ACTA BOT. CROAT. 81 (2), 2022 213

Acta Bot. Croat. 81 (2), 213–220, 2022   CODEN: ABCRA 25
DOI: 10.37427/botcro-2022-019 ISSN 0365-0588
 eISSN 1847-8476

 

Exogenous arginine treatment additively enhances 
growth and tolerance of Salicornia europaea 
seedlings under salinity
Fereshteh Shakhsi-Dastgahian1, Jafar Valizadeh1, Monireh Cheniany2, Alireza Einali1*

1 University of Sistan and Baluchestan, Faculty of Science, Department of Biology, Zahedan, Iran
2 Ferdowsi University of Mashhad, Faculty of Science, Department of Biology, Mashhad, Iran

Abstract – The effects of foliar application of 5 mM arginine (Arg) on the growth and control of salinity-induced os-
motic and oxidative stresses (0, 200, 400 and 600 mM NaCl) in Salicornia europaea seedlings were investigated. De-
spite higher levels of lipid peroxidation, lower membrane stability index (MSI), decreased pigment content and phe-
nolic compounds, and reduced activity of antioxidant enzymes observed under salinity, seedling growth indices, 
including plant height and biomass, increased significantly, and some protective and antioxidant molecules such as 
proline and flavonoids accumulated. Soluble protein level increased at the low salt concentration (200 mM) but de-
creased at other doses. Exogenous Arg treatment alone had less or no effect on plant biomass and other metabolites, 
but in combination with salt, further enhanced growth parameters, MSI and accumulation of soluble protein, pheno-
lic compounds and proline. Arg-induced changes under salinity were associated with decreased lipid peroxidation, 
flavonoids content and antioxidant enzymes activity. These results show that S. europaea seedlings are well tolerant to 
applied salt doses. The treatment with exogenous Arg alone affects plant growth slightly, but in combination with salt, 
synergistically increases growth and salt tolerance of these plants by enhancing the accumulation of proline and anti-
oxidant molecules instead of enzymatic antioxidant.

Keywords: arginine, lipid peroxidation, Salicornia europea, salinity, proline 

Introduction
In arid and semi-arid regions, lack of rainfall and high 

temperatures have increased soil salinity. Because most 
plants are sensitive to high salt contents, their growth and 
yield are affected by the osmotic and oxidative stresses in-
duced by saline soils (Li et al. 2011, Wu et al. 2012). Produc-
tion of reactive oxygen species (ROS) due to oxidative stress 
is an inevitable process in plants exposed to salt and other 
environmental stresses (Allen 1995, Garg and  Manchanda 
2009). Increased ROS levels under salinity stress damage 
plant metabolism and destroy cell membrane lipids and 
proteins as well as other biomacromolecules (Bor et al. 
2003, Gill and Tuteja, 2010), which subsequently alters se-
lective membrane permeability and causes the material to 
leak out of the cell (Weckx and Clijsters 1997). In saline  areas, 
one of the best ways to reduce the harmful effects of salin-
ity and increase productivity is to cultivate salt-resistant 
plants (Oba et al. 2001). Many halophyte plants can grow in 
saline soils due to changes in their energy metabolism 

(Winicov and Bastola 1997). The salinity tolerance mecha-
nisms of halophytes are not well understood but may be 
due in part to the synthesis of proline and other osmolytes, 
ion homeostasis, and the activity of the antioxidant de-
fense system to scavenge ROS (Hasegawa et al. 2000). 

L-arginine (Arg) is one of the proteinogenic amino acids 
of plant cells, which is a precursor to the synthesis of pro-
line, polyamines, and nitric oxide (Liu et al. 2006). Arg 
treatment improved chlorophyll synthesis and photosyn-
thesis and prevented chlorophyll degradation and ageing 
(Zeid 2009, Mostafa et al. 2010). Exogenously applying Arg 
in plants exposed to environmental stresses upregulated 
antioxidant enzymes (Barand et al. 2015) and induced the 
accumulation of compatible solutes (Ramadan et al. 2019). 

