ACTA BOT. CROAT. 80 (2), 2021 117

Acta Bot. Croat. 80 (2), 117–124, 2021   CODEN: ABCRA 25
DOI: 10.37427/botcro-2021-011 ISSN 0365-0588
 eISSN 1847-8476

 

Effects of two synthetic pyrethroids  
on Arthrospira platensis Gomont growth  
and antioxidant parameters
Hatice Tunca1*, Kübra Hödük1, Feray Köçkar2, Ali Doğru1, Tuğba Ongun Sevindik1

1 University of Sakarya, Faculty of Arts and Science, Department of Biology, Sakarya, Turkey
2 University of Balıkesir, Faculty of Arts and Science, Department of Molecular Biology and Genetics, Balıkesir, Turkey

Abstract – The transport of pesticides from application areas to other areas results in pesticide contamination and this 
sort of contamination has led to unexpected environmental problems worldwide. It is important to determine the re-
sponses of phytoplanktonic organisms to these chemicals for an understanding of the effects of pesticides on aquatic 
ecosystems. In this study, Arthrospira platensis Gomont cyanobacteria were exposed to different concentrations of the 
pesticides cypermethrin (Cyp; 0–50 µg mL–1) and deltamethrin (Dlm; 0–2 µg mL–1). Changes in chlorophyll-a concen-
tration, the absorbance at OD560, antioxidant parameters (superoxide dismutase – SOD, ascorbate peroxidase – APX, 
glutathione reductase – GR, malondialdehyde  – MDA, H2O2, and proline) were determined under the pesticide expo-
sure. Our results showed that there is a decrease in OD560 absorbance and chlorophyll-a content proportional to the 
increase of pesticide levels. SOD activity decreased with Cyp and Dlm application in A. platensis cultures. GR activity 
also decreased with Cyp applications but did not change with Dlm application. APX activity increased with Cyp treat-
ments but did not change with Dlm applications. Although MDA and hydrogen peroxide contents did not change with 
Cyp applications, they increased with Dlm applications. Proline contents increased with Cyp applications but decreased 
with Dlm applications. In conclusion, deltamethrin was more toxic than cypermethrin in the concentrations applied.

Keywords: antioxidant enzymes, Arthrospira platensis, cypermethrin, deltamethrin, growth

Introduction
Many chemicals, including pesticides, are released 

through modern industrial and agricultural activities and 
have reached a high level in the environment (Burkiewicz 
et al. 2005). Pesticides affect not only target organisms but 
also non-target organisms in the aquatic biota (Tremolada 
et al. 2004). These organisms play an important role in bio-
logical processes such as biogeochemical cycling, produc-
tion, separation, and interaction with other organisms. Pes-
ticides disturb the balance of water ecosystems with their 
direct action on plants and animals or with their bioaccu-
mulation and transfer abilities in the food chain (Netrawali 
and Gandhi 1990, Burkiewicz et al. 2005). Planktonic algae 
display a fundamental role as primary producers (Burkiewicz 
et al. 2005) and a decrease in algal density and species com-
position affects the aquatic ecosystem directly by reducing 
biodiversity and primary production (Li et al. 2005). They 
are sensitive indicators that allow testing of the different 

 effects of chemicals released into the water (Burkiewicz et 
al. 2005). For this reason, microalgae are frequently used in 
various bioassays (Li et al. 2005). Agricultural chemicals 
 inhibit the growth rate, biomass, and pigment content of 
freshwater algae by contaminating surface waters in agri-
cultural areas (Netrawali and Gandhi 1990).

Pyrethroids are a class of synthetic insecticides designed 
and optimized based on pyrethrin structure (Elliott 1995). 
These pesticides are effective insecticides that are widely 
used to control agricultural and healthcare pests. After use, 
they are released into the environment and enter water re-
sources (Mittal et al. 1994). Cypermethrin (Cyp) and delta-
methrin (Dlm) have increased toxicity, especially to aquatic 
organisms with increasing life expectancy (Johri et al. 1997). 
Megharaj et al. (1987) observed that Cyp has inhibitory ef-
fects on Scenedesmus bijugatus Kützing. Xiong et al. (2002) 
and Li et al. (2005) found similar results for Scenedesmus 

* Corresponding author e-mail: htunca@sakarya.edu.tr



TUNCA H., HÖDÜK K., KÖÇKAR F., DOĞRU A., SEVINDIK O. T.

118 ACTA BOT. CROAT. 80 (2), 2021

pesticide application. Responses given by phototrophic mi-
croorganisms to pesticides will help us to have an idea of 
how the communities are affected by the pesticides in the 
water ecosystems.

Material and methods
Algae culture and treatment

Arthrospira platensis, strain M2, was obtained from the 
Soley Microalgae Institute (California, USA) (Culture collec-
tion No: SLSP01). Algae were grown in Spirulina Medium 
(Aiba and Ogawa 1977) under axenic conditions. 20 mL algal 
cultures were inoculated onto 180 mL culture medium in an 
Erlenmeyer flask and were allowed to grow under full-spec-
trum lamps providing 93 µmol photons m–2 s–1 photosyn-
thetically available radiation in a 12:12 h light/dark cycle at 
30 ± 1 °C during 10 days. At the end of 10 days, cultures were 
renewed and, all the flasks contained 50 mL algal culture. 
Stock solutions of the commercial formulation of Cyp and 
Dlm (200 g L–1 and 25 g L–1, respectively; EC, Sakarya, 
 Turkey) were prepared with distilled water and were then di-
luted for all bioassays. Various final concentrations of cyper-
methrin (10, 20, 30, 40, 50 µg mL–1) and deltamethrin (0.125, 
0.25, 0.5, 1, 1.5, 2 µg mL–1) were in the culture medium. The 
range of concentrations was determined with preliminary 
range-finding bioassays according to EC50 value for growth 
parameters and IC50 value for enzyme activity assays and at 
least five concentrations were selected under these values. 

