Abstract
Air pollutant concentration of Trivandrum, the capital of Kerala, exceeded the limits of National Ambient Air Quality (NAAQ) standards, according to a study conducted in 2015 by NATPAC. These polluted corridors harbour vegetation on roadsides and traffic islands, planted solely for aesthetic appeal. Analysis of air pollution tolerance levels of existing plants can act as a scientific basis for efficient planning of the urban landscape. Sixty-seven species, including flowering, fruit-bearing, ornamental, shade-providing and timber-yielding species, were screened for their relative resistance to air pollution. Based on leaf pH, relative water content, chlorophyll and ascorbic acid levels, the Air Pollution Tolerance Indices (APTI) of each species were formulated and they were grouped into the following: tolerant, moderately tolerant, intermediate and sensitive groups. Agave americana (18.40), Cassia roxburghii (17.63), Anacardium occidentale (11.97), Cassia fistula (11.60), Mangifera indica (11.59) and Saraca asoca (10.88) may be considered for planting near green spaces like roundabouts and near pollution prone industrial areas, as they belong to tolerant category. Comparison of APTI during summer and monsoon also revealed the stability of Agave americana, Saraca asoca, Ficus benghalensis, Peltophorum pterocarpum, Ficus elastica, Ixora finlaysoniana, Mangifera indica, Canna indica and Delonix regia in maintaining pollution tolerance even during water disparity. Agave americana, Anacardium occidentale, Ficus elastica, Mangifera indica, Syzygium cumini, Ficus benghalensis, Nerium oleander and Ficus benjamina were found to be suited for mass planting, as was evident from their Anticipated Performance Indices (API).
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Introduction
India accommodates 15 cities belonging to the top 20 most polluted cities across the globe (Koshy 2019). The techniques to counter such a huge wave of air pollutants are limited due to economic and spatial limitations in our country. An in-depth study in Trivandrum Corporation by the National Transportation, Planning and Research Centre (NATPAC) in 2015–2016 elucidated the surge in air pollutants like carbon dioxide, carbon monoxide and particulate matter above the permissible National Ambient Air Quality (NAAQ) limits. The study was focused on road corridors with high traffic density. These corridors are endowed with small patches of vegetation at traffic islands, dividers and roundabouts. Every year on the 5th of June, numerous seedlings which are either flowering, fruit bearing, shade giving or timber yielding are distributed by the Kerala Forest Department since 2006 in schools and other institutions to hike up the forest cover in the state. Schemes like ‘Vazhiyora Thanal Padhathi’ (Shade on roadsides) and ‘Haritha Keralam’ (Greening Kerala) supplement the ecological health of heavy traffic areas. However, the species selection for such afforestation programmes is currently done only for maintaining the aesthesis of the city. The utilization of existing green space with plants capable of tolerating and thriving well under pollutant stress would add a practical value to the services of such green zones by buffering the concentration of pollutants in air. This process of phylloremediation makes use of leaves as the machinery for detoxifying air. Leaves fix CO2 and replenish the pool of breathable air taken up by the fauna as plants are capable of converting many toxic substances into harmless metabolites by processes inherent in them (Hill 1971, Lin 1976). Trees are proven to remove air pollutants by intercepting airborne particles (Nowak et al. 2006). Since every plant may not necessarily be an air pollution attenuator due to their disparity in stress-response (Gupta 2008), planting species which are resistant aids in saving the time, money and labour put forward in urban landscaping and their overall efficacy. The equable climate of Trivandrum throughout the year may be attributed to its location towards the equator (Balasubramanian 2017). The only significant climatic variable here is rainfall, which is due to its geographical positioning between the Arabian Sea and the Western Ghats (Nair et al. 2014).
The present study aims at identifying air pollution tolerant plant species for efficient landscaping in heavy traffic areas of Trivandrum city using two distinct indices—namely Air Pollution Tolerance Index (APTI) and Anticipated Performance Index (API). Based on this classification, the different locations suited for divergent species are also inferred to yield a concise landscape layout.
