ITS1–5.8S rDNA–ITS2 and trnL-trnF Sequences as Markers for the Study of Species Diversity of Altai Feather Grasses

Russian Journal of Genetics - The ITS1–5.8S rDNA–ITS2 sequence of the 35S rRNA genes of 16 species of feather grasses and 2 species of false needlegrasses of the flora of the Altai...     

Chromosome CPD(PI/DAPI)- and CMA/DAPI-banding patterns in Allium cepa L

Chromosome banding patterns of Allium cepa L. were obtained by using fluorochrome combinations chromomycin A3 (CMA) + 4',6-diamidino-2-phenylindole (DAPI), DAPI + actinomycin D (AMD) and propidium iodide (PI) + DAPI. In A. cepa, telomeric heterochromatin displayed dull fluorescence after staining with DAPI and DAPI/AMD. After staining with the GC-specific CMA and AT-specific DAPI, the CMA-positive fluorescence of the NOR region and the telomeric bands of C-heterochromatin was observed. In combination with DAPI, PI, a dye with low AT/GC specificity, produced almost uniform fluorescence of chromosomal arms and heterochromatin, whereas the NOR-adjoining regions displayed bright fluorescence. Denaturation of chromosomal DNA (95 degrees C for 1-3 min) followed by renaturation in the 2 x SSC buffer (37 degrees C, 12 h) altered the chromosome fluorescence patterns: specific PI-positive bands appeared and the contrast of CMA-banding increased. Bright fluorescence of the NOR and adjoining regions was also observed in the case. Three-minute denaturation led also to a bright PI-positive fluorescence of telomeric heterochromatin. The denaturation of chromosomal DNA before staining results in changes of the DAPI fluorescence pattern and in the appearance of DAPI fluorescence in GR-rich NOP regions. The mechanisms underlying the effects of denaturation/renaturation procedures on chromosome banding patterns obtained with different fluorochromes are discussed.     

Nucleotide composition and CpG and CpNpG content of ITS1, ITS2, and the 5.8S rRNA in representatives of the phylogenetic branches melanthiales-liliales and melanthiales-asparagales (Angiospermae,Monocotyledones) reflect the specifics of their evolution

The nucleotide composition and the contents of CpG and CpNpG in internal transcribed spacers 1 and 2 (ITS1 and ITS2) and the 5.8S rRNA gene of the nuclear genome were studied in two phylogenetic lineages of monocotyledonous angiosperms. The evolutionary advance of taxa by morphological characters proved to positively correlate with an increase in the contents of C, CpG, and CpNpG, contrasting the views that genome evolution in vertebrate and higher plants tends to decrease or, at least, preserve the amount of CpG and CpNpG, potentially subject to methylation, in nuclear DNA. Cryptaffinity taxa, which are intermediates between morphologically distinct taxonomic groups, displayed higher contents of CpG and CpNpG as compared with neighboring taxa. Changes in the contents of these elements in the regions of cryptaffinity taxa are intricate, suggesting a reciprocating character for their accumulation. Cryptaffinity taxa and their close phylogenetic relatives from the ancestral and descendant groups were assumed to reflect the key macroevolutionary changes and to correspond to saltatory periods separating the periods of gradual evolution.     

The origin of polyploid genomes of bluegrasses Poa L. and gene flow between Northern Pacific and sub-Antarctic islands

The involvement of present-day diploid bluegrass species in the formation of polyploid genomes was investigated using comparison of sequences of internal transcribed spacers ITS1 and ITS2, and the 5.8S rDNA sequence. It was demonstrated that highly polyploid New Zealand bluegrasses, P. cita (2n = 84; ca. 96 to 100), P. chathamica (2n = 112), and P. litorosa (2n = 263 to 266) formed separate highly supported clade together with tetraploids (2n = 28) P. intrusa, P. anceps, and P. trioides (Austrofestuca littoralis). Among the diploid species (2n = 14), the closest relatives of these species, as well as of the polyploid species of section Poa, are the genomes of Eurasian species P. remota, P. chaixcii (sect. Homalopoa), P densa (Bolbophorum), and P. sibirica (sect. Macropoa). Nuclear genomes of polyploid Stenopoa, Tichopoa, Oreinos, and Secundae are definitely related to the genome of Arctic species P. pseudabbreviata (sect. Abbreviatae). On the contrary, judging by the genes for nuclear 45S rRNA, genomes of diploid P. trivialis (sect. Pandemos), P. annua, and P. supina (sect. Ochlopoa both) are only remotely related to the genomes of highly polyploid species (distances p between them and other bluegrass species from different sections of subgenus Poa constitute 6-10% and 11-15%, respectively). The conclusion on the relationships between highly polyploid and diploid bluegrass species was tested using analysis of synapomorphic mutations in the 5.8S rRNA gene. It was demonstrated that genomes of Poa eminens (2n = 42) and P. schischkinii (2n = 70) (sect. Arctopoa both) were noticeably different in ITS regions from the genomes of the members of the type subgenus Poa. A comparison of the Arctopoa ITS regions showed that the differences between them constituted only 0.2%. At the same time, p distances between the Arctopoa ITS and those from the species belonging to other sections of the genus Poa varied from 5 to 14%. South American species P chonotica (sect. Andinae) (=Ncoraepoa chonotica) (2n = 42) was found to be related to Arctagrostis, Festucella, and Hookerochloa, being at the same time quite distant from the other species of the genus Poa. Polymorphic in chromosome number highly polyploid species of Northern Hemisphere, P. arctica (2n = 42 to 106), P. turneri (2n = 42, 63 to 64), and P. smirnovii (2n = 42, 70) (sect. Malacanthae) are relative to a large group of tetraploid (2n = 28) endemic bluegrass species from New Zealand and sub-Antarctic islands (P. novae-zelandiae and allied species).     

