Microsoft Word - 27-Agra_41788


289 
Bioscience Journal  Original Article 

Biosci. J., Uberlândia, v. 35, n. 1, p. 289-295, Jan./Feb. 2019 
http://dx.doi.org/10.14393/BJ-v35n1a2019-41788 

PLANT ELICITATION WITH SALICYLIC ACID INCREASES BIOACTIVE 
COMPOUNDS CONTENT AND ANTIOXIDANT ACTIVITY IN THE 

INFUSION OF Achillea millefolium L. 
 

ELICITAÇÃO DE PLANTAS DE Achillea millefolium L. COM ÁCIDO SALICÍLICO 
AUMENTA O TEOR DE COMPOSTOS ATIVOS E A ATIVIDADE ANTIOXIDANTE 

DA INFUSÃO 
 
Pedro Henrique GORNI1; Ana Cláudia PACHECO2; Jonathan Fogaça Albuquerque SILVA3; 

Ronaldo Rossetti MORELI4; Kamille Daleck SPERA5; Regildo Márcio Gonçalves SILVA6  
1. PhD in Agronomy; 2. PhD in Plant Physiology and Biochemistry; 3 and 4 Agronomy engineer filiation at Universidade do Oeste 
Paulista (UNOESTE), Rodovia Raposo Tavares, km 572, 19067-175, Presidente Prudente, São Paulo, Brazil; 5. PhD student in the 

Postgraduate Program in Biotechnology. São Paulo State University (UNESP), Institute of Chemistry, Araraquara, São Paulo, Brazil; 6. 
PhD in Genetics and Biochemistry. São Paulo State University (UNESP), School of Sciences, Humanities and Languages, Assis, 
Department of Biotechnology, Laboratory of Herbal Medicine and Natural Products, Assis, São Paulo, Brazil. pgorni@gmail.com 

 
ABSTRACT: This study evaluated the total polyphenols content and the antioxidant activity of the 

infusion prepared with leaves from Achillea millefolium L. plants treated with salicylic acid (SA). Field 
cultivated plants received SA foliar applications (T1: control; T2: 1.0 mmol L-1 applications at 20, 60 and 100 
days after planting - DAP and T3: 1.0 mmol L-1 applications at 100 DAP during three days). The infusions from 
SA treated plants showed higher levels of total polyphenols and flavonoids compared to the control one. T2 and 
T3 infusions showed increases in the antioxidant activity by 2,2-diphenyl-1-picrylhydrazyl (DPPH), nitric 
oxide (NO) and ferric-reducing antioxidant power (FRAP) tests. However, only T2 treated plants had higher 
antioxidant activity by inhibition of lipid peroxidation (TBARS). It was concluded that elicitation of A. 
millefolium plants with SA can be considered an adequate strategy to increase the production of bioactive 
compounds and the antioxidant capacity of infusions. 
 

KEYWORDS: Phenolic compounds. Nitric oxide. DPPH. FRAP. TBARS.  
 
INTRODUCTION 

 
Achillea millefolium L. - Asteraceae - is a 

plant used in traditional medicine for the treatment 
of gastrointestinal and hepatobiliary disorders and 
externally in case of skin inflammations and wound 
healing. In addition, this species is an appetite-
inducing drug because of its bitter taste 
(BENEDEK; KOPP, 2007). Popularly known as 
yarrow, A. millefolium L. is commercially produced 
as raw material for the beverage (tea composition) 
and phytomedicines industries (WILLUHN, 2002). 
The aerial parts of yarrow plants are used in the 
form of aqueous or alcoholic extracts, due to the 
high solubility of their polar phenolic substances 
(BENEDEK; KOPP, 2007). 

The profile of phenolic compounds presents 
in the tea, extracted during the infusion process, 
causes this beverage to present high antioxidant 
activity. In recent years, increasing attention has 
been devoted to the role of diet in human health, 
where the ingestion of plant foods rich in 
antioxidant compounds (fruits, vegetables and 
herbs) is essential for resistance to cellular oxidative 

stress, which causes degenerative diseases and aging 
(SARKAR; SHETTY, 2014).  