Cell growth and chlorophyll-a assay

Optical densities (ODs) at 560 nm were measured spec-
trophotometrically over 7 days under control and stressed 
conditions. . Chlorophyll-a content was estimated by meth-
anol extraction and measured spectrophotometrically over 
7 days (MacKinney 1941).

Antioxidant enzyme activities

On the 7th day of the study, 2 mL culture solutions from 
the control and treated samples were centrifuged at 14,000 
rpm for 20 min at 4 °C and the resulting pellets were kept 
at –20 °C until enzyme activity was measured. Pellets were 
ground with liquid nitrogen and suspended in specific buf-
fers with proper pH values for each enzyme. The protein 
concentrations of algal cell extracts were determined ac-
cording to Bradford (1976), using bovine serum albumin 
(BSA) as a standard.

The superoxide dismutase activity was determined by 
the method of Beyer and Fridovich (1987), based on the pho-
toreduction of NBT (nitroblue tetrazolium). Extraction of 
pellets (0.2 g) was performed in 1.5 mL homogenization 
buffer containing 100 mM K2HPO4 buffer (pH 7.0), 2% PVP, 
and 1 mM Na2EDTA. After centrifugation at 14,000 rpm 
for 20 min at 4 °C, the resulting supernatants were used to 
measure SOD activity. The reaction mixture consisted of 
100 mM K2HPO4 buffer (pH 7.8) containing 9.9 × 10–3 M 
methionine, 5.7 × 10–5 M NBT, 1% triton X-100, and enzyme 

obliquus Kützing. Wang et. al. (2011) carried out a growth 
inhibition test on Skeletonema costatum Cleve, Scrippsiella 
trochoidea (F.Stein) A.R.Loeblich III and Chattonella 
 marina (Subrahmanyan) Y.Hara et M.Chihara during 96 h. 
Sáenz et al. (2012) studied Cyp toxicity to Scenedesmus 
quadricauda Chodat, Scenedesmus acutus Meyen, Chlorella 
vulgaris Beyerinck (Beijerinck) and Pseudokirchneriella 
 subcapitata (Korshikov) F.Hindák. Wang et al. (2012) tested 
Cyp effetcs on Scenedesmus obliquus. These references show 
that Cyp has toxic effects on various groups of microalgae. 
There are also some studies on Dlm toxicity to aquatic micro-
organisms. Baeza-Squiban et al. (1987) have shown that the 
growth of Dunaliella sp. Teodoresco and Chlamydomonas 
sp. Ehrenberg was inhibited by Dlm application. Caquet et 
al. (1992) observed Dlm effects on phytoplankton commu-
nities in freshwater mesocosms and found Dlm to disappear 
rapidly from the aquatic ecosystem.

Antioxidants are compounds that reduce the harmful ef-
fects of oxidation via inhibiting free oxygen formation or 
eliminating free radicals (Baublis et al. 2000). Superoxide dis-
mutase (SOD: EC 1.15.1.1) is a class of metalloprotein that 
catalyses superoxide to oxygen and hydrogen peroxide 
(H2O2) (Valentine et al. 1998). Ascorbate peroxidase (APX: 
EC 1.11.1.11) converts hydrogen peroxide to water by using 
ascorbate as an electron donor and thereby accumulations of 
H2O2 toxic levels are prevented in photosynthetic organisms 
(Chew et al. 2003). Glutathione reductase (GR: EC 1.6.4.2), is 
a member of NADPH-dependent oxidoreductases, found in 
both prokaryotic and eukaryotic cells. GR catalyses the re-
duction of oxidized glutathione (GSSG) to reduced glutathi-
one (GSH) together with the oxidation of NADPH and plays 
an important role in the cellular defence systems against re-
active oxygen metabolites by creating a reduced GSH pool 
(Anjum et al. 2010). Malondialdehyde is a metabolite that 
occurs with peroxidation of lipids including three or more 
double bonds. Lipid peroxidation causes malondialdehyde 
formation (Goel and Sheoran 2003). It is known that proline 
content increases under various stress factors and proline ac-
cumulation protects cell parts and cell contents such as en-
zymes, membranes and polyribosomes (Kishor et al. 2005).

The enzymatic and non-enzymatic antioxidant defence 
systems create the response to oxidative stress and reflect 
the tolerance and susceptibility of algae to pesticide expo-
sure. However, although there is some information about 
algal antioxidant systems, which are either a response to the 
environmental conditions or a defensive system (Mallick 
and Mohn 2000) studies about the harmful or activator ef-
fects of pyrethroids on algal antioxidant systems are limited. 

