Phylogeny and molecular evolution of the rbcL gene of St genome in Elymus sensu lato (Poaceae: Triticeae)

Analysis of the patterns and levels of diversity in duplicate gene not only traces evolutionary history of polyploids, but also provides insight into how the evolutionary process differs between lineages and between homoeologous loci within lineages. Elymus sensu lato is a group of allopolyploid species, which share a common St genome and with the different combinations of H, Y, P, and W genomes. To estimate the evolutionary process of the rbcL gene in species of Elymus s. l. and its putative dioploid relatives, 74 sequences were obtained from 21 species of Elymus s. l. together with 24 diploid taxa representing 19 basic genomes in Triticeae. Phylogeny and sequence diversity pattern analysis suggested that (1) species of Pseudoroegneria (Nevski) Á. Löve might serve as the maternal donor of the species of Elymus s. l; (2) differentiation of St genome were shown in the species of Elymus s. l. following polyploidy event; (3) divergences within the species might associate with geographic diversity and morphological variability; (4) differences in the levels and patterns of nucleotide diversity of the rbcL gene implied that the St genome lineages in the species of Elymus s. l. have differently evolutionary potentials.     

Presence and organization of an osmotic stress response domain in wild Triticeae species

Sixteen Triticeae species of the genera Aegilops L., Pseudoroegneria (Nevski) Löve, Taeniatherum Nevski and Thinopyrum Löve were investigated by PCR amplification for the presence of a wheat germin gene internal domain involved in osmotic stress resistance. In all of the species studied a single band of identical or very similar size was detected, After cloning and sequencing of these fragments, different degrees of homology were found with the original wheat domain, which suggested that in these species there are functional differences in the osmotic response involving the germin core.     

Distinct origin of the Y and St genome in Elymus species: evidence from the analysis of a large sample of St genome species using two nuclear genes

Background

Previous cytological and single copy nuclear genes data suggested the St and Y genome in the StY-genomic Elymus species originated from different donors: the St from a diploid species in Pseudoroegneria and the Y from an unknown diploid species, which are now extinct or undiscovered. However, ITS data suggested that the Y and St genome shared the same progenitor although rather few St genome species were studied. In a recent analysis of many samples of St genome species Pseudoroegneria spicata (Pursh) À. Löve suggested that one accession of P. spicata species was the most likely donor of the Y genome. The present study tested whether intraspecific variation during sampling could affect the outcome of analyses to determining the origin of Y genome in allotetraploid StY species. We also explored the evolutionary dynamics of these species.

Methodology/Principal Findings

Two single copy nuclear genes, the second largest subunit of RNA polymerase II (RPB2) and the translation elongation factor G (EF-G) sequences from 58 accessions of Pseudoroegneria and Elymus species, together with those from Hordeum (H), Agropyron (P), Australopyrum (W), Lophopyrum (E^e), Thinopyrum (E^a), Thinopyrum (E^b), and Dasypyrum (V) were analyzed using maximum parsimony, maximum likelihood and Bayesian methods. Sequence comparisons among all these genomes revealed that the St and Y genomes are relatively dissimilar. Extensive sequence variations have been detected not only between the sequences from St and Y genome, but also among the sequences from diploid St genome species. Phylogenetic analyses separated the Y sequences from the St sequences.

Conclusions/Significance

Our results confirmed that St and Y genome in Elymus species have originated from different donors, and demonstrated that intraspecific variation does not affect the identification of genome origin in polyploids. Moreover, sequence data showed evidence to support the suggestion of the genome convergent evolution in allopolyploid StY genome species.     

Molecular phylogeny of RNA polymerase II gene reveals the relationships of tetraploid species with St genome (Triticeae: Poaceae)

To evaluate phylogeny of tetraploid with St genome, phylogenetic analyses of RNA polymerase II (RPB2), a member of the nuclear gene family encoding the second largest subunit, were performed. Our results showed that: (1) Roegneria magnicaespes and Roegneria alashanica are related to Pseudoroegneria. (2) Roegneria elytrigioides has StStStSt genomes and should therefore be classified as Pseudoroegneria elytrigioides. (3) Pseudoroegneria tauri and Pseudoroegneria deweyi which have StStPP genomes should be transferred to Douglasdeweya and be renamed as Douglasdeweya wangii and Douglasdeweya deweyi, respectively. (4) Pseudoroegneria geniculata ssp. scythica is related to Pseudoroegneria and Lophyrum, and hence should be identified as a species of Trichopyrum. (5) Pseudoroegneria libanotica might be a parental donor for Elytrigia caespitosa rather than Elytrigia caespitosa ssp. nodosa. It is unreasonable to recognize El. caespitosa ssp. nodosa as a subspecies of El. caespitosa. (6) Interspecific and intergeneric variations are detected in St genome of these tetraploid species.     