Materials and methods
Species commonly distributed for plantation under social forestry scheme by Kerala Forest Department (KFD) and Kerala Road Fund Board and planted at heavy traffic junctions and corridors of Trivandrum city were sampled. Leaves were sampled from the same plant in both summer and monsoons months in the morning between 8.00 and 9.00 am, with the ambient atmospheric temperature being 28 ± 2 °C in the summer and 23 ± 2 °C in the monsoon. The 3rd and 4th leaves from the apex of the branch were collected. In order to avoid experimental error due to pathology and pollution stress other than vehicular emission, healthy plants found near traffic signals and National Highways were selected. The sampling sites were also selected at locations devoid of industrial establishments nearby. Then the Air Pollution Tolerance Index (APTI) formula was applied on each sample collected. This equation was devised after careful consideration of several biochemical and physiological parameters of plants which makes them resilient to withstand air pollution (Singh et al. 1991). Four variables including relative water content (RWC), total chlorophyll, pH and ascorbic acid levels were analysed freshly. The measure of whose culminated empirical relation provides a measure of a plant’s relative tolerance to air pollution called the Air Pollution Tolerance Index (APTI). All the experiments were carried out in triplicates and results were tabulated as mean ± standard deviation.
Site selection
The top ten corridors (Table 1) exhibiting heavy pollutant emission in Trivandrum city were selected for the study. Selection was based on the secondary information obtained from Kerala State Pollution Control Board (KSPCB) (NATPAC 2016) (Fig. 1).
Species selection
The plant species whose leaf biochemistry was to be analysed were decided based primarily on the list of plants distributed by The Kerala Forest Department (KFD) every year, for planting in institutions, traffic islands, parks, roadsides and other public places under ‘social forestry scheme’ of the state government.
Some of the common ornamentals distributed by the Kerala Road Fund Board for planting in traffic islands and strips of land between four or six lane highways were also chosen for sampling.
Altogether, 67 different plant species consisting of both trees and shrubs including 16 flowering/avenue trees, 22 species of ornamental shrubs, 16 fruit bearing species, 9 shade providing trees and 4 timber-yielding species were analysed.
Analysis of Air Pollution Tolerance Index
Relative water content (Singh 1977)
Leaves were cut into pieces after removing the prominent veins and the fresh weight (Fw) was taken. Then they were immersed in distilled water overnight after covering with a lid to prevent water loss by evaporation. The excess water was blotted off the surface and the turgid weight (Tw) was recorded. The weighed sample was kept in an oven at 50 °C overnight and the dry weight (Dw) was noted.
pH (Singh and Rao 1983)
0.5 g of leaf tissue was ground in 50 ml distilled water using a mortar and pestle. The leaf extract was filtered out into a 25-ml beaker. After proper calibration of the digital pH meter using buffers with ph 7 and 4 respectively, the pH of the solution was measured using Eutech pH tutor.
Chlorophyll (Arnon 1949)
0.1 g of leaf tissue was extracted in 10 ml of 80% acetone and centrifuged at 3500 rpm for 10 min. Optical density (OD) readings of the extract at 645 nm and 663 nm were obtained using a visible spectrophotometer, Labtronics model LT-39.
Ascorbic acid (Sadasivam and Balasubramanian 1987)
Titrimetric analysis using DCPIP (dichloro phenyl indophenol ) was conducted using leaf extract, ground in 4% oxalic acid and the endpoint noted as V2 when the solution turns light permanent pink colour which persists 15 s of shaking. The same process was done using pure ascorbic acid solution with known concentration and the endpoint was noted as V1.
Calculation of APTI (Singh et al. 1991)
Air Pollution Tolerance Index (APTI) is an essential variable which gives us an idea about the resilience of a plant towards air pollution using four critically important biochemical parameters of the plant leaf, namely, pH, relative water content (RWC), total chlorophyll (TC) and ascorbic acid (AA) content. The plant which can maintain all the four parameters at relatively high levels even under pollution stress is considered to be extremely tolerant to pollution.