The aims of our study are: (i) to determine metabolic 
damage due to cypermethrin and deltamethrin toxicity and 
(ii) to measure the intracellular level of antioxidant respons-
es for pesticide detoxification in Arthrospira platensis-M2 
strain. For this purpose, the alterations of some parameters 
such as growth rate (OD560), chlorophyll-a content, super-
oxide dismutase (SOD), ascorbate peroxidase (APX), gluta-
thione reductase (GR), malondialdehyde (MDA), hydrogen 
peroxide (H2O2) and proline have been investigated during 



OXIDATIVE DAMAGE OF PESTICIDE ON Arthrospira platensis

ACTA BOT. CROAT. 80 (2), 2021 119

extract. The reaction was started by the addition of 0.9 µM 
riboflavin and the mixture was exposed to light with an in-
tensity of 375 µmole m–2 s–1. After 15 min, the reaction was 
stopped by switching off the light, and absorbance was read 
at 560 nm. The SOD activity was calculated by a standard 
graphic and expressed as U mg–1 protein. 

The ascorbate peroxidase activity was determined ac-
cording to Wang et al. (1991) by estimating the decreasing 
rate of ascorbate oxidation at 290 nm. APX extraction was 
performed in 50 mM Tris–HCl (pH 7.2), 2% PVP, 1 mM 
Na2EDTA, and 2 mM ascorbate. The reaction mixture con-
sisted of 50 mM K2HPO4 buffer (pH 6.6), 2.5 mM ascorbate, 
10 mM H2O2, and enzyme-containing 100 µg protein in a 
final volume of 1 mL. The enzyme activity was calculated 
from the initial rate of the reaction using the extinction co-
efficient of ascorbate (E = 2.8 mM cm–1 at 290 nm).

The glutathione reductase activity was measured with 
the method of Sgherri et al. (1994). Extraction was per-
formed in 1.5 mL of suspension solution containing 100 mM 
K2HPO4 buffer (pH 7.0), 1 mM Na2EDTA, and 2% PVP. The 
reaction mixture (total volume of 1 mL) contained 100 mM 
K2HPO4 buffer (pH 7.8), 2 mM Na2EDTA, 0.5 mM oxidised 
glutathione (GSSG), 0.2 mM NADPH and enzyme extract 
containing 100 µg protein. The decrease in absorbance at 340 
nm was recorded. Correction was made for the non-enzy-
matic oxidation of NADPH by recording the decrease at 340 
nm without adding GSSG to assay mixture. The enzyme ac-
tivity was calculated from the initial rate of the reaction after 
subtracting the non-enzymatic oxidation using the extinc-
tion coefficient of NADPH (E = 6.2 mM cm–1 at 340 nm).

Determination of malondialdehyde and hydrogen 
peroxide 

The malondialdehyde content was determined by the 
method of Heath and Packer (1968). 0.2 g of pellet was ho-
mogenized in 3 mL of 0.1% TCA (4 °C) and centrifuged at 
4100 rpm for 15 min and the supernatant was used in the 
subsequent determination. 0.5 mL of 0.1 M Tris–HCl pH 7.6 
and 1 mL of TCA–TBA–HCl reagent (15% w/v) (trichloro-
acetic acid–0.375% w/v thiobarbituric acid–0.25 N hydro-
chloric acid) were added to the 0.5 mL of the supernatant. 
The mixture was heated at 95°C for 30 min and then quick-
ly cooled in an ice bath. To remove suspended turbidity, the 
mixture was centrifuged at 4100 rpm for 15 min, then the 
absorbance of the supernatant at 532 nm was recorded. 
Non-specific absorbance at 600 nm was measured and sub-
tracted from the readings recorded at 532 nm. The MDA 
content was calculated using its extinction coefficient of 155 
mM−1 cm−1. For determination of the hydrogen peroxide 
content, 0.5 mL of 0.1 M Tris–HCl (pH 7.6) and 1 mL of 1 
M KI were added to 0.5 mL of supernatant. After 90 min, 
the absorbance was recorded at 390 nm.

The proline content determination

The proline content was determined by the method of 
Weimberg et al. (1982) where 0.1 g of pellet was homoge-

nized in 10 ml of 3% aqueous sulphosalicylic acid and ho-
mogenates were incubated in a hot water bath at 95 °C for 
30 minutes. The samples were cooled and centrifuged at 
4,100 rpm for 10 min. Two mL of the extract reacted with 2 
mL of acid–ninhydrine and 2 mL of glacial acetic acid for 1 
h at 100 °C. The reaction mixture was extracted with 4 mL 
toluene. The chromophore containing toluene was separat-
ed and the absorbance was recorded at 520 nm.

Statistical analysis

The differences between the means of control and treat-
ed samples were analysed by one-way analysis of variance 
(ANOVA), taking P < 0.05 as significant according to LSD 
with two degrees of freedom. Three replicate cultures were 
used for each treatment. The mean values ± standard error 
(SE) are shown in Figures.

Results
Biomass and chlorophyll-a content

Biomass production and chlorophyll-a content of Ar-
throspira platensis-M2 cells were significantly decreased by 
Cyp and Dlm application to the culture medium for 7 days 
(P < 0.05, Figs. 1, 2). The most significant reductions were 
observed at the highest pesticide treatments, (50 µg mL–1 for 
Cyp and 2 µg mL–1 for Dlm) in biomass production and 

Fig. 1. Biomass values, as absorbance at 560 nm (a), and chloro-
phyll-a concentration (b) of Arthrospira platensis treated with 
0–50 µg mL–1 cypermethrin during 7 days. Data are the means ± 
SE of three replicates. *Significantly different from control, P ˂ 
0.05 (LSD analysis).



