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Статті в журналах з теми "Pasture plants Physiology"
Hewitt, George B., and Jerome A. Onsager. "EFFECTS OF SAGEBRUSH REMOVAL AND LEGUME INTERSEEDING ON RANGELAND GRASSHOPPER POPULATIONS (ORTHOPTERA: ACRIDIDAE)." Canadian Entomologist 120, no. 8-9 (September 1988): 753–58. http://dx.doi.org/10.4039/ent120753-8.
Повний текст джерелаGarcía-Favre, Javier, Ignacio F. López, Lydia M. Cranston, Daniel J. Donaghy, and Peter D. Kemp. "The Growth Response of Pasture Brome (Bromus valdivianus Phil.) to Defoliation Frequency under Two Soil-Water Restriction Levels." Agronomy 11, no. 2 (February 8, 2021): 300. http://dx.doi.org/10.3390/agronomy11020300.
Повний текст джерелаMoro, Adriana L., Ana Claudia Pacheco, and Edemar Moro. "Physiological and Biochemical Alterations of Urocholoa brizantha Submitted to Water Deficit and Silicate Fertilization." Journal of Agricultural Science 10, no. 8 (July 10, 2018): 166. http://dx.doi.org/10.5539/jas.v10n8p166.
Повний текст джерелаPremazzi, Linda Monica, Francisco Antonio Monteiro, and José Eduardo Corrente. "Tillering of Tifton 85 bermudagrass in response to nitrogen rates and time of application after cutting." Scientia Agricola 60, no. 3 (2003): 565–71. http://dx.doi.org/10.1590/s0103-90162003000300023.
Повний текст джерелаPerera, Cullen, and Eckard. "Growth and Physiological Responses of Temperate Pasture Species to Consecutive Heat and Drought Stresses." Plants 8, no. 7 (July 16, 2019): 227. http://dx.doi.org/10.3390/plants8070227.
Повний текст джерелаChapman, D. F., J. M. Lee, and G. C. Waghorn. "Interaction between plant physiology and pasture feeding value: a review." Crop and Pasture Science 65, no. 8 (2014): 721. http://dx.doi.org/10.1071/cp13379.
Повний текст джерелаCasal, Jorge J., and Sureshkumar Balasubramanian. "Thermomorphogenesis." Annual Review of Plant Biology 70, no. 1 (April 29, 2019): 321–46. http://dx.doi.org/10.1146/annurev-arplant-050718-095919.
Повний текст джерелаMartinez, Carlos Alberto, Eduardo Augusto Dias de Oliveira, Tathyana Rachel Palo Mello, and Ana Lilia Alzate-Marin. "Respostas das plantas ao incremento atmosférico de dióxido de carbono e da temperatura (Plants responses to increase in atmospheric carbon dioxide and temperature)." Revista Brasileira de Geografia Física 8 (December 15, 2015): 635. http://dx.doi.org/10.26848/rbgf.v8.0.p635-650.
Повний текст джерелаKemp, PD, and GJ Blair. "Phosphorus efficiency in pasture species. VIII. Ontogeny, growth, P acquisition and P utilization of Italian ryegrass and phalaris under P deficient and P sufficient conditions." Australian Journal of Agricultural Research 45, no. 3 (1994): 669. http://dx.doi.org/10.1071/ar9940669.
Повний текст джерелаSilveira Júnior, Otacilio, Antonio Clementino dos Santos, Marcos Odilon Dias Rodrigues, Márcio Odilon Dias Rodrigues, and Nayara Martins Alencar. "Productive efficiency of mombasa grass in silvopastoral system under pasture deferment and nitrogen fertilizer." Semina: Ciências Agrárias 38, no. 5 (October 3, 2017): 3307. http://dx.doi.org/10.5433/1679-0359.2017v38n5p3307.
Повний текст джерелаДисертації з теми "Pasture plants Physiology"
Mello, Alexandre Carneiro Leão de. "Respostas morfofisiológicas do capim Tanzânia (Panicum maximum Jacq. cv. Tanzânia) irrigado à intensidade de desfolha sob lotação rotacionada." Universidade de São Paulo, 2002. http://www.teses.usp.br/teses/disponiveis/11/11139/tde-25102002-095854/.
