Ensifer adhaerens strain OV14 seed application enhances Triticum aestivum L. and Brassica napus L. development.

Given the challenges imposed by climate change and societal challenges, the European Union established ambitious goals as part of its Farm to Fork (F2F) strategy. Focussed on accelerating the transition to systems of sustainable food production, processing and consumption, a key element of F2F is to reduce the use of fertilisers by at least 20% and plant protection products by up to 50% by 2030. In recent years, a substantial body of research has highlighted the potential impact of microbial-based applications to support crop production practices through both biotic/abiotic stresses via maintaining or even improving yields and reducing reliance on intensive chemical inputs. Here, we have characterised the ability of a new soil-borne free-living bacterium strain Ensifer adhaerens OV14 (EaOV14) to significantly enhance crop vigour index by up to 50% for monocot (wheat, Triticum aestivum L., p < 0.0001) and by up to 40% for dicot (oilseed rape, Brassica napus L., p < 0.0001) species under in-vitro conditions (n = 360 seedlings/treatment). The beneficial effect was further studied under controlled glasshouse growing conditions (n = 60 plants/treatment) where EaOV14 induced significantly increased seed yield of spring oilseed rape compared to the controls (p < 0.0001). Moreover, using bespoke rhizoboxes, enhanced root architecture (density, roots orientation, roots thickness etc.) was observed for spring oilseed rape and winter wheat, with the median number of roots 55% and 33% higher for oilseed rape and wheat respectively, following EaOV14 seed treatment compared to the control. In addition, EaOV14 treatment increased root tip formation and root volume, suggesting the formation of a more robust root system architecture post-seed treatment. However, like other microbial formulations, the trade-offs associated with field translation, such as loss or limited functionality due to inoculum formulation or environmental distress, need further investigation. Moreover, the delivery method requires further optimisation to identify the optimal inoculum formulation that will maximise the expected beneficial impact on yield under field growing conditions.

Socio-economic and environmental vulnerability of urban slums: a case study of slums at Jammu (India).

Rapid urban population growth, the urbanization of poverty, and the proliferation of slums are being driven to a great extent by this dynamic form of globalization. Consequently, the multifaceted effects of globalization on the poor and low-income populations in the cities need to be better understood in this context, both at the individual level and within the community. Therefore, the present study was conducted to highlight the various determinants affecting the lives and enhancing the vulnerability of the dwellers of four slum settlements present in various areas of Jammu City, India. Emphasis was made to integrate biological, physical, social, and spatial facets of vulnerability to understand the complex dynamics of urban areas in developing countries. A descriptive survey design was used for questions concerning the social and environmental aspects. Social aspects including age, sex, education, religion, caste, profession, and family income that correspond to social stratification acted as baseline information, while both indoor and outdoor environments such as housing conditions, sanitation, personal habits, solid waste disposal, disaster proneness, and air and water pollution problems were taken into consideration to assess the environmental aspect. Results indicated that the slum settlement has a migratory population with permanent or temporary settlements. The status of education and skill level is poor which results in poor economic development and social well-being of the dwellers in slums. The study also identified vulnerability of the population on social and environmental front which could result into severe health issues. The study concluded and recommended policy planning specified for slums for uplifting such unprivileged populations.

Sustainable environmental practices of tea waste-a comprehensive review.

Tea, the major beverage worldwide, is one of the oldest commercial commodities traded from ancient times. Apart from many of its advantages, including health, socio-economic, climatic, and agro-ecological values, FAO has recognized that the tea value chain covering its growth in the field, processing and marketing, and finally, the hot cup at the user's hand needs to be made sustainable during all these stages. Tea generates a lot of waste in different forms in different stages of its growth and processing, and these wastes, if not managed properly, may cause environmental pollution. A planned utilization of these wastes as feedstocks for various processes can generate more income, create rural livelihood opportunities, help grow tea environmentally sustainable, avoid GHG emissions, and make a real contribution to SDGs. Thermochemical and biological conversion of tea wastes generates value-added products. This review provides an overview on the impacts of the tea wastes on the environment, tea waste valorization processes, and applications of value-added products. The application of value-added products for energy generation, wastewater treatment, soil conditioners, adsorbents, biofertilizers, food additives, dietary supplements, animal feed bioactive chemicals, dye, colourant, and phytochemicals has been reviewed. Further, the challenges in sustainable utilization of tea wastes and opportunities for commercial exploitation of value-added products from tea wastes have been reviewed.

