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683 
Original Article 

Biosci. J., Uberlândia, v. 34, n. 3, p. 683-696, May/June 2018 

EFFECTS OF NaCl ON PLANT GROWTH AND ANTIOXIDANT ACTIVITIES 

IN FENUGREEK (Trigonella foenum graecum L.) 

 

EFEITOS DO NaCl NO CRESCIMENTO DE PLANTAS E ATIVIDADES 

ANTIOXIDANTES EM FENO-GREGO (Trigonella foenum graecum l.) 
 

Baatour OLFA
1
; Zaghdoudi MAHA

1
; Bensalem NADA

1
; Ouerghi Abidi ZEINEB

1 
1. Unité de Physiologie et Biochimie de la Réponse des Plantes aux contraintes Abiotiques, Département de Biologie, Faculté des 

Sciences de Tunis El Manar, Campus Universitaire, 2092 Tunis, Tunisie. zaghdoudimaha@yahoo.fr 
 

ABSTRACT: Fenugreek is used as a spice, vegetable and a important medicinal crops cultivated throughout the 
world. Since antioxidant properties have been linked to health benefits of natural products, such properties were studied 
salt concentrations (0, 50, 100,150 and 200 mM NaCl) effect on plant growth mineral contents composition, antioxidant 
responses and phenolilc contents. Results showed a reduction of dry weights of leaves stems and roots growth. These 
changes were associated with decreased in water content, K+ and Ca2+ concentrations and a highly increased in Na+ and Cl- 
contents in different organs. Catalase, guaiacol peroxidase activities and total phenolic content significantly increased in 
fenugreek leaves. Data reported here revealed the variation of phenolic compound contents at different organs in the 
presence of salt, who suggested the use of Fenugreek in commercial and economic applications. 
 

KEYWORDS: Fenugreek. Salinity. Antioxidant. Polyphenols. 
 

INTRODUCTION 

 
In order to meet the increasing demand for 

medicinal plants, for the indigenous systems of 
medicine as well as for the pharmaceutical industry, 
many medicinal plants need to be cultivated 
commercially, but soil salinity and other forms of 
pollutions represent serious threats to plant 
production (QURESHI et al. 2005). In this context, 
fenugreek (Trigonella foenum graecum L.), an 
annual herb belonging to family Fabaceae, is 
extensively cultivated in most regions of the world 
for its medicinal value Moradi, 2013. 

In many countries, this species is grown in 
arid and semi-arid regions where high concentration 
of salts is an important characteristic of the soils 
(MORADI, 2013). Soil salinity is one of the major 
abiotic stresses which affect seeds germination 
(MISRA; DWIVEDI, 2004), and cause several 
problems for plant growth (DEMIRAL; TURKAN, 
2006). Although salt stress affects all growth stages 
of a plant, seed germination and seedling growth 
stages are known to be more sensitive for most plant 
species (CUARTERO et al., 2006) 

The salinity, or drought stress, causes a 
serious secondary effect on cells. The effects can be 
direct, as the decreased CO2 availability (CHAVES 
et al., 2009), alterations on photosynthetic 
metabolism (PINHEIRO et al., 2011), or they can 
arise as secondary effects, such as oxidative stress 
and the associated synthesis of ROS as well as 
changes in enzyme and antioxidant metabolism. 
Whether ROS would act as signaling molecules or 

might cause oxidative stress to the tissues depend on 
the refined balance between ROS production, and 
their scavenging. Satisfactory scavenging of ROS 
produced at the same time in environmental stresses 
depends on the action of several non enzymatic as 
well as enzymatic antioxidants in the tissues 
(SHARMA et al., 2012). 

Antioxidant enzymes play a key role in 
plant antioxidative stress (ESFANDIARI et al. 
2007). Some study results showed that both non-
enzymatic and enzymatic antioxidant mechanisms 
responded clearly to temperature and salinity stress, 
suggesting divergent response mechanisms 
(NAGESH BABU; DEVARAJ, 2008). The 
activities of antioxidant enzymes increased plant 
resistance to salinity, which depends heavily on the 
plant species and growth stage (ZHANG et al. 
2016).  

The phenolic (non-enzymatic antioxidant) 
compounds actively participate in the plant 
interactions with its environment in the sense that 
they allow it to respond to various biotic and abiotic 
stresses. These phenolic compounds play an 
important role in the adsorption and neutralization 
of free radicals, singlet oxygen, or the peroxide 
decomposition (KSOURI et al. 2007). 