Salicornia europea L. is a halophyte plant that is widely 
distributed in coastal areas and salt marshes (Davy et al. 
2001). Because it can survive in salt concentrations that are 
toxic to most plants, Salicornia is known as a salt-tolerant 
plant species (Flowers and Colmer 2008, Patel 2016). It is 
taken not only as a model species for salinity research, but 

* Corresponding author e-mail: aeinali@science.usb.ac.ir

mailto:aeinali@science.usb.ac.ir


SHAKHSI-DASTGAHIAN F., VALIZADEH J., CHENIANY M., EINALI A.

214 ACTA BOT. CROAT. 81 (2), 2022

it has also recently been considered as a potential food and 
pharmaceutical plant due to the accumulation of suitable 
nutrients such as polyphenols, fibres, and flavonoids (Patel 
2016). Despite some studies on salt stress and the role of Arg 
in its tolerance (Nejadalimoradi et al. 2014, Ramadan et al. 
2019), there is no report on the possible effects of this amino 
acid on salt stress tolerance in Salicornia. Therefore, the 
present work aimed to evaluate the impact of exogenous Arg 
on the growth and control of osmotic and oxidative stress-
es caused by salinity in S. europea.

Materials and methods
Plant materials and experimental design

Uniform seeds of Salicornia europaea L. were obtained 
from the Pakan Bazr Company at Esfahan. Seeds soaked in 
tap water for 12 h were planted in trays filled with wet co-
copeat and placed at 28 ± 1 °C to germinate. The 4 to 5 cm 
seedlings were transferred to plastic pots (two seedlings per 
pot) containing 1 kg of well-watered cocopeat-perlite (2:1) 
in a phytotron at 25 °C, a relative humidity of 60%, and a 
photoperiod of 16 h light/ 8 h dark. The seedlings were fed 
with 1/2 Hoagland’s nutrient solution at three-day intervals 
until their length reached 20 to 23 cm. Three days before 
salinity treatment, the seedlings were divided into two 
groups of 20 pots containing 40 seedlings. One group was 
treated with foliar application of 5 mM Arg, and the other 
group was left untreated and just received distilled water. 
Both groups were exposed to four levels of NaCl (0, 200, 400, 
and 600 mM) by the addition of salt to the 1/2 Hoagland’s 
nutrient solution. Salt and Arg treatments were applied to 
seedlings at three-day and six-day intervals for up to 30 
days, respectively. Seedlings were then harvested and evalu-
ated for morphological and biochemical responses to salin-
ity and Arg treatments. All studies were independently re-
peated using separate seedlings at least three times for each 
morphological and biochemical analysis.

Assessment of morphological traits and membrane 
stability index (MSI)

The measured weight characteristics included fresh 
weight (FW) and dry weight (DW) of both shoot and root, 
and longitudinal traits included shoot and root length.

MSI was determined according to Sairam and Saxena 
(2000). Two samples of fresh shoot tissue (0.1 g) were placed 
separately in a test tube containing 10 ml of distilled water. 
One sample was heated in a water bath at 40 °C for 30 min, 
and the other sample was boiled at 100 °C for 10 min. After 
determination of the electrical conductivity (EC) of the 
samples, MSI was calculated by the following formula:

MSI=1-(EC40/EC100) × 100

Determination of photosynthetic pigments

Chlorophyll (Chl) and carotenoids (Car) were extracted 
from 0.1 g of fresh shoot tissue with 2 ml of 95% (v/v) etha-
nol. The extracts were filtered through a Whatman No.1 
filter paper, and their absorbance was read at 664, 648, and 

470 nm to measure Chl a, Chl b, and Car, respectively 
( Lichtenthaler and Buschmann 2001). Total Chl was 
 obtained from the sum of Chl a and Chl b. Pigment contents 
were expressed in mg per g fresh weight.    

Enzyme extraction and assay

Fresh shoot tissue (0.1 g) was ground in liquid nitrogen 
and homogenized with 1 ml of enzyme extraction buffer 
containing 100 mM cold potassium phosphate buffer (pH 
7.4), 1 mM EDTA, 5 mM ascorbate, 50 mM 2-mercaptoeth-
anol, and 1% (w/v) polyvinylpolypyrrolidone (PVPP). The 
homogenate was filtered through three layers of cheesecloth 
and centrifuged at 12,000 g for 10 min at 4 ºC. Decoloration 
of the extract was done by adding 10 mg of charcoal before 
centrifugation. The 12,000 g supernatant was used for en-
zyme assay and soluble protein determination. Soluble pro-
tein content was determined by Bradford’s method (1976) 
using bovine serum albumin (BSA) as a standard. 

