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, Ǩ N. sylvestris (2 n = 24) ¥ ǩ 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.
Unidirectional gene conversion of rDNA units has occurred in the evolution of natural tobacco (Nicotiana tabacum). In this paper we report the use of the synthetic tobacco line Th37, 4n (N. sylvestris × N. tomentosiformis), to study early rDNA evolution associated with allopolyploidy. At least three classes of newly amplified rDNA unit variants were identified (17/20 plants). Their presence was often accompanied by near-complete elimination of N. tomentosiformis-donated rDNA units (15/20 plants). Novel rDNA units were of N. tomentosiformis-type and contained rearranged subrepeats in the intergenic spacer. The maternal N. sylvestris-derived units were unchanged, except for some alteration in the ratio of individual gene family members. A cytogenetic analysis revealed rDNA sites on N. sylvestris-derived chromosomes S10, S11, and S12 and N. tomentosiformis-derived chromosomes T3 and in some cases T4. An rDNA locus does not occur on N. tomentosiformis chromosome 4. The locus on chromosome T4 of some hybrids correlates with the occurrence of the novel units that probably amplified at the locus. Combined with an analysis of tobacco cultivars, the data indicate that an initial burst of rDNA evolution associated with allopolyploidy was followed by a slower process that led towards reduced complexity and a decreased number of rDNA variants.
Summary• Allopolyploids represent natural experiments in which DNA sequences from different species are combined into a single nucleus and then coevolve, enabling us to follow the parental genomes, their interactions and evolution over time. Here, we examine the fate of satellite DNA over 5 million yr of divergence in plant genus Nicotiana (family Solanaceae).• We isolated subtelomeric, tandemly repeated satellite DNA from Nicotiana diploid and allopolyploid species and analysed patterns of inheritance and divergence by sequence analysis, Southern blot hybridization and fluorescent in situ hybridization (FISH).• We observed that parental satellite sequences redistribute around the genome in allopolyploids of Nicotiana section Polydicliae, formed c. 1 million yr ago (Mya), and that new satellite repeats evolved and amplified in section Repandae, which was formed c. 5 Mya. In some cases that process involved the complete replacement of parental satellite sequences.• The rate of satellite repeat replacement is faster than theoretical predictions assuming the mechanism involved is unequal recombination and crossing-over. Instead we propose that this mechanism occurs with the deletion of large chromatin blocks and reamplification, perhaps via rolling circle replication.
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