Повний текст джерелаResearch has often not emphasized the importance of morphological and physiological traits that are related to the productivity of tropical forages under grazing. There is a need for clarification on how does the sward respond to specific defoliation regimes, in relation to plant morphology, sward structure and architecture, as well as physiological processes such as photosynthesis, so that optimum grazing methods can be devised. The objective of this research was to quantify morphological and physiological responses of Tanzania grass (Panicum maximum Jacq. cv. Tanzania) under three grazing intensities in an irrigated, rotationally stocked setting, in order to establish cause-effect relationships not only among the variables under study, but also between each of them and pasture productivity, expressed as forage dry mass accumulation. The experiment was conducted at Fazenda Areão of USP-ESALQ, in Piracicaba, SP, on a 4,8-ha pasture of Tanzania grass. Treatments consisted of three grazing intensities, represented by three post-graze forage masses (T1=1000, T2=2500, and T3=4000 kg green dry mass ha -1 ), in a randomized complete block design with four replications. During the grazing season (eight 36-d cycles; 3 d grazing followed by 33 d rest) the following measurements were taken: mean sward height, leaf area index (LAI), light interception (LI), mean leaf angles, net leaf photosynthesis (NLP), and leaf temperature (LT), all measured on four occasions (1, 11, 22, and 33 days after grazing was terminated) of each rest period. Forage mass (FM) was measured in a companion study and mass values were used to calculate forage accumulation and accumulation trates. Calibrations were done between forage mass and sward height and used to estimate mass from height during the regrowth phase. Partial correlation analysis indicated the existence of correlations between height and FM, height and LI, LAI and LI, and leaf angles and FM. As the grazing season progressed from spring-summer to autumn-winter, NLP rates, LT, and mean LAI declined. Mean critical LAI (95% LI) was 3.3 (T1), 3.8 (T2), and 4.2 (T3) and was always reached around the 22nd day after grazing. No differences were found in forage accumulation rate (mean = 88.7 kg dry matter ha -1 d -1 )or in total seasonal accumulation (mean = 21652 kg DM ha -1 ) among treatments. Over the season, hard grazing (lower residual mass) altered the sward structure causing shifts in plant architecture, as shown by reduced (more horizontal) leaf angles, as plants begun to intercept more light per unit of leaf area. Critical LAI values suggest that relatively short rest periods may be advantageous for Tanzania grass pastures managed intensively under rotational stocking and irrigation. Hard grazing (1000 kg residual green dry matter ha -1 ) also did not depress regrowth vigor, measured as mean forage accumulation rate. There is a need, however, to assess the long-term persistence of these intensively managed, heavily grazed pastures. Grazing management in these intensive systems should aim at post-graze forage masses that allow for maximum accumulation rates in early regrowth.
Faria, Ana Flávia Gouvéia de. "Morfogênese e análise de crescimento de três capins tropicais em resposta à frequência de desfolhação." Universidade de São Paulo, 2014. http://www.teses.usp.br/teses/disponiveis/11/11139/tde-03122014-143934/.
Повний текст джерелаFor the potential of cultivars most commonly used as Marandu palisadegrass {Brachiaria brizantha (Hochst. ex A. Rich.) RD Webster [syn. Urochloa brizantha (A. Rich.) Stapf]; CIAT 6297}, with high forage production as Tifton 85 (Cynodon spp.), and grasses recently released as Mulato II (Convert HD 364®) (Brachiaria híbrid CIAT 36061) to be rationally and intensively explored it is necessary to understand how harvest frequency affects productive responses, under a physiological standpoint. The objective was to evaluate and describe the effect of harvest frequency on the growth characteristics of Mulato II, Marandu, and Tifton 85, as well as to study morphogenesis characteristics in Mulato II and Marandu. The experimental design was a randomized complete block with four replications. The trial was carried out in Piracicaba - SP. Response variables included leaf area index (LAI), crop growth rate (CGR), relative growth rate (RGR), net assimilation rate (NAR), leaf area ratio (LAR) and leaf weight ratio (LWR). In addition phyllocron, number of live leaves per tiller (NLL), stem (SER) and leaf elongation rate (LER), leaf appearance rate (LApR), tiller density population (TDP) and leaf senescence (LSR). Mulato II is a option to intensify and diversify pasture grasses in tropical areas due to its high LAI, CGR, LWR and LAR. CGR was similar between Mulato II and Tifton 85 but LWR was highest to Mulato II. On the other hand, Tifton 85 starts the lowest LAI but has high NAR and reaches the same CGR to Mulato II, showing also as good forage option. The LApR and LER were higher an Marandu than Mulato II. Phyllochron was higher in Mulato II compared to Marandu. There was