Keywords:
XRCC1 - XRCC3 - Polymorphism, genetic - Papillomaviridae - Uterine cervical neoplasms
Descritores:
XRCC1 - XRCC3 - Polymorphism genético - Papillomaviridae - Neoplasias do colo do útero
INTRODUCTION
Cervical cancer is one of the most frequent cancers in women. It is well established
that the human papillomavirus (HPV) is imputed as a prime etiologic factor of cervical
carcinoma and its precursor lesion, cervical intraepithelial neoplasia (CIN). Around
30% of women with sexual experience are infected with high-risk HPV. However, only
1% of these women will develop CIN and cervical carcinoma. This indicates that HPV
infection is not sufficient to develop CIN or cancer, and other cofactors, such as
polymorphisms in DNA repair genes, should be considered.[1]
DNA repair genes play a key role in maintaining genomic stability and integrity. It
is now thought that an individual’s DNA repair capacity is genetically determined,
and is the result of a combination of multiple genes that display subtle differences
in their activity. Single nucleotide polymorphisms (SNPs) may cause subtle structural
alterations in repair enzymes, and subsequent modulation of cancer susceptibility.
In humans, more than 100 genes are involved in the 5 major DNA repair pathways, including
nucleotide excision repair (NER) and homologous recombinational repair.[2]
A number of SNPs in DNA repair genes have been identified. Defects in DNA repair pathways
are found to be associated with many types of cancer, including cervical carcinoma.[3] Polymorphisms in DNA repair genes are common. Studies have revealed that the effects
of these polymorphisms on DNA repair ability contribute to individual differences.[3] There are two important genes involved in this process. One, the X-Ray Repair Cross
Complementing 1 (XRCC1) gene involved in the Base Excision Repair (BER) pathway, is
linked with a scaffolding protein that directly associates with other proteins, such
as DNA polymerase ß , PARP (ADP-ribose polymerase) and DNA ligase III, in a complex
that facilitates processes of BER DNA repair[4] The other, XRCC3, one of the key components of the homologous repair (HR) pathway,
functions in the cross-link repair of DNA double-strand breaks (DSBs) by interacting
and stabilizing Rad51.(5,6) It is common knowledge that chromosome damage results from non- or misrepaired DSBs,
with many polymorphisms, such as those of DNA repair genes, having been associated
with increased cancer risk, and a possibly even higher level of chromosome damage.(7)Thus, our hereby was to investigate the relationship between XRCC1 and XRCC3 polymorphisms
and chromosomal damage in women with cervical cancer and healthy controls. We genotyped
3 variants of the 2 DNA repair genes XRCC1 (Arg194Trp and Arg399Gln) and XRCC3 (Thr241Met),
and assessed their contributions to cervical cancer susceptibility, and their association
with other epidemiological risk factors.
METHODS
Experimental subjects (Patients)
Patients with histologically confirmed primary cervical cancer were recruited from
the city of Campo Grande, Mato Grosso do Sul State (Southwestern Brazil) from June
2014 to November 2015 at the Alfredo Abrão Cancer Hospital. The study was performed
in collaboration with the Molecular Gynecology and Metabolomics Laboratory at the
College of Medicine of the Federal University of São Paulo (EPM-UNIFESP), in São Paulo.
Controls were randomly selected from healthy postmenopausal women who requested gynecological
examinations. The criteria for selection included no positive findings during examination,
no history of cancer. Sexual and reproductive history was obtained using a standardized
questionnaire. A total of 77 eligible patients (70 carcinoma and 7 adenocarcinoma
patients) and 73 eligible control women were interviewed, completed the questionnaires,
consented to provide blood samples for genotyping. Experiments were undertaken with
the understanding and written consent of each subject, and that the study conforms
with The Code of Ethics of the World Medical Association (Declaration of Helsinki)
and the study protocol was approved by the Federal University of São Paulo’s Institutional
Review Board [IRB no. CEP1367/06] and each participant signed an informed consent.
Genotyping
Genomic DNA was extracted and purified using the Illustra® blood genomicPrep Mini
Spin Kit (G&E HealthCare, Little Chalfont, UK) from peripheral blood lymphocytes.
The polymorphisms of the 3 SNPs were detected using amplification polymerase chain
reaction with restriction fragment length polymorphism (primers showed in[table 1]).[8]-[10]
Table 1
Primer sets for the amplification of XRCC1 and XRCC3 polymorphisms by polymerase chain
reaction and RFLP enzymes
|
Gene
|
Primer sequences
|
RFLP enzyme
|
PCR product length (bp)
|
Annealing Temp (°C)
|
|
XRCC1(Arg194Trp)
|
5’- GCCCCGTCCCAGGTA -3’
|
PvuII
|
490
|
62
|
|
5’- AGCCCCAAGACCCTTTCACT -3’
|
|
XRCC1(Arg399Gln)
|
5’- TCTCCCTTGGTCTCCAACCT -3’
|
MspI
|
402
|
60
|
|
5’- AGTAGTCT GCTGGCTCTGG -3’
|
|
XRCC3(Thr241Met)
|
5’- GGTCGAGTGACAGTCCAAAC -3’
|
NlaIII
|
315
|
60
|
|
5’- TGCAACGGC TGAGGGTCTT -3’
|
Primer sequences, endonucleases, and PCR product length.
