ARTICLE
Auteur(s) : S
Ouerhani1, K Rouissi1, R Marrakchi1, M Riadh Ben
Slama2, M Sfaxi2, M Ayed2, M
Chebil2, AB Elgaaied1
1Laboratoire de génétique, d’immunologie et de
pathologies humaines, faculté des sciences de Tunis El-Mannar-I,
2092 Tunis, Tunisie
2Service d’urologie, hôpital Charles-Nicole, Tunis,
Tunisie
Article reçu le 7 Novembre 2008, accepté le 19 Janvier 2009
Introduction
Bladder cancer is the fourth most common cancer in the men and the
ninth most common in the women [1]. Urothelial cell carcinomas
(UCC) represent more than 90% of bladder tumors and are classified
into superficial (pTa and pT1) and muscle invasive (≥ pT2) stages.
The majority of superficial tumors recur but progression to muscle
invasion is relatively infrequent. Only high-grade superficial
tumors (pTa GIII and pT1 GIII) progress to invasive disease and
represent a high-risk for death from disease [2]. The management of
bladder cancer is dependent on tumor stage and grade. The pTa
tumors are removed by transurethral resection, whereas invasive
tumors are treated by radical cystectomy with or without
postoperative chemotherapy. The pT1 tumors may be treated either as
pTa tumors or as pT2 tumors.
Cigarette smoking is the most important risk factor for bladder
cancer, accounting for 50% of cases in men and 35% in women [3].
A meta-analysis reported that cigarette smokers have a risk of
2.57 (95% confidence intervals [CI]: [2.20-3.00]) compared to
non-smokers [3]. Tobacco components, such as 4-aminobiphenyl
(4-ABP), increase bladder cancer risk by inducing local somatic
mutations. Indeed, the study of Feng et al. [4] has reported that
cigarette smoke generates a substantial amount of 4-ABP and
metabolically activated 4-ABP preferentially binds to codons 280
and 285 of the p53 gene. The p53 alterations occur predominantly in
invasive and high-grade superficial tumors [5]. In fact, Thompson
et al. [6] have suggested that bladder tumors in patients who smoke
tend to be large, multifocal and demonstrate high-histological
grade and stage.
Hypothetically, the mutational spectra of somatically altered
genes (such as p53) in environmentally associated cancers such as
bladder cancer may be influenced by the properties of relevant
phase I and phase II xenobiotic metabolizing enzymes, as well as by
the efficiency of the DNA repair system and other cellular host
factors. The xenobiotic-metabolizing machinery includes oxidative
enzymes (phase I), which may generally activate compounds to become
carcinogenic and phase II conjugating enzymes, considered rather
protective since they detoxify a number of reactive chemical
carcinogens [7]. The conjugating process (phase II) is mainly
controlled by the superfamilies of glutathione-S-transferases (GST)
and N-acetyl-transferases (NAT) enzymes. Polymorphisms in NAT and
GST genes alter the ability of these enzymes to metabolize
carcinogens. Indeed, epidemiological studies have shown that some
NAT2 polymorphisms have been correlated with decreased NAT2 enzyme
activities (“slow” alleles). The slow NAT2 acetylation genotype
compromises its detoxification ability, and studies have
consistently observed an association between the slow NAT2 genotype
and increased bladder cancer risk among smokers [8-10]. Moreover,
deletion of the genes and lack of the encoded enzyme have been
identified in both GSTM1 and GSTT1 loci. Subjects lacking GSTM1 are
at increased risk of developing environmentally related cancers
such as lung and bladder cancers [11, 12]. In some studies, the
GSTT1 null genotype has been suggested to be associated with an
increased risk of developing bladder [13] and lung cancers [14],
whereas other studies have reported that the risk of cancer was
increased only among those with the GSTT1 wild-type genotype [15,
16]. The identified polymorphisms in GST and NAT2 genes may
influence, by modulation of mutagenic DNA adduct levels, the
occurrence and type of critical mutations in oncogenes and in tumor
suppressor genes and thereby affect the individual susceptibility
to cancer.
Many previous case-control studies have analyzed the association
between risk factors (tobacco or genetic polymorphisms in
xenobiotic metabolizing enzyme) and bladder cancer development.