The fenugreek is known traditionally for its 
therapeutical and medicinal value, because of its 
richness in secondary metabolites that may be its 
means of defence against biotic and/or abiotic. 
However, the salinity may influence the yield of 
these  crops by two opposite effects, increasing the 
concentration of these metabolites in tissues, on the 

Received: 07/04/17 
Accepted: 20/12/17 



684 
Effects of NaCl on plant growth…  OLFA, B. et al. 

Biosci. J., Uberlândia, v. 34, n. 3, p. 683-696, May/June 2018 

one hand, and/or reducing their biomass production 
on the other hand (DE ABREU; MAZZAFERA, 
2005).  

Thus the salt-stressed plants may represent 
potential resources of polyphenols, increasing the 
concentration of these latter in tissues. Nowadays, 
we give an increasing interest to the identification 
and recovery of natural antioxidants of the plant 
origin. Consumers pay more attention to a healthy 
and balanced diet, relying heavily on the use of 
natural preservatives (RAGHAVAN, 2007). 
Therefore, we can hypothesize that the optimal 
performance of polyphenols would be obtained by 
using stress-tolerant species (DE ABREU AND 
MAZZAFERA, 2005). 

This work was conducted to elucidate the 
effects of increasing salinity concentrations on 
physiological, antioxidant activity, composition 
phenolic. The aim of this paper was to determine the 
limits of fenugreek tolerance at high salinity 
concentration. 
 
MATERIAL AND METHODS 

  

Plant materials and treatments 
Seeds of fenugreek (Trigonella foenum-

graecum L) were sterilized with sodium 
hypochlorite and rinsed thoroughly with tap water 
and then with distilled water. To evaluate the effect 
of NaCl on fenugreek, the seeds sown in Petri dishes 
with wet filter paper for germination in the dark at 
25°C. Five days after germination; seedlings were 
transferred into pots containing   nutrient solution of 
Hoagland and Arnon (1940) in a growth room. 
Photoperiod was 16 h with 150 µ mol m-2 s-1 PAR 
at the plant level. Day and night temperature   and    
relative   humidity   regimes    were 22/18°C and 
60/80%, respectively. Fifteen days after 
germination, an initial harvest was performed. Then, 
five   treatments were   started.  In the   first, 
seedlings were cultivated in the same nutrient 
solution and considered as control. In the other 
treatment, 50, 100, 150 and 200 mM NaCl was 
added to the medium.  The final   harvest   was    
performed    after    10    days    of treatment. For 
each   treatment, 8 plants were taken and the fresh 
weights of leaves (leave order 4), stems and   roots 
were   weighed.   The   samples were   then oven-
dried at 70°C for 72 h for the determination of DW 
(DANESHMAND et al. 2010). Besides, fresh  
samples  from  each   plant  were immediately  
frozen  in  liquid  nitrogen  and  stored at -80°C until 
performing biochemical  analysis. 
 

Ions Content 

Main ions were extracted from 25 mg 
samples of dried and ground organs in nitric acid 0.1 
N. Then, K+ and Na+ were assayed by flame 
emission photometry (Jenway, PFP-7, UK) and Ca2+ 
and Mg2+ contents were measured by atomic 
absorption spectrophotometry (Varian, SpectrAA 
220FS, Mulgrave, Australia). For anions, chloride   
was determined   by coulometry (Butcher Cotlove).  
All mineral analyses were performed on HNO3 
extracts. 

 
Phenolic Compounds Analysis 

Leaves were dried in a dark and aerated 
room with a temperature of 25-30 ºC, for two 
weeks. Acetonic leaf extracts, used to determine the 
polyphenol content and antioxidant activities, were 
obtained by magnetic stirring for 30 min of 1 g dry 
organ powder with 10 ml Acetone 80 %. Extracts 
were kept at 4º C for 24 h and filtered through 
Whatman filter paper. This final solution was stored 
at 4º C and used to determine phenolic, flavonoid 
and tannin contents and to estimate non-enzymatic 
antioxidant activities (total antioxidant activity and 
Scavenging ability of DPPH radical). 

 
Total phenolic content 

Total phenolics were assayed using the 
Folin-Ciocalteu reagent, following Singleton et al. 
(1999) method; the method was based on the 
reduction of a phosphowolframate-
phosphomolybdate complex by phenolics to blue 
reaction products and slightly modified by Dewanto 
et al. (2002).  An  aliquot  of  125  µl  of  diluted  
extract  (20%  (v/v))  was added  to 500  µ l  of 
deionized  water  and 125 µ l of F-C reagent. After   
shaking,   the mixture   was   incubated   for 3 min   
at room temperature.  Then, 1250 µ l of 7% Na2CO3   
solution was added. The  volume  obtained  was  
adjusted  to  3 ml  using  distilled  water, mixed 
vigorously,  and held for 90 min at ambient 
temperature.  The absorbance of the solution was 
then measured at 760 nm against a blank. The 
sample was analysed in triplicate and the total 
phenolic content was expressed as mg of gallic acid 
equivalents (GAE) per gram of dry weight through a 
calibration curve range of 50 to 400  µ g ml-1(R2 
=0.99). 

