Disease resistance in cool-season forage range and turf grasses II

The potential and proven disease resistance of various cool season cultivars of common forage, range, and turfgrasses to fungi, bacteria, and viruses is reviewed. Included are certain grass species ofAgropyron, Agrostis, Arrhenatherum, Bromus, Dactylis, Elymus, Festuca, Lolium, Phalaris, Phleum, andPoa. These cultivars may be useful in crop improvement programs and for germplasm exchange.     

三种暖季型草坪草对二氧化硫抗性的比较

二氧化硫(SO_2)是城市大气污染的重要污染物之一,这已经越来越成为国家迫在眉睫须彻底解决的环境问题,解决SO_2污染问题仍是一个重要的生态与环保课题。草坪植物现已成为城市绿化的主要造景材料,依据植物对大气污染的反应特性来选择城市草坪草种,使之在发挥景观效果的同时,发挥其更好的生态效果。采用人工模拟熏气法,以CK(自然状态)、S1(4.29mg/m~3)、S2(6.44mg/m~3)、S3(8.58mg/m~3)、S4(10.73mg/m~3)5个SO_2浓度水平,对城市常用的3种暖季型草坪草:结缕草(Zoysiajaponica)、百喜草(Paspalum notatum)、狗牙根(Cynodon dactylon)进行SO_2胁迫处理,并测定3种草坪草生理生化指标,最终比较3种草坪草对SO_2的抗性。结果表明:随SO_2浓度增加,3种草坪草的可溶性糖含量(SS)、脯氨酸含量(Pro)、丙二醛(MDA)含量呈增加趋势;结缕草可溶性蛋白(SP)呈先降后升趋势,百喜草则呈先升后降趋势,狗牙根各胁迫处理下其SP含量均低于CK;结缕草和狗牙根过氧化物酶(POD)、过氧化氢酶(CAT)和超氧化物歧化酶(SOD)活性呈增加趋势,百喜草SOD和CAT活性呈先升后降趋势,同时其POD活性在各SO_2胁迫处理下均低于CK。将所有测定指标采用模糊数学隶属度公式进行综合相关分析,得出3种草坪草对SO_2的抗性由强到弱的排序为:结缕草狗牙根百喜草。结缕草在SO_2胁迫下与其它两种草坪草相比,表现出了更好的抗性能力,因此,在城市空气不断遭受污染的今天,结缕草可以作为热带和亚热带城市绿化草坪植物的优选草种之一。     

Recent advances in genetic transformation of forage and turf grasses

Summary Forage and turf grasses are critical to sustainable agriculture and contribute extensively to the world economy. Tremendous progress has been made in genetic transformation of forage and turf grasses in the past decade. The rapid advancement of cellular and molecular biology and transgenic technology provides novel methods to accelerate and complement conventional breeding efforts. This review summarizes the latest developments in genetic transformation methods and the applications of molecular techniques for the improvement of forage and turf grasses.     

Nitric oxide accelerates seed germination in warm-season grasses

The nitric oxide (NO) donor sodium nitroprusside (SNP) significantly promoted germination of switchgrass (Panicum virgatum L. cv Kanlow) in the light and in the dark at 25°C, across a broad range of concentrations. SNP also promoted seed germination in two other warm-season grasses. A chemical scavenger of NO inhibited germination and blocked SNP stimulation of seed germination. The phenolic (+)-catechin acted synergistically with SNP and nitrite in promoting seed germination. Acidified nitrite, an alternate NO donor also significantly stimulated seed germination. Interestingly, sodium cyanide, potassium ferricyanide and potassium ferrocyanide at 200 μM strongly enhanced seed germination as well, whereas potassium chloride was without effect. Ferrocyanide and cyanide stimulation of seed germination was blocked by an NO scavenger. Incubation of seeds with a fluorescent NO-specific probe provided evidence for NO production in germinating switchgrass seeds. Abscisic acid (ABA) at 10 μM depressed germination, inhibited root elongation and essentially abolished coleoptile emergence. SNP partially overcame ABA effects on radicle emergence but did not overcome the effects of ABA on coleoptile elongation. Light microscopy indicated extension of the radicle and coleoptiles in seeds maintained on water or on SNP after 2 days. In contrast, there was minimal growth of the radicle and coleoptile in ABA-treated seeds even after 3–4 days. These data indicate that seed germination of warm-season grasses is significantly influenced by NO signaling pathways and document that NO could be an endogenous trigger for release from dormancy in these species.     

