Phylogenetic relationships in the genus Nicotiana were investigated using parsimony analyses of the internal transcribed spacer (ITS) regions of nuclear ribosomal DNA (nrDNA). In addition, origins of some amphidiploid taxa in Nicotiana were investigated using the techniques of genomic in situ hybridization (GISH), and the results of both sets of analyses were used to evaluate previous hypotheses about the origins of these taxa. Phylogenetic analyses of the ITS nrDNA data were performed on the entire genus (66 of 77 naturally occurring species, plus three artificial hybrids), comprising both diploid and polyploid taxa, and on the diploid taxa only (35 species) to examine the effects of amphidiploids on estimates of relationships. All taxa, regardless of ploidy, produced clean, single copies of the ITS region, even though some taxa are hybrids. Results are compared with a published plastid (matK) phylogeny using fewer, but many of the same, taxa. The patterns of relationships in Nicotiana, as seen in both analyses, are largely congruent with each other and previous evolutionary ideas based on morphology and cytology, but some important differences are apparent. None of the currently recognized subgenera of Nicotiana is monophyletic and, although most of the currently recognized sections are coherent, others are clearly polyphyletic. Relying solely upon ITS nrDNA analysis to reveal phylogenetic patterns in a complex genus such as Nicotiana is insufficient, and it is clear that conventional analysis of single data sets, such as ITS, is likely to be misleading in at least some respects about evolutionary history. ITS sequences of natural and well-documented amphidiploids are similar or identical to one of their two parents-usually, but not always, the maternal parent-and are not in any sense themselves 'hybrid'. Knowing how ITS evolves in artificial amphidiploids gives insight into what ITS analysis might reveal about naturally occurring amphidiploids of unknown origin, and it is in this perspective that analysis of ITS sequences is highly informative.
Nicotiana tabacum (2n = 48) is a natural amphidiploid with component genomes S and T. We used non-radioactive in situ hybridization to provide physical chromosome markers for N. tabacum, and to determine the extant species most similar to the S and T genomes. Chromosomes of the S genome hybridized strongly to biotinylated total DNA from N. sylvestris, and showed the same physical localization of a tandemly repeated DNA sequence, HRS 60.1, confirming the close relationship between the S genome and N. sylvestris. Results of dot blot and in situ hybridizations of N. tabacum DNA to biotinylated total genomic DNA from N. tomentosiformis and N. otophora suggested that the T genome may derive from an introgressive hybrid between these two species. Moreover, a comparison of nucleolus-organizing chromosomes revealed that the nucleolus organizer region (NOR) most strongly expressed in N. tabacum had a very similar counterpart in N. otophora. Three different N. tabacum genotypes each had up to 9 homozygous translocations between chromosomes of the S and T genomes. Such translocations, which were either unilateral or reciprocal, demonstrate that intergenomic transfer of DNA has occurred in the amphidiploid, possibly accounting for some results of previous genetic and molecular analyses. Molecular cytogenetics of N. tabacum has identified new chromosome markers, providing a basis for physical gene mapping and showing that the amphidiploid genome has diverged structurally from its ancestral components.
Members of a new family of highly repetitive DNA sequences called GRS were isolated from Nicotiana tabacum L. genomic DNA and characterized. Cloned, sequenced monomeric units (180-182 bp) of GRS exhibit properties characteristic of molecules that possess a stable curvature. The GRS family represents about 0.15% of total genomic DNA (10(4) copies per haploid genome) and could be derived from either Nicotiana tomentosiformis or Nicotiana otophora, two possible ancestors of the T genome of the amphidiploid N. tabacum. Sequence homology between the HRS60 (Koukalová et al. 1989) and the GRS family has been estimated to be 57%. In situ hybridization was used to localize GRS on mitotic chromosomes. Hybridization signals were obtained on five pairs of chromosomes at intercalary sites of the longer chromosome arms. The majority of GRS sequences appeared to be organized in tandem arrays and a minority were found to be dispersed through the genome in short clusters, interspersed with other types of DNA repeats, including 25S rDNA sequences. Several loci containing both GRS and HRS60 were also found. Such hybrid loci may indicate intergenomic transfer of the DNA in the amphidiploid N. tabacum. GRS sequences, like HRS60 (Fajkus et al. 1992), were found to specify the location of nucleosomes. The position of the nucleosome core has been mapped with respect to a conserved Mbol site in the GRS sequence and an oligo A/T tract is a major centre of the DNA curvature.
Chromosome spatial arrangements on metaphase plates of intergeneric intertribal cell hybrids ofNicotiana chinensis and Atropa belladonna as well as interspecific somatic hybrid plants of Nicotiana plumbaginifolia and Nicotiana sylvestris were analyzed. In the metaphases of the first divisions of protoplast fusion products, chromosomes of the two parents were spatially separated (segmented metaphase). In long-term cultured somatic hybrids, the topology of genome separation pattern in both callus cells and plants showed changes in form from "segmental" to "radial." Growing the hybrid cells in the presence of colchicine resulted in random chromosome arrangement both in cells directly exposed to different colchicine concentrations and in colchicine-treated cells grown in colchicine-free media. The degree of genome separation calculated for different cell clones remained constant during in vitro propagation of cells but was significantly lower for subclones derived from colchicine-treated cells. Therefore, it is concluded that spatial chromosome arrangement in metaphase is epigenetically controlled.As early as 1925, chromosomes were observed to be positioned on the metaphase plate in a specific manner (1). Nevertheless, up till now the spatial arrangement of chromosomes at interphase and at mitosis and, in particular, the arrangement of the parental genomes in a hybrid cell still remained poorly understood. It is known that the arrangement and orientation of the parental (maternal and paternal) chromosomes are nonrandom in the zygote and the early stages of cleavage in some animal species (2-4). In the case of sexual hybrids between barley and rye, it was shown that the spatial separation of the parental genomes tends to persist for a large number of regular mitoses in somatic tissues (5). These facts and other information suggest that spatial separation of parental genomes in the somatic tissues of a sporophyte is of general occurrence, which has probably remained unnoticed due to the fact that in somatic cells, obtained by sexual crosses, maternal and paternal genomes are morphologically identical and, hence, difficult to distinguish. The hybridization of somatic cells permits the combination of cells of phylogenetically remote species which may have morphologically distinguishable chromosomes. Segmental disposition of the parental genomes at first metaphases after fusion (6-9) has a simple explanation and does not necessarily mean that this separation would persist through a large number of subsequent mitoses. Previous studies on the chromosome arrangement of progeny cells derived from somatic hybrids were limited almost exclusively to preparations treated with colchicine, a treatment known to result in distortion of chromosomal arrangements (7, 9-13). One early investigation (14) indicated that, within the hybrid metaphase plate of Nicotiana-Atropa somatic hybrids, the chromosomes of the two parents were unevenly distributed. This prompted a study of the chromosome arrangement in somatic cell hybrids of A...
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.