Elicitor application can be used to increase 
metabolite production in the plant and to enhance its 
qualitative value for fresh produce, enriched food, 
or as a raw ingredient for feed/food and 
pharmaceutical products (POULEV et al., 2003). 
The elicitation technique is one of the strategies 
employed in the cultivation of medicinal plants to 
increase the content of bioactive compounds 
(PÉREZ et al., 2014). Elicitors are defined as 
natural or synthetic substances that, when applied to 
plants in small concentrations, initiate or increase 
the synthesis of specific bioactive compounds 
(NAMLI et al., 2014). Salicylic acid (SA) is a 
phenolic compound of hormonal nature present in 
plants, also classified as an elicitor (ANGELOVA et 
al., 2006). The eliciting action of SA has been 
proven both by its application in intact plants 
(PÉREZ et al., 2014; GORNI et al., 2017) and in 
cell and tissue culture. SA induces the expression of 
plant genes involved in secondary metabolites 
production like phenolic compounds, flavonoids, 
glucosinolates, anthocyanins, carotenoids and 

Received: 18/04/18 
Accepted: 05/10/18 



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others. Plant-related factors such as species, cultivar 
and physiological status influence SA elicitation 
responses, as well as SA doses and forms of 
application (GORNI; PACHECO, 2016). 

Studies have shown that teas antioxidant 
activity is higher than popularly fresh consumed 
vegetables, such as spinach and onion. Such studies 
demonstrate the importance of tea as a potentially 
functional food for health (KARORI et al., 2007). 
The potential antioxidant activity of ethanolic and 
aqueous extracts of leaves, flowers and seeds of A. 
millefolium was tested by elimination of ferric 
thiocyanate and H2O2 radicals. All the extracts 
showed a high antioxidant activity (KESER et al., 
2013).  

This study evaluated the effect of foliar 
application of salicylic acid in yarrow plants on total 
polyphenol and flavonoid contents and the 
antioxidant capacity of the resulting infusions. 
 
MATERIAL AND METHODS 
 

The research was carried out from May to 
September 2016 under field conditions in Presidente 
Prudente (22º07'04'' S, 51º27'05'' W, 471 ma.s.l.), 
São Paulo, Brazil. According to Köppen, the climate 
of the region is characterized as Mesothermal AW, 
with hot summers and dry winters. The soil is 
classified as Dystrophic Red Argisol with 10-12% 
of clay in the 0 - 20 cm layer (EMBRAPA, 2006). 

The soil of the experimental area was 
analyzed according to Raij et al. (2001) The soil of 
the experimental area was analyzed and corrected 
by applying limestone for elevate soil base 
saturation to 80% according to Boletim 100 
(perennial herbaceous species). The organic 
fertilization was based on tanned bovine manure (10 
kg of manure per square meter of plot, which is 
higher than the recommended due to the sandy soil). 

The seedlings were obtained by vegetative 
propagation from A. millefolium parent plants, 
whose exsiccates are deposited in the herbarium of 
the Federal University of Uberlândia-MG (HUFU 
74428). After a period of thirty days, seedlings were 
transplanted to the field. The adopted spacing was 
70 x 50 cm (NETTO; RAFFAELLI, 2004). Plants 
were manually irrigated twice a day during the 
experimental period.  

The SA were applied in the leaves by CO2 
pressurized sprayer (40 PSI) (50 mL per plant) as 
follows: T1 - control (plants sprayed only with 
water); T2 - 1.0 mmol L-1 SA applications at 20, 60 
and 100 days after planting (DAP) and T3 - 1.0 
mmol L-1 SA applications only at 100 DAP, 
spraying the plants for three consecutive days. The 

experimental design was in randomized blocks, with 
5 plots (10.5m2) per treatment in a total of 300 
plants (20 plant per plot). The harvest was carried 
out at 120 days after planting. The 6 central plants 
of each plot (useful area) were collected. 
 
Preparation of the infusion of Achillea 
millefolium L. 

The harvested leaves were dried in an air 
drier at 40o C for 48 hours. After drying, the leaves 
went grind. The infusion was obtained by the 
addition of 100 mL of distilled water (98°C) infused 
with 1g of dry leaves of A. millefolium. The infusion 
was maintained at room temperature for 10 minutes 
under agitation (SU et al., 2006). After this period, 
infusions were filtered and stored in amber glass 
bottles and kept under refrigeration (4°C). 
 
Total polyphenols content (μg/mL) 

The total polyphenols content in the 
different infusion of A. millefolium was assessed 
using Folin-Ciocalteu reagent and gallic acid as a 
standard (STAGOS et al., 2012). 25 µL of each 
infusion was added to 1.25 mL of distilled water, 
125 µL of Folin-Ciocalteu reagent. The 
homogenized tubes were resting for 3 min and then 
350 μL of 25% sodium carbonate (Na2CO3) and 750 
μL of distilled water and then tubes were incubated 
for 1 h. After that, their absorbance was recorded at 
765 nm. The total polyphenols contents of the 
infusion were reported based on micrograms of 
gallic acid equivalents per milliliters (μg GAE/mL). 
Gallic acid solutions were prepared with 
concentrations of 25 to 500 μg mL-1 in absolute 
ethyl alcohol. 
 