 
Flavonoid Quantification 

Total flavonoids were measured using a 
colorimetric assay developed by  Dewanto  et al. 
(2002) An aliquot  of diluted  sample of leaf extract  
or standard  solution  of (+)-catechin  was added to 
75 µ L NaNO2 solution (70 g l-1 ) and mixed for 6 
min, before adding 0.15 ml AlCl3 (100 g L-1 ). 



685 
Effects of NaCl on plant growth…  OLFA, B. et al. 

Biosci. J., Uberlândia, v. 34, n. 3, p. 683-696, May/June 2018 

After 5 min, 0.5 ml of 1 mol L-1 NaOH solution 
was added.  The final volume was adjusted to 2.5 
ml, thoroughly mixed, and the absorbance of the 
mixture was determined at 510 nm. Total flavonoids 
were expressed as grams of (+)-catechin equivalent 
per kilogram dry weight (g CE kg-1 DW), through 
the calibration curve of (+)-catechin (50 -500 mg 
ml). All samples were analysed in three replications. 

 
Tanin Quantification  

0.05 ml of fenugreek samples extracted in 
non diluted acetone was added to 3 ml of vanilline 
(4%), and 1.5 ml of concentrated H2SO4. 
Absorbance of resulting pink-coloured solution was 
read at 500 nm against extract solvent as a blank 
(ZHISHEN et al. 1999). The amount of total 
condensed tannins is expressed as mg (+)-catechin 
/g DW. 

The calibration curve range was 0 à 500 
µ g.ml-1 de catéchine (R2=0.99). All samples were 
analysed in three replications. 
 

Total protein extraction and enzyme assays 
Leaves from separate plants were ground in 

a mortar with liquid nitrogen, and the powder was 
mixed with 50 mmol l−1 of pH 7.5 phosphate buffer 
containing 1 mmol l−1 EDTA, 1 mmol l-1 
dithiothreitol (DTT), 50ml l−1 glycerol and 50 g l−1 
polyvinylpyrrolidone (PVP), and centrifuged (15 
000 × g, 4ºC, 20 min). After extraction, protein 
concentration was determined according to Bradford 
(Catalase (EC 1.111.1.6) activity was measured 
according to the modified method of Chance and 
Maehly.24 The reaction mixture consisted of 25 
mmol l−1 potassium phosphate buffer (pH 7.0), 30 
mmol l-1 H2O2 and enzyme extract. The 
decomposition of H2O2 was followed by measuring 
the decrease in absorbance at 240 nm. Total 
peroxidase activity (EC 1.111.1.7) was assayed 
using guaiacol as an electron donor, with a reaction 
mixture containing 50 mmol l−1 potassium 
phosphate (pH 7.0), 0.1 mmol l−1 EDTA, 5 mmol l−1 
H2O2 and 10 mmol l

−1 guaiacol – a method derived 
from Fielding and Hall (1978). The increase of 
absorbance, due to tetraguaiacol formation, was 
recorded at 470 nm.  

 
Evaluation of total antioxidant capacity 

The assay is based on the reduction of Mo 
(VI) to Mo (V) by the extract and subsequent 
formation of a green phosphate/Mo (V) complex at 
acid pH (PRIETO et al. 1999). An aliquot of sample 
extract was combined in an eppendorf tube with 1 
ml of reagent solution (0.6 M sulfuric acid, 28 mM 
sodium phosphate, and 4 mM ammonium 

molybdate). The tubes were incubated in a thermal 
block at 95 C for 90 min. After the mixture had 
cooled to room temperature, the absorbance of each 
solution was measured at 695 nm (Anthelie 
Advanced 2, SECOMAN) against a blank. The 
antioxidant capacity was expressed as mg gallic acid 
equivalent per gram of dry weight (mg GAE/g DW). 
All samples were analyzed in three replications. 
 