Invasive warm-season grasses reduce mycorrhizal root colonization and biomass production of native prairie grasses

Soil organisms play important roles in regulating ecosystem-level processes and the association of arbuscular mycorrhizal (AM) fungi with a plant species can be a central force shaping plant species' ecology. Understanding how mycorrhizal associations are affected by plant invasions may be a critical aspect of the conservation and restoration of native ecosystems. We examined the competitive ability of old world bluestem, a non-native grass (Caucasian bluestem [Bothriochloa bladhii]), and the influence of B. bladhii competition on AM root colonization of native warm-season prairie grasses (Andropogon gerardii or Schizachyrium scoparium), using a substitutive design greenhouse competition experiment. Competition by the non-native resulted in significantly reduced biomass production and AM colonization of the native grasses. To assess plant-soil feedbacks of B. bladhii and Bothriochloa ischaemum, we conducted a second greenhouse study which examined soil alterations indirectly by assessing biomass production and AM colonization of native warm-season grasses planted into soil collected beneath Bothriochloa spp. This study was conducted using soil from four replicate prairie sites throughout Kansas and Oklahoma, USA. Our results indicate that a major mechanism in plant growth suppression following invasion by Bothriochloa spp. is the alteration in soil microbial communities. Plant growth was tightly correlated with AM root colonization demonstrating that mycorrhizae play an important role in the invasion of these systems by Bothriochloa spp. and indicating that the restoration of native AM fungal communities may be a fundamental consideration for the successful establishment of native grasses into invaded sites.     

Emerging technologies advancing forage and turf grass genomics

Grassland is of major importance for agricultural production and provides valuable ecosystem services. Its impact is likely to rise in changing socio-economic and climatic environments. High yielding forage grass species are major components of sustainable grassland production. Understanding the genome structure and function of grassland species provides opportunities to accelerate crop improvement and thus to mitigate the future challenges of increased feed and food demand, scarcity of natural resources such as water and nutrients, and high product qualities.     

Evaluation of cool- and warm-season grasses for resistance to multiple chinch bug (Hemiptera: Blissidae) species

Chinch bugs are common pests of many agronomic and horticulturally important crops and turfgrasses. The extensive overlap of plant hosts and geographic distribution of Blissus leucopterus leucopterus (Say), Blissus leucopterus hirtus Montandon, Blissus insularis Barber, and Blissus occiduus Barber underscores the importance of identifying resistant germplasm. Cool- and warm-season turfgrasses and sorghum, Sorghum bicolor (L.) Moench, were evaluated for resistance to chinch bugs in the Blissus complex, and the presence of multiple resistance was documented. Greenhouse studies established that B. occiduus-resistant ('Prestige', formerly NE91-118) and -susceptible ('378') buffalograsses,, Buchlo? dactyloides (Nuttall) Engelmann, were susceptible to all other chinch bug species. KS94 sorghum exhibited resistance to both B. occiduus and B. l. leucopterus, whereas B. insularis-resistant St. Augustinegrass, Stenotaphrum secundatum (Walter) Kuntze ('Floratam'), was also resistant to B. occiduus. B. l. leucopterus-susceptible sorghum ('Wheatland') and B. insularis-susceptible St. Augustinegrasses ('Raleigh' and 'Amerishade') were highly resistant to B. occiduus. Endophyte-free and -enhanced fine fescues (Festuca spp.) were moderately to highly susceptible to B. l. hirtus but moderately to highly resistant to B. occiduus. The results of this research showed the buffalograsses evaluated, including B. occiduus-resistant Prestige, are moderately to highly susceptible to the three other chinch bug species. In contrast, B. occiduus did not cause considerable damage to any of the turfgrasses or sorghum cultivars evaluated, other than buffalograss, irrespective of whether or not they are resistant to another chinch bug species. This information is increasingly important as various grasses become adapted to regions that may possess chinch bug species other than those with which they are typically associated. These levels of Blissus resistance should be included when selecting resistant germplasm for managing Blissus species pests.     

