Trophic status, phytoplankton diversity, and water quality at Kafr El-Shinawy drinking-water treatment plant, Damietta

This work aims to study the seasonal fluctuation in physicochemical characteristics, trophic status, and some pollutants influencing phytoplankton diversity, and water quality at a compact Kafr El-Shinawy drinking-water treatment plant, Damietta – Egypt seasonally during 2018. Phytoplankton distribution was affected by the trophic status of water, level of pollutants, and physicochemical treatment processes of water. The predominance of phytoplankton species, especially Aphanizomenon flos aquae (Cyanophyta), Gomphosphaeria lacustris (Cyanophyta), Microcystis aeruginosa (Cyanophyta), Nostoc punctiforme (Cyanophyta), Oscillatoria limnetica (Cyanophyta), Pediastrum simplex (Chlorophyta), and Melosira granulata (Bacillariophyta) in treated water was much less than that in raw water. Trihalomethanes (THMs) levels in treated waters were higher than in raw water, while lower concentrations of heavy metals were recorded in treated water. Intracellular levels of microcystins were lower, whereas the extracellular levels were higher in treated water than raw water, and the former recorded the highest level in raw water during summer. Hence, the levels of dissolved microcystins and THMs in treated water were higher especially during summer, the season of luxurious growth of Microcystis species. Trophic state index (TSI) was relatively high in raw water compared with treated water due to high concentrations of nutrients (total-P, total-N, nitrite, nitrate, and ammonia) in raw water.


INTRODUCTION
Water pollution has become one of the most important environmental problems worldwide. Pollutants can be released into the environment as liquids, gases, and dissolved substances which can enter aquatic ecosystems and decrease water quality. The assessment of water quality essentially requires information about the physicochemical and biological properties of water. Temperature, acidity, hardness, pH, sulfate, chloride, dissolved oxygen (DO), biological oxygen demand, and alkalinity are physicochemical properties used for determining water quality (Swarnakar & Choubey ). Also, water quality can be assessed through natural bio-indicators; phytoplankton due to their sensitivity to nutrient availability and environmental conditions (e.g. water temperature and level of salinity; Manickam et al. ). Cyanobacterial growth adversely affects odor, taste, and color of water as some of these cyanobacteria produce potent toxins called cyanotoxins. There are various variants of cyanotoxins that are commonly produced by the genera, Although cyanobacterial cells can survive in water for long periods due to their ability to form thick-walled resting cells, the production of cyanotoxins is affected by several environmental conditions such as temperature, salinity, irradiance, and nutrients (Zhang et al. ).
One of the most serious water quality problems is eutrophication, which means the enrichment of water by organic and inorganic nutrients. Eutrophication causes structural changes to water and favors developing algae and plants. Oligotrophic, mesotrophic, eutrophic, and hypertrophic have been used by biologists to describe the various nutritional statuses of water. Oligotrophic means low nutrient concentrations and low algal growth, while hypertrophic state means high nutrients and high algal growth. Generally, nutrient concentration (nitrogen and phosphorus) and algal chlorophyll were used to assess water eutrophication. Trophic state index (TSI) is considered as one of the assessment methodologies of water eutrophication. Ray et al. () found that water pollution and eutrophication control the biodiversity of phytoplankton species and have a direct and indirect effect on biochemical constituents of phytoplankton cells.
The availability of good quality water is an indispensable feature for preventing diseases and improving the quality of human life. Water treatment plants mainly aim to improve the quality of water to make it appropriate for drinking and human consumption. Water treatment involves some physical processes such as settling and filtration, chemical processes such as disinfection and coagulation, in addition to biological processes such as slow sand filtration. As a result of chlorine disinfection during treatment of drinking water, trihalomethanes (THMs) including chloroform, dichlorobromomethane, and dibromochloromethane are produced as byproducts. THMs have short-term and longterm hazardous effects on human health.
Kafr El-Shinawy drinking-water treatment plant is a compact unit that is designed to produce safe drinking water for a small community that has no access to a central water treatment facility. The treatment processes at this water treatment plant include coagulation, flocculation, sedimentation, and filtration. In developing countries, the water quality patterns differ amongst drinking-water plants, and no previous studies have been conducted on water quality and phytoplankton composition at Kafr El-Shinawy drinking-water treatment plant. Therefore, the present work aims to shed light on the water quality at Kafr El-Shinawy treatment plant as it is the main source of drinking water of Kafr El-Shinawy village.
In this study, the effect of seasonal changes in physicochemical characteristics, trophic status of water as well as levels of pollutants, and microbial toxins on water quality and phytoplankton diversity at Kafr El-Shinawy drinking-water treatment plant will be determined and discussed.

