Floral inhibition in red fescue (Festuca rubra L.) through expression of a heterologous flowering repressor from Lolium

Extension of the vegetative growth phase through delay of flowering is an important goal in today's breeding programs of both forage and turf grasses. In forage grasses, the stem and inflorescence production comprise a significant reduction in the digestibility, nutritional value and productivity of the crop, and in turf grasses the stems that start to emerge during the growth season suppress the formation of new shoots and affect the quality, density and persistence of the sward. We have tested the potential of the strong floral repressor LpTFL1 from perennial ryegrass (Lolium perenne L.) to manipulate the transition to flowering in red fescue (Festuca rubra L.), a cool-season turf grass. Expression of LpTFL1 from the constitutive maize ubiquitin promoter represses flowering in red fescue, and the flowering repression phenotype correlates well with the level of LpTFL expression. Transgenic lines showing low to intermediate expression of LpTFL1 flowered approximately two weeks later than the controls, and transgenic lines showing very high LpTFL1 expression levels still remained non-flowering after exposure to natural vernalization conditions (Danish winter) in two successive years. There were no other phenotypic effects associated with the LpTFL transgene expression during vegetative growth. However, there was a tendency towards an LpTFL1-mediated reduction in stem length among the flowering lines. Expression of a truncated LpTFL, caused by transgene rearrangements during the transformation, lead to increased flowering and stem production and a decrease in panicle size. This is to our knowledge the first report on full inhibition of floral development in a commercially important grass species.     

Short-day and Low-temperature Induction in Lolium

The requirements for floral induction of several outbreedingpopulations of Lolium perenne, L. multiflorum, and L. rigidumhave been studied. Floral induction can be brought about byeither low temperature (0–30° C.) or short day (8hr.) independently, but short day is ineffective at low temperatures. The exact inductive requirement varies with the population.The summerannual Westerwolds ryegrass needs neither cold norshort day, the winter-annual Wimmera ryegrass shows a quantitativeresponse, while the perennial varieties from north-west Europehave an obligatory requirement for either cold or short daybefore floral induction. This relation between the annual orperennial habit and the inductive requirement was confirmedin a number of Mediterranean collections of L. perenne and L.rigidum. Considerable genetic variation in inductive requirement couldbe detected within each outbreeding population, and rapid responseto selection proved possible in Wimmera, Irish, and Kent ryegrass.     

Stable transformation and long-term expression of the gusA reporter gene in callus lines of perennial ryegrass (Lolium perenne L.)

Stable transformation of perennial ryegrass (Lolium perenne L.) was achieved by biolistic bombardment of a non embryogenic cell suspension culture, using the hpt and gusA gene. The transformation yielded on the average 5 callus lines per bombardment (1.4×10⁶ cells). Stable integration of the genes into the plant genome was demonstrated by Southern analysis of DNA, isolated from hygromycin-resistant callus lines. The gusA reporter gene, which was regulated by the constitutive promoter of the rice gene GOS2, was expressed in both transient and stable transformation assays, indicating that this promoter is suitable for expression of a transferred gene in perennial ryegrass. Long-term GUS expression was observed in ca. 40% of the callus lines, whereas the other callus lines showed instability after 6 months and 1 year of culture.     

Generation of large numbers of independently transformed fertile perennial ryegrass (Lolium perenne L.) plants of forage- and turf-type cultivars

Perennial ryegrass (Lolium perenne L.) is the most important grass species in areas with a temperate climate. Biolistic transfer of a ubiquitin promoter driven nptII expression cassette into mature or immature tissue derived calli of perennial ryegrass followed by paromomycin selection, resulted in the rapid and efficient production of fertile transgenic ryegrass plants. Transformation efficiencies after paromomycin selection in combination with the nptII selectable marker compared favourably with hygromycin selection in combination with the hph selectable marker. In total 83 independent nptII expressing plants were produced. Transformation frequency was highly affected by genotype, explant, selection regime and the duration of the callus induction period. The optimised transformation protocol for mature embryo derived calli of turf-type or forage-type cultivars resulted in an average transformation efficiency of 5.2% or 6.6% respectively. This converts into 1.7 or 2.2 independent transgenic plants per bombardment. Immature inflorescence- and immature embryo-derived calli were also successfully used as target for the gene transfer, resulting in transformation efficiencies of up to 3.7% or 11.42% respectively. Transgenic plants were transferred to soil 12 or 9 weeks after excision of mature and immature embryos or inflorescences respectively. Transgene integration and expression were confirmed by PCR and ELISA or western blot analysis. Southern blot analysis confirmed the independent nature of the transgenic lines. The majority of lines showed the integration of two to six transgene copies, while 21% of the analysed lines had a single copy insert. A short tissue culture period in comparison to recently published reports seems to be beneficial for the production of normal and fertile transgenic ryegrass plants. Consequently we report for the first time molecular evidence for sexual transgene transmission in fertile transgenic perennial ryegrass.     