The Good, the Bad, and the Useable Microbes within the Common Alder (Alnus glutinosa) Microbiome-Potential Bio-Agents to Combat Alder Dieback.

Common Alder (Alnus glutinosa (L.) Gaertn.) is a tree species native to Ireland and Europe with high economic and ecological importance. The presence of Alder has many benefits including the ability to adapt to multiple climate types, as well as aiding in ecosystem restoration due to its colonization capabilities within disturbed soils. However, Alder is susceptible to infection of the root rot pathogen Phytophthora alni, amongst other pathogens associated with this tree species. P. alni has become an issue within the forestry sector as it continues to spread across Europe, infecting Alder plantations, thus affecting their growth and survival and altering ecosystem dynamics. Beneficial microbiota and biocontrol agents play a crucial role in maintaining the health and resilience of plants. Studies have shown that beneficial microbes promote plant growth as well as aid in the protection against pathogens and abiotic stress. Understanding the interactions between A. glutinosa and its microbiota, both beneficial and pathogenic, is essential for developing integrated management strategies to mitigate the impact of P. alni and maintain the health of Alder trees. This review is focused on collating the relevant literature associated with Alder, current threats to the species, what is known about its microbial composition, and Common Alder-microbe interactions that have been observed worldwide to date. It also summarizes the beneficial fungi, bacteria, and biocontrol agents, underpinning genetic mechanisms and secondary metabolites identified within the forestry sector in relation to the Alder tree species. In addition, biocontrol mechanisms and microbiome-assisted breeding as well as gaps within research that require further attention are discussed.

Bioengineering to Accelerate Biodiesel Production for a Sustainable Biorefinery.

Biodiesel is an alternative, carbon-neutral fuel compared to fossil-based diesel, which can reduce greenhouse gas (GHGs) emissions. Biodiesel is a product of microorganisms, crop plants, and animal-based oil and has the potential to prosper as a sustainable and renewable energy source and tackle growing energy problems. Biodiesel has a similar composition and combustion properties to fossil diesel and thus can be directly used in internal combustion engines as an energy source at the commercial level. Since biodiesel produced using edible/non-edible crops raises concerns about food vs. fuel, high production cost, monocropping crisis, and unintended environmental effects, such as land utilization patterns, it is essential to explore new approaches, feedstock and technologies to advance the production of biodiesel and maintain its sustainability. Adopting bioengineering methods to produce biodiesel from various sources such as crop plants, yeast, algae, and plant-based waste is one of the recent technologies, which could act as a promising alternative for creating genuinely sustainable, technically feasible, and cost-competitive biodiesel. Advancements in genetic engineering have enhanced lipid production in cellulosic crops and it can be used for biodiesel generation. Bioengineering intervention to produce lipids/fat/oil (TGA) and further their chemical or enzymatic transesterification to accelerate biodiesel production has a great future. Additionally, the valorization of waste and adoption of the biorefinery concept for biodiesel production would make it eco-friendly, cost-effective, energy positive, sustainable and fit for commercialization. A life cycle assessment will not only provide a better understanding of the various approaches for biodiesel production and waste valorization in the biorefinery model to identify the best technique for the production of sustainable biodiesel, but also show a path to draw a new policy for the adoption and commercialization of biodiesel.

Assessment of ozone toxicity on cotton (Gossypium hirsutum L.) cultivars: Its defensive system and intraspecific sensitivity.

Anthropogenic activities help the ozone formation at the troposphere which causes toxic effects on plants and humans. Ozone is a highly reactive gas that enters in plants through stomata and initiates the overproduction of ROS which causes oxidative stress in plants that lead to the destruction of membranal lipids, proteins, impaired the production of sugars and other metabolites and ultimately damage the cell. Presented study was conducted to assess the ozone toxicity on the biomass accumulation of cotton (Gossypium hirsutum L.) cultivars and the role of antioxidative activity in intraspecific sensitivity among the tested cultivars. Results showed that the ozone exposed plants have higher accumulation of H2O2 and MDA correspond to the EDU supplementation which increase the membrane permeability and adversely influence the protein, starch, and biomass accumulation and allocation of the experimental cotton cultivars. On the basis of biomass reduction, cotton cultivar ADC1 is the most sensitive cultivar, while cultivars G. Cot.21 > GADC-2 and G. Cot.13 is moderately sensitive and cultivar V-797 is the least sensitive to ozone stress. Activated defense mechanism such as enhanced activity of antioxidative compounds and enzymes detoxify the ROS by scavenging H2O2 and protects plants against damage. However, activation of defence is variable among the cultivars and corresponded to the biomass loss. Study concluded that the ozone sensitivity among the cotton cultivars depends on the scavenging of ROS. Further, study recommended cultivar ADC-1 as an assessment tool for ozone and cultivar V-797 for cultivation at ozone prone areas to minimize the agricultural loss.