Sampling sites
The study site was a compact Kafr El-Shinawy drinkingwater treatment plant that is situated at 31 41.816 0 N and 31 17.325 0 E. Water samples were collected seasonally (at 3-month intervals) from January to December 2018 in glass bottles from both the intake (the first unit) and output (the last unit) sites of Kafr El-Shinawy water treatment plant to determine the phytoplankton composition in relation to physicochemical properties, trophic status, and levels of pollutants of the native and treated water.

Physicochemical properties of water
Temperature, turbidity, pH, and electrical conductivity (EC) were measured in the field. The temperature and pH of water samples were measured using the laboratory glass thermometer and a pH meter (model HI 8314; Hanna Instruments Ltd), respectively. Water turbidity was measured directly using the Hanna instrument microprocessor turbidity meter. Water EC was measured using Jenway conductivity meter model 470. Total alkalinity, DO, biochemical oxygen demand (BOD), silica, ammonia, nitrite, nitrate, total nitrogen, and ortho-phosphate were estimated in the laboratory according to APHA (). The total phosphorus (TP) in water samples was determined according to Grasshoff ().
The heavy metals, iron, manganese, zinc, copper, chromium, cobalt, cadmium, nickel, and lead in water samples were assayed in water by using a Perkin-Elmer 2380 atomic absorption spectrophotometer as described by Sudharsan et al. (). All physicochemical analyses of water samples were triplicated.
Trihalomethane compounds in native and treated water were estimated according to U.S. EPA Method . ().

Phytoplankton composition
Raw and treated water samples were collected seasonally for microscopic examination using a conical bolting nylon net of 0.069 mm mesh and a mouth diameter of 35 cm with the help of an outrigger canoe. The samples were filtered through fine mesh nylon and fixed in Lugol's solution and 4% formalin and algal cells were enumerated using an inverted light microscope. Phytoplankton identification was performed with reference to Tikkanen () and Botes () using an EXACTA þ OPTECH GmbH light microscope (Model B3) -Code K7161, Germany.

Extraction and estimation of intracellular and extracellular microcystins
To determine the intracellular (particulate) and extracellular microcystins in raw and treated water, subsamples (250 mL) were filtered through a 0.45 μm cellulose filter (Whatman, UK). The filtrate was kept frozen to be used for extracellular (dissolved) microcystins. The residue with trapped cells was frozen, extracted twice in 80% methanol, and centrifuged at 10,000 × g for 10 min. The supernatants were pooled together, and the organic solvent was blown with sterilized air. The aqueous fraction remaining after removing the organic solvent was filtered through GF/C filter paper and stored frozen until analysis. Concentrations of extracellular and intracellular microcystins were determined by high-performance liquid chromatography (HPLC) (Column, Nucleosil 5 C l ∼ (150 × 4.6 mm)). The solvent system was: methanol -0.05 M phosphate buffer (pH 3) (58:42). The flow rate was 1 mL min À1 .

