Your search keyword '"phosphorus utilization efficiency"' showing total 14 results

1. Plant-root-litter-soil C, N, P stoichiometry and plant phosphorus accumulation and utilization response to warming and phosphorus input in desert steppe

Author

Lingxia Feng and Bing Cao

Subjects

Warming, Phosphorus accumulation, Phosphorus utilization efficiency, Desert steppe, Ecology, QH540-549.5

Abstract

Nutrient cycling in desert steppe can be affected by continuous climate warming and exogenous nutrient inputs. This would alter plant nutrient uptake and utilization, affecting the plant production and service functions of desert ecosystems. However, we know remarkably little about the patterns of the plant-root-litter-soil system nutrient redistribution response to warming and phosphorus input in the P-limited desert steppe. The relationships between plant-root-litter-soil C, N, P contents, stoichiometry, and plant, root phosphorus accumulation and utilization are unclear. In this study, open-top chambers (OTCs) were used to simulate climate warming. We experimented with warming and phosphorus fertilizer application to explore the changes in C, N, P contents and stoichiometry along the plant-root-litter-soil continuum, and the relationships with plant, root phosphorus accumulation, and phosphorus utilization efficiency. The study demonstrated that warming increased root C, N contents, and root N:P, without a corresponding change in phosphorus content across the plant-root-litter-soil continuum. Phosphorus addition significantly elevated plant P, root P, litter P, and soil available phosphorus (AP) and decreased its C:P and N:P. Thereby boosting plant, root phosphorus accumulation and reducing plant, root phosphorus utilization efficiency, further affecting plant production. The key influence factors of plant, root phosphorus accumulation and utilization efficiency were root P, root C:N, and plant C:P. The results highlighted that the altered plant-root-litter-soil C:N:P stoichiometry induced by warming and exogenous phosphate fertilizer input would regulate plant, root phosphorus uptake and utilization patterns to adapt to the P-deficient soil environment in desert steppe.

Published

2024

2. The Impact of Various Organic Phosphorus Carriers on the Uptake and Use Efficiency in Barley

Author

Yuanfeng Huo, Jingyue Wang, Yinggang Xu, Deyi Hu, Kexian Zhang, Bingjie Chen, Yueyi Wu, Jiaxin Liu, Tianlang Yan, Yang Li, Chaorui Yan, Xuesong Gao, Shu Yuan, and Guangdeng Chen

Subjects

organic phosphorus, rhizosphere, phosphorus utilization efficiency, genotypic difference, gene expression, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

Organic phosphorus (OP) is an essential component of the soil P cycle, which contributes to barley nutrition after its mineralization into inorganic phosphorus (Pi). However, the dynamics of OP utilization in the barley rhizosphere remain unclear. In this study, phytin was screened out from six OP carriers, which could reflect the difference in OP utilization between a P-inefficient genotype Baudin and a P-efficient genotype CN4027. The phosphorus utilization efficiency (PUE), root morphological traits, and expression of genes associated with P utilization were assessed under P deficiency or phytin treatments. P deficiency resulted in a greater root surface area and thicker roots. In barley fed with phytin as a P carrier, the APase activities of CN4027 were 2–3-fold lower than those of Baudin, while the phytase activities of CN4027 were 2–3-fold higher than those of Baudin. The PUE in CN4027 was mainly enhanced by activating phytase to improve the root absorption and utilization of Pi resulting from OP mineralization, while the PUE in Baudin was mainly enhanced by activating APase to improve the shoot reuse capacity. A phosphate transporter gene HvPHT1;8 regulated P transport from the roots to the shoots, while a purple acid phosphatase (PAP) family gene HvPAPhy_b contributed to the reuse of P in barley.

