Switchgrass (Panicum virgatum L.) is a warm‐season native grass, used for livestock feed, bioenergy, soil and wildlife conservation, and prairie restoration in a large portion of the USA. The objective of this research was to quantify the relative importance of latitude and longitude for adaptation and agronomic performance of a diverse group of switchgrass populations. Six populations, chosen to represent remnant prairie populations on two north–south transects, were evaluated for agronomic traits at 12 locations ranging from 36 to 47°N latitude and 88 to 101°W longitude. Although the population × location interactions accounted for only 10 to 31% of the variance among population means, many significant changes in ranking and adaptive responses were observed. Ground cover was greater for northern‐origin populations evaluated in hardiness zones 3 and 4 and for southern‐origin populations evaluated in hardiness zones 5 and 6. There were no adaptive responses related to longitude (ecoregion). Switchgrass populations for use in biomass production, conservation, or restoration should not be moved more than one hardiness zone north or south from their origin, but some can be moved east or west of their original ecoregion, if results from field tests support broad longitudinal adaptation.
A diclofop-methyl-resistant biotype of Italian ryegrass was characterized to determine the expression and inheritance of herbicide resistance and whether this trait was due to the presence of a diclofop-insensitive form of acetyl-coenzyme A carboxylase (ACCase). At the whole plant level, the resistant biotype was > 93-fold more resistant to diclofop-methyl than the susceptible biotype. Crosses of diclofop-resistant and –susceptible plants were performed to produce F1 plants. No maternal effects were evident in responses of reciprocal F1 plants to diclofop. GR50diclofop rates determined for resistant, F1, and susceptible plants were 15, 6.3, and 0.16 kg ha−1, respectively. F2 populations treated with a 7.5 kg ha−1rate of diclofop exhibited three injury response phenotypes 3 wk after treatment: a susceptible (S) phenotype which was killed, an intermediate resistance (I) phenotype with severe injury, and a resistant (R) phenotype with little or no injury. Testcross progeny exhibited only I and S phenotypes. Observed segregation of phenotypes in F2 and testcross populations conformed to segregation ratios predicted for a trait with inheritance controlled by a single partially dominant nuclear gene. ACCase activity determined in crude cell-free extracts of resistant, F1, and susceptible biotypes exhibited I50values of 50, 20, and 0.7 μM diclofop, respectively. A positive relationship between the injury response phenotype and site of action (ACCase) response to diclofop was evident in both F1 and F2 populations. In extracts from R, I, and S phenotype F2 plants, 20 μM diclofop acid inhibited ACCase-mediated incorporation of14C by 27.1, 45.1, and 78.9%, respectively. The ACCase data are consistent with the hypothesis that diclofop resistance in Italian ryegrass is conferred by a diclofop-insensitive form of ACCase.
Intermediate wheatgrass (Thinopyrum intermedium) is a perennial grass that is being domesticated and improved for use as a grain crop. As a perennial grain crop, intermediate wheatgrass has the potential to produce economically viable, food-grade grain while providing environmental benefits such as reduced erosion and nitrate leaching. To guide agronomic activities for this new crop, more information on intermediate wheatgrass growth and development is needed. We sampled plants every 3-5 days throughout the growing season at three environments to measure growth and development in response to accumulating growing degree days (GDD). A numerical growth index was used to quantify morphological development. Growth index, plant height, biomass, height of the tallest node, and biomass partitioning to leaf, stem, and inflorescence were modelled as a function of GDD. We predicted dates (in GDD and day of the year) for critical morphological events as they relate to grain crop production using model equations. The fraction of total biomass allocated to leaves decreased and stems increased in response to GDD, and both components represented equal proportions of aboveground biomass at plant maturity. Growth and development was similar across environments, but variation in yield components (e.g., 50 seed weight, seed mass inflorescence −1 ) was observed. Our results provide the first quantification of growth and development of intermediate wheatgrass, and have application to growers seeking to determine optimal timing of agronomic practices, as well as crop modellers working to integrate new crops into simulation models. As intermediate wheatgrass expands as a perennial grain crop, growth and development should be measured in a broader range of temperature and precipitation conditions.
Many winter stresses aVect the ability of a perennial grass to overwinter in cold, temperate climates. Freezing tolerance is one of the major component traits aVecting winterhardiness. Although eVective freezing tolerance assessment procedures have long been available for perennial ryegrass (Lolium perenne L.), no work has been done to characterize plant collections in the United States that may possess novel variation for freezing tolerance and winterhardiness. In this study, 21 accessions sampled from a larger set of 300 accessions with known winterhardiness and 3 check varieties were subjected to environmentally-controlled, low temperature acclimation, followed by controlled freezing using a programmable laboratory freezer. Eight freezing treatments from ¡2 to ¡16°C were used to determine survival across the known spectrum of freezing tolerance in perennial ryegrass. LT 50 values were estimated based on whole plant survival, as well as tiller survival at each of the temperature treatments in the evaluation. LT 50 values for the accessions and checks ranged from ¡10.31 to ¡13.95°C, with 3 accessions possessing signiWcantly greater freezing tolerance than the most freeze-tolerant check, 'NK200'. LT 50 values were well correlated with winterhardiness in St. Paul during the winters of 2004-2005 and 2005-2006. Lower LT 50 values in this experiment were associated with greater spring growth following the stressful winter of 2004-2005 and upright growth habit. The lack of negative biological association between freezing tolerance and turf quality components indicates that freezing tolerance testing could be a useful tool in breeding and selection with landrace germplasm.