Biochemical composition of the predominant phytoplankton in raw and treated waters
Proteins and lipids (% DW) of predominant species were estimated during winter and summer according to AOAC () and carbohydrates were estimated spectrophotometry according to Dubois et al. ().
Chlorophyll-aas a measure of phytoplankton biomass was determined spectrophotometrically in 90% acetone extract of raw and treated waters according to Metzener et al. () using the following equations: Chlorophyll-a ¼ 11:78(A 663 )-2:29(A 647 ) Concentrations of the heavy metals (Fe, Mn, Zn, Cu, Cr, Co, Cd, Ni, and Pb) in phytoplankton cells from raw and treated water were estimated seasonally by using a Perkin-Elmer 2380 atomic absorption spectrophotometer as described by Sudharsan et al. ().

Trophic state index
TSI of both raw and treated water samples were calculated using Chlorophyll-a concentration (Chl-a) in μg L À1 and the TP in μg L À1 according to the formula of Lamparelli () and CETESB ().
where ln is the natural logarithm. The TSI is the simple arithmetic average of the indices for Chl-a and TP.

Statistical analyses
Data were analyzed using two-way analysis of variance (ANOVA), followed by mean separation according to Duncan's multiple range test at P < 0.05. Two-tailed Pearson product-moment correlation was performed to examine the relationship between all physicochemical parameters, phytoplankton diversity, and microcystin concentrations.
Statistical analysis was done using SPSS version 22.

Physicochemical properties of water
The effect of the main factors (water treatment and season) and their interaction was significant on most physicochemical parameters of water at a compact Kafr El-Shinawy treatment plant (Table 1). in summer. DO showed its higher concentrations in treated water (6.67-7.57 mg L À1 ) than that in raw water (5.10-6.83 mg L À1 ). It is also observed that DO in raw water increased by decreasing water temperature (significant negative correlation). On the contrary, BOD of both raw and treated water increased with increasing water temperature (significant positive correlation). BOD ranged from 2.71 to 3.81 mg L À1 in raw water and from 1.51 to 2.23 mg L À1 in treated water. Nitrogen forms (ammonia, nitrite, and nitrate), total nitrogen, total-P, and ortho-P were lower in raw water than in treated water and correlated significantly with BOD. Ortho-P and total-P in raw and treated water were in limited seasonal variability. Ortho-P values were very low in treated water, while total phosphorus has considerable values. Silica concentrations were higher in treated water than those in raw water and approached their maxima during winter (4.00 ± 0.34 mg L À1 in treated water and 2.51 ± 0.52 mg L À1 in raw water).
The effect of the main factors (water treatment and season) and their interaction on heavy metal concentrations of water was significant (Table 3). The effect of water treatment was stronger (with a higher F ratio) than that of a season for all determined heavy metals that decreased in treated water than that in raw water. Levels of all the measured heavy metals especially Mn, Zn, and Fe were higher in phytoplankton cells than that in raw water and treated water (Table 4). Correlation between heavy metals and other physicochemical parameters of both raw and treated water is presented in Table 5. The results showed significant correlations between most of the metals at p < 0.01. Heavy metals Fe, Mn, Zn, Cd, Ni, and Pb were correlated positively with water turbidity. Mn, Zn, Cu, and Cd were correlated negatively with DO and positively with water pH and BOD. Heavy metals Fe, Zn, Cd, Ni, and Pb were correlated positively with nutrients (ammonia, nitrite, nitrate, total-N, total-P, and ortho-P). Also, positive correlations between some heavy metals (Mn and Zn) and water EC and alkalinity were reported.
The effect of the main factors (water treatment and season) and their interaction on THMs in raw and treated water was significant (P < 0.05) as shown in Table 6. The effect of water treatment was stronger (with a higher F ratio) than that of a season for all tested THMs. The present results showed that high values of THMs in water were during summer, whereas low concentrations were during winter, with an increase in treated water. The water treatment exhibited its maximum efficiency in winter. THMs specification shows that their presence in both raw and treated water was in the order: chloroform > dichlorobromomethane > dibromochloromethane. As shown in Figure