Published

2023

3. Biochemical and Molecular Responses Underlying the Contrasting Phosphorus Use Efficiency in Ryegrass Cultivars

Author

Sofía Pontigo, Leyla Parra-Almuna, Ana Luengo-Escobar, Patricia Poblete-Grant, Adriano Nunes-Nesi, María de la Luz Mora, and Paula Cartes

Subjects

phosphorus acquisition efficiency, phosphorus utilization efficiency, phosphate transporters, acid phosphatases, ryegrass, Botany, QK1-989

Abstract

Improving plant ability to acquire and efficiently utilize phosphorus (P) is a promising approach for developing sustainable pasture production. This study aimed to identify ryegrass cultivars with contrasting P use efficiency, and to assess their associated biochemical and molecular responses. Nine ryegrass cultivars were hydroponically grown under optimal (0.1 mM) or P-deficient (0.01 mM) conditions, and P uptake, dry biomass, phosphorus acquisition efficiency (PAE) and phosphorus utilization efficiency (PUE) were evaluated. Accordingly, two cultivars with high PAE but low PUE (Ansa and Stellar), and two cultivars with low PAE and high PUE (24Seven and Extreme) were selected to analyze the activity and gene expression of acid phosphatases (APases), as well as the transcript levels of P transporters. Our results showed that ryegrass cultivars with high PAE were mainly influenced by root-related responses, including the expression of genes codifying for the P transporter LpPHT1;4, purple acid phosphatase LpPAP1 and APase activity. Moreover, the traits that contributed greatly to enhanced PUE were the expression of LpPHT1;1/4 and LpPHO1;2, and the APase activity in shoots. These outcomes could be useful to evaluate and develop cultivars with high P-use efficiency, thus contributing to improve the management of P in grassland systems.

Published

2023

4. Genetic Variation for Traits Related to Phosphorus Use Efficiency in Vigna Species

Author

Deepali Kothari, Nirmala Pargaien, Lalit Mohan Tewari, Harsh Kumar Dikshit, Gyan Prakash Mishra, Muraleedhar S. Aski, Ruchi Bansal, Sanjeev Gupta, Shiv Kumar, and Ramakrishnan Madhavan Nair

Subjects

Vigna, phosphorus uptake efficiency, phosphorus utilization efficiency, phosphorus-use efficiency, Agriculture

Abstract

Phosphorus (P) is a major limiting nutrient reducing crop yields especially in weathered soils of the subtropics and tropics. P exhibits poor mobility and availability to plants in soil. To overcome P deficiency in soil, phosphatic fertilizers are added. Global phosphate rock reserves are finite, and the addition of phosphatic fertilizers is not financially and ecologically sustainable. Mungbean (Vigna radiata (L.) Wilczek) is important grain legume for nutritional security. Attempts are being made to develop mungbean varieties with better P-use efficiency through enhanced P uptake and utilization. In the present study, 327 accessions of 18 Vigna species were examined for inter- and intra-specific variation for traits related to phosphorus uptake and utilization efficiency under hydroponic conditions at two levels of phosphorus. Significant species-specific variation was recorded for studied traits. Among the studied Vigna species, mungbean exhibited higher phosphorus use efficiency. Seven mungbean genotypes (IC 251950, IC 585931, V1002532AG, IC 371653, IC 331615, V1001400AG, and V1000532BG) were found to be promising for both PupE and PutiE. Using mean and standard deviation as criteria, mungbean genotypes identified with high phosphorus-use efficiency include IC 25950 and IC 583664. Mungbean genotypes KPS 1546, IC 277060, IC 697141, IC 343440, and Pusa 0831 were identified based on the stress tolerance index as genotypes that performed better under P stress. Cultivated species revealed higher PUE in comparison withwild forms. The most promising genotype identified from this study for PUE can be used as a parent for the development of a mapping population of mungbean for understanding genetics of PUE under a low-phosphorus environment.

Published

2023

5. Root Morphological and Physiological Adaptations to Low Phosphate Enhance Phosphorus Efficiency at Melon (Cucumis melo L.) Seedling Stage

Author

Pengli Li, Jinyang Weng, Asad Rehman, and Qingliang Niu

Subjects

low phosphate, root morphology, acid phosphatase, phosphate transporter genes, phosphate uptake rate, phosphorus utilization efficiency, Plant culture, SB1-1110

