Preferential homologous chromosome pairing in a tetraploid intergeneric somatic hybrid (Citrus reticulata + Poncirus trifoliata)revealed by molecular marker inheritance

The creation of intergeneric somatic hybrids between Citrus and Poncirus is an efficient approach for citrus rootstock breeding, offering the possibility of combining beneficial traits from both genera into novel rootstock lineages. These somatic hybrids are also used as parents for further tetraploid sexual breeding. In order to optimize these latter breeding schemes, it is essential to develop knowledge on the mode of inheritance in the intergeneric tetraploid hybrids. We assessed the meiotic behavior of an intergeneric tetraploid somatic hybrid resulting from symmetric protoplast fusion of diploid Citrus reticulata and diploid Poncirus trifoliata. The analysis was based on the segregation patterns of 16 SSR markers and 9 newly developed centromeric/pericentromeric SNP markers, representing all nine linkage groups of the Citrus genetic map. We found strong but incomplete preferential pairing between homologues of the same ancestral genome. The proportion of gametes that can be explained by random meiotic chromosome associations (τ) varied significantly between chromosomes, from 0.09 ± 0.02 to 0.47 ± 0.09, respectively, in chromosome 2 and 1. This intermediate inheritance between strict disomy and tetrasomy, with global preferential disomic tendency, resulted in a high level of intergeneric heterozygosity of the diploid gametes. Although limited, intergeneric recombinations occurred, whose observed rates, ranging from 0.09 to 0.29, respectively, in chromosome 2 and 1, were significantly correlated with τ. Such inheritance is of particular interest for rootstock breeding because a large part of the multi-trait value selected at the teraploid parent level is transmitted to the progeny, while the potential for some intergeneric recombination offers opportunities for generating plants with novel allelic combinations that can be targeted by selection

壊疽性安魏那ニ就テ

SNP calls for chromosome 5 from bulked segregant analysis. F1s were generated from crosses between a self-incompatible and a self-compatible parent of Arabidopsis lyrata, sampled from the Great Lakes region of Eastern North America, which were then crossed amongst themselves to create F2s. Pools were created from: 1) 10 individuals that were phenotypically self-incompatible; and 2) 10 individuals that were phenotypically self-compatible. Three lanes of separate runs (two 150 bp and one 100 bp paired-end read run) were sequenced on an Illumina GAII instrument for each pool. The Illumina quality-filtered reads were mapped against the A. lyrata reference genome sequence MN47 (Hu et al. 2011) using GenomeMapper (Schneeberger et al. 2009), allowing for up to 10% mismatches/gaps relative to the read length. All alternative alleles relative to the reference base with a minimum frequency within each pool of 10% and a score of at least 25 were called by SHORE, as described (Ossowski et al. 2008). SNP calls (in genes only) were made using SHORE and compared for the two pools against the MN47 reference and for a reference genome constructed from two self-compatible individuals (AL4). These individuals were created by hybridisation between individuals sampled from the same population used for the self-compatible parent of the pools with the MN47 reference strain. The genomic sequence thus was determined by subtraction from the MN47 reference. The data file shows the SNP calls, % of reads with the variant and read coverage for that position. See readme file for complete details. References Hu TT, Pattyn P, Bakker EG, et al. (2011) The Arabidopsis lyrata genome sequence and the basis of rapid genome size change. Nature Genetics 43, 476-481. doi: 10.1038/ng.807 Ossowski S, Schneeberger K, Clark RM, et al. (2008) Sequencing of natural strains of Arabidopsis thaliana with short reads. Genome Research 18, 2024-2033. 10.1101/gr.080200.108 Schneeberger K, Hagmann J, Ossowski S, et al. (2009) Simultaneous alignment of short reads against multiple genomes. Genome Biology 10, 1-12. 10.1186/gb-2009-10-9-r9

Data from: Inbreeding depression in self-incompatible North American Arabidopsis lyrata: disentangling genomic and S-locus specific genetic load

Newly formed selfing lineages may express recessive genetic load and suffer inbreeding depression. This can have a genome-wide genetic basis, or be due to loci linked to genes under balancing selection. Understanding the genetic architecture of inbreeding depression is important in the context of the maintenance of self-incompatibility and understanding the evolutionary dynamics of S-alleles. We addressed this using North-American subspecies of Arabidopsis lyrata. This species is normally self-incompatible and outcrossing, but some populations have undergone a transition to selfing. The goals of this study were to: (1) quantify the strength of inbreeding depression in North-American populations of A. lyrata; and (2) disentangle the relative contribution of S-linked genetic load compared with overall inbreeding depression. We enforced selfing in self-incompatible plants with known S-locus genotype by treatment with CO2, and compared the performance of selfed vs outcrossed progeny. We found significant inbreeding depression for germination rate (δ=0.33), survival rate to 4 weeks (δ=0.45) and early growth (δ=0.07), but not for flowering rate. For two out of four S-alleles in our design, we detected significant S-linked load reflected by an under-representation of S-locus homozygotes in selfed progeny. The presence or absence of S-linked load could not be explained by the dominance level of S-alleles. Instead, the random nature of the mutation process may explain differences in the recessive deleterious load among lineages