Phylogeny and maternal donor of Kengyilia (Triticeae: Poaceae) based on chloroplast trnT–trnL sequences

The chloroplast DNA regions trnT–trnL was used to analyze to phylogenetic relationships and maternal donor of Kengyilia species and their closely related species. The Neighbor-Joining phylogenetic reconstructions partitioned the species into two reciprocally monophyletic groups. Kengyilia melanthera was related to species of Agropyron, whereas the other species were related to species of Pseudoroegneria and Roegneria. These results indicate that there have been at least two phylogenetically divergent maternal donors within Kengyilia, i.e. Agropyron (P genome) and Pseudoroegneria (St genome). In addition, the St genome of Kengyilia had several origins and diverse species of Pseudoroegneria might have taken part in the formation of polyploid species of Kengyilia.     

Ecotypic diversity of a dominant grassland species resists exotic invasion

Many species are characterized by high levels of intraspecific or ecotypic diversity, yet we know little about how diversity within species influences ecosystem processes. Using a common garden experiment, we studied how intraspecific diversity within the widespread and often dominant North American native Pseudoroegneria spicata (Pursh) Á. Löve. affected invasion by Centaurea stoebe L. We experimentally manipulated Pseudoroegneria intraspecific diversity by changing the number of Pseudoroegneria ecotypes in common garden plots, using ecotypes collected throughout western North America. Invader biomass was 46% lower in mono-ecotype Pseudoroegneria plots than in control plots without any plants prior to invasion, and plots with 3–12 Pseudoroegneria ecotypes were 44% less invaded by Centaurea than the mono-ecotype plots. Across all plots, the total biomass of invading Centaurea plants was negatively correlated with total Pseudoroegneria biomass, but biotic resistance provided by high ecotypic diversity of Pseudoroegneria was not explained only by the increase in productivity that occurred with ecotypic diversity. Relative to Pseudoroegneria yield, Centaurea yield was lowest when Pseudoroegneria overyielded due to size-independent “complementarity” effects. This was not observed when overyielding was due to size-dependent effects. Our results suggest that the intraspecific diversity of a widespread and dominant species has the potential to impact invasion outcomes beyond its effects on native plant productivity and that mechanisms of biotic resistance to invaders may be to some degree independent of plant size.     

Phylogenetic relationships of species in <Emphasis Type="Italic">Pseudoroegneria</Emphasis> (Poaceae: Triticeae) and related genera inferred from nuclear rDNA ITS (internal transcribed spacer) sequences

To evaluate the phylogenetic relationships of species in Pseudoroegneria and related genera, the nuclear ribosomal internal transcribed spacer (ITS) sequences were analyzed for eighteen Pseudoroegneria (St), two Elytrigia (E ^e St), two Douglasdeweya (StP), three Lophopyrum (E ^e and E ^b ), three Agropyron (P), two Hordeum (H), two Australopyrum (W) and two Psathyrostachys (Ns) accessions. The main results were: (i) Pseudoroegneria gracillima, P. stipifolia, P. cognata and P. strigosa (2x) were in one clade, while P. libanotica, P. tauri and P. spicata (2x) were in the other clade, indicating there are the differentiations of St genome among diploid Pseudoroegneria species; (ii) P. geniculata ssp. scythica, P. geniculata ssp. pruinifera, Elytriga caespitosa and Et. caespitosa ssp. nodosa formed the E ^e St clade with 6-bp indel in ITS1 regions; and (iii) Douglasdeweya wangii, D. deweyi, Agropyron cristatum and A. puberulum comprised the P clade. It is unreasonable to treat P. geniculata ssp. scythica and P. geniculata ssp. pruinifera as the subspecies of P. geniculata, and they should be transferred to a new genus Trichopyrum, which consists of species with E ^e St genomes. It is also suggested that one of the diploid donor of D. wangii and D. deweyi is derived from Agropyron species, and it is reasonable to treat tetraploid species with StP genomes into Douglasdeweya.     

