�5

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 56/DIKTI/Kep./2012.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG

�5

The decreasing of NFκB level in gingival junctional epithelium 
of rat exposed to Porphyromonas gingivalis with application of 
�% curcumin on gingival sulcus

agung Krismariono
Department of Periodontics 
Faculty of Dental Medicine, Universitas Airlangga
Surabaya - Indonesia

abstract

Background: Periodontal	disease	is	a	chronic,	multi-factorial	disease.	Chronic	periodontitis	is	one	of	the	main	causes	of	tooth	
loss.	Chronic	periodontitis	is	usually	caused	by	Porphyromonas	gingivalis	(P.	gingivalis).	P.	gingivalis	can	induce	NFκB	activation	
resulting	in	the	increasing	of	periodontal	extracellular	matrix	degradation.	Curcumin	can	inhibit	NFκB	activation	and	reduce	the	
severity	of	periodontal	degradation. Purpose:	This	research	was	aimed	to	observe	level	of	NFκB	in	gingival	junctional	epithelium	of	
rat	exposed	to	Porphyromonas	gingivalis	with	local	administration	of	curcumin.	Methods:	Sixteen	Wistar	rat	were	divided	into	two	
groups.	Group	1	(treatment)	consisted	of	eight	rat	given	2	x	106	CFU/ml	P.	gingivalis	and	1%	curcumin.	Meanwhile,	group	2	(control)	
consisted	of	eight	rat	given	2	x	106	CFU/ml	P.	gingivalis	only.	GCF	samples	were	collected	from	gingival	sulcus.	The	samples	were	
biochemically	analyzed	with	ELISA	method.	Data	were	then	analyzed	statistically	by	using	independent	t-test	(α=0.05). results:	The	
examination	of	NFκB	level	showed	that	there	was	significant	difference	between	treatment	group	and	control	group	(p<0.05).	The	level	
of	NFκB	in	the	treatment	group	was	significantly	lower	than	the	control	group. Conclusion:	It	can	be	concluded	that	1%	curcumin	
application	can	reduce	NFκB	level	in	gingival	junctional	epithelium	of	rat	exposed	to	P.	gingivalis.	

Keywords:	NFκB;	junctional	epithelium	gingiva;	curcumin	

Correspondence: Agung Krismariono, c/o: Departemen Periodonsia, Fakultas Kedokteran Gigi Universitas Airlangga. Jl. Mayjend. 
Prof. Dr. Moestopo no. 47 Surabaya 60132, Indonesia. e-mail: agungkr@yahoo.com

introduction

Periodontal disease is irreversible so that if there is 
no optimal treatment, most patients will potentially have 
lifelong disorder. However, this disease is likely painly, 
so people are not aware, as a result, it is generally found 
in the advanced level.1 Chronic periodontitis is one of the 
types of periodontal disease widely spread in community. 
Porphyromonas	gingivalis	(Pg) bacteria are a major cause of 
this disease.2 In person with poor oral hygiene, the presence 
of Pg bacteria in the gingival	sulcus can potentially damage 
junctional epithelium, causing periodontitis characterized 
by loss of attachment. 

Loss of attachment to the junctional	epithelium may be 
caused by the invasion of Pg bacteria. Pg	bacteria causing 
chronic periodontitis can produce certain endotoxin, 
namely LPS and proteases, that can activate neutrophils 
and macrophages, which then will activate the transcription 
factor of nuclear factor-kappa B (NFκB). The activation of 
NFκB can trigger transcription and translation processes 
producing mediators that play a role in inflammation 
process.3 A research in rat showed that LPS	in 10 days can 
cause inflammation in periodontal tissue.4 Inflammatory 
mediators in the optimal number actually can serve 
to neutralize antigen. If the number of inflammatory 
mediators produced are excessive, the extracellular matrix 

Research Report

Dental Journal
(Majalah Kedokteran Gigi)

20�5 March; 48(�): �5–�8



Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 56/DIKTI/Kep./2012.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG

�6 Krismariono/Dent. J. (Majalah Kedokteran Gigi) 2015 March; 48(1): 35–38

will be damaged, so the periodontal tissues then can be 
damaged.5

Various attempts have been made to treat chronic 
periodontitis, such as by scaling and root planning as well as 
by giving antibiotics and anti-inflammatory either locally or 
systemically. Anti-inflammatory is required in the treatment 
of chronic periodontitis since it can neutralize the effects 
caused by the increasing of pro-inflammatory mediators. 
Anti-inflammatory commonly used in the treatment of 
chronic periodontitis is administered systemically. Systemic 
administration has few adverse side effects. Therefore, it 
needs proper efforts that are effective, efficient and safe 
for treating this disease. One of those is by using herbal 
ingredients, which have medicinal properties and can be 
administered locally, such as turmeric (Curcuma	longa).6 

The main active ingredient contained in turmeric is 
curcuminoid which main content is curcumin. Curcumin has 
useful properties, such as anti-inflammatory, antioxidant, 
antibacterial, antitumor and antihepatotoxic. Curcumin is 
also considered as a potent inhibitor of transcription factor 
NFκB.6,7 Nevertheless, the role of curcumin against NFκB 
associated with periodontal disease, especially chronic 
periodontitis with indicators taken from GCF has never 
been proven.

