Genomic relationships between hexaploid Helianthus resinosus and diploid Helianthus annuus (Asteraceae)

Genus Helianthus comprises diploid and polyploid species. An autoallopolyploid origin has been proposed for hexaploid species but the genomic relationships remain unclear. Mitotic and meiotic studies in annual Helianthus annuus (2n = 2x = 34) and perennial Helianthus resinosus (2n = 6x = 102) as well as the F₁ hybrids between both species were carried out. Chromosome counting confirmed the hybrid origin of the latter plants and their tetraploid condition. Bivalents in hybrids ranged from 12 to 28 ( $ \bar{x} $  = 20.8). Univalents, trivalents and quadrivalents were also observed. Meiotic products comprised dyads, triads and normal tetrads and pollen grains were heterogeneous in size. These observations suggest the occurrence of 2n pollen in addition to the expected n. Genomic in situ hybridization (GISH) of total H. annuus DNA on H. resinosus chromosomes rendered weak but uniform signals; similar hybridization pattern was observed using three other annual species. Hybridization with H. annuus probe performed on root tip cells of F₁ H. annuus × H. resinosus hybrids revealed 17 chromosomes with a strong hybridization signal. GISH in hybrid meiocytes distinguished chromosomes from parental species and revealed autosyndetic pairing of H. resinosus chromosomes, allosyndetic pairing in bivalents, trivalents and quadrivalents, and the presence of univalents derived from parents, H. annuus and H. resinosus. Results obtained from classical and molecular cytogenetics do not support H. annuus as a direct ancestor of H. resinosus. The occurrence of allosyndetic pairing and the relatively high fertility of the F₁ hybrids point to the possibility that useful genes could be transferred from H. resinosus to cultivate sunflower, although the effective rate of recombination has not been evaluated. GISH method proved effective to recognize parental chromosomes in H. annuus × H. resinosus progeny.     

Genomic relationships between species of theElymus semicostatus group andElymus sensu lato (Poaceae)

Meiotic pairing behaviour in 19 interspecificElymus hybrids is reported and discussed. The hybrids were made between four species belonging to theE. semicostatus group of sect.Goulardia, viz.,E. semicostatus, E. abolinii, E. fedtschenkoi, andE. panormitanus (all 2n = 28), andElymus species of seven different sections, viz., sect.Clinelymiopsis:E. caucasicus (2n = 28); sect.Elymus:E. sibiricus (2n = 28); sect.Goulardia:E. caninus (2n = 28),E. trachycaulus (2n = 28), andE. tsukushiensis (2n = 42); sect.Hyalolepis:E. batalinii (2n = 42); sect.Hystrix:E. hystrix (2n = 28); sect.Macrolepis:E. canadensis (2n = 28); and sect.Turczaninovia:E. dahuricus (2n = 42). Chromosomal pairing at meiotic metaphase I indicated that the species of theE. semicostatus group are genomically closer to the tetraploidE. caucasicus and the hexaploid species, regardless of sectional origin, than to the other tetraploid species of sectionGoulardia. Highest meiotic pairing was found in hybrids involvingE. caucasicus, E. tsukushiensis, andE. dahuricus. The presence of pairing regulating genes inE. abolinii is suspected.     

Genomic and genetic relationships among species of Leymus (Poaceae: Triticeae) inferred from 18S-26S ribosomal genes

The 18S-26S ribosomal genes in three closely related species of Leymus (Poaceae: Triticeae) were examined using fluorescence in situ hybridization (FISH) and restriction fragment length polymorphism (RFLP). Both approaches revealed a close relationship between L. arenarius (8x = 56, northern European) and L. racemosus (4x = 28, central Eurasian), whereas L. mollis (4x = 28, northern American/Pacific) was distinct. Each species had three homologous pairs of major rDNA loci: a1, a2, and a3 for L. arenarius; m1, m2, and m3 for L. mollis; and r1, r2, and r3 for L. racemosus. Leymus arenarius had in addition three minor loci, a4, a5, and a6. The major loci of L. arenarius and L. racemosus were identical, indicating that the former species could have originated from the latter, via interspecific hybridization and/or polyploidy. The rDNA-RFLPs further indicated relationships of these species to other species of Leymus (L. karellini, 8x = 56 and L. angustus, 12x = 84) and Psathyrostachys (P. fragilis, P. huashanica, P. juncea, and P. lanuginosa, which are all diploids). A phenogram constructed from 20 BamHI, EcoRI, and DraI rDNA fragments revealed closer relationship between the two genera, Leymus and Psathyrostachys, than that among species within a genus.     