Role of textile effluent fertilization with biosurfactant to sustain soil quality and nutrient availability.

The textile industry is one of the world's most pollution generating industries, and management of its toxic effluent has become a global issue. However, the use of textile effluent as source of nutrients can be a viable option due to the presence of some essential minerals, although the presence of several toxic elements can deteriorate soil health. Therefore, experiments were conducted to identify the potential of textile effluent fertilization together with biosurfactant amendment to increase the soil health and nutrient status for agricultural sustainability. In this study, soil fertilized with different concentrations of textile effluent treatments (i.e. T1A, T2A and T3A) was treated with two different concentrations of biosurfactants to accurately appraise the suitability of a set of soil quality parameters including, physical, chemical, biochemical, and biological activities. A thorough analysis of all soil health parameters was undertaken before sowing the seeds and after cultivation of either Triticum aestivum (cv. LOK-1 and GW-496) or Capsicum annum (cv. GVC-101 and GVC-121). The results indicated that lower concentrations of textile effluent are a good source of nutrients while biosurfactants served as good solubilizers of metals and made it more available at the higher effluent concentration (T2C). Under these conditions, not only did fertilizers significantly increased, but also the microbial population as well as the enzymatic activity of soil was enhanced. Lower concentrations of micronutrients in the soil after crop cultivation is attributed to the higher level of their availability to the plants during their growth and development. This study provides new insight into the biosurfactants application to enhance soil micronutrients availability and increase crop productivity using textile effluents as a source of nutrients.

Role of transitory starch on growth, development and metal accumulation of Triticum aestivum cultivars grown under textile effluent fertilization.

Accumulation of transitory starch in leaves is an environment-dependent multifaceted process affected through stress caused by nutrient deficiency or excess of heavy metals in growing medium. On the other hand, textile effluent is one of the major pollution causing industrial waste due to the presence of heavy metal and organic contaminants. Besides the presence of higher pollution load, this effluent also contains some minerals essential for plant growth and metabolism and can serve as source of nutrients to plants. In presented experiment, a mesocosm study was conducted to evaluate the phenotypic, biochemical performance and trace element status of Triticum aestivum (cv. LOK-101 and GW-496) cultivars in response to transitory starch activity grown under textile effluent fertilization. Improved activity of transitory starch under textile effluent fertilization deals with plant growth by providing carbon in the form of soluble sugar. Study also finds a strong correlation of photosynthetic pigments, carbohydrates and plant biomass to transitory starch. As expected, the elemental concentration (Zn, Cu, Mn, Fe, Co, Pb, Cd, and As) in plants increased with increasing dose of textile effluent. The study concluded that the transitory starch is one of the key components in plant leaves that regulate plant growth under stress condition. Furthermore, the study also concluded that the lower dose of textile effluent significantly favours growth and nutrient status of plants without any negative impact. Therefore, the application of lower concentration of textile effluent as basal dose in agriculture may serve as source of nutrient/micronutrient to plants and also can be a sustainable way for effluent management.

Sustainable utilization of crop residues for energy generation: A life cycle assessment (LCA) perspective.

Modernization in the crop cultivation and development of high yielding varieties resulted in increased crop residues. A large portion of crop residues is not handled appropriately, which leads to environmental burden on society. The crop residues are rich in organic substances, which can be better utilized for various purposes, including energy generation. The utilization of crop residues for energy generation has partially contributed to resolve the inappropriate handling practices, thus reducing their environmental impacts. Life cycle assessment (LCA) is used as a tool to investigate environmental sustainability and can be explored to integrate with social and economic effects to quantify environmental impacts for energy generation from crop residues. This review will provide a comprehensive understanding on LCA inference for decision support to policy-makers and different relevant choices to various applications for sustainable energy generation from crop residues.