an interaction harvest frequency x year to phyllochron, and with 28 days the lowest phyllochron was at first year, and with 42 days there was no difference between two years. The LER, SER and LSR were higher with 42 days of harvest frequency. There was interaction harvest frequencies x year and cultivars x harvest frequencies to NLL. This was higher in the first year with 28 and 42 days, and at 42 days in both years studied. NLL was equal in Marandu and Mulato II with 28 days and higher in Marandu with 42 days. Marandu and Mulato II had higher NLL with 42 days. CGR is similar in Mulato II and Tifton 85, but the LWR is highest in Mulato II. Tifton 85 had lowest residual LAI, but high NAR and CGR similar to Mulato II. Mulato II and Tifton 85 used different mechanisms to achieve the same CGR. 28 days prioritizes leaf production. In morphogenesis, Marandu is the best because it presented the highest growth rates (LApR, LER, NLL) and lowest phyllochron. Despite Marandu was better than Mulato II, it did not reflect in greater herbage accumulation and nutritive value, due greater TDP in Mulato II. There was highest SER and LSR with 42 days, so 28 days is best to avoid high SER. When there is adequate precipitation, lowest frequency (28 days) increase harvest efficiency.
Gonçalves, Alexandre de Campos. "Características morfogênicas e padrões de desfolhação em pastos de capim marandu submetidos a regimes de lotação contínua." Universidade de São Paulo, 2003. http://www.teses.usp.br/teses/disponiveis/11/11139/tde-08082003-140411/.
Повний текст джерелаThe lack of information on the ecophysiology of tropical pasture species limits the adjustment of grazing management practices that allow for the best possible utilization of their forage production potential. Bearing that in mind, the present experiment, carried out at the Departamento de Zootecnia, USP/ESALQ, Piracicaba, SP, evaluated the morphogenetic characteristics and defoliation patterns of Brachiaria brizantha (Hochst ex A. Rich) cultivar Marandu from November 2001 to February 2002. Treatments corresponded to four sward state conditions (10, 20, 30 and 40 cm sward surface height) generated by cattle grazing under continuous stocking with variable stocking rate and were allocated to experimental units according to a complete randomized block design with four replications. The evaluated responses were: (1) morphogenetic characteristics: leaf appearance rate (LAR), phyllochron, number of leaves per tiller and leaf life span; (2) individual tiller defoliation patterns: frequency and intensity of defoliation and grazing efficiency (utilization). Short swards (10 cm) presented higher LAR (0.12 leaf/tiller.day and 0.012 leaf/tiller.degree-day) and smaller phyllochrone (9.0 days/leaf and 84.8 degree-days/leaf) than tall swards (20, 30 and 40 cm) (0.11, 0.10, 0.10 leaf/tiller.day and 0.011, 0.011, 0.010 leaf/tiller.degree-day; 10.3, 10.3, 10.9 days/leaf and 95.1, 95.1, 100.6 degree-days/leaf, respectively), the latter three being the same (P > 0.10). Leaf life span followed the phyllochron results (34.4, 43.1, 45.5, 48.4 days/leaf and 332.1, 441.6, 433.5, 462.0 degree-days/leaf for the 10, 20, 30 and 40 cm swards, respectively) since no variation was observed in number of leaves per tiller (4.5 leaves/tiller) (P > 0.10). Variations in morphogenetic characteristics throughout the experiment were due to the phenological state of plants, which changed from vegetative to reproductive. Frequency (0.077 defoliation/tiller.day) and intensity (0.296 proportion of the original length removed by grazing) of defoliation of individual tillers were biggest in the 10 cm-swards (P < 0.10). In the 20, 30 and 40 cm-swards defoliation intensity remained relatively constant (0.173) (P > 0.10), while defoliation frequency decreased as sward surface height increased (0.068, 0.067, 0.056 for the 20, 30 and 40 cm-swards, respectively) (P < 0.10). A similar trend was obtained when frequency and intensity of defoliation were calculated on a per leaf basis (0.043, 0.033, 0.031, 0.026 e 0.760, 0.683, 0.654, 0.665, respectively, for the 10, 20, 30 and 40 cm-swards). There was a positive relationship between the stocking rate used to generate experimental treatments and the resulting frequency and intensity of defoliation of individual tillers. Senescing leaves were defoliated less severely than mature and expanding leaves, particularly because of the lower frequency with which they were visited (0.009, 0.028, 0.024, respectively), since corresponding variations in defoliation intensity were small. Pasture utilization efficiency was highest in the 10 cm-swards (82.3%), a consequence of their high frequency and intensity of defoliation that resulted in decreased leaf life span under those circumstances. Increasing sward surface height resulted in decreasing utilization efficiency (76.2, 69.4 and 68.7% for the 20, 30 and 40 cm-swards, respectively). Regardless of sward surface height, the top 33% of the sward height was used for grazing, indicating potential restrictions to herbage consumption of cattle grazing short pastures.