Abstract

The high phosphorus (P) acquisition ability of crops can reduce their dependence on artificial inorganic phosphate (Pi) supplementation under Pi-limited conditions. Melon (Cucumis melo L.) is vulnerable to Pi deficiency. This study was carried out to explore the morphological and physiological responses of melon to low-Pi stress under a hydroponic system. The results show that low-Pi stress significantly disturbed nutrient homeostasis, reduced P content, and resulted in iron accumulation in melon seedlings and brown iron plaque formation on the root surface. A nutrient pool of P and Fe formed on the roots to forage for more Pi under low-Pi conditions. Severe long-term low-Pi stress promoted primary root elongation and inhibited lateral root growth, which increased the longitudinal absorption zone of the roots. The decrease in P content of the roots upregulated the expression of the acid phosphatase (APase) gene and increased APase activity. The high-affinity phosphate transporter (Pht1) genes were also upregulated significantly. These morphological and physiological responses significantly increased Pi uptake rate and P utilization efficiency at the melon seedling stage. These findings will be useful for screening low-Pi-tolerant varieties and sustaining melon production in P-limited environments.

Published

2022

6. A major quantitative trait locus controlling phosphorus utilization efficiency under different phytate-P conditions at vegetative stage in barley

Author

Shang-qing GAO, Guang-deng CHEN, De-yi HU, Xi-zhou ZHANG, Ting-xuan LI, Shi-hang LIU, and Chun-ji LIU

Subjects

barley, phosphorus utilization efficiency, quantitative trait locus, recombinant inbred line, phytate-P, Agriculture (General), S1-972

Abstract

Organic phosphorus (P) is an important component of the soil P pool, and it has been proven to be a potential source of P for plants. The phosphorus utilization efficiency (PUE) and PUE related traits (tiller number (TN), shoot dry weight (DW), and root dry weight) under different phytate-P conditions (low phytate-P, 0.05 mmol L−1 and normal phytate-P, 0.5 mmol L−1) were investigated using a population consisting of 128 recombinant inbred lines (RILs) at the vegetative stage in barley. The population was derived from a cross between a P-inefficient genotype (Baudin) and a P-efficient genotype (CN4027, a Hordeum spontaneum accession). A major locus (designated Qpue.sau-3H) conferring PUE was detected in shoots and roots from the RIL population. The quantitative trait locus (QTL) was mapped on chromosome 3H and the allele from CN4027 confers high PUE. This locus explained up to 30.3 and 28.4% of the phenotypic variance in shoots under low and normal phytate-P conditions, respectively. It also explains 28.3 and 30.7% of the phenotypic variation in root under the low and normal phytate-P conditions, respectively. Results from this study also showed that TN was not correlated with PUE, and a QTL controlling TN was detected on chromosome 5H. However, dry weight (DW) was significantly and positively correlated with PUE, and a QTL controlling DW was detected near the Qpue.sau-3H locus. Based on a covariance analysis, existing data indicated that, although DW may affect PUE, different genes at this locus are likely involved in controlling these two traits.

Published

2018

7. Characterization and Selection of Phosphorus Deficiency Tolerant Rice Genotypes in Sri Lanka

Author

Y.C. Aluwihare, M. Ishan, M.D.M. Chamikara, C.K. Weebadde, D.N. Sirisena, W.L.G. Samarasinghe, and S.D.S.S. Sooriyapathirana

Subjects

phosphorus, tolerance, rice, genotype, phosphorus utilization efficiency, landrace, Plant culture, SB1-1110

Abstract

Phosphorus (P) deficiency in soil is a major constrain for rice production. An important set of rice genotypes (landraces, old improved and new improved varieties) were screened for P deficiency tolerance in two major cropping seasons of Sri Lanka, in 2012. The Ultisol soil, which was collected from a plot cultivated with rice without fertilizer application for past 40 years (P0) at the Rice Research and Development Institute (RRDI), Bathalagoda, Sri Lanka, was used as the potting medium for greenhouse trials. Two field trials were conducted in the same plots at RRDI. Both P0 and P30 (30 mg/kg P2O5) conditions were used in the two greenhouse trials. At the early vegetative (three weeks after transplanting), late vegetative (six weeks after transplanting) and flowering stages, plant height and number of tillers per plant were recorded. At the flowering stage, shoots were harvested and shoot dry weight, shoot P concentration, shoot P uptake and P utilization efficiency were measured. All data were statistically analyzed using analysis of variance, regression and cluster procedures. The measured parameters were significantly different between P0 and P30 conditions (P < 0.05). Higher shoot dry weight was reported by the rice genotypes H4 and Marss under P0 conditions. The regression analysis between shoot dry weight and P utilization efficiency revealed that the studied rice genotypes could be categorized to three P deficiency tolerance classes. A total of 13 genotypes could be considered as highly tolerant and 4 genotypes as sensitive for P deficiency. These results could be used to select parental genotypes for breeding and genetic studies and also to select interesting varieties or landraces for organic rice production.

