The ancestry of Hordeum depressum (Poaceae, Triticeae)

Based on morphological, cytological, and molecular data, three diploid Hordeum species have by various authors been suggested to may have participated in the ancestry of the tetraploid H. depressum . In order to test the different hypotheses we undertook hybridizations between the proposed taxa, H. brachyantherum ssp. californicum, H. intercedens , and H. pusillum . Autoploids and amphiploids were achieved by treatment of young shoots with colchicine. These were then hybridized with H. depressum and the resulting hybrid plants were tested for fertility. The results strongly indicate that H. depressum arose as a consequence of hybridization between H. brachyantherum ssp. californicum and H. intercedens , probably with H. brachyantherum ssp. californicum as the female parent.     

Intergeneric Hybridization between Species of Leymus, Psathyrostachys and Hordeum (Poaceae, Triticeae)

A total of 132 intergeneric crossing attempts (49 combinations)involving species of Leymus Hochst., Psathyrostachys Nevskiand Hordeum L. were performed, of which 103 were between Hordeumand Leymus. Embryo rescue was used throughout the experiment.Hybrids between Leymus and Psathyrostachys were difficult toobtain. Hybrid progeny were relatively easily obtained whencrossing Hordeum and Leymus. Plants from 20 different combinationswere obtained. Nineteen of these have not previously been reported.Meiotic analysis of three hybrid combinations of Hordeum x Leymusis reported. The high frequency of univalents in meiotic interphase(MI) indicates that allosyndetic chromosome pairing did notoccur, supporting the assumption that the genomes of Leymusare non-homologous to the H genomes of Hordeum.Copyright 1994,1999 Academic Press Taxonomy, Triticeae, Leymus, Psathyrostachys, Hordeum, intergeneric hybridization     

A taxonomic revision of Secale (Triticeae, Poaceae)

Several taxa have previously been recognized within Secale , but most of them are difficult or even impossible to distinguish morphologically. We recognize only three species: S. sylvestre, S. strictum , and S. cereale. Secale strictum has priority over S. montanum and has two subspecies, ssp. strictum and ssp. africanum , and two varieties within ssp. strictum , van strictum and var. ciliatoglume comb. nov. Secale cereale is also treated as having two subspecies. The cultivated taxa, marked by their tough rachises, are placed in ssp. cereale and the wild or weedy taxa that have more or less fragile rachis, in ssp. ancestrale. A complete synonymy is given for S. cereale , but typification has been omitted because, in many instances, type material does not exist or has been impossible to trace.     

Cytogenetic analyses inKengyilia laxiflora (Poaceae, Triticeae)

Kengyilia laxiflora (2n = 42) was cytogenetically studied with testersK. hirsuta (2n = 42, PPStStYY) andRoegneria kamoji (2n = 42, HHStStYY). Our data suggested thatK. laxiflora may possess a modified P genome, the P¹. Its St and Y genomes may also contain some structural changes and are more closely related to the St and Y genomes ofK. hirsuta than to those ofR. kamoji. Kengyilia laxiflora is reproductively separated from bothK. hirsuta andR. kamoji. These results indicated thatK. laxiflora is a good species in the genusKengyilia.     

Morphometrical analyses of Secale (Triticeae, Poaceae)

Some fifteen taxa ranked as species or subspecies have generally been recognized within Secale. However, most of these seem impossible to separate on morphology alone. Based on 14 morphological characters considered of diagnostic value and scored on 44 specimens representing most of the taxa a Principal Components Analysis (PCA) was carried out. Limited correlation was found between the characters and consequently the first three principal axes account for only about 60% of the total variation. The PCA shows only a weak separation of annual and perennial taxa. Further analyses mainly of spikelet characters support merging of most of the previously accepted taxa within each of these two groups. A total of three species with five infraspecific taxa are here proposed within the genus and a key is provided to the taxa.     

