Long-term genome diploidization in allopolyploid Nicotiana section Repandae (Solanaceae)

Here, we analyze long-term evolution in Nicotiana allopolyploid section Repandae (the closest living diploids are N. sylvestris, the maternal parent, and N. obtusifolia, the paternal parent). We compare data with other more recently formed Nicotiana allopolyploids. We investigated 35S and 5S nuclear ribosomal DNA (rDNA) chromosomal location and unit divergence. A molecular clock was applied to the Nicotiana phylogenetic tree to determine allopolyploid ages. N. tabacum and species of Repandae were c. 0.2 and 4.5 Myr old, respectively. In all Repandae species, the numbers of both 35S and 5S rDNA loci were less than the sum of those of the diploid progenitors. Trees based on 5S rDNA spacer sequences indicated units of only the paternal parent. In recent Nicotiana allopolyploids, the numbers of rDNA loci equal the sum of those of their progenitors. In the Repandae genomes, diploidization is associated with locus loss. Sequence analysis indicates that 35S and 5S units most closely resemble maternal and paternal progenitors, respectively. In Nicotiana, 4.5 Myr of allopolyploid evolution renders genomic in situ hybridization (GISH) unsuitable for the complete resolution of parental genomes.     

The promiscuous and the chaste: frequent allopolyploid speciation and its genomic consequences in American daisies (Melampodium sect. Melampodium; Asteraceae)

Polyploidy, an important factor in eukaryotic evolution, is especially abundant in angiosperms, where it often acts in concert with hybridization to produce allopolyploids. The application of molecular phylogenetic techniques has identified the origins of numerous allopolyploids, but little is known on genomic and chromosomal consequences of allopolyploidization, despite their important role in conferring divergence of allopolyploids from their parental species. Here, using several plastid and nuclear sequence markers, we clarify the origin of tetra- and hexaploids in a group of American daisies, allowing characterization of genome dynamics in polyploids compared to their diploid ancestors. All polyploid species are allopolyploids. Among the four diploid gene pools, the propensity for allopolyploidization is unevenly distributed phylogenetically with a few species apparently more prone to participate, but the underlying causes remain unclear. Polyploid genomes are characterized by differential loss of ribosomal DNA loci (5S and 35S rDNA), known hotspots of chromosomal evolution, but show genome size additivity, suggesting limited changes beyond those affecting rDNA loci or the presence of processes counterbalancing genome reduction. Patterns of rDNA sequence conversion and provenance of the lost loci are highly idiosyncratic and differ even between allopolyploids of identical parentage, indicating that allopolyploids deriving from the same lower-ploid parental species can follow different evolutionary trajectories.     

Journey through the past: 150 million years of plant genome evolution

The genome sequence of the plant model organism Arabidopsis thaliana was presented in December of the year 2000. Since then, the 125 Mb sequence has revealed many of its evolutionary secrets. Through comparative analyses with other plant genomes, we know that the genome of A. thaliana, or better that of its ancestors, has undergone at least three whole genome duplications during the last 120 or so million years. The first duplication seems to have occurred at the dawn of dicot evolution, while the later duplications probably occurred <70 million years ago (Ma). One of those younger genome-wide duplications might be linked to the K-T extinction. Following these duplication events, the ancestral A. thaliana genome was hugely rearranged and gene copies have been massively lost. During the last 10 million years of its evolution, almost half of its genome was lost due to hundreds of thousands of small deletions. Here, we reconstruct plant genome evolution from the early angiosperm ancestor to the current A. thaliana genome, covering about 150 million years of evolution characterized by gene and genome duplications, genome rearrangements and genome reduction.     