Genomic relationships among diploid and polyploid species of the genus Eryngium L. using genomic in situ hybridization

Eryngium L. (Umbelliferae) is a large genus including more than 250 species worldwide. The large morphological variability in this genus makes it difficult to delimit the species or to establish phylogenetic relationships. The occurrence of different ploidy levels within the genus might indicate a hybrid origin of the polyploid species. In the present study, the chromosome number and karyotype of E. regnellii are reportedfor the first time and the ploidy level of a population of E. paniculatum is confirmed. We compare the genomes of the diploids E. horridum and E. eburneum, the tetraploids E. megapotamicum and E. regnellii, and the hexaploids E. pandanifolium (as a representative of the whole pandanifolium complex) and E. paniculatum using genomic in situ hybridization (GISH). Although it was not possible to identify the parental species of the polyploid taxa analyzed, the GISH technique allowed us to postulate some hypotheses about their origin. Eryngium horridum and E. eburneum do not seem to be the direct progenitors of the polyploids analyzed. On the other hand, it seems that other diploid species unrelated to E. horridum and E. eburneum are involved in their origin. Our results are consistent with morphological and phylogenetic studies, indicating a close relationship between the species of the series Latifolia.     

Evolutionary dynamics of Waxy and the origin of hexaploid Spartina species (Poaceae)

We investigated the evolutionary dynamics of duplicated copies of the granule-bound starch synthase I gene (GBSSI or Waxy) within polyploid Spartina species. Molecular cloning, sequencing, and phylogenetic analyses revealed incongruences between the expected species phylogeny and the inferred gene trees. Some genes within species were more divergent than expected from ploidy level alone, suggesting the existence of paralogous sets of Waxy loci in Spartina. Phylogenetic analyses indicate that this paralogy originated from a duplication that occurred prior to the divergence of Spartina from other Chloridoideae. Gene tree topologies revealed three divergent homoeologous sequences in the hexaploid S. alterniflora that are consistent with the proposal of an allopolyploid origin of the hexaploid clade. Waxy sequences differ in insertion–deletion events in introns, which may be used to diagnose gene copies. Both paralogous and homoeologous coding regions appear to evolving under selective constraints.     

Intra- and interspecific phylogenetic relationships among diploid Triticum-Aegilops species (Poaceae) based on base-pair substitutions, indels, and microsatellites in chloroplast noncoding sequences

This study analyzes intra- and interspecific variation in chloroplast DNA (cpDNA) in diploid Triticum-Aegilops species. This analysis focused on DNA sequence variation in noncoding regions of cpDNA, which included base-pair substitutions, insertion/deletions (indels, 50 loci pooled), microsatellites (7 loci pooled), and inversions. Nine of 13 Triticum-Aegilops species were successfully identified and genotyped using these data. Sixty-two haplotypes were detected in 115 accessions of 13 diploid species. Because of the large number of characters examined, novel deep relationships within and among Triticum-Aegilops species could be identified and evaluated. Phylogenetic trees for the genus Triticum-Aegilops were constructed with Hordeum vulgare and Dasypyrum villosum as outgroups, and the results were compared to previous studies. These data support the following inferences: (1) Aegilops species should be included in Triticum; (2) groups D, T, M, N, U, and section Sitopsis (except Ae. speltoides) underwent speciation concurrently, but most diploid species evolved independently; (3) Ae. mutica does not occupy a basal position in Triticum-Aegilops; (4) Ae. speltoides is in a basal position and differs significantly from other Sitopsis species; (5) Ae. caudata is polyphyletic in all trees; (6) the genus Aegilops is paraphyletic with Secale.     