Total flavonoid content (μg/mL) 

The dosage of flavonoids was performed 
according to Yao et al. (2013). To quantify the total 
flavonoid content in A. millefolium infusion, a 100 
μL aliquot of the extract was added to the test tube 
together with 400 μL of 70% alcohol and 50 μL of 
5% NaNO2. After 6 minutes 50 μL of the 10% 
aluminium chloride (AlCl3) solution, 300 μL of 
NaOH (1 M) and 100 μL of distilled water were 
added. The spectrophotometer was read at 510 nm. 
The total flavonoids contents of the infusion were 
reported based on micrograms of rutin equivalents 
per milliliters (μg RE/mL). Rutin solutions were 
prepared with concentrations of 25 to 500 μg mL-1 
in absolute ethyl alcohol. 
 
Antioxidant activity 

Free radical scavenger activity DPPH 
(2,2-diphenyl-1-picryl-hydrazyl) 



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In this method, DPPH solution (500 µM) 
was prepared in ethanol, 250 µL of this solution was 
added to 50 µL of sample solution (at concentrations 
of 250, 500 and 1000 μg / mL), 1 mL of acetate 
buffer (100 mmol L-1 / pH 5.5) and 1.25 mL of 
absolute ethanol and then incubated at room 
temperature for 30 min, the absorbance was 
measured at 518 nm (BLOIS, 1958). The percentage 
of radical scavenging activity was calculated from 
Equation: AA (%) = [(Ac - As)/Ac] x 100 where Ac 
is the absorbance of the control, and As is the 
absorbance of the sample and expressed as IC50 
value. 

Iron Reduction Activity (FRAP) 
The total antioxidant potential of the tea 

samples was determined using a modification of the 
ferric reducing ability of plasma (FRAP) assay of 
Kukić et al. (2008). 90 µL of each sample was 
added to 2.7 mL of FRAP reagent (0.3 M sodium 
acetate buffer pH 3.6, tripyridyl triazine (TPTZ) 10 
mmol L-1 and ferric chloride 20 mmol L-1) and 270 
µL of distilled water. The mixture was vortexed and 
incubated at 37°C for 30 minutes. Absorbance of the 
solutions was read at 595 nm. The calibration curve 
was obtained with ferrous sulfate (100 - 2000 μM) 
and the results expressed in μmol Fe2+ mg-1 sample. 

Nitric Oxide (NO) sequestering activity 
For the evaluation of nitric oxide (NO) 

scavenging assay was carried by using sodium 
nitroprusside, it was used the methodology 
described by Marcocci et al. (1994) was measured 
with the Griess reagent. 320 μL of each sample was 
added to 360 μL sodium nitroprusside (25 mmol L-1 
/ phosphate buffer saline pH 7.4) and 215 μL of 
Griess reagent was added in test tubes and incubated 
in a 37°C water bath for 2 hours, in the absence of 
light. The absorbance of the test was determined in a 
spectrophotometer at 540 nm. The calibration curve 
was obtained with sodium nitrite (2.5 – 80 μM) and 
the results expressed in the amount of nitrite formed 
(μM mL-1). 

Inhibition of lipid peroxidation (TBARS) 
The evaluation of antioxidant capacity by 

the inhibition of lipid peroxidation was based on 
TBARS (Tiobarbituric Acid Reactive Species) 
methodology, described by Guimarães et al. (2010) 
with some modifications. Egg homogenate (1 mL) 
of 1%, v/v in phosphate buffered saline (20 mmol L-
1 / pH 7.4) and 100 µL of sample were added to 100 
μL of the 2,2'-Azobis(2-amidinopropane) 
dihydrochloride (AAPH) (0.12M) to induce lipid 
peroxidation. The mixture was incubated for 30 
minutes at 37ºC. After incubating and cooling at 
room temperature, it was added 500 μL of 
trichloroacetic acid (15%) and 500 μL of 

thiobarbituric acid (0.67%). The mixture was 
incubated at 97ºC for 15 minutes. After incubation, 
centrifugation 1200 rpm for 10 minutes. Then, the 
reading of the supernatant was performed at 532 
nm. Inhibition (%) of lipid peroxidation was 
calculated using the equation: Inhibitory activity 
(%) = [(Ac - As)/Ac] x 100 where Ac is the 
absorbance of the control, and As is the absorbance 
of the sample. 
 