Detomini, Euro Roberto. "Modelagem da produtividade potencial de Brachiaria brizantha (variedades cultivadas Marandu e Xaraés." Universidade de São Paulo, 2004. http://www.teses.usp.br/teses/disponiveis/11/11136/tde-30082004-172539/.
Повний текст джерелаWith the main goal to purpose a model to estimate the total plant biomass (dry matter) potential productivity (forage removed under cutting management intensive system and optimal conditions) of Brachiaria brizantha, cultivars Marandu and Xaraés, as a function of global solar radiation and air temperature, besides the following goals: (i) acquiring a response curve that might show the shoot and root dried biomass potential productivity regarding to the relative development; (ii) characterizing the dry-matter productivity of leaves, stems and senescing structures of shoots; (iii) identifying the optimal time to pasture cutting; and (iv) characterizing the leaf area index temporal variation; field experiments were carried in Crop Production Department experimental area of Universidade de São Paulo (Piracicaba, SP, Brazil) from November 22nd of 2003 to January 26th of 2004. According to results acquired, it is possible to conclude: (i) the purposed model greatly simulates the total plant biomass (dry matter) potential productivity of Brachiaria brizantha, cultivars Marandu and Xaraés, as a function of year season (from cutting date), climatic variables (daily mean values of global solar radiation and air temperature) and local latitude; (ii) from modeling and field experiments taken together; it is possible to obtain a response-curve reporting the biomass potential productivity of shoot and root compartments as a function of relative development from observed shoot and root dry-matter values, leaf area index (LAI), air temperature and global solar radiation; (iii) the empirical equations greatly denote the productivity temporal variation of leaves, stems and senescing structures dry matter; (iv) the optimal time to both forage utilization (cutting) is around 64% of relative development due to after this moment the shoot dry-matter productivity is strongly affected by increases in stems and senescing structures productivities, otherwise leaf productivity rates decrease as much as relative development raises; and (v) the leaf area index temporal variation of both genotypes might be characterized as a exponential-growth response.
(7371827), Miguel A. Lopez. "Developing the Yield Equation for Plant Breeding Purposes in Soybean (Glycine max L. Merr)." Thesis, 2019.
Знайти повний текст джерелаDissecting the soybean grain yield (GY) to approach it as a sum of its associated processes seems a viable approach to explore this trait considering its complex multigenic nature. Monteith (1972, 1977) first defined potential yield as the result of three physiological efficiencies: light interception (Ei), radiation use efficiency (RUE) and harvest index (HI). Though this rationality is not recent, few works assessing these three efficiencies as strategies to improve crops have been carried out. This thesis approaches yield from the perspective of Ei, RUE, and HI to better understand yield as the result of genetic and physiological processes. This study reveals the phenotypic variation, heritability, genetic architecture, and genetic relationships for Ei, RUE, and HI and their relationships with GY and other physiological and phenological variables. Similarly, genomic prediction is presented as a viable strategy to partially overcome the tedious phenotyping of these traits. A large panel of 383 soybean recombinant inbred lines (RIL) with significant yield variation but shrinkage maturity was evaluated in three field environments. Ground measurements of dry matter, photosynthesis (A), transpiration (E), water use efficiency (WUE), stomatal conductance (gs), leaf area index (LAI) and phenology (R1, R5, R8) were measured. Likewise, RGB imagery from an unmanned aircraft system (UAS) were collected with high frequency (~12 days) to estimate the canopy dynamic through the canopy coverage (CC). Light interception was modeled through a logistic curve using CC as a proxy and later compared with the seasonal cumulative solar radiation collected from weather stations to calculate Ei. The total above ground biomass collected during the growing season and its respective cumulative light intercepted were used to derive RUE through linear models fitting, while apparent HI was calculated through the ratio seeds dry matter vs total above-ground dry matter. Additive-genetic correlations, genome wide association (GWA) and whole genome regressions (WGR) were performed to determine the relationship between traits, their association with genomic regions, and the feasibility of predicting these efficiencies through genomic information. Our results revealed moderate to high phenotypic variation for Ei, RUE, and