Vol 51 No 4 Okt-Des 2018.indd


205

Dental Journal
(Majalah Kedokteran Gigi)
2018 December; 51(4): 205–209

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG

The effects of Acanthus ilicifolius chloroform extract on TLR-2 
expression of macrophages in oral candidiasis 

Dwi Andriani and Agni Febrina Pargaputri 
Department of Oral Biology
Faculty of Dentistry, Universitas Hang Tuah
Surabaya – Indonesia 

ABSTRACT

Background: Immunosuppressed conditions due to long-term corticosteroid and tetracycline consumption are susceptible to 
fungal invasion, especially by Candida albicans (C. albicans), that requires treatment of oral candidiasis. Toll like receptor-2 (TLR-2) 
plays a role in candida recognition. Nystatin is regularly employed for oral candidiasis, but produces certain side-effects. Chloroform 
extract of Acanthus ilicifolius (A. ilicifolius) leaves represents both a potent inhibitor of C. albicans growth and an antioxidant. 
Purpose: This study aimed to compare the effect of A. ilicifolius leaf chloroform extract and nystatin treatment on TLR-2 expression 
in oral candidiasis immunosupressed models. Methods: This study constitutes a true experimental investigation incorporating a post 
test-only control group design. 20 healthy male Rattus novergicus (Wistar), aged 12 weeks and with an average weight of 250g, were 
immunosuppressed through oral administration of dexamethasoneand tetracycline for a period of 21 days before being induced with C. 
albicans (ATCC-10231) 6 x 108 for two weeks. The subjects were divided into five groups (n=4/group): healthy (H), no-treatment(P), 
nystatin treatment(N), A. Ilicifollius (8%) treatment (AI-1) and A. ilicifollius (16%) treatment (AI-2). The subjects were treated for 14 
days, with their tongue being subsequently biopsied. TLR-2 expression was subjected to immunohistochemical examination, observed 
under a microscope (400x magnification) and statistically analyzed (one-way Anova, LSD-test, p<0.05). Results: TLR-2 expression 
of P (6.25 ± 2.5), N (11.25 ± 0.96), AI-1 (13.00 ± 1.15), AI-2 (12.75 ± 1.7) was higher than H (1.75 ± 0.5). Significant differences 
existed between N to P, N, AI-1, AI-2; P to N, AI-1 and AI-2 (p<0.05). No significant differences were present between N, AI-1 and 
AI-2 (p < 0.05). Conclusion: A. ilicifolius extract can increase expression of TLR-2 in oral Candidiasis-immunosuppressed models. 
A. ilicifolius extract produces the same effect in increasing TLR-2 expression when compared to nystatin.

Keywords: achanthus ilicifolius; Candida albicans; immunosupressed; oral candidiasis;  TLR-2

Correspondence: Dwi Andriani, Department of Oral Biology, Faculty of Dentistry, Universitas Hang Tuah. Jl. Arief Rahman Hakim 
150 Surabaya 60111, Indonesia. E-mail dwi.andriani@hangtuah.ac.id

Research Report

INTRODUCTION

Infection in humans can be either bacterial or fungal 
in nature. Although often a commensal organism in 
humans, several fungi can prove to be pathogenic 
under certain conditions. Fungal infections can occur in 
immunocompromised patients suffering from trauma, 
HIV infection, immunosuppression and neutropenia and 
in whom the normally protective bacterial microflora is 
disrupted.1 Prolonged use of systemic drugs, for example 
broad-spectrum antibiotics, immune-suppressants and 
drugs with xerostomic side-effects, alter the local oral 

flora or disrupt the mucosal surface or reduce salivary 
flow, thereby creating a favorable environment for candida 
to grow and cause oral infection.2  Drug induced oral 
candidiasis has been reported in asthma patients treated with 
steroid inhalers for approximately three months.3

The most common fungal infection affecting the oral 
cavity is oral candidiasis approximately 60% of the cases 
of which are caused by Candida albicans (C. albicans) 
infection.4 According to research conducted in Surabaya 
during 2007, following candida isolation in AIDS patients 
suffering from oral candidiasis with clinical features of 
acute pseudomembrane candidiasis, acute erythematosus 