Limits for determining the extent of tolerance towards air pollution were set separately for shrubs and trees, according to the demonstration by Liu et al. 1983. These range limits of APTI values demarcating tolerant, moderately tolerant, intermediate and sensitive species were set after finding out the mean APTI and its standard deviation (SD) (of the entire 67 species analysed). This is because of the tendency of different types of plants, thriving in different environments to exhibit discrete response to pollution stress (Singh and Rao 1983). Tolerant plant species are represented by an APTI value greater than mean APTI+SD, whereas moderately tolerant plants come just below this, i.e. between mean APTI+SD and mean APTI. Within mean APTI and mean APTI-SD comes the intermediate category and finally those below this lowest range are occupied by the sensitive plants (Liu and Ding 2008). Accordingly, the presently set spectra are as follows:
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Trees:
Tolerant—greater than 10.83 APTI; Moderately tolerant—10.83 to 8.77 APTI; Intermediate—8.77 to 6.72 APTI; Sensitive—less than 6.72.
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Shrubs and herbs:
Tolerant—greater than 10.82 APTI; Moderately tolerant—10.82 to 8.50; Intermediate—8.50 to 6.19; Sensitive—less than 6.19.
Seasonal analysis—premonsoon vs monsoon
For those species showing APTI value greater than 9, (i.e. those which exhibit a significant degree of air pollution tolerance), readings were also taken during the monsoon to find out possible influence of rainfall on the four parameters.
Analysis of Anticipated Performance Index
Anticipated Performance Index (API) is a measure which takes into account both the APTI as well as other socioeconomic attributes of the plant for effective planning of large-scale plantations like greenbelts.
API analysis was done based on the parameters set by Panda et al. 2018.
As shown in Table 2, each plant species was graded according to their respective APTI values and morphological features, in terms of ‘+’ and ‘−’. By adding up the number of ‘+’ and ‘−’ separately and subtracting the total number of ‘−’ from the total number of ‘+’, a value will be derived. This value corresponds to the plant’s Anticipated Performance Index (API). Convert this in terms of 100, taking the maximum value as 16. Once the API score of a plant is derived, it can be compared with the standards for classification in Table 3, which aids in determining how far the plant is suited for mass propagation. The APTI range limits and API grade allocation method were adopted from the work done by Panda et al. (2018) and Pathak et al. (2011) respectively.
For instance, Delonix regia has an APTI score of 9.22, which according to Table 2, gives it ‘++’ value for APTI. Being a large (++), spreading dense (++) and deciduous (−) tree having small sized (−), smooth (−) and delineate (−) lamina with more than 5 uses (++), the API score totals to 4, which on conversion in terms of hundred will give 25. This value places D. regia in ‘Not suggested for mass plantations’ category, according to the API assessment grading standards in Table 3.
Results and discussion
Six out of the entire 67 species under study were found to have APTI value between 10.88 and 18.40 which included Agave americana > Cassia roxburghii > Anacardium occidentale > Cassia fistula > Mangifera indica > Saraca asoca, and were accommodated in the tolerant category (Table 4.). However, species with APTI between 5.31 and 6.71, exhibiting extreme sensitivity to air pollution, consisted of Tecoma stans > Jacaranda mimosifolia> Guazuma ulmifolia > Terminalia catappa > Pongamia pinnata = Tectona grandis.
Ascorbic acid is a strong reductant capable of reducing water during light reaction in photosynthesis (Singh and Verma 2007). The role of ascorbic acid in tolerance towards air pollution is visibly evident in cellular proliferation and stress response as the concentration of ascorbic acid present was notably proportional to its reducing power (Joshi and Swami 2007). The significance of ascorbic acid in determining APTI can be visualized from the degree of ascorbic acid quantified from leaves of Agave americana and Cassia roxburghii (Table 4) and their subsequent ranking based on their APTI scores.
The influence of pH on tolerance to pollution is loosely tied to the metabolism of ascorbic acid. pH apparently has a direct positive relationship in the breakdown of hexose sugar to ascorbic acid as high pH favours this process and promotes more ascorbic acid accumulation (Bora and Joshi 2014). As the concentration of ascorbic acid increases, so does its reducing power and APTI value. Ficus benjamina and Morus alba were found to have exceptionally high pH values in this investigation.
