The classification of the legume family proposed here addresses the long‐known non‐monophyly of the traditionally recognised subfamily Caesalpinioideae, by recognising six robustly supported monophyletic subfamilies. This new classification uses as its framework the most comprehensive phylogenetic analyses of legumes to date, based on plastid matK gene sequences, and including near‐complete sampling of genera (698 of the currently recognised 765 genera) and ca. 20% (3696) of known species. The matK gene region has been the most widely sequenced across the legumes, and in most legume lineages, this gene region is sufficiently variable to yield well‐supported clades. This analysis resolves the same major clades as in other phylogenies of whole plastid and nuclear gene sets (with much sparser taxon sampling). Our analysis improves upon previous studies that have used large phylogenies of the Leguminosae for addressing evolutionary questions, because it maximises generic sampling and provides a phylogenetic tree that is based on a fully curated set of sequences that are vouchered and taxonomically validated. The phylogenetic trees obtained and the underlying data are available to browse and download, facilitating subsequent analyses that require evolutionary trees. Here we propose a new community‐endorsed classification of the family that reflects the phylogenetic structure that is consistently resolved and recognises six subfamilies in Leguminosae: a recircumscribed Caesalpinioideae DC., Cercidoideae Legume Phylogeny Working Group (stat. nov.), Detarioideae Burmeist., Dialioideae Legume Phylogeny Working Group (stat. nov.), Duparquetioideae Legume Phylogeny Working Group (stat. nov.), and Papilionoideae DC. The traditionally recognised subfamily Mimosoideae is a distinct clade nested within the recircumscribed Caesalpinioideae and is referred to informally as the mimosoid clade pending a forthcoming formal tribal and/or clade‐based classification of the new Caesalpinioideae. We provide a key for subfamily identification, descriptions with diagnostic charactertistics for the subfamilies, figures illustrating their floral and fruit diversity, and lists of genera by subfamily. This new classification of Leguminosae represents a consensus view of the international legume systematics community; it invokes both compromise and practicality of use.
Phytoplankton account for nearly half of global primary productivity and strongly affect the global carbon cycle, yet little is known about the forces that drive the evolution of these keystone microscopic organisms. Here we combine morphometric data from the fossil record of the ubiquitous coccolithophore genus Gephyrocapsa with genomic analyses of extant species to assess the genetic processes underlying Pleistocene palaeontological patterns. We demonstrate that all modern diversity in Gephyrocapsa (including Emiliania huxleyi) originated in a rapid species radiation during the last 0.6 Ma, coincident with the latest of the three pulses of Gephyrocapsa diversification and extinction documented in the fossil record. Our evolutionary genetic analyses indicate that new species in this genus have formed in sympatry or parapatry, with occasional hybridisation between species. This sheds light on the mode of speciation during evolutionary radiation of marine phytoplankton and provides a model of how new plankton species form.
White campion (Silene latifolia) is one of the few examples of plants with separate sexes and with X and Y sex chromosomes. The presence or absence of the Y chromosome determines which type of reproductive organs--male or female--will develop. Recently, we characterized the first active gene located on a plant Y chromosome, SlY1, and its X-linked homolog, SlX1. These genes encode WD-repeat proteins likely to be involved in cell proliferation. Here, we report the characterization of a novel Y-linked gene, SlY4, which also has a homolog on the X chromosome, SlX4. Both SlY4 and SlX4 potentially encode fructose-2,6-bisphosphatases. A comparative molecular analysis of the two sex-linked loci (SlY1/SlX1 and SlY4/SlX4) suggests selective constraint on both X- and Y-linked genes and thus that both X- and Y-linked copies are functional. Divergence between SlY4 and SlX4 is much greater than that between the SlY1 and SlX1 genes. These results suggest that, as for human XY-linked genes, the sex-linked plant loci ceased recombining at different times and reveal distinct events in the evolutionary history of the sex chromosomes.
Theory predicts that selection should be less effective in the nonrecombining genes of Y-chromosomes, relative to the situation for genes on the other chromosomes, and this should lead to the accumulation of deleterious nonsynonymous substitutions. In addition, synonymous substitution rates may differ between X- and Y-linked genes because of the male-driven evolution effect and also because of actual differences in per-replication mutation rates between the sex chromosomes. Here, we report the first study of synonymous and nonsynonymous substitution rates on plant sex chromosomes. We sequenced two pairs of sex-linked genes, SlX1-SlY1 and SlX4-SlY4, from dioecious Silene latifolia and S. dioica, and their non-sex-linked homologues from nondioecious S. vulgaris and Lychnis flos-jovis, respectively. The rate of nonsynonymous substitutions in the SlY4 gene is significantly higher than that in the SlX4 gene. Silent substitution rates are also significantly higher in both Y-linked genes, compared with their X-linked homologues. The higher nonsynonymous substitution rate in the SlY4 gene is therefore likely to be caused by a mutation rate difference between the sex chromosomes. The difference in silent substitution rates between the SlX4 and SlY4 genes is too great to be explained solely by a higher per-generation mutation rate in males than females. It is thus probably caused by a difference in per-replication mutation rates between the sex chromosomes. This suggests that the local mutation rate can change in a relatively short evolutionary time.