RESULTS 

 

Plant aspect, Growth and 

relative water contents 
The   growth   responses to   salt stress   of 

fenugreek were represented in Figure 1. The 
biomass accumulation of fenugreek was impaired 
by NaCl, a few days after salt treatment was 
started; wish yellow colouration of young leaves 
(revealed incipient necrosis). For shoots, biomass 
production decreased by 10% in comparison to 
control after 10 days of NaCl treatment (Figure 1). 
This response was accompanied by a diminution of 
the leaf number mainly associated with a reduction 
of total leaf area, (Table 1) and  gradual diminution 
total leaf surface area by 60% at NaCl 200 mM. 
Nevertheless, the effect of salt on biomass was also 
important in roots than  leaves and less pronounced 
in stems. In addition, the applied NaCl inhibit the 
growth of fenugreek plant. 

Water content   of three organs of 
fenugreek (Figure. 2) depended poorly on  NaCl 
treatments.  At 50 mM, salt treatment induced   no 
significant effect on stems and roots tissue 
hydration in fenugreek, but increased it (by 30 %) 
in leaves. At higher NaCl concentration (200 mM 
NaCl), water content decreases significantly at 
different organs, but it’s were  more pronounced in 
roots (Figure. 2). 

The water content of stems is was higher 
than  leaves and roots in the presence and absence of 
salt.  Other parameters can be used to express the 
effect of NaCl on the growth of fenugreek plants, 
such as the sensitivity index SI, calculated from the 
production of dry material are shown in Table 1. 

 
 
 
 
 
 
 
 
 
 

 



686 
Effects of NaCl on plant growth…  OLFA, B. et al. 

Biosci. J., Uberlândia, v. 34, n. 3, p. 683-696, May/June 2018 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
Figure 1: Fresh weights   (FW) and Dry weights (DW)    in leaves,   stems, and  roots Fenugreek plants after 10 

days of growth under NaCl (0, 50,100, 150 et 200 mM NaCl) conditions. Average of 8 repetitions and 
confidence intervals at 5%. 

 
 
 
 
 

 
 
 
 
 
 
 
 
 
 
 
 
 

 
Figure 2: Effect of NaCl on tissue hydration in leaves, stems, and roots fenugreek plants after 10 days of 

growth under NaCl (0, 50, 100, 150 and 200 mM NaCl) conditions. Average of 8 repetitions and 
confidence intervals at 5%.  

 
 
  

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687 
Effects of NaCl on plant growth…  OLFA, B. et al. 

Biosci. J., Uberlândia, v. 34, n. 3, p. 683-696, May/June 2018 

Table 1: Effect of increasing NaCl concentration in leaves of Trigonella foenum-graecum on the leaf surface 
and the total number of plant leaves of fenugreek. The culture duration is 10 days in absence or 
presence of 50, 100,150 and 200 mM NaCl.  Average of 6 repetitions. Safety interval at 5%. 

 
 
 
 
 
 
 
 
 

 
SI negative values are observed in response to higher concentrations of NaCl (150 and 200 mM). 
 
Ion accumulation  

Salt stress causes disturbances in the 
mineral nutrition of fenugreek plants. In the 
presence of NaCl, the amounts of K+ and Ca2+ 
absorbed by roots and transported to the shoots were 
decreased significantly with the increasing of 
salinity levels , (exceptly of steems) stricted 
significantly.  

Na+ and Cl- concentrations in the tissues 
increased with different NaCl concentration, (Figure 
3). The Na+ and Cl- accumulation was clearly 
increased as when NaCl concentration was 
increased from 0 to 200 mM,  in the different 
organs. As similarly to Cl- accumulation, Na+ 
reaches very high values  at of 200 mM NaCl: 4.45; 
4.01 and 5.59 méq.g DW-1, respectively, in the 
leaves, stems and roots. 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Figure 3: Na
+

, Cl,-  K+ and Ca 2+ content   in leave, stem, and roots fenugreek  plants after 10 days of 
growth under NaCl (0, 50, 100, 150 and 200 mM NaCl) conditions. Average of 8 repetitions and 
confidence intervals at 5%. 

 

The soluble proteins 
Protein contents in the leaves of fenugreek 

plant after 10 day of NaCl treatment are given in 
Figure 4. It seems that the presence of NaCl salt in 
the nutrient solution did not affect proteins contents  
at a 50 mM NaCl concentration, but  was increase 
from 100 mM NaCl, and increased by about 200% 
at 150 mM. 
 