Phylogenetic relationships between Leymus (Poaceae,Triticeae) and related diploid Triticeae species based on isozyme and genome-specific random amplified polymorphic DNA (RAPD) markers

Abstract

To investigate the phylogenetic relationships between Leymus and related diploid species of the Triticeae tribe, the esterase isozyme (EST), superoxide dismutase (SOD) isozymes, and genome-specific random amplified polymorphic DNA (RAPD) markers were used to analyze for 14 Leymus species, together with two Psathyrostachys species (Ns), three Pseudoroegneria species (St), two Hordeum species (H), Lophopyrum elongatum (E^e), Australopyrum retrofractum (W), and Agropyron cristatum (P). The data were used to construct dendrograms by means of UPGMA in the NTSYS-pc computer program. The results suggested that (1) isozyme analysis can be used in the systematic studies of these perennial Triticeae; (2) there is a close relationship between Leymus, Psathyrostachys juncea, three Pseudoroegneria species, and Lophopyrum elongatum; (3) the Ns genome-specific RAPD marker was present in all 14 polyploid species of Leymus, while the E^e and P genome-specific RAPD markers were absent in 14 polyploid species of Leymus; the St, W and H genome-specific RAPD markers were present in some species of Leymus; (4) Leymus species have multiple origins, and different Leymus species derived their genomes from different donors.     

Phylogenetic analysis of the genus Pseudoroegneria and the Triticeae tribe using the rbcL gene

The Pseudoroegneria species are perennial grasses in the Triticeae tribe, whose St genome has been linked to several important polyploid species. Due to frequent hybridization and complex genetic mechanism, the relationships within Pseudoroegneria, and within the Triticeae have been heavily disputed. Using the chloroplast rbcL gene we estimated the nucleotide diversity of 8 Pseudoroegneria species. We also examined the phylogenetic relationships within Pseudoroegneria and of Pseudoroegneria within the Triticeae. The estimates of nucleotide diversity indicated that Pseudoroegneria tauri and Pseudoroegneria spicata species had the highest diversity, while Pseudoroegneria gracillima had the lowest diversity. The phylogenetic analysis of Pseudoroegneria placed all P. spicata species into a clade separate from the other Pseudoroegneria species, while the relationship of the other Pseudoroegneria species could not be determined. Due to the groupings of Pseudoroegneria with the polyploid Elymus, our results strongly supported Pseudoroegneria as the maternal genome donor to Elymus. There was also weak support that P. spicata may be the maternal donor to the StH Elymus species.     

Origin and Reticulate Evolutionary Process of Wheatgrass Elymus trachycaulus (Triticeae: Poaceae)

To study origin and evolutionary dynamics of tetraploid Elymus trachycaulus that has been cytologically defined as containing StH genomes, thirteen accessions of E. trachycaulus were analyzed using two low-copy nuclear gene Pepc (phosphoenolpyruvate carboxylase) and Rpb2 (the second largest subunit of RNA polymerase II), and one chloroplast region trnL–trnF (spacer between the tRNA Leu (UAA) gene and the tRNA-Phe (GAA) gene). Our chloroplast data indicated that Pseudoroegneria (St genome) was the maternal donor of E. trachycaulus. Rpb2 data indicated that the St genome in E. trachycaulus was originated from either P. strigosa, P. stipifolia, P. spicata or P. geniculate. The Hordeum (H genome)-like sequences of E. trachycaulus are polyphyletic in the Pepc tree, suggesting that the H genome in E. trachycaulus was contributed by multiple sources, whether due to multiple origins or introgression resulting from subsequent hybridization. Failure to recovering St copy of Pepc sequence in most accessions of E. trachycaulus might be caused by genome convergent evolution in allopolyploids. Multiple copies of H-like Pepc sequence from each accession with relative large deletions and insertions might be caused by either instability of Pepc sequence in H- genome or incomplete concerted evolution. Our results highlighted complex evolutionary history of E. trachycaulus.     

