Studies on the Host Range,Biology, and Pathogenicity of Punctodera punctata Infecting Turfgrasses

Punctodera punctata completed its life cycle on Poa annua (annual bluegrass), P. pratensis (Merion Kentucky bluegrass), Lolium perenne (perennial ryegrass), and Festuca rubra rubra (spreading fescue). Minimum time for completion of a life cycle from second-stage juvenile to mature brown cyst was 40 days at 22-28 C. Inoculation by single juveniles indicated that reproduction was most likely by amphimixis. Infestation levels of 50 or 500 juveniles/250 cm³ soil did not affect top dry weight, root dry weight, or total dry weight of Poa annua.     

Physiological mechanism of hypertolerance of cadmium in Kentucky bluegrass and tall fescue: Chemical forms and tissue distribution

Kentucky bluegrass (Poa pratensis) and tall fescue (Festuca arundinacea) are hypertolerant grasses to soil cadmium contamination. Little information is available on their tolerance mechanism. A sand culture and a hydroponic culture experiment were designed to investigate the Cd chemical form changes and its translocation in different tissues. The results showed that Kentucky bluegrass and tall fescue can tolerate 50–200 mg kg⁻¹ of soil Cd stresses and accumulate as high as 4275 and 2559 mg Cd kg⁻¹ DW, respectively, in their shoots without the loss of shoot biomass. Their Cd hypertolerance was correlated with an increase of the undissolved Cd phosphates in the leaves in both grass species, as determined by sequential solvent extraction procedures. The superior Cd tolerance of tall fescue to Kentucky bluegrass was associated with less Cd translocation into the stele of roots and less Cd transported to leaves. The pectate- and protein-integrated Cd forms may be involved in the symplastic translocation of Cd from cortex into stele, and this may lead the higher Cd concentrations in the stele of roots and then above ground leaves via long-distance transport in Kentucky bluegrass.     

Identification of Apomixis in the Kentucky Bluegrass (Poa pratensisL.) Using SDS-PAGE of Endosperm Storage Proteins

To determine the characteristics of seed reproduction in the Kentucky bluegrass (Poa pratensisL.), individual seed variability with respect to the composition of endosperm storage proteins was studied. Comparative analysis of caryopses obtained by self-fertilization and free fertilization of plants I ₁ (no. 2-4) and I ₂ (no. 2-4-7) of the wild-type specimen Murmanskii 95 was performed by means of SDS-PAGE. Using a cytoembryological express method, we demonstrated that facultative stimulation-autonomous apomeiotic apomixis, along with the formation of meiotic megasporocytes, is characteristic of the Kentucky bluegrass. This method made it possible to determine the consequences of meiotic processes in the maternal plant and to reveal the hybrid nature of seed endosperm.     

Role of exogenous salicylic acid in alleviating cadmium-induced toxicity in Kentucky bluegrass

To understand the role of salicylic acid (SA) in alleviating cadmium (Cd) toxicity in Kentucky bluegrass (Poa pratensis L.), we investigated the changes of biochemical and physiological indexes in five-week-old Kentucky bluegrass seedlings exposed to 0, 5, 10 or 50 μM Cd with or without 500 μM SA for 7 d. Results showed that, compared to the Cd treatment applied alone, 500 μM SA pretreatment significantly decreased Cd accumulations and increased the chlorophyll level, growth and nutrient elements content (K, Ca, Mg and Fe) in plants, accompanying with the reduction in malondialdehyde and hydrogen peroxide contents. Furthermore, SA pretreatment enhanced remarkably the superoxide dismutase, ascorbate peroxidase and peroxidase activity in the Cd-stressed plants, but decreased catalase activity. Overall, SA might regulate the antioxidant defense activities, reduce Cd uptake and stimulate nutrient elements absorption in Cd-treated with Kentucky bluegrass, thereby improving its resistance to Cd stress.     