Diploidization and genome size change in allopolyploids is associated with differential dynamics of low‐ and high‐copy sequences

Recent advances have highlighted the ubiquity of whole‐genome duplication (polyploidy) in angiosperms, although subsequent genome size change and diploidization (returning to a diploid‐like condition) are poorly understood. An excellent system to assess these processes is provided by Nicotiana section Repandae, which arose via allopolyploidy (approximately 5 million years ago) involving relatives of Nicotiana sylvestris and Nicotiana obtusifolia. Subsequent speciation in Repandae has resulted in allotetraploids with divergent genome sizes, including Nicotiana repanda and Nicotiana nudicaulis studied here, which have an estimated 23.6% genome expansion and 19.2% genome contraction from the early polyploid, respectively. Graph‐based clustering of next‐generation sequence data enabled assessment of the global genome composition of these allotetraploids and their diploid progenitors. Unexpectedly, in both allotetraploids, over 85% of sequence clusters (repetitive DNA families) had a lower abundance than predicted from their diploid relatives; a trend seen particularly in low‐copy repeats. The loss of high‐copy sequences predominantly accounts for the genome downsizing in N. nudicaulis. In contrast, N. repanda shows expansion of clusters already inherited in high copy number (mostly chromovirus‐like Ty3/Gypsy retroelements and some low‐complexity sequences), leading to much of the genome upsizing predicted. We suggest that the differential dynamics of low‐ and high‐copy sequences reveal two genomic processes that occur subsequent to allopolyploidy. The loss of low‐copy sequences, common to both allopolyploids, may reflect genome diploidization, a process that also involves loss of duplicate copies of genes and upstream regulators. In contrast, genome size divergence between allopolyploids is manifested through differential accumulation and/or deletion of high‐copy‐number sequences.     

A genetic appraisal of a new synthetic Nicotiana tabacum (Solanaceae) and the Kostoff synthetic tobacco

Polyploids have significantly influenced angiosperm evolution. Understanding the genetic consequences of polyploidy is advanced by studies on synthetic allopolyploids that mimic natural species. In Nicotiana, Burk (1973) and Kostoff (1938) generated synthetic tobacco (N. tabacum) using the parents ♀N. sylvestris × ♂N. tomentosiformis. We previously reported rapid genetic changes in the Burk material. Kostoff's material has 24 chromosomes of N. sylvestris origin (S-genome), 24 of N. tomentosiformis origin (T-genome), and a large intergenomic translocation, but not an additive distribution of ribosomal DNA (rDNA) families as expected from the parental contribution. Our new synthetic tobacco lines TR1 and TR2 are chromosomally balanced with no intergenomic translocations and are either sterile or have highly reduced fertility, supporting the nuclear cytoplasmic hypothesis that allopolyploid fertility is enhanced by intergenomic translocations. Two plants of TR1 (TR1-A, TR1-B) have the expected number, structure, and chromosomal distribution of rDNA families, in contrast to Burk's and Kostoff's synthetic tobaccos and to synthetic polyploids of Arabidopsis. Perhaps allopolyploids must pass through meiosis before genetic changes involving rDNA become apparent, or the genetic changes may occur stochastically in different synthetic allopolyploids. The lack of fertility in the first generation of our synthetic tobacco lines may have uses in biopharmacy.     

Polyploidy and angiosperm diversification

Polyploidy has long been recognized as a major force in angiosperm evolution. Recent genomic investigations not only indicate that polyploidy is ubiquitous among angiosperms, but also suggest several ancient genome-doubling events. These include ancient whole genome duplication (WGD) events in basal angiosperm lineages, as well as a proposed paleohexaploid event that may have occurred close to the eudicot divergence. However, there is currently no evidence for WGD in Amborella, the putative sister species to other extant angiosperms. The question is no longer "What proportion of angiosperms are polyploid?", but "How many episodes of polyploidy characterize any given lineage?" New algorithms provide promise that ancestral genomes can be reconstructed for deep divergences (e.g., it may be possible to reconstruct the ancestral eudicot or even the ancestral angiosperm genome). Comparisons of diversification rates suggest that genome doubling may have led to a dramatic increase in species richness in several angiosperm lineages, including Poaceae, Solanaceae, Fabaceae, and Brassicaceae. However, additional genomic studies are needed to pinpoint the exact phylogenetic placement of the ancient polyploidy events within these lineages and to determine when novel genes resulting from polyploidy have enabled adaptive radiations.     