A new multiflorous species of Leymus (Poaceae: Triticeae) from western China

A new species of Leymus section Racemosus, L. pluriflorus L.B.Cai & T.L.Zhang, is described and illustrated. It grows in the eastern part of Qinghai Province and the southern part of Gansu Province, China. It most closely resembles L. crassiusculus L.B.Cai, from which it differs in having longer rachis internodes, some pedicellate spikelets, more florets per spikelet, glabrous lemmas, shorter paleas and shorter anthers. It differs from all other Chinese species taxa in Leymus with regard to the large number (8–12) of florets in its spikelets, and from all species of Leymus in adjacent countries in having three to four spikelets per node. © 2009 The Linnean Society of London, Botanical Journal of the Linnean Society, 2009, 159 , 343–348.     

The genome constitution ofRoegneria grandis (Poaceae, Triticeae)

Roegneria grandis was hybridized withR. ciliaris var.japonensis (2n = 28, SSYY),Elymus caninus (2n = 28, SSHH), andPseudoroegneria spicata (2n = 28, SSSS). Chromosome pairing was studied in parents and hybrids. It is concluded from this study that: (i)R. grandis is an allotetraploid species and contains the basic genomes S and Y: (ii) a certain degree of homoeology exists between the S and Y genomes of the species studied.     

Intergeneric hybridization and C-banding patterns inHordelymus (Triticeae,Poaceae)

Crosses ofHordelymus europaeus (2n = 4x = 28) with four genera in theTriticeae were attempted. Adult hybrids were obtained in combinations withHordeum bogdanii (2x),Hordeum depressum (4x), andSecale cereale (2x). The meiotic pairing was very low in the hybrids withH. bogdanii andSecale cereale (0.12 and 0.30 chiasmata/cell, respectively), whereas high pairing (9.90 chiasmata/cell) was found in hybrids withH. depressum due to autosyndetic pairing ofH. depressum chromosomes. The chromosome complement ofHordelymus europaeus comprised 16 metacentrics, 8 submetacentrics, and 4 SAT-chromosomes. The Giemsa C-banding patterns of the chromosomes were characterized by small to minute bands at no preferential positions. It is hypothesized thatHordelymus europaeus may genomically be closest related toTaeniatherum andPsathyrostachys spp.     

Progenitor-derivative relationships of Hordeum polyploids (Poaceae, Triticeae) inferred from sequences of TOPO6, a nuclear low-copy gene region

Polyploidization is a major mechanism of speciation in plants. Within the barley genus Hordeum, approximately half of the taxa are polyploids. While for diploid species a good hypothesis of phylogenetic relationships exists, there is little information available for the polyploids (4×, 6×) of Hordeum. Relationships among all 33 diploid and polyploid Hordeum species were analyzed with the low-copy nuclear marker region TOPO6 for 341 Hordeum individuals and eight outgroup species. PCR products were either directly sequenced or cloned and on average 12 clones per individual were included in phylogenetic analyses. In most diploid Hordeum species TOPO6 is probably a single-copy locus. Most sequences found in polyploid individuals phylogenetically cluster together with sequences derived from diploid species and thus allow the identification of parental taxa of polyploids. Four groups of sequences occurring only in polyploid taxa are interpreted as footprints of extinct diploid taxa, which contributed to allopolyploid evolution. Our analysis identifies three key species involved in the evolution of the American polyploids of the genus. (i) All but one of the American tetraploids have a TOPO6 copy originating from the Central Asian diploid H. roshevitzii, the second copy clustering with different American diploid species. (ii) All hexaploid species from the New World have a copy of an extinct close relative of H. californicum and (iii) possess the TOPO6 sequence pattern of tetraploid H. jubatum, each with an additional copy derived from different American diploids. Tetraploid H. bulbosum is an autopolyploid, while the assumed autopolyploid H. brevisubulatum (4×, 6×) was identified as allopolyploid throughout most of its distribution area. The use of a proof-reading DNA polymerase in PCR reduced the proportion of chimerical sequences in polyploids in comparison to Taq polymerase.     

Taxonomy in the Hordeum murinum complex (Poaceae)

Jacobsen, N, & Bothmer, R. von, 1995. Taxonomy in the Hordeum murinum complex (Poaceae). — Nord. J. Bot. 15: 449–458. Copenhagen. ISSN 0107–055X.
Hordeum murinum as circumscribed here comprises ssp. glaucum (2x), ssp. murinum (4x), and ssp. leporinum (4x, 6x). Previous taxonomical treatments are reviewed as well as the more recent approaches, viz. numerical and statistical analyses, investigations of isoenzymes, rDNA, cpDNA, meiotic analyses, and chromosome banding patterns. A formal nomenclatural treatment is presented.     