Published

2016

8. Phosphorus Nutrition Affects Temperature Response of Soybean Growth and Canopy Photosynthesis

Author

Shardendu K. Singh, Vangimalla R. Reddy, David H. Fleisher, and Dennis J. Timlin

Subjects

carbon balance, carbon gain, Glycine max, phosphorus utilization efficiency, T × P interaction, tissue phosphorus, Plant culture, SB1-1110

Abstract

In nature, crops such as soybean are concurrently exposed to temperature (T) stress and phosphorus (P) deficiency. However, there is a lack of reports regarding soybean response to T × P interaction. To fill in this knowledge-gap, soybean was grown at four daily mean T of 22, 26, 30, and 34°C (moderately low, optimum, moderately high, and high temperature, respectively) each under sufficient (0.5 mM) and deficient (0.08 mM) P nutrition for the entire season. Phosphorus deficiency exacerbated the low temperature stress, with further restrictions on growth and net photosynthesis. For P deficient soybean at above optimum temperature (OT) regimes, growth, and photosynthesis was maintained at levels close to those of P sufficient plants, despite a lower tissue P concentration. P deficiency consistently decreased plant tissue P concentration ≈55% across temperatures while increasing intrinsic P utilization efficiency of canopy photosynthesis up to 147%, indicating a better utilization of tissue P. Warmer than OTs delayed the time to anthesis by 8–14 days and pod development similarly across P levels. However, biomass partitioning to pods was greater under P deficiency. There were significant T × P interactions for traits such as plant growth rates, total leaf area, biomass partitioning, and dry matter production, which resulted a distinct T response of soybean growth between sufficient and deficient P nutrition. Under sufficient P level, both lower and higher than optimum T tended to decrease total dry matter production and canopy photosynthesis. However, under P-deficient condition, this decrease was primarily observed at the low T. Thus, warmer than optimum T of this study appeared to compensate for decreases in soybean canopy photosynthesis and dry matter accumulation resulting from P deficiency. However, warmer than OT appeared to adversely affect reproductive structures, such as pod development, across P fertilization. This occurred despite adaptations, especially the increased P utilization efficiency and biomass partitioning to pods, shown by soybean under P deficiency.

Published

2018

9. The Soybean Purple Acid Phosphatase GmPAP14 Predominantly Enhances External Phytate Utilization in Plants

Author

Youbin Kong, Xihuan Li, Bing Wang, Wenlong Li, Hui Du, and Caiying Zhang

Subjects

purple acid phosphatase, acid phosphatase, phytate, phosphorus utilization efficiency, soybean, Plant culture, SB1-1110

Abstract

Induction and secretion of acid phosphatases (APases) is considered to be an important strategy for improving plant growth under conditions of low inorganic phosphate (Pi). Purple acid phosphatases (PAPs), are an important class of plant APases that could be secreted into the rhizosphere to utilize organic phosphorus (Po) for plant growth and development. To date, only a few members of the PAP family have been identified in soybean. In this paper, we identified a secreted PAP in soybean, GmPAP14, and investigated its role in utilizing external phytate, the main form of organic phosphorus in the soil. An analysis of its expression and promoter showed that GmPAP14 was mainly expressed in the root and was strongly induced following Po treatment, during which its expression expanded from meristematic to maturation zones and root hairs. In vitro enzyme assays indicated that GmPAP14 had a relatively high phytase activity. Furthermore, GmPAP14 overexpression increased secreted APase activities and phytase activities, leading to the improved use of external plant phytate, higher phosphorus content, and increased shoot weight. Thus, these results confirmed that GmPAP14 is an important gene induced in response to Po, and that it predominantly participates in utilizing external Po to enhance plant growth and development.