Genomic organization of ribosomal RNA genes in Bromus (Poaceae).

Restriction site maps of the rDNA genes of nine Bromus species are described. The rDNA repeat units ranged from 8.2 to 11.1 kbp in length. Intraspecific length variation was observed in the BamHI digestions in three of the nine species. Restriction site variation was observed mainly in the intergenic spacer (IGS) but was also detected in the coding region. A unique KpnI site was present in the IGS of Bromus tectorum and Bromus sericeus (subgenus Stenobromus); in addition, B. sericeus contained an extra EcoRI site. An additional DraI site was observed in the IGS of Bromus trinii (subgenus Neobromus). A BstEII site in the IGS, common to seven of the species, was absent in B. tectorum and B. sericeus. In the coding region, a 2.1-kbp BstEII fragment was present in four subgenera represented by Bromus inermis and Bromus erectus (subgenus Festucaria), Bromus marginatus and Bromus carinatus (subgenus Ceratochloa), B. tectorum and B. sericeus (subgenus Stenobromus), and B. trinii (subgenus Neobromus); a similar fragment of only 1.1 kbp was present in Bromus mollis and Bromus arvensis (subgenus Bromus). An additional BamHI site was present in the coding region of B. erectus. Ribosomal DNA data suggested that B. mollis and B. arvensis (subgenus Bromus) are genetically isolated from the other subgenera, which showed a derived relationship. Restriction site mapping of the rDNA genes could provide useful molecular data for species identification and population and evolutionary studies in Bromus. Key words : Bromus, ribosomal DNA, restriction maps, evolutionary relationships.     

Genomic relationships within theElymus parviglumis group (Triticeae: Poaceae)

Genomic relationships of 13 tetraploid species within the AsiaticElymus parviglumis group containing the SY genomes were assessed by analysing chromosome pairing at metaphase I of the parental species and their interspecific hybrids. Two major genomic subgroups among the tetraploids were identified from the cluster analysis of the averaged c-values, namely, theE. caucasicus subgroup (two species) and theE. parviglumis subgroup (11 species). The genomic affinity of theElymus species is associated with the interspecific geographic distance.After October 1, 1993     

The genome composition of hexaploid Psammopyrum athericum and octoploid Psammopyrum pungens (Poaceae: Triticeae).

The genomic constitution of two species in the genus Psammopyrum, i.e., Ps. athericum (2n = 6x = 42) and Ps. pungens (2n = 8x = 56), was studied by genomic in situ hybridization (GISH). In Ps. athericum, one diploid chromosome set hybridized to a genomic probe from Pseudoroegneria ferganensis (St genome), one diploid set to a probe from Agropyron cristatum (P genome), and one diploid set to a probe from Thinopyrum junceiforme (EbEe genomes) or Th. bessarabicum (Eb genome). Substituting the St-genome probe with an L-genome probe from Festucopsis serpentinii resulted in exactly the same hybridization pattern, suggesting a genomic constitution of EStP or ELP for Ps. athericum. The same probes used on Ps. pungens showed two diploid sets of chromosomes hybridizing to the St-genome probe, one diploid set hybridizing to the P-genome probe, and one diploid set hybridizing to the EbEe-genome probe. The L-genome probe hybridized to approximately 14 of the chromosomes that were labeled by the St-genome probe. Hence the genomic constitution for Ps. pungens is proposed to be EStStP or EStLP.     

Andropogon crispifolius (Poaceae: Andropogoneae): a new species from the cerrado of central Brazil

Andropogon crispifolius a new species from the environs of the Parque Nacional das Emas (in the states of Goiás and Mato Grosso do Sul) in central Brazil is here described, illustrated and compared with A. pohlianus Hack. It is a large, perennial, coarse grass characterized primarily by its strongly crispate older leaves. This new species is placed in sect. Notosolen Stapf, previously represented in South America by a single species, A. pohlianus .     

