Integrative Soil Application of Humic Acid and Foliar Plant Growth Stimulants Improves Soil Properties and Wheat Yield and Quality in Nutrient-Poor Sandy Soil of a Semiarid Region.

Sandy soils (containing > 50% sand) are widely distributed worldwide and are characterized by their poor structure, low organic matter, weak hydraulic and nutritional properties, and low crop productivity. Using a 2-year pot experiment, in this study, we investigated the effects of humic acid (HA) as a soil amendment and study two plant growth stimulants (PGSs), zinc oxide nanoparticles (ZnONPs), and L-tryptophan (L-TRP), as a foliar application on wheat grown in nutrient-poor sandy soil. Three HA rates (0 (HA0), 0.2 (HA0.2), and 0.4 (HA0.4) g kg-1 soil) and five PGS levels [control, 50 mg l-1 (ZnONPs50), 100 mg l-1 (ZnONPs100), 0.25 mmol l-1 (L-TRP0.25), and 0.5 mmol l-1 (L-TRP0.5)] were used. The soil hydro-physico-chemical properties, morpho-physiological responses, yield, and quality were measured. HA addition amended the soil structure by allowing rapid macroaggregate formation, decreasing bulk density and pH, and increasing porosity and electrical conductivity, thereby improving soil hydraulic properties. HA0.2 and HA0.4 additions improved growth, yield components, and grain minerals, resulting in higher grain yield by 28.3-54.4%, grain protein by 10.2-13.4%, wet gluten by 18.2-23.3%, and dry gluten by 23.5-29.5%, respectively, than HA0. Foliar application of ZnONPs or L-TRP, especially at higher concentrations compared to the control, noticeably recorded the same positive results as HA treatments. The best results were achieved through the integration of HA0.4 + ZnONPs100 or L-TRP0.5 to the tested nutrient-poor sandy soil. The interactive application of HA0.4 + ZnONPs100 or L-TRP0.5 and the use of mineral fertilizer, which is considered a surplus point in permaculture, can be recommended for sustainable wheat production in nutrient-poor sandy soil.

Induction of protein aggregation in zebrafish embryos as a method for the screening of new drugs or mutations against proteinopathies.

The sustained increase in the prevalence of protein aggregation related diseases requires the development of feasible methods for the design of therapeutic alternatives. The procedure traditionally used for the search of drugs or therapeutic mutations includes in vitro experiments, designed to prevent the aggregation of model proteins, which are then complemented with cellular toxicity studies in vivo, slowing down the finding of solutions. To address this, we have developed a protocol that facilitates the search of molecules and anti-aggregation mutations since it allows to evaluate their therapeutic capabilities directly in in vivo experiments with the use of zebrafish early embryos. Avoiding the necessity of performing in vitro and in vivo procedures separately. Giving a more realistic method for the results interpretation. Zebrafish embryos were induced to produce intracellular aggregates of proteins by simple microinjections of known quantities of an aggregation prone protein previously labeled. The toxicity was evaluated by the survival of the embryos, while the formation of aggregates was quantified by fluorescence microscopy. The size distribution of the protein aggregates was revealed by means of ultracentrifuge sedimentation analysis. For the development of the present method, the human γ-tubulin protein was used as model protein, which generated intracellular aggregates in more than 60% of the injected embryos. To evaluate the method, a mutation was performed that altered the state of intracellular aggregation of γ-tubulin, obtaining a significant decrease in the amount and size of the intracellular aggregates. The present method can be used for any suitable intracellular aggregation protein model. The current method present important advantages such as: Easy induction of intracellular aggregates. Simple detection of intracellular protein aggregates through fluorescence microscopy and subcellular fractionation. Overall view of the effect of drugs or mutations by combining the toxicity, the development behavior and the size distribution of intracellular protein aggregates.

Evaluación de los cambios en algunas propiedades físicas y químicas de un ultisolpor efecto del bacillus subtilis / Evaluation of the changes in the some physical and chemical properties of an ultisol for effect of the bacillus subtilis

El interés en estudios de biorremediación de suelos deteriorados por sobreexplotación y uso indiscriminado de agroquímicos se debe a que alteran la microflora, el sistema de autorregulación y la sustentabilidad en el largo plazo. Un Ultisol, suelo de baja fertilidad química y sometido a reducción de tamaño de agregados (<2,0 mm), solarizado para reducir la población microbiológica, fue inoculado con la bacteria Basillus subtilis en concentraciones de 106, 107, 108, 109 unidades formadoras de colonias (ufc). En 120 días se observó un incremento importante en magnitud de: estabilidad estructural, tamaño promedio de agregados, pH, fósforo disponible y una disminución del aluminio intercambiable. Estas variaciones en la respuesta estuvieron relacionadas con la actividad de los microorganismos en el suelo, y responden a la capacidad de solubilización de minerales por la bacteria, de producción de condiciones alcalinas y de biofilms, que unidos al aumento de biomasa de raíces de la planta, mucílagos y carbohidratos, coadyuvan en la formación de agregados estables y de mayor tamaño. Las propiedades físicas y químicas al final del experimento se estabilizaron en valores mayores a los encontrados en el suelo inicial, produciendo un efecto positivo general sobre el mismo, desde el punto de vista de la fertilidad global, al aumentar el fósforo disponible, disminuir la acidez intercambiable e incrementar la estabilidad y el tamaño promedio de agregados del suelo a corto plazo.

The interest about the studies of bioremediation in deteriorated soils under and over exploitation, indiscriminate use of agrochemicals that alter the microflora, the self regulation system and the sustainability in the long term. An Ultisol, with poor chemical properties and low fertility, because the reduction of aggregates size (< 2.0 mm). Solarize to reduce the microbiological population, it was inoculated with the bacteria Basillus subtilis in concentrations of 106, 107, 108, 109 colony forming units (cfu). In 120 days important increment in magnitude of: structural stability, size average of aggregates, pH, available phosphorus. Also diminish the interchangeable aluminum. These variations in the answer were related with the activity of the microorganisms in the soil, and it responds so that solubilisation capacity of minerals because the bacteria activity, production of alkaline conditions and biofilms too. Furthermore the increase of plant roots biomass, mucilages and carbohydrates cooperate in the formation of stable aggregates and bigger size of them. The physical and chemical properties at the end of the experiment were stabilized in bigger values than found in the initial soil. Confirming a positive general effect overall the soil, since the point of view of the global fertility, when increasing the available phosphorus, reduce the interchangeable acidity and increase the soil stability and average size aggregates in the short term.