Statistical analysis 

All determinations (total polyphenols, 
flavonoids and antioxidant tests) were repeated five 
times. Data were tabulated and submitted to analysis 
of variance (p ≤ 0.05), and the Tukey test using the 
Sisvar software. The results were presented by 
means of the treatments and standard error. 
 
RESULTS AND DISCUSSION 

 
The chemical composition of teas and 

infusions is complex and include polyphenols, 
alkaloids (caffeine, theophylline and theobromine), 
amino acids, carbohydrates, proteins, chlorophylls, 
volatile compounds, minerals, trace elements and 
other unidentified compounds (KARORI et al., 
2007). Among these, polyphenols are the most 
interesting group and are the main bioactive 
molecules in teas and infusions, corresponding to 
about 250-350 mg of the soluble solids present in 
this beverage (CABRERA; GIMENEZ; LOPEZ, 
2003). Several studies have demonstrated that the 
teas biological activity is related to the phenolic 
composition of the plant species that are used for the 
preparation of infusions (GRAMZA; KORCZAK, 
2005). Among these biological activities, is cited the 
ability of teas act as antioxidants in the human body. 

It can be verified that there was variation in 
the content of total polyphenols and flavonoids in 
the infusion of yarrow as a function of SA 
application to the plants (Table 1). Infusions from 
treated plants showed increases of 43.3% (T2 
treatment) and 54.2% (T3 treatment) in polyphenols, 
compared to the infusion obtained from the control 
plants. According to Ghasemzadeh and Jaafar 
(2012), when applied exogenously to plants at low 
concentrations, the SA interacts with stress-
signaling mechanisms and induces the synthesis of 
phenolic compounds. The elicitor signal 
transduction starts on the surface of the plasma 
membrane and includes events like the production 
of reactive oxygen species (ROS) and reactive 
nitrogen species (RNS), changes in the potential of 
plasma membrane cell and enhanced ion fluxes (Cl− 
and K+ efflux and Ca2+ influx), rapid changes in 



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protein phosphorylation, lipid oxidation, salicylic 
acid and jasmonic acid accumulation and the de 
novo biosynthesis of transcription factors, which 
directly regulate the expression of genes involved in 
several bioactive compounds (FERRARI, 2010 ; 
FRANKFATER et al., 2009). 

The treatments with SA resulted in 
significant increases of 27.5% (T2 treatment) and 
45.4% (T3 treatment) in the total flavonoid contents 
present in the infusions, when compared to the 
control (Table 1). This result agrees with Pérez et al. 
(2014), where SA treatments increased the 
flavonoids rutin and naringin in peppermint infusion 
(Mentha piperita). 

The presence of phenolic compounds in A. 
millefolium has been associated with its health-
promoting properties, such as choleretic activities, 
antioxidant, anti-inflammatory and antimutagenicity 
(GEORGIEVA et al., 2015; HUO et al., 2013). The 
phenolic compounds present in A. millefolium are 
flavonoids and phenolic acids. The flavonoids 
mainly occur as apigenin, luteolin and quercetin. 
Regarding the phenolic acids, the ubiquituous plant 
compound chlorogenic acid is accompanied by 
dicaffeoylquinic acids (DCQAs), namely 1,5-, 3,4-, 
3,5- and 4,5 –DCQA (BENEDEK; KOOP, 2007). 

 
Table 1. Total compounds in the tea of Achillea millefolium L. plants treated with salicylic acid. Different 

letters indicate significant difference by the Tukey test ** (p ≤ 0.01). 
Salicylic acid Total compounds (µg/mL) 

application Polyphenols Flavonoids 

Control  69.25±0.00b 239.42±6.01c 

20, 60 and 100 DAP 99.25±1.44a 305.25±4.33b 
100 DAP 106.75±6.03a** 348.175±3.25a** 

 
Due to the different types of free radicals 

and their different forms of action in living 
organisms (ALVES et al., 2010), it is necessary to 
use other complementary methods to evaluate the 
antioxidant activity of plants. The antioxidant 
substances can present different protective 
properties and act in several stages of the oxidative 
process through different mechanisms (SILVA et 
al., 2010). DPPH is the most commonly used 
standard method in the world for this purpose. 
However, DPPH is a synthetic radical, not present in 
living beings. In this way, other methods like FRAP 
(based on the antioxidant activity via ferric reducer 
and iron ion chelation capacity), TBARS (based on 

antioxidant activity via enzymatic action to reduce 
lipid peroxidation) and NO - nitric oxide (based on 
activity antioxidant via free radical sequestration 
action) are used for antioxidant activity 
determination. Georgieva et al. (2015) studied the 
antioxidant activity in A. millefolium (leaves and 
stems) in different tests, observing a greater activity 
of elimination of free radicals in the DPPH and 
FRAP tests.  

