Your search keyword '"N2 FIXATION"' showing total 1,152 results

1. Graphene oxide anchored ZnO composites for enhanced piezoelectric catalytic nitrogen fixation and dye degradation

Author

Peng, Fengping, Kai, Xuan, Bao, Yuanfei, Tang, Kai, Wang, Wei, and Wu, Chunzheng

Published

2025

2. Enhancing photocatalytic N2 fixation efficiency through the construction of optimized hollow ZnO/Cu Mott-Schottky heterojunction microreactors

Author

Yang, Rong, Liu, Jianan, Sun, Xuemeng, Wang, Cheng, and Jiang, Baojiang

Published

2025

3. Exploring the Impacts of Elevated CO2 on Food Security: Nutrient Assimilation, Plant Growth, and Crop Quality

Author

Dakora, Felix D., Li, Huihui, and Zhao, Jun

Published

2025

4. Non-symbiotic N2 fixation is less sensitive to changes in temperature than carbon mineralization in Northern forest soils

Author

Vázquez, Eduardo and Spohn, Marie

Published

2025

5. Enhanced photocatalytic organic pollutant degradation, H2 production and N2 fixation via a versatile zinc oxide-based nanocomposite: Synthesis, characterization and mechanism Insight

Author

Zhang, Yang, Sultan Aljibori, Hakim S., Algarni, Zaina, Amari, Abdelfattah, Mahariq, Ibrahim, Zhang, Keping, and El-Sabban, Heba A.

Published

2024

6. A highly effective N2 fixation method based on reverse vortex flow gliding arc plasma under water

Author

Zhang, Yunfei, Zhu, Cheng, Wei, Haixiao, Tian, Yuan, Xia, Weidong, and Wang, Cheng

Published

2024

7. Green ammonia production technologies: A review of practical progress

Author

Ojelade, Opeyemi A., Zaman, Sharif F., and Ni, Bing-Jie

Published

2023

8. Non-thermal plasma assisted catalytic nitrogen fixation with methane at ambient conditions

Author

Nguyen, Hoang M., Omidkar, Ali, Li, Wenping, Meng, Shijun, Li, Zhaofei, and Song, Hua

Published

2023

9. Constructing S-scheme heterojunction Cs3Bi2Br9/BiOBr via in-situ partial conversion to boost photocatalytic N2 fixation.

Author

Ren, An-Di, Liu, Zhao-Lei, Yuan, Su-Xian, Zhang, Min, and Lu, Tong-Bu

Subjects

*CHARGE exchange, *ACTIVATION energy, *CHARGE transfer, *HETEROJUNCTIONS, *NANOCRYSTALS

Abstract

An in - situ partial conversion strategy is proposed and employed to successfully synthesize a lead-free halide perovskite-based S-scheme heterojunction of Cs 3 Bi 2 Br 9 /BiOBr, which exhibits swift transfer and separation of photogenerated carriers and thus significant improvement in photocatalytic N 2 reduction activity compared to traditional electrostatic self-assembled heterojunction. [Display omitted] The judicious construction of interfaces with swift charge communication to enhance the utilization efficiency of photogenerated carriers is a viable strategy for boosting the photocatalytic performance of heterojunctions. Herein, an in-situ partial conversion strategy is reported for decorating lead-free halide perovskite Cs 3 Bi 2 Br 9 nanocrystals onto BiOBr hollow nanotube, resulting in the formation of an S-scheme heterojunction Cs 3 Bi 2 Br 9 /BiOBr. This unique in-situ growth approach imparts a closely contacted interface to the Cs 3 Bi 2 Br 9 /BiOBr heterojunction, facilitating interfacial electron transfer and spatial charge separation compared to a counterpart (Cs 3 Bi 2 Br 9 :BiOBr) fabricated via traditional electrostatic self-assembly. Additionally, the establishment of an S-scheme charge transfer pathway preserves the robust redox capability of photogenerated carriers. Furthermore, the free electron transfer from Cs 3 Bi 2 Br 9 to BiOBr promotes the activation of the N N bond and diminishes the energy barrier associated with the rate-determining step in the N 2 reduction process. Consequently, the Cs 3 Bi 2 Br 9 /BiOBr heterojunction exhibits highly selective photocatalytic N 2 reduction to NH 3 (nearly 100 %) at a rate of 130 μmol g−1 h−1 under simulated sunlight (100 mW cm−2), surpassing BiOBr, Cs 3 Bi 2 Br 9 , and Cs 3 Bi 2 Br 9 :BiOBr by factors of 6, 4, and 2, respectively. [ABSTRACT FROM AUTHOR]

Published

2025

10. Electrocatalytic and Photocatalytic N 2 Fixation Using Carbon Catalysts.

Author

Xu, Changchun, Su, Hongli, Zhao, Shuaifei, Nilghaz, Azadeh, Tang, Kunning, Ma, Luxiang, and Zou, Zhuo

Subjects

*HYDROGEN evolution reactions, *CARBON-based materials, *ELECTRON transitions, *PHOTOREDUCTION, *PHOTOCATALYSTS, *ELECTROCATALYSTS

Abstract

Carbon catalysts have shown promise as an alternative to the currently available energy-intensive approaches for nitrogen fixation (NF) to urea, NH3, or related nitrogenous compounds. The primary challenges for NF are the natural inertia of nitrogenous molecules and the competitive hydrogen evolution reaction (HER). Recently, carbon-based materials have made significant progress due to their tunable electronic structure and ease of defect formation. These properties significantly enhance electrocatalytic and photocatalytic nitrogen reduction reaction (NRR) activity. While transition metal-based catalysts have solved the kinetic constraints to activate nitrogen bonds via the donation-back-π approach, there is a problem: the d-orbital electrons of these transition metal atoms tend to generate H-metal bonds, inadvertently amplifying unwanted HER. Because of this, a timely review of defective carbon-based electrocatalysts for NF is imperative. Such a review will succinctly capture recent developments in both experimental and theoretical fields. It will delve into multiple defective engineering approaches to advance the development of ideal carbon-based electrocatalysts and photocatalysts. Furthermore, this review will carefully explore the natural correlation between the structure of these defective carbon-based electrocatalysts and photocatalysts and their NF activity. Finally, novel carbon-based catalysts are introduced to obtain more efficient performance of NF, paving the way for a sustainable future. [ABSTRACT FROM AUTHOR]

Published

2025

11. Spatial Heterogeneity of Nitrogen Fixation and Denitrification in Streams: Spatial Heterogeneity of Nitrogen Fixation and Denitrification in Streams: E. K. Eberhard and others.

Author

Eberhard, Erin K., Techtmann, Stephen M., Baxter, Colden V., and Marcarelli, Amy M.

Abstract

Stream ecosystems exhibit high degrees of spatial heterogeneity at nested scales from microhabitats to regions. This heterogeneity may facilitate the co-occurrence of biogeochemical processes that are favored under incompatible environmental conditions, like dinitrogen (N2 gas) fixation and denitrification. We hypothesized that environmental variation at the patch scale (1–10’s m) would facilitate the co-occurrence of N2 fixation and denitrification through the formation of hot spots. We measured rates of N2 fixation and denitrification and relative abundances of nifH and nirS (genes that encode for the enzymes nitrogenase and nitrite reductase, respectively) in patches determined by channel geomorphic units and substratum type in seven streams encompassing a gradient of N and P concentrations. We found hot spots, where rates of N2 fixation and denitrification were 1–4 times higher than reach-average rates, in all study streams. Most N2 fixation hot spots were in patches with rock substrata, while denitrification rates and relative abundances of nifH and nirS were higher in patches with fine sediment. Yet, in one of the streams, the same patches hosted rates in the top 25% of all patches for both denitrification and N2 fixation. Across all streams and patches, organic matter and dissolved oxygen concentrations were important predictors of rates of N2 fixation, denitrification, and nifH relative abundance, while P concentration was important to N2 fixation and denitrification. Our results demonstrate that understanding the spatial ecology of microbially driven nutrient cycling is required to characterize nutrient fluxes more completely in stream ecosystems. [ABSTRACT FROM AUTHOR]

Published

2025

12. Short-term fate of nitrogen fixed by moss-cyanobacteria associations under different rainfall regimes

Author

Song Guo, Lina Avila Clasen, and Kathrin Rousk

Subjects

Mosses, Cyanobacteria, N2 fixation, Nutrient leaching, N transfer, 15N labeling, Ecology, QH540-549.5

Abstract

Nitrogen (N) fixation by moss-cyanobacteria associations has been recognized as an important N input pathway in many ecosystems from arctic tundra to tropical forests. However, the transfer of fixed N2 from mosses to the soil as well as the effects of rainfall frequency and volume on this N transfer has hardly been studied – even though mosses can leach nutrients upon rewetting. In this study, we investigated the transfer of fixed N2 by moss-cyanobacteria associations in one month under four watering regimes with a combination of high and low volume and frequency. For this, we used two morphologically similar moss species collected from ecosystems with different climate and N availability (subarctic - Hylocomium splendens; and tropical - Thuidium delicatulum). Acetylene reduction assays were conducted as a measure of N2 fixation rates in mosses, and 15N-N2 tracing was used to follow the fixed N2 from moss to the underlying substrate. Nitrogen fixation rates were higher in T. delicatulum than in H. splendens, but rainfall volume and frequency did not show strong effects on N2 fixation rates. Nonetheless, the extent of N leached from mosses was more sensitive to an increase in rainfall volume than to an increase in frequency, and more N was lost from T. delicatulum under high volume precipitation than from H. splendens. Both total nitrogen and 15N enrichment results demonstrate that the fixed N2 was mostly stored in moss tissues with less than 1 % leached to the substrate. Our results show that both moss species retain almost all fixed N2 within their tissues under small rainfall disturbances within one month, while increased N availability under higher precipitation volume renders some moss species an important N source for the soil.