However, the relationship between these risk factors, the stage and
the grade of bladder tumors has not been evaluated. We therefore
examined in this study the combined effect of smoking and
polymorphisms in xenobiotic metabolizing enzymes (slow NAT2, GSTM1
and GSTT1 null genotypes) in different histological subgroups of
bladder tumors aiming at clarifying whether smoking and genetic
variations represent risk factors for the development of tumors
with high stage and grade. Efficient study design utilizing these
biomarkers should accelerate the development of optimum bladder
cancer prevention strategies.
Patients and methods
Patients
A total of 97 patients with UCC of bladder cancer were included in
the present study. Patients were recruited from the Department of
Urology at the Charles-Nicole Hospital in Tunisia. All were from
North of Tunisia, 90.07% of them were men, and the mean age at
diagnosis was 67.76 ± 9.04 years. These patients were
classified according to their tobacco status. The smoker category
included current smokers who smoked daily. A heavy smoker was
defined as a current smoker who had smoked 20 cigarettes or more
each day. Non-consumers of tobacco were defined as persons who had
never smoked or had consumed less than 20 packs of cigarettes or
360 g of tobacco in their lifetime or less than one cigarette
per day. The intensity of tobacco use (PY) was defined as the
amount of tobacco consumed during the life of patients (1 PY =
7 300 cigarettes smoked during 1 year). It was found that
81.45% (79/97) of patients were current smokers, and 18.55% were
non-tobacco consumers. It was found that 88.60% (70/79) of smokers
were heavy smokers and 53.16% (42/79) have smoked more than
40 PY.
Tumors were staged and graded according to the criteria of the
tumor-node-metastasis classification (TNM) and the
WHO-International Society of Urological Pathology as follows: 25
pTa GI, 11 pTa GII, 2 pTa GIII, 25 pT1 GII, 12 pT1 GIII and 22
invasive tumors (≥ pT2). After giving informed consent, peripheral
blood samples were collected from all patients into tubes with EDTA
at pH 8.
DNA preparation and genotyping
Genomic DNA was extracted from leukocytes using a phenol/chloroform
procedure [17]. The quality of genomic DNA was controlled by
electrophoresis on a 1% agarose gel stained with ethidium bromide.
GSTM1 and GSTT1 null genotypes were identified using a
multiplex-polymerase chain reaction (PCR)-based method as described
by Arand et al. [18]. For NAT2, a PCR was carried out as described
by Hsieh et al. [19]. The whole intronless NAT2 gene was resulted
in a 1093-base pair fragment that was then digested with 5 U
of KpnI, 10 U of BamHI, 5 U of TaqI and 10 U of
AluI, to reveal NAT2*5, NAT2*6, NAT2*7 and NAT2*14 alleles,
respectively. Digestions were performed at 37 °C overnight for
KpnI, BamHI and AluI and at 65 °C for TaqI. The obtained
fragments were separated on a 2% agarose gel.
Individuals with two wild-type alleles (NAT2*4/*4) were
classified as rapid acetylators, the others were classified as
intermediate acetylators when they had one mutant allele and as
slow acetylators when they had two mutant alleles including NAT2*5,
NAT2*6, NAT2*7 or NAT2*14 [20, 21].
Statistical analysis
The relative risks (RR) were estimated with 95% CI at the 0.05
significance level [22]. RR was calculated using non-smoker
patients with the homozygous wild-type genotypes as reference using
the software EpiInfo™ 6.0.
Results
Tumors were staged according to the criteria of the TNM
classification as follows: 75 superficial (pTa or pT1) and 22
invasive (≥ pT2). The percents of smokers developing superficial
and invasive tumors were 81.3 and 81.2%, respectively (table 1). The comparison of these percentages does
not show a significant statistical difference (P = 0.79), which
suggested that tobacco does not appear to be a factor affecting the
bladder tumors stage. The same result was obtained when we
stratified patients according to the intensity of tobacco use (table 1). The frequencies of slow NAT2, GSTM1
and GSTT1 null genotypes in patients with superficial tumors vs
those with invasive tumors were, respectively, at 52 vs 50%, 20 vs
31.8% and 36 vs 36.4% (table 1). The
comparison of these frequencies does not show a significant
statistical difference. Moreover, the stratification of superficial
and invasive tumors according to smoking status, GST and NAT2
genotypes does not show a significant statistical difference (table 2).
