Generation of high frequency of novel alleles of the high molecular weight glutenin in somatic hybridization between bread wheat and tall wheatgrass

Somatic hybridization between bread wheat and tall wheatgrass (Agropyron elongatum) has generated fertile introgression progenies with novel combinations of high molecular weight glutenin subunits (HMW-GS). Most of these novel HMW-GS alleles were stably inherited. Sixteen HMW-GS sequences were PCR amplified from three introgression progeny lines and sequenced. The alignment of these sequences indicated that five, probably derived from point mutations of the parental genes, whereas eight likely represent the product of replication slippage. Three Glu-1Ay sequences appear to have lost the transposon presented in the parental gene. Two subunits carry an additional cysteine residue, which may be favorable to the quality of end-use product. We demonstrate that novel HMW-GS alleles can be rapidly generated via asymmetric somatic hybridization. Heng Liu and Shuwei Liu have contributed equally to the work.     

Molecular characterisation of the low-molecular weight glutenin subunit genes of tall wheatgrass and functional properties of one clone Ee34

Wild tall wheatgrass (Lophopyrum elongatum L., 2x = 14) is an important resource for improving bread wheat (Titicum aestivum L.), including HMW-GS and LMW-GS relevant to end-use quality of the wheat flour. A set of 14 distinct sequences were amplified from the genomic DNA of the tall wheatgrass, using degenerate primers targeted at Glu-3, the locus containing the genes encoding the low-molecular weight glutenin subunits (LMW-GS). Three sequences contained an internal stop codon and were classified as pseudogenes. The other 11 all consisted of a single intron-less intact open-reading frame. An alignment of deduced protein sequences showed that the primary structure of all 11 sequences was similar to that of wheat and other wheat-related grass Glu-3 genes. All 11 sequences carried the 14 amino acid residue N-terminal motif MESNIIISFLK/RPWL, and were classified as LMW-m genes, based on the identity of the first amino acid of the mature protein. All but one of the sequences contained seven cysteine residues (the exception had 6). Their repetitive domain differs significantly from that present in Glu-3 genes isolated from the close relative intermediate wheatgrass (Thinopyrum Intermedium, 6x). A phylogenetic analysis showed that the tall wheatgrass sequences were closely related to those of the intermediate wheatgrass, but only distantly so to those from decaploid tall wheatgrass. One of the 11 LMW-GS peptides with a free-cysteine residue was heterologously expressed in E. coli and purified in sufficient scale to perform a flour supplementation test. This showed that the dough strength of bread wheat flour was significantly increased by the presence of the tall wheatgrass LMW-GS.     

Introgression of bread wheat chromatin into tall wheatgrass via somatic hybridization

Regenerates were obtained following somatic hybridization between tall wheatgrass (Agropyron elongatum) and bread wheat (Triticum aestivum cv. Jinan177) protoplasts. Two lines (CU and XI) were self-fertile in the first (R₀) and subsequent (R₁ and R₂) generations. The phenotype of each R₁ population was uniform. All CU progeny were phenotypically similar to the tall wheatgrass parent, while XI progeny had thinner, smoother and softer leaves. Cytological analysis showed that more wheat chromatin was present in the hybrid callus than in the R₁ and R₂ plants, and that some intercalary translocations of wheat chromosome segments were retained in the R₂ generation. AFLP profiling confirmed the presence of wheat DNA in the introgression lines. Analysis of the high molecular weight glutenin subunit content of derived seed identified three novel subunits, not present in either the wheat or the tall wheatgrass parent. Microsatellite-based profiling of the chloroplast genome of the introgression lines suggested that only chloroplast sequences from the tall wheatgrass parent were present. The specifically inherited phenomena and possible application of these hybrids are discussed. Haifeng Cui and Zhiyong Yu were contributed equally to this article.     

The place of asymmetric somatic hybridization in wheat breeding

Since its first development some 40 years ago, the application of the somatic hybridization technique has generated a body of hybrid plant material involving a wide combination of parental species. Until the late 1990s, the technique was ineffective in wheat, as regeneration from protoplasts was proving difficult to achieve. Since this time, however, a successful somatic hybridization protocol for wheat has been established and used to generate a substantial number of both symmetric and asymmetric somatic hybrids and derived materials, especially involving the parental combination bread wheat and tall wheatgrass (Thinopyrum ponticum). This review describes the current state of the art for somatic hybridization in wheat and focuses on its potential application for wheat improvement.     