Vegetation behaves as a sponge or sink of air pollutants including gases and particulate matter detrimental to the fauna (Dash and Sahoo 2017). However, contact and eventual coating of plants with such particulates can lead to clogging of stomatal pores, which would tremendously affect the photosynthetic efficiency of the plant (Trivedi and Singh 1995).
Studies by Bora and Joshi (2014) highlight the negative impact of air pollution on the amount of total chlorophyll content. The photosynthetic productivity of the plant was found to have a direct influence on the amount of chlorophyll content present in the leaves (Agrawal and Tiwari 1997). Apparently, the entry of air pollutants via the stomata causes the clogging up of the stomata leading to a drastic decrease in the photosynthetic rate which intern reduces the sugar, protein and chlorophyll quantities of the leaf (Joshi and Swami 2007; Prajapati and Tripathi 2008; Narwaria and Kush 2012). Here (Table 4), we can see that Peltophorum pterocarpum (7.18 mg/g), Cassia fistula (5.91 mg/g), Jacaranda mimosifolia (5.35 mg/g) and Caesalpinia pulcherrima (5.22 mg/g) lead while taking chlorophyll content into consideration. The positioning of Jacaranda mimosifolia in the sensitive category even in the presence of high concentration of chlorophyll itself reveals the synergistic effect of all the four parameters in determining the degree of tolerance to air pollution. Similarly, extremely tolerant plants like Agave americana displayed very low chlorophyll content and Cassia fistula indicated very low RWC, but the culminated result keeps both in the resilient category which corroborates the above said concept of synergy.
Relative water content (RWC) is however associated with the protoplasmic permeability in plants which leads to loss of water and nutrients under stressful conditions (Geravandi et al. 2011). RWC is a measure which determines the water retention capacity of the plant under stress (Krishnaveni et al. 2013). If the plant is able to maintain its turgor and water holding capacity under pollution prone conditions, it will have very high RWC and hence a considerably high APTI score. Few examples from our study include Agave americana, Ficus elastica and Canna indica, all of which exhibits a very high percentage of RWC.
Agave americana and Cassia roxburghii were found to be the best among the entire 67 species analysed, considering their APTI scores and this is the first report of their extreme defense against air pollutants. Previous reports on Agave americana from Perummal Malay Hills, Salem, position it only in the moderate to intermediate range of pollution tolerance (Krishnaveni et al. 2013).
Results in agreement with the present study were observed by Lakshmi et al. (2009) in the industrial sites of Visakhapatanam regarding the tolerance of Cassia fistula against air pollution. But conflicting findings were observed at Erhoike- Kokori oil exploration station of Delta state by Agbaire as the trend of air pollution tolerance was mostly different from the present results observed with Psidium guajava and Anacardium occidentale pronounced as being sensitive and Terminalia catappa as being tolerant. Mangifera indica was found to be the most stable assuming very high air pollution tolerance in majority of the studies especially of those in Delta state, Udaipur, Asansol, Trivandrum and Shivamogga (Agbaire and Esiefarienrhe 2009; Rathore et al. 2018; Choudhary and Banerjee 2009; Jyothi and Jaya 2010; Adamsab et al. 2011).
Studies by Tripathi and Tiwari (2009) also coincide with the present results regarding the robustness of Saraca asoca in resisting air pollution stress; however, Pongamia pinnata was found to be extremely sensitive to air pollution in the city of Trivandrum which differs considerably from what was observed in Brass city by Tripathi. The present APTI results of Ficus species were observed to come in the moderate to tolerant range which is invariably supported by the views of Choudhary and Banerjee (2009).
