Elaeis guineensis is one of the potential carbon sequestering perennial crop by biological means. It has helped in the mitigating global warming and climatic fluctuations. The main objective of our study is to evacuate the hidden potential treasure of oil palm in carbon sequestration and vegetable oil yield. In this study we selected Tenera hybrids oil palm plantations in Coimbatore district of Tamil Nadu with standard management practices. It had been selected in the year 2019 and assessed for carbon sequestration potential and Fresh fruit bunch yield by non-destructive carbon stock assessment methods and standard estate practices for harvest. In our study the carbon sequestration is higher in trunks found to be 15.3 t C/ha (tons carbon per hectare) in 5 years and 26.6 t C/ha in 10 years while roots sequestered carbon for about 4.0 t C/ha in 5 years and 6.93 t C/ha in 10 years plantations. The fronds sequesters about 1.39 t C/ha in 5 years and 2.1 t C/ha in 10 years oil palm plantations while the fresh fruit bunch yield in 5 years and 10 years plantations were found to be 7.60 t/ha/year (tons per hectare per year) and 12.31 t/ha/year respectively. The present study evidenced that the biomass production and fresh fruit bunch yield in oil palm proportionally increases with the age group. This study holds that the higher biomass production which increases carbon sequestration and yields in oil palm helps in altering of the microclimate and to increase the economic benefits of farming communities.
Oil palm (Elaeis guineensis), being a potential carbon sequestering perennial crop by biological means, has helped in mitigating global warming and climatic fluctuations. In our study, we selected Tenera hybrids in three oil palm plantations of major oil palm growing regions of Theni and Thanjavur districts of Tamil Nadu, India during the year 2019. Carbon sequestration potential was assessed by the standard procedures and methodology. The present study revealed that carbon sequestration was higher in trunks, which was found to be 2.57 t C/ha (tons of carbon per hectare) in 4 years, 22.33 t C/ha in 8 years and 59.79 t C/ha in 15 years with respect to the age of plantation. The roots sequestered carbon for about 0.67 t C/ha in 4 years, 5.80 t C/ha in 8 years and 15.54 t C/ha in 15 years old plantations and the fronds sequesters about 1.41 t C/ha in 4 years, 2.44 t C/ha in 8 years and 3.01 t C/ha in 15 years old oil palm plantations. The findings evidenced that the biomass production in oil palm increased proportionally with different age group of oil palm. This findings established the importance of oil palm plantation for carbon sequestration to reduce natural as well as anthropogenic sources for climatic fluctuations.
Oil palm (Elaeis guineensis) has proven to be a phytolith-occluded carbon (PhytOC)-rich species that plays a vital role in acting as a carbon sink for reducing atmospheric carbon dioxide (CO 2 ) concentration. The present research estimated the silicon, phytolith, and PhytOC contents in four (OP4), eight (OP8), and fifteen (OP15)-year-old oil palm plantations. Qualitative analysis using a scanning electron microscope (SEM) revealed the presence of abundant globular echinate phytoliths with varied diameter (8.484−10.18 μm) in fronds, empty fruit bunches, and roots. Furthermore, a wide band (400−490 cm −1 ) underlined a higher relative abundance of Si−OH groups in empty fruit bunches, fronds, and roots, which emphasized the amorphous nature of silica. Quantitative analysis revealed that the phytolith (phytolith/dry biomass), PhytOC (PhytOC/phytolith), and PhytOC (PhytOC/dry biomass) contents in all oil palms differed significantly (p < 0.05) and increased with age. The PhytOC stock showed significant variation, with the trend of OP15 > OP8 > OP4. The belowground biomass of OP4 (16.43 g kg −1 ) and OP8 (17.13 g kg −1 ) had a maximum PhytOC concentration compared to the aboveground biomass, and the belowground proportion varied from 20.62 to 20.65%. The study demonstrated a positive correlation between the phytolith and PhytOC contents of oil palm; thereby, oil palm should be cultivated for enhanced long-term sequestration as a phytolith accumulator.
Halophytic plants can tolerate a high level of salinity through several morphological and physiological adaptations along with the presence of salt tolerant rhizo-microbiome. These microbes release phytohormones which aid in alleviating salinity stress and improve nutrient availability. The isolation and identification of such halophilic PGPRs can be useful in developing bio-inoculants for improving the salt tolerance and productivity of non-halophytic plants under saline conditions. In this study, salt-tolerant bacteria with multiple plant growth promoting characteristics were isolated from the rhizosphere of a predominant halophyte, Sesuvium portulacastrum grown in the coastal and paper mill effluent irrigated soils. Among the isolates, nine halotolerant rhizobacterial strains that were able to grow profusely at a salinity level of 5% NaCl were screened. These isolates were found to have multiple plant growth promoting (PGP) traits, especially 1-aminocyclopropane-1-carboxylic acid deaminase activity (0.32–1.18 μM of α-ketobutyrate released mg−1 of protein h−1) and indole acetic acid (9.4–22.8 μg mL−1). The halotolerant PGPR inoculation had the potential to improve salt tolerance in Vigna mungo L. which was reflected in significantly (p < 0.05) higher germination percentage (89%) compared to un-inoculated seeds (65%) under 2% NaCl. Similarly, shoot length (8.9–14.6 cm) and vigor index (792–1785) were also higher in inoculated seeds. The strains compatible with each other were used for the preparation of two bioformulations and these microbial consortia were tested for their efficacy in salt stress alleviation of Vigna mungo L. under pot study. The inoculation improved the photosynthetic rate (12%), chlorophyll content (22%), shoot length (5.7%) and grain yield (33%) in Vigna mungo L. The enzymatic activity of catalase and superoxide dismutase were found to be lower (7.0 and 1.5%, respectively) in inoculated plants. These results revealed that halotolerant PGPR isolated from S. portulacastrum can be a cost-effective and ecologically sustainable method to improve crop productivity under high saline conditions.
Various approaches are used to integrate the desired genes encoding the antigen protein for a given illness into the genome of plant tissues in plant-based vaccination technology. Gene transfer by agrobacterium and transformation via a genetically engineered plant virus are two typical approaches for producing efficient vaccinations. Antibodies are an important component of vertebrates' adaptive immune systems, and they may now be made by converting plants with antibody-coding genes from animals and humans. Despite the fact that plants do not produce antibodies naturally, plant-derived antibodies (plantibodies) have been proven to behave similarly to mammalian antibodies. However, as science and technology have progressed, new approaches have been created to improve the efficiency of older technologies including biolistic, electroporation, agroinfiltration, sonication, and polyethylene glycol treatment. Despite the fact that plant-based vaccinations have numerous advantages for the vaccine industry, there are still constraints that limit the rate at which these third-generation vaccines may be successfully manufactured. Despite these limitations, continued attempts are still underway to develop effective vaccines for a variety of human and animal diseases, owing to its enormous potential.
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