Published

2024

13. Short-term fate of nitrogen fixed by moss-cyanobacteria associations under different rainfall regimes.

Author

Guo, Song, Clasen, Lina Avila, and Rousk, Kathrin

Subjects

RAINFALL frequencies, RAINFALL, TROPICAL forests, NITROGEN fixation, MOSSES, LEACHING

Abstract

• High volume precipitation does not translate into increased moss-associated nitrogen (N) fixation rates. • N fixation increased more in a tropical moss compared to a subarctic moss under all rainfall regimes. • Less than 1 % of fixed N was leached from mosses within a 1-month period. • N leaching from mosses was more sensitive to watering volume than frequency. Nitrogen (N) fixation by moss-cyanobacteria associations has been recognized as an important N input pathway in many ecosystems from arctic tundra to tropical forests. However, the transfer of fixed N 2 from mosses to the soil as well as the effects of rainfall frequency and volume on this N transfer has hardly been studied – even though mosses can leach nutrients upon rewetting. In this study, we investigated the transfer of fixed N 2 by moss-cyanobacteria associations in one month under four watering regimes with a combination of high and low volume and frequency. For this, we used two morphologically similar moss species collected from ecosystems with different climate and N availability (subarctic - Hylocomium splendens ; and tropical - Thuidium delicatulum). Acetylene reduction assays were conducted as a measure of N 2 fixation rates in mosses, and 15N-N 2 tracing was used to follow the fixed N 2 from moss to the underlying substrate. Nitrogen fixation rates were higher in T. delicatulum than in H. splendens , but rainfall volume and frequency did not show strong effects on N 2 fixation rates. Nonetheless, the extent of N leached from mosses was more sensitive to an increase in rainfall volume than to an increase in frequency, and more N was lost from T. delicatulum under high volume precipitation than from H. splendens. Both total nitrogen and 15N enrichment results demonstrate that the fixed N 2 was mostly stored in moss tissues with less than 1 % leached to the substrate. Our results show that both moss species retain almost all fixed N 2 within their tissues under small rainfall disturbances within one month, while increased N availability under higher precipitation volume renders some moss species an important N source for the soil. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

14. Characterizing dissolved inorganic and organic nutrients in the oligotrophic Kuroshio Current off eastern Taiwan during warm seasons.

Author

Jia-Jang Hung, Sheng-Hsian Tsai, Yen-Hui Lin, and Zhi-Ying Hsiang

Subjects

REGIONS of freshwater influence, COASTS, SEAWATER, MIXING height (Atmospheric chemistry), WATER masses, SEASONS, KUROSHIO

Abstract

This study conducted sensitive and precise analyses of dissolved organic nitrogen (DON) and dissolved organic phosphorus (DOP) concentrations and trace concentrations of nitrate and nitrite (N+N) and soluble reactive phosphorus (SRP) in seawater. The methods were applied to investigate the distributions and controls of N+N, SRP, DON, and DOP in the oligotrophic Kuroshio Current (KC) area off eastern Taiwan during warm seasons. The water in the studied area was classified into four major types: typical Kuroshio water (KW), KW influenced by the East China Sea water, KC influenced by the South China Sea (SCS) water, and KW influenced by the SCS water and river plumes, which is confined to the coastal zone. Nutrient distributions in KC revealed very low N+N (0.002-0.40 mM) and SRP (0.015-0.125 mM) concentrations but high DON (<8 mM) and DOP (<0.3 mM) concentrations above the nutricline depth, which accounted for >80% of TDN and TDP, respectively; theses concentrations can primarily be attributed to strong, permanent surface stratification. Among the water types, KW had the lowest N+N, SRP, DON, and DOP concentrations but greatest chlorophyll maximum depth and nutricline depth, except for in locations influenced by island-induced upwelling. The concentrations of all nutrients increased by various degrees in the other water types, which was attributed to the exchange and mixing of different water masses and coastal uplift of subsurface waters. KW was not only highly oligotrophic but also N+N-limited reflected from very low [N+N]/[SRP] ratio (0.02-0.15) in the mixed layer (ML). Overall, the N+N limitation and high nitrate anomaly value (N*: 2.47 ± 0.16 mM) above the nutricline depth strongly indicate prevailing N2 fixation at the surface of KW. Very high DON/DOP ratio in KW (16.9-69.1) probably resulted from the release of N-rich organic nutrients from phytoplankton including N2 fixers at the surface and faster recycling of DOP than DON in deep waters. Persistent coastal uplift of subsurface water occurs everywhere over the shore-side region of the KC, resulting in increasing surface concentrations of nutrients and chlorophyll a. Overall, the aforementioned physical and biogeochemical processes determined the upper-ocean distributions of nutrient species in warm seasons. [ABSTRACT FROM AUTHOR]

Published

2024

15. N 2 Fixation, N Transfer, and Land Equivalent Ratio (LER) in Grain Legume–Wheat Intercropping: Impact of N Supply and Plant Density.

Author

Salinas-Roco, Sebastian, Morales-González, Amanda, Espinoza, Soledad, Pérez-Díaz, Ricardo, Carrasco, Basilio, del Pozo, Alejandro, and Cabeza, Ricardo A.

Subjects

INTERCROPPING, FAVA bean, CATCH crops, PLANT spacing, LEGUMES, AGRICULTURE, WATER efficiency, WATER use

Abstract

Intercropping legumes with cereals can lead to increased overall yield and optimize the utilization of resources such as water and nutrients, thus enhancing agricultural efficiency. Legumes possess the unique ability to acquire nitrogen (N) through both N2 fixation and from the available N in the soil. However, soil N can diminish the N2 fixation capacity of legumes. It is postulated that in intercropping, legumes uptake N mainly through N2 fixation, leaving more soil N available for cereals. The latter, in turn, has larger root systems, allowing it to explore greater soil volume and absorb more N, mitigating its adverse effects on N2 fixation in legumes. The goal of this study was to evaluate how the supply of N affects the intercropping of faba beans (Vicia faba L.) and peas (Pisum sativum L.) with wheat under varying plant densities and N levels. We measured photosynthetic traits, biomass production, the proportion of N derived from air (%Ndfa) in the shoot of the legumes, the N transferred to the wheat, and the land equivalent ratio (LER). The results revealed a positive correlation between soil N levels and the CO2 assimilation rate (An), chlorophyll content, and N balance index (NBI) in wheat. However, no significant effect was observed in legumes as soil N levels increased. Transpiration (E) increased in wheat intercropped with legumes, while stomatal conductance (gs) increased with N addition in all crops. Water use efficiency (WUE) decreased in faba beans intercropped with wheat as N increased, but it showed no significant change in wheat or peas. The shoot dry matter of wheat increased with the addition of N; however, the two legume species showed no significant changes. N addition reduced the %Ndfa of both legume species, especially in monoculture, with peas being more sensitive than faba beans. The intercropping of wheat alleviated N2 fixation inhibition, especially at high wheat density and increased N transfer to wheat, particularly with peas. The LER was higher in the intercropping treatments, especially under limited N conditions. It is concluded that in the intercropping of wheat with legumes, the N2 fixation inhibition caused by soil N is effectively reduced, as well as there being a significant N transfer from the legume to the wheat, with both process contributing to increase LER. [ABSTRACT FROM AUTHOR]

Published

2024

16. Assessing the biomass yield and nitrogen fixation of Lupinus angustifolius varieties as green manure in Jalisco, Mexico

Author

Juan Francisco Zamora Natera, Isidro Zapata Hernández, Carlos Ernesto Aguilar Jiménez, Franklin B. Martínez Aguilar, and José Galdámez Galdámez

Subjects

dry matter, harvest date, legumes, lupins, n2 fixation, rhizobia, Agriculture (General), S1-972

Abstract

Limited information is available in Mexico regarding the use of Lupinus angustifolius L. as a green manure. This study aimed to assess the effectiveness of six Lupinus angustifolius varieties as green manure in terms of above-ground biomass production, expressed as dry matter (DM), and total nitrogen (N) accumulation at successive harvest dates. Additionally, the study aimed to estimate N2 fixation 110 days after sowing (DAS). The varieties Haags Blaue, Boregine, Borlu, Probor, Sonate, and Boruta were sown during the winter season of 2018-2019 using a randomized block factorial design. The N difference method was employed to estimate N2 fixation, with wheat serving as the reference crop. Data on above-ground biomass production, N concentration, and total N accumulation were recorded at different harvest times: 80, 95, and 110 DAS. The biomass yield of all varieties significantly increased from the first to the last harvest, with the highest yield observed at the final harvest (ranging from 7,632 to 10,200 kg ha-1). The highest total N accumulation from biomass was recorded at the last harvest. On average, the Borlu, Boregine, Haags Blaue, and Boruta varieties accumulated 195.4 kg ha-1 of total N (ranging from 195.6 to 221.2 kg ha-1). The proportion of N derived from the atmosphere (%Ndfa) through N2 fixation averaged 80.09% (ranging from 72% to 93%), resulting in an average N fixation of 160 kg ha-1 (ranging from 106 to 185 kg ha-1) in above-ground biomass. All six varieties demonstrated potential as green manure, considering their above-ground biomass production, total N accumulation, and ability to fix N2.

Published

2023

17. Native soil origin influences the symbiotic N fixation effectiveness of chickpea mesorhizobia grown in Australian soils.

Author

Rathjen, JR, Zaw, M, Ryder, MH, Zhou, Y, Lai, TV, and Denton, MD

Subjects

*SOILS, *CHICKPEA, *FIELD research, *ACID soils

Abstract

Experiments conducted under controlled conditions can be poor predictors of the field performance of rhizobial inoculants. In this study, five field experiments were conducted over 2 years to evaluate the symbiotic performance of 12 previously identified strains isolated from Australia and Myanmar soils that had potential to improve chickpea productivity through symbiotic N2 fixation. Strains collected from Australian soils had more than double the survival on seed and up to three times the nodulation at some experimental sites, compared with strains isolated from Myanmar soils. Generally, the newly isolated strains did not perform better than the current Australian commercial strain, Mesorhizobium ciceri CC1192. Although Myanmar strains had poor nodulation of chickpea plants (below nodule rating 1 in most cases) under Australian field conditions, the plant traits related to growth and symbiosis, such as shoot dry weight (SDW), yield and N fixation, were improved and sometimes equal to the plants inoculated with the Australian strains. Partial correlations showed that plants inoculated with Myanmar strains had greater associations with N fixation measurements (7 plant traits) than nodule number (1 trait), while a symbiotic effectiveness measure of the ratio between N fixation and nodule mass indicated that Myanmar strains are more than 75% more symbiotically efficient compared with the Australian strains. Better seed and soil survival of the Myanmar strains may increase plant nodulation and may lead to a highly effective inoculant strain. This study is one of the first to report increased symbiotic efficiency of N fixation of novel strains compared to a widely utilised commercial chickpea-nodulating strain, on a per nodule basis. [ABSTRACT FROM AUTHOR]

Published

2024

18. Au Nanoparticle-Loaded UiO-66 Metal–Organic Framework for Efficient Photocatalytic N 2 Fixation.

Author

Zhao, Zehui, Ren, Guangmin, Meng, Xiangchao, and Li, Zizhen

Subjects

METAL-organic frameworks, GOLD nanoparticles, PHOTOREDUCTION, PHOTOCATALYSTS, NITROGEN

Abstract

In order to achieve efficient photocatalytic N2 reduction activity for ammonia synthesis, a photochemical strategy was used in this work. UiO-66 was prepared through the solvothermal method and further loaded with Au nanoparticles (Au NPs) onto the UiO-66 (Zr) framework. The experimental results verified that there were metal–support interactions between Au NPs and UiO-66; this could facilitate charge transfer among Au NPs and UiO-66, which was beneficial to enhance the photocatalytic activity. The best N2 fixation effect of Au/UiO-66 with a loading of 1.5 wt% was tested, with a photocatalytic yield of ammonia of 66.28 μmol g−1 h−1 while maintaining good stability. The present work provides a novel approach to enhancing photocatalytic N2 fixation activity by loading NPs onto UiO-66. [ABSTRACT FROM AUTHOR]

Published

2024

19. Heterogeneity in habitat and nutrient availability facilitate the co-occurrence of N2 fixation and denitrification across wetland–stream–lake ecotones of Lakes Superior and Huron.