TUNCA H., HÖDÜK K., KÖÇKAR F., DOĞRU A., SEVINDIK O. T.

120 ACTA BOT. CROAT. 80 (2), 2021

chlorophyll-a content. Cyp and Dlm toxicity affected the 
biomass production and chlorophyll-a content of A. platen-
sis-M2 cells, which increased in a time-dependent manner 
during the 7 days (Figs. 1a,b, 2a,b). The EC 50 values of Cyp 
and Dlm applications were 53.12 ± 1.16 µg mL–1 and 1.76 ± 
0.07 µg mL–1 respectively for 7th day, based on biomass pro-
duction.

The antioxidant parameters

The effect of Cyp applications on SOD activity in A. pla-
tensis-M2 cells is presented in Fig. 3a. All Cyp concentra-
tions (5, 10, 20, 30, 40, 50 µg mL–1) caused an increase in 
SOD activity on A. platensis-M2 cells as compared to con-
trol. The maximum inhibition in SOD activity (96%) oc-
curred at 40 µg mL–1 Cyp concentration. APX activities in-
creased at the same concentrations (P < 0.05, Fig. 3b). On 
the other hand GR activities also decreased at all concentra-
tions except 5 µg mL–1 Cyp application (P < 0.05, Fig. 3c). 
Ten, 20, 30, 40, 50 µg mL–1 Cyp concentrations caused  17, 
66, 47, 70, 85% decrease in GR activity, respectively. MDA 
and H2O2 contents (Fig. 4a,b) did not change significantly, 
but proline contents (Fig. 4c) increased at all Cyp concen-
trations (P > 0.05).

The effect of Dlm applications on SOD activity in A. 
platensis-M2 cells is presented in Fig. 5a. SOD activities de-
creased by 37, 47, 21, 39, 36, 52% (P < 0.05) at all Dlm con-

centrations, respectively; APX and GR activities did not dis-
play significant alteration (P > 0.05, Fig. 5b,c). MDA contents 
increased at 0.5, 1, 1.5 µg mL–1 Dlm applications 74, 85, 78%; 
respectively (P < 0.05, Fig 6a); however H2O2 content in-
creased with 1, 1.5 and 2 µg mL–1 Dlm applications (P < 0.05, 
Fig. 6b). Proline content decreased significantly at 2 µg mL–
1 Dlm concentration (P < 0.05, Fig. 6c).

Discussion
In this study, we have found that exogenous addition of 

different concentrations of two synthetic pyrethroids (cy-
permethrin and deltamethrin) showed varying degrees of 
toxicity to the growth of Arthrospira platensis M2 strain. In 
a study of Scenedesmus bijugatus, Nostoc linckia Bornet ex 
Bornet et Flahault, Synechococcus elongatus (Nägeli) Näge-
li and Phormidium tenue Gomont, Megharaj et al. (1987) 
found that cypermethrin inhibited the growth of Scenedes-
mus bijugatus at 10–50 μg mL−1 concentrations. Xiong et al. 
(2002) applied cypermethrin to Scenedesmus obliquus dur-
ing a 96 h period and found that the EC50 was 112 mg L–1. 
Li et al. (2005) reported that cypermethrin inhibited the 
growth of Scenedesmus obliquus at 50–250 mg L–1 concen-
trations during 96 h, and the chlorophyll-a and carotenoid 
content of Scenedesmus obliquus decreased with the appli-
cation. Li et al. found the EC50 value of cypermethrin as 
112 ± 9 mg L–1. Wang et. al. (2011) carried out a growth in-
hibition test about cypermethrin toxicity on Skeletonema 
costatum, Scrippsiella trochoidea, and Chattonella marina 
during 96 h and they determined EC50 values as 71.4 μg L−1, 
205 μg L−1 and 191 μg L−1, respectively. Sáenz et al. (2012) 
study cypermethrin toxicity to Scenedesmus quadricauda, 
Scenedesmus acutus, Chlorella vulgaris and Pseudokirchne-
riella subcapitat and the inhibited growth concentrations 
are 0.3–5 mg L–1, 0.6 mg L–1, 0.15 – 2.5 mg L–1 and 0.075 mg 
L–1, respectively. In another study, Wang et al. (2012) deter-
mine the toxic effects of commercial cypermethrin on S. 
obliquus and measure EC50 value of 2.37 mg L–1. The data 
and the concentrations used (10–50 µg mL–1) of Megharaj 
et al. (1987) are the closest to the results of our study. As was 
shown in the literature, Cyp has an inhibitory effect on al-
gal growth and chlorophyll-a content.

As with the toxicity of Cyp, there are some studies about 
the effect of Dlm on algae. In the study of Burkiewicz et al. 
(2005), the cell density of Scenedesmus subspicatus Chodat 
decreased with 2.5, 5 and 10 mg L–1 Dlm applications dur-
ing 24 h and 1.25 mg L–1 Dlm application during 72 h. Lut-
nicka et al. (2014) observed that Dlm has inhibited the 
growth of Chlorella vulgaris by 13% at the end of 14 days 
with a 0.02 μg L–1 Dlm application. 