Impact assessment of azulene and chromium on growth and metabolites of wheat and chilli cultivars under biosurfactant augmentation.

Dye azulene and heavy metal chromium are two different types of persistent toxic compounds present in textile effluent. These compounds contaminate the soil and harm plant productivity during unchecked disposal of textile effluent to the farm soil. Environmental and safety concerns associated with crops, soil, and human health encourage the exploration of biological tools to control the issue. We hereby propose the application of biosurfactant (lipopeptide) to reduce the toxic effects of azulene and chromium in plants. Results of the study indicated that the augmentation of biosurfactant with azulene and chromium promoted seed germination, plant biomass, specific leaf weight (SLW), chlorophyll content, protein content, soluble sugar and ascorbic acid concentration in cultivars of wheat and chilli. Decreasing the level of proline under biosurfactant augmentation further confirms the reduction of oxidative stress caused by azulene and chromium amendment. The results indicated that lipopeptide biosurfactant could be an effective biological tool to reduce the toxic effect of persistent substances in soil, thus maintaining soil health and sustainable agriculture.

Ozone risk assessment of castor (Ricinus communis L.) cultivars using open top chamber and ethylenediurea (EDU).

Castor bean (Ricinus communis L.) an important non-edible oilseed crop, is a prominent feed stock towards the generation of renewable materials for industrial production which has multiple applications ranging from cosmetics to biofuels industry. India accounts for 76% of the total world production of castor oil seed. However, major concern for developing countries like India where expanding economy led to rapid increases in gases like NOx, CO and VOCs photochemically form ozone. Ozone is strong oxidant that damages agriculture, ecosystems, and materials with considerable reduction in crop yields and crop quality. One way to reduce ozone induced loss is to focus on the adapting crops to ozone exposure by selecting cultivars with demonstrated ozone resistance. An experiment was conducted for ozone risk assessment of castor cultivars to select cultivar with demonstrated resistance against ozone pollution. This study comprise an open top chamber experiment with three treatments viz. (i) control (ambient ozone concentration), (ii) enhanced ozone (average 75 ppb for 4 h daily throughout the growing season), and (iii) EDU application. Results suggested that the ozone pollution substantially affected growth and physiology of castor cultivars. Crop biomass and yield was also negatively influenced by ozone pollution. Developed defence provided strength to withstand against ozone pollution to the experimental crop cultivars. However, developed defence is cultivar specific and positively correlated with the resistance against ozone pollution. Study concluded that the damage to ozone is directly dependent on the antioxidative potential of plant species. However, ozone adaptability is based on the genetic makeup of the cultivar and yield related loss to ozone can be minimizing by selecting ozone tolerant variety as seen in cultivar Nidhi-999.

Ensifer-Mediated Transformation (EMT) of Rice (Monocot) and Oilseed Rape (Dicot).

Ensifer adhaerens OV14 underpins the successful crop transformation protocol, termed Ensifer-mediated transformation (EMT). The adaptability and efficiency of EMT technology to successfully transform both monocot and dicots have been previously reported. To facilitate community users' transition to EMT, the modified rice and oilseed rape plants generated in this work were developed using EMT protocols that were grounded in standard Agrobacterium-mediated transformation (AMT) processes. Therefore, this chapter describes simple yet crucial steps involved in transferring the use of EMT of rice and oilseed rape for generation of fertile and independent transgenic lines.

Oxidative stress defence responses of wheat (Triticum aestivum L.) and chilli (Capsicum annum L.) cultivars grown under textile effluent fertilization.

Oxidative stress is complex physiological phenomenon that accompanies virtually in all stresses including either the deficiency or the surplus of micronutrients in the soil. In response to reactive oxygen species (ROS) generation, plants use a range of mechanisms to minimize the toxicity and protect cell membranes from damage. There are known reports indicating that effluents from the textile industry can serve as a micronutrient supplier under otherwise limited conditions. However, the addition of these effluents may cause toxicity to plants due to the presence of some non-essential heavy metals and persistent compounds if supplied in excess. A mesocosm study was conducted with wheat (Triticum aestivum L) and chilli (Capsicum annum L) cultivars grown under textile effluent fertilization to evaluate the accumulation of malondialdehyde (MDA) and H2O2, and the enzymatic and non-enzymatic antioxidative defences developed against this stress. Our findings indicated that the accumulation of MDA and H2O2 were mainly stimulated in control plants (0% textile effluent) followed by 60% concentration of textile effluent fertilization. Plants counteract oxidative stress by increasing both enzymatic (Superoxide dismutase, SOD; catalase, CAT; peroxidase, POX; ascorbate peroxidase, APX; glutathione reductase, GR) and non-enzymatic (phenolic compounds, flavonoids and ascorbic acid) antioxidants significantly. The activities of major antioxidants were promoted by higher concentrations of textile effluents. In addition, low antioxidative defences against damage caused by oxidative stress to the controls were evident by yield loss and deteriorated product quality. Compared to the chilli cultivars, MDA and H2O2 were higher in wheat cultivars; at the same time activities of antioxidants were also higher in wheat cultivars. The results of this study showed that the application of textile effluents supplied plant nutrients which improved antioxidative defences by regulating the enzymatic and non-enzymatic antioxidative mechanisms while the nutrient deprived condition prevailed.