Author

Eberhard, Erin K., Kane, Evan S., and Marcarelli, Amy M.

Subjects

*DISSOLVED organic matter, *DENITRIFICATION, *ECOTONES, *NITROGEN, *HABITATS, *WETLANDS, *NITROGEN fixation

Abstract

Great Lakes coastlines are mosaics of wetland, stream, and lake habitats, characterized by a high degree of spatial heterogeneity that may facilitate the co-occurrence of seemingly incompatible biogeochemical processes due to variation in environmental factors that favor each process. We measured nutrient limitation and rates of N2 fixation and denitrification along transects in 5 wetland–stream–lake ecotones with different nutrient loading in Lakes Superior and Huron. We hypothesized that rates of both processes would be related to nutrient limitation status, habitat type, and environmental characteristics including temperature, nutrient concentrations, and organic matter quality. We found that median denitrification rates (914 μg N m−2 h−1) were 166 × higher than N2 fixation rates (5.5 μg N m−2 h−1), but the processes co-occurred in 48% of 83 points measured across all 5 transects and habitat types. N2 fixation occurred on sediment and macrophyte substrate, while denitrification occurred mostly in sediment. Nutrient-diffusing substrate experiments indicated that biofilm chlorophyll-a was limited by N and/or P at 55% and biofilm AFDM was limited at 26% of sample points. N2 fixation and denitrification rates did not differ significantly with differing nutrient limitation. Predictive models for N2 fixation and denitrification rates both included variables related to the composition of dissolved organic matter, while the model for N2 fixation also included P concentrations. These results demonstrate the potential for heterogeneity in habitat characteristics, nutrient availability, and organic matter composition to lead to biogeochemical complexity at the local scale, despite overall N removal at broader scales. [ABSTRACT FROM AUTHOR]

Published

2023

20. Biofilm formation and cell plasticity drive diazotrophy in an anoxygenic phototrophic bacterium.

Author

Fernández-Juárez, Víctor, Hallstrøm, Søren, Pacherres, Cesar O., Jiaqi Wang, Coll-Garcia, Guillem, Kühl, Michael, and Riemann, Lasse

Subjects

*BIOFILMS, *NITROGEN fixation, *PHOTOSYNTHETIC bacteria, *DISSOLVED organic matter, *SEAWATER, *QUORUM sensing, *PHYSIOLOGICAL adaptation, *CELL anatomy

Abstract

Non-cyanobacterial diazotrophs (NCDs) are widespread and active in marine waters. The carbon and low-oxygen (O2) conditions required for their N2 fixation may be encountered on marine particles, while a putative role of light remains uninvestigated. This study explored factors that regulate N2 fixation in Rhodopseudomonas sp. BAL398--a anoxygenic phototrophic bacterium isolated from low-salinity surface waters. Light (250 µmol photons m-2 s-1) and anoxia (0 µM O2) stimulated growth and N2 fixation; however, diazotrophy in light was dependent on high organic carbon levels (35 mM, glucose:succinate). Immunolabeling revealed that cellular nitrogenase levels increased with light, decreasing inorganic nitrogen (N) and ambient O2 (250 µM). Light and O2 stimulated motility and biofilm formation on surfaces, and N2 fixation rates increased compared to the control treatment. N2 fixation rates were positively correlated with the formation of rosette-like cellular structures, and an increased concentration of nitrogenase was observed toward the center of these structures, which increased their occurrence 600 times when cultures reached maximum N2 fixation rates vs when they had low rates. Interestingly, N2 fixation was not completely inhibited under oxic conditions and was accompanied by increased formation of capsules and cysts. Rosettes, as well as capsules and cysts, may thus serve as protection against O2. Our study reveals the physiological adaptations that underlie N2 fixation in an anoxygenic phototroph, emphasizing the significance of biofilm formation for utilizing light and fixing N2 under oxic conditions, and underscores the need for deciphering the importance of light for marine NCDs. IMPORTANCE The contribution of non-cyanobacterial diazotrophs (NCDs) to total N2 fixation in the marine water column is unknown, but their importance is likely constrained by the limited availability of dissolved organic matter and low O2 conditions. Light could support N2 fixation and growth by NCDs, yet no examples from bacterioplankton exist. In this study, we show that the phototrophic NCD, Rhodopseudomonas sp. BAL398, which is a member of the diazotrophic community in the surface waters of the Baltic Sea, can utilize light. Our study highlights the significance of biofilm formation for utilizing light and fixing N2 under oxic conditions and the role of cell plasticity in regulating these processes. Our findings have implications for the general understanding of the ecology and importance of NCDs in marine waters. [ABSTRACT FROM AUTHOR]

Published

2023

21. The effects of different seeding rates on nitrogen acquisition in pea-wheat intercropping.

Author

TON, Aybegün and JENSEN, Erik Steen

Subjects

*CATCH crops, *AGRICULTURAL resources, *INTERCROPPING, *PEAS, *CROPPING systems, *AGRICULTURAL productivity, *WEEDS, *WHEAT

Abstract

Intercropping may improve the use of environmental resources in low-input agricultural systems compared to sole crops and it is possible that risk may be reduced in intercropping, leading to more stable yields and weed control. The aim of the present study was to determine the effect of seeding rate of a normal leafed cultivar and a semileafless pea cultivar (Pisum sativum L.) grown as sole crops, cultivar mixture, and in double and triple intercrops with spring wheat (Triticum aestivum L.) on competitive dynamics, yield and use of nitrogen sources from soil, and symbiotic N2 fixation. A randomized complete blocks experiment design was used. The differences between the treatments were not significant for total grain yield. Land equivalent ratios for grain yield varied between 1.04 (80P/20W) and 1.40 (80D/20W), which showed that plant growth factors are used more efficiently by the intercrops than by the sole crops for grain production. Nitrogen accumulation was higher in pea sole crops compared to pea component crops in the intercrops, due to the decreased pea density and decreased pea growth caused by interspecific competition from wheat. The amount of N2 fixed in pea in the intercrops at the flowering harvest was less than the in the pea sole crop also due to competition from wheat for other growth factors than nitrogen, probably by shading. It was concluded that pea-wheat intercropping can use N resources more efficiently compared to sole crops in sustainable cropping systems. [ABSTRACT FROM AUTHOR]

Published

2023

22. Developing a genetic approach to target cyanobacterial producers of heterocyte glycolipids in the environment.

Author

Pérez Gallego, Ruth, Bale, Nicole J., Sinninghe Damste, Jaap S., and Villanueva, Laura

Subjects

GLYCOLIPIDS, DNA primers, NITROGEN cycle, CARBON cycle, POLYSACCHARIDES, ENVIRONMENTAL sampling

Abstract

Heterocytous cyanobacteria are important players in the carbon and nitrogen cycle. They can fix dinitrogen by using heterocytes, specialized cells containing the oxygen-sensitive nitrogenase enzyme surrounded by a thick polysaccharide and glycolipid layer which prevents oxygen diffusion and nitrogenase inactivation. Heterocyte glycolipids can be used to detect the presence of heterocytous cyanobacteria in present-day and past environments, providing insight into the functioning of the studied ecosystems. However, due to their good preservation throughout time, heterocyte glycolipids are not ideal to detect and study living communities, instead methods based on DNA are preferred. Currently cyanobacteria can be detected using untargeted genomic approaches such as metagenomics, or they can be specifically targeted by, for example, the use of primers that preferentially amplify their 16S rRNA gene or their nifH gene in the case of nitrogen fixing cyanobacteria. However, since not all cyanobacterial nitrogen fixers are heterocytous, there is currently no fast gene-based method to specifically detect and distinguish heterocytous cyanobacteria. Here, we developed a PCR-based method to specifically detect heterocytous cyanobacteria by designing primers targeting the gene (hglT) encoding the enzyme responsible for the last step in the biosynthesis of heterocyte glycolipid (i.e., a glycosyltransferase). We designed several primer sets using the publicly available sequences of 23 heterocytous cyanobacteria, after testing them on DNA extracts of 21 heterocyte-forming and 7 non-heterocyte forming freshwater cyanobacteria. The best primer set was chosen and successfully used to confirm the presence of heterocytous cyanobacteria in a marine environmental sample. [ABSTRACT FROM AUTHOR]

Published

2023

23. Assessing the biomass yield and nitrogen fixation of Lupinus angustifolius varieties as green manure in Jalisco, Mexico.

Author

Zamora Natera, Juan Francisco, Zapata Hernández, Isidro, Aguilar Jiménez, Carlos Ernesto, Martínez Aguilar, Franklin B., and Galdámez Galdámez, José

Subjects

HARVESTING time, LUPINES, BIOMASS production, BIOMASS, FACTORIAL experiment designs, NITROGEN fixation

Abstract

Limited information is available in Mexico regarding the use of Lupinus angustifolius L. as a green manure. This study aimed to assess the effectiveness of six Lupinus angustifolius varieties as green manure in terms of above-ground biomass production, expressed as dry matter (DM), and total nitrogen (N) accumulation at successive harvest dates. Additionally, the study aimed to estimate N2 fixation 110 days after sowing (DAS). The varieties Haags Blaue, Boregine, Borlu, Probor, Sonate, and Boruta were sown during the winter season of 2018-2019 using a randomized block factorial design. The N difference method was employed to estimate N2 fixation, with wheat serving as the reference crop. Data on above-ground biomass production, N concentration, and total N accumulation were recorded at different harvest times: 80, 95, and 110 DAS. The biomass yield of all varieties significantly increased from the first to the last harvest, with the highest yield observed at the final harvest (ranging from 7,632 to 10,200 kg ha-1). The highest total N accumulation from biomass was recorded at the last harvest. On average, the Borlu, Boregine, Haags Blaue, and Boruta varieties accumulated 195.4 kg ha-1 of total N (ranging from 195.6 to 221.2 kg ha-1). The proportion of N derived from the atmosphere (%Ndfa) through N2 fixation averaged 80.09% (ranging from 72% to 93%), resulting in an average N fixation of 160 kg ha-1 (ranging from 106 to 185 kg ha-1) in above-ground biomass. All six varieties demonstrated potential as green manure, considering their above-ground biomass production, total N accumulation, and ability to fix N2. [ABSTRACT FROM AUTHOR]