Chromosome Maps of Trilliaceae: II. A Study of the Genome Composition in Polyploid Species of the Genus Trillium by Fluorescence Nucleotide Base-Specific Staining of Heterochromatic Chromosome Regions

Chromosome banding with nucleotide base-specific fluorochromes chromomycin A₃ (CMA) and Hoechst 33258 (H33258) was used to study the karyotypes and to construct cytological maps for diploidTrillium camschatcense(2n = 10), tetraploid T. tschonoskii(2n = 20), hexaploidT. rhombifolium (2n = 30), and a triploid T. camschatcense × T. tschonoskii hybrid (T. × hagae, 2n = 15). With H33258, species- and genome-specific patterns with numerous AT-rich heterochromatin bands were obtained for each of the four forms; CMA revealed a few small, mostly telomeric GC-rich bands. In T. tschonoskii, the two subgenomes were similar to each other and differed from the T. camschatcense genome; on this evidence, the species was considered to be a segmental allotetraploid. InT. ×hagae, one T. camschatcense and both T. tschonoskii subgenomes were identified. The subgenomes of T. rhombifoliumonly partly corresponded to the T. camschatcense and T. tschonoskii genomes, in contrast to the morphologically identical Japanese species T. hagae. This was assumed to indicate that allohexaploids T. rhombifolium and T. hagae originated independently at different times; i.e., their origin is polyphyletic. Based on the chromosome maps, a new nomenclature was proposed for theTrillium genomes examined: K₁K₁ for T. camschatcense,T₁T₁T₂T₂ for T. tschonoskii,K₁T₁T₂ for T. × hagae, and K_1RK_1RT_1RT_1RT_2RT_2R for T. rhombifolium.     

Polymorphic Sites in ITS1-5.8S rDNA-ITS2 Region in Hybridogenic Genus × <Emphasis Type="Italic">Elyhordeum</Emphasis> and Putative Interspecific Hybrids <Emphasis Type="Italic">Elymus</Emphasis> (Poaceae: Triticeae)

The genus Elymus L. is a complicated aggregate of ecological and geographical races, species, subspecies, varieties, and hybrids. We suggest that comparative analysis of intragenomic polymorphism of internal transcribed spacers ITS1 and ITS2 of 35S rRNA genes in the supposed hybrids and their possible “parents” can be one of the approaches to verification of hybrid origin of the samples collected in nature to confirm or reject the hypotheses about their possible “parents.” Polymorphic sites (PS) in ITS of 23 Elymus species, as well as in two supposed interspecific Elymus hybrids and in a supposed intergeneric hybrid between Elymus × Hordeum determined as × Elyhordeum sp., were analyzed in the work. We collected all hybrids in the Altai. There were 2 and 5 PS in two samples of E. dahuricus and 1 and 4 PS in two studied samples of E. schrenkianus in the ITS1-5.8S rDNA-ITS2 region. From 0 to 4 (modes 0 and 3) PS were detected in 32 samples relating to 21 tetraploid Elymus species. More PS (14) were found in the × Elyhordeum sp. sample. A large number of single nucleotide substitutions were found in 5.8S rRNA in × Elyhordeum. It was shown that about half of them do not change the secondary structure of the 5.8S rRNA molecule, so these molecules probably retain the ability to work as a component of large subunit of a ribosome. On the other hand, the absence or weakening of 5.8S rDNA homogenization in × Elyhordeum indirectly suggests that a significant part of 5.8S rDNA is not transcribed. Paradoxically, ITS sequences of × Elyhordeum sp. are less polymorphic than 5.8S rDNA. There are no ITS sequences derived from Hordeum among × Elyhordeum ITS sequenced by Sanger method. No traces of the H subgenome and a subgenome originating from Agropyron (P-subgenome) are seen in the Alt 10–278 plant genome (a chimera, combining the morphological traits of Elymus, Elytrigia, and Agropyron). In this plant, as well as in the supposed intersectional hybrid Alt 11–60 distinguished by a mosaic of the traits typical for the E. caninus × E. mutabilis species, only 4 and 5 PS, respectively, are detected when sequencing by Sanger method. The comparison of ITS sequences of the supposed Elymus Alt 10–278 hybrid and its probable “parents” demonstrates that one of the species of the Elymus macrourus kinship circle, as well as the Elytrigia geniculata, could be one of its ancestors. The comparison of the ITS sequence of the supposed parental species with ITS of Alt 11–60 samples and five PS of the supposed Alt 11–60 hybrid does not contradict the hypothesis that this is an intersectional hybrid of the first generation that emerged with the involvement of E. caninus and E. mutabilis common in the Altai.     