Next-generation sequencing and genome evolution in allopolyploids

?Premise of the study: Hybridization and polyploidization (allopolyploidy) are ubiquitous in the evolution of plants, but tracing the origins and subsequent evolution of the constituent genomes of allopolyploids has been challenging. Genome doubling greatly complicates genetic analyses, and this has long hindered investigation in that most allopolyploid species are "nonmodel" organisms. However, recent advances in sequencing and genomics technologies now provide unprecedented opportunities to analyze numerous genetic markers in multiple individuals in any organism. ?Methods: Here we review the application of next-generation sequencing technologies to the study of three aspects of allopolyploid genome evolution: duplicated gene loss and expression in two recently formed Tragopogon allopolyploids, intergenomic interactions and chromosomal evolution in Tragopogon miscellus, and repetitive DNA evolution in Nicotiana allopolyploids. ?Key results: For the first time, we can explore on a genomic scale the evolutionary processes that are ongoing in natural allopolyploids and not be restricted to well-studied crops and genetic models. ?Conclusions: These approaches can be easily and inexpensively applied to many other plant species-making any evolutionarily provocative system a new "model" system.     

Molecular cytogenetics and tandem repeat sequence evolution in the allopolyploid Nicotiana rustica compared with diploid progenitors N. paniculata and N. undulata

Nicotiana rustica (2n = 4x = 48) is a natural allotetraploid composed of P and U genomes which are closely related to genomes of diploid species N. paniculata and N. undulata. Genomic in situ hybridization (GISH) also confirms that the diploid parents, or close relatives, are the ancestors of N. rustica. In order to study genetic interactions between ancestral genomes in the allotetraploid, we isolated three families of repetitive sequences, two from N. paniculata (NPAMBE and NPAMBO) and one from N. undulata (NUNSSP). Southern blot hybridization revealed that the sequences are digested with a range of restriction enzymes into regular ladder patterns indicating a tandem arrangement of high copy repeats possessing monomeric units of about 180 bp. The three-tandem sequences belong to a larger Nicotiana tandem repeat family called here the HRS-60 family. Members of this family are found in all Nicotiana species studied. Fluorescence in situ hybridization (FISH) analysis localized the satellite repeats to subtelomeric regions of most chromosomes of N. paniculata and N. undulata. The pattern of sequence distribution on the P- and U-genomes of N. rustica was similar to the putative parents N. paniculata and N. undulata respectively. However, NPAMBO repeats appear to be reduced and rearranged in N. rustica that may suggest evolution within the P genome. GISH and FISH with the tandem repeat probes failed to reveal intergenomic translocations as might be predicted from the nucleocytoplasmic interaction hypothesis.     

Untangling complex histories of genome mergings in high polyploids

Polyploidy, the duplication of entire genomes, plays a major role in plant evolution. In allopolyploids, genome duplication is associated with hybridization between two or more divergent genomes. Successive hybridization and polyploidization events can build up species complexes of allopolyploids with complicated network-like histories, and the evolutionary history of many plant groups cannot be adequately represented by phylogenetic trees because of such reticulate events. The history of complex genome mergings within a high-polyploid species complex in the genus Cerastium (Caryophyllaceae) is here untangled by the use of a network algorithm and noncoding sequences of a low-copy number gene. The resulting network illustrates how hybridization and polyploidization have acted as key evolutionary processes in creating a plant group where high-level allopolyploids clearly outnumber extant parental genomes.     

