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Abstract
Telomere length variation has been associated with increased risk of several types of tumors, and telomere shortening, with genetic anticipation in a number of genetic diseases including hereditary cancer syndromes. No conclusive studies have been performed for Lynch syndrome, a hereditary colorectal cancer syndrome caused by germline mutations in the DNA mismatch repair genes. Here we evaluate telomere length in Lynch syndrome, both as a cancer risk factor and as a mechanism associated with anticipation in the age of cancer onset observed in successive generations of Lynch syndrome families. Leukocyte telomere length was measured in 244 mismatch repair gene mutation carriers from 96 Lynch syndrome families and in 234 controls using a monochrome multiplex quantitative PCR method. Cancer-affected mutation carriers showed significantly shorter telomeres than cancer-free mutation carriers. In addition, cancer-affected carriers showed the most pronounced shortening of telomere length with age, compared with unaffected carriers. The anticipation in the age of cancer onset observed in successive generations was not associated with telomere shortening, although, interestingly, all mother-son pairs showed telomere shortening. In conclusion, cancer-affected mismatch repair gene mutation carriers have distinct telomere-length pattern and dynamics. However, anticipation in the age of onset is not explained by telomere shortening. Pending further study, our findings suggest that telomere attrition might explain the previously reported dependence of cancer risk on the parent-of-origin of mismatch repair gene mutations.
Citation: Seguí N, Pineda M, Guinó E, Borràs E, Navarro M, Bellido F, et al. (2013) Telomere Length and Genetic Anticipation in Lynch Syndrome. PLoS ONE 8(4): e61286. https://doi.org/10.1371/journal.pone.0061286
Editor: Paolo Peterlongo, IFOM, Fondazione Istituto FIRC di Oncologia Molecolare, Italy
Received: January 15, 2013; Accepted: March 8, 2013; Published: April 23, 2013
Copyright: © 2013 Seguí et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This work was funded by the Spanish Ministry of Economy (State Secretariat for Research, Development and Innovation) (BFU2009-10281), Carlos III Health Institute (FIS PI08/1635, FIS PI08/1359 and RETIC RD06/0020/1050 and RD06/0020/1051), the Scientific Foundation Asociación Española Contra el Cáncer, the Catalan Government (2009SGR290), and CIBERESP (CB07/02/2005). Nuria Seguí is supported by a fellowship from the Carlos III Health Institute and Laura Valle holds a contract “Ramón y Cajal”. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Lynch syndrome (LS) (MIM 120435) is the most common hereditary syndrome that predisposes to colorectal cancer (CRC) and other extracolonic tumors, accounting for 2%–5% of the total burden of CRC. It is caused by germline mutations in the DNA mismatch repair (MMR) genes MLH1 (MIM 120436), MSH2 (MIM 609309), MSH6 (MIM 600678) and PMS2 (MIM 600259), as well as in EPCAM (MIM 185535). There is large phenotypic variation in the age of onset among and within families [1], [2]. Progressively earlier age of cancer onset in successive generations has been reported [3]–[10]. However, the underlying molecular mechanisms of both the overall phenotypic variation and the anticipation in the age of onset are still unknown.
Telomere shortening has gained considerable interest as a potential biomarker of cancer risk and as a mechanism associated with genetic anticipation. Moreover, we have recently shown that a common genetic variant located in the telomerase gene (hTERT; MIM 187270) increases cancer risk in LS patients at early ages, and that this SNP is associated with shortened telomere length in cancer-affected MMR gene mutation carriers [11]. Telomeres consist of multiple short repeats (TTTAGG) at the ends of chromosomes and protect them against large-scale genomic rearrangements. In most somatic cells, telomeres shorten with each replication cycle, eventually leading to cellular senescence or apoptosis. Interestingly, telomere length anomaly appears to be one of the earliest and most prevalent genetic alterations in the process of malignant transformation [12], [13]. Given the proposed role of telomere shortening in early processes of carcinogenesis, attention has been directed to its potential role as a cancer risk biomarker. With this purpose, a number of retrospective and prospective observational studies have been conducted, although results are inconsistent among studies and tumor types [14]–[16]. With respect to CRC, despite the conflicting results obtained in retrospective studies, prospective studied have not found a convincing association between leukocyte telomere length and CRC risk [16]–[18].
Telomere length attrition has also been proposed as a mechanism of anticipation in different inherited diseases, being associated with early onset and/or severity of disease in genetic disorders such as dyskeratosis congenita [19]–[21], Li-Fraumeni [22], [23], and familial breast and ovarian cancer [24], [25].
Here we aim to elucidate the role of telomere length in LS-associated cancer risk and to study its implication in anticipation in the age of onset observed in successive generations of LS families.