A novel DNA-based diagnostic test for the detection of annual and intermediate ryegrass contamination in perennial ryegrass

Perennial ryegrass (Lolium perenne L.) is a preferred choice for the turf grass industry due to its ability to provide a durable turf cover. Genetic or physical contamination of annual (L. multiflorum Lam.) or intermediate (L. hybridum) ryegrass species in perennial ryegrass is one of the major problems affecting the grass seed industry. At present, seedling root fluorescence (SRF), a biochemical marker, is used for the detection of annual ryegrass contamination. Due to the unreliability of the SRF test, the seed industry is seeking an alternative, more reliable and accurate detection method. Currently, there are no DNA tests available in ryegrass for detecting contamination with annual and intermediate ryegrass types. We developed a novel quantitative polymerase chain reaction (Q-PCR)-based DNA test for the detection of annual and/or intermediate ryegrass types in perennial ryegrass. This DNA test was designed using an insertion/deletion (InDel) site in the LpVRN2_2 (Vernalization 2) gene, which is one of the several genes controlling vernalization in ryegrass. The new DNA test is more reliable, accurate and cost-effective in detecting contamination, with a high sensitivity of 0.04% in a sample size of 5,000 seeds. Use of larger sample sizes (12.5-fold higher compared to SRF test) provided additional accuracy in detecting the level of contamination. The method has produced consistent results in 68 perennial, 26 annual and 14 intermediate ryegrass lines.     

Synteny between a major heading-date QTL in perennial ryegrass (<Emphasis Type="Italic">Lolium perenne</Emphasis> L.) and the<Emphasis Type="Italic"> Hd3</Emphasis> heading-date locus in rice

The genetic control of induction to flowering has been studied extensively in both model and crop species because of its fundamental biological and economic significance. An ultimate aim of many of these studies has been the application of the understanding of control of flowering that can be gained from the study of model species, to the improvement of crop species. The present study identifies a region of genetic synteny between rice and Lolium perenne, which contains the Hd3 heading-date QTL in rice and a major QTL, accounting for up to 70% of the variance associated with heading date in L. perenne. The identification of synteny between rice and L. perenne in this region demonstrates the direct applicability of the rice genome to the understanding of biological processes in other species. Specifically, this syntenic relationship will greatly facilitate the genetic dissection of aspects of heading-date induction by enabling the magnitude of the genetic component of the heading-date QTL in L. perenne to be combined with the sequencing and annotation information from the rice genome.Communicated by Q. Zhang     

Allelopathic potential of vegetative and flowering ragwort (Senecio jacobaea L.) plants against associated pasture species

The allelopathic effects of vegetative and flowering plants of the annual/biennial pasture weed Senecio jacobaea L. (ragwort) against Lolium perenne L. (perennial ryegrass) and four pasture legumes were investigated using a range of bioassays. Bioassays based on shoot and root leachates demonstrated detectable, although usually slight, allelopathic effects, and these did not usually differ between the two developmental stages of S. jacobaea. However, aqueous extract and tissue decomposition bioassays demonstrated stronger allelopathic effects, particularly for flowering plants, and this was in general agreement with toxicity assessments of soil collected from under S. jacobaea plants in the field. According to our study, flowering plants have the potential to weaken pasture through allelopathy, and decomposition of above-ground litter appears as the most likely mechanism facilitating this. The aqueous extract and tissue decomposition bioassays also revealed that L. perenne was less susceptible to S. jacobaea allelopathy than were the legumes, suggesting that encouraging a strong L. perenne component in pastures has potential for reducing the overall inhibitory ef S. jacobaea on pasture production.     

Molecular cloning and genetic mapping of perennial ryegrass casein protein kinase 2 α-subunit genes

The α-subunit of the casein protein kinase CK2 has been implicated in both light-regulated and circadian rhythm-controlled plant gene expression, including control of the flowering time. Two putative CK2α genes of perennial ryegrass (Lolium perenne L.) have been obtained from a cDNA library constructed with mRNA isolated from cold-acclimated crown tissue. The genomic organisation of the two genes was determined by Southern hybridisation analysis. Primer designs to the Lpck2a-1 and Lpck2a-2 cDNA sequences permitted the amplification of genomic products containing large intron sequences. Amplicon sequence analysis detected single nucleotide polymorphisms (SNPs) within the p150/112 reference mapping population. Validated SNPs, within diagnostic restriction enzyme sites, were used to design cleaved amplified polymorphic sequence (CAPS) assays. The Lpck2a-1 CAPS marker was assigned to perennial ryegrass linkage group (LG) 4 and the Lpck2a-2 CAPS marker was assigned to LG2. The location of the Lpck2a-1 gene locus supports the previous conclusion of conserved synteny between perennial ryegrass LG4, the Triticeae homoeologous group 5L chromosomes and the corresponding segment of rice chromosome 3. Allelic variation at the Lpck2a-1 and Lpck2a-2 gene loci was correlated with phenotypic variation for heading date and winter survival, respectively. SNP polymorphism may be used for the further study of the role of CK2α genes in the initiation of reproductive development and winter hardiness in grasses.     