Allopolyploidization-accommodated genomic sequence changes in triticale

Background: Allopolyploidization is one of the major evolutionary modesof plant speciation. Recent interest in studying allopolyploidshas provided significant novel insights into the mechanismsof allopolyploid formation. Compelling evidence indicates thatgenetic and/or epigenetic changes have played significant rolesin shaping allopolyploids, but rates and modes of the changescan be very different among various species. Triticale (x Triticosecale)is an artificial species that has been used to study the evolutionarycourse of complex allopolyploids due to its recent origin andavailability of a highly diversified germplasm pool. Scope: This review summarizes recent genomics studies implemented inhexaploid and octoploid triticales and discusses the mechanismsof the changes and compares the major differences between genomicchanges in triticale and other allopolyploid species. Conclusions: Molecular studies have indicated extensive non-additive sequencechanges or modifications in triticale, and the degree of variationappears to be higher than in other allopolyploid species. Thedata indicate that at least some sequence changes are non-random,and appear to be a function of genome relations, ploidy levelsand sequence types. Specifically, the rye parental genome demonstrateda higher level of changes than the wheat genome. The frequencyof lost parental bands was much higher than the frequency ofgained novel bands, suggesting that sequence modification and/orelimination might be a major force causing genome variationin triticale. It was also shown that 68 % of the total changesoccurred immediately following wide hybridization, but beforechromosome doubling. Genome evolution following chromosome doublingoccurred more slowly at a very low rate and the changes weremainly observed in the first five or so generations. The datasuggest that cytoplasm and relationships between parental genomesare key factors in determining the direction, amount, timingand rate of genomic sequence variation that occurred duringinter-generic allopolyploidization in this system.     

The ups and downs of genome size evolution in polyploid species of Nicotiana (Solanaceae)

BACKGROUND: In studies looking at individual polyploid species, the most common patterns of genomic change are that either genome size in the polyploid is additive (i.e. the sum of parental genome donors) or there is evidence of genome downsizing. Reports showing an increase in genome size are rare. In a large-scale analysis of 3008 species, genome downsizing was shown to be a widespread biological response to polyploidy. Polyploidy in the genus Nicotiana (Solanaceae) is common with approx. 40 % of the approx. 75 species being allotetraploid. Recent advances in understanding phylogenetic relationships of Nicotiana species and dating polyploid formation enable a temporal dimension to be added to the analysis of genome size evolution in these polyploids. METHODS: Genome sizes were measured in 18 species of Nicotiana (nine diploids and nine polyploids) ranging in age from <200,000 years to approx. 4.5 Myr old, to determine the direction and extent of genome size change following polyploidy. These data were combined with data from genomic in situ hybridization and increasing amounts of information on sequence composition in Nicotiana to provide insights into the molecular basis of genome size changes. KEY RESULTS AND CONCLUSIONS: By comparing the expected genome size of the polyploid (based on summing the genome size of species identified as either a parent or most closely related to the diploid progenitors) with the observed genome size, four polyploids showed genome downsizing and five showed increases. There was no discernable pattern in the direction of genome size change with age of polyploids, although with increasing age the amount of genome size change increased. In older polyploids (approx. 4.5 million years old) the increase in genome size was associated with loss of detectable genomic in situ hybridization signal, whereas some hybridization signal was still detected in species exhibiting genome downsizing. The possible significance of these results is discussed.     

Size matters in Triticeae polyploids: larger genomes have higher remodeling

Polyploidization is one of the major driving forces in plant evolution and is extremely relevant to speciation and diversity creation. Polyploidization leads to a myriad of genetic and epigenetic alterations that ultimately generate plants and species with increased genome plasticity. Polyploids are the result of the fusion of two or more genomes into the same nucleus and can be classified as allopolyploids (different genomes) or autopolyploids (same genome). Triticeae synthetic allopolyploid species are excellent models to study polyploids evolution, particularly the wheat-rye hybrid triticale, which includes various ploidy levels and genome combinations. In this review, we reanalyze data concerning genomic analysis of octoploid and hexaploid triticale and different synthetic wheat hybrids, in comparison with other polyploid species. This analysis reveals high levels of genomic restructuring events in triticale and wheat hybrids, namely major parental band disappearance and the appearance of novel bands. Furthermore, the data shows that restructuring depends on parental genomes, ploidy level, and sequence type (repetitive, low copy, and (or) coding); is markedly different after wide hybridization or genome doubling; and affects preferentially the larger parental genome. The shared role of genetic and epigenetic modifications in parental genome size homogenization, diploidization establishment, and stabilization of polyploid species is discussed.     