Published

2023

24. Performance of Maize-Bean Intercropping Assessed Through Varied Spatial Arrangements and Nutrient Phosphorus Levels in Tanzania

Author

Wilson Masele, Eliakira Kisetu, and Makwinja Faraja

Subjects

intercropping, n2 fixation, soil fertility, Agriculture, Plant culture, SB1-1110, Agricultural industries, HD9000-9495

Abstract

Erratic climatic conditions, inherent low fertility and nutrient depletion are among the most important biophysical constraints of food crops production in semi-arid African regions. This study aimed to elucidate the impact of different crop spatial arrangements associated with different levels of Phosphorus on the performance of maize-bean intercropping in Tanzania. The experiment was laid in a complete randomized design of factorial-split arrangement and three factors in different levels. Sowing patterns were randomly assigned to all experimental plots whereas Phosphorus rates were randomly assigned within a specific sowing pattern one after another. Data were subjected to statistical analysis using GenStat software of a generalized treatment structure in a randomized design. Results of the interaction between cropping pattern and the P-rates on beans and maize at a 5% level of significance indicated that grain yield, pods/plant, and biological yield did not differ significantly (P>0.05) while plant height, leaf area index, and plants per plot differed significantly (P

Published

2023

25. High piezo/photocatalytic efficiency of Ag/Bi5O7I nanocomposite using mechanical and solar energy for N2 fixation and methyl orange degradation

Author

Lu Chen, Wenqian Zhang, Junfeng Wang, Xiaojing Li, Yi Li, Xin Hu, Leihong Zhao, Ying Wu, and Yiming He

Subjects

Ag/Bi5O7I, Piezocatalysis, Photocatalysis, N2 fixation, MO degradation, Renewable energy sources, TJ807-830, Ecology, QH540-549.5

Abstract

In this work, Ag/Bi5O7I nanocomposite was prepared and firstly applied in piezo/photocatalytic reduction of N2 to NH3 and methyl orange (MO) degradation. Bi5O7I was synthesized via a hydrothermal-calcination method and shows nanorods morphology. Ag nanoparticles (NPs) were photo deposited on the Bi5O7I nanorods as electron trappers to improve the spatial separation of charge carriers, which was confirmed via XPS, TEM, and electronic chemical analyses. The catalytic test indicates that Bi5O7I presents the piezoelectric-like behavior, while the loading of Ag NPs can strengthen the character. Under ultrasonic vibration, the optimal Ag/Bi5O7I presents high efficiency in MO degradation. The degradation rate is determined to be 0.033 min−1, which is 4.7 folds faster than that of Bi5O7I. The Ag/Bi5O7I also presents a high performance in piezocatalytic N2 fixation. The piezocatalytic NH3 generation rate reaches 65.4 μmol L−1 g−1 h−1 with water as a hole scavenger. The addition of methanol can hasten the piezoelectric catalytic reaction. Interestingly, when ultrasonic vibration and light irradiation simultaneously act on the Ag/Bi5O7I catalyst, higher performance in NH3 generation and MO degradation is observed. However, due to the weak adhesion of Ag NPs, some Ag NPs would fall off from the Bi5O7I surface under long-term ultrasonic vibration, which would greatly reduce the piezoelectric catalytic performance. This result indicates that a strong binding force is required when preparing the piezoelectric composite catalyst. The current work provides new insights for the development of highly efficient catalysts that can use multiple energies.

Published

2023

26. Modulating Lewis acidic active sites of Fe doped Bi2MoO6 nanosheets for enhanced electrochemical nitrogen fixation.

Author

Wang, Ying, Zhang, Yanan, Gao, Yuan, and Wang, Debao

Subjects

*NANOSTRUCTURED materials, *ELECTRON density, *LEWIS acids, *SURFACE texture, *NITROGEN fixation, *DOPING agents (Chemistry)

Abstract

[Display omitted] Electrocatalytic nitrogen reduction reaction (NRR) for artificial ammonia synthesis under mild conditions has been considered as a promising alternative to the conventional Haber–Bosch method. The highly desired efficient NRR still faced with the mulriple challenges of adsorption and activation of N 2 and limited Faraday efficiency. Here, Fe-doped Bi 2 MoO 6 nanosheets fabricated by one step synthesis exhibits high NH 3 yield rate of 71.01 μg·h−1·mg−1 and Faraday Efficiency of 80.12%. The decreased electron density of Bi in collaboration with Lewis acid active sites on Fe-doped Bi 2 MoO 6 , jointly enhance the adsorption and activation of Lewis basic N 2. Benefited from surface texture optimization and the superior ability of N 2 adsorption and activation, the increasing density of effective active sites greatly improve the NRR behavior. This work provides new opportunities for developing efficient and highly selective catalysts for NH 3 synthesis via NRR. [ABSTRACT FROM AUTHOR]

Published

2023

27. Quantifying N2 fixation and its contribution to export production near the Tonga-Kermadec Arc using nitrogen isotope budgets

Author

Heather J. Forrer, Sophie Bonnet, Rachel K. Thomas, Olivier Grosso, Cecile Guieu, and Angela N. Knapp

Subjects

N2 fixation, nitrate d15N, Tonga Arc, South Pacific, hydrothermal vents, d15N budget, Science, General. Including nature conservation, geographical distribution, QH1-199.5

Abstract

The spatial distribution of marine di-nitrogen (N2) fixation informs our understanding of the sensitivities of this process as well as the potential for this new nitrogen (N) source to drive export production, influencing the global carbon (C) cycle and climate. Using geochemically-derived δ15N budgets, we quantified rates of N2 fixation and its importance for supporting export production at stations sampled near the southwest Pacific Tonga-Kermadec Arc. Recent observations indicate that shallow (

Published

2023

28. Plant growth-promoting traits of culturable seed microbiome of citrus species from Purvanchal Himalaya.

Author

Sinha, Sakshi, Thakuria, Dwipendra, Chaliha, Chayanika, Uzir, Panchali, Hazarika, Samarendra, Dutta, Pranab, Singh, A. K., and Laloo, Bingiala

Subjects

MANDARIN orange, INDOLEACETIC acid, ORCHARD management, SEEDS, SPECIES, CITRUS, ORCHARDS

Abstract

Despite Northeastern India being "Treasure House of Citrus Genetic Wealth," genetic erosion of citrus diversity poses severe concern with a corresponding loss in seed microbial diversity. The seed microbiome of citrus species unique to the Purvanchal Himalaya is seldom explored for their use in sustainable orchard management. Isolation and characterization of culturable seed microbiomes of eight citrus species, namely, Citrus reticulata Blanco, C. grandis (L.) Osbeck, C. latipes Tanaka, C. megaloxycarpa Lushaigton, C. jambhiri Lush, C. sinensis (L.) Osbeck, C. macroptera Montr, and C. indica Tanaka collected from NE India were carried out. The isolates were then screened for an array of plant growth-promoting (PGP) traits [indole acetic acid (IAA) production, N2 fixation, phosphate and zinc complex dissolution, siderophores, and Hydrogen Cyanide (HCN) production]. The pure culture isolates of seed microbiomes were capable of dissolving insoluble Ca3(PO4)2 (1.31-4.84 µg Pi ml-1 h-1), Zn3(PO4)2 (2.44-3.16 µg Pi ml-1 h-1), AlPO4 (1.74-3.61 µg Pi ml-1 h-1), and FePO4 (1.54-4.61µg Pi ml-1 h-1), mineralized phytate (12.17-18.00 µg Pi ml-1 h-1) and produced IAA-like substances (4.8-187.29 µg ml-1 h-1). A few isolates of the seed microbiome were also able to fix nitrogen, secrete siderophore-like compounds and HCN, and dissolve ZnSO4 and ZnO. The 16S ribosomal Ribonucleic Acid (rRNA)-based taxonomic findings revealed that Bacillus was the most dominant genus among the isolates across citrus species. Isolates CG2-1, CME6-1, CME6-4, CME6-5, CME6-9, CJ7-1, CMA10-1, CI11-3, and CI11-4 were identified as promising bioinoculants for development of microbial consortium having multifaceted PGP traits for nutritional benefits of nitrogen, phosphorus and zinc, and IAA hormonal benefits to citrus crops for better fitness in acid soils. [ABSTRACT FROM AUTHOR]

Published

2023

29. SELECTION OF SUITABLE GENOTYPES OF LENTIL (Lens culinaris MEDIK.) TOLERANT TO PHOSPHORUS DEFICIENCY.

Author

BOUGHANEM, Wassila, BOUSSALHIH, Ibrahim, and LAZALI, Mohamed

Subjects

*LENTILS, *LEGUME farming, *GENOTYPES, *NITROGEN fixation, *SEED yield, *SOIL fertility

Abstract

Lentil (Lens culinaris Medik.) is a popular Mediterranean legume crop grown for its nutritious seeds and to improve soil fertility. Lentil yield is a critical and difficult trait to improve in crop genetics because it is influenced by various factors that negatively affect seed yields and quality traits. The main constraint to legume production and symbiotic nitrogen fixation is the soil's insufficient phosphorus (P) availability. This P-deficiency also affects rhizobia multiplication in the rhizosphere, reducing the likelihood of infection and nodule growth. The primary goal of this study is to determine the degree of adaptation of lentils to Pdeficiency to select the best genotypes grown, considering growth rate, grain yield, and efficiency in the use of rhizobial symbiosis. In this context, we are investigating the behavior of some lentil genotypes grown in the Khemis Miliana (Algeria) area over two growing seasons, 2018 and 2019. The results show that yield values vary between genotypes, ranging from 500 to 1200 kgha-1; specifically, the genotypes 'Large blonde and 'Ibla 1 recorded the highest yield over two growing seasons. Furthermore, efficiency in the use of the rhizobial symbiosis of lentils was higher for 'Djendel during the 2018 season (1.57 g shoot DWg-1 nodule DW) than for 'Large blonde (0.2 g shoot DWg-1 nodule DW). The genotypes chosen for their P usage efficiency had higher yields and were the best at dealing with low P availability in the field. [ABSTRACT FROM AUTHOR]

