Outside the Cell Surface: Encoding the Role of Exopolysaccharide Producing Rhizobacteria to Boost the Drought Tolerance in Plants

Mandal, Mamun; Chatterjee, Soumya; Majumdar, Sukanta

doi:10.1007/978-3-030-95365-2_18

Cited by 5 publications

(2 citation statements)

References 89 publications

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“…Production of compounds showing importance in killing pathogens such antibiotics, secretion of enzymes (chitinase, protease/elastase, cellulase, catalase, and β-(1,3)-glucanas; Duhan et al, 2022), volatile compounds (HCN; Vaghela and Gohel, 2022), and also induce systematic resistant in plants against pathogen is the important contribution of plant probiotics (Yin et al, 2022;Chaudhary et al, 2022a). In addition, the ability of plant probiotics to produce exopolysaccharides and biofilms has multiple benefits, including protection from abiotic stress (Banerjee et al, 2019) and desiccation (Mandal et al, 2022), effective root colonization (Naseem et al, 2018), and improved soil aggregation and stabilization (Jhuma et al, 2021). Numerous microbial strains have been identified to possess plant probiotic properties that stimulate plants' growth and improve crop yield (Das et al, 2022;Pantigoso et al, 2022;Khan et al, 2023).…”

Section: Plant Probiotics: Unraveling a Long Story In A Nutshellmentioning

confidence: 99%

Synergistic impact of nanomaterials and plant probiotics in agriculture: A tale of two-way strategy for long-term sustainability

et al. 2023

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Modern agriculture is primarily focused on the massive production of cereals and other food-based crops in a sustainable manner in order to fulfill the food demands of an ever-increasing global population. However, intensive agricultural practices, rampant use of agrochemicals, and other environmental factors result in soil fertility degradation, environmental pollution, disruption of soil biodiversity, pest resistance, and a decline in crop yields. Thus, experts are shifting their focus to other eco-friendly and safer methods of fertilization in order to ensure agricultural sustainability. Indeed, the importance of plant growth-promoting microorganisms, also determined as “plant probiotics (PPs),” has gained widespread recognition, and their usage as biofertilizers is being actively promoted as a means of mitigating the harmful effects of agrochemicals. As bio-elicitors, PPs promote plant growth and colonize soil or plant tissues when administered in soil, seeds, or plant surface and are used as an alternative means to avoid heavy use of agrochemicals. In the past few years, the use of nanotechnology has also brought a revolution in agriculture due to the application of various nanomaterials (NMs) or nano-based fertilizers to increase crop productivity. Given the beneficial properties of PPs and NMs, these two can be used in tandem to maximize benefits. However, the use of combinations of NMs and PPs, or their synergistic use, is in its infancy but has exhibited better crop-modulating effects in terms of improvement in crop productivity, mitigation of environmental stress (drought, salinity, etc.), restoration of soil fertility, and strengthening of the bioeconomy. In addition, a proper assessment of nanomaterials is necessary before their application, and a safer dose of NMs should be applicable without showing any toxic impact on the environment and soil microbial communities. The combo of NMs and PPs can also be encapsulated within a suitable carrier, and this method aids in the controlled and targeted delivery of entrapped components and also increases the shelf life of PPs. However, this review highlights the functional annotation of the combined impact of NMs and PPs on sustainable agricultural production in an eco-friendly manner.

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Section: Plant Probiotics: Unraveling a Long Story In A Nutshellmentioning

confidence: 99%

Synergistic impact of nanomaterials and plant probiotics in agriculture: A tale of two-way strategy for long-term sustainability

et al. 2023

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“…Przybysz et al [ 141 ] recently reported perennial meadows plants ( Centaurea scabiosa L., Echium vulgare L., and Convolvulus arvensis L.) species accumulate more PM and are better adapted than annual meadows plants species (such as Chenopodium album L., Achillea millefolium L., and Echium vulgare L.). The ability of the plants to withstand urban-specific growth circumstances, such as poor soil quality, heat, drought, salt stress, and air pollution, should be considered when choosing plants for the urban meadows and targeted for PM accumulation [ 158 , 159 , 160 , 161 ]. Therefore, urban meadows can be a crucial strategy to purify the air in polluted and populated cities.…”

Section: Green Urban Architecture and Their Impactmentioning

confidence: 99%

Breathing Fresh Air in the City: Implementing Avenue Trees as a Sustainable Solution to Reduce Particulate Pollution in Urban Agglomerations

Mandal

Popek

Przybysz

et al. 2023

Plants

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The issue of air pollution from particulate matter (PM) is getting worse as more and more people move into urban areas around the globe. Due to the complexity and diversity of pollution sources, it has long been hard to rely on source control techniques to manage this issue. Due to the fact that urban trees may provide a variety of ecosystem services, there is an urgent need to investigate alternative strategies for dramatically improving air quality. PM has always been a significant concern due to its adverse effects on humans and the entire ecosystem. The severity of this issue has risen in the current global environmental context. Numerous studies on respiratory and other human disorders have revealed a statistical relationship between human exposure to outdoor levels of particles or dust and harmful health effects. These risks are undeniably close to industrial areas where these airborne, inhalable particles are produced. The combined and individual effects of the particle and gaseous contaminants on plants’ general physiology can be detrimental. According to research, plant leaves, the primary receptors of PM pollution, can function as biological filters to remove significant amounts of particles from the atmosphere of urban areas. This study showed that vegetation could provide a promising green infrastructure (GI) for better air quality through the canopy and leaf-level processes, going beyond its traditional role as a passive target and sink for air pollutants. Opportunities exist for urban GI as a natural remedy for urban pollution caused by PMs.

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Importance of Ionic Liquids in Plant Defense: A Novel Approach

Mandal,

Sarkar

2023

Handbook of Ionic Liquids

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Outside the Cell Surface: Encoding the Role of Exopolysaccharide Producing Rhizobacteria to Boost the Drought Tolerance in Plants

Cited by 5 publications

References 89 publications

Synergistic impact of nanomaterials and plant probiotics in agriculture: A tale of two-way strategy for long-term sustainability

Synergistic impact of nanomaterials and plant probiotics in agriculture: A tale of two-way strategy for long-term sustainability

Breathing Fresh Air in the City: Implementing Avenue Trees as a Sustainable Solution to Reduce Particulate Pollution in Urban Agglomerations

Importance of Ionic Liquids in Plant Defense: A Novel Approach

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