Rapid genomic changes in interspecific and intergeneric hybrids and allopolyploids of Triticeae.

Allopolyploidy is preponderant in plants, which often leads to speciation. Some recent studies indicate that the process of wide hybridization and (or) genome doubling may induce rapid and extensive genetic and epigenetic changes in some plant species and genomic stasis in others. To further study this phenomenon, we analyzed three sets of synthetic allopolyploids in the Triticeae by restriction fragment length polymorphism (RFLP) using a set of expressed sequence tags (ESTs) and retrotransposons as probes. It was found that 40-64.7% of the ESTs detected genomic changes in the three sets of allopolyploids. Changes included disappearance of parental hybridization fragment(s), simultaneous appearance of novel fragment(s) and loss of parental fragment(s), and appearance of novel fragment(s). Some of the changes occurred as early as in the F1 hybrid, whereas others occurred only after allopolyploid formation. Probing with retrotransposons revealed numerous examples of disappearance of sequences. No gross chromosome structural changes or physical elimination of sequences were found. It is suggested that DNA methylation and localized recombination at the DNA level were probably the main causes for the genomic changes. Possible implications of the genomic changes for allopolyploid genome evolution are discussed.     

Allopolyploidy-Induced Rapid Genome Evolution in the Wheat (Aegilops–Triticum) Group

To better understand genetic events that accompany allopolyploid formation, we studied the rate and time of elimination of eight DNA sequences in F1 hybrids and newly formed allopolyploids of Aegilops and Triticum. In total, 35 interspecific and intergeneric F1 hybrids and 22 derived allopolyploids were analyzed and compared with their direct parental plants. The studied sequences exist in all the diploid species of the Triticeae but occur in only one genome, either in one homologous pair (chromosome-specific sequences [CSSs]) or in several pairs of the same genome (genome-specific sequences [GSSs]), in the polyploid wheats. It was found that rapid elimination of CSSs and GSSs is a general phenomenon in newly synthesized allopolyploids. Elimination of GSSs was already initiated in F1 plants and was completed in the second or third allopolyploid generation, whereas elimination of CSSs started in the first allopolyploid generation and was completed in the second or third generation. Sequence elimination started earlier in allopolyploids whose genome constitution was analogous to natural polyploids compared with allopolyploids that do not occur in nature. Elimination is a nonrandom and reproducible event whose direction was determined by the genomic combination of the hybrid or the allopolyploid. It was not affected by the genotype of the parental plants, by their cytoplasm, or by the ploidy level, and it did not result from intergenomic recombination. Allopolyploidy-induced sequence elimination occurred in a sizable fraction of the genome and in sequences that were apparently noncoding. This finding suggests a role in augmenting the differentiation of homoeologous chromosomes at the polyploid level, thereby providing the physical basis for the diploid-like meiotic behavior of newly formed allopolyploids. In our view, this rapid genome adjustment may have contributed to the successful establishment of newly formed allopolyploids as new species.     

Allopolyploidy-induced rapid genome evolution in the wheat (Aegilops-Triticum) group

To better understand genetic events that accompany allopolyploid formation, we studied the rate and time of elimination of eight DNA sequences in F1 hybrids and newly formed allopolyploids of Aegilops and TRITICUM: In total, 35 interspecific and intergeneric F1 hybrids and 22 derived allopolyploids were analyzed and compared with their direct parental plants. The studied sequences exist in all the diploid species of the Triticeae but occur in only one genome, either in one homologous pair (chromosome-specific sequences [CSSs]) or in several pairs of the same genome (genome-specific sequences [GSSs]), in the polyploid wheats. It was found that rapid elimination of CSSs and GSSs is a general phenomenon in newly synthesized allopolyploids. Elimination of GSSs was already initiated in F1 plants and was completed in the second or third allopolyploid generation, whereas elimination of CSSs started in the first allopolyploid generation and was completed in the second or third generation. Sequence elimination started earlier in allopolyploids whose genome constitution was analogous to natural polyploids compared with allopolyploids that do not occur in nature. Elimination is a nonrandom and reproducible event whose direction was determined by the genomic combination of the hybrid or the allopolyploid. It was not affected by the genotype of the parental plants, by their cytoplasm, or by the ploidy level, and it did not result from intergenomic recombination. Allopolyploidy-induced sequence elimination occurred in a sizable fraction of the genome and in sequences that were apparently noncoding. This finding suggests a role in augmenting the differentiation of homoeologous chromosomes at the polyploid level, thereby providing the physical basis for the diploid-like meiotic behavior of newly formed allopolyploids. In our view, this rapid genome adjustment may have contributed to the successful establishment of newly formed allopolyploids as new species.     