Studies in Bengaluru mimic the presently observed trend of the high APTI score of Bougainvillea spectabilis among ornamentals in withstanding pollutant stress (Manjunath and Reddy 2019). The current investigation along with other studies in Kathmandu green belt areas, Nauni Solan State Highway in Himachal Pradesh and industrial areas of Bhopal highlights the extreme sensitivity of Jacaranda mimosifolia towards air pollution as is clearly visible from their respective APTI values (Shrestha and Malla 1996; Haseena 2016; Tiwari and Bansal 1994). However, the influence of other uncontrollable environmental factors affecting the stability of APTI value of a plant species is evident from the studies conducted in Ambo town, Ethiopia, as Jacaranda mimosifolia tops the charts in being highly tolerant to air pollution (Sekhar and Sekhar 2019).
Among the 4 parameters, RWC and ascorbic acid content plays a significant role in nullifying the detrimental effects of air pollution in plants as is evident from the results obtained (Table 4).
Seasonal analysis was conducted to elucidate any possible trends of variability existing in the plant biochemistry in accordance with air pollution. The RWC was found to be the only significant trait showing a general disparity during monsoon and summer months as during monsoon, the RWC increased in all the plants analysed compared to summer (Table 5). This may be attributed to the replenishment of the ground water table due to rain. The increase in APTI value during monsoon in all the plants analysed may be due to the washing effect of rain which unclogs the stomatal pores off dust particles and other minute particulate matter. This would facilitate easier gaseous and water vapour exchange between the plant and the atmosphere which in fact removes a potential source of plant stress.
Anticipated Performance Index (API) takes into account the APTI value, the socio-economic and biological aspects and provides a basis for sieving out species suited for large scale plantations like greenbelts (Table 6).
Plants with high API scores like Agave americana, Anacardium occidentale, Ficus elastica, Mangifera indica, Syzygium cumini, Ficus benghalensis, Nerium oleander and Ficus benjamina give heavy weightage to both APTI as well as its exploitable uses. Gupta et al. (2016) identified Ficus benghalensis, Mangifera indica, Swietenia mahogani, Saraca asoca and Psidium guajava as trees with excellent API scores. A critical review of about 89 research articles by Sahu and Sahu (2015) also points out the significantly high Anticipated Performance Indices of Mangifera indica, Ficus religiosa and Azadirachta indica and their potential in greenbelt development.
All in all, Agave americana was found to rank the first considering all the three aspects under study, i.e. APTI, seasonal stability of RWC and API score.
The aforementioned plants (Table 7) can be used for structuring the landscape layout in regions showing similar ecodynamics and species availability as that of Trivandrum city.
Conclusions
This is the first report on the relative efficacy of Agave americana, Cassia roxburghii in withstanding air pollution in Trivandrum city. Tolerant species with very high APTI including Agave americana (18.40), Cassia roxburghii (17.63), Anacardium occidentale (11.97), Cassia fistula (11.60), Mangifera indica (11.59) and Saraca asoca (10.88) are detected to be suited for planting near areas prone to heavy vehicular air pollution. Species with high API score Agave americana, Anacardium occidentale, Ficus elastica, Mangifera indica, Syzygium cumini, Ficus benghalensis, Nerium oleander and Ficus benjamina can be planted in mass plantations like greenbelts. Sensitive species with very low APTI value like Jacaranda mimosifolia, Tecoma stans, Terminalia catappa, Pongamia pinnata, Guazuma ulmifolia and Tectona grandis can be used in crude prediction of pollutant presence exceeding tolerable limits.
Data availability
All data generated or analysed during this study are included in this manuscript.
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Acknowledgements
Facilities: The Principal, University College, University of Kerala, Trivandrum.
Secondary data: Kerala State Pollution Control Board (KSPCB), Kerala Forest Department (KFD) and National Transportation Planning and Research Centre (NATPAC).
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Kerala State Council for Science, Technology and Environment (KSCSTE)
Availed by: Ancy S. Watson
Purpose: Research Grant
Kerala Forest Department Fund (KFDF)
Availed by: Sudha Bai R.
Purpose: For Glass wares and chemicals
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Watson, A.S., Bai R, S. Phytoremediation for urban landscaping and air pollution control—a case study in Trivandrum city, Kerala, India. Environ Sci Pollut Res 28, 9979–9990 (2021). https://doi.org/10.1007/s11356-020-11131-1
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DOI: https://doi.org/10.1007/s11356-020-11131-1