HI. Additive-genetic correlation showed a strong relationship of GY with HI and moderate with RUE and Ei when the whole data set was considered, but negligible contribution of HI on GY when just the top 100 yielding RILs were analyzed. High genetic correlation to grain yield (GY) was also observed for A (0.87) and E (0.67), suggesting increase in GY can be achieved through the improvement of A or E. The GWA analyses showed that Ei is associated with three SNPs; two of them located on chromosome 7 and one on chromosome 11 with no previous quantitative trait loci (QTLs) reported for these regions. RUE is associated with four SNPs on chromosomes 1, 7, 11, and 18. Some of these QTLs are novel, while others are previously documented for plant architecture and chlorophyll content. Two SNPs positioned on chromosome 13 and 15 with previous QTLs reported for plant height and seed set, weight and abortion were associated with HI. WGR showed high predictive ability for Ei, RUE, and HI with maximum correlation ranging between 0.75 to 0.80. Both directed and undirected multivariate explanatory models indicate that HI has a strong relationship with A, average growth rate of canopy coverage for the first 40 days after planting (AGR40), seed-filling (SFL), and reproductive length (RL). According to the path analysis, increase in one standard unit of HI promotes changes in 0.5 standard units of GY, while changes in the same standard unit of RUE, and Ei produce increases on GY of 0.20 and 0.19 standard units. This study presents novel genetic knowledge for Ei, RUE, HI and GY along with a set of tools that may contribute to the development of new cultivars with enhanced light interception, light conversion and optimized dry matter partitioning in soybean. This work not only complements the physiological knowledge already available with the genetic control of traits directly associated with yield, but also represents a pioneer attempt to integrate traditional physiological traits into the breeding process in the context of physiological breeding
Sun, Xuezhao. "Structure, composition and degradation of the cell walls of forage chicory (Cichorium intybus L.) leaves : a thesis presented in partial fulfilment of the requirements for the degree of Doctor of Philosophy in Nutritional Science at Massey University, Palmerston North, New Zealand." 2006. http://hdl.handle.net/10179/1498.
Повний текст джерелаBurggraaf, Victoria G. "The feeding value for dairy cows and the agronomic performance of white clover (Trifolium repens L.) selected for increased floral condensed tannin : a thesis presented in partial fulfilment of the requirements for the degree of Doctor of Philosophy in Plant Science at Massey University, Palmerston North, New Zealand." 2005. http://hdl.handle.net/10179/1531.
Повний текст джерелаLegumes containing 20 to 40 g of condensed tannin (CT) per kg of dry matter (DM) can improve dairy cow milk production by reducing ruminal protein degradation to ammonia and preventing bloat. White clover (Triflium repens L.) produces CT in its flower heads. High tannin (HT) white clover, bred for increased flowering and increased floral CT concentration, was evaluated under dairy grazing in Hamilton, New Zealand. Its performance in monoculture was compared to that of Grasslands Huia white clover over two years, and five short-term grazing experiments determined its effects on Friesian dairy cows. Huia and HT had similar floral CT concentrations, ranging from 15 to 77 g/kg DM over two flowering seasons. HT clover had higher flower densities than Huia until the second summer after sowing, resulting in higher clover (leaf plus flower) CT concentrations. Clover CT peaked at 12.1 g/kg DM for HT and 5.7 g/kg DM for Huia. HT swards had lower stolon growing point densities than Huia swards and annual DM yields averaged 10.0 and 11.0 t DM/ha for the respective clovers. The ingress of non-sown white clover genotypes reduced treatment differences in the last 10 months of the experiment. Mild bloat occurred in cows grazing both clovers. Cows grazing HT white clover had rumen ammonia concentrations 5 to 26% lower than that of cows grazing Huia, indicating less proteolysis in the rumen of HT cows, but there were no consistent effects on rumen soluble protein or volatile fatty acids (VFA). Differences between treatments in dietary CT concentrations were too small to affect milk production or composition. Minced mixtures of 0, 25, 50, 75 or 100% of DM as white clover flower with the remainder as white clover leaf, were incubated in vitro and rumen metabolite concentrations determined at 0, 2 ,4, 8, 12 and 24 hours. Polyethylene glycol was added to one of the 50% flower treatments to inactivate CT. Clover flowers had less soluble protein than leaves at 0 hours, and increasing the percentage of flowers from 0 to 100% reduced the net conversion of plant-N