Effect of Plant Growth Regulator and Irrigation on Physiological and Harvest Maturity of Red Clover in Relation to Seed Quality PDF Download
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Author: Duangporn Angsumalee
Publisher:
ISBN:
Category : Plant regulators
Languages : en
Pages : 151
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Book Description
Red clover (Trifolium pratense L.) seed yield can be affected by plant growth regulators (PGR) and irrigation; however, the effects of these factors on physiological maturity (PM), harvest maturity (HM), and seed quality are unknown. The objectives of this study were to: 1) determine how irrigation and trinexapac-ethyl (TE, a PGR) affect PM, HM, seed viability, and seed vigor of red clover at different stages of maturity, 2) evaluate the effect of irrigation, TE and their interaction on seed yield, its components, and the quality of red clover seeds at harvest, 3) investigate changes in gibberellic and abscisic acid contents in red clover during seed development and maturation, and 4) determine the potential of red clover seed storability under different storage conditions over two years. A field study was conducted over a two-year period at Hyslop Research Farm, Corvallis, Oregon. A single irrigation was applied at first flowering stage (BBCH 55). Five rates of TE, ranging from 0 to 700 g a.i. ha−1, were applied at stem elongation and bud emergence stages (BBCH 32 and BBCH 51, respectively). Seed viability and vigor tests were conducted at Oregon State University Seed Laboratory to measure the effects of treatments on seed quality. Irrigation delayed PM by four days compared to the non-irrigated treatment. The TE applications did not alter seed maturation. At PM, the flower heads contained light brown petals with brownish-green sepals and seeds were pale green to pale yellow. Heads at HM contained dark brown petals and sepals, whereas seeds turned to yellow or yellow-dark grayish purple. Seed dry weight did not change significantly from PM to HM. Seed moisture content at maximum seed dry weight (PM) ranged from 340 to 540 g kg−1 and decreased to below 140 g kg−1 at HM. Seed quality as determined by tetrazolium (TZT), standard germination (SGT), and cold tests (CT) were gradually increased during seed development and maturation. The accelerated aging test (AAT) was not a reliable indicator for evaluating vigor of young seeds. At HM, seeds reached maximum quality for all treatments, with 92 - 98% viability by TZT and SGT, and 90 - 94% vigor by CT. Seed yield was increased by irrigation and TE application, but the interaction between these two treatments was not significant. Irrigation increased seed yield in both years by 10% due to the greater seed weight. However, TE increased seed yield by up to 18% only when applied at stem elongation stage in the second year. The increase in seed yield by TE was attributed to greater number of heads per stem. Neither irrigation nor TE had significant effect on above-ground biomass or stems m−2. Seed viability and vigor were slightly correlated with thousand-seed weight and stems m−2, respectively. However, none of them significantly affected seed quality. The study revealed that seed yield can be increased by: 1) a single irrigation application during first flowering stage (BBCH 55) in both years; and 2) TE application at a rate of 280 g a.i. ha−1 at the stem elongation stage (BBCH 32) in the second-year stand of red clover. Gibberellic acid (GA3) and abscisic acid (ABA) are two major phytohormones that affect seed germination. Changes in the contents of GA3 and ABA from seed development to maturation was conducted using seeds from untreated, TE-treated, irrigated, and TE plus irrigated plots. The GA3 and ABA were extracted from seeds using the solid phase method and were quantified by the liquid chromatography-tandem mass spectrometry (LC-MS/MS). The ABA content was high (1242 pg g−1 DW) at the early stage of seed development, and then gradually decreased to 388 pg g-1 DW at HM. The GA3 content did not change significantly during seed development until HM, ranging from 173 to 187 pg g−1 DW. Irrigation and TE application did not significantly affect the endogenous production of GA3 and ABA in the seeds. The ABA:GA3 ratio was high (6.7) at the early stage of seed development, but seed germination was low (24%). When seeds reached HM, the ABA:GA3 ratio dropped to 2.2 and seed germination increased to 93%. These results suggest that physiological dormancy is not a substantial concern in red clover seeds. However, before scarification, seed with hard seed coat at HM was approximately 34%. Hard seeds were scarified before conducting the germination tests. Maintaining seed quality during storage is essential to ensure value until the time of planting. Two red clover seed lots, untreated and field treated with TE, were stored for 24 months in three conditions: 1) uncontrolled environment of open warehouse (WH), 2) controlled room temperature (RT) at 20°C, and 