Among superficial tumors, 81.3% were with low-grade (GI or GII)
and 18.7% (14/75) were with high-grade (GIII). More than 90% of
patients with superficial low-grade tumors were smokers. This
percentage was statistically different from that reported for
patients with high-grade tumors (table
3). The high frequency of smokers in patients with
superficial low-grade tumors (used as a reference group) compared
to those with high-grade led to a RR < 1 (RR = 0.48; 95% CI:
[0.26-0.88]). The comparison of GSTM1 and GSTT1 null genotype
frequencies in patients with superficial low-grade and those with
superficial high-grade tumors does not show a significant
statistical difference (table 3). For
these genotypes, significant statistical differences were only
obtained, when we compared smokers to non-smoker patients (table 4). For NAT2 gene, a significant
statistical difference in genotypic distribution between patients
with superficial low-grade tumors and those with high-grade tumors
was detected for the intermediate NAT2 genotype (P = 0.04). This
genotype presented a 1.33-fold increased risk of developing
high-grade bladder tumors compared to reference group (RR = 1.33;
95% CI: [1.03-1.72]). This risk increases to 3.67 in non-smoker
patients carrying altered NAT2 genotypes compared to non-smoker
patients carrying rapid NAT2 genotype (P = 0.02; RR = 3.67; 95% CI:
[1.40-9.62]).
Table 1 The distribution of patients according to tumor
stage; tobacco status and xenobiotic metabolizing enzyme
genotypes.
|
Tumors stage
|
P
|
RR (CI 95%)
|
|
|
|
Smoking status
|
|
|
|
|
|
Non-smokers
|
14 (18.7%)
|
04 (18.2%)
|
|
1a
|
|
Smokers
|
61 (81.3%)
|
18 (81.2%)
|
0.79
|
–
|
|
1-19 PY
|
09 (14.75%)
|
00 (00.0%)
|
0.33
|
–
|
|
20-39 PY
|
18 (29.5%)
|
10 (55.5%)
|
0.52
|
–
|
|
≥ 40 PY
|
34 (55.75%)
|
08 (44.5%)
|
0.94
|
–
|
|
GSTM1 genotype
|
|
|
|
|
|
Wild-type
|
36 (48.0%)
|
11 (50.0%)
|
|
1a
|
|
Null
|
39 (52.0%)
|
11 (50.0%)
|
0.93
|
–
|
|
GSTT1 genotype
|
|
|
|
|
|
Wild-type
|
60 (80.0%)
|
15 (68.2%)
|
|
1a
|
|
Null
|
15 (20.0%)
|
07 (31.8%)
|
0.38
|
–
|
|
NAT2 genotype
|
|
|
|
|
|
Rapid
|
20 (26.7%)
|
03 (13.6%)
|
|
1a
|
|
Intermediate
|
28 (37.3%)
|
11 (50.0%)
|
0.28
|
–
|
|
Slow
|
27 (36.0%)
|
08 (36.4%)
|
0.55
|
–
|
aReference group.
Table 2 Stratification of GST and NAT2 genotypes in
superficial and invasive tumors according to smoking status.
|
Tobacco status
|
Genotypes
|
pTa/pT1
|
≥ pT2
|
P
|
RR (CI 95%)
|
|
GSTM1
|
|
|
|
|
|
Non-smokers
|
Wild-type
|
9
|
1
|
|
1a
|
|
Null
|
5
|
3
|
0.27
|
–
|
|
Smokers (≥ 20 PY)
|
Wild-type
|
24
|
10
|
0.40
|
–
|
|
Null
|
28
|
8
|
0.65
|
–
|
|
GSTT1
|
|
|
|
|
|
Non-smokers
|
Wild-type
|
9
|
2
|
|
1a
|
|
Null
|
5
|
2
|
1
|
–
|
|
Smokers (≥ 20 PY)
|
Wild-type
|
43
|
13
|
0.97
|
–
|
|
Null
|
9
|
5
|
0.40
|
–
|
|
NAT2
|
|
|
|
|
|
Non-smokers
|
Rapid
|
3
|
1
|
|
1a
|
|
Intermediate
|
6
|
2
|
0.47
|
–
|
|
Slow
|
5
|
1
|
0.62
|
–
|
|
Smokers (≥ 20 PY)
|
Rapid
|
14
|
2
|
0.50
|
–
|
|
Intermediate
|
19
|
9
|
0.77
|
–
|
|
Slow
|
19
|
7
|
0.59
|
–
|
aReference group.