Statistical analysis
Genotype and allele frequencies between the cases and controls were evaluated by the
Chi square test. Univariate and multivariate logistic regression was applied to calculate
odds ratios (ORs) and 95% confidence intervals (CIs), respectively, for the association
between the genotypes and risk of cervical carcinoma. The association between the
frequencies of all the variant genotypes and cervical cancer risk factors was also
evaluated by stratification analyses.
RESULTS
Characteristics of the population
There were no differences regarding the ethnics origin of studied population, among
cases 49.1% (n=52) were caucasians and 56.8% (n=25) were non-caucasians compared to
50.9% (n=54) and 43.2% (n=19) in the control group (Chi2 = 0.75; p=0.47). Of the 77
cancer patients, 70 (90.9%) had squamous cell carcinomas, 7 (9.1%) adenocarcinomas.
Of the 77 cancer patients, 8 (10.4%) were IA stage, 3 (3.9%) were IIA stage, 9 (11.7%)
were IIIA stage, 5 (6.5%) were IVA stage, 12 (15.6%) were IB stage, 16 (20.8%) were
IIB stage, 23 (29.9%) were IIIB stage and 1 was IVB stage ([Table 2]).
Table 2
Clinical stage of cervical cancer patients
|
Clinical Stage
|
N
|
%
|
|
IA
|
8
|
10.4
|
|
IB
|
12
|
15.6
|
|
IIA
|
3
|
3.9
|
|
IIB
|
16
|
20.8
|
|
IIIA
|
9
|
11.7
|
|
IIIB
|
23
|
29.9
|
|
IVA
|
5
|
6.5
|
|
IVB
|
1
|
1.3
|
|
Total
|
77
|
100.0
|
Distribution of the study cases according to the FIGO staging of cervical cancer.
Cases of cervical intraepithelial neoplasia (CIN) were excluded from the study. The
median ages of the cancer patients were 54.6 (range 20-86) years and control women
were 52.3 (range 43-71) years (U = 2,532; p = 0.29). The sexual and reproductive histories
including menarche, number of pregnancies, age at the first parity, number of abortions,
menopause age, among cancer patients and controls were significantly different ([Table 3]).
Table 3
Quantitative variables among cases and controls
|
Variables
|
|
N
|
Mean
|
Std. Dev.
|
Median
|
Min.
|
Max.
|
U
|
P-value
|
|
Age of menarche
|
Cases
|
77
|
12.13
|
1.23
|
12
|
10
|
16
|
1,539
|
<0.001
|
|
Controls
|
73
|
13.47
|
1.79
|
13
|
10
|
18
|
|
Age of menopause
|
Cases
|
56
|
47.46
|
3.01
|
48
|
40
|
55
|
1,282
|
<0.001
|
|
Controls
|
73
|
49.47
|
3.20
|
50
|
41
|
55
|
|
Number of pregnancies
|
Cases
|
77
|
4.97
|
3.92
|
4
|
0
|
19
|
2,282
|
0.04
|
|
Controls
|
73
|
3.48
|
1.67
|
3
|
1
|
9
|
|
Number of parities
|
Cases
|
77
|
4.49
|
3.34
|
4
|
0
|
17
|
1,982
|
<0.001
|
|
Controls
|
73
|
2.89
|
1.44
|
3
|
0
|
9
|
|
Number of abortions
|
Cases
|
77
|
0.48
|
1.14
|
0
|
0
|
8
|
2,439
|
0.13
|
|
Controls
|
73
|
0.60
|
0.94
|
0
|
0
|
5
|
Descriptive analysis of quantitative variables among cases and controls. Results obtained
after Mann-Whitnney analysis
The genotypic and allelic frequencies
The genotype distributions and the allele frequencies of all 3 SNPs among cases and
controls were not significantly different (Tables 4 and 5).