Polymorphic sites in transcribed spacers of 35S rRNA genes as an indicator of origin of the <Emphasis Type="Italic">Paeonia</Emphasis> cultivars

Region ITS1–5.8S rDNA–ITS2 is sequenced in 27 varieties of cultivated ornamental peonies, ten of which presumably originate from Paeonia lactiflora, one from P. officinalis, 13 from hybridization of P. lactiflora and P. peregrina, or P. officinalis, and three are Itoh hybrids. Comparative analysis of distribution patterns of polymorphic sites (PS) for the obtained DNA sequences and data from GenBank is carried out. Hypotheses of origin of the studied varieties, except for two, which, as previously assumed, originate from hybridization of P. lactiflora and P. peregrina, are confirmed. It is shown that the sequence ITS1–5.8S rDNA–ITS2 is a good genetic marker for cultivars of the P. lactiflora group and Itoh hybrids, and that the PS distribution patterns in these sequences can provide valuable information on the kinship and origin of individual varieties. However, insufficient knowledge of wild species from the P. officinalis kinship group limits the use of this marker in the study of varieties obtained through interspecific hybridization within the Paeonia section.     

Nucleotide Composition of the Cold-Sensitive Heterochromatic Regions in Paris hainanensis Merrill

Cold-induced decondensation of heterochromatic regions (CSR-bands) in Paris hainanensis(=Daiswa hainanensisMerrill Takht.) (2n= 10; 10 + b) was studied. The comparison of CSR-banding patterns with those obtained by nucleotide-specific staining with fluorochromes DAPI and chromomycin A₃demonstrated that low temperatures induced decondensation only of large AT-rich heterochromatic regions. It is suggested that this is characteristic of all plant species.     

The origin of polyploid genomes of bluegrasses <Emphasis Type="Italic">Poa</Emphasis> L. and Gene flow between northern pacific and sub-Antarctic Islands

The involvement of present-day diploid bluegrass species in the formation of polyploid genomes was investigated using comparison of sequences of internal transcribed spacers ITS1 and ITS2, and the 5.8S rRNA sequence. It was demonstrated that highly polyploid New Zealand bluegrasses, P. cita (2n = 84; ca. 96 to 100), P. chathamica (2n = 112), and P. litorosa (2n 263–266) formed separate highly supported clade together with tetraploids (2n = 28) P. intrusa, P. anceps, and P. triodioides (Austrofestuca littoralis). Among the diploid species (2n = 14), the closest relatives of these species, as well as of the polyploid species of section Poa, are the genomes of Eurasian species P. remota, P. chaixii (sect. Homalopoa), P. densa (sect. Bolbophorum), and P. sibirica (sect. Macropoa). Nuclear genomes of polyploid Stenopoa, Tichopoa, Oreinos, and Secundae are definitely related to the genome of Arctic species P. pseudoabbreviata (sect. Abbreviatae). On the contrary, judging by the genes for nuclear 45S rRNA, genomes of diploid P. trivialis (sect. Pandemos), P. annua, and P. supina (sect. Ochlopoa both) are only remotely related to the genomes of highly polyploid species (p-distances between them and other bluegrass species from different sections of subgenus Poa constitute 6–10% and 11–15%, respectively). The conclusion on the relationships between highly polyploid and diploid bluegrass species was tested using analysis of synapomorphic mutations in the 5.8S rRNA gene. It was demonstrated that genomes of Poa eminens (2n = 42) and P. schischkinii (2n = 70) (sect. Arctopoa both) were noticeably different in ITS regions from the genomes of the members of the type subgenus Poa. A comparison of the Arctopoa ITS regions showed that the differences between them constituted only 0.2%. At the same time, p-distances between the Arctopoa ITS and those from the species belonging to other sections of the genus Poa varied from 5 to 14%. South American species P. chonotica (sect. Andinae) (= Nicoraepoa chonotica) (2n = 42) was found to be related to Arctagrostis, Festucella, and Hookerochloa, being at the same time quite distant from the other species of the genus Poa. Polymorphic in chromosome number highly polyploid species of Northern Hemisphere, P. arctica (2n = 42 to 106), P. turneri (2n = 42, 63 to 64), and P. smirnowii (2n = 42, 70) (sect. Malacanthae) are relative to a large group of tetraploid (2n = 28) endemic bluegrass species from New Zealand and sub-Antarctic islands (P. novaezelandiae and allied species).