Control of floral transition in the bioenergy crop switchgrass

Switchgrass (Panicum virgatum L.), a perennial warm season bunchgrass native to North America, has been a target in the U.S. as a renewable bioenergy crop because of its ability to produce moderate to high biomass yield on marginal soils. Delaying flowering can increase vegetative biomass production by allowing prolonged growth before switching to the reproductive phase. Despite the identification of flowering time as a biomass trait in switchgrass, the molecular regulatory factors involved in controlling floral transition are poorly understood. Here we identified PvFT1, PvAPL1‐3 and PvSL1, 2 as key flowering regulators required from floral transition initiation to development of floral organs. PvFT1 expression in leaves is developmentally regulated peaking at the time of floral transition, and diurnally regulated with peak at approximately 2 h into the dark period. Ectopic expression of PvFT1 in Arabidopsis, Brachypodium and switchgrass led to extremely early flowering, and activation of FT downstream target genes, confirming that it is a strong activator of flowering in switchgrass. Ectopic expression of PvAPL1‐3 and PvSL1, 2 in Arabidopsis also activated early flowering with distinct floral organ phenotypes. Our results suggest that switchgrass has conserved flowering pathway regulators similar to Arabidopsis and rice.     

The Effect of Shading During Vegetative and Reproductive Growth on the Photosynthetic Capacity of Leaves in a Grass Sward

The decline in photosynthetic capacity of successive newly expandedleaves, which occurs as a vegetative grass sward increases inleaf area, was prevented in a field sward of S24 perennial ryegrass(Lolium perenne L.) by protecting tillers from shading by theirneighbours. This adds support for the view that the declineis caused by the shading of leaves during their expansion. However, in a flowering sward where there is no such decline,the photosynthetic capacity of leaves was not reduced by shadingthem with a plastic mesh during expansion, although it was bypegging down tillers so that they developed at the bottom ofthe sward. Lolium perenne, perennial rye-grass, photosynthetic capacity, growth, shading     

Infection Biology of Bacterial Wilt of Forage Grasses

Infection of perennial ryegrass (Lolium perenne L.), Italian ryegrass (Loliummultiflorum L.), and timothy (Phleum pratense L.) by Xanthomonas campestris pv. graminis and Xanthomonas campestris pv. phlei occurred mainly via wounds rather than natural openings. Nevertheless, bacteria were detected by isolation and immunofluorescence in plants sprayed with the pathogen without prior wounding and in plants in which intact ears had been dipped in inocula. High concentrations of bacteria were observed around the stomata of perennial ryegrass and timothy by scanning electron microscopy 48 h after inoculation. Perennial ryegrass and Italian ryegrass and individual plants of ryegrass and timothy differedin susceptibility to the pathogens.     

Genetic linkage mapping of an annual × perennial ryegrass population

Annual (Lolium multiflorum Lam.) and perennial (L. perenne L.) ryegrass are two common forage and turfgrass species grown throughout the world. Perennial ryegrass is most commonly used for turfgrass purposes, and contamination by annual ryegrass, through physical seed mixing or gene flow, can result in a significant reduction in turfgrass quality. Seed certifying agencies in the United States currently use a test called seedling root fluorescence (SRF) to detect contamination between these species. The SRF test, however, can be inaccurate and therefore, the development of additional markers for species separation is needed. Male and female molecular-marker linkage maps of an interspecific annual × perennial ryegrass mapping population were developed to determine the map location of the SRF character and to identify additional genomic regions useful for species separation. A total of 235 AFLP markers, 81 RAPD markers, 16 comparative grass RFLPs, 106 SSR markers, 2 isozyme loci and 2 morphological characteristics, 8-h flowering, and SRF were used to construct the maps. RFLP markers from oat and barley and SSR markers from tall fescue and other grasses allowed the linkage groups to be numbered, relative to the Triticeae and the International Lolium Genome Initative reference population P150/112. The three-generation population structure allowed both male and female maps to be constructed. The male and female maps each have seven linkage groups, but differ in map length with the male map being 537 cm long and the female map 712 cm long. Regions of skewed segregation were identified in both maps with linkage groups 1, 3, and 6 of the male map showing the highest percentage of skewed markers. The (SRF) character mapped to linkage group 1 in both the male and female maps, and the 8-h flowering character was also localized to this linkage group on the female map. In addition, the Sod-1 isozyme marker, which can separate annual and perennial ryegrasses, mapped to linkage group 7. These results indicate that Lolium linkage groups 1 and 7 may provide additional markers and candidate genes for use in ryegrass species separation.Communicated by C. Möllers     

Flowering of S. 24 Perennial Ryegrass (Lolium perenne L.) in Short Days at Low Temperature

The flowering of the quantitative long-day plant perennial ryegrass(Lolium perenne L.) in short days (8 h), when grown at low temperature(9/4 °C) and under natural summer daylight, is presentedas evidence for the replacement of specific environmental requirementsfor flowering by alternative stimuli in a grass.     