THE GENOME ORIGIN OF TETRAPLOID SPECIES OF LEYMUS (POACEAE: TRITICEAE) INFERRED FROM VARIATION IN REPEATED NUCLEOTIDE SEQUENCES

To investigate the origin of the tetraploid species of Leymus Hochst., we examined variation in 26 repeated nucleotide sequence families isolated from four species of Triticeae. The genome relationships were determined by calculating repeated nucleotide sequence identity (RSI) between species. RSI is the ratio of the number of diagnostic bands (DBs) and diagnostic hybridization intensities (DIs) in Southern blots of a diploid taxon encountered in a polyploid species divided by the total number of the DBs and DIs of the diploid taxon (DB is a band in Southern blot observed in a single diploid taxon, and DI is the intensity of hybridization higher by at least one order of magnitude in a diploid taxon than in any other diploid taxon). The RSIs of Psathyrostachys Nevski with Leymus ranged from 0.92 to 0.95, which confirmed that the N genome of Psathyrostachys was involved in the phylogeny of Leymus. Since RSIs of other genera of Triticeae with Leymus varied from 0.00 to 0.17, it is unlikely that any of them contributed the second pair of Leymus genomes. RSIs were also calculated between Leymus and the lineage of Lophopyrum Löve-Thinopyrum Löve or the lineage of Lophopyrum-Thinopyrum-Pseudoroegneria (Nevski) Löve-Agropyron Gaertn. The RSIs were close to zero, which made it unlikely that the second pair of Leymus genomes originated from even an extinct species in these major lineages of Triticeae. Several lines of evidence were obtained that indicated that the second pair of Leymus genomes is also from Psalhyrostachys. The genomes of tetraploid species of Leymus were designated N₁N₁N₂N₂, rather than JJNN as proposed by other workers.     

Phylogenetic analysis of questionable tetraploid species in Roegneria and Pseudoroegneria (Poaceae: Triticeae) inferred from a gene encoding plastid acety1-CoA carboxylase

To evaluate the phylogenetic relationships of questionable tetraploid species Roegneria alashanica Keng, Roegneria magnicaespes (D.F. Cui) L.B. Cai, Roegneria elytrigioides C. Yen et J.L. Yang, Roegneria grandis Keng and Pseudoroegneria geniculata (Trin.) Á. Löve, the single copy sequences of the plastid acetyl-CoA carboxylase gene (Acc1) were analyzed among the five species and the related diploid and tetraploid species. The results indicated that: (a) R. alashanica contained one set of modified St genome which was closely related to the E^e genome, and the other set of genome was closely related to the P genome; (b) R. magnicaespes contained one set of St genome, the other set of genome might be closely related to the P genome. There are close affinities between R. magnicaespes and R. alashanica; (c) R. elytrigioides contained two sets of St genomes, and it is reasonable to be treated as Pseudoreogneria elytrigioides (C. Yen et J.L. Yang) B.R. Lu; (d) the genome of R. grandis should be designed as St^gY. The St^g genome was a differentiated form of the St genome in Pseudoroegneria and was homoeologous with the Y genome in Roegneria; (e) the genomic constitution of P. geniculata was similar to that of R. magnicaespes and R. alashanica and distinctly related to P. geniculata ssp. scythica (E^eSt). They should be treated as different species in different genera; and (f) the Y genome was possibly originated from the St genome, and was sister to the St, E^e, E^b and W genomes.     

Reticulate Evolutionary History of a Complex Group of Grasses: Phylogeny of Elymus StStHH Allotetraploids Based on Three Nuclear Genes

Background

Elymus (Poaceae) is a large genus of polyploid species in the wheat tribe Triticeae. It is polyphyletic, exhibiting many distinct allopolyploid genome combinations, and its history might be further complicated by introgression and lineage sorting. We focus on a subset of Elymus species with a tetraploid genome complement derived from Pseudoroegneria (genome St) and Hordeum (H). We confirm the species'' allopolyploidy, identify possible genome donors, and pinpoint instances of apparent introgression or incomplete lineage sorting.