Table 4
Genotype analysis
|
|
Wild
|
Heterozygote
|
Homozygote
|
Total
|
Exact Fisher test
|
|
|
N (%)
|
N (%)
|
N (%)
|
N (%)
|
|
|
XRCC1 (Arg194Trp)
|
|
Cases
|
60 (77.9)
|
16 (20.8)
|
1 (1.3)
|
77 (100)
|
1.00
|
|
Controls
|
57 (78.1)
|
16 (21.9)
|
0 (0.0)
|
73 (100)
|
|
|
|
XRCC1 (Arg399Gln)
|
|
Cases
|
13 (16.9)
|
28 (36.4)
|
36 (46.8)
|
77 (100)
|
0.01
|
|
Controls
|
10 (13.7)
|
47 (64.4)
|
16 (21.9)
|
73 (100)
|
|
XRCC3 (Thr241Met)
|
|
Cases
|
43 (55.8)
|
28 (36.4)
|
6 (7,8)
|
77 (100)
|
0.74
|
|
Controls
|
36 (48.6)
|
30 (41.7)
|
7 (9.7)
|
73 (100)
|
|
|
Genotype distribution of polymorphisms in a case-control study. P values calculated
according to the Exact Fisher Test.
Table 5
Allelic frequencies
|
|
wild
|
polymorphic
|
total
|
Exact Fisher test
|
|
|
N (%)
|
N (%)
|
N
|
|
|
XRCC1 (Arg194Trp)
|
|
Cases
|
136 (88.3)
|
18 (11.7)
|
154
|
0.86
|
|
Controls
|
130 (89.0)
|
16 (11.0)
|
146
|
|
|
XRCC1 (Arg399Gln)
|
|
Cases
|
54 (35.1)
|
100 (64.9)
|
154
|
0.06
|
|
Controls
|
67 (45.9)
|
79 (54.1)
|
146
|
|
|
XRCC3 (Thr241Met)
|
|
Cases
|
114 (74.0)
|
40 (26.0)
|
154
|
0.44
|
|
Controls
|
102 (69.9)
|
44 (30.1)
|
146
|
|
|
Allelic distribution of polymorphisms in a case-control study. P-values calculated
according to the Exact Fisher Test.
Non-adjusted odds ratio estimation of risk for cervical cancer
Neither XRCC1 or XRCC3 (heterozygotes or mutated genotypes) influenced the risk for
cervical carcinoma when using wildtype genotypes as references.
None of the variants among these 3 SNPs increased or decreased the risk for cervical
cancer ([Table 6]).
Table 6
Non-adjusted Odds Ratio correlation analysis of XRCC1 and XRCC3 polymorphisms and
the risk for cervical carcinoma
|
|
|
Odds Ratio
|
95% CI
|
P-value
|
|
XRCC1 (Arg194Trp)
|
|
Wild
|
(CC)
|
1
|
|
|
|
Heterozygote
|
(CT)
|
0.95
|
0.43 - 2.08
|
0.90
|
|
Mutated
|
(TT)
|
NA
|
NA
|
NA
|
|
XRCC1 (Arg399Gln)
|
|
Wild
|
(GG)
|
1
|
|
|
|
Heterozygote
|
(GA)
|
0.46
|
0.18 - 1.18
|
0.11
|
|
Mutated
|
(AA)
|
1.73
|
0.63 - 4.77
|
0.29
|
|
XRCC3 (Thr241Met)
|
|
Wild
|
(CC)
|
1
|
|
|
|
Heterozygote
|
(CT)
|
1.78
|
1.54 - 0.48
|
0.48
|
|
Mutated
|
(TT)
|
0.22
|
2.33 - 0.58
|
0.58
|
Odds Ratio and confidence intervals (CIs.) non-adjusted for possible confusion variables.
Adjusted analyses of cervical cancer risk in patients with different genotypes and
different risk factors
We further evaluated the association of XRCC1 and XRCC3 variant genotypes with cervical
carcinoma risk stratified by high-risk exposure factors. Logistic regression analysis
was performed after correction for possible confusion variables and the mutated genotype
of XRCC1 (Arg399Gln) appeared to show a trend as a protective factor for the disease
development when compared to wild genotype but with a weak odds ratio (OR=0.20; 95%
CI = 0.05 - 0.73; p=0.02), ([Table 7]).
Table 7
Adjusted Odds Ratio analysis adjusted for age, menarche, age of menopause and number
of pregnancies
|
|
|
Odds Ratio
|
95% CI
|
P-value
|
|
XRCC1 (Arg194Trp)
|
|
Wild
|
(CC)
|
1
|
|
|
|
Heterozygote
|
(CT)
|
1.03
|
0.35 - 3.02
|
0.95
|
|
Mutated
|
(TT)
|
NA
|
NA
|
NA
|
|
XRCC1 (Arg399Gln)
|
|
Wild
|
(GG)
|
1
|
|
|
|
Heterozygote
|
(GA)
|
0.20
|
0.05 - 0.73
|
0.02
|
|
Mutated
|
(AA)
|
0.47
|
0.12 - 1.89
|
0.29
|
|
XRCC3 (Thr241Met)
|
|
|
|
|
|
Wild
|
(CC)
|
1
|
|
|
|
Heterozygote
|
(CT)
|
0.86
|
0.35 - 2.13
|
0.75
|
|
Mutated
|
(TT)
|
0.90
|
0.19 - 4.21
|
0.90
|
Odds Ratio analysis and respective confidence intervals (CIs.) adjusted for age, menarche,
age of menopause and number of pregnancies.