Ascorbate peroxidase (APX) activity was determined 
spectrophotometrically by measuring the generation rate of 
dehydroascorbate in a reaction mixture (1 ml) containing 
50 mM potassium phosphate buffer (pH 7.0), 1 mM H2O2, 
0.5 mM ascorbic acid, and enzyme extract at 290 nm, as-
suming an extinction coefficient of 2.8 mM-1 cm-1 (Chen and 
Asada 1992). 

Peroxidase (POX) activity was determined by evaluat-
ing the rate of guaiacol oxidation in an assay mixture (1 ml) 
containing 50 mM potassium phosphate buffer (pH 7.0), 5 
mM guaiacol, 1 mM H2O2, and enzyme extract at 470 nm, 
using an extinction coefficient of 26.6 mM-1 cm-1 (Srinivas 
et al. 1999).

The assay of polyphenol oxidase (PPO) was done ac-
cording to the rate of purpurogallin production in 1 ml of 
a reaction mixture containing 50 mM potassium phosphate 
buffer (pH 7.0), 40 mM pyrogallol, and enzyme extract. The 
assay mixture was monitored at 430 nm, and the activity of 
the enzyme was calculated using the extinction coefficient 
of 2.47 mM-1 cm-1 (Nakano and Asada 1981). 

Determination of total phenolic and flavonoid contents

Phenol compounds were determined by the method of 
Singleton et al. (1999) with some modifications (Einali et al. 
2018) using gallic acid as the standard.  

Total flavonoids were measured according to Krizek et 
al. (1998). Fresh shoot tissue (0.1 g) was extracted with 1 ml 
of acidified ethanol (ethanol: acetic acid, 99:1, v/v). The ex-
tract was centrifuged at 5,000 g for 10 min, and the absor-
bance of the resultant supernatant was recorded at 300 nm 
after heating at 80 °C for 10 min. Total flavonoid content 
was expressed as absorbance per mg of shoot tissue FW.  

Other analytical methods

Proline content was estimated according to Bates et al. 
(1973) using proline as a standard. The level of lipid per-
oxidation was determined by measuring malondialdehyde 
(MDA) content as described by Heath and Packer (1968), 
assuming an extinction coefficient of 155 Mm-1cm-1.



ARGININE ENHANCES TOLERANCE OF SALICORNIA EUROPAEA

ACTA BOT. CROAT. 81 (2), 2022 215

Statistical analysis

All data were expressed as the mean ± standard error 
(SE) of triple analyses. Normality and equal variance were 
also tested. Statistically significant differences were deter-
mined in a factorial design by a two-way analysis of variance 
(ANOVA) at P < 0.05 using the Duncan method.

Results
Effect of exogenous Arg on plant growth and membrane 

stability during salt treatment
Salt and Arg treatments alone or in combination in-

creased the apparent growth of S. europaea seedlings (Tab. 
1, On-line Suppl. Fig. 1). Both shoot and root lengths were 

Tab. 1. Exogenous effect of 5 mM arginine (Arg) on plant longitudinal characteristics, plant biomass and membrane stability index 
(MSI) of Salicornia europaea seedlings under different concentrations of salinity. Each value is the mean ± SE of three independent 
measurement from three separate seedlings and the different letters in each column indicate significant differences among the various 
treatments at P < 0.05 according to the Duncan test. 