Evolution of rDNA in Nicotiana allopolyploids: a potential link between rDNA homogenization and epigenetics

Background: The evolution and biology of rDNA have interested biologistsfor many years, in part, because of two intriguing processes:(1) nucleolar dominance and (2) sequence homogenization. Wereview patterns of evolution in rDNA in the angiosperm genusNicotiana to determine consequences of allopolyploidy on theseprocesses. Scope: Allopolyploid species of Nicotiana are ideal for studying rDNAevolution because phylogenetic reconstruction of DNA sequenceshas revealed patterns of species divergence and their parents.From these studies we also know that polyploids formed overwidely different timeframes (thousands to millions of years),enabling comparative and temporal studies of rDNA structure,activity and chromosomal distribution. In addition studies onsynthetic polyploids enable the consequences of de novo polyploidyon rDNA activity to be determined. Conclusions: We propose that rDNA epigenetic expression patterns establishedeven in F₁ hybrids have a material influence on the likely patternsof divergence of rDNA. It is the active rDNA units that arevulnerable to homogenization, which probably acts to reducemutational load across the active array. Those rDNA units thatare epigenetically silenced may be less vulnerable to sequencehomogenization. Selection cannot act on these silenced genes,and they are likely to accumulate mutations and eventually beeliminated from the genome. It is likely that whole silencedarrays will be deleted in polyploids of 1 million years of ageand older.     

Concerted evolution of 18–5.8–26S rDNA repeats in Nicotiana allotetraploids

We review and extend data showing concerted evolution of parental 18–5.8–26S nuclear ribosomal DNA (18–26S rDNA) gene families in three natural Nicotiana allotetraploids ( N. tabacum , N. rustica and N. arentsii , each 2 n  = 4 x  = 48) and one synthetic N. tabacum line (Th37, ♀ N. sylvestris (2 n  = 24) × ♂ N. tomentosiformis (2 n  = 24)). The origin of the gene families was analysed by sequence polymorphisms in the intergenic spacer (IGS) region and the number of chromosomal loci by fluorescence in situ hybridization (FISH). FISH revealed that the number and locations of 18–26S rDNA in the natural allopolyploids was the sum of those found in the diploid progenitors. However, the rDNA restriction patterns showed polymorphisms in the IGS that were not additive, suggesting that parental rDNA clusters were partially ( N. tabacum, N. rustica ) or completely ( N. arentsii ) overwritten by hybrid-specific units. Thus the Nicotiana allotetraploids show evidence of concerted evolution, including both intralocus and interlocus gene conversion. A feral N. tabacum collected in Bolivia had a higher proportion of unconverted parental rDNA units than cultivated tobacco varieties, suggesting either that rDNA homogenization is accelerated by inbreeding or multiple origins of tobacco. There is no evidence for the elimination of N. sylvestris- derived rDNA units in the synthetic Th37 tobacco line as occurred in natural tobacco, although several novel rDNA unit variants were found in most but not all the hybrid plants. Factors that may control the occurrence and extent of rDNA homogenization are discussed for allopolyploids in Nicotiana and other taxa.  © 2004 The Linnean Society of London, Biological Journal of the Linnean Society , 2004, 82 , 615–625.