Published

2023

30. Quantification of aquatic unicellular diazotrophs by immunolabeled flow cytometry.

Author

Geisler, Eyal, Siebner, Hagar, Rahav, Eyal, and Bar-Zeev, Edo

Subjects

*FLOW cytometry, *NITROGEN cycle, *NITROGENASES, *LASER microscopy, *NITROGEN

Abstract

Unicellular diazotrophs are recognized as important contributors to the aquatic nitrogen cycle. Yet, quantifying the number of aquatic diazotrophs, especially the unicellular fraction, is highly challenging and relies mostly on microscopical and molecular approaches. In this study, a new flow cytometry-based method was developed to quantify unicellular diazotrophs by immunolabeling the nitrogenase enzyme. The quantification method was initially developed using a diazotrophic monoculture (Vibrio natriegens) and verified by different controls as well as various auxiliary approaches such as N2 fixation and confocal laser scanning microscopy. It was evident that only 15–20% of the total number of V. natriegens cells synthesized the nitrogenase enzyme, even though the media was N-limited and anaerobic. This approach was further tested on field samples collected from marine and freshwater environments. Overall, the number of unicellular diazotrophs measured in various aquatic environments ranged from 1 to 6 × 107 cells L−1. However, the fraction of these diazotrophs compared to total bacteria was significantly lower in the Eastern Mediterranean Sea (0.1%) than that collected along the Jordan River (4.7%). Nevertheless, N2 fixation rates per cell were highest in the Mediterranean Sea (~ 90 attomole N cell−1d−1), while lower in the lake and the river measured herein (1.4 to 0.3 attomole N cell−1 d−1, respectively). Following the above, this direct quantification approach can provide new insights on the number and specific contribution of unicellular diazotrophs to total N2 fixation in marine and freshwater environments. [ABSTRACT FROM AUTHOR]

Published

2023

31. Developing a genetic approach to target cyanobacterial producers of heterocyte glycolipids in the environment

Author

Ruth Pérez Gallego, Nicole J. Bale, Jaap S. Sinninghe Damste, and Laura Villanueva

Subjects

heterocytous cyanobacteria, N2 fixation, heterocyte glycolipids, glycosyltransferase, lipid biosynthesis, polymerase chain reaction, Microbiology, QR1-502

Abstract

Heterocytous cyanobacteria are important players in the carbon and nitrogen cycle. They can fix dinitrogen by using heterocytes, specialized cells containing the oxygen-sensitive nitrogenase enzyme surrounded by a thick polysaccharide and glycolipid layer which prevents oxygen diffusion and nitrogenase inactivation. Heterocyte glycolipids can be used to detect the presence of heterocytous cyanobacteria in present-day and past environments, providing insight into the functioning of the studied ecosystems. However, due to their good preservation throughout time, heterocyte glycolipids are not ideal to detect and study living communities, instead methods based on DNA are preferred. Currently cyanobacteria can be detected using untargeted genomic approaches such as metagenomics, or they can be specifically targeted by, for example, the use of primers that preferentially amplify their 16S rRNA gene or their nifH gene in the case of nitrogen fixing cyanobacteria. However, since not all cyanobacterial nitrogen fixers are heterocytous, there is currently no fast gene-based method to specifically detect and distinguish heterocytous cyanobacteria. Here, we developed a PCR-based method to specifically detect heterocytous cyanobacteria by designing primers targeting the gene (hglT) encoding the enzyme responsible for the last step in the biosynthesis of heterocyte glycolipid (i.e., a glycosyltransferase). We designed several primer sets using the publicly available sequences of 23 heterocytous cyanobacteria, after testing them on DNA extracts of 21 heterocyte-forming and 7 non-heterocyte forming freshwater cyanobacteria. The best primer set was chosen and successfully used to confirm the presence of heterocytous cyanobacteria in a marine environmental sample.

Published

2023

32. Plant growth–promoting traits of culturable seed microbiome of citrus species from Purvanchal Himalaya

Author

Sakshi Sinha, Dwipendra Thakuria, Chayanika Chaliha, Panchali Uzir, Samarendra Hazarika, Pranab Dutta, A. K. Singh, and Bingiala Laloo

Subjects

phosphate complexes dissolution, zinc complexes dissolution, IAA production, N2 fixation, siderophore, microbial consortium, Plant culture, SB1-1110

Abstract

Despite Northeastern India being “Treasure House of Citrus Genetic Wealth,” genetic erosion of citrus diversity poses severe concern with a corresponding loss in seed microbial diversity. The seed microbiome of citrus species unique to the Purvanchal Himalaya is seldom explored for their use in sustainable orchard management. Isolation and characterization of culturable seed microbiomes of eight citrus species, namely, Citrus reticulata Blanco, C. grandis (L.) Osbeck, C. latipes Tanaka, C. megaloxycarpa Lushaigton, C. jambhiri Lush, C. sinensis (L.) Osbeck, C. macroptera Montr, and C. indica Tanaka collected from NE India were carried out. The isolates were then screened for an array of plant growth–promoting (PGP) traits [indole acetic acid (IAA) production, N2 fixation, phosphate and zinc complex dissolution, siderophores, and Hydrogen Cyanide (HCN) production]. The pure culture isolates of seed microbiomes were capable of dissolving insoluble Ca3(PO4)2 (1.31–4.84 µg Pi ml-1 h-1), Zn3(PO4)2 (2.44–3.16 µg Pi ml-1 h-1), AlPO4 (1.74–3.61 µg Pi ml-1 h-1), and FePO4 (1.54–4.61µg Pi ml-1 h-1), mineralized phytate (12.17–18.00 µg Pi ml-1 h-1) and produced IAA-like substances (4.8–187.29 µg ml-1 h-1). A few isolates of the seed microbiome were also able to fix nitrogen, secrete siderophore-like compounds and HCN, and dissolve ZnSO4 and ZnO. The 16S ribosomal Ribonucleic Acid (rRNA)–based taxonomic findings revealed that Bacillus was the most dominant genus among the isolates across citrus species. Isolates CG2-1, CME6-1, CME6-4, CME6-5, CME6-9, CJ7-1, CMA10-1, CI11-3, and CI11-4 were identified as promising bioinoculants for development of microbial consortium having multifaceted PGP traits for nutritional benefits of nitrogen, phosphorus and zinc, and IAA hormonal benefits to citrus crops for better fitness in acid soils.

Published

2023

33. Operando analysis reveals potential-driven in situ formation of single-Fe-atom electrocatalysts for green production of ammonia.

Author

Fa Yang, Ping Song, Xin Ge, Yan Wang, Takao Gunji, Wei Zhang, Xiao Zhao, and Weilin Xu

Subjects

*X-ray absorption spectra, *ELECTROCATALYSTS, *STRUCTURE-activity relationships, *OPEN-circuit voltage, *INFRARED absorption, *GREEN products

Abstract

As a sustainable approach for N2 fixation, electrocatalytic N2 reduction reaction (N2RR) to produce ammonia (NH3) is highly desirable with a precise understanding to the structure-activity relationship of electrocatalysts. Here, firstly, we obtain a novel carbon-supported oxygen-coordinated single-Fe-atom catalyst for highly efficient pro-duction of ammonia from electrocatalytic N2RR. Based on such new type of N2RR electrocatalyst, by combining operando X-ray absorption spectra (XAS) with density function theory calculation, we reveal significantly that the as-prepared active coordination structure undergoes a potential-driven two-step restructuring, firstly from FeSAO4(OH)1a to FeSAO4(OH)1a'(OH)1b with the adsorption of another -OH on FeSA at open-circuit potential (OCP) of 0.58 VRHE, and subsequently restructuring from FeSAO4(OH)1a'(OH)1b to FeSAO3(OH)1a" due to the breaking of one Fe-O bond and the dissociation of one --OH at working potentials for final electrocatalytic process of N2RR, thus revealing the first potential-induced in situ formation of the real electrocatalytic active sites to boost the conversion of N2 to NH3. Moreover, the key intermediate of Fe-NNHx was detected experimentally by both operando XAS and in situ attenuated total reflection--surface-enhanced infrared absorption spectra (ATR-SEIRAS), indicating the alternating mechanism followed by N2RR on such catalyst. The results indicate the necessity of considering the potential-induced restructuring of the active sites on all kinds of electrocatalysts for such as highly efficient ammonia production from N2RR. It also paves a new way for a precise understanding to the structure-activity relationship of a catalyst and helps the design of highly efficient catalysts. [ABSTRACT FROM AUTHOR]

Published

2023

34. Silicon Supply Improves Nodulation and Dinitrogen Fixation and Promotes Growth in Trifolium incarnatum Subjected to a Long-Term Sulfur Deprivation.

Author

Coquerel, Raphaël, Arkoun, Mustapha, Dupas, Quentin, Leroy, Fanny, Laîné, Philippe, and Etienne, Philippe

Subjects

NITROGEN fixation, CLOVER, SULFUR, SEED yield, HARVESTING time, ATMOSPHERIC nitrogen, SILICON

Abstract

In many crops species, sulfur (S) deprivation negatively affects growth, seed yield quality and plant health. Furthermore, silicon (Si) is known to alleviate many nutritional stresses but the effects of Si supply on plants subjected to S deficiency remain unclear and poorly documented. The objective of this study was to evaluate whether Si supply would alleviate the negative effects of S deprivation on root nodulation and atmospheric dinitrogen (N2) fixation capacity in Trifolium incarnatum subjected (or not) to long-term S deficiency. For this, plants were grown for 63 days in hydroponic conditions with (500 µM) or without S and supplied (1.7 mM) or not with Si. The effects of Si on growth, root nodulation and N2 fixation and nitrogenase abundance in nodules have been measured. The most important beneficial effect of Si was observed after 63 days. Indeed, at this harvest time, a Si supply increased growth, the nitrogenase abundance in nodules and N2 fixation in S-fed and S-deprived plants while a beneficial effect on the number and total biomass of nodules was only observed in S-deprived plants. This study shows clearly for the first time that a Si supply alleviates negative effects of S deprivation in Trifolium incarnatum. [ABSTRACT FROM AUTHOR]

Published

2023

35. Size-fractionated N2 fixation off the Changjiang Estuary during summer.

Author

Zhibing Jiang, Yuanli Zhu, Zhenhao Sun, Hongchang Zhai, Feng Zhou, Xiaojun Yan, Quanzhen Chen, Jianfang Chen, and Jiangning Zeng

Subjects

ESTUARIES, TERRITORIAL waters, WATER masses, TRICHODESMIUM, KUROSHIO, TURBIDITY, NITROGEN fixation