to ammonia-N from 29 to 12%. The contribution of CT to these effects was small. Increasing percentages of clover flowers did not significantly affect total VFA production but increased acetate to propionate (A:P) ratios. White clover CT decreased A:P ratios. In another in vitro experiment perennial ryegrass leaf (Lolium perenne L.) was incubated either alone or with white clover flowers or birdsfoot trefoil (Lotus corniculatus L.). Clover flowers were more effective at reducing proteolysis than birdsfoot trefoil, due largely to less release of soluble protein, but birdsfoot trefoil treatments had the lowest A:P ratios. In conclusion, HT clover had higher forage CT concentrations than Huia because of increased flowering. Increased flowering reduced the agronomic performance of HT and lowered rumen ammonia concentrations, but did not increase milk production or prevent bloat. White clover flowers reduced rumen proteolysis in vitro, but this was mainly a result of their low protein concentration. White clover CT and birdsfoot trefoil forage benefited the molar percentages of VFA, but increasing the proportion of clover flowers did not. Further increases in white clover CT concentrations may benefit ruminant performance, but this should not be implemented through increased flowering.
(8797199), Blake A. Russell. "Trait Identification to Improve Yield and Nitrogen Use Efficiency in Wheat." Thesis, 2020.
Знайти повний текст джерелаWheat is a major source of calories and protein for humans worldwide. Wheat is the most widely grown crop, with cultivation areas and production systems on every continent. The cultivated land area is vast because of its importance and adaptability to various environmental conditions. Global wheat production has not kept up with the growing population, provoking the need to develop new methods and techniques to increase genetic gains. The first research chapter of this Ph.D. dissertation involves performing genome-wide association studies (GWAS) to identify and examine transferability of marker-trait associations (MTAs) across environments. I evaluated yield and yield components traits among 270 soft red winter (SRW) wheat varieties. The population consists of experimental breeding lines adapted to the Midwestern and eastern United States and developed by public university breeding programs. Phenotypic data from a two-year field study and a 45K-SNP marker dataset were analyzed by FarmCPU model to identify MTAs for yield related traits. Grain yield was positively correlated with thousand kernel weight, biomass, and grain weight per spike while negatively correlated with days to heading and maturity. Sixty-one independent loci were identified for agronomic traits, including a region that with –logP of 16.35, which explained 18% of the variation in grain yield. Using 12 existing datasets from other states and seasons, in addition to my own data, I examined the transferability of significant MTAs for grain yield and days to heading across homogenous environments. For grain yield and days to heading, I only observed 6 out of 28 MTAs to hold up across homogenous environments. I concluded that not all marker-trait associations can be detected in other environments.
In the second research chapter of this Ph.D. dissertation, I dissected yield component traits under contrasting nitrogen environments by using field-based low-throughput phenotyping. I characterized grain yield formation and quality attributes in soft red winter wheat. Using a split-block design, I studied responses of 30 experimental lines, as sub-plot, to high nitrogen and low nitrogen environment, as main-plot, for two years. Differential N environments were imposed by the application, or lack thereof, of spring nitrogen application in a field, following a previous corn harvest. In this study, I measured agronomic traits, in-tissue nitrogen concentrations, nitrogen use efficiency, nitrogen harvest index and end-use quality traits on either all or subset of the germplasm. My data showed that biomass, number of spikes and total grain numbers per unit area were most sensitive to low nitrogen while kernel weight remained stable across environments. Significant genotype x N-environment interaction allowed me to select N-efficient germplasm, that can be used as founding parents for a potential breeding population specifically for low-N environments. I did this selection on the basis of superior agronomic traits and the presence of the desirable gluten quality alleles such as Glu-A1b (2*) and Glu-D1d (5+10).
Частини книг з теми "Pasture plants Physiology"
McCloud, Darell E. "Forage Plant Physiology in the Improvement of Pastures." In Forage Plant Physiology and Soil-Range Relationships, 121–31. Madison, WI, USA: American Society of Agronomy, 2015. http://dx.doi.org/10.2134/asaspecpub5.c8.
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