138

Dental Journal
(Majalah Kedokteran Gigi)
2019 September; 52(3): 138–141

Research Report

Effects of sidestream tobacco smoke on P53 expressions in 
Rattus novergicus tongue epithelial mucosa

Dian Angriany,1 Diah Savitri Ernawati,1 Adiastuti Endah Parmadiati,1 Hening Tuti Hendarti1 and Rosnah Binti Zain2
1Department of Oral Medicine, Faculty of Dental Medicine, Universitas Airlangga, Surabaya – Indonesia
2Department of Oral Pathology and Oral Medicine, Faculty of Dentistry, MAHSA University, Bandar Saujana Putra – Malaysia

ABSTRACT
Background: Smoking, both active and passive, has been widely recognised as toxic to the human body, since it induces several 
forms of cancer, including that affecting the oral cavity. Benzopyrene, the carcinogen contained in tobacco smoke, can even lead to 
carcinogenesis which potentially affects the regulation of cell apoptosis in both active and passive smokers. Purpose: This study aims 
to investigate the carcinogenic effects of cigarette smoke on apoptosis of rat tongue mucosae through p53 expression. To determine 
the risk of malignant transformation through tumor suppressor genes in the apoptotic pathway. Methods: Rattus norvegicus subjects 
were divided into four groups, namely Treatment Group 1 exposed to sidestream cigarette smoke for four weeks (P1), Treatment 
Group 2 exposed to sidestream cigarette smoke for eight weeks (P2), Control Group not exposed to sidestream cigarette smoke for 
four weeks (K2), and Control Group (K) not exposed to sidestream cigarette smoke for eight weeks (K2). The exposure process was 
conducted using a smoking pump and alternating exposure. Four micron-thick sections of formalin were subsequently fixed together 
with paraffin embedded biopsy material from tongue mucosa of Rattus norvegicus. The tissue sections from the treatment groups were 
then analyzed immunohistochemically to compare the expressions of p53 and Bcl-2 proteins with those of the control groups. Results: 
The T-test results indicated statistically significant differences in the expressions of p53 between the 4-week control group (K1) and 
the 4-week treatment group (P1) (p=0.01, p<0.05) as well as between the 8-week control group (K2) and the 8-week treatment group 
(P2) (p=0.03, p<0.05). Conclusion: Exposure to cigarette smoke can induce changes in tumor suppressor genes and also affect the 
regulation of cell apoptosis, thus changing cell structure and leading to malignancy. 

Keywords: apoptosis; carcinogenesis; sidestream cigarette smoke; p53; tongue mucosa

Correspondence: Diah Savitri Ernawati, Department of Oral Medicine, Faculty of Dental Medicine, Universitas Airlangga. Jl. Mayjend. 
Prof. Dr. Moestopo no. 47 Surabaya 60132, Indonesia. E-mail: diah -s-e@fkg.unair.ac.id

INTRODUCTION

Over the last 50 years, numerous studies have been 
conducted on the toxic chemicals contained in cigarette 
smoke which are regarded as carcinogens for humans. 
Cigarette smoke is one risk factor for oral cancer in 
both active and passive smokers due to the presence of 
carcinogenic elements that can potentially induce cancer. 
Passive smokers inhale the second-hand environmental 
cigarette smoke exhaled by active smokers.

Smoke inhaled by passive smokers can also cause health 
problems similar to those experienced by active smokers 
since it contains approximately 200 toxic substances, 69 of 
which are carcinogenic. These carcinogens form covalent 

bonds with DNA (DNA adducts) subsequently inducing 
carcinogenesis.1,2 The correlation between both active 
and passive smoking and carcinogenesis has actually been 
studied and identified to exist in several forms of cancer. A 
high risk of smoking-related cancers also relates to the head 
and neck. These include cancer of the oral cavity, pharynx 
and larynx, in addition to lung cancer.3

The process of carcinogenesis is a somatic event thought 
to be caused by accumulative genetic and epigenetic 
changes affecting the normal molecular control settings in 
cell proliferation. These genetic changes can subsequently 
deactivate the tumor suppressor gene, thereby triggering 
tumor formation.4 The tumor suppressor gene (p53 gene) 
is a transcription factor that activates a large number of 

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.v52.i3.p138–141

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139Angriany, et al./Dent. J. (Majalah Kedokteran Gigi) 2019 September; 52(3): 138–141

Table 1. The expressions of p53 in the control groups and the 
treatment groups after exposure to cigarette smoke for 
4 and 8 weeks

Groups Mean + SD P
K1 13.17 + 2.9

0.01*
P1 7.17 + 3.8
K2 14.17 + 3.8

0.03*
P2 7.5 + 1.9

 

13.17

7.17

14.17

7.5

0

2

4

6

8

10

12

14

16

4 weeks 4 weeks 8 weeks 8 weeks

control treatment control treatment

p53 Expression

Figure 1. The graph of the average p53 expressions in the 4-week control group and the 4-week treatment group as well as between 
the 8-week control group and the 8-week treatment group.

