Bacterial Subspecies Variation and Nematode Grazing Change P Dynamics in the Wheat Rhizosphere

Low phosphorus soils are thought to constitute the majority of soils worldwide and cannot support intensive agriculture without high fertilizer inputs. Rhizobacteria are well-known to modify P dynamics and an increased bacterial diversity normally has a positive impact on various process rates. However, it is not known how variation in bacterial diversity at the subspecies level could influence trophic interactions in the rhizosphere and its consequences on plant P nutrition. We therefore hypothesized that the interactions between closely related P solubilizing bacteria and their grazing nematodes could improve plant P dynamics from an unavailable P source. We isolated four Pseudomonas poae strains and extracted nematodes from a Saskatchewan wheat field soil sample. The potential of all bacterial isolates with and without nematodes for increasing P availability in the wheat rhizosphere was tested in controlled microcosms with Ca3(PO4)2 as sole P source. Liberated P, phosphatase activity, plant P and bacterial abundance based on phnX gene copies were determined. Phosphorus solubilization efficiency of isolates varied between isolates whereas phosphatase enzyme activity was only detected under nematodes grazing and during the first 15 days of the experiment. Nematodes grazing upon individual Pseudomonas poae increased phosphatase enzyme activity, bacterial abundance, but decreased plant P concentration compared to non-grazed system. In contrast, the treatment combining all Pseudomonas poae isolates together with nematodes resulted in significant increases in P availability and plant P concentration. Diverse P-solubilizing efficiency and interaction with nematodes within the same bacterial “species” suggest that P dynamics might be linked to micro variation in soil diversity that would not accurately be picked up using common tools such as 16S rRNA gene sequencing

Trophic relationships in the rhizosphere (effect of fungal, bacterial and nematode interactions on mineral nutrition of Pinus pinaster seedlings)

Les microorganismes agissent comme un puits et une source de N et Pdisponibles car ils sont responsables des cycles biogéochimiques de N et P. La bouclemicrobienne, basée sur la prédation des bactéries par les microprédateurs tels que lesnématodes bactérivores, est considérée comme un facteur majeur de la minéralisation de Net de P dans les écosystèmes terrestres. Cependant, peu de données sont disponibles surl'impact de la prédation par les nématodes sur la nutrition minérale des plantes ligneusesectomycorhizées. Différentes expérimentations ont été conduites pour quantifier le rôle dela prédation des bactéries par les nématodes sur l'architecture et la croissance racinaire, lanutrition minérale (N et P) d'une espèce ligneuse, Pinus pinaster, associée ou non avec lebasidiomycète ectomycorhizien Hebeloma cylindrosporum. Les plantes ont été cultivéesdans un système expérimental simplifié et stérile, et inoculées ou non avec Bacillus subtiliset des nématodes bactérivores (de la famille des Rhabditidae ou des Cephalobidae) isolés àpartir d'ectomycorhizes et de sol provenant d'une plantation de Pin maritime. L'effet de laprédation sur la croissance des plantes et le devenir du 15N bactérien vers les partiesaériennes dépend très fortement de la disponibilité en P du milieu. De plus, la prédationdes bactéries est indispensable pour permettre à la plante d'utiliser le P du phytate, unesource de P organique très peu disponible pour la plante mais très facilement utilisable parB. subtilis car cette bactérie est capable de libérer de la phytase dans le milieu. Cesrésultats ouvrent de nouvelles perspectives pour améliorer l'utilisation du phytate pour lanutrition phosphatée des plantes.Soil microorganisms act as a sink and a source of available N and P bymediating key processes in the biogeochemical N and P cycling. The microbial loop, basedupon the grazing of bacteria by predators such as bacterial-feeding nematodes, is thoughtto play a major role in the mineralization of nutrients such as nitrogen (N) and phosphorus(P) in terrestrial ecosystems. However, little is known about the impact of grazing bynematodes on mineral nutrition of ectomycorrhizal woody plants. Different studies wereundertaken to quantify the role of nematode grazing on bacteria on the root growth andarchitecture, mineral nutrition (N and P) of a woody species, Pinus pinaster, whether ornot associated with the ectomycorrhizal basidiomycete Hebeloma cylindrosporum. Plantswere grown in a sterile simplified experimental system, whether inoculated or not withBacillus subtilis and bacterial-feeding nematodes (belonging to Rhabditidae orCephalobidae families) that were isolated from ectomycorrhizae and from soil of a P.pinaster plantation. The effect of nematode grazing on plant growth and the fate ofbacterial 15N towards plant shoots was strongly dependent upon medium P availability. Inaddition, nematode grazing was required to enable the plant to access P from phytate, awell-known poorly available P source to plants but that was used by bacterial populationsof B. subtilis due to its ability to release phytase in the medium. These results open analternative route to increase the use of phytate for plant P nutrition.MONTPELLIER-SupAgro La Gaillarde (341722306) / SudocSudocFranceF

