Search Results (3)

Plant growth-promoting endophytic bacteria (PGPEB), producing auxins, are offered for a promising eco-friendly crop production. Precise bacterial strain selection is essential to ensure consistent and effective plant growth and resilience. Creating a model for the optimal dose-dependent interactions between PGPEB and hosts is necessary for understanding the mechanisms of high-precision selection of the inoculant composition to enhance bacterial preparations’ efficacy. This study investigated the impact of pre-sowing treatment with exogenous auxin indole-3-acetic acid (IAA) at various concentrations (0, 10, 1, 0.1, 0.01, 0.001, 0.0001, 0.00001 mg L⁻¹) on the growth and antioxidant responses of three cultivars (cvs) of Phaseolus vulgaris L. (bean): Ufimskaya, Elsa, and Zolotistaya. The findings showed dose-dependent and cultivar-specific responses of 7-day-old bean seedlings to exogenous IAA. Ufimskaya cv exhibited significant increases in shoot, main root, and total root lengths at 0.001 mg L⁻¹ IAA, while higher and lower concentrations inhibited growth. The reduced catalase (CAT) activity in roots and the elevated CAT activity in shoots correlated with shoot length and total root length of Ufimskaya cv. Importantly, the growth parameters exhibited weak or no correlations with malondialdehyde (MDA) and H₂O₂ content in roots and shoots, which is a peculiarity of the Ufimskaya cv response to exogenic IAA in contrast to the shown earlier response to inoculation with endophytes. The growth of only the main root of Elsa cv peaked at 0.1 mg L⁻¹ IAA, and there were neutral or inhibitory effects with other concentrations. The positive correlation between CAT activity in shoots and the main root length and total root length as well as positive correlation between MDA content in roots and the total root length of Elsa cultivar were revealed. The shoot length and total root length of Zolotistaya cv were neutral or negatively responded to all concentration IAA, but the number of roots increased by 2–4 times. For Zolotistaya cv, positive correlations were observed between CAT activity in roots and the length of the main root and the total root length. Overall, these cultivar-specific antioxidant responses to exogenous IAA may help create models for optimal dose-dependent interactions between auxin-producing PGPEB and plants, enhancing the effectiveness of microbial preparations for consistent bean growth promotion. Full article

The application of beneficial bacteria may present an alternative approach to chemical plant protection and fertilization products as they enhance growth and resistance to biotic and abiotic stresses. Plant growth-promoting bacteria are found in the rhizosphere, epiphytically or endophytically (Plant Growth Promoting Endophytic Bacteria, PGPEB). In the present study, 36 out of 119 isolated endophytic bacterial strains from roots, leaves and flowers of the pharmaceutical plant Calendula officinalis were further identified and classified into Bacillus, Pseudomonas, Pantoea, Stenotrophomonas and Rhizobium genera. Selected endophytes were evaluated depending on positive reaction to different plant growth promoting (PGP) traits, motility, survival rate and inhibition of phytopathogenic fungi in vitro and ex vivo (tomato fruit). Bacteria were further assessed for their plant growth effect on Arabidopsis thaliana seedlings and on seed bio-primed tomato plantlets, in vitro. Our results indicated that many bacterial endophytes increased seed germination, promoted plant growth and changed root structure by increasing lateral root density and length and root hair formation. The most promising antagonistic PGPEB strains (Cal.r.29, Cal.l.30, Cal.f.4, Cal.l.11, Cal.f.2.1, Cal.r.19 and Cal.r.11) are indicated as effective biological control agents (BCA) against Botrytis cinerea on detached tomato fruits. Results underlie the utility of beneficial endophytic bacteria for sustainable and efficient crop production and disease control. Full article

Saline soils are a major challenge in agriculture, and salinization is increasing worldwide due to climate change and destructive agricultural practices. Excessive amounts of salt in soils cause imbalances in ion distribution, physiological dehydration, and oxidative stress in plants. Breeding and genetic engineering methods to improve plant salt tolerance and the better use of saline soils are being explored; however, these approaches can take decades to accomplish. A shorter-term approach to improve plant salt tolerance is to be inoculated with bacteria with high salt tolerance or adjusting the balance of bacteria in the rhizosphere, including endosymbiotic bacteria (living in roots or forming a symbiont) and exosymbiotic bacteria (living on roots). Rhizosphere bacteria promote plant growth and alleviate salt stress by providing minerals (such as nitrogen, phosphate, and potassium) and hormones (including auxin, cytokinin, and abscisic acid) or by reducing ethylene production. Plant growth-promoting rhizosphere bacteria are a promising tool to restore agricultural lands and improve plant growth in saline soils. In this review, we summarize the mechanisms of plant growth-promoting bacteria under salt stress and their applications for improving plant salt tolerance to provide a theoretical basis for further use in agricultural systems. Full article