Aneuploidy and Genetic Variation in the <i>Arabidopsis thaliana</i> Triploid Response

Henry, Isabelle; Dilkes, Brian P.; Young, Kimball; Watson, Brian; Wu, Helen L.; Comai, Luca

doi:10.1534/genetics.104.037788

Cited by 146 publications

(196 citation statements)

References 38 publications

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“…Here we crossed the synthetic diploid Wa-1 as a pollen parent to natural tetraploid Wa-1 female to generate triploid Wa-1 plants containing Wa-1 cytoplasm. This triploid was subsequently crossed as a female to synthetic diploid Wa-1 male (Col-0 cytoplasm) to produce triploid, aneuploid and diploid progeny 33 , all with Wa-1 cytoplasm ( Supplementary Fig. 5 shows the crossing strategy to maintain Wa-1 cytoplasm in the ploidy series).…”

Section: Resultsmentioning

confidence: 99%

“…However, a tetraploid TILLING plant carrying the desired mutant allele must be converted to diploid for easy genetic analysis. In fact, the cenh3-1 allele used to create the HI strain was originally isolated from a tetraploid TILLING population that conventionally required two transitional generations via a triploid bridge to generate a diploid CENH3/ cenh3-1 heterozygote 22,33,34 . With a HI strategy, we hypothesized that a tetraploid TILLING population can be converted to diploid by a single cross.…”

Section: Resultsmentioning

confidence: 99%

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A haploid genetics toolbox for Arabidopsis thaliana

et al. 2014

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Genetic analysis in haploids provides unconventional yet powerful advantages not available in diploid organisms. In Arabidopsis thaliana, haploids can be generated through seeds by crossing a wild-type strain to a transgenic strain with altered centromeres. Here we report the development of an improved haploid inducer (HI) strain, SeedGFP-HI, that aids selection of haploid seeds prior to germination. We also show that haploids can be used as a tool to accelerate a variety of genetic analyses, specifically pyramiding multiple mutant combinations, forward mutagenesis screens, scaling down a tetraploid to lower ploidy levels and swapping of nuclear and cytoplasmic genomes. Furthermore, the A. thaliana HI can be used to produce haploids from a related species A. suecica and generate homozygous mutant plants from strong maternal gametophyte lethal alleles, which is not possible via conventional diploid genetics. Taken together, our results demonstrate the utility and power of haploid genetics in A. thaliana.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

A haploid genetics toolbox for Arabidopsis thaliana

et al. 2014

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“…In some instances, chromosome gains or losses are even part of their evolution. There are, however, several wellstudied examples in maize, rice, and Arabidopsis where aneuploid plants grow significantly more poorly than their wild-type counterparts (McClintock 1929;Singh et al 1996;Henry et al 2005). Particularly, in maize and rice, the degree of poor growth correlates with the size of the additional chromosome ( Figure 1D).…”

Section: The Studies Of Aneuploidy: a Long Traditionmentioning

confidence: 98%

Aneuploidy: Cells Losing Their Balance

2008

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A change in chromosome number that is not the exact multiple of the haploid karyotype is known as aneuploidy. This condition interferes with growth and development of an organism and is a common characteristic of solid tumors. Here, we review the history of studies on aneuploidy and summarize some of its major characteristics. We will then discuss the molecular basis for the defects caused by aneuploidy and end with speculations as to whether and how aneuploidy, despite its deleterious effects on organismal and cellular fitness, contributes to tumorigenesis.

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“…Tetraploid derivative of Arabidopsis thaliana ecotype Ler-0 (4x-Ler) was produced as previously described (Henry et al, 2005). The tetraploid Arabidopsis arenosa (Care-1) is a wild-collected accession corresponding to ABRC seed stock number CS3901.…”

Section: Plant Materialsmentioning

confidence: 99%

The BOY NAMED SUE Quantitative Trait Locus Confers Increased Meiotic Stability to an Adapted Natural Allopolyploid of Arabidopsis

et al. 2014

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Whole-genome duplication resulting from polyploidy is ubiquitous in the evolutionary history of plant species. Yet, polyploids must overcome the meiotic challenge of pairing, recombining, and segregating more than two sets of chromosomes. Using genomic sequencing of synthetic and natural allopolyploids of Arabidopsis thaliana and Arabidopsis arenosa, we determined that dosage variation and chromosomal translocations consistent with homoeologous pairing were more frequent in the synthetic allopolyploids. To test the role of structural chromosomal differentiation versus genetic regulation of meiotic pairing, we performed sequenced-based, high-density genetic mapping in F2 hybrids between synthetic and natural lines. This F2 population displayed frequent dosage variation and deleterious homoeologous recombination. The genetic map derived from this population provided no indication of structural evolution of the genome of the natural allopolyploid Arabidopsis suecica, compared with its predicted parents. The F2 population displayed variation in meiotic regularity and pollen viability that correlated with a single quantitative trait locus, which we named BOY NAMED SUE, and whose beneficial allele was contributed by A. suecica. This demonstrates that an additive, gain-of-function allele contributes to meiotic stability and fertility in a recently established allopolyploid and provides an Arabidopsis system to decipher evolutionary and molecular mechanisms of meiotic regularity in polyploids.

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Aneuploidy and Genetic Variation in the Arabidopsis thaliana Triploid Response

Cited by 146 publications

References 38 publications

A haploid genetics toolbox for Arabidopsis thaliana

A haploid genetics toolbox for Arabidopsis thaliana

Aneuploidy: Cells Losing Their Balance

The BOY NAMED SUE Quantitative Trait Locus Confers Increased Meiotic Stability to an Adapted Natural Allopolyploid of Arabidopsis

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