DOI: 10.20473/j.djmkg.v51.i4.p205–209

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206Andriani, et al./Dent. J. (Majalah Kedokteran Gigi) 2018 December; 51(4): 205–209

 Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v51.i4.p205–209

candidiasis, chronic hyperplastic candidiasis, acute 
erythematosus candidiasis and perleche, C. albicans species 
was found in approximately 35.29% of cases, while non-C. 
albicans species were detected in the other 64.71%.5

Neutrophils and macrophages constitute the immune 
cell types involved in immune mechanism defense against 
fungal infections. They recognize candida through 
pattern recognition receptors (PRRs) which interact with 
specific molecules called pathogen-associated molecular 
patterns (PAMPs) exposed on the surface of the candida.6  
Recognition of fungal cells occurs by means of PRR, 
dectin-1 (-1,3 glucan) and several other PRRs involved 
in identifying different cell wall polysaccharides of this 
pathogen. These include toll like receptors including: (TLR) 
2 which recognizes phospholipomannan of C. albicans, 
TLR4 which recognizes O-mannan of C. albicans and 
mannose receptor (MR) which recognizes N-mannan of C. 
albicans 7. These cells release cytokines and chemokines 
to further modulate the immune response for mucosal 
protection.8,9 Activation of TLRs, includingTLR-2, not only 
induces inflammatory responses, but also the development 
of antigen-specific adaptive immunity against fungal 
infection. 

Nystatin is a drug which, in addition to amphotericin 
B, miconazole, itraconazole and fluconazole, is commonly 
used in oral candidiasis therapy. It produces several side-
effects including: unpleasant tastes in the mouth, vomiting, 
diarrhea, nausea, anorexia, abdominal pain, thrush and 
headaches.10 Acanthus ilicifolius (A. ilicifolius) is a 
mangrove plant of the Acanthaceae family native to tropical 
regions in Asia and Africa employed by communities 
in Malaysia, India and Thailand to treat rheumatism, 
neuralgia, wounds resulting from poisoned arrows, coughs, 
asthma, influenza and dermatitis.11,12 A. ilicifolius leaf 
extract contains several active phytochemical components 
such as proteins, resins, steroids, tannins, glycosides, 
reducing sugars, saponins, sterols, terpenoids, phenols, 
cardioglycosides and catachols.11 This plant also has the 
ability to act as an antimicrobial.13

Chloroform and n-hexane extracts from A. ilicifolius 
leaves have a powerful inhibitive effect on Bacillus 
subtilis, Staphylococcus aureus, C. albicans, Aspergilus 
fumigatus and Aspergilus niger.12 The chloroform extract 
from A. ilicifolius leaves at a dose of 400 mg/kgBW has 
been reported to have an anti-ulcerative effect in mice, 
while one of 500 mg/kgBW has been demonstrated to be 
a practical anti-carcinogenic.14,15 The chloroform extract of 
A. ilicifolius leaves has an anti-candida effect and produces 
the highest inhibitory zone compared with other extraction 
methods.16 Chloroform extract of A. ilicifolius leaf 1% is 
effective in inhibiting C. albicans through thermoplastic 
nylon soaking. The administration of chloroform extract A. 
ilicifolius 8 mg/ml may increase IL-17 in immunosuppressed 
subjects suffering from oral candidiasis.17,18

The purpose of this study was to compare the effect 
of  A. ilicifolius chloroform extract and nystatin on 
TLR-2 expression immunosuppressed models as an 

alternative medicine derived from natural materials for 
oral candidiasis.

MATERIALS AND METHODS

This research represented a true experiment incorporating 
post test-only control group design. It employed 20 healthy, 
12-week old, male, Rattus novergicus (Wistar), each 250 
grams in weight, which were divided into five groups 
(n=4/group). Group-1(H): healthy/normal subject group, 
Group-2 (P): subjects induced with C. albicans and 0.1% 
CMCNa, Group-3 (N): subjects induced with C. albicans 
and treated with nystatin topical, Group A. ilicifollius 8% 
treatment (AI-1): subjects induced with C. albicans and 
treated with 8% A. ilicifolius chloroform extract topically, 
Group- A. ilicifollius 16% treatment (AI-2): subjects 
induced with C. albicans and treated topically with 16% 
A. ilicifolius chloroform extract. The method of animal 
subject induction in this study was based on Chami’s et al. 
research, with several modifications. Immunosuppression 
was achieved by orally administering dexamethasone 0.5 
mg/day and 1% tetracycline /day for 21 days. Between 
the 7th and 21st days the subjects were induced with 0.1 
cc of C. albicans (ATCC-10231) 6 x 108, applied to their 
tongues with a sterile cotton bud three times a week for 
two weeks.19

