人工染色体研究进展

doi:10.3724/SP.J.1005.2011.00293

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HEREDITAS ›› 2011, Vol. 33 ›› Issue (4): 293-297.doi: 10.3724/SP.J.1005.2011.00293

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Advances and perspectives in artificial chromosomes

LI Lin-Chuan, HAN Fang-Pu

State Key Laboratory of Plant Cell and Chromosome Engineering, Institute of Genetics and Developmental Biology, Chinese Academy of Sciences, Beijing 100101, China

Received:2010-10-07 Revised:2010-12-06 Online:2011-04-20 Published:2011-04-25
Contact: HAN Fang-Pu E-mail:fphan@genetics.ac.cn

Abstract

Abstract: Artificial chromosomes (ACs) are genetic-engineered vector systems with defined native chromosomal elements. ACs have large carrying capacity and genetic stability without integration into host genome, thus avoiding random insertion and positional effects. ACs were first successfully developed in yeast (Yeast artificial chromosome, YAC), and then in bacterium (Bacterial artificial chromosome, BAC), human (Human artificial chromosome, HAC), and plant (Plant artificial chromosome, PAC). Here, we summarized recent progress on ACs, especially, on PAC. To date, YAC and BAC have been widely applied in genome sequencing and gene isolation, while HAC and PAC have been subjected to gene therapy, protein production, and plant transgenesis, respectively. Recently, American scientists reported a man-made genome of prokaryote Mycoplasma mycoides. However, like ACs, this man-made genome was also genetic-engineered product and can’t survive as an independent life without a cellular environment.

Key words: gene therapy, plant artificial chromosome, transgenic plant, artificial chromosomes

LI Lin-Chuan, HAN Fang-Pu. Advances and perspectives in artificial chromosomes[J]. HEREDITAS, 2011, 33(4): 293-297.

References

[1] Mehta GD, Agarwal MP, Ghosh SK. Centromere identity: a challenge to be faced. Mol Genet Genomics, 2010, 284(2): 75-94.
[2] Dalal Y, Bui M. Down the rabbit hole of centromere assembly and dynamics. Curr Opin Cell Biol, 2010, 22(3): 392-402.
[3] Jain D, Cooper JP. Telomeric strategies: means to an end. Annu Rev Genet, 2010, 44: 243-269.
[4] Giraud-Panis MJ, Pisano S, Poulet A, Le Du MH, Gilson E. Structural identity of telomeric complexes. FEBS Lett, 2010, 584(17): 3785-3799.
[5] Murray AW, Szostak JW. Construction of artificial chromosomes in yeast. Nature, 1983, 305(5931): 189-193.
[6] Burke DT, Carle GF, Olson MV. Cloning of large segments of exogenous DNA into yeast by means of artificial chromosome vectors. Science, 1987, 236(4803): 806-812.
[7] Bellis M, Gérard A, Charlieu JP, Marçais B, Brun ME, Viegas-Péquignot E, Carter DA, Roizès G. Construction and characterization of a partial library of yeast artificial chromosomes from human chromosome 21. DNA Cell Biol, 1991, 10(4): 301-310.
[8] Green ED, Riethman HC, Dutchik JE, Olson MV. Detection and characterization of chimeric yeast artificial-chromosome clones. Genomics, 1991, 11(3): 658-669.
[9] Roberts L. Two chromosomes down, 22 to go. Science, 1992, 258(5079): 28-30.
[10] Sakata K, Antonio BA, Mukai Y, Nagasaki H, Sakai Y, Ma-kino K, Sasaki T. INE: a rice genome database with an integrated map view. Nucleic Acids Res, 2000, 28 (1): 97-101.
[11] Shizuya H, Birren B, Kim UJ, Mancino V, Slepak T, Tachiiri Y, Simon M. Cloning and stable maintenance of 300-kilobase-pair fragments of human DNA in Escherichia coli using an F-factor-based vector. Proc Natl Acad Sci USA, 1992, 89(18): 8794-8797.
[12] Shizuya H, Kouros-Mehr H. The development and applications of the bacterial artificial chromosome cloning system. Keio J Med, 2001, 50(1): 26-30.
[13] Kim UJ, Shizuya H, Kang HL, Choi SS, Garrett CL, Smink LJ, Birren BW, Korenberg JR, Dunham I, Simon MI. A bacterial artificial chromosome-based framework contig map of human chromosome 22q. Proc Natl Acad Sci USA, 1996, 93(13): 6297-6301.
[14] Asakawa S, Abe I, Kudoh Y, Kishi N, Wang YM, Kubota R, Kudoh J, Kawasaki K, Minoshima S, Shimizu N. Hu-man BAC library: construction and rapid screening. Gene, 1997, 191(1): 69-79.
[15] Harrington JJ, Van Bokkelen G, Mays RW, Gustashaw K, Willard HF. Formation of de novo centromeres and construction of first-generation human artificial microchromosomes. Nat Genet, 1997, 15(4): 345-355.
[16] Irvine DV, Shaw ML, Choo KH, Saffery R. Engineering chromosomes for delivery of therapeutic genes. Trends Biotechnol, 2005, 23(12): 575-583.
[17] Heller R, Brown KE, Burgtorf C, Brown WR. Mini-chromosomes derived from the human Y chromosome by telomere directed chromosome breakage. Proc Natl Acad Sci USA, 1996, 93(14): 7125-7130.
[18] Duncan A, Hadlaczky G. Chromosomal engineering. Curr Opin Biotechnol, 2007, 18(5): 420-424.
[19] Lufino MM, Edser PA, Wade-Martins R. Advances in high-capacity extrachromosomal vector technology: episomal maintenance, vector delivery, and transgene expression. Mol Ther, 2008, 16(9): 1525-1538.
[20] Macnab S, Whitehouse A. Progress and prospects: human artificial chromosomes. Gene Therapy, 2009, 16(10): 1180-1188.
[21] Keith KC, Copenhaver GP, Luo S, Preuss D. Arabidopsis centromeres: minichromosome analysis of functional centromere domains. Abstract of 11^th Arabidopsis Meeting, 2000, 41: 49.
[22] Carlson SR, Rudgers GW, Zieler H, Mach JM, Luo S, Grunden E, Krol C, Copenhaver GP, Preuss D. Meiotic transmission of an in vitro-assembled autonomous maize minichromosome. PLoS Genet, 2007, 3(10): 1965-1974.
[23] Onomura K, Kurata N. Construction of rice

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