Ensifer-mediated Arabidopsis thaliana Root Transformation (E-ART): A Protocol to Analyse the Factors that Support Ensifer-mediated Transformation (EMT) of Plant Cells.

Ensifer adhaerens OV14, a soil borne alpha-proteobacteria of the Rhizobiaceae family, fortifies the novel plant transformation technology platform termed 'Ensifer-mediated transformation' (EMT). EMT can stably transform both monocot and dicot species, and the host range of EMT is continuously expanding across a diverse range of crop species. In this protocol, we adapted a previously published account that describes the use of Arabidopsis thaliana roots to investigate the interaction of A. thaliana and Agrobacterium tumefaciens. In our laboratory, we routinely use A. thaliana root explants to examine the factors that enhance the utility of EMT. In addition, the E-ART protocol can be used to study the transcriptional response of E. adhaerens and host plant following exposure to explant tissue, the transformability of different Ensifer adhaerens strains/mutants as well as testing the susceptibility of A. thaliana mutant lines as a means to decipher the mechanisms underpinning EMT.

Profiling antibiotic resistance and electrotransformation potential of Ensifer adhaerens OV14; a non-Agrobacterium species capable of efficient rates of plant transformation.

Ensifer adhaerens OV14 underpins the successful crop transformation protocol termed Ensifer-mediated transformation but issues exist in regard to addressing the pleomorphic tendency of the bacterium in suboptimal conditions, identifying the optimal parameters for electrotransformation and defining the strain's antibiotic profile. Here, modifications made to growth medium composition addressed the pleomorphic trait of E. adhaerens OV14, delivering uniform E. adhaerens OV14 growth to ensure efficient rates of electroporation with plasmids up to 42.2 kb in size. Separately, 63 putative antibiotic resistance coding sequences were identified across the E. adhaerens OV14 genome, with testing confirming the strain's susceptibility to gentamicin (≥10 mg L(-1)), tetracycline (≥10 mg L(-1)), chloramphenicol (≥100 mg L(-1)) and cefotaxime (≥500 mg L(-1)) and resistance to ampicillin, paramomycin, streptomycin, spectinomycin, ticarcillin-clavulanate and kanamycin. Partial resistance against carbenicillin, rifampicin, hygromycin-B and neomycin was also recorded. Resistance to kanamycin was supported by seven independent nptII-like homologs located within the E. adhaerens OV14 genome. Transcriptional analysis of these targets highlighted two homologs (AHK42288 and AHK42618) whose transcription was significantly elevated within 2 h exposure to kanamycin and which in the case of AHK42288 was maintained out to 6 h post-exposure. In conclusion, our results have identified optimal conditions for the handling of E. adhaerens and have identified a future genome editing target (AHK42288) to negate the kanamycin-resistant phenotype of E. adhaerens.

Interactive effect of ultraviolet-B and mineral nutrients on accumulation and translocation of trace elements in wheat crop.

Field study was conducted in two wheat cultivars (Triticum aestivum L. cv. HD 2329 and HUW 234) by supplimenting UV-B irradiation with different levels of mineral nutrients in order to evaluate the accumulation and translocation of trace elements. sUV-B significantly affected accumulation and translocation of most of the metals studied. Application of nutrients at higher doses enhanced the accumulation of trace elements in plants and grains of both cultivars. A higher dose of nutrient along with sUV-B resulted in increased accumulation of lead both in plants and grains, cadmium and chromium in grains, and copper in plants and decreased accumulation of cadmium in plants, copper in grains, chromium in plants and iron in plants and grains of both the tested cultivars. Nickel concentration increased in plants of HUW 234 due to simultaneous stress. Trace element concentration did not differ noticeably in the tested cultivars but the stress response differed perceptibly. Cultivar HD 2329 showed more significant interaction than HUW 234.