Published

2018

10. RELATIVE GROWTH RESPONSE OF HYDROPONICALLY GROWN WHEAT GENOTYPES TO DEFICIENT AND ADEQUATE PHOSPHORUS LEVELS

Author

M. Abbas, M. Aslam, J. A. Shah, N. Depar, and M. Y. Memon

Subjects

hydroponics, phosphorus levels, phosphorus utilization efficiency, wheat genotypes, Agriculture

Abstract

Phosphorus (P) nutrition is indispensable for plant growth and development. Seven wheat varieties (Sarsabz, Kiran-95, Khirman, NIA-Amber, NIA-Sunhari, NIA-Sunder and NIA-Saarang) were evaluated for their growth response to P deficient (0.02 mM) and adequate (0.20 mM) levels in hydroponic culture. A factorial combination of treatments, repeated four times, was arranged in a completely randomized design. Wheat varieties differed significantly (P< 0.01) in shoot and root dry matter production, root: shoot ratio, shoot and root P concentration and uptake, and shoot P utilization efficiency. Shoot P uptake and utilization efficiency were strongly correlated (r = 0.89, r = 0.77) with shoot dry matter production. On the basis of shoot dry matter production and P utilization efficiency, cultivars were grouped into four categories. NIA-Sunder, Sarsabz and Kiran-95 were efficient as well as responsive (ER) genotypes. Khirman, NIA-Sunhari, NIA-Saarang and NIA-Amber were categorized as non-efficient and non-responsive (NENR) genotypes. Prevalence of such genetic variations among these wheat cultivars can be useful in developing P- efficient genotypes.

Published

2016

11. Genotypic Variation in Cotton Genotypes for Phosphorus-Use Efficiency

Author

Asif Iqbal, Huiping Gui, Hengheng Zhang, Xiangru Wang, Nianchang Pang, Qiang Dong, and Meizhen Song

Subjects

gossypium hirsutum l., cotton genotypes, phosphorus uptake efficiency, phosphorus utilization efficiency, cotton breeding, environmental sustainability, cotton cultivation, Agriculture

Abstract

Low phosphorus (P) availability is a major constraint for cotton production. Consequently, P-efficient genotypes can improve productivity under conditions where the higher application of P is not economical. This study was conducted to characterize cotton genotypes for P-use efficiency under various P concentrations (0, 10, 20, 40, 80, and 500 μM KH2PO4). The results showed large genotypic variation in five selected traits, such as root dry weight, shoot dry weight, photosynthetic activity, P-utilization efficiency, and P-uptake efficiency. Based on these five selected traits, the genotypes were grouped into three main classes as efficient, moderate efficient, and inefficient genotypes as proposed by different researchers. Most of the genotypes behaved in a similar pattern under different P concentrations. Among the genotypes, Xinluzao-49 and Xinluzao-48 were considered as P efficient while CCRI-64 and Yumian-21 as inefficient genotypes. However, the rest of the genotypes were considered as moderately P efficient. The results prove that a large genetic potential exists in cotton genotypes for P-use efficiency, and the use of P-efficient genotypes for cultivation will reduce the application of phosphatic fertilizers. Furthermore, the use of P-efficient genotypes will improve cotton breeding activities and help in improving the environmental sustainability of cotton production.

Published

2019

12. Production of Phaseolus vulgaris L. Genotypes with Tithonia diversifolia (Hemsl.) Gray and Cajanus cajan (L.) Millsp.