 

Antioxidant enzyme activity 
To control the level of reactive oxygen 

species under stress conditions, plant tissues contain 
a series of enzymes scavengers of ROS. An 
arrangement of enzymes is needed for the 
regeneration of the active forms of the antioxidants; 
represented by both non enzymatic and enzymatic 
reactions (ZOROV, 2014) 
 

 

19,9 ± 426,8 ± 6.430,9 ± 938,5 ± 1041,3 ± 9Leaf number

0,4 ± 0.050,41 ± 0.020,48 ± 0.030,51 ± 0.060,49 ± 0.07Individual leaf surface area

7,79 ± 1.4910,83 ± 2.1514,09 ± 3.5519,03 ± 3.3319,75 ± 3.46Total leaf surface area

200150100500NaCl mM

a a b c d

a a a b b

a b c d e19,9 ± 426,8 ± 6.430,9 ± 938,5 ± 1041,3 ± 9Leaf number

0,4 ± 0.050,41 ± 0.020,48 ± 0.030,51 ± 0.060,49 ± 0.07Individual leaf surface area

7,79 ± 1.4910,83 ± 2.1514,09 ± 3.5519,03 ± 3.3319,75 ± 3.46Total leaf surface area

200150100500NaCl mM

19,9 ± 426,8 ± 6.430,9 ± 938,5 ± 1041,3 ± 9Leaf number

0,4 ± 0.050,41 ± 0.020,48 ± 0.030,51 ± 0.060,49 ± 0.07Individual leaf surface area

7,79 ± 1.4910,83 ± 2.1514,09 ± 3.5519,03 ± 3.3319,75 ± 3.46Total leaf surface area

200150100500NaCl mM

a a b c d

a a a b b

a b c d e

 

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688 
Effects of NaCl on plant growth…  OLFA, B. et al. 

Biosci. J., Uberlândia, v. 34, n. 3, p. 683-696, May/June 2018 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
Figure 4. Effect of NaCl on the content of total soluble protein in fenugreek plant leaves (Trigonella foenum-

graecum) local variety. Average of 8 repetitions and confidence intervals at 5%. 
 

In our study, a quantitative analysis of the 
activities of some antioxidant enzymes, such as 
guaiacol peroxidase and catalase, are also measured 
in order to clarify the effect of salt on the 
antioxidant activity of fenugreek plants grown on a 
medium added or not with NaCl (0, 50, 100 et 150 
mM). The results are shown for the leaves in 
Figures 5 and 6. An increase in the activity of 
antioxidant enzymes at a lower salt concentration 
(50 mM), as shown in Figures 6. 

The GPX activity increases with the NaCl 
concentration in fenugreek leaves and reached 300% 

at a concentration of 100 and 150 mM NaCl as 
compared to control. The catalase activity in 
fenugreek plants, cultured in the presence and 
absence of salt, is shown in Figures 6. At control 
medium, catalase activity is of 6.77 m.mol H2O2 
min-1.mg P-1. In the presence of 100 and 150 mM 
NaCl, CAT activity in leaves respectively increases 
by 200 and 250% as compared to control. The salt 
stress induced a significant increase in the activity 
of enzyme of fenugreek.  

 
 
 
 
 
 

 

 

 

 

 

 

 

 

 

Figure 5: Effect of salt on the peroxidase activity (GPX) on the fenugreek plant leaves (Trigonella foenum 
graecum). Average of 6 repetitions and safety intervals of 5%. 

 

 

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689 
Effects of NaCl on plant growth…  OLFA, B. et al. 

Biosci. J., Uberlândia, v. 34, n. 3, p. 683-696, May/June 2018 

 

0

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m
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m
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C
A
T
,

 
Figure 6: Effect of salt on the catalase activity on the fenugreek plant leaves (Trigonella foenum graecum). 

Average of 6 repetitions and safety intervals of 5%. 
 
Assay of secondary metabolites 

Total polyphenols content 
The effect of salt stress on the total 

polyphenol content of fenugreek leaves was shown 
in Table 2. Polyphenols content depend on the salt 

concentration. The increase of salt concentration 
induced a greater accumulation of polyphenols. 
Indeed,  polyphenol contents significantely 
increased by 30 and 71% as compared to  control.  
 

 
Table 2: The effect of salt stress on the levels of total polyphenols (mg EAG.g-1 MS), flavonoids, condensed 

tannins (mg EC.g-1 MS) and in total antioxidant capacity of fenugreek leaves.  Average of 4 
repetitions and safety intervals at 5%. 

 
 
 
 
 
 
 

 

 

 

 

 

 

 

 

 

Flavonoids content 
Depending on  salt treatments, the changes 

in  flavonoids levels in  leaves are shown in table 2. 
Total flavonoids contents, expressed as mg EC.g-1 
MS, are estimated on acetone extracts of fenugreek 
leaves. A stimulation of flavonoids content in leaves 
as salt concentration increases. In addition 
flavonoids content  increased by two and three-fold 
respectively at 50 and 150 mM NaCl as compared to 
control.  
 