Combined effects of enhanced ultraviolet-B radiation and mineral nutrients on growth, biomass accumulation and yield characteristics of two cultivars of Vigna radiata L.

In a field experiment, the effect of enhanced UV-B radiation (simulating 20% ozone depletion at Allahabad, 20 degrees 47' N latitude) was studied on two cultivars of Vigna radiata L. with various levels of mineral nutrients (N and P). Study showed decrease in total biomass accumulation, harvest index, RSR and yield after exposure with enhanced level of UV-B. RGR and CGR also showed decline after exposure with UV-B. Application of recommended dose of mineral nutrients alleviated the deleterious effect of UV-B and increased plant dry matter vis a vis yield. Both cultivars showed sensitivity to UV-B but cultivar Malviya Janpriya was more responsive to UV-B than Malviya Jyoti.

Role of ethylene diurea (EDU) in assessing impact of ozone on Vigna radiata L. plants in a suburban area of Allahabad (India).

A field study was conducted to evaluate the suitability of ethylene diurea (N-[2-(2-oxo-1-imidazolidinyl)ethyl]-N'-phenylurea; EDU) in assessing the impact of O3 on mung bean plants (Vigna radiata L. var. Malviya Jyoti) grown in suburban area of Allahabad city situated in a dry tropical region of India. EDU is a synthetic chemical having anti-ozonant property. Mean monthly O3 concentration varied between 64 and 69 microg m(-3) during the experimental period. In comparison to EDU-treated plants, non-EDU-treated plants showed significant reductions in plant growth and yield under ambient conditions. Significant favourable effects of EDU-application were observed with respect to photosynthetic pigments, soluble protein, ascorbic acid and phenol contents. EDU-treated plants maintained higher levels of pigments, protein and ascorbic acid in foliage as compared to non-EDU-treated ones. The study clearly demonstrated that EDU alleviates the unfavourable effects of O3 on mung bean plants, and therefore can be used as a tool to assess the growth and yield losses in areas having higher O3 concentrations.

Amelioration of Indian urban air pollution phytotoxicity in Beta vulgaris L. by modifying NPK nutrients.

Air pollution levels are increasing at an alarming rate in many developing countries, including India and causing a potential threat to crop production. Field experiments were conducted to examine the impact of urban air pollutants on biomass (yield) and some physiological and biochemical parameters of palak (Beta vulgaris L. var. All Green) that grew from germination to maturity at seven periurban sites of Allahabad city having different concentrations of air pollutants under different levels of nutrients. The 6h daily mean NO2, SO2 and O3 concentrations varied from 2.5 to 42.5, 10.6 to 65 and 3.5 to 30.8 microg m(-3), respectively at different locations. Levels of air pollution showed significant negative correlations with photosynthetic pigments, protein, ascorbic acid and starch contents and catalase activity of palak leaves. A significant negative correlation was found for total biomass with SO2 (r=-0.92), NO2 (r=-0.85) and O3 (r=-0.91) concentrations. The increased fertilizer application (N, P and K) over the recommended dose resulted in a positive response by reducing losses in photosynthetic pigments and total biomass. This study proved that ambient air pollution of Allahabad city is influencing negatively to the growth and yield of palak plants.

Growth responses of wheat (Triticum aestivum L. var. HD 2329) exposed to ambient air pollution under varying fertility regimes.

The problem of urban air pollution has attracted special attention in India due to a tremendous increase in the urban population; motor vehicles vis a vis the extent of energy utilization. Field studies were conducted on wheat crops (Triticum aestivum L. var. HD 2329) by keeping the pot-grown plants in similar edaphic conditions at nine different sites in Allahabad City to quantify the effects of ambient air pollution levels on selected growth and yield parameters. Air quality monitoring was done at all the sites for gaseous pollutants viz. SO2, NO2, and O3. Various growth parameters (plant height, biomass, leaf area, NPP, etc.) showed adverse effects at sites receiving higher pollution load. Reduction in test weight and harvest index was found to be directly correlated with the levels of pollutant concentrations. The study clearly showed the negative impact of air pollution on periurban agriculture.