The relatively recent origin of sex chromosomes in the plant genus Silene provides an opportunity to study the early stages of sex chromosome evolution and, potentially, to test between the different population genetic processes likely to operate in nonrecombining chromosomes such as Y chromosomes. We previously reported much lower nucleotide polymorphism in a Y-linked gene (SlY1) of the plant Silene latifolia than in the homologous X-linked gene (SlX1). Here, we report a more extensive study of nucleotide diversity in these sex-linked genes, including a larger S. latifolia sample and a sample from the closely related species Silene dioica, and we also study the diversity of an autosomal gene, CCLS37.1. We demonstrate that nucleotide diversity in the Y-linked genes of both S. latifolia and S. dioica is very low compared with that of the X-linked gene. However, the autosomal gene also has low DNA polymorphism, which may be due to a selective sweep. We use a single individual of the related hermaphrodite species Silene conica, as an outgroup to show that the low SlY1 diversity is not due to a lower mutation rate than that for the X-linked gene. We also investigate several other possibilities for the low SlY1 diversity, including differential gene flow between the two species for Y-linked, X-linked, and autosomal genes. The frequency spectrum of nucleotide polymorphism on the Y chromosome deviates significantly from that expected under a selective-sweep model. However, we detect population subdivision in both S. latifolia and S. dioica, so it is not simple to test for selective sweeps. We also discuss the possibility that Y-linked diversity is reduced due to highly variable male reproductive success, and we conclude that this explanation is unlikely.
The evolution of sex chromosomes involves the suppression of recombination around a sexdetermining locus, and the subsequent divergence in DNA sequence between the two homologous sex chromosomes. Dioecious plants offer the opportunity to study independent early stages of this process, because of multiple, recent transitions between hermaphroditism and dioecy. Here, we present data from de novo genome assembly and annotation, genetic mapping and transcriptome analysis of the diploid dioecious herb Mercurialis annua, revealing several of the typical hallmarks of early sex-chromosome evolution. Until now only a single sex-linked PCR marker has been published. Our analysis identified a single linkage group, LG10, as the likely sex chromosome, with a region containing 69 sex-linked transcripts with a clearly lower male than female recombination, high X/Y divergence and multiple incidences of premature stop codons on the Y allele. We found many genes with sexbiased expression. Female-biased genes were randomly distributed across the genome, but male-biased genes were slightly enriched on the Y chromosome. Interestingly, Y-linked genes had reduced expression compared with X-linked genes, a pattern consistent with Y chromosome degeneration. M. annua has been a powerful model for the study of rapid sexualsystem transitions in plants; our results here establish it as a model for the study of the early stages of sex-chromosome evolution.
16Phenotypic plasticity can maintain population fitness in novel or changing environments if it allows the 17 phenotype to track the new trait optimum. Understanding how adaptation to contrasting environments 18 determines plastic responses can identify how plasticity evolves, and its potential to be adaptive in response 19 to environmental change. We sampled 79 genotypes from populations of two closely related but ecologically 20 divergent ragwort species (Senecio, Asteraceae), and transplanted multiple clones of each genotype into four 21 field sites along an elevational gradient representing each species' native range, the edge of their range, and 22 conditions outside their native range. At each transplant site, we quantified differences in survival, growth, 23 leaf morphology, chlorophyll fluorescence and gene expression for both species. Overall, the two species 24 differed in their sensitivity to the elevational gradient. As evidence of plasticity, leaf morphology changed 25 across the elevational gradient, with changes occurring in opposite directions for the two species. Differential 26 gene expression across the four field sites also revealed that the genetic pathways underlying plastic 27 responses were highly distinct in the two species. Despite the two species having diverged recently, 28 adaptation to contrasting habitats has resulted in the evolution of distinct sensitivities to environmental 29 variation, underlain by distinct forms of plasticity. 30 genotype-by-environment interactions, phenotypic plasticity, physiological plasticity, specialisation 32 33 62when the environment is predictable, leading to adaptive plasticity within the environmental limits 63 experienced during adaptation (Bradshaw 1965; Schlichting 1986; Baythavong and Stanton 2010). Whether 64 such plasticity will continue to be adaptive when exposed to novel conditions, such as those imposed by 65 4 climate change, remains an empirical issue (Ghalambor et al. 2007). Strong stabilising selection created by 66 predictable environments is expected to lead to specific plastic responses and reduce genetic variation for 67 plasticity (Oostra et al. 2018). By contrast, populations adapted to a wider range of habitats that are more 68 spatially and temporally variable are predicted to maintain genetic variation in plastic responses, increasing 69 the potential for selection on plasticity (Chevin et al. 2010). Detecting and characterising patterns of G×E for 70 a range of naturally occurring genotypes can help us understand whether evolutionary responses can occur 71 even if plasticity is constrained in certain directions (Via 1993; Chevin and Hoffmann 2017). 72 The genetic architecture underlying variation in plasticity is largely unknown (Fusco and Minelli 2010). 73 Plastic responses at the gene expression level are most likely controlled either by epiallelic control of the 74 genes themselves or allelic variation in the regulators of the genes (Rockman and Kruglyak 2006). If allelic 75 (sequence changes) or epiallelic (e.g. DNA me...
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