A. ilicifolius chloroform extract was produced by 
dehydrating leaves in the open air for two days. 10 grams 
of dried A. ilicifolius leaves were subsequently mixed with 
200 ml of chloroform using a mortal and pastle, covered and 
allowed to stand for five hours. The solvent was removed 
and filtered with Whatman’s no. 1 filter paper before being 
evaporated at low pressure by using a Buchi Rotavapor 
R-200 at 45°C. The chloroform extract was then stored in 
a refrigerator for future use.20

Treatment using A. ilicifolius chloroform extract 8% 
(Group AI-1), 16% (Group AI-2) and Nystatin as control 
groups was performed by applying 0.5 cc of the material to 
the surface of the tongue at the same time on 14 consecutive 
days, after which the subjects in each group were sacrificed 
and biopsed. TLR-2 expression was examined using a 
immunohistochemical staining method and then observed 
by means of a light microscope at 400x magnification. 

The statistical analysis used both one-way ANOVA 
and LSD statistical tests to determine the significance of 
differences between groups.

RESULTS

The expression of TLR-2 in an oral candidiasis 
immunosuppressed model derived from the tongue of a 
subject is shown in  Figure 1. Figure 2 indicates that the 
healthy/ normal group (H) had the lowest expression of 
TLR-2 (1.75 + 0.5) compared to P (6.25 ± 2.5), N (11.25 
± 0.96), AI-1 (13.00 ± 1.15) and AI-2 (12.75 ± 1.7), while 

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207 Andriani, et al./Dent. J. (Majalah Kedokteran Gigi) 2018 December; 51(4): 205–209

 Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v51.i4.p205–209

Figure 1. TLR-2 expression of macrophage in the tongue of Rattus novergicus (Wistar) (black arrow). A: Healthy/ normal group (H), 
B: Oral candidiasis group (P), C: group of subjects induced by C. albicans and treated with nystatin topical (N), D: group 
of subjects induced by C. albicans and treated with A. ilicifolius chloroform extract topically (AI) (400x Magnification).

Figure 2. Means of TLR-2 expression of macrophage. 
 This graphic represents the mean + standard deviation in each group of TLR-2 expression of macrophage after treatment 

with nystatin (N) and A. ilicifolius 8% (AI-1) and A. ilicifolius 16% (AI-2) compared with healthy subjects (H) and those 
receiving no treatment (P). There were significant differences between the healthy/normal group (H) and P, N, AI-1 and 
AI-2; P compared to N, AI-1 and AI-2 (p < 0.05). while there were no significant differences between N compared to AI-1 
and AI-2, and AI-1 compared to AI-2 (p > 0.05). (*p < 0.05 vs H and P).

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208Andriani, et al./Dent. J. (Majalah Kedokteran Gigi) 2018 December; 51(4): 205–209

 Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v51.i4.p205–209

the highest expression of TLR-2 appeared in the group 
of subjects which had been induced with C. albicans and 
treated topically with 8% A. ilicifolius chloroform extract 
(AI-1) compared to other groups. 

A one-way ANOVA statistical test was employed 
which indicated the significant differences between groups 
(p<0.05). A subsequent LSD statistical test confirmed 
significant differences between the healthy/normal group 
(H) compared to groups P (0.018), N (0.017), AI-1 (0.017) 
and AI-2 (0.018) (p<0.05). Significant differences also 
existed in P compared to N (0.020), AI-1 (0.019) and AI-2 
(0.021) (p<0.05), while there was no significant differences 
between N and AI-1 (0.063) or AI-2 (0.18) and AI-1 
compared to AI-2 (0.766) (p>0.05).

