Transfer of Brassica tournefartii (TT) genes to allotetraploid oilseed Brassica species (B. juncea AABB, B. napus AACC, B. carinata BBCC): homoeologous pairing is more pronounced in the three-genome hybrids (TACC, TBAA, TCAA, TCBB) as compared to allodiploids (TA, TB, TC)

For the transfer of genes from B. tournefortii (TT) to the allotetraploid oilseed brassicas, B. juncea AABB, B. carinata BBCC and B. napus AACC, B. tournefortii was first crossed with the three basic diploid species, B. campestris (AA), B. nigra (BE) and B. oleracea (CC), to produce the allodiploids TA, TB and TC. These were tetraploidized by colchicine treatment to produce the allotetraploids TTAA, TTBB and TTCC, which were further crossed with B. juncea and B. napus to produce three-genome hybrids with substitution-type genomic configurations: TACC, TBAA and TCAA. These hybrids along with another hybrid TCBB produced earlier, the three allodiploids, their allotetraploids and the four diploid parent species were studied for their male meiotic behaviour. The diploid parent and the allotetraploids (TTAA, TTBB and TTCC) showed regular meiosis although the pollen viability was generally low in the allotetraploids. In the allodiploids (TA, TB and TC) only some end-to-end associations were observed without any clearly discernible chiasmata or exchange points. Chromosomes involved in end-to-end associations were randomly distributed at the metaphase/anaphase-I stages. In contrast, the three-genome hybrids (TACC, TBAA, TCAA and TCBB) showed normal bivalents whose number exceeded the expected bivalent values. Bivalents arising out of homoeologous pairing were indistinguishable from normal pairs by their disjunction pattern but could be distinguished on the basis of the heteromorphy of the homoeologous chromosomes. The three-genome hybrids could be backcrossed to allotetraploid oilseed brassicas as they had some fertility. In contrast, the allodiploids could neither be selfed nor back-crossed. On the basis of their meiotic stability, in terms of more pronounced homoeologous pairing and fertility for backcrossing, the three-genome configurations provide the best possible situation for the introgression of alien genes from the secondary gene pool to the allotetraploid oilseed crops B. juncea, B. napus and B. carinata.     

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.     

Citrus somatic hybrid: an alternative system to study rapid structural and epigenetic reorganization in allotetraploid genomes

Citrus somatic hybrids produced in the past years provide a novel opportunity to study the immediate effects of allopolyploidization on genome structure and methylation. Here, we present a first attempt to investigate the alterations in genome structure and methylation in three sets of citrus somatic allotetraploids and their diploid parents using amplified fragment length polymorphism (AFLP) and methylation-sensitive amplified polymorphism (MSAP) techniques. Our results indicate that all the allotetraploids mainly have the AFLP and MSAP banding patterns containing specific bands from both parents plus some alterations. The incidences of the AFLP polymorphic bands in allotetraploids show a range from 4.61 to 7.88 %, while from 12.50 to 15.67 % of the sites are methylated. In addition, the proportions of callus-parent-specific DNA structure and methylation alterations are much greater than those of leaf-parent-specific alterations in the somatic hybrids. Furthermore, we find that the somatic hybrids take on a greater divergence from the callus parent and a closer relationship to leaf parent in all groups of plants by dendrogram analysis based on AFLP or MSAP data. Taken together, our results suggest that somatic hybrids are very useful in elucidating the immediate changes that occur in newly synthesized allotetraploid.