Abstract
Identification of tree species that can biologically monitor air pollution and can endure air pollution is very much important for a sustainable green belt development around any polluted place. To ascertain the species, ten tree species were selected on the basis of some previous study from the campus of the University of Burdwan and were studied in the pre-monsoon and post-monsoon seasons. The study has been designed to investigate biochemical and physiological activities of selected tree species as the campus is presently exposed to primary air pollutants and their impacts on plant community were observed through the changes in several physical and biochemical constituents of plant leaves. As the plant species continuously exchange different gaseous pollutants in and out of the foliar system and are very sensitive to gaseous pollutants, they serve as bioindicators. Due to air pollution, foliar surface undergoes different structural and functional changes. In the selected plant species, it was observed that the concentration of primary air pollutants, proline content, pH, relative water holding capacity, photosynthetic rate, and respiration rate were higher in the pre-monsoon than the post-monsoon season, whereas the total chlorophyll, ascorbic acid, sugar, and conductivity were higher in the post-monsoon season. From the entire study, it was observed that the concentration of sulfur oxide (SO x ), nitrogen oxide (NO x ), and suspended particulate matter (SPM) all are reduced in the post-monsoon season than the pre-monsoon season. In the pre-monsoon season, SO x , NO x , and SPM do not have any significant correlation with biochemical as well as physiological parameters. SPM shows a negative relationship with chlorophyll ‘a’ (r = −0.288), chlorophyll ‘b’ (r = −0.267), and total chlorophyll (r = −0.238). Similarly, chlorophyll a, chlorophyll b, and the total chlorophyll show negative relations with SO x and NO x (p < 0.005) during the post-monsoon season. Proline shows a positive relationship with SO x in the pre-monsoon season whereas in the post-monsoon season proline content shows a positive relationship with both SO x and NO x . The present study facilitates to screen eight sensitive and two moderately tolerant tree species according to their air pollution tolerance index (APTI) values.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Arnon, D. I. (1949). Copper enzyme polyphenoloxides in isolated chloroplast in Beta vulgaris. Plant Physiology, 24, 1–15.
Balogun, V. S., & Orimoogunje, O. O. I. (2015). An assessment of seasonal variation of air pollution in Benin City, Southern Nigeria. Atmospheric and Climate Sciences, 5, 209–218.
Barrs, H. D., & Weatherley, P. E. (1962). A re-examination of the relative turgidity technique for estimating water deficits in leaves. Australian Journal of Biological Sciences, 15, 413–428.
Bates, L. S., Waldren, R. P., & Teare, L. D. (1973). Rapid determination of free proline for water stress studies. Plant and Soil, 39, 205–207.
Buchchi, B. G., Nazaneen Parveen, S., Naveen, K. K., & Sridhar, R. M. (2013). Evaluation of air pollution tolerance indices of plant species growing in the vicinity of cement industry and Yogi Vemana University campus. Indian Journal of Advances in Chemical Science, 2(1), 16–20.
Chattopadhyay, S., Gupta, S., & Saha, R. N. (2010). Spatial and temporal variation of urban air quality: a GIS approach. Journal of Environmental Protection, 1, 264–277.
Chauhan, A. (2015). Effect of SO2 on ascorbic acid content in crop plants-first line of defense against oxidative stress. International Journal of Innovative Research & Development, 4(11), 8–13.
Chaurasia, S., Karwariya, A., & Gupta, A. D. (2013). Effect of cement industry pollution on chlorophyll content of some crops at Kodinar, Gujarat, India. Proceedings of the International Academy of Ecology and Environmental Sciences, 3(4), 288–295.
Das, S., & Prasad, P. (2010). Seasonal variation in air pollution tolerance indices and selection of plant species for industrial areas of Rourkela. Indian Journal of Environmental Protection, 30(12), 978–988.
Das, K., Dey, U., Bhaumik, R., Datta, J. K., & Mondal, N. K. (2011). A comparative study of lichen biochemistry and air pollution status of the urban, semi-urban and industrial area of Hooghly and Burdwan district, West Bengal. Journal of Stress Physiology & Biochemistry, 7(4), 311–323.
Dutta, D., Kundu, D., & Datta, J. K. (2017). Evaluation of growth, physiology and yield of mung bean (Vigna radiata) by inoculating isolated nitrogen fixing bacteria from pharmaceutical wastewater. Journal of Environmental Science and Pollution Research, 3(1), 149–152.
Enete, I. C., Chukwudeluzu, V. U., & Okolie, A. O. (2013). Evaluation of air pollution tolerance index of plants and ornamental shrubs in Enugu City: Implications for urban heat island effect. World Environment, 3(3), 108–115.
Garg, A., Saxena, P., & Ghosh, C. (2015). Evaluation of tolerance and sensitivity of selected plant species with special reference to gasoline exhaust pollution. International Journal of Scientific & Technology Research, 4(2), 199–207.
Gheorghe, I.F., & Ion, B. (2011). The effects of air pollutants on vegetation and the role of vegetation in reducing atmospheric pollution. The impact of air pollution on health, economy, environment and agricultural sources. INTECH, http://www.intechopen.com. http://www.cpcb.nic.in/newitems/7.pdf. Accessed 25 Mar 2016.