Although the Dlm concentrations in the study of Lut-
nicka et al. (2014) were lower than in our applications, the 
concentrations of Burkiewicz et al. (2005) were similar to 
those in our studies’.

In our study, SOD activities of A. platensis decreased at 
all Cyp applications except 5 µg mL–1 and at all Dlm appli-

Fig. 2. Biomass values, as absorbance at 560 nm (a), and chloro-
phyll-a concentration (b) of Arthrospira platensis treated with 0–2 
µg mL–1 deltamethrin during 7 days. Data are the means ± SE of 
three replicates. *Significantly different from control, P ˂ 0.05 
(LSD analysis).



OXIDATIVE DAMAGE OF PESTICIDE ON Arthrospira platensis

ACTA BOT. CROAT. 80 (2), 2021 121

cations according to control. In our study, Cyp and Dlm 
pesticides also caused significant reductions in chlorophyll-
a, and thus loss of photosynthetic metabolism may have 
caused significant reductions in SOD activity. Wang et al. 
(2011) also reported that Cyp pesticide in high concentra-
tions (> 50 μg L–1) inhibited SOD activity in Skeletonema 
costatum, Scrippsiella trochoidea and Chattonella marina, 
and they pointed out the inactivation of SOD activity may 
have been due to growth being inhibited by cypermethrin. 
One or more of the suggested reasons in these articles may 
be the main mechanism of Cyp and Dlm toxicity on the 
SOD enzyme activity in our study.

GR and glutathione are effective on the Halliwell / Asada 
pathway in the inactivation of H2O2 in plant cells (Bray et al. 
2000). GR catalyzes the last step of the ascorbate-glutathione 
pathway. GR activity significantly decreased at 10, 20, 30, 40, 
and 50 µg mL–1 Cyp applications. Sáenz et al. (2012) found 
that Cyp concentrations causing algicidal effects, and there-
by inhibitory effects of GR enzyme activity due to oxidative 

stress damage on P. subcapitata. The reductions in GR en-
zyme activities may have been related to loss of cell viability 
or deterioration of enzyme structure and enzyme reactions.

In contrast, GR activity did not change in Dlm applica-
tion in our study. Dewez et al. (2005) treated a fungicide 
Fludioxonil to Scenedesmus obliquus and indicated that GR 
activity was not significantly affected and the oxidized glu-
tathione pool may have also been used by other enzymes.

APX enzyme activity statistically increased at all con-
centrations in Cyp treatment. APX use ascorbic acid for the 
elimination of detrimental H2O2 (Verma and Dubey 2003). 
Studies on plants showed that APX activity increased in 
various stress conditions (Hideg and Vass 1996, Verma and 
Dubey 2003).

Teisseire and Vernet (2001) supported the conclusion 
that GR enzyme activity was related to the APX enzyme ac-
tivity. In our study, it was concluded that the absence of al-
teration in GR activity at the application concentrations of 
Dlm promoted the absence of alteration in APX enzyme at 

Fig. 3. Total superoxide dismutase (SOD; a), ascorbate peroxidase 
(APX; b) and glutathione reductase (GR; c) activities of Arthro-
spira platensis treated with 0–50 µg mL–1 cypermethrin. Data are 
the means ± SE of three replicates. *Significantly different from 
control, P ˂ 0.05 (LSD analysis).

Fig. 4. Malondialdehyde (MDA; a), hydrogen peroxide (H2O2; 
b) and proline (c) contents of Arthrospira platensis treated with 
0–50 µg mL–1 cypermethrin. Data are the means ± SE of three 
re plicates. *Significantly different from control, P ˂ 0.05 (LSD 
analysis).



TUNCA H., HÖDÜK K., KÖÇKAR F., DOĞRU A., SEVINDIK O. T.

122 ACTA BOT. CROAT. 80 (2), 2021

similar concentrations because the ascorbate pool was 
counterbalanced by the GR enzyme. 

In our study, MDA content in A. platensis cultures treat-
ed with Dlm significantly increased at 0.5 μg mL–1, 1 μg mL–
1, and 1.5 µg mL–1 concentrations. The changes in MDA con-
tent were parallel with the changes of H2O2 content for Dlm 
pesticide. The increase of H2O2 content caused the formation 
of OH radicals by the Haber-Weis reaction and therefore 
lipid peroxidation was increased (Goel and Sheoran 2003). 
Moreover, the inhibition of SOD activity caused accumula-
tion of O2– in the medium in deltamethrin application. It is 
known that lipid peroxidation is linked to the amount of O2– 
(Choudhary et al. 2007). Also, Baruah and Chaurasia (2020) 
reported that alpha-cypermethrin decreased the photosyn-
thetic pigment content and it increased the MDA content of 
Chlorella sp. at 6–48 mg L–1 during 96 h bioassay. The reduc-
tion of photosynthetic pigments also increases lipid peroxi-
dation (Chen et al. 2008). A significant reduction of chloro-
phyll-a content may take place with lipid peroxidation at 
Dlm application. It was reported that MDA content, an in-
dicator of lipid peroxidation, was increased by the endosul-

fan application (Kumar et al. 2008). Wang et al. (2011) found 
that cypermethrin enhanced MDA content on Skeletonema 
costatum, Scripsiella trochoidea and Chatonella marina. 