MSI (%)Dry weight (g)Fresh weight (g)Root length 
(cm)

Shoot length 
(cm)

Arginine 
treatment

Salt treatment 
(mM) RootShootRootShoot

48.30±4.10a0.018±0.001e0.01±0.002g0.23±0.03c1.23±0.09f9.97±0.61d13.70±0.87c-Arg0

51.10±6.30a0.029±0.002d0.04±0.003c0.25±0.07c2.76±0.28c13.00±0.93c16.90±2.24c+Arg

43.70±1.30b0.021±0.004e0.02±0.003f0.57±0.06b1.88±0.33e11.97±1.05c16.00±2.00c-Arg200

46.80±2.60ab0.035±0.003d0.04±0.002bc0.29±0.06c3.63±0.23b15.60±0.80b23.30±1.31b+Arg

42.10±3.30b0.032±0.005d0.03±0.003d0.59±0.10b2.22±0.16e14.43±1.62b21.57±2.79b-Arg400

45.20±1.20b0.060±0.002a0.05±0.003a0.26±0.03c4.80±0.24a17.77±0.38a27.43±1.67a+Arg

18.80±2.10c0.042±0.003c0.03±0.003e0.96±0.10a2.68±0.19d14.03±1.04b19.80±1.91b-Arg600

44.70±4.40b0.053±0.004b0.04±0.004ab0.22±0.08c3.39±0.25b15.77±0.94b22.70±2.35b+Arg

Fig. 1. Changes in the content of the photosynthetic pigments of Salicornia europaea seedlings under salinity treated with or without 
5 mM Arg. (A) Chl a, (B) Chl b, (C) Total Chl, (D) Chl a/b, (E) Total Car, and (F) Chl/Car ratio. Data are mean ± SE of three independent 
experiments from three separate seedlings, and the different letters indicate significant differences among the various treatments at P 
< 0.05 according to the Duncan test.



SHAKHSI-DASTGAHIAN F., VALIZADEH J., CHENIANY M., EINALI A.

216 ACTA BOT. CROAT. 81 (2), 2022

positively affected by salinity in a concentration-dependent 
manner. The highest increase in length was found in seed-
lings treated with a concentration of 400 mM NaCl. Arg 
treatment showed a significant effect on improving plant 
height either alone or in combination with salinity. How-
ever, shoot and root height remained statistically unchanged 
in Arg-treated seedlings grown at 600 mM NaCl compared 
to untreated controls (Tab. 1). 

The fresh and dry weight of seedlings increased in re-
sponse to salt treatment in shoot and root. Plant biomass and 
shoot fresh weight were positively changed by Arg treatment 
alone or in combination with salinity. However, fresh weight 
of root in Arg-treated seedlings remained unchanged or was 
drastically decreased compared to untreated controls (Tab. 1).

Salt treatment alone reduced MSI at all concentrations, 
especially in seedlings treated with 600 mM NaCl. Arg 
treatment alone or in combination with salinity up to 400 
mM did not affect MSI but greatly improved this index in 
seedlings treated with 600 mM NaCl (Tab. 1).

Effect of exogenous Arg on plant pigments during salt 
treatment

Salt treatment at all concentrations significantly reduced 
the photosynthetic pigments of S. europaea seedlings (Fig. 
1). Arg treatment alone did not change Chl a content, but 
its effect in combination with salinity depended on the salt 
concentration (Fig. 1A). In contrast, Arg treatment alone 
significantly reduced Chl b levels but had no effect when 
 applied in combination with salinity (Fig. 1B). Total Chl 
 content was positively affected by Arg treatment only in 
seedlings grown at 200 mM NaCl (Fig. 1C). The Chl a/b 
 ratio increased in response to both salinity and Arg treatments 
(Fig. 1D). However, this ratio decreased in Arg-treated 
 seedlings grown in 600 mM NaCl.

Arg treatment enhanced carotenoid content in 200 mM 
NaCl-grown seedlings but did not change it when applied 
alone or in combination with other salinities (Fig. 1E). The 
Chl / Car ratio was affected by 200 mM NaCl but not by 
other salt concentrations. Arg treatment alone or in combi-
nation with 200 mM NaCl reduced this ratio but was not 
effective at other salt doses (Fig. 1F).

Effect of exogenous Arg on plant phenolics during salt 
treatment

Salt treatment at all concentrations caused a significant 
reduction in the total phenol concentration of S. europaea 
seedlings (Fig. 2A). Arg treatment alone decreased phenol 
content, while it was effective in a salt-dependent manner 
when applied to seedlings grown at different salinity concen-
trations. In contrast, the flavonoid content of seedlings grown 
at 400 and 600 mM NaCl enhanced compared to the control 
(Fig. 2B). While Arg treatment reduced the level of seedling 
flavonoids exposed to the mentioned salt doses, it was ineffec-
tive when used alone or with 200 mM NaCl (Fig. 2B).