The γ-gliadin gene content of a derivative from a somatic hybrid between bread wheat and tall wheatgrass

A PCR-based strategy was applied to obtain the DNA sequence of γ-gliadin open reading frames present in line II-12, a derivative from a somatic hybrid between bread wheat (Triticum aestivum L.) cv. Jinan177 and tall wheatgrass (Lophopyrum ponticum, 10×). A total 50 analysable sequences were obtained, 18 from II-12 and 16 each from the parents. Amplicon length ranged from 720 to 936 bp, corresponding to a putative mature protein of 239–309 residues. The primary structure of these putative proteins comprised five domains, of which only two varied in length. Phylogenetic analyses showed that the mature γ-gliadin sequences fell into four major clades. Group 1 contained sequences shared between II-12 and L. ponticum, suggesting that some L. ponticum γ-gliadin genes are present in the introgression line. Group 3 has five Jinan177 and five II-12 sequences, indicating that II-12 also carries wheat versions of Gli-1. Group 2 and 4 comprised four and two II-12, three and one Jinan177 as well as one and four L. ponticum sequences, respectively. Fewer genes encoding coeliac disease epitopes were present in II-12 than in the wheat donor parent. Three II-12 γ-gliadins and one from the wheat parent contained an odd number of cysteine residues, and two of them had an additional cysteine residue at the amino end of domain V. The possible use of II-2 for improving quality of bread wheat is discussed.     

Development of wheat–<Emphasis Type="Italic">Lophopyrum elongatum</Emphasis> recombinant lines for enhanced sodium ‘exclusion’ during salinity stress

Lophopyrum elongatum (tall wheatgrass), a wild relative of wheat, can be used as a source of novel genes for improving salt tolerance of bread wheat. Sodium ‘exclusion’ is a major physiological mechanism for salt tolerance in a wheat–tall wheatgrass amphiploid, and a large proportion (~50%) for reduced Na⁺ accumulation in the flag leaf, as compared to wheat, was earlier shown to be contributed by genetic effects from substitution of chromosome 3E from tall wheatgrass for wheat chromosomes 3A and 3D. Homoeologous recombination between 3E and wheat chromosomes 3A and 3D was induced using the ph1b mutant, and putative recombinants were identified as having SSR markers specific for tall wheatgrass loci. As many as 14 recombinants with smaller segments of tall wheatgrass chromatin were identified and low-resolution breakpoint analysis was achieved using wheat SSR loci. Seven recombinants were identified to have leaf Na⁺ concentrations similar to those in 3E(3A) or 3E(3D) substitution lines, when grown in 200 mM NaCl in nutrient solution. Phenotypic analysis identified recombinants with introgressions at the distal end on the long arm of homoeologous group 3 chromosomes being responsible for Na⁺ ‘exclusion’. A total of 55 wheat SSR markers mapped to the long arm of homoeologous group 3 markers by genetic and deletion bin mapping were used for high resolution of wheat–tall wheatgrass chromosomal breakpoints in selected recombinants. Molecular marker analysis and genomic in situ hybridisation confirmed the 524-568 recombinant line as containing the smallest introgression of tall wheatgrass chromatin on the distal end of the long arm of wheat chromosome 3A and identified this line as suitable for developing wheat germplasm with Na⁺ ‘exclusion’.     

Homologs of the Genes for Receptor-Like Kinase Proteins Conferring Plant Resistance to Pathogens. Comparative Analysis of the Homologs of the Wheat Gene Cre3in the Triticeae

Direct genomic DNA amplification with the primers recognizing the NBS–kinase sequence of the wheat gene Cre3(Genbank accession AF052641) was used to obtain partial homologs of this gene in perennial and annual rye, wheat, and tall wheatgrass. The nucleotide sequences of the cloned fragments and their deduced amino acid sequences were compared to the already-known Cre3homologs in other wheat, aegilops, and barley genotypes. Within the tribe Triticeae, the extent of homology ranged from 86 to 94% for nucleotide sequences and from 74 to 96% for the deduced amino acid sequences, with the most variable region between Kin3 and PR3 conserved motifs.     

Generation of novel high quality HMW-GS genes in two introgression lines of <Emphasis Type="Italic">Triticum aestivum</Emphasis>/<Emphasis Type="Italic">Agropyron elongatum</Emphasis>

Background  

High molecular weight glutenin subunits (HMW-GS) have been proved to be mostly correlated with the processing quality of common wheat (Triticum aestivum). But wheat cultivars have limited number of high quality HMW-GS. However, novel HMW-GS were found to be present in many wheat asymmetric somatic hybrid introgression lines of common wheat/Agropyron elongatum.     