Responses to drought and flooding in tropical forage grasses

Seasonal drought and flooding severely limit pasture growth in tropical savannas. The objective of this study is to analyze and compare yield, biomass allocation, leaf growth rate and nutrient concentration of four important perennial C₄ forage grasses to short term flooding and moderate drought under controlled conditions. The grasses studied were the tufted Andropogon gayanus (CIAT 621) and Hyparrhenia rufa and the stoloniferous Echinochloa polystachya and Brachiaria mutica. All grasses were able to adjust their growth and development in response to flooding and drought: leaf growth and total biomass decreased under both treatments but the specific responses to these treatments differed markedly. Considering only total yield and leaf area, A. gayanus and H. rufa were relatively more tolerant to and less affected by drought whereas B. mutica and E. polystachya were more flood tolerant. In A. gayanus and H. rufa, both treatments reduced the proportion of assimilates devoted to roots and culms while increasing that of leaves decreasing the root/shoot ratio. In contrast, in B. mutica and E. polystachya only the proportion devoted to culms or stolons increased under flooding but the root/shoot ratio remained relatively stable under both treatments. All grasses produced adventitious rootlets except A. gayanus which was the most affected by flooding. Waterlogging decreased leaf nutrient concentration in all grasses which contributed to growth reduction. All species were relatively tolerant to both stresses. The results confirm the empirical observation that stoloniferous species B. mutica and E. polystachya are more tolerant to flooding thanks to adaptations typical of wetland plants such as hollow stolons which enhance oxygen diffusion to the roots and the development of adventitious rootlets that promotes water and nutrient absorption.     

Cold acclimation of forage grasses in relation to pink snow mould (Microdochium nivale) resistance

The aim of our work is to investigate the changes in phenolic level, PAL activity and heat production rate induced during pre-hardening at 12°C and cold acclimation at 2°C of the forage grasses Festulolium, meadow fescue, tall fescue and Italian ryegrass in relation to their resistance to snow mould caused by Microdochium nivale. Meadow fescue and tall fescue were most resistant to M. nivale infection, while Italian ryegrass demonstrated the least resistance to this fungus inoculation. Festulolium, meadow fescue and tall fescue responded similarly to low temperature, while Italian ryegrass demonstrated considerable disturbance of energy balance and lower phenolic concentration, which could explain a higher susceptibility of the latter species to infection by M. nivale. The enhanced level of phenolic compounds, probably utilised for cell wall lignification as well as equilibrium of the metabolic activity observed in meadow fescue and tall fescue, is very important for both cold and pathogen-resistance mechanisms. The studied Festulolium cultivar ‘Felopa’, a hybrid of the Lolium multiflorum and Festuca pratensis genomes, was characterised by changes in biochemical parameters similar to the resistant meadow fescue and tall fescue.     

Availability and zinc accumulation in forage grasses grown in contaminated soil

Zinc is an important micronutrient to plant growth, but when present in large quantities it can become a toxic element to plants. This study was aimed to evaluate the growth, concentration, accumulation and availability of Zn to forage grasses (Megathyrsus maximus cvs. Aruana and Tanzania, Urochloa brizantha cvs. Xaraés and Marandu and Urochloa decumbens cv. Basilisk) cultivated in Zn contaminated soils. The experiments were conducted under greenhouse conditions over a 90-day evaluation period, and Zn rates were 0, 100, 300 and 900 mg kg^?1 of soil. The Zn rates in soil caused growth reduction in all evaluated forage grasses. The cultivar Aruana was generally more tolerant to Zn, while the Marandu was generally more susceptible to the addition of Zn. The cultivar Aruana proved to be superior to others due to its higher growth and higher critical level toxicity of Zn. None of the forage grasses evaluated can be considered a Zn hyperaccumulator. The extraction order was DTPA at pH 7.3 < Mehlich-1 < USEPA 3051 < USEPA 3052 in the soil independent of forage grasses cultivation. The USEPA 3051 extractor was similar to Mehlich-1 in predicting the availability of Zn in soil.     

Seasonal range selection in bighorn sheep: conflicts between forage quality,forage quantity,and predator avoidance

Summary The migratory and foraging behavior of individually marked bighorn ewes (Ovis canadensis) was studied to test the hypothesis that forage quality determined seasonal range selection. Forage quality was monitored through analysis of fecal crude protein. Ewes in the study population utilized two distinct ranges differing in elevation and possibly predation risk. Pregnant ewes migrated in May from the low-elevation winter range to lambing areas at higher elevation, before plant growth had started there. In so doing, they moved from a range of high-quality forage to one of low-quality forage, apparently to avoid predation on newborn lambs. Non-pregnant adult ewes migrated later. Most yearling ewes (which are not pregnant) migrated with the adult ewes to the lambing areas, but returned to the winter range within a few days, then migrated again to high-elevation areas in June. Forage quality was higher at high elevation from mid-June at least through July, but forage availability appeared to be lower than in the winter range. Seasonal range selection is likely determined by a combination of nutritional and antipredator constraints. The antipredator strategy of bighorn ewes does not always allow them to utilize the range with the best forage.     