Dryad_CSV_data4analysis_Alldata_2011_03_18

These are the data as they were analysed: molecular S-genotyping and microsatellite verification and growth measures (based on raw measurements

Dryad_CSV_rawdata_Alldata_2011_03_18

These are the size measurements and counts on the plants and the dates on which they were take

Evolution of genome size in Hawaiian endemic genus Schiedea (Caryophyllaceae)

Genome sizes may vary by orders of magnitude among relatively closely related species. Gene and genome duplications and movements of transposable elements (TEs) can quickly inflate genome sizes. Whole genome duplications (polyploidization) may be an important source of evolutionary innovation and many fast evolving island genera are known or assumed to be polyploids. Our main aim is to shed light on the question of how genome size evolved within a rapidly diversifying island lineage. We report the estimates of DNA content for 27 species of the Hawaiian endemic plant genus Schiedea and its widespread sister genus Honckenya (Caryophyllaceae: Alsinoideae). Unexpectedly, genomes of Schiedea species appeared to be relatively compact (1.41 to 3.74 pg/cell), compared to Honckenya (8.57 to 10.66 pg/cell). Interestingly, Schiedea species from younger islands tended to have larger genomes than species from older islands, which may be explained by activation of TE transpositions in small populations after colonization events that resulted in the formation of new species on younger islands. To test whether the Schiedea genome has undergone recent polyploidization events we measured divergence between 62 pairs of paralogous genes in S. globosa. The distribution of divergence values was unimodal with a mode of 7%, supporting a single polyploidization event. Dating this event using Schiedea/Honckenya divergence (2%) and Schiedea/Silene divergence (11%) we estimate that it might have occurred in the ancestor of the genera Schiedea and Honckenya, but after the split between the subfamilies Alsinoideae and Silenoideae

Sibling competition does not magnify inbreeding depression in North American Arabidopsis lyrata

About half of all angiosperms have some form of molecular self-incompatibility to promote outcrossing. If self-incompatibility breaks down, inbreeding depression (δ) is the main barrier to the evolution of self-fertilisation (selfing). If inbreeding depression is lower than 50% (δ < 0.5), the inherent transmission advantage of selfers should theoretically drive the evolution of selfing. However, this does not always happen in practice. For example, despite frequent breakdowns of self-incompatibility in North American Arabidopsis lyrata, selfing has only evolved in few populations. This is surprising given that previous inbreeding-depression estimates were well below the 0.5 threshold. Here, we test whether this could be due to underestimation of true inbreeding depression in competition-free environments. Specifically, we tested whether direct competition between crossed and selfed siblings magnified inbreeding-depression estimates in A. lyrata. We found that this was neither the case for belowground nor for aboveground biomass. For reproductive traits, there was hardly any significant inbreeding depression regardless of competition. Combined with previous findings that drought stress and inducing defence also did not magnify inbreeding depression, our results suggest that the relatively low estimates of inbreeding depression for biomass are indeed realistic estimates of the true inbreeding depression in North American A. lyrata.publishe

Differences in mating system and predicted parental conflict affect post-pollination reproductive isolation in a flowering plant

Mating system shifts from outcrossing to selfing are frequent in plant evolution. Relative to outcrossing, selfing is associated with reduced parental conflict over seed provisioning, which may result in postzygotic, asymmetric, reproductive isolation in crosses between populations of different mating systems. To test the hypothesis that post-pollination reproductive isolation between populations increases with increasing differences in mating system and predicted parental conflict, we performed a crossing experiment involving all combinations of three self-compatible populations (with low outcrossing rates), and three self-incompatible populations (with high outcrossing rates) of the arctic-alpine herb Arabis alpina, assessing fitness-related seed and plant traits of the progeny. Predicted levels of parental conflict ("genome strength") were quantified based on strength of self-incompatibility and estimates of outcrossing rates. Crosses between self-compatible and self-incompatible populations yielded very small seeds of low viability, resulting in strong reproductive isolation. In 14 of 15 reciprocal between-population crosses, seeds were heavier when the paternal plant had the stronger genome, and seed mass differences between cross directions increased with an increased difference in parental conflict. Overall, our results suggest that, when sufficiently large, differences in mating system and hence in expected parental conflict may result in strong post-pollination reproductive barriers contributing to speciation

Admixture between native and invasive populations may increase invasiveness of Mimulus guttatus

Self-fertilization and admixture of genotypes from different populations can have major fitness consequences in native species. However, few studies have addressed their potential roles in invasive species. Here, we used plants of Mimulus guttatus from seven native North American, three invasive Scottish and four invasive New Zealand populations to address this. We created seeds from self-fertilization, within-population outcrossing, between-population outcrossing within the same range, and outcrossing between the native and invasive ranges. A greenhouse experiment showed that native and invasive plants of M. guttatus suffered to similar degrees from inbreeding depression, in terms of asexual reproduction and biomass production. After outcrossing with plants from other populations, M. guttatus benefited from heterosis, in terms of asexual and sexual reproduction, and biomass production, particularly when plants from native and invasive populations were crossed. This suggests that, when novel genotypes of M. guttatus from the native North American range will be introduced to the invasive ranges, subsequent outcrossing with M. guttatus plants that are already there might further boost invasiveness of this species