Russian wheat aphid (Hemiptera: Aphididae) reproduction and development on five noncultivated grass hosts

The Russian wheat aphid, Diuraphis noxia (Kurdjumov), is a small grains pest of worldwide economic importance. The Russian wheat aphid is polyphagous and may encounter differential selective pressures from noncultivated grass hosts. Aphid biotypic diversity can disrupt the progress of plant breeding programs, leading to a decreased ability to manage this pest. The goal of this research was to quantify Russian wheat aphid biotype 2 (RWA2) reproductive and development rates on five common noncultivated grass hosts to gain information about host quality, potential refuges, and sources of selection pressure. First, RWA2 reproduction was compared on crested wheatgrass (Agropyron cristatum, (L.) Gaertn.), intermediate wheatgrass (Elytrigia intermedia, (Host) Nevski), slender wheatgrass (Elymus trachycaulus, (Link) Gould ex Shinners), western wheatgrass (Pascopyrum smithi, (Rydb.) A. L?ve), and foxtail barley (Hordeum jubatum, (L.) Tesky) at 18–24°C. Second, RWA2 reproduction was compared on intermediate and crested wheatgrass at three temperature regimes 13–18°C, 18–24°C, and 24–29°C. At moderate temperatures (18–24°C), the intrinsic rate of increase values for all five hosts ranged from 0.141 to 0.199, indicating the possibility for strong population sources on all tested hosts. Aphids feeding on crested and intermediate wheatgrass at the 13–18°C temperature had lower fecundity, less nymph production days, longer generational times, and lower intrinsic rate of increase than aphids feeding at the 18–24°C temperature regime. Aphids feeding at 24–29°C did not survive long enough to reproduce. The positive intrinsic rates of increase in Russian wheat aphid on the wheatgrasses suggest that these grasses can support aphid populations at moderate to low temperatures.     

Characterizing HMW-GS alleles of decaploid <Emphasis Type="Italic">Agropyron elongatum</Emphasis> in relation to evolution and wheat breeding

Bread wheat quality is mainly correlated with high molecular weight glutenin subunits (HMW-GS) of endosperm. The number of HMW-GS alleles with good processing quality is limited in bread wheat cultivars, while there are plenty of HMW-GS alleles in wheat-related grasses to exploit. We report here on the cloning and characterization of HMW-GS alleles from the decaploid Agropyron elongatum. Eleven novel HMW-GS alleles were cloned from the grass. Of them, five are x-type and six y-type glutenin subunit genes. Three alleles Aex4, Aey7, and Aey9 showed high similarity with another three alleles from the diploid Lophopyrum elongatum, which provided direct evidence for the E^e genome origination of A. elongatum. It was noted that C-terminal regions of three alleles of the y-type genes Aey8, Aey9, and Aey10 showed more similarity with x-type genes than with other y-type genes. This demonstrates that there is a kind of intermediate state that appeared in the divergence between x- and y-type genes in the HMW-GS evolution. One x-type subunit, Aex4, with an additional cysteine residue, was speculated to be correlated with the good processing quality of wheat introgression lines. Aey4 was deduced to be a chimeric gene from the recombination between another two genes. How the HMW-GS genes of A. elongatum may contribute to the improvement of wheat processing quality are discussed.     

Intergeneric somatic hybridization in Gramineae: somatic hybrid plants between tall fescue (Festuca arundinacea Schreb.) and Italian ryegrass (Lolium multiflorum Lam.)

Summary Tall fescue (Festuca arundinacea Schreb.) protoplasts, inactivated by iodoacetamide, and non-morphogenic Italian ryegrass (Lolium multiflorum Lam.) protoplasts, both derived from suspension cultures, were electrofused and putative somatic hybrid plants were recovered. Two different genotypic fusion combinations were carried out and several green plants were regenerated in one of them. With respect to plant habitus, leaf and inflorescence morphology, the regenerants had phenotypes intermediate between those of the parents. Southern hybridization analysis using a rice ribosomal DNA probe revealed that the regenerants contained both tall fescue- and Italian ryegrass-specific-DNA fragments. A cloned Italian ryegrass-specific interspersed DNA probe hybridized to total genomic DNA from Italian ryegrass and from the green regenerated somatic hybrid plants but not to tall fescue. Chromosome counts and zymograms of leaf esterases suggested nuclear genome instability of the somatic hybrid plants analyzed. Four mitochondrial probes and one chloroplast DNA probe were used in Southern hybridization experiments to analyze the organellar composition of the somatic hybrids obtained. The somatic hybrid plants analyzed showed tall fescue, additive or novel mtDNA patterns when hybridized with different mitochondrial gene-specific probes, while corresponding analysis using a chloroplast gene-specific probe revealed in all cases the tall fescue hybridization profile. Independently regenerated F. arundinacea (+) L. multiflorum somatic hybrid plants were successfully transferred to soil and grown to maturity, representing the first flowering intergeneric somatic hybrids recovered in Gramineae.     