Infusions of A. millefolium plants treated 
with SA showed high antioxidant activity, both in 
terms of inhibition of oxidation and elimination of 
free radicals (Table 2). 

 
Table 2. Antioxidant activity in tea of Achillea millefolium L. plants treated with salicylic acid. Different letters 

indicate significant difference by the Tukey test ** (p ≤ 0.01). 
Salicylic acid Antioxidant activity 

application DPPH (IC50) FRAP (µmol Fe
2+/mg) 

Control 1283,652±14,849c 0.396±0.0001c 
20, 60 and 100 DAP 1037,098±7,805b 0.507±0.0001b 

100 DAP 936,729±14,565a** 0.517±0.0001a** 

 TBARS (%) NO (µM nitrite/mL) 

Control 61.38±0.038b 10.778±0.161c 
20, 60 and 100 DAP 69.31±0.028a** 13.222±0.184b 

100 DAP 53.60±0.018c 13.863±0.024a** 

 



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Using the DPPH method, there was a 
reduction in the IC50 value of 37% in T3 treatment 
when compared to control plants infusion. This 
increase in antioxidant activity as a result of SA 
plant elicitation was also verified when the FRAP 
(28 and 30.5% for T2 and T3 treatments, 
respectively) and NO (22.7 and 28.6% for T2 and 
T3 treatments, respectively) tests were used. 
Regarding the TBARS method, there was a 13% 
increase in antioxidant activity only in the infusion 
of the plants from T2 treatment, compared to the 
control infusion.  

The phenolic compounds have, in their 
structure, several characteristic benzene groups, 
having as substituents hydroxyl groups 
(HERNÁNDEZ; PRIETO GONZÁLES, 1999). The 
hydrogen atoms of the adjacent hydroxyl groups 
(ortho-diphenols), located at various positions of 
rings A, B and C, the double bonds of the benzene 
rings and the double bonding of the oxo function (-
C = O) of some flavonoid molecules guarantee to 
these compounds their high antioxidant activity 
(RICE-EVANS; MILLER; PAGANGA, 1996). 

 
 

There is a high correlation between vegetal 
species antioxidant effects and total phenolic 
contents (PIZZALE et al., 2002; PÉREZ et al., 
2014). In this way, SA elicitation is a tool for 
improving the antioxidant activity of herbal and 
spices, due to improvements in phenolic compounds 
accumulations. 
 
CONCLUSION 

 
The results obtained in this study showed 

that the foliar application of salicylic acid in 
Achillea millefolium L. plants resulted in increases 
in total polyphenols and flavonoids present in the 
infusion, with a consequent increase in their 
antioxidant activity. 
 
ACKNOWLEDGEMENTS 

 
This study was financed in part by the 

Coordenação de Aperfeiçoamento de Pessoal de 
Nível Superior - Brasil (CAPES) - Finance 
Code 001. 

 
 

RESUMO: Este estudo avaliou o teor total de polifenóis e a atividade antioxidante da infusão 
preparada com folhas de plantas de Achillea millefolium L. tratadas com ácido salicílico (AS). As plantas 
cultivadas em campo receberam aplicações foliares de AS (T1 – controle; T2 - aplicação de 1,0 mmol L-1 aos 
20, 60 e 100 dias após o plantio (DAP) e T3 – aplicações de 1,0 mmol L-1 aos 100 DAP durante três dias 
consecutivos). As infusões de plantas tratadas com AS apresentaram níveis mais elevados de polifenóis totais e 
flavonóides em comparação ao controle. As infusões T2 e T3 mostraram aumentos na atividade antioxidante 
por meio de testes de 2,2- diphenyl-1-picrylhydrazyl (DPPH), óxido nítrico (NO) e poder antioxidante de 
redução férrica (FRAP). No entanto, apenas plantas do tratamento T2 apresentaram maior atividade 
antioxidante por inibição da peroxidação lipídica (TBARS). Concluiu-se que a elicitação de plantas de A. 
millefolium com AS pode ser considerada uma estratégia adequada para aumentar a produção de compostos 
bioativos e a capacidade antioxidante das infusões. 
 

PALAVRAS-CHAVE: Compostos fenólicos. Óxido nítrico. DPPH. FRAP. TBARS.  
 
 
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