The lack of winterhardiness of some cool‐season grasses limit their usefulness in northern climates. Perennial ryegrass (Lolium perenne L.) lacks winterhardiness in Minnesota but has desirable qualities, such as wear tolerance and rapid establishment, that are useful in many turf applications. While domesticated germplasm may lack winterhardiness, undomesticated wild or landrace germplasm may have genes for better winterhardiness in environments like Minnesota's. In 2004, 300 accessions from two public sources in the USA were planted with eight check varieties and populations in two environments in central Minnesota, St. Paul and Becker. Thirty individuals of each accession were evaluated for seedling vigor and tiller survival after the first winter. Other turf‐quality traits and tiller survival after the second winter were evaluated on those plants that survived the first winter. The first winter was extremely harsh and resulted in the death of all accessions and checks at Becker. There was good differentiation among accessions at St. Paul for tiller survival, with 8 of the 300 accessions performing better than NK200, the most winterhardy check variety. The second winter was considerably less harsh, with less death of tillers and whole plants. While the accessions do not have suitable turf quality for direct domestication, turf quality can be improved through breeding.
Alfalfa (Medicago sativa L.) cultivars are available that produce high‐quality forage; however, information is lacking on the consistency of cultivar forage quality over environments and the influence of stand age on quality. Our objectives were to evaluate alfalfa cultivars for consistency of forage quality over time and environments and to test the validity of sampling seeding‐year stands for forage quality. We sampled eight alfalfa entries (seven cultivars and one experimental germplasm) at bud and flower maturity stages in the seeding year (one harvest) and first production year (two harvests) in six states (Indiana, Kentucky, Minnesota, New York, Washington, and Wisconsin). ANOVA and orthogonal contrast analyses were conducted to assess entry × environment interactions for forage quality. First‐cut forage in the first production year had lower forage quality than third‐cut forage, and differences between entries were more pronounced at the first cutting. Including seeding‐year data in the ANOVA produced a complex location × entry × stand age interaction, indicating that seeding‐year data alone were insufficient to characterize alfalfa entries for forage quality. ‘Cimarron VR’, ‘Arrow’, and ‘5432’ had the greatest stability for forage quality and could serve as high, medium, and low forage‐quality checks, respectively, in forage quality testing trials. ‘WL 322 HQ’ and ‘Pacesetter’ often had high quality, but were not stable for forage quality over environments. Correlations between crude protein, acid detergent fiber (ADF), neutral detergent fiber (NDF), and in vitro digestible dry matter were consistent across locations, entries, cuttings, and maturities. The high correlation between NDF and ADF (r > 0.97, P < 0.05) suggests that it may not be necessary to use both procedures to predict entry differences in forage quality.
Field experiments were conducted to determine the effect of a short-term spring-seeded smother plant on corn development and weed control. Yellow mustard was managed to provide interference durations of 2,4,6, or 8 wk, and maximum height of 10 or 20 cm. Three yellow mustard planting patterns and eight seeding rates were evaluated during 1989 and 1990 at St. Paul and Rosemount, MN. Yellow mustard seeded at 2120 seeds m−2with an interference duration of 4 wk and a maximum height of 10 cm decreased corn yield 17% and reduced weed dry weight 4 wk after yellow mustard emergence an average of 66%. Yellow mustard with a 2-wk interference duration did not reduce weed dry weight. Yellow mustard seeded at 2120 seeds m−2with a 6- or 8-wk life cycle and 10-cm height reduced weed dry weight at the end of the interference period an average of 82% but delayed corn silk emergence an average of 5.3 d and reduced average grain yield 19%. Increasing yellow mustard height from 10 to 20 cm delayed corn silk emergence and reduced grain yield but did not decrease weed dry weight. Yellow mustard with an interference duration of 4 wk and a maximum height of 10 cm, seeded over the corn row at 530 seeds m−2, reduced weed dry weight 4 wk after mustard emergence an average of 51%, and resulted in an average corn grain yield reduction of 4%, compared with corn grown in monoculture averaged over weedy and weed-free treatments. These results suggest that it may be possible to develop spring-seeded smother plants that reduce weed biomass up to 80% but have only a small impact on corn yield.
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