Abstract

Recent evidence has shown active N2 fixation in coastal eutrophic waters, yet the rate and controlling factors remain poorly understood, particularly in large estuaries. The Changjiang Estuary (CE) and adjacent shelf are characterized by fresh, nitrogen-replete Changjiang Diluted Water (CDW) and saline, nitrogendepletion intruded Kuroshio water (Taiwan Warm Current and nearshore Kuroshio Branch Current), where N2 fixation may be contributed by different groups (i.e., Trichodesmium and heterotrophic diazotrophs). Here, for the first time, we provide direct measurement of size-fractionated N2 fixation rates (NFRs) off the CE during summer 2014 using the 15N2 bubble tracer method. The results demonstrated considerable spatial variations (southern > northern; offshore > inshore) in surface and depth-integrated NFRs, averaging 0.83 nmol N L-1 d-1 and 24.3 µmol N m-2 d-1, respectively. The highest bulk NFR (99.9 µmol N m-2 d-1; mostly contributed by >10 µm fraction) occurred in the southeastern East China Sea, where suffered from strong intrusion of the Kuroshio water characterized by low N/P ratio (<10) and abundant Trichodesmium (up to 10.23 × 106 trichomes m-2). However, low NFR (mostly contributed by <10 µm fraction) was detected in the CE controlled by the CDW, where NOx concentration (up to 80 µmol L-1) and N/P ratio (>100) were high and Trichodesmium abundance was low. The >10 µm fraction accounted for 60% of depth-integrated bulk NFR over the CE and adjacent shelf. We speculated that the present NFR of >10 µm fraction was mostly supported by Trichodesmium. Spearman rank correlation indicated that the NFR was significantly positively correlated with Trichodesmium abundance, salinity, temperature and Secchi depth, but was negatively with turbidity, N/P ratio, NOx, and chlorophyll a concentration. Our study suggests that distribution and size structure of N2 fixation off the CE are largely regulated by water mass (intruded Kuroshio water and CDW) movement and associated diazotrophs (particularly Trichodesmium) and nutrient conditions. [ABSTRACT FROM AUTHOR]

Published

2023

36. Responses in Nodulated Bean (Phaseolus vulgaris L.) Plants Grown at Elevated Atmospheric CO 2.

Author

Bellido, Enrique, de la Haba, Purificación, and Agüera, Eloísa

Subjects

ATMOSPHERIC carbon dioxide, COMMON bean, LEGUMES, BEANS, PLANT fertilization, RHIZOBIUM leguminosarum, AGRICULTURE, CARBON metabolism

Abstract

The increase in the concentration of CO2 in the atmosphere is currently causing metabolomic and physiological changes in living beings and especially in plants. Future climate change may affect crop productivity by limiting the uptake of soil resources such as nitrogen (N) and water. The contribution of legume–rhizobia symbioses to N2 fixation increases the available biological N reserve. Elevated CO2 (eCO2) has been shown to enhance the amount of fixed N2 primarily by increasing biomass. Greater leaf biomass under eCO2 levels increases N demand, which can stimulate and increase N2 fixation. For this reason, bean plants (Phaseolus vulgaris L.) were used in this work to investigate how, in a CO2-enriched atmosphere, inoculation with rhizobia (Rhizobium leguminosarum) affects different growth parameters and metabolites of carbon and nitrogen metabolism, as well as enzymatic activities of nitrogen metabolism and the oxidative state of the plant, with a view to future scenarios, where the concentration of CO2 in the atmosphere will increase. The results showed that bean symbiosis with R. leguminosarum improved N2 fixation, while also decreasing the plant's oxidative stress, and provided the plant with a greater defense system against eCO2 conditions. In conclusion, the nodulation with rhizobia potentially replaced the chemical fertilization of bean plants (P. vulgaris L.), resulting in more environmentally friendly agricultural practices. However, further optimization of symbiotic activities is needed to improve the efficiency and to also develop strategies to improve the response of legume yields to eCO2, particularly due to the climate change scenario in which there is predicted to be a large increase in the atmospheric CO2 concentration. [ABSTRACT FROM AUTHOR]

Published

2023

37. Comparative Effect of Organic and Inorganic Fertilizers On Improving Soil Fertility and Productivity of Different Legumes Under Alkaline Calcareous Soil.

Author

Ullah, Ikram, Tariq, Muhammad, and Sharif, Muhammad

Abstract

Copyright of Gesunde Pflanzen is the property of Springer Nature and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

38. N2 Fixation, N Transfer, and Land Equivalent Ratio (LER) in Grain Legume–Wheat Intercropping: Impact of N Supply and Plant Density

Author

Sebastian Salinas-Roco, Amanda Morales-González, Soledad Espinoza, Ricardo Pérez-Díaz, Basilio Carrasco, Alejandro del Pozo, and Ricardo A. Cabeza

Subjects

legumes, cereal, intercropping, N2 fixation, N transfer, Botany, QK1-989

Abstract

Intercropping legumes with cereals can lead to increased overall yield and optimize the utilization of resources such as water and nutrients, thus enhancing agricultural efficiency. Legumes possess the unique ability to acquire nitrogen (N) through both N2 fixation and from the available N in the soil. However, soil N can diminish the N2 fixation capacity of legumes. It is postulated that in intercropping, legumes uptake N mainly through N2 fixation, leaving more soil N available for cereals. The latter, in turn, has larger root systems, allowing it to explore greater soil volume and absorb more N, mitigating its adverse effects on N2 fixation in legumes. The goal of this study was to evaluate how the supply of N affects the intercropping of faba beans (Vicia faba L.) and peas (Pisum sativum L.) with wheat under varying plant densities and N levels. We measured photosynthetic traits, biomass production, the proportion of N derived from air (%Ndfa) in the shoot of the legumes, the N transferred to the wheat, and the land equivalent ratio (LER). The results revealed a positive correlation between soil N levels and the CO2 assimilation rate (An), chlorophyll content, and N balance index (NBI) in wheat. However, no significant effect was observed in legumes as soil N levels increased. Transpiration (E) increased in wheat intercropped with legumes, while stomatal conductance (gs) increased with N addition in all crops. Water use efficiency (WUE) decreased in faba beans intercropped with wheat as N increased, but it showed no significant change in wheat or peas. The shoot dry matter of wheat increased with the addition of N; however, the two legume species showed no significant changes. N addition reduced the %Ndfa of both legume species, especially in monoculture, with peas being more sensitive than faba beans. The intercropping of wheat alleviated N2 fixation inhibition, especially at high wheat density and increased N transfer to wheat, particularly with peas. The LER was higher in the intercropping treatments, especially under limited N conditions. It is concluded that in the intercropping of wheat with legumes, the N2 fixation inhibition caused by soil N is effectively reduced, as well as there being a significant N transfer from the legume to the wheat, with both process contributing to increase LER.

Published

2024

39. Size-fractionated N2 fixation off the Changjiang Estuary during summer

Author

Zhibing Jiang, Yuanli Zhu, Zhenhao Sun, Hongchang Zhai, Feng Zhou, Xiaojun Yan, Quanzhen Chen, Jianfang Chen, and Jiangning Zeng

Subjects

N2 fixation, Trichodesmium, unicellular diazotrophs, Changjiang Estuary, Changjiang Diluted Water, Kuroshio, Microbiology, QR1-502

Abstract

Recent evidence has shown active N2 fixation in coastal eutrophic waters, yet the rate and controlling factors remain poorly understood, particularly in large estuaries. The Changjiang Estuary (CE) and adjacent shelf are characterized by fresh, nitrogen-replete Changjiang Diluted Water (CDW) and saline, nitrogen-depletion intruded Kuroshio water (Taiwan Warm Current and nearshore Kuroshio Branch Current), where N2 fixation may be contributed by different groups (i.e., Trichodesmium and heterotrophic diazotrophs). Here, for the first time, we provide direct measurement of size-fractionated N2 fixation rates (NFRs) off the CE during summer 2014 using the 15N2 bubble tracer method. The results demonstrated considerable spatial variations (southern > northern; offshore > inshore) in surface and depth-integrated NFRs, averaging 0.83 nmol N L−1 d−1 and 24.3 μmol N m−2 d−1, respectively. The highest bulk NFR (99.9 μmol N m−2 d−1; mostly contributed by >10 μm fraction) occurred in the southeastern East China Sea, where suffered from strong intrusion of the Kuroshio water characterized by low N/P ratio (100) were high and Trichodesmium abundance was low. The >10 μm fraction accounted for 60% of depth-integrated bulk NFR over the CE and adjacent shelf. We speculated that the present NFR of >10 μm fraction was mostly supported by Trichodesmium. Spearman rank correlation indicated that the NFR was significantly positively correlated with Trichodesmium abundance, salinity, temperature and Secchi depth, but was negatively with turbidity, N/P ratio, NOx, and chlorophyll a concentration. Our study suggests that distribution and size structure of N2 fixation off the CE are largely regulated by water mass (intruded Kuroshio water and CDW) movement and associated diazotrophs (particularly Trichodesmium) and nutrient conditions.

Published

2023

40. Effect of rhizobia inoculation and seaweed extract (Ecklonia maxima) application on the growth, symbiotic performance and nutritional content of cowpea (Vigna unguiculata (L.) Walp.)

Author

Cynthia Gyogluu Wardjomto, Mustapha Mohammed, Titus Y. Ngmenzuma, and Keletso C. Mohale

Subjects

biostimulant, cowpea, N2 fixation, seaweed extract, photosynthesis, Rhizobium, Agriculture, Plant culture, SB1-1110

Abstract

Research efforts to develop alternatives to chemical-based fertilizers for sustainable crop production has led to renewed interest in beneficial soil microbes such as rhizobia and plant growth promoting biostimulants such as the seaweed (Ecklonia maxima). This study assessed the interactive effect of the co-application of seaweed extract with two Bradyrhizobium strains (Inoculant 1 and Inoculant 2) on the growth, symbiotic performance and nutritional composition of three cowpea (Vigna unguiculata (L.) Walp.) genotypes (IT97K-390-2, Songotra and TVU13998) grown under glasshouse conditions. The response of cowpea to the treatments was genotype dependent, such that the combined application of inoculant 2 plus seaweed extract increased nodule dry matter in genotype Songotra, and together with sole inoculant 2 increased the parameter in genotype IT97K-390-2, just as the inoculation plus seaweed extract treatments increased the parameter in genotype TVU13998 when compared to their respective counterparts receiving other treatments. Sole inoculation or inoculation plus seaweed extract treatments increased shoot dry matter in all varieties (2.0 to 7.2 g.plant-1) relative to the control plants receiving sole nitrate (0.5 to 1.2 g.plant-1), sole seaweed extract (0.3 g.plant-1), nitrate plus seaweed extract (1.2 to 1.6 g.plant-1) or the absolute control (0.2 g.plant-1). Due to N2 fixation in the inoculated plants, their leaf δ15N (-2.66‰ to -1.20‰) were markedly lower (p≤0.001) than values recorded by the control plants (+3.30‰ to +510‰) which had no nodules; consequently, leaf N accumulation was greater in the inoculation-based treatments (41.2 to 258.2 mg.plant-1) relative to the uninoculated controls (1.7 to 24.7 mg.plant-1). In most instances, the sole inoculation and inoculation plus seaweed extract treatments increased leaf photosynthetic rates (except for genotype TVU13998 treated with inoculant 1 + seaweed extract), water use efficiency (δ13C) (except in genotype TVU13998) and the concentrations of macro and micronutrients in leaves (except for K in Songotra treated with inoculant 1 or inoculant 1 + seaweed extract as well as Mn in TVU13998 treated with inoculant 1 among others) of the cowpeas relative to the controls. We highlight the potential benefits of the synergistic interactions between rhizobia and seaweed extract for enhancing plant growth and nutrient accumulation in cowpea leaves.

