Your search keyword '"Nicolas Cafaro La Menza"' showing total 6 results

1. Macro and Micro-Nutrient Accumulation and Partitioning in Soybean Affected by Water and Nitrogen Supply

Author

Ingrid Silva Setubal, Aderson Soares de Andrade Júnior, Silvestre Paulino da Silva, Artenisa Cerqueira Rodrigues, Aurenívia Bonifácio, Evandro Henrique Figueiredo Moura da Silva, Paulo Fernando de Melo Jorge Vieira, Rafael de Souza Miranda, Nicolas Cafaro La Menza, and Henrique Antunes de Souza

Subjects

Glycine max, biomass, plant nutrition, water stress, soybean yield, nitrogen, Botany, QK1-989

Abstract

This study aimed to investigate the influence of water availability and nitrogen fertilization on plant growth, nutrient dynamics, and variables related to soybean crop yield. Trials were performed in Teresina, Piauí, Brazil, using randomized blocks in a split-split plot arrangement. The plots corresponded to water regimes (full and deficient), the split plots to N fertilization (0 and 1000 kg ha−1 N-urea), and the split-split plots to harvest times of soybean plants (16, 23, 30, 37, 44, 58, 65, 79 and 86 days after emergence), with three replicates. In general, the accumulation and partitioning of nitrogen (N), phosphorus (P), potassium (K), calcium (Ca), magnesium (Mg), sulphur (S), copper (Cu), iron (Fe), manganese (Mn), zinc (Zn) and boron (B) were decreased in plants subjected to water deficit and without N fertilization. Although nitrogen fertilization promoted elevated N accumulation in tissues, it did not result in any significant yield gain, and the highest seed yields were found in plants under full irrigation, regardless of N supplementation. However, deficient irrigation decreased the seed oil content of N-fertilized plants. In conclusion, N fertilization is critical for nutrient homeostasis, and water availability impairs biomass and nutrient accumulation, thereby limiting soybean yield performance.

Published

2023

2. Nitrogen limitation in high-yield soybean: Seed yield, N accumulation, and N-use efficiency

Author

John L. Lindquist, Juan Pablo Monzon, Patricio Grassini, Timothy J. Arkebauer, Nicolas Cafaro La Menza, James E. Specht, and George L. Graef

Subjects

0106 biological sciences, food and beverages, Soil Science, chemistry.chemical_element, 04 agricultural and veterinary sciences, engineering.material, 01 natural sciences, Nitrogen, Crop, Animal science, chemistry, Negatively associated, Yield (chemistry), 040103 agronomy & agriculture, engineering, 0401 agriculture, forestry, and fisheries, Dry matter, Fertilizer, Oil concentration, Agronomy and Crop Science, 010606 plant biology & botany, Biomass composition

Abstract

Recent reviews about soybean nitrogen (N) requirement have speculated about a possible N limitation in high-yield environments (>4.5 Mg ha−1). However, these studies did not provide definitive experimental data to test that hypothesis and results from the literature are conflicting. To fill this knowledge gap, we evaluated N limitation across 13 high-yield soybean environments in Argentina and USA. Each experiment included a ‘zero-N’ treatment, which forced the crop to rely on biological N2 fixation and indigenous soil N, and a ‘full-N’ treatment, which provided an ample fertilizer N supply during the entire crop cycle based on site-specific yield potential. Accumulated N in aboveground dry matter (ADM) measured in a N-omission maize plot grown adjacent to the soybean experiments was used to determine indigenous soil N supply. Soybean seed yield, protein and oil concentration, ADM, harvest index (HI), accumulated N in ADM, N harvest index (NHI), and seed N were measured in both treatments at physiological maturity. A simple conceptual framework relating ADM with accumulated N was used to assess treatment differences in ADM, accumulated N, and N-use efficiency (NUE). To account for treatment differences in seed biomass composition, mass-based ADM was expressed in glucose equivalents (ADMe). Seed yield ranged from 4.6 to 6.7 Mg ha−1 (full-N) and 4 to 5.8 Mg ha−1 (zero-N), with the full-N treatment averaging 12% (0.6 Mg ha−1) and 3% (9 g kg−1) higher seed yield and protein concentration, respectively. The full-N treatment exhibited 18% (70 kg N ha−1) and 14% (1.6 Mg ha−1) greater accumulated N and ADM, respectively, compared with the zero N treatment, without changes in HI and NHI, but slightly lower NUE (29 versus 30 kg ADM kg−1 N in full and zero-N, respectively). However, NUE differences between treatments became indistinguishable when ADM was expressed as ADMe (45 kg glucose kg−1 N). The (full-N minus zero-N) seed yield difference and the indigenous soil N supply were negatively associated. This research documented (i) the existence of N limitation in high-yield soybean, (ii) that seed yield and protein concentration increases were physiologically associated with changes in accumulated N (but not in NUE and/or NHI), and (iii) that the degree of N limitation is modulated by indigenous soil N supply. Findings from this study can serve as a basis to identify environments with the largest N limitation and thus guide N management in soybean.