3) controlled cold storage (CS) at 10°C. Seed quality, i.e., viability and vigor, was determined at 6-month intervals to measure the rate of deterioration after each storage period. Relative humidity (RH) was observed as 55% in RT and 90% in CS. Average seed viability of both seed lots stored in WH and RT and were 96% and 95%, respectively, throughout the 24-month storage period. Seeds stored at RT for 24 months maintained high vigor of 87% as determined by the AAT, whereas seeds stored at WH maintained vigor of 81% for 18 months and then dropped to 67% at the end of the 24-month storage period. In CS, seed viability and vigor gradually dropped, reaching 0% at the end of the 24-month storage period due to the adverse effect of the high RH (90%) in the CS. Seed maintained acceptable viability and vigor standards of above 80% when seed moisture content was less than 10%. This study suggests that red clover seeds from untreated and TE-treated plots can be stored safely under similar WH conditions used in this study for 18 months and in RT for 24 months when the initial seed moisture content is under 10%. The results of this study improved our understanding of the potential storability of the red clover seed in response to TE application.
Author: Duangporn Angsumalee
Publisher:
ISBN:
Category : Plant regulators
Languages : en
Pages : 151
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Book Description
Red clover (Trifolium pratense L.) seed yield can be affected by plant growth regulators (PGR) and irrigation; however, the effects of these factors on physiological maturity (PM), harvest maturity (HM), and seed quality are unknown. The objectives of this study were to: 1) determine how irrigation and trinexapac-ethyl (TE, a PGR) affect PM, HM, seed viability, and seed vigor of red clover at different stages of maturity, 2) evaluate the effect of irrigation, TE and their interaction on seed yield, its components, and the quality of red clover seeds at harvest, 3) investigate changes in gibberellic and abscisic acid contents in red clover during seed development and maturation, and 4) determine the potential of red clover seed storability under different storage conditions over two years. A field study was conducted over a two-year period at Hyslop Research Farm, Corvallis, Oregon. A single irrigation was applied at first flowering stage (BBCH 55). Five rates of TE, ranging from 0 to 700 g a.i. ha−1, were applied at stem elongation and bud emergence stages (BBCH 32 and BBCH 51, respectively). Seed viability and vigor tests were conducted at Oregon State University Seed Laboratory to measure the effects of treatments on seed quality. Irrigation delayed PM by four days compared to the non-irrigated treatment. The TE applications did not alter seed maturation. At PM, the flower heads contained light brown petals with brownish-green sepals and seeds were pale green to pale yellow. Heads at HM contained dark brown petals and sepals, whereas seeds turned to yellow or yellow-dark grayish purple. Seed dry weight did not change significantly from PM to HM. Seed moisture content at maximum seed dry weight (PM) ranged from 340 to 540 g kg−1 and decreased to below 140 g kg−1 at HM. Seed quality as determined by tetrazolium (TZT), standard germination (SGT), and cold tests (CT) were gradually increased during seed development and maturation. The accelerated aging test (AAT) was not a reliable indicator for evaluating vigor of young seeds. At HM, seeds reached maximum quality for all treatments, with 92 - 98% viability by TZT and SGT, and 90 - 94% vigor by CT. Seed yield was increased by irrigation and TE application, but the interaction between these two treatments was not significant. Irrigation increased seed yield in both years by 10% due to the greater seed weight. However, TE increased seed yield by up to 18% only when applied at stem elongation stage in the second year. The increase in seed yield by TE was attributed to greater number of heads per stem. Neither irrigation nor TE had significant effect on above-ground biomass or stems m−2. Seed viability and vigor were slightly correlated with thousand-seed weight and stems m−2, respectively. However, none of them significantly affected seed quality. The study revealed that seed yield can be increased by: 1) a single irrigation application during first flowering stage (BBCH 55) in both years; and 2) TE application at a rate of 280 g a.i. ha−1 at the stem elongation stage (BBCH 32) in the second-year stand of red clover. Gibberellic acid (GA3) and abscisic acid (ABA) are two major phytohormones that affect seed germination. Changes in the contents of GA3 and ABA from seed development to maturation was conducted using seeds from untreated, TE-treated, irrigated, and TE plus irrigated plots. The GA3 and ABA were extracted from seeds using the solid phase method and were quantified by the liquid chromatography-tandem mass spectrometry (LC-MS/MS). The ABA content was high (1242 pg g−1 DW) at the early stage of seed