Inoculation with Azospirillum argentinense Az19 improves the yield of maize subjected to water déficit at key stages of plant development / La inoculación con Azospirillum argentinense Az19 mejora el rendimiento del maíz expuesto a déficit hídrico durante estadios clave del desarrollo vegetal

Resumen El déficit hídrico constituye una severa limitación a la productividad agrícola. En el marco de la producción sostenible de cultivos, la biotecnología microbiana está cobrando relevancia para aumentar la tolerancia a la sequía y mejorar el rendimiento de los cultivos en condiciones adversas. El propósito de este trabajo fue comparar la acción de la cepa de Azospirillum argentinense Az19, con tolerancia in vitro a estresores abióticos, con la cepa Az39, utilizada ampliamente para la formulación de inoculantes comerciales, al inocularlas en plantas sometidas a déficit hídrico. Se realizaron ensayos de invernadero y de campo. En invernadero, la cepa Az19 evitó el impacto adverso del déficit hídrico en el estadio V2 sobre el crecimiento del maíz. Además, el porcentaje de plantas con espigas y el peso de la espiga disminuyó significativamente con la restricción hídrica aplicada en V2 y en floración en plantas inoculadas con la cepa Az39, pero no en las inoculadas con Az19. En el primer ensayo de campo con el maíz híbrido comercial DOW DS 515 PW las plantas inoculadas con Az19 fueron las que mejor toleraron la deficiencia hídrica. En el segundo ensayo de campo se utilizaron dos genotipos de maíz con sensibilidad diferencial a la sequía. La inoculación con Az19 condujo a una mayor tolerancia al déficit hídrico, con un efecto detectable en algunos componentes del rendimiento en el genotipo sensible. Sobre la base de estos resultados, proponemos el empleo de A. argentinense Az19 para la formulación de inoculantes basados en Azospirillum especialmente indicados para áreas agroecológicas que experimenten períodos de déficit hídrico.

Inoculation with Azospirillum argentinense Az19 improves the yield of maize subjected to water deficit at key stages of plant development.

Water deficit constitutes a severe limitation to agricultural productivity. In the context of sustainable crop production, the potential of microbial biotechnology to increase plant drought tolerance and improve crop yields under adverse conditions is gaining relevance. This work aimed to compare the performance of Azospirillumargentinense strain Az19 to that of strain Az39, the most widely used for commercial inoculants, when inoculated in maize plants exposed to water deficit. For this purpose, greenhouse and field assays were conducted. In the greenhouse experiment, strain Az19 prevented the adverse effect of water deficit at V2 stage on maize growth. Moreover, the percentage of fertile plants and the ear weight decreased significantly under water deficits imposed at V2 and flowering in Az39-inoculated plants but not in Az19-inoculated plants. In the first field trial with the commercial maize hybrid DOW DS 515 PW, Az19-inoculated plants were those which better tolerated the water deficit imposed. In the second field trial, two maize genotypes with differential drought sensitivity (LP 29×LP 2542, sensitive; LP 882 (923)×LP 4703, tolerant) were tested. Higher tolerance to water deficit was detected in plants inoculated with A. argentinense Az19, with a noticeable effect on grain yield components in the sensitive genotype. Based on these results, we propose the use of A. argentinense Az19 for the formulation of more targeted Azospirillum-based inoculants, suitable for agroecological areas subjected to seasonal water deficits.

Successful production of the potato antimicrobial peptide Snakin-1 in baculovirus-infected insect cells and development of specific antibodies.

BACKGROUND: Snakin-1 (StSN1) is a broad-spectrum antimicrobial cysteine-rich peptide isolated from Solanum tuberosum. Its biotechnological potential has been already recognized since it exhibits in vivo antifungal and antibacterial activity. Most attempts to produce StSN1, or homologous peptides, in a soluble native state using bacterial, yeast or synthetic expression systems have presented production bottlenecks such as insolubility, misfolding or low yields. RESULTS: In this work, we successfully expressed a recombinant StSN1 (rSN1) in Spodoptera frugiperda (Sf9) insect cells by optimizing several of the parameters for its expression in the baculovirus expression system. The recombinant peptide lacking its putative signal peptide was soluble and was present in the nuclear fraction of infected Sf9 cells. An optimized purification procedure allowed the production of rSN1 that was used for immunization of mice, which gave rise to polyclonal antibodies that detect the native protein in tissue extracts of both agroinfiltrated plants and stable transgenic lines. Our results demonstrated that this system circumvents all the difficulties associated with recombinant antimicrobial peptides expression in other heterologous systems. CONCLUSIONS: The present study is the first report of a successful protocol to produce a soluble Snakin/GASA peptide in baculovirus-infected insect cells. Our work demonstrates that the nuclear localization of rSN1 in insect cells can be exploited for its large-scale production and subsequent generation of specific anti-rSN1 antibodies. We suggest the use of the baculovirus system for high-level expression of Snakin/GASA peptides, for biological assays, structural and functional analysis and antibody production, as an important step to both elucidate their accurate physiological role and to deepen the study of their biotechnological uses.