Materials and Methods
Ethics statement
Written informed consent was obtained from all subjects. The study received the approval of the IDIBELL Ethics Committee (ref. PR221/09).
Study participants
A total of 388 individuals, 244 MMR gene mutation carriers and 144 non-carriers, from 96 LS families were included in the study. They were assessed through the Hereditary Cancer Program at the Catalan Institute of Oncology, ICO-IDIBELL, from 1998 to 2012. MMR gene mutation analysis was performed on genomic DNA extracted from peripheral blood. Large genomic alterations in the genes were studied using Multiplex Ligation-dependent Probe Amplification (MLPA) (SALSA MLPA Kits, MRC-Holland, The Netherlands). Mutation screening was carried out by direct sequencing after PCR amplification (primers and conditions available upon request). Ninety cancer-free individuals were included as controls. All individuals are of Caucasian origin. Informed consent was obtained from all subjects, although data were analyzed anonymously. Table 1 shows a summary of the genetic and clinical characteristics of the groups studied.
Cases and controls were recruited from the same homogeneous population, and storage and DNA extraction from peripheral blood were performed at the same facility and using the same extraction methods. We have observed that blood DNA samples from different sources (i.e., extracted at different laboratories, using different extraction methods, etc.) show large non-genetic variation in telomere length (data not shown). Thus, only samples (cases and controls) that underwent the exact same DNA extraction protocol (Flexigene DNA kit, Qiagen, Hilden, Germany) performed by the personnel of the Unit of Molecular Diagnostics of the Hereditary Cancer Program at ICO-IDIBELL, and that were stored under the same conditions, were included in the study, as recommended by Prescott et al. for retrospective studies [16].
Telomere length assessment
Telomere length quantification was performed using the monochrome multiplex quantitative PCR method described by Cawthon et al. [26], which has been found to provide greater consistency than other methods used to measure telomere length [17]. The assays were performed using the Quantifast SybrGreen PCR Master Mix (Qiagen, Hamburg, Germany), beta-globin as single copy gene, and the LightCycler 480 real-time PCR detection system (Roche Diagnostics GmbH, Mannheim, Germany). All samples were assayed in triplicate. A standard curve with 7 concentrations spanning an 81-fold rage (60 ng, 40 ng, 20 ng, 6.7 ng, 4 ng, 2.2 ng and 0.74 ng), also in triplicate, of an anonymous standard DNA (healthy and cancer-free 45 year-old individual) was included in every 384-well plate. Good replicates of the standard curves (for telomeres (T) and single copy gene (S)) and subsequent fitted linear regression lines were obtained among plates. Whenever possible, equal numbers of samples from different clinical groups were run in each 384-well plate. The relative telomere length (RTL) value for each sample was calculated according to the standard lines (for T and S) of the corresponding plate. Therefore, the value obtained was relative to the value of the anonymous standard DNA in the same plate (inter-run calibration). The average telomere length of each sample is expected to be proportional to its RTL.
Statistical analyses
Shortening of telomere length is observed with increasing age in cancer-free individuals [27]. In our control set (controls plus non-carriers, n = 234), RTL was inversely correlated with age (Pearson's correlation r = −0.187; p = 0.004). As previously described, RTL measurements were adjusted for age using the line of best fit for controls [25]. Thus, the difference between the observed and the predicted value was calculated for each sample and is represented as “age-adjusted RTL”. There were no telomere length differences between sexes (data not shown); therefore, sex was not included as a confounding factor in the statistical tests.
Differences in age-adjusted telomere lengths were analyzed using the Wilcoxon rank sum test (Mann-Whitney U). Pearson's test was used to assess the correlation between telomere length and age (telomere length dynamics). To measure the significance of the difference between two correlation coefficients (Pearson's r), Fisher's r-to-z transformation was performed. Anticipation was represented by Kaplan-Meier curves and the differences between survival curves were studied using a log-rank test. Proportions were compared by Fisher's exact test (expected cell count <5) or Chi-square. All tests were two-sided and p-values below 0.05 were considered statistically significant. The analyses were performed using R.
Results
Telomere length and shortening dynamics
Relative telomere length was assessed in 244 MMR gene mutation carriers, both cancer-affected (n = 144) and unaffected (n = 100), and in 234 controls, including non-carriers from the same LS families (n = 144) and unrelated cancer-free controls (n = 90) (Figure 1). Relative telomere length values were adjusted for age as indicated in the Materials and Methods section (see statistical analyses). We found that among mutation carriers, cancer cases had significantly shorter age-adjusted telomeres than unaffected individuals (p = 0.032). It is worth noting that unaffected mutation carriers have longer telomeres than unaffected controls: a significant increase of the fourth quartile (longest telomeres) is observed in cancer-free MMR mutation carriers (36.0%) compared with controls (21.8%; p = 0.010) and cancer-affected carriers (20.1%; p = 0.009) (Figure 2).
