartzberg, P. L.
  3. Nucleic Acids Research. 2008 36(18): 1-9.
  1. 3.   Multicopy plasmid modification with phage lambda red recombineering
  2. Thomason, L. C.; Costantino, N.; Shaw, D. V.; Court, D. L.
  3. Plasmid. 2007, Sep; 58(2): 148-158.
  1. 4.   Recombineering: In vivo genetic engineering in E-coli, S-enterica, and beyond
  2. Sawitzke, J. A.; Thomason, L. C.; Costantino, N.; Bubunenko, M.; Datta, S.; Court, D. L.
  3. Advanced Bacterial Genetics: Use of Transposons and Phage for Genomic Engieering. 2007; 421 : 171-199.
  1. 5.   The Ter mutation in the dead end gene causes germ cell loss and testicular germ cell tumours
  2. Youngren, K. K.; Coveney, D.; Peng, X. N.; Bhattacharya, C.; Schmidt, L. S.; Nickerson, M. L.; Lamb, B. T.; Deng, J. M.; Behringer, R. R.; Capel, B.; Rubin, E. M.; Nadeau, J. H.; Matin, A.
  3. Nature. 2005, MAY 19; 435(7040): 360-364.
  1. 6.   Simple and highly efficient BAC recombineering using gaIK selection
  2. Warming, S.; Costantino, N.; Court, D. L.; Jenkins, N. A.; Copeland, N. G.
  3. Nucleic Acids Research. 2005 33(4, Art. No. e36):
  1. 7.   Mini-lambda: a tractable system for chromosome and BAC engineering
  2. Court, D. L.; Swaminathan, S.; Yu, D. G.; Wilson, H.; Baker, T.; Bubunenko, M.; Sawitzke, J.; Sharan, S. K.
  3. Gene. 2003 315: 63-69.
  1. 8.   A highly efficient recombineering-based method for generating conditional knockout mutations
  2. Liu, P. T.; Jenkins, N. A.; Copeland, N. G.
  3. Genome Research. 2003 13(3): 476-484.
  1. 9.   Recombineering with overlapping single-stranded DNA oligonucleotides: Testing a recombination intermediate
  2. Yu, D. G.; Sawitzke, J. A.; Ellis, H.; Court, D. L.
  3. Proceedings of the National Academy of Sciences of the United States of America. 2003 100(12): 7207-7212.
  1. 10.   A simple two-step, 'hit and fix' method to generate subtle mutations in BACs using short denatured PCR fragments
  2. Yang, Y. P.; Sharan, S. K.
  3. Nucleic Acids Research. 2003 31(15): art. no.-e80.
  1. 11.   Recombineering: A powerful new tool for mouse functional genomics
  2. Copeland, N. G.; Jenkins, N. A.; Court, D. L.
  3. Nature Reviews Genetics. 2001 2(10): 769-779.
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