Author

Donald C. L. Kass, Pedro S. Jorge-Mustonen, and Maren Oelbermann

Subjects

bean genotypes, mulch, bean yield, shoot biomass, phosphorus uptake efficiency, phosphorus utilization efficiency, Agriculture

Abstract

Adding mulch biomass prior to crop seeding may improve production of tropical soil. We evaluated the response of four bean (Phaseolus vulgaris L.) genotypes to the addition of mulch biomass from Tithonia diversifolia (Hemsl.) Gray and Cajanus cajan L. Millsp. The addition of mulch did not result in significant differences (p < 0.05) in soil characteristics when compared to a control (no mulch addition) except for soil potassium (K), which was significantly greater (p < 0.05) in the T. diversifolia mulch biomass treatment. Bean yield and shoot biomass were significantly greater (p < 0.05) in the mulch biomass treatments compared to the control (no biomass added). In these treatments, Phosphorus (P)-efficient bean genotypes had a significantly greater (p < 0.05) yield and shoot biomass. Bean shoot nutrient concentrations were significantly different (p < 0.05) between mulch biomass treatments and between bean genotypes (P, K and magnesium (Mg) only). Phosphorus utilization and uptake efficiencies were significantly different (p < 0.05) between mulch biomass treatments and between bean genotypes. Bean root biomass was not significantly different (p < 0.05) between mulch biomass treatments, but was significantly different (p < 0.05) between bean genotypes. The number of root nodules was significantly greater (p < 0.05) in the T. diversifolia mulch biomass treatment and was significantly different between bean genotypes.

Published

2013

13. Molecular Characterization and Functional Analysis of OsPHY1, a Purple Acid Phosphatase (PAP)–Type Phytase Gene in Rice(Oryza sativaL.)

Author

Rui-juan LI, Wen-jing LU, Cheng-jin GUO, Xiao-juan LI, Jun-tao GU, and Kai XIAO

Subjects

rice (Oryza sitava L.), phytase, expression, transgenic tobacco, phosphorus utilization efficiency, Agriculture (General), S1-972

Abstract

Abstract: As a specific type of acid phosphatses, phytases play diverse roles in plants by catalazing the degradation of phytic acid and its derivatives. In this study, a rice phytase gene referred to OsPHY1 has been functionally characterized. OsPHY1 contains a 1 620 bp of open reading frame, encoding a 539-aa polypeptide. A conserve domain metallophosphatase (MPP) (MPP_PAPs), generally harbored in phytase and purple acid phosphatases (PAP), was identified in OsPHY1 (residue 194-398). Phylogenetic analysis revealed that OsPHY1 shares high similarities with phytase genes and PAP-type genes that derived from diverse plant species. The OsPHY1 transcripts were detected to be abundant in germinating seeds, suggesting that this gene plays potential roles on degradation of seed phytic acid and its derivatives during the germination process. Biochemical analysis confirmed that OsPHY1 possesses strong catalytic activities on phytic acid-Na2, with optimal temperature of 57°C and suitable pH of 3.5. Based on transgene analysis, the putative role of OsPHY1 in plants on utilization of phytate was assessed. Under the condition that phytic acid-Na2 was used as sole P source, the OsPHY1-overexpressing tobacco plants behaved higher phytase activities, higher concentrations of Pi, more accumulative amount of total phosphorus, and much more improved growth traits than those of the control plants. Therefore, OsPHY1 is acted as an important component on degradation of the phytins during the seed germination process in rice. Also, OsPHY1 has a potential use on generation of elite crop germplasms with improved use efficiencies on phytate and its derivatives.

Published

2012

14. Improving phosphorus efficiency in cereal crops: Is breeding for reduced grain phosphorus concentration part of the solution?

Author

Terry eRose, Lei eLiu, and Matthias eWissuwa

Subjects

sustainable agriculture, phosphorus cycle, grain phosphorus, nutrient use efficiency, phosphorus utilization efficiency, Plant culture, SB1-1110

Abstract

Given the non-renewable nature of global phosphate reserves, there is a push to increase the phosphorus (P) efficiency of agricultural crops. Research has typically focussed on investigating P acquisition efficiency or internal P utilization efficiency to reduce crop fertilizer requirements. A novel option that would reduce the amount of P exported from fields at harvest, and may ultimately reduce P fertilizer requirements, would be to reduce the amount of P translocated to grains to minimize grain P concentrations. While such a trait has been mentioned in a number of studies over the years, there has not been a concerted effort to target this trait in breeding programs. In this perspective piece we explore the reasons why a low grain P trait has not been pursued, and discuss the potential benefits and drawbacks of such a trait in the context of breeding to improve the P efficiency of cropping systems.

Published

2013