Phylogenetic analysis in some Hordeum species (Triticeae; Poaceae) based on two single-copy nuclear genes encoding acetyl-CoA carboxylase

We investigate the phylogenetic relationship, and evolutionary history of 18 diploid and polyploid Hordeum species including 22 taxa based on two single-copy nuclear ACC1 and ACC2 genes using maximum parsimony, maximum likelihood, and Bayesian inference. The results of molecular phylogenetic analysis demonstrated genetic relationships among taxa and origin of polyploids. Our phylogenetic analyses revealed a clear alloploid origin of Hordeum capense, with Eurasian Hordeum marinum subsp. gussoneanum as the Xa genome donor and diploid Asian Hordeum roshevitzii as the H genome donor. The formation of hexaploid Hordeum lechleri likely involves hybridization between tetraploid Hordeum brachyantherum subsp. brachyantherum and a diploid possessing the I genome. The Acc1 and Acc2 gene data analyses suggested that Siberian Hordeum bogdanii might have be the common ancestor of the diploid New World Hordeum species. Perennial diploid South American species, Hordeum comosum was the first-diverging group within the clade of diploid American species in the analyses.     

Interspecific hybridization with Hordeum depressum (Poaceae)

Hordeum depressum is a distinct, reproductively isolated, tetraploid species. The study of meiosis in hybrids with the closest congeneric relatives revealed intermediate to low pairing with most species. The exceptions are Hordeum brachyantherum ssp. californicum and H. arizonicum. H. depressum , probably share one highly similar genome with ssp. californicum and perhaps two with H. arizonicum . However, it is difficult to draw firm conclusions based only on meiotic figures, since the pairing may be disturbed by high autosyndetic pairing between the H. depressurn genomes.     

Variation and differentiation in Hordeum marinum (Poaceae)

In Hordeum marinum two subspecies are recognized, viz. ssp. marinum , 2x and ssp. gussoneanum , 2x and 4x. The tetraploid cytotype has a more eastern distribution in the Mediterranean area than the two diploids. Crosses and meiotic data in hybrids revealed that the three cytotypes are closely related. The tetraploid ssp. gussoneanum behaves like a true alloploid but evidently has a very strong diploidizing mechanism, which prevents recombination between the genomes. The isoenzyme pattern shows differences between the cytotypes and a clinal differentiation in ssp. marinum.     

Kengyilia habahenensis (Poaceae: Triticeae) — a new species from the Altai mountains,China

Kengyilia habahenensis, spec. nova, from the Altai mountains, China, is described morphologically and cytologically. It has 2n = 42 chromosomes, and the genome formula PYS.     

窄颖仲彬草生物系统学研究

窄颖仲彬草Ｋｅｎｇｙｉｌｉａ ｓｔｅｎａｃｈｙｒａ（Ｋｅｎｇ） Ｊ．Ｌ． Ｙａｎｇ ,Ｙｅｎ ｅｔ Ｂａｕｍ 是分布于我国西部的一种多年生六倍体植物。将其与犬草Ｅｌｙｍｕｓ ｃａｎｉｎｕｓ（Ｌ．） Ｌ．, 鹅观草Ｒｏｅｇｎｅｒｉａ ｋａｍｏｊｉ Ｏｈｗｉ, 糙毛仲彬草Ｋ．ｈｉｒｓｕｔａ （Ｋｅｎｇ） Ｊ．Ｌ．Ｙａｎｇ,Ｙｅｎ ｅｔ Ｂａｕｍ ３ 个种进行了杂交。对亲本及杂种Ｆ１ 代花粉母细胞减数分裂中期Ｉ染色体配对行为进行了观察。减数分裂平均构型分别为： Ｅ． ｃａｎｉｎｕｓ×Ｋ． ｓｔｅｎａｃｈｙｒａ２３－７９ Ⅰ＋ ５－２０ Ⅱ＋ ０－２７Ⅲ; Ｒ．ｋａｍｏｊｉ ×Ｋ．ｓｔｅｎａｃｈｙｒａ１８－２３ Ⅰ＋ １１－６８ Ⅱ＋ ０－０６ Ⅲ＋ ０－０６ Ⅳ; Ｋ．ｈｉｒｓｕｔａ ×Ｋ．ｓｔｅｎａｃｈｙｒａ４－８３Ⅰ＋ １７－３１ Ⅱ＋ ０－５５ Ⅲ＋ ０－２０ Ⅳ＋ ０－０２ Ⅴ。根据以上结果, 结合种的形态特征, 窄颖仲彬草应从鹅观草属Ｒｏｅｇｎｅｒｉａ Ｃ． Ｋｏｃｈ 拟冰草组ＰａｒａｇｒｏｐｙｒｏｎＫｅｎｇ 中组合到仲彬草属Ｋｅｎｇｙｉｌｉａ Ｙｅｎ ｅｔ Ｙａｎｇ。     