In subjects belonging to LS families: MMR gene mutation carriers affected with cancer (median: −0.131), MMR gene mutation carriers with no diagnosed cancer (median: −0.079) and cancer-free non-carriers (median: −0.091); and in cancer-free controls (median: −0.097). The boxes represent the interquartile range of distributions (25th and 75th percentiles); the horizontal lines within the boxes, the medians; and the vertical lines, the 5th and 95th percentiles.
As expected, the negative slope of the linear regression line that best fit the RTL data for the controls indicated that telomere length shortened with age (Pearson's correlation coefficient r = −0.187; p = 0.004); the same was observed for the MMR gene mutation carriers (r = −0.297; p = 2.37×10−6). No differences were observed between both groups (p = 0.204) (Figure 3A). Among MMR gene mutation carriers, cancer-affected individuals showed faster telomere attrition with age (r = −0.344; p = 2.4×10−5) than cancer-free carriers (r = −0.094; p = 0.351) (for the difference, p = 0.045) (Figure 3B). No differences were observed between MSH2 (r = −0.446; p = 0.003) and MLH1 (r = −0.318; p = 0.003) mutation carriers (for the difference, p = 0.435).
(A) RTL distribution as a function of age for controls (n = 234; white circles) and all MMR gene mutation carriers (n = 244; black circles). (B) RTL distribution as a function of age for cancer-affected MMR gene mutation carriers (n = 144; black circles) and cancer-free MMR gene mutation carriers (n = 100; crossed circles). r: Pearson's correlation coefficient.
Telomere length and anticipation in the age of cancer onset
The occurrence of age anticipation in cancer-affected mutation carriers was analyzed in 59 LS families, harbouring MLH1 (32 families), MSH2 (20 families) and MSH6 (7 families) mutations. The distribution of age at cancer diagnosis in parents and children showed a consistent shift to early ages in children (p = 2.5×10−7) (Figure 4). On average, cancer was diagnosed 12 years earlier in children (Table 2). Five out of 65 parents and 3 out of 30 children had been diagnosed with cancer (1st LS-related cancer diagnosed) during the follow-up period or clinical surveillance of mutation carriers. Their exclusion from the analysis did not alter the results (data not shown). The information available from polyp removal and surveillance time across generations was incomplete and was not included in the study.
Kaplan-Meier curves and associated p-values showing the differences in age of cancer onset between parents and children, all of them cancer-affected MMR gene mutation carriers.
The relationship between telomere length and anticipation in LS was next investigated. No differences between parents and children were observed in cancer-affected MMR gene mutation carriers (p = 0.867) (Figure 5). Similarly, no association was found when MLH1 and MSH2 gene mutation cases were analyzed separately (Figure S1). Next, we compared changes in telomere length in individual parent-child pairs (Table 3). In all instances, the child was diagnosed with cancer at an earlier age than the corresponding LS parent. Children showed shorter telomeres than their parents in 10 out of 21 (47.6%) cancer-affected carrier pairs, in 6 out of 9 (66.7%) cancer-free carrier pairs, and in 1 out of 3 (33.3%) cancer-free non-carriers evaluated, although the these differences were not statistically significant (p = 0.562).
Box plots representing age-adjusted RTL distributions in cancer-affected parents and children with MMR gene mutations. The boxes represent the interquartile range of distributions (25th and 75th percentiles); the horizontal lines within the boxes, the medians; and the vertical lines, the 5th and 95th percentiles.
Anticipation was associated with shorter telomeres in all (5/5) mother-son cancer-affected MMR gene mutation carriers, whereas this association was only observed in 31% (5/16) of the other cancer-affected carrier pair combinations (p = 0.012) (Table 3).
Discussion
In this study we found that cancer-affected MMR gene mutation carriers have shorter telomeres and faster telomere attrition rates (accelerated telomere shortening with age) than unaffected mutation carriers and controls, and that telomere shortening is not associated with anticipation in the age of cancer onset in successive generations.
