Genomic plasticity and the diversity of polyploid plants

Altered circadian rhythms regulate growth vigour in hybrids and allopolyploids

Segregating hybrids and stable allopolyploids display morphological vigor1,2,3, and Arabidopsis allotetraploids are larger than the parents Arabidopsis thaliana and A. arenosa1,4. The mechanisms are unknown. Circadian clocks mediate metabolic pathways and increase fitness in animals and plants5,6,7,8. Here we report that epigenetic modifications of the circadian clock genes CIRCADIAN CLOCK ASSOCIATED 1 (CCA1) and LATE ELONGATED HYPOCOTYL (LHY)9,10 and their reciprocal regulators TIMING OF CAB EXPRESSION 1 (TOC1) and GIGANTEA (GI)10,11,12 mediate expression changes in downstream genes and pathways. During the day, epigenetic repression of CCA1 and LHY induced expression of TOC1, GI and downstream genes that contain CCA1 binding site (CBS)13 in chlorophyll and starch metabolic pathways in allotetraploids and F₁ hybrids, which produced more chlorophyll and starch than the parents in the same environment. Mutations in cca1 and cca1 lhy and daily repression of cca1 in TOC1:cca1-RNAi transgenic plants increased expression of downstream genes and chlorophyll and starch content, whereas constitutively expressing CCA1 or ectopically expressing TOC1:CCA1 had the opposite effects. The causal effects of CCA1 on output traits suggest that hybrids and allopolyploids gain advantages from the control of circadian-mediated physiological and metabolic pathways, leading to growth vigor and increased biomass.

Rapid chromosome evolution in recently formed polyploids in Tragopogon (Asteraceae)

Background

Polyploidy, frequently termed “whole genome duplication”, is a major force in the evolution of many eukaryotes. Indeed, most angiosperm species have undergone at least one round of polyploidy in their evolutionary history. Despite enormous progress in our understanding of many aspects of polyploidy, we essentially have no information about the role of chromosome divergence in the establishment of young polyploid populations. Here we investigate synthetic lines and natural populations of two recently and recurrently formed allotetraploids Tragopogon mirus and T. miscellus (formed within the past 80 years) to assess the role of aberrant meiosis in generating chromosomal/genomic diversity. That diversity is likely important in the formation, establishment and survival of polyploid populations and species.

Methodology/Principal Findings

Applications of fluorescence in situ hybridisation (FISH) to natural populations of T. mirus and T. miscellus suggest that chromosomal rearrangements and other chromosomal changes are common in both allotetraploids. We detected extensive chromosomal polymorphism between individuals and populations, including (i) plants monosomic and trisomic for particular chromosomes (perhaps indicating compensatory trisomy), (ii) intergenomic translocations and (iii) variable sizes and expression patterns of individual ribosomal DNA (rDNA) loci. We even observed karyotypic variation among sibling plants. Significantly, translocations, chromosome loss, and meiotic irregularities, including quadrivalent formation, were observed in synthetic (S₀ and S₁ generations) polyploid lines. Our results not only provide a mechanism for chromosomal variation in natural populations, but also indicate that chromosomal changes occur rapidly following polyploidisation.

Conclusions/Significance

These data shed new light on previous analyses of genome and transcriptome structures in de novo and establishing polyploid species. Crucially our results highlight the necessity of studying karyotypes in young (<150 years old) polyploid species and synthetic polyploids that resemble natural species. The data also provide insight into the mechanisms that perturb inheritance patterns of genetic markers in synthetic polyploids and populations of young natural polyploid species.