Phytoplankton composition
Three phytoplankton groups were found in raw and treated waters, viz. Cyanophyta, Chlorophyta, and Bacillariophyta.
The phytoplankton density in treated water was much less than those in raw water. The effect of the main factors (water treatment and season) and their interaction on the phytoplankton community at the study area was significant (P < 0.05) as shown in Table 6. The effect of water treatment was stronger (with a higher F ratio) than that of a season for The maximum cell numbers of phytoplankton were found in raw water during summer (55.5 × 10 7 cell L À1 ).
The species composition of raw water (47 taxa) was richer than that of treated water (only 15 taxa). During winter, Oscillatoria limnetica was predominated in raw water (98.5% total phytoplankton). Meanwhile, Microcystis aeruginosa predominated during summer (57.5%). Other Cyanophyta species also coexisted but in low numbers (  Pearson's correlation coefficient revealed that the composition of the phytoplankton community depends on the physicochemical parameters of water, which in turn depends on water treatment and seasons. As shown in Table 8, a significant negative correlation was reported between Bacillariophyta cell numbers and both silica (r ¼ À0.356, P < 0.01).   Bold numbers indicate a negative correlation.

Intracellular and extracellular microcystins
The effect of the main factors (water treatment and season) and their interaction on the levels of intracellular and extracellular microcystin was significant (P < 0.05) with a higher effect of water treatment (higher F ratio) than that of a season (Table 6). Both intracellular and extracellular (dissolved) microcystins recorded their higher concentrations during summer. Throughout the study period, the intracellular microcystin levels were lower in treated water than in raw water. In raw water, the lowest intracellular microcystin was obtained during winter (0.71 μg L À1 ), while the highest concentration was 1.70 μg L À1 during summer (Table 9).
The maximum concentration of dissolved microcystins in raw water (1.30 μg L À1 ) was lower than that in treated water (2.01 μg L À1 ) during summer. Also, the minimum concentration of dissolved microcystins in raw water (0.56 μg L À1 ) during winter was lower than that in treated water (1.00 μg L À1 ) during autumn.  phytoplankton of raw and treated water was very highly significant (P < 0.05) with a higher effect of water treatment than that of a season ( Table 6). The chlorophyll-a content in phytoplankton was significantly higher in raw water than in treated water during the study period (P < 0.01), particularly during spring (Figure 4). Chlorophyll-a content was generally highest during summer (1.42 μg L À1 ), followed by spring (1.21 μg L À1 ), while the lowest values were during winter (0.04 μg L À1 ).