There was no significant change in the MDA content at 
the Cyp application and it was supported by the results of H2O2 
content. Moreover, the increase in the proline content may 
have prevented the cell membrane damage and the amount of 
MDA. Siripornadulsil et al. (2002) reported that the cadmium 
application did not alter the amount of MDA in the proline 
overproducing transgenic Chlamydomonas reinhardtii 
P.A.Dangeard, and they suggested that proline may have in-
hibited free radical damage due to its antioxidant action.

The amount of H2O2 in A. platensis cultures exposed to 
the Dlm significantly increase with addition of 1 μg mL–1, 1.5 
μg mL–1, and 2 μg mL–1 Dlm. It was expected that the appli-
cation of Dlm pesticide would result in a decrease in the H2O2 
content with the increase of SOD enzyme activity, but the 
H2O2 content likely increased due to the increased activity of 
oxidases such as glycolate oxidase, glucose oxidase, amino 
acid oxidase and sulfite oxidase in plants (Asada 1999). 

Fig. 6. Malondialdehyde (MDA; a), hydrogen peroxide (H2O2; b) 
and proline (c) contents of Arthrospira platensis treated with 0–2 
µg mL–1 deltamethrin. Data are the means ± SE of three replicates. 
*Significantly different from control, P ˂ 0.05 (LSD analysis).

Fig. 5. Total superoxide dismutase (SOD; a), ascorbate peroxidase 
(APX; b) and glutathione reductase (GR; c) activities of Arthro-
spira platensis treated with 0–2 µg mL–1 deltamethrin. Data are 
the means ± SE of three replicates. *Significantly different from 
control, P ˂ 0.05 (LSD analysis).



OXIDATIVE DAMAGE OF PESTICIDE ON Arthrospira platensis

ACTA BOT. CROAT. 80 (2), 2021 123

The amount of H2O2 in all concentrations of cultures of 
A. platensis exposed to Cyp (except 1 μg mL–1 and 5 μg mL–1) 
was not changed by increased APX enzyme activity. The 
decrease in the amount of H2O2 is likely due to the increase 
in enzymes consuming the H2O2 content, such as the APX 
enzyme (Mallick and Mohn 2000).

The free proline amount of A. platensis cultures exposed 
to Cyp was statistically significantly increased at all concen-
trations compared to the control. Proline accumulation has 
been reported in plants exposed to heavy metal stress (Sara-
dhi and Saradhi 1991). Proline is an effective singlet oxygen 
scavenger and regulates the cell redox potential (Saradhi 
and Saradhi 1991, Alia et al. 2001). Proline acts as an os-
motic regulator and scavenger of OH radical in cells and 
thus it interacts with cell macromolecules such as DNA, 
protein, and lipids and consequently stabilizes the structure 
and function of these molecules (Kavir et al. 2005). The in-
crease of proline content may be an adaptive response under 
extreme stress conditions (Fatma et al. 2007, Kumar et al. 
2014). Proline reduces free radical production under stress 
conditions (Alia 1993). Fatma et al. (2007) studied the ef-
fects of environmental pollution by evaluating proline con-
tent on Westiellopsis prolifica Janet cyanobacterium and 
found that alphamethrin pesticide and heavy metals in-
creased proline accumulation.

The free proline content of A. platensis cultures exposed 
to the Dlm effect was significantly reduced at 2 µg mL–1 con-
centration. Ewald and Schlee (1983) found that sulfide de-
creased the proline content by inhibiting proline synthesis. 
Likewise, Dlm may have inhibited the proline synthesis or 
may have disrupted proline configuration in our Dlm ap-
plication.

In conclusion, in this study, the decrease in biomass and 
chlorophyll-a was related to the concentration of Cyp and 
Dlm. Antioxidant enzyme activities and parameters were 
affected by different degrees according to the particular pes-
ticides and their concentrations. These differences arose 
from the ROS producing capacity of Cyp and Dlm. Also, 
deltamethrin is more toxic than cypermethrin according to 
concentrations. Since these pesticides have a toxic effect on 
aquatic organisms, care should be taken when they are used 
with all necessary precautions to prevent their release into 
the aquatic ecosystem.

Acknowledgement

This study was supported by Sakarya University Re-
search Projects under Grant no. BAP 2017-02-20-001 and 
BAP 2016-02-20-002.

References
Aiba, S., Ogawa, T., 1977: Assessment of growth yield of a blue-

green alga: Spirulina platensis in axenic and continuous cul-
ture. Journal of General Microbiology 102, 179–182.

Alia, S.P.P., 1993: Suppression in mitochondrial electron trans-
port is the prime cause behind stress induced proline accu-
mulation. Biochemical and Biophysical Research Commu-
nications 193, 54–58.

Alia, S.P.P., Mohanty, P., Matysik, J., 2001: Effect of proline on 
the production of singlet oxygen. Amino Acid 21, 195–200.

Anjum, N.A., Umar, S., Chan, M.T., 2010: Ascorbate-glutathione 
pathway and stress tolerance in plants. In: Pang, C.H., Wang, 
P.S. (eds.), Role of ascorbate peroxidase and glutathione re-
ductase, 91–115. Springer Science, New York.

Asada, K., 1999: The water-water cycle in chloroplasts: scaveng-
ing of active oxygens and dissipation of excess photons. An-
nual Review of Plant Physiology and Plant Molecular Biol-
ogy 50, 601–639.