Published

2023

41. Simulated heat waves promote the growth but suppress the N2 fixation rates of Dolichospermum spp. and cyanobacterial communities in temperate lakes

Author

Benjamin J. Kramer and Christopher J. Gobler

Subjects

Nitrogen, Ammonium, Nitrate, Heat waves, N2 fixation, Cyanobacteria, Ecology, QH540-549.5

Abstract

The intensity and duration of heat waves are expected to increase this century, occurrences considered favorable for harmful, bloom-forming freshwater cyanobacteria. Dinitrogen (N2) fixation is a major component of nitrogen cycling in freshwater systems, yet little is known with respect to how diazotrophic (N2 fixing) cyanobacteria respond to heat waves. Here, we quantified the effects of elevated temperature and fixed N enrichment on the growth and N2 fixation rates of Dolichospermum isolates from differing latitudes and cyanobacterial communities in four lakes across New York state, USA, during the summer and early fall. In culture experiments, temperatures ≥ 26℃ significantly reduced maximum growth rates of the sub-polar Dolichospermum strains from Finland relative to those grown at 20 − 25℃, while a strain of Dolichospermum isolated from subtropical Australia grew significantly faster at 20 − 30℃ compared to cooler temperatures. All strains, however, exhibited significantly lower N2 fixation rates at higher temperatures (29 − 30℃) relative to lower temperatures (13-26℃). During ecosystem-based experiments with cyanobacterial communities comprised of Nostocales and other diazotrophic cyanobacteria, short-term (3–4 day) exposures to elevated temperatures mimicking heat waves (+3-6℃; 27-31℃) and/or N (NH4+) enrichment caused a significant increase in cyanobacterial net growth rates but also caused a significant decline in N2 fixation rates. Collectively, results indicate that while heat waves and fixed N loading can promote cyanobacterial communities, they also suppress diazotrophy, which is generally regarded as a significant component of nitrogen cycling in eutrophic freshwater systems. Such reductions in N2 fixation would promote or intensify N limitation of primary production in lakes during the summer, an outcome that would be exacerbated under future warming scenarios.

Published

2023

42. Excess labile carbon promotes diazotroph abundance in heat-stressed octocorals

Author

Nan Xiang, Achim Meyer, Claudia Pogoreutz, Nils Rädecker, Christian R. Voolstra, Christian Wild, and Astrid Gärdes

Subjects

coral reefs, global warming, organic eutrophication, symbiosis, N2 fixation, octocoral prokaryotes, Science

Abstract

Nitrogen limitation is the foundation of stable coral-algal symbioses. Diazotrophs, prokaryotes capable of fixing N2 into ammonia, support the productivity of corals in oligotrophic waters, but could contribute to the destabilization of holobiont functioning when overstimulated. Recent studies on reef-building corals have shown that labile dissolved organic carbon (DOC) enrichment or heat stress increases diazotroph abundance and activity, thereby increasing nitrogen availability and destabilizing the coral-algal symbiosis. However, the (a)biotic drivers of diazotrophs in octocorals are still poorly understood. We investigated diazotroph abundance (via relative quantification of nifH gene copy numbers) in two symbiotic octocorals, the more mixotrophic soft coral Xenia umbellata and the more autotrophic gorgonian Pinnigorgia flava, under (i) labile DOC enrichment for 21 days, followed by (ii) combined labile DOC enrichment and heat stress for 24 days. Without heat stress, relative diazotroph abundances in X. umbellata and P. flava were unaffected by DOC enrichment. During heat stress, DOC enrichment (20 and 40 mg glucose l−1) increased the relative abundances of diazotrophs by sixfold in X. umbellata and fourfold in P. flava, compared with their counterparts without excess DOC. Our data suggest that labile DOC enrichment and concomitant heat stress could disrupt the nitrogen limitation in octocorals by stimulating diazotroph proliferation. Ultimately, the disruption of nitrogen cycling may further compromise octocoral fitness by destabilizing symbiotic nutrient cycling. Therefore, improving local wastewater facilities to reduce labile DOC input into vulnerable coastal ecosystems may help octocorals cope with ocean warming.

Published

2023

43. Deoxygenation enhances photosynthetic performance and increases N2 fixation in the marine cyanobacterium Trichodesmium under elevated pCO2

Author

He Li and Kunshan Gao

Subjects

growth rate, N2 fixation, photosynthesis, respiration, Trichodesmium erythraeum, Microbiology, QR1-502

Abstract

Effects of changed levels of dissolved O2 and CO2 on marine primary producers are of general concern with respect to ecological effects of ongoing ocean deoxygenation and acidification as well as upwelled seawaters. We investigated the response of the diazotroph Trichodesmium erythraeum IMS 101 after it had acclimated to lowered pO2 (~60 μM O2) and/or elevated pCO2 levels (HC, ~32 μM CO2) for about 20 generations. Our results showed that reduced O2 levels decreased dark respiration significantly, and increased the net photosynthetic rate by 66 and 89% under the ambient (AC, ~13 μM CO2) and the HC, respectively. The reduced pO2 enhanced the N2 fixation rate by ~139% under AC and only by 44% under HC, respectively. The N2 fixation quotient, the ratio of N2 fixed per O2 evolved, increased by 143% when pO2 decreased by 75% under the elevated pCO2. Meanwhile, particulate organic carbon and nitrogen quota increased simultaneously under reduced O2 levels, regardless of the pCO2 treatments. Nevertheless, changed levels of O2 and CO2 did not bring about significant changes in the specific growth rate of the diazotroph. Such inconsistency was attributed to the daytime positive and nighttime negative effects of both lowered pO2 and elevated pCO2 on the energy supply for growth. Our results suggest that Trichodesmium decrease its dark respiration by 5% and increase its N2-fixation by 49% and N2-fixation quotient by 30% under future ocean deoxygenation and acidification with 16% decline of pO2 and 138% rise of pCO2 by the end of this century.

Published

2023

44. A gulf-wide synoptic isoscape of zooplankton isotope ratios reveals the importance of nitrogen fixation in supporting secondary production in the central Gulf of Mexico

Author

Oscar Gabriel Hernández-Sánchez, Víctor F. Camacho-Ibar, Leticia Barbero, Juan Carlos Herguera, and Sharon Z. Herzka

Subjects

mesozooplankton, isoscape, nitrogen sources, Bayesian mixing model, N2 fixation, Gulf of Mexico (GOM), Science, General. Including nature conservation, geographical distribution, QH1-199.5

Abstract

A synoptic gulf-wide isoscape of carbon (δ13C) and nitrogen (δ15N) in the Gulf of Mexico based on mesozooplankton (335-1000 um) was used as a proxy for the isotopic baseline and for calculating regional contributions of dissolved inorganic nitrogen sources. Mesozooplankton were sampled at 0-200 m (depth permitting) during the XIXIMI-06 and GOMECC-3 cruises held during the summer of 2017. A striking latitudinal gradient was found in δ15N values of zooplankton, with the highest values (10.4 ± 1.2‰) found over the northern shelf, and lowest values in the central, oligotrophic gulf (1.9 ± 0.5‰). To estimate the fractional contribution of potential nitrogen sources, the gulf was divided into six regions based on the spatial distribution of surface Chl-a, SST from remote sensing products and likely region-specific source contributions. A literature survey of (δ13C and δ15N values of particulate organic matter was used to characterize region-specific endpoint isotope ratios for use in a Bayesian isotope mixing model. Regional differences in δ15N values and the results of mixing models indicated nitrogen fixation is most likely an important source (45-74% contribution) of new nitrogen in the oceanic regions of the Gulf, the Loop Current and the Yucatan Shelf. In the oligotrophic gulf, the potential input of relatively light nitrate that reflects remineralization of surface layer POM or the excretion of light nitrogen by heterotrophs was insufficient to explain the low δ15N values found in the central Gulf, although it could account for about 40% of the N supporting secondary production. The high nitrogen isotope ratios found in the northern shelf were attributed to denitrified N (60%) and the inflow of heavy nitrogen from the Mississippi-Atchafalaya river system. Our results support the potential importance of fixed nitrogen in the deep waters of the Gulf of Mexico during the summer, characteristic for its highly stratified surface waters.

Published

2023

45. Symbiotic effectiveness of Bradyrhizobium strains on soybean growth and productivity in Northern Mozambique

Author

Stephen Kyei-Boahen, Canon Engoke Norris Savala, Carlos Pedro Muananamuale, Carlos Malita, Alexander Nimo Wiredu, Amaral Machaculeha Chibeba, Patrick Elia, and David Chikoye

Subjects

soybean, rhizobia strains, inoculation, nodulation, N2 fixation, grain yield, Nutrition. Foods and food supply, TX341-641, Food processing and manufacture, TP368-456

Abstract

Inoculation of soybean [Glycine max (L.) Merr.] with rhizobia strains is a low-cost investment which can increase yields of smallholder farmers in Mozambique. The performance of four Bradyrhizobium strains was evaluated to identify the best strain to inoculate soybean grown in different agro-ecologies. Field experiments were conducted in three ecological zones in 2018 and 2019 using soybean variety Zamboane inoculated with Bradyrhizobium diazoefficiens strain USDA 110, B. japonicum strains USDA 136, USDA 442 and WB74, and a non-inoculated control in a randomized complete block design with four replications. Indigenous rhizobia populations at the sites ranged from 9.0 x 101 to 2.2 x 103 cells g−1 soil. All four strains increased nodulation, but USDA 110 was superior at two sites with low native rhizobia population, whereas USDA 442 and WB74 were the best at the site with relatively high native rhizobia population. On an average, the strains doubled the number of nodules and increased the dry weight up to 5.8-fold. Inoculation increased shoot dry weight and N content at podding, plant biomass, and number of pods plant−1 across sites but the effects of the strains on seeds per pod, and 100-seed weight were inconsistent. Shoot N content did not differ among inoculant strains and ranged from 15.70 g kg−1 in the control to 38.53 g kg−1 across inoculation. All four strains increased soybean grain yield across sites in 2018 but USDA 110 outperformed the other strains and was also the best at one of the two sites in 2019. Grain yield responses associated with USDA 110 ranged from 552 kg ha−1 (56%) to 1,255 kg ha−1 (76%). Positive correlations between nodule dry weight plant−1 and seed yield, and number of pods plant−1 and grain yield were observed. The gross margin ranged from $343.50–$606.80 ha−1 for the control, but it increased to $688.34–$789.36 when inoculants were applied. On an average, inoculation increased gross margin by $182.57-$395.35 ha−1 over that of non-inoculated control in 2018 but drought stress in 2019 reduced the benefit. The results demonstrate that USDA 110 was the best inoculant strain and has the potential of increasing smallholder productivity and net returns.