development, and then gradually decreased to 388 pg g-1 DW at HM. The GA3 content did not change significantly during seed development until HM, ranging from 173 to 187 pg g−1 DW. Irrigation and TE application did not significantly affect the endogenous production of GA3 and ABA in the seeds. The ABA:GA3 ratio was high (6.7) at the early stage of seed development, but seed germination was low (24%). When seeds reached HM, the ABA:GA3 ratio dropped to 2.2 and seed germination increased to 93%. These results suggest that physiological dormancy is not a substantial concern in red clover seeds. However, before scarification, seed with hard seed coat at HM was approximately 34%. Hard seeds were scarified before conducting the germination tests. Maintaining seed quality during storage is essential to ensure value until the time of planting. Two red clover seed lots, untreated and field treated with TE, were stored for 24 months in three conditions: 1) uncontrolled environment of open warehouse (WH), 2) controlled room temperature (RT) at 20°C, and 3) controlled cold storage (CS) at 10°C. Seed quality, i.e., viability and vigor, was determined at 6-month intervals to measure the rate of deterioration after each storage period. Relative humidity (RH) was observed as 55% in RT and 90% in CS. Average seed viability of both seed lots stored in WH and RT and were 96% and 95%, respectively, throughout the 24-month storage period. Seeds stored at RT for 24 months maintained high vigor of 87% as determined by the AAT, whereas seeds stored at WH maintained vigor of 81% for 18 months and then dropped to 67% at the end of the 24-month storage period. In CS, seed viability and vigor gradually dropped, reaching 0% at the end of the 24-month storage period due to the adverse effect of the high RH (90%) in the CS. Seed maintained acceptable viability and vigor standards of above 80% when seed moisture content was less than 10%. This study suggests that red clover seeds from untreated and TE-treated plots can be stored safely under similar WH conditions used in this study for 18 months and in RT for 24 months when the initial seed moisture content is under 10%. The results of this study improved our understanding of the potential storability of the red clover seed in response to TE application.
Author: Thomas B. Silberstein
Publisher:
ISBN:
Category : Red clover
Languages : en
Pages : 112
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Book Description
Excessive growth by red clover, Trifolium pratense L., grown for seed interferes with maximum seed production and harvest in Oregon's Willamette Valley. This study was conducted during 1986 and 1987 on red clover cv. Kenland to determine if plant height and dry matter production could be inhibited and seed yields improved with the plant growth regulators (PGRs) uniconazol (XE-1019) and paclobutrazol (Parlay). The effects of different soil-applied and foliar-applied PGRs and application rates on plant height, crop biomass, and yield components of red clover were measured at Corvallis, OR on Woodburn silt-loam (fine-silty mixed mesic Aquultic Argixerolls) soil. Soil-applied PGRs were also managed under single and multiple irrigation regimes in 1986. Under a single irrigation regime in 1986, canopy height was reduced by 32% when XE-1019 was applied at 1.12 kg ai/ha and was reduced by 13% when Parlay was applied at 1.68 kg ai/ha. Averaged over the two-year period, straw yield was reduced 40% with XE-1019 (1.12 kg ai/ha) and by 12% with Parlay (1.68 kg ai/ha). Seed yield was increased by 11% with the lower XE-1019 rate (0.14 kg ai/ha) and was increased by 14% with the higher Parlay rate (1.68 kg ai/ha). Soil-applied PGR treatments reduced canopy height by 25% with XE-1019 (1.12 kg ai/ha) and was reduced by 11% with Parlay (1.68 kg ai/ha) under multiple irrigation in 1986. Straw yield was reduced by 30% with XE-1019 (0.84 kg ai/ha), but Parlay had no effect on straw yield. In addition, seed yield was increased by 8% with XE-1019 (0.56 kg ai/ha) and by 18% with Parlay (1.68 kg ai/ha). Foliar-applied XE-1019 (1.12 kg ai/ha) reduced canopy height by 13% in 1986 and by 25% in 1987, whereas foliar-applied Parlay (1.12 kg ai/ha) reduced canopy height by 9% in 1986 and by 19% in 1987. In 1986, seed yield increases averaged 16% across all 3CE-1019 treatments (0.07 to 1.12 kg ai/ha) and was increased an average of 21% across all Parlay treatments (0.28 to 1.68 kg ai/ha). However, 1987 was drier and warmer than 1986, consequently, foliar-applied XE-1019 reduced seed yields by an average of 23% and Parlay reduced seed yields by an average of 21%. Total dry weight and straw weight were unaffected by foliar-applied PGR treatment in both years. Use of XE-1019 and Parlay in field crop production has the potential to reduce dry matter production and improve seed recovery, but results vary from year to year. These PGRs have the potential to improve seed yields and may be effective in improving harvest conditions by reducing vegetative biomass.