Baeza-Squiban, A., Marano, F., Ronot, X., Adolphe, M., Puiseux-
Dao, S., 1987: Effects of deltamethrin and its commercial 
formulation DECIS on different cell types in vitro: Cytotox-
icity, cellular binding, and intracellular localization. Pesti-
cide Biochemistry and Physiology 28, 103–113.

Baruah, P., Chaurasia, N. 2020: Ecotoxicological effects of alpha-
cypermethrin on freshwater alga Chlorella sp.: Growth in-
hibition and oxidative stress studies. Environmental Toxi-
cology and Pharmacology 76, 103347.

Baublis, A.J., Clydesdale, F.M., Decker E.A., 2000: Antioxidants 
in wheat-based breakfast cereals. Cereals Foods World 45, 
71–74.

Beyer, W.F., Fridovich, I., 1987: Assaying for superoxide dis-
mutase activity: Some large consequences of minor changes 
in conditions. Analytical Biochemistry 161, 559–566.

Bradford, M.M.A., 1976: A rapid and sensitive method for the 
quantitation of microgram quantities of protein utilizing the 
principle of protein-dye binding. Analytical Biochemistry 
72, 248–254.

Bray, E.A., Bailey-Serres, J., Weretilnyk, E., 2000: Biochemistry 
and Molecular Biology of Plants. In: Gruissem, W., Jones, R. 
(eds.), Responses to abiotic stress, 1158–1203. American So-
ciety of Plant Physiologists, Rockville.

Burkiewicz, K., Synak, R., Tukaj, Z., 2005: Toxicity of three in-
secticides in a standard algal growth inhibition test with 
Scenedesmus subspicatus. Bullettin of Environmental Con-
tamination and Toxicolology 74, 1192–1198.

Caquet, T., Thybaud, E., Le Bras S., Jonot, O., Ramade F., 1992: 
Fate and biological effects of lindane and deltamethrin in 
freshwater mesocosms. Aquatic Toxicology 23, 261–277.

Chen, T.F., Zheng, W.J., Wong, Y.J. Yang, F., 2008: Selenium-in-
duced changes in activities of antioxidant enzymes and con-
tent of photosynthetic pigments in Spirulina platensis. Jour-
nal of Integrative Plant Biology 50, 40–48.

Chew, O., Whelan, J., Millar, A.H., 2003: Molecular definition 
of the ascorbate-glutathione cycle in Arabidopsis mitochon-
dria reveals dual targeting of antioxidant defenses in plants. 
The Journal of Biological Chemistry 278, 46869–46877.

Choudhary, M., Jetley, U. K., Khan, M. A., Zutshi, S., & Fatma, 
T. 2007: Effect of heavy metal stress on proline, malondial-
dehyde, and superoxide dismutase activity in the cyanobac-
terium Spirulina platensis-S5. Ecotoxicology and environ-
mental safety, 66(2), 204–209.

Dewez, D., Geoffroy, L., Vernet, G., Popovic, R., 2005: Determi-
nation of photosynthetic and enzymatic biomarkers sensitiv-
ity used to evaluate toxic effects of copper and fludioxonil in 
alga Scenedesmus obliquus. Aquatic Toxicology 74, 150–159.

Elliott, M., 1995: Chemicals in insect control. In: Casida, J.E., 
Quistad G.B. (eds.), Pyrethrum flowers: production, chem-
istry, toxicology, and uses, 3–31. Oxford University Press, 
New York.

Ewald, D., Schlee, D., 1983: Biochemical effects of sulphur diox-
ide on proline metabolism in the alga Trebouxia sp. New 
Phytology 94, 235–240.

Fatma, T., Khan, A., Choudhary, M., 2007: Impact of environ-
mental pollution on cyanobacterial proline content. Journal 
of Applied Phycology 19, 625–629.



TUNCA H., HÖDÜK K., KÖÇKAR F., DOĞRU A., SEVINDIK O. T.

124 ACTA BOT. CROAT. 80 (2), 2021

Goel, A., Sheoran, I.S., 2003: Lipid peroxidation and peroxide-
scavenging enzymes in cotton seeds under natural ageing. 
Biologia Plantarum 46, 429–434.

Hideg, E., Vass, I., 1996: UV-B induced free radical production 
in plant leaves and isolated thylakoid membranes. Plant Sci-
ence 115, 251–260.

Heath, R.L, Packer, L., 1968: Photoperoxidation in isolated chlo-
roplasts. I. Stoichiometry of fatty acid peroxidation. Archives 
of Biochemistry and Biophysics 125, 189–198.

Johri, A.K., Saxena, D.M., Lal, R., 1997: Interaction of synthetic 
pyrethroids with micro-organisms: a review. Microbios 89, 
151–156.

Kavir, K.P.B., Sangam, S., Amrutha, R.N., Laxmi, P.S.N.K.R., 
2005: Regulation of proline biosynthesis, degradation, up-
take and transport in higher plants: Its implications in plant 
growth and abiotic stress tolerance. Current Science 88(3), 
424–438.

Kishor, P. K., Sangam, S., Amrutha, R.N., Laxmi, P. S., Naidu, 
K.R., Rao, K.S., Sreenath Rao, Reddy, K.J., P. Theriappan P., 
Sreenivasulu, N., 2005: Regulation of proline biosynthesis, 
degradation, uptake and transport in higher plants: its im-
plications in plant growth and abiotic stress tolerance. Cur-
rent Science, 88, 424–438.