Published

2019

3. Contributors

Author

L. Gabriela Abeledo, Majid Alimagham, Fernando H. Andrade, Andrea Ávila-Valdés, Mike Bange, Anita Behn, Mike Bell, Peter M. Berry, H. Daniel Bertero, Andrew Borrell, Nicolas Cafaro La Menza, Daniel F. Calderini, Hugo Campos, X. Carolina Lizana, Yashvir S. Chauhan, Karine Chenu, Alfredo G. Cirilo, James H. Cock, David J. Connor, Alan Cruickshank, Philippe Debaeke, Alejandro del Pozo, Joe Eyre, Muhammad Farooq, Bob French, Shu Fukai, Barbara George-Jaeggli, Ian Godwin, Patricio Grassini, Lydie Guilioni, Amir Hajjarpoor, Graeme Hammer, Jim Heitholt, Christa M. Hoffmann, Geoff Inman-Bamber, Natalia G. Izquierdo, Phillip Jackson, David J. Jordan, Junichi Kashiwagi, Jana Kholova, John A. Kirkegaard, Heinz-Josef Koch, Lijalem Balcha Korbu, Shiv Kumar, Lachlan Lake, Julianne M. Lilley, Bao-Luo Ma, Emma Mace, Bernward Märländer, Mario Mera, M. Inés Mínguez, Daniel J. Miralles, Juan Pablo Monzón, Harsh Nayyar, Erik van Oosterom, María E. Otegui, Dante Pinochet, Santiago Alvarez Prado, Raju Pushpavalli, Rao Rachaputi, David A. Ramirez, Maria Laura Ramirez, Idupulapati M. Rao, Juan I. Rattalino Edreira, Abdul Rehman, Changzhong Ren, Daniel Rodriguez, Deborah P. Rondanini, Diego Rubiales, Victor O. Sadras, Patricio Sandaña, Roxana Savin, Akanksha Sehgal, Román A. Serrago, Kadambot H.M. Siddique, Abraham Singels, Sarvjeet Singh, Vijaya Singh, Kumari Sita, Gustavo A. Slafer, Millicent R. Smith, John Snider, Rogério P. Soratto, James E. Specht, Yongfu Tao, Fatima A. Tenorio, Neil C. Turner, Sergio A. Uhart, Vincent Vadez, Len J. Wade, Graeme C. Wright, Rashmi Yadav, and Zhiming Zheng

Published

2021

4. Soybean

Author

Patricio Grassini, Nicolas Cafaro La Menza, Juan I. Rattalino Edreira, Juan Pablo Monzón, Fatima A. Tenorio, and James E. Specht

Published

2021

5. Is soybean yield limited by nitrogen supply?

Author

James E. Specht, Nicolas Cafaro La Menza, Juan Pablo Monzon, and Patricio Grassini

Subjects

0106 biological sciences, Development environment, PROTEIN, Soil Science, chemistry.chemical_element, 01 natural sciences, SOYBEAN, Seed protein, N fertilizer, Agronomía, reproducción y protección de plantas, Dry matter, Oil concentration, Mathematics, food and beverages, Sowing, 04 agricultural and veterinary sciences, OIL, Nitrogen, YIELD POTENTIAL, NITROGEN, chemistry, Agronomy, CIENCIAS AGRÍCOLAS, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Agricultura, Silvicultura y Pesca, Agronomy and Crop Science, 010606 plant biology & botany, Crop season

