Literature DB >> 17103243

Transformation of rice with long DNA-segments consisting of random genomic DNA or centromere-specific DNA.

Bao H Phan1, Weiwei Jin, Christopher N Topp, Cathy X Zhong, Jiming Jiang, R Kelly Dawe, Wayne A Parrott.   

Abstract

Rice was transformed with either long DNA-segments of random genomic DNA from rice, or centromere-specific DNA sequences from either maize or rice. Despite the repetitive nature of the transgenic DNA sequences, the centromere-specific sequences were inserted largely intact and behave as simple Mendelian units. Between 4 and 5% of bombarded callus clusters were transformed when bombarded with just pCAMBIA 1305.2. Frequency of recovery dropped to 2-3% when BACs with random genomic inserts were co-bombarded with pCAMBIA, and fell to less than 1% when BACs with centromeric DNA inserts and pCAMBIA were co-bombarded. A similar effect was noted on regeneration frequency. Differences in transformation ability, regeneration and behavior of plants transgenic for BACs with random genomic DNA inserts, as compared to those with centromeric DNA inserts, suggests functional differences between these two types of DNA.

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Year:  2006        PMID: 17103243     DOI: 10.1007/s11248-006-9041-3

Source DB:  PubMed          Journal:  Transgenic Res        ISSN: 0962-8819            Impact factor:   3.145


  24 in total

Review 1.  Plant centromeres: structure and control.

Authors:  E J Richards; R K Dawe
Journal:  Curr Opin Plant Biol       Date:  1998-04       Impact factor: 7.834

2.  Agrobacterium-mediated plant transformation with large DNA fragments.

Authors:  D Shibata; Y G Liu
Journal:  Trends Plant Sci       Date:  2000-08       Impact factor: 18.313

3.  Development of new transformation-competent artificial chromosome vectors and rice genomic libraries for efficient gene cloning.

Authors:  Yao-Guang Liu; Hongmei Liu; Letian Chen; Weihua Qiu; Qunyu Zhang; Hao Wu; Chunyi Yang; Jing Su; Zhonghua Wang; Dongsheng Tian; Mantong Mei
Journal:  Gene       Date:  2002-01-09       Impact factor: 3.688

4.  An asymptotic determination of minimum centromere size for the maize B chromosome.

Authors:  T L Phelps-Durr; J A Birchler
Journal:  Cytogenet Genome Res       Date:  2004       Impact factor: 1.636

5.  Regeneration of fertile transgenic indica (group 1) rice plants following microprojectile transformation of embryogenic suspension culture cells.

Authors:  S Zhang; L Chen; R Qu; P Marmey; R Beachy; C Fauquet
Journal:  Plant Cell Rep       Date:  1996-03       Impact factor: 4.570

6.  Stable transfer of intact high molecular weight DNA into plant chromosomes.

Authors:  C M Hamilton; A Frary; C Lewis; S D Tanksley
Journal:  Proc Natl Acad Sci U S A       Date:  1996-09-03       Impact factor: 11.205

7.  Misdivision analysis of centromere structure in maize.

Authors:  E Kaszás; J A Birchler
Journal:  EMBO J       Date:  1996-10-01       Impact factor: 11.598

8.  A binary-BAC system for plant transformation with high-molecular-weight DNA.

Authors:  C M Hamilton
Journal:  Gene       Date:  1997-10-24       Impact factor: 3.688

9.  Complementation of plant mutants with large genomic DNA fragments by a transformation-competent artificial chromosome vector accelerates positional cloning.

Authors:  Y G Liu; Y Shirano; H Fukaki; Y Yanai; M Tasaka; S Tabata; D Shibata
Journal:  Proc Natl Acad Sci U S A       Date:  1999-05-25       Impact factor: 11.205

10.  Rice (Oryza sativa) centromeric regions consist of complex DNA.

Authors:  F Dong; J T Miller; S A Jackson; G L Wang; P C Ronald; J Jiang
Journal:  Proc Natl Acad Sci U S A       Date:  1998-07-07       Impact factor: 11.205
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  15 in total

1.  Construction of BIBAC and BAC libraries from a variety of organisms for advanced genomics research.

Authors:  Hong-Bin Zhang; Chantel F Scheuring; Meiping Zhang; Yang Zhang; Cheng-Cang Wu; Jennifer J Dong; Yaning Li
Journal:  Nat Protoc       Date:  2012-02-16       Impact factor: 13.491

2.  Inactivation of a centromere during the formation of a translocation in maize.

Authors:  Zhi Gao; Shulan Fu; Qianhua Dong; Fangpu Han; James A Birchler
Journal:  Chromosome Res       Date:  2011-09-27       Impact factor: 5.239

3.  Engineered plant minichromosomes: a bottom-up success?

Authors:  Andreas Houben; R Kelly Dawe; Jiming Jiang; Ingo Schubert
Journal:  Plant Cell       Date:  2008-01-25       Impact factor: 11.277

4.  Engineered plant minichromosomes: a resurrection of B chromosomes?

Authors:  Andreas Houben; Ingo Schubert
Journal:  Plant Cell       Date:  2007-08-10       Impact factor: 11.277

Review 5.  A tale of two centromeres--diversity of structure but conservation of function in plants and animals.

Authors:  James A Birchler; Zhi Gao; Fangpu Han
Journal:  Funct Integr Genomics       Date:  2008-12-13       Impact factor: 3.410

6.  Bioactive beads-mediated transformation of rice with large DNA fragments containing Aegilops tauschii genes.

Authors:  Naoki Wada; Shin'ichiro Kajiyama; Yukio Akiyama; Shigeki Kawakami; Daisuke No; Susumu Uchiyama; Motoyasu Otani; Takiko Shimada; Naoko Nose; Go Suzuki; Yasuhiko Mukai; Kiichi Fukui
Journal:  Plant Cell Rep       Date:  2009-02-12       Impact factor: 4.570

Review 7.  Towards the development of better crops by genetic transformation using engineered plant chromosomes.

Authors:  Manoj K Dhar; Sanjana Kaul; Jasmeet Kour
Journal:  Plant Cell Rep       Date:  2011-01-20       Impact factor: 4.570

Review 8.  Engineered minichromosomes in plants.

Authors:  James A Birchler
Journal:  Chromosome Res       Date:  2015-02       Impact factor: 5.239

Review 9.  Engineering of plant chromosomes.

Authors:  Michael Florian Mette; Andreas Houben
Journal:  Chromosome Res       Date:  2015-02       Impact factor: 5.239

Review 10.  Plant centromeres: genetics, epigenetics and evolution.

Authors:  Ludmila Cristina Oliveira; Giovana Augusta Torres
Journal:  Mol Biol Rep       Date:  2018-08-16       Impact factor: 2.316
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