Comparison of common cytotypesof Andropogon gerardii(Andropogoneae,Poaceae)

Many plant species contain populations with more than one polyploid cytotype, but little is known of the mechanisms maintaining several cytotypes in a population. Andropogon gerardii cytotypes were compared to evaluate different models of autopolyploid cytotype coexistence. The enneaploid (90 chromosome, 9x) cytotype was found to be larger and taller than the hexaploid (60 chromosome, 6x) cytotype. Seed production is significantly more efficient in hexaploids, but seed production per area was not significantly different. The two cytotypes are not exomorphologically separable in the field because of great plasticity in response to environmental variation and wide variation within each cytotype. These data suggest cytotypic variation is maintained by natural selection.     

Phylogenetic relationships among Leymus and related diploid genera (Triticeae: Poaceae) based on chloroplast trnQ–rps16 sequences

To investigate the phylogenetic relationships among Leymus and related diploid genera, the genome donor of Leymus, and the evolutionary history of polyploid Leymus species, chloroplast trnQ–rps16 sequences were analyzed for 36 accessions of Leymus representing 25 species, together with 11 diploid taxa from six monogenomic genera. The phylogenetic analyses (Neighbor‐Joining and MJ network) supported three major clades (Ns, St and Xm). Sequence diversity and genealogical analysis suggested that 1) Leymus species from the same areas or neighboring geographic regions are closely related; 2) most of the Eurasian Leymus species are closely related to Psathyrostachys: P. juncea might serve as the Ns genome donor of polyploid Eurasian Leymus species; 3) the Xm genome may originate from ancestral lineages of Pseudoroegneria (St), Lophopyrum (E^e), Australopyrum (W) and Agropyron (P); 4) the trnQ–rps16 sequences of Leymus are evolutionarily distinct, and may clarify parental lineages and phylogenetic relationships in Leymus.     

利用RAPD分析披碱草属、鹅观草属和猬草属模式种的亲缘关系

利用随机扩增多态性DNA（RAPD）技术对小麦族披碱草属、鹅观草属和猬草属3个属的模式种进行了基因组DNA多态性分析。42个引物产物的290条谱带中,257条（88.62%)表现出多态性,说明披碱草属、鹅观草属和猬草属3个属的模式种间具有丰富的遗传多样性。利用290个RAPD标记,计算材料间Nei氏遗传相似性系和遗传距离,在NTSYS程序中利用UPGMA进行聚类。结果表明,Elymus sibiricus种不同居群间的遗传差异较小,遗传距离在0.097-0.180之间。E.sibiricus,Roegneria caucasica和Hystrix patula的种间遗传差异明显,遗传距离在0.458-0.605之间。H.patula与E.sibiricus的亲缘关系较近。R.caucasica与E.sibiricus的亲缘关系较远。     

Morphological variation inLolium (Poaceae) as a measure of species relationships

Analysis of morphological and phenological data for determining the genetic variation within sevenLolium species led to the recognition of two groups within this genus. One group, containing the two inbreeding speciesL. temulentum andL. persicum, was clearly distinct from all other species. Strong morphological and phenological intergradation was found between both species. The cross-breeding species,L. perenne, L. rigidum, andL. multiflorum, formed another group. Little differentiation was found between these species, though they were distinct. Two inbreeding species,L. loliaceum andL. remotum, were clearly distinct from each other and the two groups.L. loliaceum had an isolated position and was most related toL. rigidum. L. remotum had an intermediate position between the cross-breeding and inbreeding species, and was almost equally distant from all three cross-breeding species.Genetic variation inLolium spp. I.     

Cytotypes of Andropogon gerardii Vitman (Poaceae): fertility and reproduction of aneuploids

In many North American prairies, populations of Andropogon gerardii Vitman (Poaceae) are composed of hexaploid and enneaploid cytotypes (2 n  = 60, 90), with intermediates occurring occasionally. Under controlled pollination, the two common cytotypes can be crossed, producing progeny with a range of chromosome numbers. In an investigation of fertility and compatibilities of intermediate cytotypes, individuals with chromosome numbers between 60 and 90 were crossed with each other, with the 2 n  = 60 and 90 cytotypes, and with South American Andropogon species having 60 chromosomes. Regardless of cytotype, all A. gerardii plants had some fertility and virtually all crosses produced seeds. Cytotype is only partially predictive of fertility. Inter-specific hybrids between A. gerardii and South American hexaploid species were vigorous but sterile. Gene flow in natural A. gerardii populations of mixed cytotype probably involves plants of all cytotypes.  © 2003 The Linnean Society of London, Botanical Journal of the Linnean Society , 2003, 141 , 95–103.     