Abstract

As soybean yield continues to increase, it seems critical to know if there is a yield level at which potential contribution of indigenous nitrogen (N) sources (N fixation and soil mineralization) becomes insufficient to meet crop N requirements for high yields, while still maintaining or increasing protein and oil concentration. We have hypothesized that, in absence of other limiting factors, degree of N limitation increases with increasing yield potential (Yp) of the production environment. To test this hypothesis, we developed a novel protocol to ensure an ample N supply during the entire crop season (full-N treatment). That protocol was applied to field-grown irrigated soybean in Balcarce (Argentina) and Nebraska (USA), where measured full-N seed yields were ±15% of their simulated Yp in 92% of the cases. The combination of locations, years, sowing dates, and N treatments resulted in a wide range of seed yields, from 2.5 to 6.5 Mg ha−1. Overall, full-N seed yield averaged 11% higher than seed yield without N addition (zero-N). However, magnitude of yield difference between full-N and zero-N depended upon Yp, ranging from no detectable yield difference in low-Yp (ca. 2.5 Mg ha−1) to up to 900 kg ha−1 in high-Yp environments (ca. 6 Mg ha−1). Seed yield differences were associated with higher aboveground dry matter, seed number, and seed weight in the full-N versus zero-N treatments. Seed protein (but not oil) concentration was higher in the full-N treatment, and both protein and oil yields were higher in the full-N versus zero-N treatments. Findings from this study indicate that (i) N limits soybean seed yield (as well as protein yield, and oil yield) in environments with high Yp, where indigenous N sources seem insufficient to fully satisfy crop N requirements, and (ii) yield response to N fertilizer can occur above a 2.5 Mg ha−1 Yp threshold and has an upper limit of 250 kg seed per Mg increase in Yp. Fil: Cafaro la Menza, Nicolás. Consejo Nacional de Investigaciones Científicas y Técnicas; Argentina. University of Nebraska; Estados Unidos Fil: Monzon, Juan Pablo. Consejo Nacional de Investigaciones Científicas y Técnicas; Argentina. Instituto Nacional de Tecnología Agropecuaria. Centro Regional Buenos Aires Sur. Estación Experimental Agropecuaria Balcarce; Argentina Fil: Specht, James E.. University of Nebraska; Estados Unidos Fil: Grassini, Patricio. University of Nebraska; Estados Unidos

Published

2017

6. Critical period for seed number determination in soybean as determined by crop growth rate, duration, and dry matter accumulation

Author

Patricio Grassini, Anibal Alejandro Cerrudo, James E. Specht, Matı́as Canepa, Juan Pablo Monzon, Fernando H. Andrade, Juan I. Rattalino Edreira, and Nicolas Cafaro La Menza

Subjects

Critical phase, Crop, Animal science, Crop growth rate, Crop growth, food and beverages, Soil Science, Dry matter, Biology, Crop species, Agronomy and Crop Science, Two stages, Management practices

Abstract

Seed number (SN) is positively associated with aboveground dry matter (ADM) accumulation in most crop species. In soybean, there are discrepancies among studies relative to the start and end of the critical period for seed number determination. The objective of this study was to more precisely identify those two stages. To do so, we followed two approaches: (i) analyses of experimental data where differences in SN occurred as a result of variation in crop growth due to weather and management practices and (ii) review of published experiments where soybean was subjected to artificial stresses during specific crop phases. Following the first approach, we analyzed the relationships between SN versus ADM accumulation and its components, crop growth rate (CGR) and duration, for different reproductive phases using data from experiments that portrayed a wide range of environments and management practices. In the second approach, we compared SN values in stressed versus non-stressed treatments. Accumulated ADM during the R3 to R6 phase explained ca. 70 % of the variation in SN across experiments. The CGR during R3-R6 was also a good predictor of SN, but it had lower explanatory power compared with accumulated ADM, because CGR did not account for changes in duration of critical period across experiments. Review of published data, wherein soybean crops were subjected to artificial stresses during different reproductive phases, confirmed that the R3-R6 phase is a critical phase for SN determination in soybean. Key findings of this study were: (i) critical period for SN determination in soybean occurs during the R3-R6 phase and (ii) accumulated ADM during the critical period is a better predictor of SN compared with CGR because it accounts for differences in the duration of the critical period as a result of weather and management.

Published

2021