Giri, S., Shrivastava, D., Deshmukh, K., & Dubey, P. (2013). Effect of air pollution on chlorophyll content of leaves. Current Agriculture Research Journal, 1(2), 93–98.
Jana, B. B., Kundu, D., Datta, D., Lahiri, S., Bag, S., Sarkar, D., & Bhakta, J. N. (2016). Evidences of manure driven and C:N regulated enhanced carbon status and microalgal productivity in managed aquatic system under simulated greenhouse conditions. Journal of Earth Science and Climate Change, 7(1). doi:10.4172/2157-7617.1000336.
Joshi, N., & Bora, M. (2011). Impact of air quality on physiological attributes of certain plants. Report and Opinion, 3(2), 42–47.
Joshi, P. C., & Swami, A. (2007). Physiological responses of some tree species under roadside automobile pollution stress around city of Haridwar, India. Environmentalist, 27, 365–374.
Joshi, P. C., & Swami, A. (2009). Air pollution induced changes in the photosynthetic pigments of selected plant species. Journal of Environmental Biology, 30(2), 295–298.
Joshi, O. P., Pawar, K., & Wagela, D. K. (1993). Air quality monitoring of Indore city with special reference to SO2 and tree barks pH. Journal of Environmental Biology, 14(2), 157–162.
Jyothi, J. S., & Jaya, D. S. (2010). Evaluation of air pollution tolerance index of selected plant species along roadsides in Thiruvananthapuram, Kerala. Journal of Environmental Biology, 3, 379–386.
Kanakidou, M., Mihalopoulos, N., Kindap, T., Im, U., Vrekoussis, M., Gerasopoulos, E., Dermitzaki, E., Unal, A., Koçak, M., Markakis, K., Melas, D., Kouvarakis, G., Youssef, A. F., Richter, A., Hatzianastassiou, N., Hilboll, A., Ebojie, F., Wittrock, F., von Savigny, C., Burrows, J. P., Ladstaetter-Weissenmayer, A., & Moubasher, H. (2011). Megacities as hot spots of air pollution in the East Mediterranean. Atmospheric Environment, 45, 1223–1235.
Keller, T. (1986). The electrical conductivity of Norway spruce needle diffusate as affected by air pollutants. Tree Physiology, 1, 85–94.
Kuddus, M., Kumari, R., & Ramteke, W. P. (2011). Studies on air pollution tolerance of selected plants in Allahabad city, India. Journal of Environmental Management, 2(3), 42–46.
Lohe, R. N., Tyagi, B., Singh, V., Tyagi, P. K., Khanna, D. R., & Bhutiani, R. (2015). A comparative study for air pollution tolerance index of some terrestrial plant species. Global Journal of Environmental Science and Management, 4, 315–324.
Mandloi, B. L., & Dubey, P. S. (1988). The industrial emission and plant response at Pithanpur (M.P). International Journal of Ecological and Environmental Science, 14, 75–99.
Mashitha, P. M., & Pise, V. L. (2001). Biomonitoring of air pollution by correlating the pollution tolerance index of some commonly grown trees of an urban area. Pollution Research, 20(2), 195–197.
Masuch, G., Kicinski, H., Kettrup, A., & Boss, K. S. (1988). Single and combined effects of continuous and discontinuous O3 and SO2 emission on Norway spruce needle: Histochemical and cytological changes. International Journal of Environmental Analytical Chemistry, 32, 213–241.
McCready, R. M., Guggolz, J., Silviera, V., & Ownes, H. S. (1950). Determination of starch and amylase in vegetables, application to peas. Analytical Chemistry, 22, 1156–1158.
Mina, U., Sigh, R., & Chakrabarti, B. (2013). Agricultural production and air quality: an emerging challenge. International Journal of Environmental Science: Development and Monitoring, 4(2), 80–85.
Mondal, D., Gupta, S., & Datta, J. K. (2011). Anticipated performance index of some tree species considered for green belt development in an urban area. International Research Journal of Plant Science, 2(4), 99–106.
Mukherjee, S. P., & Choudhuri, M. A. (1983). Implications of water stress-induced changes in the level of endogenous ascorbic acid and hydrogen peroxide in Vigna seedlings. Physiologia Plantarum, 58, 166–170.
Odafevejiri, A. P. (2016). Impact of air pollution on proline and soluble sugar content of selected plant species. Chemistry and Materials Research, 8(5), 72–76.
Palit, D., Kar, D., Misra, P., & Banerjee, A. (2013). Assessment of air quality using several biomonitors of selected sites of Durgapur, Burdwan district by air pollution tolerance index approach. Indian Journal of Scientific Research, 4(1), 149–152.
Pathak, R. K., Tomar, C., Neelumalviya, & Mahajan, S. (2015). Phytomonitoring of atmospheric pollution in roadside perennial trees of Indore city (M.P.) India. International Journal of Advances in Engineering & Technology, 7(6), 1727–1734.