<Emphasis Type="Italic">Agrobacterium</Emphasis>-mediated transformation of shoot apices of Kentucky bluegrass (<Emphasis Type="Italic">Poa pratensis</Emphasis> L.) and production of transgenic plants carrying a <Emphasis Type="Italic">betA</Emphasis> gene

Apical meristems of multiple shoots produced from axenic seedlings of Kentucky bluegrass (Poa pratensis L.) were used for Agrobacterium tumefaciens-mediated transformation. Transformation parameters were optimized for concentration of bacterial cells, duration of infection, and vacuum infiltration. The highest transformation frequency (1.42%) was obtained by infection with Agrobacterium suspension of OD₆₀₀ = 0.6 for 5 min, under a negative pressure of 0.5 × 10⁵ Pa. After co-cultivation, the herbicide-resistant plants were rooted and transplanted into flowerpots. Transgenic plants were confirmed by polymerase chain reaction (PCR) assay and Southern blot analysis. Using this transformation system, the betA gene encoding choline dehydrogenase and mutant als gene encoding the enzyme acetolactate synthase were introduced into three Kentucky bluegrass cultivars.     

Festuca campestris density and defoliation regulate abundance of the rhizomatous grass Poa pratensis in a fallow field

Invasion by the rhizomatous grass Kentucky bluegrass (Poa pratensis) is a global phenomenon, including into foothills rough fescue (Festuca campestris) grasslands of southwestern Alberta, Canada. In order to better understand the competitive relationships between these species, we conducted a fallow field study where rough fescue bunchgrass tussocks were transplanted at one of three planting densities (15, 30, or 45 cm spacing), and then subject to various treatments in a factorial design, including one‐time intensive summer defoliation and seeding of bluegrass into adjacent bare soil. Rough fescue plants exhibited marked intraspecific competition, as high planting densities increased tussock mortality, while decreasing plant tiller counts and relative inflorescence production, together with plant and tiller‐specific mass. However, high densities of the bunchgrass also reduced the cover and biomass of encroaching bluegrass, coincidental with reduced resource (soil moisture and light) availability in mid‐summer. Although summer defoliation increased rough fescue tiller counts, this disturbance reduced plant and tiller mass, and also increased Kentucky bluegrass. We conclude that while high densities of nondefoliated stands of rough fescue may increase resistance to bluegrass encroachment, a reduction in either fescue plant density or vigor via defoliation can increase the risk of bluegrass invasion within northern temperate grassland.     

小麦矮秆突变体jm22d响应赤霉素处理的转录组学分析

为拓宽小麦矮秆遗传资源,利用γ射线辐照济麦22获得了一个赤霉素不敏感型矮秆突变体jm22d。株高相关性状调查结果及茎秆细胞学试验显示,jm22d株高为53±1.8 cm,比野生型（WT）低约20 cm。jm22d整株茎秆共有4节,比WT少一节且各节间长度显著小于WT。与WT相比,jm22d茎秆细胞长度缩短。赤霉素含量测定发现,jm22d叶片中赤霉素含量高于WT,而茎秆中赤霉素含量低于WT（P<0.01）,因此,jm22d株高降低与赤霉素转运途径出现异常有关。为了深入研究jm22d对赤霉素的响应机理,对jm22d和WT幼苗进行赤霉素处理,分别收取处理0（D0）、1（D1）和3 d（D3）的样品进行转录组学分析。结果表明,与WT相比,在jm22d中共筛选到696个上调和1 067个下调的表达基因,其中62个和349个基因在3个时间点分别表现为上调和下调表达。叶绿素含量测定表明,jm22d中叶绿素含量随赤霉素处理时间的延长而降低,聚类分析结果表明,差异表达基因主要富集在光合作用-天线蛋白（photosynthesis-antenna proteins,ko00196）、卟啉和叶绿素代谢（porphyrin and chlorophyll metabolism,ko00860）、亚油酸新陈代谢（linoleic acid metabolism,ko00591）等通路,因此赤霉素处理对jm22d体内叶绿素含量的积累具有抑制作用。通过KEGG分析在植物激素信号转导途径中挖掘到5个差异表达基因（TraesCS2B01G582300、TraesCS2B01G600800、TraesCS2B01G556600、TraesCS2B01G630000和TraesCS6B01G439600）参与生长素、细胞分裂素等激素代谢途径,这些基因在jm22d中显著下调,这可能是jm22d矮化的重要原因。研究结果为矮秆突变体矮化机制的解析提供了重要参考。     