Methodology/Principal Findings

We sequenced portions of three unlinked nuclear genes—phosphoenolpyruvate carboxylase, β-amylase, and granule-bound starch synthase I—from 27 individuals, representing 14 Eurasian and North American StStHH Elymus species. Elymus sequences were combined with existing data from monogenomic representatives of the tribe, and gene trees were estimated separately for each data set using maximum likelihood. Trees were examined for evidence of allopolyploidy and additional reticulate patterns. All trees confirm the StStHH genome configuration of the Elymus species. They suggest that the StStHH group originated in North America, and do not support separate North American and European origins. Our results point to North American Pseudoroegneria and Hordeum species as potential genome donors to Elymus. Diploid P. spicata is a prospective St-genome donor, though conflict among trees involving P. spicata and the Eurasian P. strigosa suggests either introgression of GBSSI sequences from P. strigosa into North American Elymus and Pseudoroegneria, or incomplete lineage sorting of ancestral GBSSI polymorphism. Diploid H. californicum and/or allotetraploid H. jubatum are possible H-genome donors; direct involvement of an allotetraploid Hordeum species would simultaneously introduce two distinct H genomes to Elymus, consistent with some of the relationships among H-genome sequences in Hordeum and Elymus.

Conclusions/Significance

Comparisons among molecular phylogenetic trees confirm allopolyploidy, identify potential genome donors, and highlight cases of apparent introgression or incomplete lineage sorting. The complicated history of this group emphasizes an inherent problem with interpreting conflicts among bifurcating trees—identifying introgression and determining its direction depend on which tree is chosen as a starting point of comparison. In spite of difficulties with interpretation, differences among gene trees allow us to identify reticulate species and develop hypotheses about underlying evolutionary processes.     

Polyploidy origin of wheatgrass Douglasdeweya wangii (Triticeae, Poaceae): evidence from nuclear ribosomal DNA internal transcribed spacer and chloroplast trnL–F sequences

To study hybrid speciation in wheatgrass Douglasdeweya wangii and to investigate the evolutionary pattern of nuclear ribosomal DNA (nrDNA) internal transcribed spacer sequences (ITSs) in allotetraploids, DNA sequence variation of ITSs and chloroplast trnL–F sequences from D. wangii and its putative donors were analyzed. The ITSs revealed that D. wangii had an StP genome composition. Most accessions of D. wangii had one parental ITS copy in their genome, one accession had two parental ITSs. The trnL–F sequences revealed an especially close relationship of Pseudoroegneria to all D. wangii individuals included, and the two accessions of Pseudoroegneria tauri (PI401324 and PI401331) were maternal candidates of the studied D. wangii individuals. Both of ITS and trnL–F trees suggested multiple origins and recurrent hybridization of D. wangii. Thus, the results suggested that: (1) the St and P genome in allotetraploid D. wangii were donated by Pseudoroegneria and Agropyron, respectively;(2) Pseudoroegneria was the maternal donor of D. wangii, and P. tauri 26 (accession PI401324) and P. tauri 27 (accession PI401331) were most likely the potential candidates of maternal donors; (3) D. wangii individuals studied here showed multiple origins and experienced recurrent hybridization; and (4) bidirectional interlocus concerted evolution of ITSs had occurred in most D. wangii accessions, while in one accession concerted evolution among homeologous loci did not occur.     

Genome constitutions of Roegneriaalashanica,R. elytrigioides,R. magnicaespes and R. grandis (Poaceae: Triticeae) via genomic in‐situ hybridization

The genomic constitutions of Roegneria alashanica, R. elytrigioides, R. magnicaespes and R. grandis were studied using GISH. DNA of Pseudoroegneria spicata (St), P. libanotica (St), P. stipifolia (St), R. ciliaris (StY), Lopophyllum elongatum (E^e), Agropyron cristatum (P) and Hordeum bogdanii (H) were used for probing, respectively. The results indicated that: 1) R. alashanica and R. magnicaespes contained one St genome, the other genome was unidentified, however, it was not an E, P, H or Y genome; 2) R. elytrigioides contained two St genomes and should on this basis be included in Pseudoroegneria; 3) R. grandis contained an St and an St^g genome. The St^g genome is suggested to be a modified form of the St genome of Pseudoroegneria and to be homoeologous with the Y genome. It might be an intermediate type between the St and Y genomes. Therefore, R. elytrigioides should be treated as Pseudoroegneriaelytrigioides.Roegneria alashanica, R. magnicaespes and R. grandis does apparently not belong in the genus Roegneria but further studies are needed to establish their correct taxonomic position.     