Table 3 Distribution of patients with superficial
bladder tumors according to tumor grade, smoking status and
xenobiotic metabolizing enzyme genotypes.
|
Grade of superficial tumors
|
P
|
RR (CI 95%)
|
|
I/II (N = 61)
|
III (N = 14)
|
|
Smoking status
|
|
|
|
|
|
Non-smokers
|
6 (9.8%)
|
8 (57.14%)
|
|
1a
|
|
Smokers
|
55 (90.2%)
|
6 (41.16%)
|
0.0002
|
0.48 [0.26-0.88]
|
|
1-19 PY
|
8 (14.55%)
|
1 (16.66%)
|
0.07
|
–
|
|
20-39 PY
|
17 (30.9%)
|
1 (16.66%)
|
0.004
|
0.45 [0.25-0.84]
|
|
≥ 40 PY
|
30 (54.55%)
|
4 (66.66%)
|
0.003
|
0.49 [0.26-0.90]
|
|
GSTM1 genotype
|
|
|
|
|
|
Wild-type
|
29 (47.55%)
|
7 (50%)
|
|
1a
|
|
Null
|
32 (52.45%)
|
7 (50%)
|
0.89
|
–
|
|
GSTT1 genotype
|
|
|
|
|
|
Wild-type
|
50 (81.97%)
|
10 (71.42%)
|
|
1a
|
|
Null
|
11 (18.03%)
|
4 (28.58%)
|
0.60
|
–
|
|
NAT2 genotype
|
|
|
|
|
|
Rapid
|
19 (31.15%)
|
1 (7.14%)
|
|
1a
|
|
Intermediate
|
20 (32.78%)
|
8 (57.14%)
|
0.04
|
1.33 [1.03-1.72]
|
|
Slow
|
22 (36.07%)
|
5 (35.72%)
|
0.35
|
–
|
aReference group.
Table 4 Stratification of GST and NAT2 genotypes in
superficial low- and high-grade tumors according to smoking
status.
|
Tobacco status
|
Genotypes
|
GI/GII
|
GIII
|
P
|
RR (CI 95%)
|
|
GSTM1
|
|
|
|
|
|
Non-smokers
|
Wild-type
|
5
|
4
|
|
1a
|
|
Null
|
1
|
4
|
0.30
|
–
|
|
Smokers (≥ 20 PY)
|
Wild-type
|
21
|
3
|
0.06
|
–
|
|
Null
|
26
|
2
|
0.02
|
0.60 [0.33-1.08]
|
|
GSTT1
|
|
|
|
|
|
Non-smokers
|
Wild-type
|
4
|
5
|
|
1a
|
|
Null
|
2
|
3
|
0.65
|
–
|
|
Smokers (≥ 20 PY)
|
Wild-type
|
39
|
4
|
0.004
|
0.49 [0.23-1.02]
|
|
Null
|
8
|
1
|
0.13
|
–
|
|
NAT2
|
|
|
|
|
|
Non-smokers
|
Rapid
|
3
|
0
|
|
1a
|
|
Intermediate/slow
|
3
|
8
|
0.02
|
3.67 [1.40-9.62]
|
|
Smokers (≥ 20 PY)
|
Rapid
|
14
|
0
|
–
|
–
|
|
Intermediate/slow
|
33
|
5
|
0.80
|
–
|
aReference group.
Discussion
UCC is a heterogeneous neoplasm that presents as either superficial
or muscle invasive at diagnosis. Superficial low-grade tumors are
characterized by frequent recurrences. In contrast, high-grade
tumors (pTa GIII and pT1 GIII) represent a significant risk of
future tumors progression and death for the disease. Tobacco smoke
is the most important exogenous risk factor for bladder cancer. The
elimination of tobacco carcinogens is carried out by phase I and
phase II xenobiotic metabolizing enzymes. In order to determine the
combined effect of smoking and genetic polymorphisms in xenobiotic
metabolizing enzymes on the histological stage and grade of bladder
tumors from Tunisian population, 97 patients with UCC were examined
with respect to smoking status and NAT2, GSTM1 and GSTT1 genotype
distribution.