Author: L. G. Jones
Publisher:
ISBN:
Category : Clover
Languages : en
Pages : 20
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Author:
Publisher:
ISBN:
Category : Forage plants
Languages : en
Pages : 8
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Author: N.L. Taylor
Publisher: Springer Science & Business Media
ISBN: 9401586926
Category : Science
Languages : en
Pages : 246
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Book Description
This book examines the literature on red clover since about 1985. In each of the 17 chapters, an effort was made to summarize the earlier literature and to integrate the recent findings into this background. The timing is appropriate with the present interest in sustainable agriculture, in which red clover was so prominent in the past. This is the first book to be published which deals solely with this important forage species. Audience: Primarily scientists and scientifically trained technicians who will appreciate an up-to-date summary on red clover.
Author: Roy Glen Wiggans
Publisher:
ISBN:
Category : Red clover
Languages : en
Pages : 48
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Author: Krystyna ?uk-Go?aszewska
Publisher: Nova Science Publishers
ISBN: 9781536118001
Category : Science
Languages : en
Pages : 70
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Book Description
Red clover (Trifolium pratense L.) is one of the many species belonging to the genus Trifolium, which are widely cultivated around the world. It is a perennial plant and offers permanence that determines its uses as well as environmental and agronomic requirements. Red clover is grown mainly for seeds and biomass. The most important environmental factors that affect red clover yield are soil conditions, temperature and precipitation during the growing season. Key agronomic factors include sowing date, cultivation regime, fertilization, plant protection and harvesting date. The species can be grown in pure and mixed stands (with alfalfa, cereals and various grass species). Newly bred triploid varieties of red clover are characterized by desirable growth habit traits and yield components as well as high yield. Red clover has many applications. It is currently experiencing a revival of interest as a traditional folk remedy. The species acts as a rich source of compounds with expectorant, analgesic and antiseptic properties. The callus from Trifolium pratense has been found to exert inhibitory effects on fungal and bacterial strains. Red clover contains isoflavones, anthocyanin pigments and phytoestrogens, which may help reduce the risk of heart disease, breast cancer and endometrial cancer; it also alleviates menopausal symptoms. Red clover lowers blood cholesterol levels and helps prevent prostate cancer. Red clover ointments are used to treat skin diseases, including psoriasis. Red clover provides biomass for livestock nutrition and/or biogas production. It has high nutritional value and constitutes valuable raw material for silage making. Red clover can be grown with grasses, barley, oats and wheat, thus providing various types of fodder with high biological value and natural high-protein feed. When grown as a cover crop, red clover fixes and supplies nitrogen to cereal crops. It also helps break disease and insect cycles, especially in plantations protected against weeds. The crude protein content of red clover decreases with advancing maturity. Due to its permanence, this perennial plant contributes to environmental protection and anesthetization; it helps prevent soil erosion, and is used in phytoremediation and barren land management schemes.
Author: Carroll Paton Wilsie
Publisher:
ISBN:
Category : Red clover
Languages : en
Pages : 42
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Author:
Publisher:
ISBN:
Category : Agriculture
Languages : en
Pages : 1732
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Author: Ruiz Núñez Ruiz N.
Publisher:
ISBN:
Category :
Languages : en
Pages : 94
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