Based on those facts, curcumin is expected to reduce 
the degree of inflammation in the gingival junctional 
epithelium caused by bacterial Pg invasion. Curcumin is 
also expected to inhibit the increasing of NFκB level so 
that pro-inflammatory mediators produced by NFκB that 
cause periodontitis can be decreased. The purpose of this 
research is to investigate NFκB level in gingival junctional 
epithelium of rat exposed to Porphyromonas	gingivalis with 
local administration of curcumin.

materials and methods

This research can be considered as an in vivo experiment 
using male rat (Rattus	norvegicus) Wistar aged 5-6 months 
old and weighed 250-300 grams. The choosing of the 
age was based on the fact that the size of the jaw and 
gingival of the rat in that age is big enough to be applied 
with the medicines. This research was conducted at 
Laboratory of Biology in Faculty of Natural Science and 
Mathematics, Laboratory of Microbiology, and Laboratory 
of Biochemistry in Universitas Brawijaya. The samples of 
this research were selected randomly with the sample size 
determined through trial. Based on a sample size formula 
the representative number of samples must be eight.7

Curcumin powder was prepared in solution by using 
corn oil solvent to achieve a concentration of 1%. The 
concentration of 1% was determined based on a previous 
research conducted by Suhag.9 Meanwhile, to stimulate 
periodontitis disease in those rat, Pg	 bacteria (ATCC 33 
277) were given and grown in a medium containing tryptic 
soy broth (TSB). They were incubated in an anaerobic 
atmosphere for 24 hours. They were grown in blood agar 

containing 10% sheep blood, 0.4 mL/ml vitamin K1 and 
5 mL/ml hemin and then put into an anaerobic incubator 
with a composition of 80% N2, 10% H2, and 10% CO2 for 
24 hours at a temperature of 370 C. The largest colonies 
were transferred into liquid medium containing thioglicolat, 
and then incubated for 24 hours at 370 C in an anaerobic 
atmosphere. After PBS was given, spectrophotometry 
with 624 nm wavelength was used to make bacterial 
concentration as many as 1 x 106 CFU.10 

Rat used as experimental animals were adapted for 1 
week before the research, by conditioning them in a cage 
with feeding (certain concentrate) and beverages (distilled 
water) according to standards of animal care in Biological 
Laboratory, Faculty of Natural Science and Mathematics, 
Universitas Brawijaya. Those rat were then locally given 
0.03 ml of live Pg	ATCC 33 277 with the concentration of 
2 x 106 CFU/ ml in the gingival	sulcus bottom of their left 
and right mesial incisor teeth. The same procedure was then 
repeated every three days for two weeks. This procedure 
was conducted to make the animals get periodontitis. In 
the treatment group, 1% curcumin in corn oil as much as 
0.03 ml was administered locally in the same area as the 
provision of bacteria every day for two weeks to provide a 
therapeutic effect. Meanwhile, in the control group, only 
corn oil was administered every day for two weeks in the 
same area as the provision of bacteria. 

NFκB level was measured on day 14 by using 
periopaper put into the gingival sulcus for 30 seconds to 
get gingival crevicular fluid (GCF).11 The examination was 
conducted two weeks after the treatment. Periodontitis can 
be occurred in the past 10 days.4 Samples derived from 
GCF (in periopaper) put into eppendorf tubes and stored 
at -800 C until all the samples were collected and ready for 
examination. After all the samples were collected from 
the GCF, then the preparation of eLISA examination was 
conducted. each eppendorf tube containing periopaper 
was added with 0.5ml, 0.02M PBS with pH 7.0 to 7.2 as 
the solvent, and then centrifugation was conducted at 3000 
rpm for 20 minutes. Finally, the supernatant of all of those 
samples was taken for examination in accordance with 
eLISA procedure using specific rat monoclonal antibody 
for NFκB. 

results

Table 1 and Figure 1 show that NFκB levels in both the 
control group (bacteria and corn oil) and the treatment group 
(bacteria and curcumin in corn oil) on day 14. The results 
of Kolmogorov-Smirnov Goodness of Fit Test showed the 
value of p was 0.954 (p>0.05). It indicates that the survey 
data were normally distributed.

Based on the analysis of independent t-test results 
between the treatment group and the control group, it is 
known that there were significant differences between 
the control group and the treatment group with p=0.000 
(p<0.05). It is also showed that NFκB level in the treatment 



��

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 56/DIKTI/Kep./2012.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG

��Krismariono/Dent. J. (Majalah Kedokteran Gigi) 2015 March; 48(1): 35–38

group given 1% curcumin was lower than that in the control 
group.

discussion

This research was conducted to find an alternative 
solution for healing chronic periodontitis. The data from 
previous researches indicate that oral hygiene is the main 
cause of pathogen bacteria accumulation. This accumulation 
of bacteria causes periodontal tissue damage characterized 
by loss of attachment and migration of gingival junctional 
epithelium to apical. The results of this research showed that 
the group of rat not given curcumin had higher NFκB level 
than the group given curcumin. It means that curcumin has 
an effect in inhibiting NFκB activity in gingival junctional 
epithelium cells of those rat.