Kumar, M.S., Habib, K.,  Fatma, T. 2008: Endosulfan induced 
biochemical changes in nitrogen-f i xing cyanobacte-
ria. Science of the Total Environment, 403(1–3), 130–138.

Kumar, S., Praveenkumar, R., Jeon, B.H., Thajuddin, N., 2014: 
Chlorpyrifos-induced changes in the antioxidants and fatty 
acid compositions of Chroococcus turgidus NTMS12. Letters 
of  Applied Microbiology 59 (5), 535–541

Li, X., Ping, X., Xiumei, S., Zhenbin, W., Liqiang, X., 2005: Tox-
icity of cypermethrin on growth, pigments, and superoxide 
dismutase of Scenedesmus obliquus. Ecotoxicology and En-
vironmental Safety 60, 188–192.

Lutnicka, H., Fochtman, P., Bojarski, B., Ludwikowska, A., For-
micki, G., 2014: The influence of low concentration of cyper-
methrin and deltamethrin on phyto- and zooplankton of 
surface waters. Folia Biologica 62, 251–257.

MacKinney, G., 1941: Absorption of light by chlorophyll solu-
tion. The Journal of Biological Chemistry 140, 315–322.

Mallick, N., Mohn, F.H., 2000: Reactive oxygen species: response 
of algal cells. Journal of Plant Physiology 157, 183–193.

Megharaj, M., Venkateswarlu, K., Rao, A.S., 1987: Influence of 
cypermethrin and fenvalerate on a green alga and three cya-
nobacteria isolated from soil. Ecotoxicology and Environ-
mental Safety 14, 142–146.

Mittal, P.K., Adak, T., Sharma, V.P., 1994: Comparative toxicity 
of certain mosquitocidal compounds to larvivorous fish, 
Poecilia reticulata. Indian Journal of Malariology 31, 43–47.

Netrawali, M.S., Gandhi, S.R., 1990: Mechanism of cell destruc-
tive action of organophosphorus insecticide phosalone in 
Chlamydomonas reinhardtii algal cells. Bulletin of Environ-
mental Contamination and Toxicology 44, 819–825.

Sáenz, M.E., Marzio, W.D.D., Alberdi, J.L., 2012: Effects of a 
commercial formulation of cypermethrin used in biotech 
soybean crops on growth and antioxidant enzymes of fresh-
water algae. Journal of Environmental Protection 2, 15–22.

Saradhi, A., Saradhi, P.P., 1991: Proline accumulation under 
heavy metal stress. Journal of Plant Physiology 138, 554–558.

Sgherri, C.L.M, Loggini B., Puliga S., Navari-Izzo F., 1994: An-
tioxidant system in Sporobolus stapfianus: changes in re-
sponse to desiccation and rehydration. Phytochemistry 35, 
561–565.

Siripornadulsil, S., Traina, S., Verma, D.P.S., Sayre, R.T., 2002: 
Molecular mechanisms of proline-mediated tolerance to tox-
ic heavy metals in transgenic microalgae. Plant Cell 14, 
2837–2847.

Teisseire, H., Vernet, G., 2001: Effects of the fungicide folpet on 
the activities of antioxidative enzymes in duckweed (Lemna 
minor). Pesticide Biochemistry and Physiology 69, 112–117.

Tremolada, P., Finizio, A., Villa, S., Gaggi, C., Vighi, M., 2004: 
Quantitative inter-specific chemical activity relationships of 
pesticides in the aquatic environment. Aquatic Toxicology 
67, 87–103.

Valentine, W.M., Amarnath, V., Amarnath, K., Erve, J.C.L., Gra-
ham, D.G., Morgan, D.L., Sills, R.C., 1998: Covalent modifi-
cation of hemoglobin by carbon disulfide: a potential bio-
marker of effect. Neurotoxicology 19, 99–107.

Verma, S., Dubey, R.S., 2003: Lead toxicity induces lipid peroxi-
dation and alters the activities of antioxidant enzymes in 
growing rice plants. Plant Science 164, 645–650.

Wang, S.Y., Jiao, H., Faust, M., 1991: Changes in ascorbate, gluta-
thione and related enzyme activity during thidiazuron-in-
duced bud break of apple. Physiology Plantarum 82, 231–236.

Wang, Z., Xie, J., Jiang, S., Shi, J., Liu, Y., Gong, W., 2012: Effects 
of commercial cypermethrin on the growth of Scenedesmus 
obliquus and its physiochemical responses. China Environ-
mental Science 32, 659–665.

Wang, Z.H., Nie, X.P., Yue, W.J., 2011: Toxicological effects of cy-
permethrin to marine phytoplankton in a co-culture system 
under laboratory conditions. Ecotoxicology 20, 1258–1267.

Weimberg, R., Lerner, H.R, Poljakoff‐Mayber, A., 1982: A rela-
tionship between potassium and proline accumulation in 
salt‐stressed Sorghum bicolor. Physiology Plantarum 55, 5–10.

Xiong, L., Wu, Z., Kuang, Q., Xia, Y., He, F., 2002: Studies on the 
toxicity of cypermethrin to Scenedesmus obliquus. Acta Hy-
drobiologica Sinica 26, 66–73.