gene expressions involved in cell cycle regulation and 
apoptosis. The p53 gene is the first tumor suppressor gene 
identified in cancer cells whose working mechanism is 
normally in an inactive state. It will become active if the 
cell experiences stress. Loss of function in the p53 gene due 
to mutations can affect the apoptotic mechanism involving 
the bcl-2 and caspase genes. The mechanism of the p53 gene 
induces apoptosis by stimulating mitochondria through the 
induction of the Bax gene to release cytochrome c to the 
cytosol to form caspase cascade.5

In addition, carcinogenesis conditions can induce 
changes in cells, resulting in malignancy. Therefore, this 
study aims to examine the carcinogenic effects of cigarette 
smoke exposure on the mucosa of the rat’s tongue against 
apoptosis through p53 expressions.

MATERIALS AND METHODS

This study was received ethical approval from the Ethics 
Committee of the Faculty of Dental Medicine, Universitas 
Airlangga, (No: 769/HRECC.FODM/XII/2019). This study 
constitutes experimental laboratory research involving 24 
male Wistar strain rats (Rattus norvegicus) aged 3-week 
old and 170 grams in weight which had been obtained 
from the Biochemical Laboratory of Universitas Airlangga, 
Surabaya. The inclusion criteria for these Wistar rats 
comprised; a good state of health, a body weight of 160-180 
grams, and a 1-week adaptation period during which they 
had to satisfy the requirements of being clear-eyed, having 
a shiny coat, being agile, and passing firm stools. 

This study was conducted at the Biochemistry 
Laboratory of Universitas Airlangga, Surabaya and the 
Biomolecular Laboratory of Universitas Brawijaya, 
Malang. The Wistar rats were divided into four groups, 
namely two control groups consisting of a 4-week control 
group and an 8-week control group, as well as two treatment 
groups composed of a 4-week treatment group and an 
8-week treatment group. Each group contained 6 members. 
The subjects in the treatment groups were exposed to 
unfiltered clove cigarette smoke with a tar content of 34 
mg and a nicotine content of 2.1 mg via a smoking pump 

which ensured constant exposure to a dose equivalent to 
that of 20 cigarettes per day.6 Meanwhile, the subjects in 
the control groups received their usual rations of food and 
drink and were placed in an open space.

After completion of the planned treatment, the subjects 
were sacrificed by means of inhalation of lethal doses of 
ether. Those in Treatment Group 1 and Control Group 1 were 
sacrificed at the end of the 4th week, while their counterparts 
in Treatment Group 2 and Control Group 2 were sacrificed 
at the end of the 8th week. Following excision of their 
tongue mucosa, histological preparations were produced. 
The tissue sections were immunohistochemically analyzed 
for the expression of p53 gene.

The preparations were examined through a Nikon e100 
light microscope at 400x magnification in order to calculate 
their p53 expressions. The results of each parameter were 
then analyzed statistically. A Shapiro-Wilk normality test 
was carried out to determine the distribution of research 
data, followed by a Levene’s variance homogeneity test. If 
the results showed normally distributed data, a paired two-
sample T test was subsequently performed. The analysis 
was carried out using SPSS for Windows version 16 (IBM, 
Armonk, New York, USA).

RESULTS

The mean and standard deviation of p53 expressions in the 
control groups and the treatment groups after exposure to 
cigarette smoke for four weeks and eight weeks are presented 
in Table 1 and Figure 1. The p53 immunohistochemical 
staining process results can be seen in Figure 2. The T test 

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.v52.i3.p138–141

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140 Angriany, et al./Dent. J. (Majalah Kedokteran Gigi) 2019 September; 52(3): 138–141

 

A B 

C D 

Figure 2. A. Description of wild p53 expression in the 4-week control group (K1) B. Description of wild p53 expression in the 4-week 
treatment group (P1) C. Description of wild p53 expression in the 8-week control group (K2) D. Description of wild p53 
expression in the 8-week treatment group (P2). p53 expression showed by red arrow.

results indicated a significant difference in p53 expression 
between the control and treatment groups after cigarette 
smoke exposure for four weeks (p=0.01, p<0.05). Similarly, 
there was also a significant difference in p53 expression 
between the control and treatment groups after cigarette 
smoke exposure for eight weeks (p=0.03, p<0.01).

