Role of biostimulants in mitigating the effects of climate change on crop performance

Bhupenchandra, Ingudam; Chongtham, S. K.; Devi, E. Lamalakshmi; Ramesh, R.; Choudhary, Anil K.; Salam, Menaka Devi; Sahoo, Manas Ranjan; Bhutia, Tshering Lhamu; Devi, Soibam Helena; Thounaojam, Amarjit Singh; Behera, Chandana; Harish., M. N.; Kumar, Adarsh; Dasgupta, Madhumita; Devi, Yumnam Prabhabati; Singh, Dheeraj; Bhagowati, Seema; Devi, Chingakham Premabati; Singh, Hemam Ramananda; Khaba, Chingakham Inao

doi:10.3389/fpls.2022.967665

Cited by 42 publications

(15 citation statements)

References 245 publications

(184 reference statements)

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“…Combining the CA c practice with legume-intensi cation also enhanced the SOC input owing to adequate leaf litterfall and root biomass additions from legumes with narrow C:N ratio 18,19 ; which in turn, enhanced the soil microbial diversity 17,[23][24][25] . Legume roots also release the root exudates which harbor the microbial diversity in the rhizosphere 4,20,26 , that's why the double-legumes system i.e. PCMCS had highest microbial counts of bacteria, fungi and actenomycetes in current study.…”

Section: Resultsmentioning

confidence: 68%

“…CA management also promotes the soil organic carbon (SOC) storage, aggregate stability, and soil biological activity over intensive tillage 1,[15][16][17] . In addition, improved soil physico-chemical and biological properties and microclimate modulation under CA-management 9,10,18,19 , may also prove helpful in inducing the moisturestress tolerance ability in rainfed crops 20 . Hence, it is obligatory to generate robust scienti c evidences for CA based agronomic interventions for the water-scarce semi-arid regions that too under triple-zero tilled cropping systems, as most of the research till date is largely con ned to irrigation-based rice-wheat cropping system (RWCS) in south-Asia 21 .…”

Section: Introductionmentioning

confidence: 99%

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Triple-Zero Tillage and System Intensification lead to enhanced Productivity, Micronutrient Biofortification and Moisture-Stress Tolerance Ability in Chickpea in a Pearlmillet–Chickpea Cropping System of Semi-arid Climate

Bana

Faiz

Sangwan

et al. 2023

Preprint

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Pearlmillet–chickpea cropping system (PCCS) is emerging as an important sequence in semi-arid regions of south-Asia owing to less water-requirement. However, chickpea (dry-season crop) faces comparatively acute soil moisture-deficit over pearlmillet (wet-season crop), limiting overall sustainability of PCCS. Hence, moisture-management (specifically in chickpea) and system intensification is highly essential for sustaining the PCCS in holistic manner. Since, conservation agriculture (CA) has emerged is an important climate-smart strategy to combat moisture-stress alongwith other production-vulnerabilities. Hence, current study comprised of three tillage systems in main-plots viz., Complete-CA with residue retention (CAc), Partial-CA without residue-retention (CAp), and Conventional-tillage (ConvTill) under three cropping systems in sub-plots viz., conventionally grown pearlmillet–chickpea cropping system (PCCS) alongwith two intensified systems i.e. pearlmillet-chickpea-fodder pearlmillet cropping system (PCFCS) and pearlmillet-chickpea-mungbean cropping system (PCMCS) in split-plot design. The investigation outcomes mainly focused on chickpea (dry-season crop) revealed that, on an average, there was a significant increase in chickpea grain yield under CAc to the tune of 27, 23.5 and 28.5% under PCCS, PCFCS and PCMCS, respectively over ConvTill. NPK uptake and micronutrient (Fe & Zn) biofortification in chickpea grains were again significantly higher under triple zero-tilled CAc plots with residue-retention; which was followed by triple zero-tilled CAp plots without residue-retention and the ConvTill plots. Likewise, CAc under PCMCS led to an increase in relative leaf water (RLW) content in chickpea by ~ 20.8% over ConvTill under PCCS, hence, ameliorating the moisture-stress effects. Interestingly, CA-management and system-intensification significantly enhanced the plant biochemical properties in chickpea viz., super-oxide dismuatage, ascorbate proxidase, catalase and glutathione reductase; thus, indicating their prime role in inducing moisture-stress tolerance ability in moisture-starved chickpea. Triple zero-tilled CAc plots also reduced the N2O fluxes in chickpea but with slightly higher CO2 emissions, however, curtailed the net GHG-emissions. Triple zero-tilled cropping systems (PCFCS & PCMCS) both under CAc and Cap led to a significant improvement in soil microbial population and soil enzymes activities (alkaline phosphatase, fluorescein diacetate, dehydrogenase). Overall, the PCCS system-intensification with mungbean (PCMCS) alongwith triple zero-tillage with residue-retention (CAc) may amply enhance the productivity, micronutrient biofortification and moisture-stress tolerance ability in chickpea besides propelling the ecological benefits under semi-arid agro-ecologies. However, the farmers should preserve a balance while adopting CAc or CAp where livestock equally competes for quality fodder.