利用多基因序列探讨稻属药稻复合体二倍体物种的系统发育关系

稻属药稻复合体Oryza officinalis complex中有5个二倍体物种,涉及B、C和E3个染色体组,分布在亚洲、非洲和大洋洲。其中,O.australiensis是稻属中惟一含E染色体组的物种;O.punctata则是惟一含B染色体组的物种。虽然O.officinalis、O.rhizomatis和O.eichingeri都含C染色体组,但由于它们间断分布在亚洲和非洲,可能在稻属异源多倍体成种中发挥了不同作用。染色体组B、C和E之间,以及上述二倍体物种之间的系统发育关系及其在稻属多倍体物种形成     

Chloroplast DNA variation in diploid and polyploid species of Bromus (Poaceae) subgenera Festucaria and Ceratochloa

Summary Chloroplast DNA (cpDNA) restriction endonuclease patterns are used to examine phylogenetic relationships between Bromus subgenera Festucaria and Ceratochloa. Festucaria is considered monophyletic based on the L genome, while Ceratochloa encompasses two species complexes: the B. catharticus complex, which evolved by combining three different genomes, and the B. carinatus complex, which is thought to have originated from hybridization between polyploid species of B. catharticus and diploid members of Festucaria. All species of subgenus Ceratochloa (hexaploids and octoploids) were identical in chloroplast DNA sequences. Similarly, polyploid species of subgenus Festucaria, except for B. auleticus, were identical in cpDNA sequences. In contrast, diploid species of subgenus Festucaria showed various degrees of nucleotide sequence divergence. Species of subgenus Ceratochloa appeared monophyletic and phylogenetically closely related to the diploid B. anomalus and B. auleticus of subgenus Festucaria. The remaining diploid and polyploid species of subgenus Festucaria appeared in a distinct grouping. The study suggests that the B. catharticus complex must have been the maternal parent in the proposed hybrid origin of B. carinatus complex. Although there is no direct evidence for the paternal parent of the latter complex, the cpDNA study shows the complex to be phylogenetically very related to the diploid B. anomalus of subgenus Festucaria.     

Phylogenetic relationships among diploid Aegilops species inferred from 5S rDNA units

Relationships among the currently recognized 11 diploid species within the genus Aegilops have been investigated. Sequence similarity analysis, based upon 363 sequenced 5S rDNA clones from 44 accessions plus 15 sequences retrieved from GenBank, depicted two unit classes labeled the long AE1 and short AE1. Several different analytical methods were applied to infer relationships within haplomes, between haplomes and among the species, including maximum parsimony and maximum likelihood analyses of consensus sequences, “total evidence” phylogeny analysis and “matrix representation with parsimony” analysis. None were able to depict suites of markers or unit classes that could discern among the seven haplomes as is observed among established haplomes in other genera within the tribe Triticeae; however, most species could be separated when displayed on gene trees. These results suggest that the haplomes currently recognized are so refined that they may be relegated as sub-haplomes or haplome variants. Amblyopyrum shares the same 5S rDNA unit classes with the diploid Aegilops species suggesting that it belongs within the latter. Comparisons of the Aegilops sequences with those of Triticum showed that the long AE1 unit class of Ae. tauschii shared the clade with the equivalent long D1 unit class, i.e., the putative D haplome donor, but the short AE1 unit class did not. The long AE1 unit class but not the short, of Ae. speltoides and Ae. searsii both share the clade with the previously identified long {S1 and long G1 unit classes meaning that both Aegilops species can be equally considered putative B haplome donors to tetraploid Triticum species. The semiconserved nature of the nontranscribed spacer in Aegilops and in Triticeae in general is discussed in view that it may have originated by processes of incomplete gene conversion or biased gene conversion or birth-and-death evolution.