Genomic groups,morphology, and sectional delimitation in EurasianElymus (Poaceae,Triticeae)

Seven tetraploid species ofElymus, viz.E. sibiricus, E. caninus, E. gmelinii, E. semicostatus, E. caucasicus, E. parviglume, andE. longearistatus subsp.canaliculatus, representing five sections were studied morphologically and used in interspecific hybridizations. The aim was to investigate whether the present sectional delimitation of the genus was in agreement with genomic data and if there was a correlation between genome constitution and morphology. The study revealed: (i) further information on the genomic affinities between the different species, (ii) that there is no congruence between genome constitution of the species and current sectional delimitation, and (iii) that there is a correlation between genome constitution and morphology in the palea apex shape and in the size of cilia of the palea.     

A phylogenetic analysis of the monogenomic Triticeae (Poaceae) based on morphology

A cladistic analysis, primarily based on morphology, is presented from 40 diploid taxa representing the 24 monogenomic genera of the Triticeae. General problems related to the treatment of hybrids and supposedly allopolyploid heterogenomic taxa are highlighted. Special emphasis is given to taxa not traditionally included in Aegilops s.J. Most of the 33 characters used in the analysis are coded as binary. The only four multistate characters in the matrix are treated as unordered. Three diploid species of Bromus are used as outgroup. The number of equally parsimonious trees found is very large (approx. 170000; length = 107, ci = 0.36, ri = 0.75) and the strict consensus tree has an expectedly low level of resolution. However, most of the equally parsimonious trees owe their existence to an unresolved Aegilops clade. If this clade is replaced by its hypothetical ancestor, the number of equally parsimonious trees drops dramatically (48; length = 78, ci = 0.45, ri = 0.76). When trees for which more highly resolved compatible trees exist are excluded, only two trees remain. Bremer support is used as a measure of branch support. The trees based on morphology and on molecular data are largely incongruent.     

拟鹅观草属3种植物的核型研究

对禾本科小麦族拟鹅观草属物种Pseudoroegneria geniculata、P.geniculata ssp.scythica和P.geniculata ssp.pruinifera的核型进行了研究.结果显示:P.geniculata和P.geniculata ssp.scythica为四倍体物种,P.geniculata ssp.pruinifera为六倍体物种;P.geniculata、P.geniculata ssp.scythica和P.geniculata ssp.pruinifera的核型公式分别为2n=4x=28=18m(2sat)+10sm(2sat)、2n=4x=28=28m(2sat)和2n=6x=42=36m(6sat)+6sm(2sat);P.geniculata和P.geniculata ssp.pruinifera为2A核型,而P.geniculata ssp.scythica为1A核型.研究表明:3种植物的核型存在差异;P.geniculata ssp.pruinifera的核型为首次报道,其核型明显不同于P.geniculata和P.geniculata ssp.scythica.     

Synopsis of Leymus Hochst. (Triticeae: Poaceae)

Leymus is a genus in the Triticeae tribe, Poaceae. The taxa of this genus are allopolyploid species which possess the Ns and Xm genomes. According to cytological, cytogenetic and molecular genetic analyses, some species of Hystrix and Elymus ought to be transferred to this genus. A world revision of the genus Leymus is needed. In this paper we summarize experimental results, provide a key to sections, species and varieties, and list all the taxa we recognize in Leymus with their synonyms. This synopsis is a new taxonomic system to be used for the revision of Leymus.