Effect of exogenous Arg on proline, soluble protein and 
lipid peroxidation during salt treatment

The proline content in seedlings grown at salinity up to 
400 mM remained statistically unchanged but increased 
significantly in response to 600 mM NaCl (Fig. 3A). Arg 

Fig. 2. Changes in total phenol (A) and total flavonoid (B) contents 
of Salicornia europaea seedlings under salinity treated with or 
without 5 mM arginine (Arg). Values are mean ± SE of three in-
dependent experiments from three separate seedlings. The differ-
ent letters show significant differences among the various treat-
ments at P < 0.05 according to the Duncan test.

Fig. 3. Changes in proline (A), soluble protein (B), and malondial-
dehyde (MDA) (C) contents of Salicornia europaea seedlings under 
salinity treated with or without 5 mM arginine (Arg). Data are mean 
± SE of three independent experiments from three separate seed-
lings. The different letters indicate significant differences among the 
various treatments at P < 0.05 according to the Duncan test.



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ACTA BOT. CROAT. 81 (2), 2022 217

treatment alone did not change proline levels, whereas this 
metabolite was highly accumulated when combined with 
salt. Arg-treated seedlings grown in 600 mM NaCl showed 
more than 4-fold proline accumulation than untreated con-
trols (Fig. 3A).

Soluble protein concentration increased in 200 mm 
NaCl-grown seedlings but decreased in seedlings fed higher 
doses of salt. Protein content was not affected by Arg treat-
ment alone or with salt up to 400 mM, whereas when com-
bined with 600 mM NaCl, it changed positively (Fig. 3B).

Lipid peroxidation was increased by salinity in a dose-
dependent manner. Arg treatment increased the MDA con-
tent in seedlings nourished with salt-free medium but de-
creased it in plants grown in combination with salt (Fig. 3C).

Changes in enzyme activities in Arg-treated seedlings 
during salt treatment

The activities of APX, POX and PPO in S. europaea 
seedlings were negatively changed by salt treatments (Fig. 
4). Exogenous Arg treatment highly decreased the APX ac-
tivity of salt-treated or salt-untreated seedlings (Fig. 4A). 
However, POX activity of seedlings treated with Arg alone 
or in combination with salinity up to 400 mM remained 
roughly unchanged but decreased abruptly in seedlings 

growing at 600 mM NaCl compared to untreated controls 
(Fig. 4B). In contrast, PPO activity was positively affected 
by Arg treatment alone or in combination with salt (Fig. 4C).   

Discussion
In contrast to the destructive effects of salinity on plant 

growth and biomass in most plants (Qiu et al. 2014, Ahmad 
et al. 2018, Ghanem et al. 2021), our results showed that sa-
linity could have a positive effect on height, fresh weight, and 
biomass of S. europaea seedlings. Similarly, the maximum 
growth of another Salicornia species (S. dolichostachya) was 
observed at 300 mM NaCl (Katschnig et al. 2013), which is 
consistent with our results. Arg treatment alone or with salt 
has an additive effect on plant growth and biomass. This 
agrees with most studies showing that foliar spraying of 
mung bean (Qados 2010), wheat (Mostafa et al. 2010), and 
sunflower (Nejadalimoradi et al. 2014, Ramadan et al. 2019) 
with Arg increased the growth of these plants under salin-
ity stress. The ameliorative effect of Arg on plant growth 
under salinity has been attributed to its role as a precursor 
of polyamines (Mostafa et al. 2010) or as a source of nitric 
oxide (NO) (Ramadan et al. 2019). However, the negative ef-
fect of Arg on root FW during salinity was noticeable. In 
contrast to the synergic effects of Arg and salinity on plant 
growth, root FW showed an antagonistic relationship be-
tween Arg and salinity treatments. Due to the enhancement 
effect of Arg and salt treatments on root biomass, this dimin-
ishing effect may refer to the potential for water maintenance 
in root tissues of salt-treated seedlings in the presence of Arg.