DISCUSSION

Immunosuppressive conditions and long-term 
antibiotic consumption represent predisposing factors 
that can lead to oral candidiasis. In this study, subjects 
were immunosuppressed through the administering of 
dexamethasone and combined with tetracycline, the 
latter of which is intended to cleanse the oral cavity 
of bacteria, thereby enabling C. albicans to proliferate 
without contamination by other bacteria. The tongues of 
subjects were used as a site of inoculation, treatment and 
sampling.

In this study, the level of TLR-2 expression, the 
nystatin treatment, 8% A. ilicifolius treatment, and 16% 
A. ilicifolius treatment, was found to be lower in the 
healthy group when compared to the candidiasis group. 
The untreated candidiasis also possessed lower TLR-2 
expression compared to that of the treatment groups. 
Immunosuppressive factors (catecholamines and steroids) 
induced by stress may also down-regulate the expression 
of TLRs. A number of studies have reported that TLRs 
are up-regulated in inflammatory conditions and down-
regulated in immunosuppressive conditions.21 Therefore, it 
is speculated that immunosuppressed conditions may have 
down-regulated the expression of TLR-2 in this study. 

There was no significant difference between the 
treatment group of nystatin, the treatment of 8% A. 
ilicifolius and the treatment of 16% A. ilicifolius (p < 0.05). 
This indicates that nystatin therapy involving both 8% A. 
ilicifolius, and 16% A. ilicifolius administered to subjects 
with immunosuppressed candidiasis demonstrated the same 
ability to increase TLR-2 expression which was possibly 
due to the phytochemical content of the extract. Chloroform 
leaf extract of A. ilicifolius contains phenol, flavanoid and 
tannin, which promote both antimicrobial and antioxidant 
activity.21 One study reported that the pentacyclic 
triterpenoid (isolated chloroform extract) present has the 
potential to restore vascular disorders associated with 
hypertension, obesity, diabetes, atherosclerosis. It could 
also be used in cancer therapy, as anti-ulcer drugs, as 

well as for the prevention and treatment of metabolic 
diseases.12,22

Previous studies of both nystatin and A. ilicifollius 
extract (8% and 16%) found that the latter were similar to 
nystatin in increasing the amount of IL-17 expression in 
oral candidiasis immunosuppressed conditions models.18 

This indicates that the capture of TLR-2 leads to a decrease 
in the number of candida and increased pro-inflammatory 
cytokines. In this study, the concentration of 8% A. 
ilicifolius extract produced the effect on the increase of 
proinflammatory cytokines via TLR-2 pathway. Up-
regulation of TLRs may lead to an inflammatory response 
and protective function against infection, while down-
regulation of TLRs may suppress inflammation and 
facilitate subsequent infection.23

Another study reported an increase in the capture 
capability of TLR-2 in mice afflicted with candidiasis 
which was associated with decreased TNF and chemokine 
production.24 TLR-2 can enhance the ability of macrophages 
in C. albicans-induced mice25, while its absence can reduce 
neutrophil chemotaxis and antifungal mechanisms.26 TLR-2 
binds phospholipomannans from C. albicans in the presence 
of galectin-3 and β-mannosides to induce a macrophage 
pro-inflammatory response.27 TLR-2 in combination with 
dectin-1 can also bind the β-glucan fungus. Inhibition 
of TLR-2 in human mononuclear cells can cause a 40-
50% reduction in the production of proinflammatory 
cytokines in vitro. A decrease in the amount of TLR-2 
may escalate susceptibility to infection by C. albicans.28 
TLR activation, in particular that of TLR-2, can suppress 
defense immunity against C. albicans through IL-10 
induction and T-regulatory cells.29 TLR signals through 
the MyD88 pathway leading to activation of MAPK and 
induces the translocation of nuclear factor kappa B to the 
nucleus which promotes the transcription and synthesis of 
proinflammatory cytokines.30

In conclusion, A. ilicifolius chloroform extract 
can increase expression of TLR-2 in oral candidiasis-
immunosupressed models. A. ilicifolius chloroform extract 
produces the same effect by increasing TLR-2 expression 
compared with nystatin. Further research is required 
regarding the function of acanthus in this model and its 
role in the mechanism of oral candidiasis.

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