Phylogeny of the StH genome species in Triticeae (Poaceae): Evidence from chloroplast trnL-F and mitochondria COXII intron sequences

The StH genome species in Triticeae exhibit different morphological variations and extensive geographic distribution. To estimate the phylogenetic relationship of the StH genome species in Triticeae, mitochondria COXII intron and chloroplast trnL-F sequences of 16 StH genome species were analyzed with those of four Pseudoroegneria species (St) and four Hordeum species (H). Sequence diversity and genealogical analysis suggested that (1) the trnL-F and COXII sequence may evolve faster in the polyploid species than in the diploids; (2) the COXII intron has a high evolutionary rate compared to trnL-F sequence and would provide potentially useful phylogenetic analysis in the StH genome species; (3) different Pseudoroegneria species might serve as the maternal donor during the polyploid speciation of the StH genome species; (4) phylogenetic relationships of the StH genome species may be not linked with the inter-continental disjunction between Eurasian and North American.     

Elimination of a tandem repeat of telomeric heterochromatin during the evolution of wheat

 An analysis of accessions of Triticum and Aegilops species (86 diploid, 91 tetraploid and 109 hexaploid) was performed using squash-dot hybridization with the tandem repeat Spelt1 sequence as a probe. The Spelt1 sequence is a highly species-specific repeat associated with the telomeric heterochromatin of Aegilops speltoides Boiss. in which its copy numbers vary from 1.5×10⁵ to 5.3×10⁵. The amounts of Spelt1 are sharply decreased in tetraploid and hexaploid species and vary widely from less than 10² to 1.2×10⁴. Two tetraploid wheats, Triticum timopheevii Zhuk. and T. carthlicum Nevski, are exceptional endemic species and within their restricted geographical distributions maintain the amounts of Spelt1 unaltered. The Spelt1 repetitive sequence was localized on the 6BL chromosome of tetraploid wheat Triticum durum Desf. cv ‘Langdon’ by dot-hybridization using D-genome disomic substitution lines. The possible causes of the loss of the telomere-associated tandem repeat Spelt1 in the process of wheat evolution and polyploidization are discussed. Received: 5 March 1998 / Accepted: 28 May 1998     

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.     

Traits of stem anatomy of some herbaceous members of the family Polygonaceae Juss.

The stem anatomy of the vine Fallopia convolvulus (L.) Á. Löve and that of the self-supporting plant Polygonum patulum M. Bieb. is described. Two groups of tracheary system—few wide elements and many narrow ones—are present in the xylem of the herbaceous vine. The maximum vessel diameters are far greater in Fallopia convolvulus than in Polygonum patulum. Such traits are typical of woody lianas and their self-supporting relatives. The cambium can give rise to wide vessels inward of separate phloem strands in Fallopia convolvulus. The newly formed vessels may substitute for the injured ones. This favors xylem recovery from a drought-induced embolism.     

Isolation and characterization of novel Glu-St1 alleles from Pseudoroegneria spicata and Pd. strigosa

Pseudoroegneria is a small genus of the Triticeae tribe; its St genome is present in over half of allopolyploid Triticeae species. The high molecular weight (HMW) subunits of glutenin (GS) encoded by the St genome are not well described. In this paper, we report the characterization of fourteen alleles of HMW-GS genes from the two species Pd. spicata and Pd. strigosa. Analysis shows that all fourteen sequences possess a typical primary structure shared by other known HMW-GS, but with some unique modifications. All fourteen Glu-St1 alleles are significantly smaller than normal Glu-1 genes due to fewer repeat motifs in a repetitive region with no indication of large deletion in other conserved regions. Thus, the small size is a common feature of HMW-GS encoded by Glu-St1 loci of Pseudoroegneria species. Sequence analysis indicated that all fourteen Glu-St1 alleles were intermediate type between x- and y-type, which represent an intermediate stage in the evolutionary divergence of x- and y-type subunits.