DISCUSSION

In general, unfiltered clove cigarettes are more dangerous 
than their filtered counterparts due to a higher tar, nicotine 
and carbon monoxide (CO) content. The cloves contained in 
such cigarettes actually constitute an additive whose effect 
is that the mixture of tobacco and cloves can increase the 
temperature of a lighted cigarette. As a result, the CO and 
nicotine levels of clove cigarettes are three times higher 
than those of tobacco-only cigarettes, while their tar levels 
are as much as to five times higher.7

Cigarette smoke can potentially induce cancer due to 
the presence of carcinogenic elements. Consequently, it 
is considered a risk factor of oral cancer in both active 
and passive smokers, influenced by the duration and dose 
of exposure to it. A previous study by Kushihashi et al. 
(2012),3  assessed the impact of the number of cigarettes 
smoked per day and the duration of smoking among active 
smokers or that of cigarette exposure among passive 
smokers on the occurrence of head and neck cancer. The 
study argued that smoking plays a significant role in the 
development of squamous cell carcinoma (p = 0.0338).

The development of oral cancer is a complex process 
that can be observed through the use of animal models. 
Their use facilitates accurate and representative descriptions 
of cellular and molecular changes which have been analyzed 
histopathologically and which arise from the initiation and 
development of oral cancer due to a change from normal 
to pathological conditions.8

Employing in vivo animal models as research subjects 
renders the initiation, promotion, development and 
metastasis of cancer, including oral cancer, observable.9 
Therefore, this study was conducted using 3-month-old, 
male, Wistar rats (Rattus norvegicus) which represent 
the most widely employed animal subjects for laboratory 
research and which, at the age of three months, have reached 
biological maturity.10 Male Wistar rats were chosen as 
research subjects because their conditions are not affected 
by hormonal factors, such as the menstrual cycle and 
pregnancy.11 Hormonal changes can affect the immunity 
of the subjects which will, in turn, affect the results of the 
study.12 p53 constitutes a group of tumor suppressor gene 
proteins playing a role in cell growth control in the nucleus, 
particularly with regard to the cell division cycle.

This study produced significant decreases in the level 
of p53 expressions in the 4-week treatment group (p = 
0.01, p<0.05) and the 8-week treatment group (p=0.03, 
p<0.05) after exposure to cigarette smoke for 4 and 8 
weeks. Similarly, a previous study conducted by Husgafvel 
et al. (2000),13  focused on non-smokers to ascertain the 
relationship between exposure to environmental tobacco 
smoke (ETS) and lung cancer in non-smokers and employed 
both frequency biomarkers and p53 mutation types as 
carcinogenetic biomarkers associated with tobacco use. 
It concluded that ETS directly exhaled into the air can 
negatively affect the health of non-smokers without 
their even inhaling it since ETS contains carcinogenic 
substances. 

The increase in mutant p53 in cases of lung cancer is 
potentially experienced to a greater extent by non-smokers 
who are in the immediate vicinity of smokers and, therefore, 
exposed to ETS. This indicates that prolonged exposure 
to second-hand smoke increases the risk of neoplasia in 
non-smokers.13 Other oral cancer-related studies have 
been carried out by inducing rats through exposure to 
carcinogens in the oral cavity such as those found in tobacco 

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.v52.i3.p138–141

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http://dx.doi.org/10.20473/j.djmkg.v52.i3.p138-141


141Angriany, et al./Dent. J. (Majalah Kedokteran Gigi) 2019 September; 52(3): 138–141

cigarettes.14 One such investigation was conducted by 
Pfeifer et al. (2002),15  which found a strong correlation 
between smoking and oral cancer through analysis of the 
p53 mutation spectrum.

The increased amount of carcinogenic material 
absorbed by mucosal epithelial cells will heighten the 
risk of oncogene, tumor suppressor gene (TSG) and 
deoxyribonucleic acid (DNArg) mutations that play a 
role in cell division. 4-(methylnitrosamino)-1-(3-pyridyl)-
1-butanone (NNK) and N'-nitrosonornicotine (NNN), 
together with cigarette smoke content, for example 
polycyclic aromatic hydrocarbons (HAP), are able to 
modify DNA nitrogen bases through methylation and 
hydroxylation. Other ingredients, such as nitric oxide (NO) 
and free radical compounds, can induce the accumulation of 
free radicals in the oral mucosa. The excessive activity of 
free radicals and other reactive elements can subsequently 
lead to oxidative stress resulting in genomic instability, 
such as modification of DNA nitrogen bases potentially 
leading to gene mutations. The modification of the DNA 
nitrogen base can promote DNA adduction potentially 
leading to damage to the DNA of oral mucosal epithelial 
cells. DNA damage, in turn, triggers the oncogene, TSG 
and DNArg mutations.

The gene mutations can indicate whether changes 
in malignant epithelial cells of the oral mucosa have 
been initiated.2,16 Similarly, in this study, the decreased 
expression of p53 due to exposure to cigarette smoke 
shows that gene mutations can normally affect the cell 
cycle and initiate the risk of malignancy. In conclusion, 
this study argues that exposure to cigarette smoke can 
cause decreased expression of wild p53 leading to the cells 
becoming malignant.

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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.v52.i3.p138–141

http://e-journal.unair.ac.id/index.php/MKG
http://dx.doi.org/10.20473/j.djmkg.v52.i3.p138-141