Trophic state index
The ANOVA results showed that the effect of the main factors (water treatment and season) and their interaction on the TSI values of the water samples were significantly different (P < 0.05). The effect of water treatment on TSI values was stronger (with a higher F ratio) than that of a season (Table 6). The trophic state classifications of water samples    Water turbidity was significantly correlated with nutrient concentrations (ammonia, nitrite, nitrate, total nitrogen, ortho-P, and total-P) in water. The high turbidity of raw water (4.30-6.01 NTU) compared with treated water (1.27-1.86 NTU) might be related to high organic pollution of raw water and the efficiency of water treatment.
Water pH is an important factor in the aquatic system that directly affects the phytoplankton community. In the present study, the slight increase in raw water pH might be due to biological activity such as photosynthesis and  DO level is an indicator of the water's ability to support a well-balanced aquatic life and acts as an indicator of the trophic status of the water body (Salah & El-Moselhy ). The increase in DO of treated water (6.67-7.57 mg L À1 ) above that of raw water (5.10-6.83 mg L À1 ) might be due to the physicochemical treatment processes of water such as aeration, coagulation, sedimentation, filtration, and addition of oxidative agents. These treatments increased DO and decreased the turbidity of treated water.
A significant negative correlation between DO and water temperatures (r ¼ À0.502, p < 0.05) was also reported by Shehata & Badr (). Low values of DO in raw water during the summer (5.10 ± 0.50 mg L À1 ) might be attributed to high sewage and agricultural pollution that enhance microbial growth in raw water. The high value of BOD in raw water during summer (3.81 ± 0.32 mg L À1 ) may be attributed to the respiration activity of phytoplankton and other aquatic biotas which is stimulated by increasing water temperature and relative high wastewater discharges.
Low silica concentrations in raw water (2.23-3.60 mg L À1 ) might be related to the high growth of diatoms, especially during autumn and winter. But, the increased silica in treated water (2.33-4.00 mg L À1 ) can be related to in treated water may be attributed to the oxidation of   whereas some other heavy metals, including Cu, Zn, and Cr, are essential elements for the human body in small quantities, but turn toxic in high doses. In the present study, the low concentrations of heavy metals (Fe, Mn, Zn, Cu, Cr, Co, Cd, Ni, and Pb) in treated water than in raw water may be related to coagulation and sedimentation processes in treatment basins, in addition to the efficiency of physicochemical water treatment processes including ion exchange and precipitation.
The higher levels of all the measured heavy metals, especially Mn, Zn, and Fe in phytoplankton cells than in raw and treated water were due to the bioaccumulation capacity of phyto-   A great many of the world's drinking-water sources suffer from eutrophication and outbreaks of cyanobacteria, mainly as a result of increased stream regulation. TSI is a number that can be used to classify water in different trophic states. TSI assesses water quality regarding nutrient enrichment and its relationship with excessive growth of algae.
Chlorophyll-a and TP are key indicators used to determine the trophic state. It could range from oligotrophic to hypereutrophic. In the present study, TSI values of water samples at input and output of Kafr El-Shinawy treatment plant based on total-P and chlorophyll-a had been estimated and were significantly different. In the present study, the relative higher trophic state of raw water (TSI ¼ 46.72-50.53) than that of treated water (TSI ¼ 33.19-40.75) throughout the year was due to high concentrations of nutrients (total-P, total-N, nitrite, nitrate, and ammonia) in raw water. Nitrogen and phosphorus in raw water are generated from human and industrial wastes. High values of turbidity in raw water especially during spring (6.01 ± 0.57 NTU) and summer (6.00 ± 0.57 NTU) could be attributed to the meso-eutrophic state of water and high phytoplanktonic growth (mainly Cyanophyta). While low values of turbidity in treated water especially during winter (1.27 ± 0.12 NTU) and autumn (1.34 ± 0.13 NTU) could be due to the oligotrophic state of water. Several previous studies reported that the primary production of phytoplankton is an important indicator used in assessing water trophy. It explained the positive correlations of TSI with phytoplankton (Cyanophyta and Chlorophyta) numbers.

This study presents information on water quality at Kafr
El-Shinawy drinking-water treatment plant to provide clean and safe drinking water. The study demonstrated that the phytoplankton composition depends on the changes in physicochemical properties of water as well as the trophic status of water. The optimized physicochemical properties of raw water and meso-eutrophic state increase the phytoplankton growth especially, cyanobacteria to a level of bloom formation. The high growth of cyanobacteria led to the production of cyanotoxins with a high content of intracellular microcystin and low content of extracellular microcystin in raw water. On the contrary, most of the intracellular microcystins were released in treated water during water treatment processes. Phytoplankton cells control the levels of heavy metals in raw and treated water through their bioaccumulation capacity. Consequently, heavy metal levels in raw and treated water are less than those in phytoplankton cells. THMs were higher in treated water than in raw water, with marked efficiency of the physical-chemical treatment of water in the flocculation basin. The dissolved microcystin and THMs contents in treated water are higher than the allowable limit. The present study recommends that ecotechnology or biomanipulation could be used in Kafr El-Shinawy drinking-water treatment plant for improving the water quality and to decrease eutrophication.