A new α-gliadin gene family for wheat breeding: somatic introgression line II-12 derived from <Emphasis Type="Italic">Triticum aestivum</Emphasis> and <Emphasis Type="Italic">Agropyron elongatum</Emphasis>

Ninety-five α-gliadin open reading frames were cloned and sequenced from the somatic hybrid wheat introgression line II-12 and its parents Triticum aestivum cv. Jinan177 (JN177) and Agropyron elongatum. Novel α-gliadin genes were found to originate via point mutation, unequal crossover or slippage of a parental gene, demonstrating that new genes could be rapidly created through somatic hybridization in a manner similar to that previously shown for high-molecular-weight glutenin subunits (HMW-GS) genes. The data reveal the composition and origin of the α-gliadin gene in II-12, showing that: (1) most were homologous to those of JN177; (2) a few were derived direct from A. elongatum; and (3) some new genes were created de novo. A particular quality attribute of interest was the presence or absence of celiac disease (CD) epitopes, which were found to be four times more common among α-gliadin genes from the parent wheat JN177 than in those from A. elongatum. Although four types of CD epitopes were found in introgression line II-12, the number of genes encoded CD epitopes was lower than in JN177 due to the occurrence of pseudogenes. We discuss the benefit of these α-gliadins to wheat breeding. Fanguo Chen, Chunhui Xu, and Mengzhu Chen contributed equally to this work.     

Intragenomic diversity and phylogenetic systematics of wild rosemaries (Rosmarinus officinalis L. s.l., Lamiaceae) assessed by nuclear ribosomal DNA sequences (ITS)

Nuclear ribosomal sequences (ITS) were used to study species boundaries and to infer phylogenetic patterns in wild rosemaries (Rosmarinus officinalis, R. eriocalyx, R. tomentosus). Intragenomic polymorphisms (overlapping peaks and in some cases unreadable sequences) were found throughout the sequencing electrophoretograms of most Rosmarinus accessions. Sequencing the cloned ITS products from representative individuals resulted in 25 ribotypes differing at 59 variable sites. Average sequence divergence among clones was 1.75%, and the most divergent sequences differed by 3.48%. No single ribotype was shared between any two-paired species. The highest values of intragenomic divergence were similar in R. officinalis (1.63%) and R. eriocalyx (1.14%–2.12%), and contrast with those shown by R. tomentosus (0.97%). Sequence data suggest that most divergent rDNA sequences within individuals belong to paralogous loci that apparently are not pseudogenes. A detailed inspection of direct and cloned sequences does not show evidence that the intragenomic polymorphism found is due to interspecific hybridization. Phylogenetic analyses of cloned sequences suggested that both R. officinalis and R. tomentosus were monophyletic, whereas R. tomentosus clones were nested within a paraphyletic R. eriocalyx.     

Establishment of a plant regeneration system for wheatgrasses (Thinopyrum,Agropyron and Pascopyrum)

Wheatgrasses (Thinopyrum, Agropyron and Pascopyrum spp.) are a ubiquitous group of cool-season grasses used throughout much of the semiarid temperate world. In order to explore the potential of biotechnology to accelerate conventional breeding efforts, we developed an efficient plant regeneration system for different wheatgrass species: tall wheatgrass [Thinopyrum ponticum (Podp.) Liu and Wang], intermediate and pubescent wheatgrass [Thinopyrum intermedium (Host) Barkw. and D.R. Dewey], crested wheatgrass [Agropyron cristatum (L.) Gaertner], and western wheatgrass [Pascopyrum smithii (Rydb.) Löve]. Embryogenic callus was induced from mature and immature embryos and immature inflorescence with an induction frequency in the range of 0.5–8.3% for the different wheatgrass species tested. Individual embryogenic calluses were then used to establish single genotype-derived suspension cultures. Efficient plant regeneration was achieved from the established em-bryogenic suspensions with regeneration frequencies in the range of 20–65% for tall wheatgrass, 21–40% for intermediate and pubescent wheatgrasses, 32–51% for crested wheatgrass, and 25–48% for western wheatgrass. The cell suspension-derived wheatgrass plants were fertile and phenotypically normal in the field. The efficient plant regeneration system provides a solid basis for genetic transformation of wheatgrasses.     