DISCUSSION
In the present study, XRCC1 Arg399Gln heterozygote genotype were associated with a
statistically significant influence on the risk for cervical carcinoma.
Several reports have explored the correlation between the XRCC1 and XRCC3 polymorphisms
and risk of breast, head and neck, colorectal and thyroid cancers.[11]-[15] Some of the mentioned DNA repair genes were correlated with cervical cancer in recent
study,[10] however our results did not correlate with those findings.
We found that the risk associated with XRCC1 Arg399Gln genotype was altered for cervical
cancer patients, suggesting that the biological mechanism of DNA repair and may be
implicated in the disease development. Moreover, cofactors associated with the development
of carcinoma cells may be distinct, not only in relation to environmental risk factors
but also in genetic susceptibility.(16,17) Cervical carcinoma is known to develop from precursor CIN lesions through a multistep
process.[18] However, our study could not contemplate the association between those 3 SNPs and
the risk for CIN. It implied that these genes could be associated with the period
of carcinogenesis from CIN to carcinoma. In summary, our findings could offer evidence
of the association between polymorphisms XRCC1 gene and decreased or increased risk
for cervical cancer. In addition, the effect of genotypes was less evident in those
women with multiple partners, early age of sexual activity and early age of first
parity.
Our results could support the hypothesis that genetic variations in the DNA repair
genes may contribute to an inherited genetic susceptibility to cervical carcinoma
in the studied population.
There were limitations in our study. The sample size was not enough adequate to draw
definitive conclusions or perform any subgroup analyses with respect to associations
between the NER genotypes and clinical stages or different histological samples (carcinoma,
adenocarcinoma and CIN, for example). As with other case-control study designs, information
bias is present. For example, evaluation of clinical information, were difficult to
obtain from the medical record. Such cases were excluded, further limiting our sample
size. Every effort was made to gather missing information, including use of the Tumor
Registry and Death Index.
Despite these efforts important information such as the number of sexual partners
in both groups could not be obtained. Furthermore, an element of selection bias may
have been introduced in our cohort population by the fact that Alfredo Abrão Cancer
Hospital is a large referral cancer center in Campo Grande city and may not be reflective
of the population of typical cervical cancer patients.
However, the prevalence of the polymorphisms in these patients did not differ from
that in the general population. The predictive and prognostic role of DNA repair gene
polymorphisms in clinical outcomes is the subject of a growing body of literature
in pharmacogenomics.(17,18) These parameters can determine whether these polymorphisms are predictive of treatment
response or prognostic by determining outcome. On the basis of the expected outcome
of the patient, both factors may be important in the choice of chemotherapeutic agents.
Evaluation of genetic polymorphisms in cancer susceptibility may help us to understand
the significance of these polymorphisms in the identification of individuals at higher
risk of developing resistance to anticancer drug therapies. This study suggests that
NER gene polymorphisms may modulate chemotherapy response and patient survival.
In the future, larger studies may provide a more complete understanding of relevant
genetic factors and environmental exposures that could result in improved strategies
for determining both chemotherapy choice and efficacy in clinical trials.
ACKNOWLEDGEMENTS
We would like to acknowledge the invaluable participation of the patients with cervical
cancer, and to Hospital do Câncer Alfredo Abrão, staff across the accrual and patient
management (Nurses, Clinicians,
Medical Oncologists and Surgeons). We also want to thank members of the Molecular
Gynecology and Metabolomics Lab at EPM-UNIFESP for valuable help on Molecular Biology
and Human Genetics.
Authors’ contributions
Dr. F. Colacino-Silva was the principal investigator, Dr. A.A. Siufi helped in patients’
accrual and treatment, Drs. J.P.F.O. Kleine and M.B. Salzgeber were responsible for
running PCR-RFLP assays and data generation and Drs. F. Colacino-Silva, I.D.C.G. Silva
and P. D’Amora were responsible for data interpretation and for the manuscript writing.
Bibliographical Record
Fabricio Colacino-Silva, João Paulo Ferreira de Oliveira Kleine, Márcia Batista Salzgeber,
Rodrigo de Aquino Castro, Manoel João Batista Castello Girão, Ismael Dale Cotrim Guerreiro
da Silva, Paulo D’Amora. Polymorphie DNA repair genes XRCC1 and XRCC3 and the risk
for cervical cancer in Brazilian patients. Brazilian Journal of Oncology 2017; 13:
e-1792180.
DOI: 10.1055/s-0044-1792180