 

 

Condensed tannins content 
Salt addition increased the tannin content 

from 50 mM of NaCl, but increases by 200 % 
compared to the control at 100 mM NaCl (Table 2).   

 
Estimation of total antioxidant capacity 

The total antioxidant capacity was estimated 
in fenugreek leaves extracts (Table 2). The results 
showed that salt stress induces a significant 
stimulation of the antioxidant capacity of leaves. 
 
 
 

0 mM 50 mM 100 mM 150 mM

Polyphenol content

Tanin content

Flavonoid content

4.58 8.38 10.7 12.7

0.84

2.66 8.25

1.36

4.53 6.16

1.66 1.75

ATT 21.78 25.06 25.78 31.06

a

a

a

a

b

b

b

b

c

c

c

b

d

d

d

c

0 mM 50 mM 100 mM 150 mM

Polyphenol content

Tanin content

Flavonoid content

4.58 8.38 10.7 12.7

0.84

2.66 8.25

1.36

4.53 6.16

1.66 1.75

ATT 21.78 25.06 25.78 31.06

a

a

a

a

b

b

b

b

c

c

c

b

d

d

d

c



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Effects of NaCl on plant growth…  OLFA, B. et al. 

Biosci. J., Uberlândia, v. 34, n. 3, p. 683-696, May/June 2018 

DISCUSSION 
 
The biomass produced by the Fenugreek, as 

illustrated by leaf, stem and root dry weight, was 
more depressed by salt in 150 and 200 mM. Growth 
rate is expected to be positively related with 
photosynthetic capacity, which itself is determined 
by the total leaf number and the specific 
photosynthetic activity of leaves. The effect of NaCl 
on the growth of the fenugreek plants is perceptible 
from a concentration of 100 mM NaCl. This effect 
resulted in a decrease in plant biomass. To better 
enhance the effect of NaCl on the growth of this 
plant, we estimated the sensitivity index SI (Table 
1). Our results suggest that the sensitivity of 
biomass production is mainly dependant on the 
growth activity during treatment. In addition 
negative SI negative values are observed in response 
to higher concentrations of NaCl (100 and 150 
mM). The decrease in biomass depending on the 
severity of stress could be an adaptive strategy. 
Indeed, plant reduces its exchange surface with the 
external environment in order to conserve a better 
water content. In aromatic and medicinal plants, 
recent studies emphasized sensitivity to salt stress; 
illustrated by a decrease in growth, such as in 
Mentha pulegium (OUESLATI et al. 2010), an 
halophyte behavior in Sesuvium portulacastrum 
(MESSEDDI et al. 2004) or by a reduction in the 
biomass production by 25 and 38 % as compared to 
control plants at 50 and 75 mM NaCl, respectively 
(BEN TAARIT et al. 2010). A growth reduction by 
salt constraint is considered by many authors as 
critical parameters for discrimination between 
species or cultivars, tolerant and sensitive.  

(TUTEJA et al., 2011). Our findings suggest 
that fenugreek was sensitive to salt at a moderate 
NaCl concentration (100 mM NaCl). 

Increasing levels of NaCl induced   a 
progressive absorption of Na+ and Cl- in plant, 
agreeing with Turan et al. (2007a, b). Excessive Na+ 
concentration in the plant tissue hinders nutrient 
balance, and causes toxicity osmotic regulation 
and causes specific ion toxicity (ARZANI, 2008). 
When NaCl was applied to the soil, the levels of K+ 
in plant were reduced in accordance with the 
antagonism between Na+ and K+ (AZEVEDO; 
TABOSA, 2000).  Besides, as in a Thellungiella 
halophila (M’RAH et al. 2006), a competition in 
absorption and transport of (K/Na) from the roots to 
aerial parts was found. According to Kaddour et al. 
(2009), a good selectivity for K+ was necessary to 
maintain better plant growth on saline medium. 
Indeed, a law biomass production due to Na+ 
competition with K+ for uptake and transport causes 