Our data show that 81.45% (79/97) of patients were current
smokers and 18.55% were non-tobacco consumers. It was found that
88.60% (70/79) of smokers were heavy smokers, and 53.16% (42/79)
have smoked more than 40 PY. These results suggested the
important role of tobacco in bladder cancer development in the
Tunisian population. Indeed, other studies have reported that
smokers are two to three times more likely to develop UCC, and 50%
of all bladder tumors are directly attributable to cigarette
smoking [23, 24]. The distribution of patients according to smoking
status and histological tumors and stage has suggested that the
frequency of smokers in the superficial tumor group was not
different from that reported in the invasive tumor group (P >
0.05). Conversely, the percentage of smokers in the superficial
low-grade tumor group was higher than that found in the superficial
high-grade tumor group. We conclude that in Tunisian patients,
tobacco does not appear to be a factor affecting the tumor stage,
but was essentially associated with the development of superficial
low-grade tumors. This finding was in contradiction with several
other studies, which have suggested that bladder tumors in patients
who smoke tend to be large, multifocal and demonstrate
high-histological grade and stage [6].
The distribution of patients according to genotypic frequencies
of GSTM1 and GSTT1 genotypes and histological tumors stage did not
show a significant statistical difference. This result suggests
that genetic polymorphisms in GST enzymes do not appear as a factor
affecting the histological tumor stage. Similarly, the comparison
of GSTM1 and GSTT1 genotype frequencies between patients with
superficial low-grade, and those with superficial high-grade tumors
did not show a significant statistical difference. The association
between GSTM1 null genotype and the GSTT1 wild-type genotype and
superficial low-grade tumors was only obtained when we compared
smoking patients to non-smokers. This association was essentially
attributed to the direct effect of tobacco carcinogens. Our
hypothesis suggests that in superficial low-grade tumors, tobacco
carcinogens in interaction with GST enzymes induce somatic
mutations in FGFR3 oncogene (fibroblast growth factor receptor 3).
This oncogene has been shown to be the most frequently altered gene
in low-grade tumors [25]. Until now, only one study has studied the
effect of tobacco carcinogens on the FGFR3 mutation spectrum and
did not report any correlation [26].
The distribution of patients according to genotypic frequencies
of NAT2 and histological tumor grade has suggested that non-smoker
patients carrying an altered NAT2 genotypes presented a 3.67-fold
increased risk of developing high-grade bladder tumors compared to
non-smokers patients carrying a rapid NAT2 (P = 0.02; RR = 3.67;
95% CI: [1.40-9.62]). Our hypothesis suggests that in the absence
of tobacco, which was the most important environmental risk factor,
the role of genetic factors will be essential in determining the
initiation of pathology. The altered NAT2 alleles increase the risk
of bladder cancer development by increasing somatic mutation in
tumors suppressor genes. Indeed, previous studies suggest that the
NAT2 slow acetylator genotypes may be associated with an impaired
metabolism of carcinogens that predispose individuals to p53 gene
mutations, which were associated with the development of
superficial high-grade bladder tumors [27].
Although some of the results presented here are novel, this
study has some limitations. Firstly, the sample size is small,
limiting the precision of the statistical analyses. Secondly, we
have not information regarding somatic altered genes such as FGFR3
and p53, which were respectively, associated with superficial low-
and high-grade bladder tumors. Besides that in the future,
enlargement of sample sizes in the Tunisian population and analysis
of somatic altered genes (which is already ongoing) will be
essential to assess the role that environmental factors together
with the genetic factors play as predictors of differential
susceptibility to the presentation of malignancy.
Conclusion
In conclusion, our data support the idea that tobacco and
polymorphisms in xenobiotic metabolizing enzymes were not
associated with tumor stages overall, but can affect the grade of
superficial tumors. The orientation to superficial low- or
high-grade tumors depends on the somatic altered genes. This
hypothesis could be tested through the evaluation of the somatic
gene alterations in bladder tumor patients stratified by smoking
status.
Conflict of interest: Authors confirm that they do not have any
disclosure to make at submission, and none of them has any
potential financial conflict of interest related do this
manuscript.
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