Mode of reproduction is detected by Parth1 and Sex1 SCAR markers in a wide range of facultative apomictic Kentucky bluegrass varieties

Gametophytic apomixis in Kentucky bluegrass (Poa pratensis L.) involves the parthenogenetic development of unreduced eggs from aposporic embryo sacs. Marker-assisted selection for the mode of reproduction in P. pratensis would avoid costly and time-consuming phenotypic progeny tests. We developed and tested two SCAR primer pairs that are associated with the mode of reproduction in P. pratensis. The SCAR primers identified the apomictic and sexual genotypes among progenies of sexual x apomictic crosses with very low bias. Furthermore, when tested on a wide range of Italian and exotic P. pratensis germplasm, they were able to unequivocally distinguish sexual from apomictic genotypes. This system should, therefore, allow new selection models to be set up in this species.     

Differential accumulation of proteins in leaves and roots associated with heat tolerance in two Kentucky bluegrass genotypes differing in heat tolerance

To understand the mechanisms of heat stress responses in perennial grasses, differential proteins in leaves and roots of two genotypes of Kentucky bluegrass (Poa pratensis), including heat-tolerant ‘Midnight’ and heat-sensitive ‘Brilliant’, were analyzed with two-dimensional gel electrophoresis (2-DE) and mass spectrometry (MS). Plants were exposed to heat stress for 28 days in growth chambers. Under 7–28 days of heat stress, leaf photochemical efficiency declined significantly while electrolyte leakage increased in leaves and roots, and to a lesser extent for heat-tolerant ‘Midnight’ than for heat-sensitive ‘Brilliant’. Compared with leaves, cell membrane damage due to heat stress was more severe in roots. The 2-DE and MS analysis identified 37 heat-responsive proteins in leaves, 28 heat-responsive proteins in roots; 14 proteins in leaves and 9 proteins in roots exhibited differential expression between the two genotypes. The results indicate that proteins involved in metabolism and energy in leaves and those in antioxidant defense in roots are associated with heat tolerance in Kentucky bluegrass. The differential accumulation of these proteins might be the reason for different heat tolerance in two Kentucky bluegrass genotypes in aerial and underground parts.     

Optimization of in vitro multiple shoot clump induction and plantlet regeneration of Kentucky bluegrass (Poa pratensis)

An efficient protocol for Kentucky bluegrass (Poa pratensis L.) in vitro culture was established using shoot apices of seedlings as explants. The optimal procedure of this protocol for majority of the genotypes was that meristematic cell clumps and small calluses were firstly induced from the bases of explants on initial culture medium supplemented with 0.9 μM 2,4-d and 8.9 μM 6-BA for 20 d, then were separated and transferred to shoot clumps induction medium containing 8.9 μM 6-BA for the formation of multiple shoot clumps. The percentage of multiple shoot clumps and numbers of shoots per clump were deeply related with the combinations of different plant growth regulators, duration of initial culture, the intensity of illumination and genotypes. Histological observation of the induced explants revealed that the meristematic cell clumps were produced from repeated division of the cortical cells and original meristematic primodium cells of explants, and the multiple shoots were formed via organogenesis pathway in the meristematic cell regions of cultures on shoot clumps induction medium. In this study, plantlets were efficiently regenerated on large scale from seven cultivars of Kentucky bluegrass. Hence the meristematic cell clumps and small calluses in this protocol could be considered good targets for genetic transformation of Kentucky bluegrass.