From soil to plant, the journey of P through trophic relationships and ectomycorrhizal association

Phosphorus (P) is essential for plant growth and productivity. It is one of the most limiting macronutrients in soil because it is mainly present as unavailable, bound P whereas plants can only use unbound, inorganic phosphate (Pi), which is found in very low concentrations in soil solution. Some ectomycorrhizal fungi are able to release organic compounds (organic anions or phosphatases) to mobilize unavailable P. Recent studies suggest that bacteria play a major role in the mineralization of nutrients such as P through trophic relationships as they can produce specific phosphatases such as phytases to degrade phytate, the main form of soil organic P. Bacteria are also more effective than other microorganisms or plants at immobilizing free Pi. Therefore, bacterial grazing by grazers, such as nematodes, could release Pi locked in bacterial biomass. Free Pi may be taken up by ectomycorrhizal fungus by specific phosphate transporters and transferred to the plant by mechanisms that have not yet been identified. This mini-review aims to follow the phosphate pathway to understand the ecological and molecular mechanisms responsible for transfer of phosphate from the soil to the plant, to improve plant P nutrition

Probabilistic Analysis of Strength of Structural Concrete for Post-Code Buildings in Developing Countries

Code compliance and quality construction remain a point of interest for developing countries. For structural vulnerability studies on reinforced concrete buildings, researchers usually adopt random strength parameters to represent the compressive strength of concrete for various structural members. This matter becomes a challenge if researchers are dealing to quantify the structural response of code-compliant buildings. Since the research on the response of code-compliant buildings is limited hence this paper aims at data collection and presenting the probabilistic trends in compressive strength variation of structural concrete being used or has been used in multiple projects of the federal capital city of Pakistan for code-compliant buildings. The data has been collected from well-reputed academic and commercial testing labs in the area for past 10 years (the timeline after implementation of BCP 2007). Compressive strength testing records of concrete cylinders for 28 days strength have been sorted for different structural members i.e., beams, columns, shear walls, slabs and footings separately. From the selected data, histograms have been plotted for each member category and mean values with standard deviations have been highlighted. Obtained results are further compared with anticipated design compressive strengths which were obtained from different tagged reports, design offices and resident engineers of the sites. The produced results would lead to true representation of structural strength of concrete for code-compliant buildings, to be further studied for structural vulnerability and risk assessments of the desired areas in developing countries

Hydrogen Production Using TiO2-Based Photocatalysts: A Comprehensive Review

Titanium dioxide (TiO2) is one of the most widely used photocatalysts due to its physical and chemical properties. In this study, hydrogen energy production using TiO2- and titanate-based photocatalysts is discussed along with the pros and cons. The mechanism of the photocatalysis has been elaborated to pinpoint the photocatalyst for better performance. The chief characteristics and limitations of the TiO2 photocatalysts have been assessed. Further, TiO2-based photocatalysts modified with a transition metal, transition metal oxide, noble metal, graphitic carbon nitride, graphene, etc. have been reviewed. This study will provide a basic understanding to beginners and detailed knowledge to experts in the field to optimize the TiO2-based photocatalysts for hydrogen production

Energy and economic analysis of building integrated photovoltaic thermal system: Seasonal dynamic modeling assisted with machine learning-aided method and multi-objective genetic optimization

Building integrated photovoltaic thermal (BIPV/T) systems offer a highly effective means of generating clean energy for both electricity and heating purposes in residential buildings. Hence, this article introduces a new BIPV/T system to optimally minimize the energy consumption of a household residential building. The meticulous design of the proposed BIPV/T system is accomplished through MATLAB/Simulink® dynamic modeling. Performance analysis for the BIPV/T system is performed under different seasonal conditions with in-depth techno-economic analyses to estimate the expected enhancement in the thermal, electrical, and economic performance of the system. Moreover, a sensitivity analysis is conducted to explore the impact of various factors on the energetic and economic performances of the proposed BIPV/T system. More so, the two-layer feed-forward back-propagation artificial neural network modeling is developed to accurately predict the hourly solar radiation and ambient temperature for the BIPV/T. Additionally, a multi-objective optimization using the NSGA-II method is also conducted for the minimization of the total BIPV/T plant area and maximization of the total efficiency and net thermal power of the system as well as to estimate the optimized operating conditions for input variables across different seasons within the provided ranges. The sensitivity analysis revealed that higher solar flux levels lead to increased electric output power of the BIPV/T plant, but total efficiency decreases due to higher thermal losses. Moreover, the proposed NSGA-II shows a feasible method to attain a maximum net thermal power and optimal total efficiency of 5320 W and 63% with a minimal total plant area of 32.89 m2 that attained a very low deviation index from the ideal solution. The levelised cost of electricity is obtained as 0.10 $/kWh under the optimal conditions. Thus, these findings offer valuable insights into the potential of BIPV/T systems as a sustainable and efficient energy solution for residential applications