Rai, P. K. (2013). Environmental magnetic studies of particulates with special reference to biomagnetic monitoring using roadside plant leaves. Atmospheric Environment, 72, 113–129.
Rai, P. K., & Panda, L. L. S. (2014). Leaf dust deposition and its impact on a biochemical aspect of some roadside plants of Aizawl, Mizoram, North East India. International Research Journal of Environment Sciences, 3(11), 14–19.
Rai, P. K., & Panda, L. L. S. (2015). Roadside plants as bioindicators of air pollution in an industrial region, Rourkela, India. International Journal of Advancements in Research & Technology, 4(1), 14–36.
Rao, C. S. (2006). Environmental pollution control engineering. New Delhi: New age International Publishers.
Rao, D. N., & Leblance, F. (1966). Effect of sulfur dioxide on lichen alga with special reference to the chloroplast. The Bryologist, 69, 69–72.
Reddy, G. S., & Biswajit, R. (2003). Ambient air quality status in Raniganj-Asansol area, India. Environmental Monitoring Assessment, 89(2), 153–163.
Santosh, K. P., & Tripathi, B. D. (2008). Seasonal variation of leaf dust accumulation and pigment content in plant species exposed to urban particulates pollution. Journal of Environmental Quality, 37, 865–870.
Sarkar, S., & Gupta, A. (2016). Biological monitoring of cement factory emissions in Badarpur, Assam, India, using Mangifera indica L. Indian Journal of Applied Research, 6(7), 391–393.
Sengupta, B. (2003). Guidelines for ambient air quality monitoring. National Ambient Air Quality Monitoring Series (NAAQMS)/2003–04. Central Pollution Control Board, Ministry of Environment & Forests.
Seyyednejad, S. M., & Koochak, H. (2011). A study on air pollution effects on Eucalyptus camaldulensis. In International Conference on Environmental, Biomedical, and Biotechnology (Vol. 16, pp. 98–101). Singapore: IACSIT Press.
Shannigrahi, A. S., Fukushim, T., & Sharma, R. C. (2004). Anticipated air pollution tolerance of some plant species considered for green belt development in and around an industrial/urban area in India: an overview. International Journal of Environmental Studies, 61(2), 125–137.
Singh, S.K., & Rao, D.N. (1983). Evaluation of the plants for their tolerance to air pollution Proceedings symposium on Air Pollution control held at IIT, Delhi, pp. 218–224.
Sisodia, A., & Dutta, S. (2016). Air pollution tolerance index of certain plant species: a study of National Highway no-8, India. Journal of Environmental Research and Development, 10(4), 723–728.
Subramani, S., & Devaanandan, S. (2015). Application of air pollution tolerance index in assessing the air quality. International Journal of Pharmacy and Pharmaceutical Sciences, 7(7), 216–221.
Tankha, K., & Gupta, R. K. (1992). Effect of water deficit and sulphur dioxide on total soluble proteins, nitrate reductase activity and free proline content in sunflower leaves. Biologia Plantarum, 34(3–4), 305–310.
Thakar, B. K., & Mishra, P. C. (2010). Dust collection potential and air pollution tolerance index of tree vegetation around Vedanta Aluminium Limited, Jharsuguda. The Bioscan, 3, 603–612.
Tripathi, A. K., & Gautam, M. (2007). Biochemical parameters of plants as indicators of air pollution. Journal of Environmental Biology, 28(1), 127–132.
Verma, A. (2003). Attenuation of automobile generated air pollution by higher plants. Dissertation, University of Lucknow.
Wang, F., Zeng, B., Sun, Z., & Zhu, C. (2009). Relationship between proline and Hg2+ induced oxidative stress in a tolerant rice mutant. Archives of Environmental Contamination and Toxicology, 56, 723–731.
West, P. W., & Gaeke, G. C. (1956). Fixation of sulphur dioxide as sulfitomercurate III and subsequent colorimetric determination. Analytical Chemistry, 28, 1816–1819.
Woodward, A. J., & Bennett, I. J. (2005). The effect of salt stress and abscisic acid on proline production, chlorophyll content, and growth of in vitro propagated shoots of Eucalyptus camaldulensis. Plant Cell, Tissue and Organ Culture, 82, 189–200.
Acknowledgements
The authors would like to thank the Department of Environmental Science, University of Burdwan, West Bengal, India, for providing research facilities.
Author information
Authors and Affiliations
Corresponding author
Additional information
Public interest statement
Plant physiology comprises the study of biological and chemical processes of plant cells, tissues, and organs within a plant. Different cells and tissues are physically and chemically specialized to perform different roles. Plant physiology involves the study of plant response to environmental conditions and their variation.
Rights and permissions
About this article
Cite this article
Sen, A., Khan, I., Kundu, D. et al. Ecophysiological evaluation of tree species for biomonitoring of air quality and identification of air pollution-tolerant species. Environ Monit Assess 189, 262 (2017). https://doi.org/10.1007/s10661-017-5955-x
Received:
Accepted:
Published:
DOI: https://doi.org/10.1007/s10661-017-5955-x