Curcumin can inhibit the phosphorylation of IκB kinase, 
so the translocation of NFκB into the nucleus of the cell 
is inhibited, resulting the decreasing of NFκB activity so 
that the expression of pro-inflammatory cytokines is also 
decrased.7 The inhibition of the phosphorylation of the 
inhibitor factor of IκB kinase in the cytoplasm can occur 
because curcumin is lipophilic13 so it could penetrate 
cell membranes and be located in either the cytoplasm or 
nucleus.14

Curcumin can inhibit NFκB activation prior to its 
translocation into the cell nucleus. NFκB activation in 

patients with periodontitis has increased about 90%, while 
that in healthy tissue is only 30%. The expression of IκB 
as an NFκB inhibitor in patients with periodontitis is only 
5%.15

Curcumin as an anti-inflammatory is a potential 
inhibitor of NFκB. NFκB determines the expression of 
genes encoding cytokines, chemokine, growth factors, cell 
adhesion molecules, some acute protein phases, such as 
iNOS and COX-2, and receptors on the cell membrane, such 
as TLR.16 The activation of NFκB can be caused by a wide 
variety of triggers, such as bacteria, viruses, cytokines, free 
radicals and toxic environments. The activation of NFκB 
is associated with inflammatory process found in diseases, 
such as periodontitis, arthritis, atherosclerosis, and other 
degenerative diseases.17 On the other hand, the complex 
and persistent inhibition of NFκB is also connected directly 
with apoptosis, impaired immune cell development, and 
cell growth inhibition.16 

Chronic periodontitis disease is generally caused by 
Pg bacteria.2 The increasing of NFκB is generally caused 
by products produced by Pg bacteria, such as protease, 
LPS, and fimbriae.18 Protease produced by Pg bacteria can 
trigger a series of immune response. Arg-gingipain (RGP), 
protease produced by Pg bacteria, is a potential activator 
for protease-activated receptor-2 (PAR-2).19 It means that 
protease is capable of breaking peptide in N-terminal of 
PAR-2 molecule, resulting in a new amino acid (neo-ligand) 
binding to the trans-membrane domain triggering PAR-2 
activation. PAR-2 will further stimulate signals to NFκB, 
so NFκB is activated and trans-located into the nucleus.20 

In addition to proteases, LPS produced by Pg bacteria 
is also a potent stimulator to produce pro-inflammatory 
cytokines. It means that in periodontal tissue exposed to 
LPS, monocytes will be activated, and pro-inflammatory 
cytokines will be secreted. LPS may also activate receptors 
on the cell membrane, such as TLR-2, TLR-4 and TLR-7. 
The activation of TLR causes intracellular signals passing 
through MyD88 pathway that induces p38 MAPK and 
subsequently activates NF-κB.21 

Fimbriae contained on live Pg can also be considered as 
an effective inducer that can activate NFκB due to signals 
from TLR-2. TLR-2 can enhance the activity of NFκB due 
to fimbriae of Pg bacteria.21 The fimbriae of Pg bacteria can 
stimulate TLR-2 which signals will further activate NFκB.22 
In other words, the activation of NFκB is stimulated by 
TLR-2 signals more dominantly activating cytokines 
induced by TNF in acute responses of osteoclastogenesis 
process.23 The increasing of osteoclasts then will cause 
damage to the periodontal tissues. 

In addition to extracellular signals, the increasing of 
NFκB level may also be caused by intracellular signals 
derived from virulence factor of the structure of Pg bacteria, 
ie peptidoglycan. Peptidoglycan, a bacterial cell wall, can 
be recognized by TLR-2 located on the cell membrane or by 
NOD1 and NOD2 located in the cytoplasm. This synergism 
between TLR and NOD-2 then can activate NFκB.24 

table 1. The mean and standard deviation levels of NFκB

NFκB
Treatment group

X + SD
Control group

X + SD

63,79 + 8,049 pg/ml 130,48 + 22,378 pg/ml

 

 

 

 

  

 

 

 

 

 

Figure1. NFκB level in the control group and the treatment group 

 

 

 

 

0

20

40

60

80

100

120

140

control group treatment group

figure1. NFκB levels in the control group and the treatment 
group. 



Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 56/DIKTI/Kep./2012.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG

�8 Krismariono/Dent. J. (Majalah Kedokteran Gigi) 2015 March; 48(1): 35–38

The focus of this research is to analyze the activity of 
the transcription factor NFκB used as a strategy for the 
prevention and treatment of periodontal disease, especially 
chronic periodontitis. From the results of this research, it is 
known that the administration of 1% curcumin can make 
NFκB level in the treatment group lower than that in the 
control group. This means that inflammation is the problem 
of tissue damage in chronic periodontitis disease, but its 
severity can be reduced by administration of curcumin. 
It can be concluded that 1% curcumin locally given in 
gingival sulcus can reduce the degree of inflammation 
in the periodontal tissues, especially gingival junctional 
epithelium, by decreasing NFκB level.

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