Reduction of photosynthetic pigments of S. europaea oc-
curred under salt treatment, which is consistent with other 
studies (Zeid 2009, Ramadan et al. 2019, Ghanem et al. 
2021). The decrease in pigment content under salinity can 
be attributed to their degradation by free radicals generated 
during stress (Ma et al. 2020) or activation of chlorophyll 
catabolic processes along with inhibition of biosynthetic en-
zymes (Rady et al. 2015). Unlike other studies (Zeid 2009, 
Ramadan et al. 2019), Arg treatment alone did not affect or 
decrease the pigment content of S. europaea seedlings. The 
positive effect of Arg on pigment content was observed on-
ly with 200 mM NaCl. This implies that Arg does not change 
photosynthetic pigments under high salinities. Thus, the 
improvement in the growth of Arg-treated seedlings under 
salinity is not directly related to photosynthetic pigments 
but may be due to the increased photosynthetic capacity 
through maintaining chloroplast structure. The reduction 
of lipid peroxidation during salinity due to Arg treatment 
associated with an increase in MSI could further support 
this suggestion.

One of the effects of salinity is lipid peroxidation, which 
occurs in plants both sensitive to and tolerant of salinity, 
due to oxidative damage, although its severity is higher in 
salt-sensitive plants (Kumar et al. 2020). Accumulation of 
MDA, as an indicator of lipid peroxidation, in S. europaea 
seedlings under salinity was associated with a decrease in 
MSI, which indicates the destructive effect of salt. However, 

Fig. 4. Changes in the activity of ascorbate peroxidase (APX) (A), 
peroxidase (POX) (B), and polyphenol oxidase (PPO) (C) of Salicornia 
europaea seedlings under salinity treated with or without 5 mM 
arginine (Arg). Results are mean ± SE of three independent 
 experiments from three separate seedlings. The different letters 
show significant differences among the various treatments at P < 0.05 
according to the Duncan test.



SHAKHSI-DASTGAHIAN F., VALIZADEH J., CHENIANY M., EINALI A.

218 ACTA BOT. CROAT. 81 (2), 2022

these seedlings had a higher growth in the presence of salt, 
showing that they can tolerate these salinity concentrations 
well. Arg treatment in combination with salt but not alone, 
caused less lipid peroxidation and increased MSI. Similar 
results were reported in canola seedlings treated with Arg 
under salinity (Nasibi et al. 2014). This indicates that Arg 
enhances salt tolerance in S. europaea. To counteract the 
oxidative damage caused by abiotic stress, plants use de-
fense mechanisms, including the accumulation of Osmo 
protectants and non-enzymatic compounds along with an-
tioxidant enzymes (Ali et al. 2017, Polash et al. 2019). Pro-
line is a compatible solute that acts as an Osmo protectant, 
stabilizer and protector of membranes, enzymes, and pro-
teins, and scavenger of free radical (Ashraf and Foolad 2007, 
Kumar et al. 2020). As recently demonstrated (Ghanem et 
al. 2021), the increase in proline during salt treatments of S. 
europaea seedlings indicates the strategy of these plants in 
salt tolerance. Accumulation of proline in seedlings treated 
with Arg under salinity can be related to the positive effects 
of this amino acid on the production of proline, NO and 
polyamines (Liu et al. 2006). Thus, a more than fourfold in-
crease in the proline content of Arg-treated seedlings ex-
posed to 600 mM NaCl could explain a decrease in lipid 
peroxidation versus an increase in MSI in these plants.