Fertile introgression products generated via somatic hybridization between wheat and Thinopyrum intermedium

Key message

Fertile hybrids were produced with genetic material transferred from Th. intermedium into a wheat background and supply a source of genetic variation to wheat improvement.

Abstract

Both symmetric and asymmetric somatic hybrids have been obtained from the combination of wheatgrass (Thinopyrum intermedium) and bread wheat (Triticum aestivum). Two wheat protoplast populations, one derived from embryogenic calli and the other from a non-regenerable, rapidly dividing cell line, were fused with Th. intermedium protoplasts which had been (or not been) pre-irradiated with UV. Among the 124 regenerated calli, 64 could be categorized as being of hybrid origin on the basis of plant morphology, peroxidase isozyme, RAPD DNA profiling and karyological analysis. Numerous green plantlets were regenerated from 13 calli recovered from either the symmetric hybrid (no UV pre-treatment) or the asymmetric one (30 s UV irradiation). One of these hybrid plants proved to be vigorous and self-fertile. The regenerants were all closer in phenotype to wheat than to Th. intermedium. Genomic in situ hybridization analysis showed that the chromosomes in the hybrids were largely intact wheat ones, although a few Th. intermedium chromosome fragments had been incorporated within them.     

Naturally occurring phenanthrene degrading bacteria associated with seeds of various plant species

Seeds of 11 of 19 plant species tested yielded naturally occurring phenanthrene degrading bacteria when placed on phenanthrene impression plates. Seed associated phenanthrene degrading bacteria were mostly detected on caragana, Canada thistle, creeping red fescue, western wheatgrass, and tall wheat grass. Based on 16S rRNA analysis the most common bacteria isolated from these seeds were strains belonging to the genera Enterobacteria, Erwinia, Burkholderia, Pantoea, Pseudomonas, and Sphingomonas. These plants may provide an excellent source of pre-adapted bacterial-plant associations highly suitable for use in remediation of contaminated soil environments.     

Modification of the salinity response of wheat by the genome ofElytrigia elongatum

Summary Triticum aestivum cv. Chinese Spring wheat,Elytrigia elongatum (tall wheatgrass), and theTriticum-Elytrigia amphiploid were grown in complete nutrient culture containing, in addition, 0, 40, 80 and 120 mM NaCl. The 3 genotypes responded quite differently to increasing salinity; the Na concentration of wheat shoots increased in direct proportion to the increase in salinity of the external medium whereas the Elytrigia response was interpreted as showing high affinity for Na at low external Na (40 mM) but comparative exclusion of Na at high salinities (120 mM). In contrast, Na levels of the amphiploid were less than those of either wheat or Elytrigia under both low and high salinities. Thus the amphiploid behaved like wheat at 40 mM NaCl but more like Elytrigia at 120 mM NaCl because Na transport to the amphiploid shoot was restricted over the whole salinity range. The K concentration of the amphiploid shoot at high salinities was significantly greater than the K concentrations of either wheat or Elytrigia.     

Isolation,characterization and application of a species-specific repeated sequence from Haynaldia villosa

A species-specific repeated sequence, pHvNAU62, was cloned from Haynaldia villosa, a wheat relative of great importance. It strongly hybridized to H. villosa, but not to wheat. In situ hybridization localized this sequence to six of seven H. villosa chromosome pairs in telomeric or sub-telomeric regions. Southern hybridization to whea-H. villosa addition lines showed that chromosomes 1V through 6V gave strong signals in ladders while chromosome 7V escaped detection. In addition to H. villosa, several Triticeae species were identified for a high abundance of the pHvNAU62 repeated sequence, among which Thinopyrum bassarabicum and Leymus racemosus produced the strongest signals. Sequence analysis indicated that the cloned fragment was 292 bp long, being AT rich (61%), and showed 67% homology of pSc7235, a rye repeated sequence. Isochizomer analysis suggested that the present repeated sequence was heavily methylated at the cytosine of the CpG dimer in the genome of H. villosa.It was also demonstrated that pHvNAU62 is useful in tagging the introduced 6VS chromosome arm, which confers a resistance gene to wheat powdery mildew, in the segregating generations.