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Section: Resultsmentioning

confidence: 68%

Section: Introductionmentioning

confidence: 99%

Triple-Zero Tillage and System Intensification lead to enhanced Productivity, Micronutrient Biofortification and Moisture-Stress Tolerance Ability in Chickpea in a Pearlmillet–Chickpea Cropping System of Semi-arid Climate

Bana

Faiz

Sangwan

et al. 2023

Preprint

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“…For these reasons, the analysis of botanical extracts as potential agents to help achieve the objective of sustainable agriculture is an increasingly active area of research. In addition, biostimulants have been proposed as a solution for mitigating the effects of climate change on crop performance and a powerful tool against the effects of abiotic stress [ 13 , 14 ].…”

Section: Introductionmentioning

confidence: 99%

Use of Yucca (Yucca schidigera) Extracts as Biostimulants to Promote Germination and Early Vigor and as Natural Fungicides

Benito

Ligorio

Bellón³

et al. 2023

Plants

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Climate change is increasing drought and salinity in many cultivated areas, therefore threatening food production. There is a great demand for novel agricultural inputs able to maintain yield under the conditions imposed by the anthropogenic global warming. Biostimulants have been proposed as a useful tool to achieve this objective. We have investigated the biostimulant effect of different yucca (Yucca schidigera) extracts on plant growth at different stages of development under different abiotic stress conditions. The extracts were tested in the model plant Arabidopsis thaliana, and in three different crops; tomato (Solanum lycopersicum var microtom), broccoli (Brassica oleracea var. italica) and lettuce (Lactuca sativa var romana). We have found that the investigated extracts are able to promote germination and early vigor under drought/osmotic and salt stress induced either by sodium chloride or lithium chloride. This effect is particularly strong in Arabidopsis thaliana and in the Brassicaceae broccoli. We have also determined using antibiograms against the model yeast Saccharomyces cerevisiae that the evaluated extracts may be used also as a natural fungicide. The results in this report show that yucca extracts may be used to enhance early vigor in some crops and as a natural fungicide, providing a new and useful tool for farmers.

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“…The requisite for more research on the effect of biological products on grasses has been highlighted [ 4 , 13 ]. Aside from the European legislation objective in reducing the use of pesticides and fertilizers by 2030, as well as the promotion of new technologies [ 4 ], an additional driving force behind the increasing interest in biostimulants for all plants is that of climate change [ 21 ]. The use of biostimulants in mitigating the adverse impacts of harsh environmental conditions on plants are currently being reported [ 21 ].…”

Section: Introductionmentioning

confidence: 99%

“…Aside from the European legislation objective in reducing the use of pesticides and fertilizers by 2030, as well as the promotion of new technologies [ 4 ], an additional driving force behind the increasing interest in biostimulants for all plants is that of climate change [ 21 ]. The use of biostimulants in mitigating the adverse impacts of harsh environmental conditions on plants are currently being reported [ 21 ]. As such, the use of biostimulants is projected to increase on a global level by 10.4% annually until 2030 [ 22 ].…”

Section: Introductionmentioning

confidence: 99%

Biostimulants for Sustainable Management of Sport Turfgrass

Bosi

Negri

Accorsi³

et al. 2023

Plants

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Research on the efficacy of innovative, ecofriendly biostimulants in sport turf management is scarce, with less information available from open-field experiments, and even less pertaining to thatch control-related problems. The objective was to investigate the open-field effectiveness of a commercial product, EM-1, and two newly developed products, ExpA and ExpB, in improving both rhizosphere and turfgrass, Agrostis stoloniferous L., characteristics on a golf green. ExpA and ExpB, identical in microbial composition, were equally effective in significantly increasing chlorophyll synthesis and visual turf quality, as well as in resistance to tearing out, compared to the untreated control 56 days after treatment (DAT). EM-1 showed intermediate trends between the control and novel biostimulants. The inclusion of humic acids and mycorrhizal fungi to the microbial composition in ExpB significantly improved some rhizosphere properties 56 DAT relative to the control. Results on ExpB evidenced a significant decrease in the thatch layer thickness and fresh leaf weight, associated with a significant increase in the humus thickness, organic matter decomposition and evapotranspiration efficiency. An increased dry leaf biomass was also shown. ExpA and EM-1 showed either marginal or intermediate improvements relative to the control. ExpB represents a promising alternative to alleviate negative environmental impacts associated with turf maintenance-related activities.

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Role of biostimulants in mitigating the effects of climate change on crop performance

Cited by 42 publications

References 245 publications

Triple-Zero Tillage and System Intensification lead to enhanced Productivity, Micronutrient Biofortification and Moisture-Stress Tolerance Ability in Chickpea in a Pearlmillet–Chickpea Cropping System of Semi-arid Climate

Triple-Zero Tillage and System Intensification lead to enhanced Productivity, Micronutrient Biofortification and Moisture-Stress Tolerance Ability in Chickpea in a Pearlmillet–Chickpea Cropping System of Semi-arid Climate

Use of Yucca (Yucca schidigera) Extracts as Biostimulants to Promote Germination and Early Vigor and as Natural Fungicides

Biostimulants for Sustainable Management of Sport Turfgrass

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