a deficiency of potassium (SHIYAB et al.  2003). 
Since potassium as suggested by Ashraf and Orooj 
(2006) and Oueslati et al. (2010) was one of the 
most growth-limiting factors under saline 
conditions. Salt stress may have either an ionic or an 
osmotic component in plants (TONON et al. 2004). 
Both could potentially be responsible for the 
observed physiological perturbations in fenugreek 
leaves. The accumulation of Na+ and Cl- in leaves of 
glycophytes is known to impose various stressors on 
the cells which alter their functional state, resulting 
in physiological stress (GASPAR et al. 2002). When 
severe, these have several detrimental effects, 
corresponding to direct or indirect salt toxicity. As 
initially hypothesized by (M’RAH, 2006), in the 
absence of efficient internalization of the ions by 
leaf cells, their concentration in the leaf apoplast 
may reach excessive values, leading to leaf cell 
dehydration (MUNNS; PASSIOURA, 1984) and 
membrane disruption (SPEER; KAISER, 1991). 
Furthermore, if ions absorbed by the leaf cells are 
not efficiently compartmentalized in the vacuoles, 
Na+ and Ca2+ may build to toxic levels in the 
cytoplasm (FLOWERS et al. 1991), and essential 
metabolic pathways such as photosynthesis may be 
inhibited (MELONI et al. 2003). Ionic and osmotic 
disturbances may also result in stomata closure, 
which limits photosynthesis (MELONI et al. 2003).  

In this study, we showed that fenugreek 
plants exposed to NaCl increased the high proline 
(Fig 7). Also, leaves of plants exposed on salt stress 
have accumulated high levels of proline compared 
to control plants. In addition there was 
circumstantial evidence that the synthesis of proline 
dirty stress induced was an adaptive response since 
it can function as a non-toxic osmolyte, an 
osmoprotectant that occurs in the cytoplasm where 
it acts as a protecting of enzyme at the origin 
(DELAUNEY; VERMA, 1993).  It is believed that 
this amino-acid helps in the protection of enzymes 
and membrane integrity in plants subject to 
restrictive conditions (ASHRAF; FOOLAD, 2007). 
However, there is evidence that proline 
accumulation was a symptom of salt stress-induced 
metabolic disorders rather than being involved in its 
alleviation (SILVEIRA et al. 2009). From this fact, 
the salinity significantly increases in proline content 
in different cultivars and tolerant and sensitive 
species, with a greater accumulation among those 
most tolerant (MANSOUR et al. 2005). This can be 
correlated to an adaptation to salt (MANSOUR et al. 
2005).  

Effect of salt stress on the plant tissues were 
determined by measuring of MDA content. Our 
results showed lipid peroxidation increased as the 



691 
Effects of NaCl on plant growth…  OLFA, B. et al. 

Biosci. J., Uberlândia, v. 34, n. 3, p. 683-696, May/June 2018 

stress level rose up. In fact, in leaves at 150 mM 
NaCl, the MDA content was 4 fold higher than in 
control. The increase in MDA content was a clear 
indication for oxidative stress in these plants, which 
thus seemed to suffer from a acute   saline 
aggression.  It has   been   reported that   MDA 
content was correlated with leaf H2O2   
accumulation in two corn varieties (HAJLAOUI et 
al. 2009). These results were previously reported in 
other cultivated species (SUDHAKAR et al. 2001). 

To better understand the nature of salt effect 
and the ability of the fenugreek plant to tolerate this 
abiotic stress, we were interested in studying the 
effect of salt stress on biochemical parameters in 
fenugreek. Excess of ROS causes phytotoxic 
reactions such as lipid peroxidation, protein 
degradation and DNA mutation (PITZSCHKE; 
HIRT, 2006).  To protect themselves against these 
toxic oxygen intermediates, a simultaneous increase 
antioxidant system such as catalase and peroxidases 
in salt treated plants.  The antioxidant system is 
made of a large number of enzymes and a low 
molecular weight compounds that important for the 
homeostasis of ROS (MAHMOUDI et al. 2010). 

Our results show that salt treatment 
significantly increased CAT and GPX activities in 
fenugreek in the presence of 50, 100 and 150 mM 
NaCl. These results are consistent with those of 
Meloni et al. (2002) who found among cotton 
cultivars a stimulation of peroxidase activity by 76 
and 94% of control at 100 and 200 mM NaCl. Also, 
the salt induced a significant increase in the guaiacol 
peroxidase activity in the leaves of rice plants (LEE 
et al. 2001). This suggests that this plant has a high 
capacity of H2O2 decomposition. The antioxidant 
activity increase, such as GPX, APX, and CAT is 
essential in this tolerance. GPX and CAT are the 
most effective antioxidant enzymes in plant 
protection against cell damage Scandalios (2005 ). 
Moreover, it was shown that CAT works with SOD 
to better protect plants against cell damage 
(SCANDALIOS, 2005). In addition, CAT and GPX 
are responsible for the detoxification of H2O2 and 
they probably have the same importance at the 
detoxification stage in fenugreek as response to this 
NaCl concentration. These results clearly indicate 
the criteria role of CAT and GPX in the fenugreek 
plant protection against the NaCl toxicity.  