Published

2023

46. Exploring the Role of Cryptic Nitrogen Fixers in Terrestrial Ecosystems: A Frontier in Nitrogen Cycling Research.

Author

Cleveland, Cory C., Reis, Carla R. G., Perakis, Steven S., Dynarski, Katherine A., Batterman, Sarah A., Crews, Timothy E., Gei, Maga, Gundale, Michael J., Menge, Duncan N. L., Peoples, Mark B., Reed, Sasha C., Salmon, Verity G., Soper, Fiona M., Taylor, Benton N., Turner, Monica G., and Wurzburger, Nina

Subjects

*NITROGEN fixation, *NITROGEN cycle, *ECOSYSTEMS, *PLANT litter, *SOIL microbiology, *BALLAST water

Abstract

Biological nitrogen fixation represents the largest natural flux of new nitrogen (N) into terrestrial ecosystems, providing a critical N source to support net primary productivity of both natural and agricultural systems. When they are common, symbiotic associations between plants and bacteria can add more than 100 kg N ha−1 y−1 to ecosystems. Yet, these associations are uncommon in many terrestrial ecosystems. In most cases, N inputs derive from more cryptic sources, including mutualistic and/or free-living microorganisms in soil, plant litter, decomposing roots and wood, lichens, insects, and mosses, among others. Unfortunately, large gaps remain in the understanding of cryptic N fixation. We conducted a literature review to explore rates, patterns, and controls of cryptic N fixation in both unmanaged and agricultural ecosystems. Our analysis indicates that, as is common with N fixation, rates are highly variable across most cryptic niches, with N inputs in any particular cryptic niche ranging from near zero to more than 20 kg ha−1 y−1. Such large variation underscores the need for more comprehensive measurements of N fixation by organisms not in symbiotic relationships with vascular plants in terrestrial ecosystems, as well as identifying the factors that govern cryptic N fixation rates. We highlight several challenges, opportunities, and priorities in this important research area, and we propose a conceptual model that posits an interacting hierarchy of biophysical and biogeochemical controls over N fixation that should generate valuable new hypotheses and research. [ABSTRACT FROM AUTHOR]

Published

2022

47. Unraveling the Effects of Pruning Frequency on Biomass Productivity, Nonstructural Carbohydrates and Nitrogen Fixation Rates of Sesbania sesban.

Author

Makhubedu, Thabo I., Letty, Brigid A., Mafongoya, Paramu L., and Scogings, Peter F.

Subjects

SESBANIA, NITROGEN fixation, BIOMASS, CARBOHYDRATES, TREE pruning, BIOMASS production, PLANT biomass

Abstract

Tree pruning is a management tool in agroforestry systems for reducing shade, enhancing nutrient cycling or providing fodder. However, little information is available on the effect of pruning management on plant growth, nonstructural carbohydrate (NSC) levels in the roots and N2 fixation of Sesbania sesban. A glasshouse experiment was conducted to assess the effect of pruning frequency on biomass production, NSC levels and N2 fixation of Sesbania sesban. Pruning treatments consisted of a control (PF0), one pruning at 3 months after transplanting (MAT) (PF1), two successive prunings at 3 and 6 MAT (PF2), and three successive prunings at 3, 6 and 9 MAT (PF3), with each pruning removing shoot biomass above 50% of the initial height. The experiment was laid out in a completely randomized design (CRD) with four replications. Results showed that increasing pruning frequency resulted in decreased nodulation and nonstructural carbohydrate levels in the roots. Above and below ground biomass, root length, percentage N derived from the atmosphere and amount of N2 fixed were decreased in a similar manner whether plants were successively pruned twice or thrice. It can be concluded that two or three successive prunings in nine months significantly reduce nonstructural carbohydrates, DM productivity and N2 fixation of S. sesban, and might result in supply of insufficient biomass required for improving soil N fertility and livestock production. [ABSTRACT FROM AUTHOR]

Published

2022

48. Single-Atom Co-Catalysts Employed in Titanium Dioxide Photocatalysis.

Author

Kerketta, Ujjaval, Tesler, Alexander B., and Schmuki, Patrik

Subjects

*TITANIUM dioxide, *PHOTOCATALYSIS, *HETEROGENEOUS catalysis, *CHEMICAL reactions, *CHARGE transfer, *ELECTRONIC structure

Abstract

With a distinct electronic structure and unsaturated coordination centers, supported single-atoms (SAs) have shown great potential in heterogeneous catalysis due to their superior activity, stability, and selectivity. Over the last few years, the fascination of SA-use spread also over photocatalysis, i.e., a particular case of heterogeneous catalysis in which chemical reactions are activated by charge transfer from an illuminated semiconductor. Titanium dioxide (TiO2) is one of the most studied photocatalytic materials. It is widely used as a light absorbing semiconductor decorated with metallic (nanoparticles and single-atom) co-catalysts. In the current review, we emphasize the role of SAs as a co-catalyst in photocatalysis, and clearly set it apart from the use of single atoms in classic heterogeneous catalysis. The review first briefly describes the principal features of SAs, and gives an overview of most important examples of single-atom co-catalysts. Then, we discuss photocatalysis and key examples of single-atom co-catalysts used on TiO2 photocatalysts and their applications. At last, we provide an outlook for further exploring TiO2-based single-atom photocatalytic systems. [ABSTRACT FROM AUTHOR]

Published

2022

49. Comparative Transcriptomics Sheds Light on Remodeling of Gene Expression during Diazotrophy in the Thermophilic Methanogen Methanothermococcus thermolithotrophicus

Author

Nevena Maslać, Chandni Sidhu, Hanno Teeling, and Tristan Wagner

Subjects

methanogenic archaea, N2 fixation, thermophile, nitrogenase, nitrogen starvation, differential transcriptomics, Microbiology, QR1-502

Abstract

ABSTRACT Some marine thermophilic methanogens are able to perform energy-consuming nitrogen fixation despite deriving only little energy from hydrogenotrophic methanogenesis. We studied this process in Methanothermococcus thermolithotrophicus DSM 2095, a methanogenic archaeon of the order Methanococcales that contributes to the nitrogen pool in some marine environments. We successfully grew this archaeon under diazotrophic conditions in both batch and fermenter cultures, reaching the highest cell density reported so far. Diazotrophic growth depended strictly on molybdenum and, in contrast to other diazotrophs, was not inhibited by tungstate or vanadium. This suggests an elaborate control of metal uptake and a specific metal recognition system for the insertion into the nitrogenase cofactor. Differential transcriptomics of M. thermolithotrophicus grown under diazotrophic conditions with ammonium-fed cultures as controls revealed upregulation of the nitrogenase machinery, including chaperones, regulators, and molybdate importers, as well as simultaneous upregulation of an ammonium transporter and a putative pathway for nitrate and nitrite utilization. The organism thus employs multiple synergistic strategies for uptake of nitrogen nutrients during the early exponential growth phase without altering transcription levels for genes involved in methanogenesis. As a counterpart, genes coding for transcription and translation processes were downregulated, highlighting the maintenance of an intricate metabolic balance to deal with energy constraints and nutrient limitations imposed by diazotrophy. This switch in the metabolic balance included unexpected processes, such as upregulation of the CRISPR-Cas system, probably caused by drastic changes in transcription levels of putative mobile and virus-like elements. IMPORTANCE The thermophilic anaerobic archaeon M. thermolithotrophicus is a particularly suitable model organism to study the coupling of methanogenesis to diazotrophy. Likewise, its capability of simultaneously reducing N2 and CO2 into NH3 and CH4 with H2 makes it a viable target for biofuel production. We optimized M. thermolithotrophicus cultivation, resulting in considerably higher cell yields and enabling the successful establishment of N2-fixing bioreactors. Improved understanding of the N2 fixation process would provide novel insights into metabolic adaptations that allow this energy-limited extremophile to thrive under diazotrophy, for instance, by investigating its physiology and uncharacterized nitrogenase. We demonstrated that diazotrophic growth of M. thermolithotrophicus is exclusively dependent on molybdenum, and complementary transcriptomics corroborated the expression of the molybdenum nitrogenase system. Further analyses of differentially expressed genes during diazotrophy across three cultivation time points revealed insights into the response to nitrogen limitation and the coordination of core metabolic processes.

Published

2022

50. Nonconservative behavior of dissolved molybdenum and its potential role in nitrogen cycling in the Bohai and Yellow Seas

Author

Jinqi Fan, Liqin Duan, Meiling Yin, Huamao Yuan, and Xuegang Li

Subjects

dissolved molybdenum, nonconservative behavior, biological uptake, N2 fixation, nitrate reduction, Science, General. Including nature conservation, geographical distribution, QH1-199.5

Abstract

Molybdenum plays an important role in marine biological activity, especially in nitrogen cycling as a cofactor for N2 fixation and nitrate reductase. However, the dissolved Mo (dMo) behavior and its interaction with N cycling in the coastal waters is still unclear. In this study, the dMo concentrations and parameters related to Mo distribution and N cycling in surface and bottom seawaters of the Bohai (BS) and Yellow Seas (YS) were examined. The results showed that dMo concentrations ranged from 36.4 nmol L-1 to 125.0 nmol L-1, most of which deviated significantly from the conservative line, indicating nonconservative behavior of Mo relative to salinity. The highest dMo concentrations occurring in 36°N section of north of the South YS (SYS), were close to conservative value (105 nmol L-1). Significant depletion up to 40-50 nmol L-1 of dMo mainly appeared in the BS, NYS and south of the SYS, suggesting the possible removal of dMo by biological utilization and particle adsorption. Particularly, the increasing dMo concentrations away the Yellow River estuary indicated that freshwater dilution was one of reasons for dMo distributions in the BS. The similar spatial distribution of dMo and dissolved Mn concentrations suggested the possible scavenging by MnOx phases for Mo removal. The negative correlation between dMo and chlorophyll-a (Chl-a) concentrations in surface seawaters suggested that biological uptake was involved in dMo removal. The depleted dMo in most of sites corresponded with the higher nitrite concentrations, implying the possible involvement of nitrate reduction process. Although the highest N2 fixation rates and relative abundances of cyanobacteria appeared in 36°N section, corresponding with the conservative dMo, suggesting that Mo may play a minor role in N2 fixation process there. The ten-folds of relative abundance of bacteria with nitrate reduction function than that with N2 fixation function suggested that dMo seems to play more important role in nitration reduction than nitrogen fixation in the BS and YS.

Published

2022