Expressed sequence tag-derived microsatellite markers of perennial ryegrass (Lolium perenne L.)

An expressed sequence tag (EST) library of the key grassland species perennial ryegrass (Lolium perenne L.) has been exploited as a resource for microsatellite marker development. Out of 955 simple sequence repeat (SSR) containing ESTs, 744 were used for primer design. Primer amplification was tested in eight genotypes of L. perenne and L. multiflorum representing (grand-) parents of four mapping populations and resulted in 464 successfully amplified EST-SSRs. Three hundred and six primer pairs successfully amplified products in the mapping population VrnA derived from two of the eight genotypes included in the original screening and revealed SSR polymorphisms for 143 ESTs. Here, we report on 464 EST-derived SSR primer sequences of perennial ryegrass established in laboratory assays, providing a dedicated tool for marker assisted breeding and comparative mapping within and among forage and turf grasses. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Induced systemic resistance responses in perennial ryegrass against Magnaporthe oryzae elicited by semi‐purified surfactin lipopeptides and live cells of Bacillus amyloliquefaciens

The suppressive ability of several strains of cyclic lipopeptide‐producing Bacillus rhizobacteria to grey leaf spot disease caused by Magnaporthe oryzae has been documented previously; however, the underlying mechanism(s) involved in the induced systemic resistance (ISR) activity in perennial ryegrass (Lolium perenne L.) remains unknown. Root‐drench application of solid‐phase extraction (SPE)‐enriched surfactin and live cells of mutant Bacillus amyloliquefaciens strain FZB42‐AK3 (produces surfactin, but not bacillomycin D and fengycin) significantly reduced disease incidence and severity on perennial ryegrass. The application of the treatments revealed a pronounced multilayered ISR defence response activation via timely and enhanced accumulation of hydrogen peroxide (H₂O₂), elevated cell wall/apoplastic peroxidase activity, and deposition of callose and phenolic/polyphenolic compounds underneath the fungal appressoria in naïve leaves, which was significantly more intense in treated plants than in mock‐treated controls. Moreover, a hypersensitive response (HR)‐type reaction and enhanced expression of LpPrx (Prx, peroxidase), LpOXO4 (OXO, oxalate oxidase), LpPAL (PAL, phenylalanine ammonia lyase), LpLOXa (LOX, lipoxygenase), LpTHb (putative defensin) and LpDEFa (DEFa, putative defensin) in perennial ryegrass were associated with SPE‐enriched surfactin and live AK3 cell treatments, acting as a second layer of defence when pre‐invasive defence responses failed. The results indicate that ISR activity following surfactin perception may sensitize H₂O₂‐mediated defence responses, thereby providing perennial ryegrass with enhanced protection against M. oryzae.     

Isolation and characterization of cold-regulated transcriptional activator <Emphasis Type="Italic">LpCBF3</Emphasis> gene from perennial ryegrass (<Emphasis Type="Italic">Lolium perenne</Emphasis> L.)

In plants, low temperatures can activate the CBF cold response pathway playing a prominent role in cold acclimation by triggering a set of cold-related gene expressions. CBF homologous gene, designated as LpCBF3, from a cold-tolerant perennial ryegrass (Lolium perenne L.) accession was identified. It carries the sequences for nuclear localization signal (NLS), AP2 DNA-binding domains and an acidic activation present in most of the plant CBF proteins. Southern analysis indicated the presence of three homologs of LpCBF3 gene in perennial ryegrass genome, and only one amino acid variation in LpCBF3 protein between cold-tolerant and -sensitive perennial ryegrass accessions. In their putative promoter regions, some differential regions were found. Northern blotting and RT-PCR analysis found that LpCBF3 reached the highest expression after 1.5 h of cold treatment (4 degrees C). The COR homologous gene, a downstream gene of CBF, can be expressed in the plant stem of cold-tolerant perennial ryegrass accessions without cold treatment. Without cold treatment, the COR gene cannot be activated in cold-sensitive perennial ryegrass accessions. Cold treatment can prompt expression levels of COR homologous genes in both perennial ryegrass accessions. In transgenic Arabidopsis, the overexpression of LpCBF3 with the 35S promoter resulted in dwarf-like plants, later flowering and greater freezing tolerance.