Phenolic compounds are an important group 
that is widely distributed in plants; they show a wide 
spectrum of biological activities such as antioxidant 
activity, antiinflammatory effect, and anticancer 
effect Shao et al., 2008). The quantification of total 
polyphenols in fenugreek leaves was study at high 
NaCl concentration (150 mM). As shown in table 5 

a significant amount of polyphenols content (12,7 
mg of GAE g-1 at 150 mM NaCl), which is about 2,5 
times higher than control leaves extracts (4.58 mg of 
GAE g-1 ). Elzaawely et al. (2007) reported similar 
results in plant leaves of Alpinia zerumbet treated 
with copper sulphate, which gave them greater 
resistance to this salt explained by the antioxidant 
activity of polyphenols according to these authors. 

The levels of total polyphenols were higher 
than those reported in some other medicinal and 
aromatic plants such as Nigella sativa L. 
(BOURGOU et al. 2008). In addition, our results are 
consistent with several studies showing an increase 
in the polyphenol content in salt stress (NAVARRO 
et al. 2006). These data suggest that the degree of 
the cellular oxidative damage in plants exposed to 
abiotic stress is controlled by the ability to protect 
against oxidative agents (KSOURI et al. 2007).  

As for total polyphenols, salt stimulates the 
synthesis of flavonoids in these plants with a much 
stronger effect in leaves at 150 mM NaCl (table 2). 
According to Cushine and Lamb, (2005), flavonoids 
are phenolic compounds had a significant 
antioxidant anti-tumor and anti-microbial activity, 
and contribute to the prevention of cardiovascular 
diseases. Flavonoids are often induced by abiotic 
stress and have a role in plants protection (GRACE; 
LOGAN, 2000). Similarly, an increase in condensed 
tannins was observed (table 5). It is generally 
accepted that phenolic compounds give plants a 
strong antioxidant activity (JIN JUN et al. 2001). 
Our results confirmed that the fenugreek grown at 
100 mM NaCl had a better antioxidant activity 
compared to other concentrations. Karray et al. 
(2010) showed that in Mentha pulegium, salt 
induces an increase in polyphenol levels in leaves 
and their antioxidant activity. 
 
CONCLUSION 

 
Fenugreek appears to be tolerant to NaCl 

100 mM but sensitive to 150 mM. This low 
sensitivity was mainly due to maintenance of 
biosynthetic activity, salt status, a higher phenolic 
concentration and stronger antioxidant activities.  
Finally, this survey of effect salt stress at fenugreek 
reveals that the intraspecific variability of biomass 
production was accompanied by a modest but real 
variability in the capacity to induce antioxidative 
mechanisms in response to salt stress. 

 
FUNDING 
 

This study was achieved in the Biology 
Department in the Faculty of Sciences, the 



692 
Effects of NaCl on plant growth…  OLFA, B. et al. 

Biosci. J., Uberlândia, v. 34, n. 3, p. 683-696, May/June 2018 

University Campus Tunis El Manar and not funded 
(no subsidy) 

 

 
 

RESUMO: O feno-grego é usado como especiaria, vegetal e uma importante cultura medicinal cultivada em 
todo o mundo. Como as propriedades antioxidantes têm sido associadas aos benefícios à saúde dos produtos naturais, tais 
propriedades foram estudadas quanto ao efeito das concentrações de sal (0, 50, 100, 150 e 200 mM de NaCl) no 
crescimento das plantas, composição do conteúdo mineral, respostas antioxidantes e teores fenólicos. Os resultados 
mostraram uma redução do peso seco dos caules das folhas e crescimento das raízes. Essas alterações foram associadas à 
diminuição do conteúdo de água, concentrações de K+ e Ca2+ e um aumento nos teores de Na+ e Cl- em diferentes 
órgãos. As atividades de catalase e da peroxidase do guaiacol e o teor de fenólicos totais aumentaram significativamente 
em folhas de feno-grego. Os dados aqui relatados revelaram a variação do conteúdo de compostos fenólicos em diferentes 
órgãos na presença de sal, que sugeriu o uso do feno-grego em aplicações comerciais e econômicas. 

 

PALAVRAS-CHAVE: Feno-grego. Salinidade. Antioxidante. Polifenóis 
 

 

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