Polyphenols and flavonoids, as antioxidant molecules, 
play an important role in scavenging free radicals by them-
selves and inducing antioxidant enzymes (Kofroňová et al. 
2020). Our results showed that the content of total phenols 
decreases, but the flavonoids increase during salinity. How-
ever, increases in both polyphenols and flavonoids have 
been reported in plants under salt stress (Lim et al. 2012, 
Sarker et al. 2019). The phenolics changes during salinity 
were associated with a decrease in PPO activity, which can 
be related to salt tolerance. This is consistent with studies 
showing that decreased PPO activity is associated with 
stress tolerance (Thipyapong et al. 2004, Sofo et al. 2005). It 
indicates that among phenolic compounds, flavonoids may 
have a role in S. europaea tolerance to salinity. In contrast, 
Arg treatment combined with salinity had an additive effect 
on total phenols but decreased flavonoids content along 
with an increase in PPO activity. Considering the role of 
Arg in enhancing the growth of S. europaea seedlings under 
salinity, Arg treatment probably induces the production of 
phenolic compounds other than flavonoids to scavenge free 
radicals. It means that Arg with salt can change the pattern 
of phenolic production with PPO activity to induce high salt 
tolerance. This result in conflict with PPO activity points to 
the unclear role for the enzyme in stress tolerance, as re-
ported previously (Boeckx et al. 2015).

The soluble protein content of S. europaea increased 
at 200 mM NaCl but decreased under more salt concentra-
tions (400 and 600 mM). This is consistent with previous 
reports of Pisum sativum (Velitcukova and Fedina 1998) 
and tomato (Manan et al. 2016) under salt stress, indicat-
ing a decrease in soluble protein levels due to inhibition of 
protein biosynthesis or increased protein degradation 
(Mersie and Singh 1993). Arg treatment increased the pro-

tein levels of seedlings fed with 600 mM NaCl. The posi-
tive effect of Arg on the increase of soluble proteins, which 
has also been reported in Lupinus termis under salinity 
( Akladious and Hanafy 2018), refers to the synthesis of 
 specific proteins that are involved in the salinity tolerance 
of plants (Qados, 2010).

In contrast to the findings of most studies (Ali et al. 2017, 
Polash et al. 2019, Kumar et al. 2020), in this research the 
activity of antioxidant enzymes, such as APX and POX as 
H2O2-decomposing enzymes in S. europaea seedlings de-
creased or remained unchanged in response to different salt 
concentrations. Similarly, Arg treatment decreased APX ac-
tivity at all salinities but reduced POX at only 600 mM 
 NaCl. Since Arg is involved in the production of proline, 
NO and polyamines (Liu et al. 2006), its protective effect, 
increasing salt tolerance in S. europaea seedlings, can be at-
tributed to the subsequent metabolism of this amino acid. 
There are two lines of evidence that support this suggestion. 
First, the positive effect of Arg on proline accumulation, es-
pecially in 600 mM NaCl, confirms the role of Arg in induc-
ing proline biosynthesis. The second line of evidence comes 
from a study showing that the protective effect of Arg on 
sunflower seedlings under salt stress may be due to the re-
lease of NO from Arg (Nejadalimoradi et al. 2014). How-
ever, in contrast to this report, our results show that Arg 
treatment decreased the activity of APX and POX in seed-
lings under salinity. Therefore, the role of Arg in enhancing 
the salt tolerance of this plant may be related to proline ac-
cumulation.

In the current study, salinity per se played a positive role 
in the growth and biomass of root and shoot in S. europaea 
seedlings, demonstrating that they tolerate these salt doses. 
Salt treatment was also associated with increased lipid per-
oxidation and decreased MSI, pigment content and pheno-
lic compounds. Soluble protein content increased at low sa-
linity but decreased under other salt concentrations. While 
the activity of antioxidant enzymes decreases, proline and 
flavonoids accumulate during salinity. Arg treatment alone 
exhibited a slight or no change in seedling growth and me-
tabolite content, but in combination with salt showed a syn-
ergistic effect on enhancing growth parameters, MSI and 
accumulation of soluble protein, phenolic compounds and 
proline. It was associated with decreased lipid peroxidation, 
flavonoids and enzyme activity. It can be concluded that Arg 
treatment alone slightly impresses seedlings growth but 
when combined with salt, evidently plays an additive role 
in increasing salt tolerance of these plants by enhancing the 
accumulation of proline as an osmoprotectant and antioxi-
dant molecules rather than enzymatic antioxidant.

Acknowledgements
We would like to thank the Deputy of Research at the 

University of Sistan and Baluchestan for financial support 
in the form of a grant for an M.Sc. research project.



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ACTA BOT. CROAT. 81 (2), 2022 219

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