Physically mapping quantitative traits for stress-resistance in the forage grasses

Recent advances in cytogenetics of the Lolium/Festuca complex provide new opportunities for understanding and manipulating physiological mechanisms in complex quantitative traits such as stress resistance. The complex provides a valuable reserve for research and breeding since (a) it includes a wide range of valuable agronomic characters, (b) it has the capacity for intergeneric hybridization with promiscuous recombination, and its genomes, despite their close homology, have sufficient structural heterogeneity to allow Lolium and Festuca chromosomes to be discriminated using genomic in situ hybridization (GISH).Two alternative procedures are used to 'dissect' stress-resistance traits into their individual components both to determine their function and to physically map the relevant QTL(s) onto chromosome arms: (a) Festuca genes are introgessed into Lolium to improve stress resistance, (b) Lolium genes are introgressed into Festuca to reduce stress resistance. Whichever approach is used, alien introgressions can be detected by GISH and assigned to chromosome arms to create a physical map. Genes of interest may then be located more accurately following further recombination events which reduce the size of the relevant alien introgression.It has become obvious during the past years that genetic and physical maps are not directly comparable as chiasmata are not evenly distributed along the chromosome axis. By integrating physical maps created by GISH and genetic linkage-maps, the precise site of genes on a chromosome arm may be determined, and markers found which are tightly linked to the genes of interests, for future use in breeding programmes.Key words: Genomic in situ hybridization (GISH), physical mapping, Lolium/Festuca complex, stress resistance.      

Availability and toxicity of cadmium to forage grasses grown in contaminated soil

It is important to know the mechanisms for forage development, especially those related to the tolerance of potentially toxic elements, when considering their use in phytoremediation in heavy metal contaminated areas. In this study, we evaluated plant growth, concentration, and the availability of cadmium (Cd) for forage grasses (Panicum maximum Jacq. cv. Aruana and cv. Tanzânia; Brachiaria decumbens cv. Basilisk; Brachiaria brizantha cv. Xaraés and cv. Marandu) cultivated in Cd contaminated soils. The experiments were performed under greenhouse conditions over a 90-day evaluation period, and the Cd rates were 2, 4, and 12 mg/kg of soil. The relative growth rate of the forage grasses decreased as Cd rates increased, and the following descending order of susceptibility was observed: Marandu > Xaraés > Aruana > Tanzânia > Basilisk, with regard to phytotoxicity in these plants. The forage Cd concentration increased in line with increases in the Cd rates. Cd contents extracted by Mehlich-1 and by diethylenetriaminepentaacetic acid presented high positive correlation with forage relative growth. The forage plants did not block Cd entry into the food chain because they were not capable of limiting Cd absorption.     

Advanced phenotyping offers opportunities for improved breeding of forage and turf species

Background and Aims

Advanced phenotyping, i.e. the application of automated, high-throughput methods to characterize plant architecture and performance, has the potential to accelerate breeding progress but is far from being routinely used in current breeding approaches. In forage and turf improvement programmes, in particular, where breeding populations and cultivars are characterized by high genetic diversity and substantial genotype × environment interactions, precise and efficient phenotyping is essential to meet future challenges imposed by climate change, growing demand and declining resources.

Scope

This review highlights recent achievements in the establishment of phenotyping tools and platforms. Some of these tools have originally been established in remote sensing, some in precision agriculture, while others are laboratory-based imaging procedures. They quantify plant colour, spectral reflection, chlorophyll-fluorescence, temperature and other properties, from which traits such as biomass, architecture, photosynthetic efficiency, stomatal aperture or stress resistance can be derived. Applications of these methods in the context of forage and turf breeding are discussed.

Conclusions

Progress in cutting-edge molecular breeding tools is beginning to be matched by progress in automated non-destructive imaging methods. Joint application of precise phenotyping machinery and molecular tools in optimized breeding schemes will improve forage and turf breeding in the near future and will thereby contribute to amended performance of managed grassland agroecosystems.