In line of recent retrospective and prospective studies on sporadic CRC risk and leukocyte telomere length, it has been suggested that the shorter telomere length observed in retrospectively collected samples from CRC patients is not a cancer risk factor, but rather a consequence of the disease (from treatment or disease burden) [16], [17]. However, a recent prospective study has shown that both extremely long and extremely short telomeres increase CRC risk [18]. In hereditary cases, we observe shorter telomeres in cancer-affected MMR gene mutation carriers than in cancer-free carriers, suggesting either that the shortened telomeres are a result of the disease, or that shorter telomere length is an additional risk factor for LS patients, i.e. a risk modifier. This is supported by our recent observation that a variant in the telomerase gene, hTERT, increases cancer risk in young LS patients (<45 years of age), as it is associated with shortened telomeres in cancer-affected MMR gene mutation carriers [11]. Further studies assessing telomere length before and after cancer diagnosis in CRC patients will provide a definitive answer regarding the suggested effect of cancer on telomere length in blood cells. Unfortunately, samples from sporadic CRC cases that underwent the same DNA extraction and storage than the hereditary cases and controls herein studied were not available, precluding a direct comparison. This study will be critical to clarify whether telomere shortening is specific to cancer-affected LS patients or if it occurs in all CRC-affected patients.
Our data show longer telomeres in cancer-free MMR gene mutation carriers compared to cancer-free controls. A plausible explanation for this observation, and consistent with the fact that short telomeres act as factors of increased cancer risk, is that longer telomeres protect MMR gene mutation carriers from developing cancer. On the other hand, Jones et al. proposed that certain genetic factors that increase CRC risk may cause longer telomeres [17]. Alternatively, and in line with this model, our results might suggest that MMR haploinsufficiency, as a genetic factor of CRC risk, can exert a lengthening effect on the telomeres. Additional studies to assess the effect of MMR haploinsufficiency on telomere lengthening are needed to validate this hypothesis.
We also observed that leukocyte telomere dynamics differ between cancer-free mutation carriers and cancer-affected carriers, the latter group showing faster telomere shortening with age. Bozzao et al. found that affected carriers showed accelerated attrition rate compared to controls [28]. Based on previously published data on MMR-deficiency and telomeres [29]–[33], they suggested that MMR haploinsuffiency in LS individuals may lead to tolerance of short telomeres, causing faster telomere shortening over the course of life. However, our results show that this increased shortening rate does not occur in cancer-free carriers, thus invalidating the hypothesis. Therefore, this effect may be either the result of telomere shortening in cancer-affected individuals, or a marker of increased cancer risk among MMR gene mutation carriers, supporting the idea that short telomere length or accelerated telomere attrition rate are factors of increased cancer risk in LS. Identifying the dynamics of leukocyte telomere length with age in sporadic cases from retrospective and prospective studies may resolve this question.
No association was found between the anticipation in the age of onset observed in successive generations and telomere length. For years, and despite the numerous reports identifying anticipation in LS, it was uncertain whether true genetic anticipation contributed to the early diagnosis age observed in LS. Recently, a Bayesian method that corrects for random effects, isolating the confounding effect of changes in secular trends, screening, and medical practices, and adjusting for changes in age-specific incidence across birth cohorts, confirmed the anticipation in the age of onset between successive generations of LS families [10]. Nevertheless, the molecular mechanism underlying this observation has not been yet identified. Due to the lack of information on surveillance time in parents and children, polyp removal, and other confounding factors, as well as the insufficient sample size for an accurate assessment of genetic anticipation, it is certain that the measurement obtained in our series (12 years) is clearly overestimated. Nevertheless, we accept the results of previous reports on this matter in which accurate statistical methodologies were used and anticipation was still confirmed [8]–[10], and our series was used to assess the involvement of telomere attrition in anticipation. Our data rule out the role of telomere shortening in anticipation in LS. As previously suggested, other molecular mechanisms such as the accumulation of mismatch repair slippage events through generations or other genetic or environmental factors might explain age anticipation in successive generations of LS families [34], [35]. Considering the limitations of our study regarding sample size, and the inconclusive results obtained when studying telomere length in cancer patients, further studies on larger LS series should be performed to validate these results.
Van Vliet et al. recently suggested that CRC risk in carriers of MMR gene mutations depends on the parent-of-origin of the mutation. In particular, they suggested a maternally transmitted mechanism modifying cancer risk in male MMR gene mutation carriers [36]. Here we observe anticipation associated with shorter telomeres in all mother-son cancer-affected MMR gene mutation carriers, whereas the same association is only found in 31% of the other cancer-affected carrier pair combinations. Although the sample size of parent-child pairs is very limited, this observation might suggest that the maternally transmitted risk mechanism is shortened telomeres. Studies assessing whether telomere shortening occurs in the female germline, as recently demonstrated in other mammals [37], together with the analysis of larger samples of LS parent-child pairs, are required to verify this hypothesis.
In conclusion, our findings indicate that cancer-affected MMR gene mutation carriers show distinct features and dynamics of telomere length measured in blood DNA, to controls and unaffected mutation carriers. While we rule out telomere length attrition as the common cause of anticipation in LS, it may account for the dependence of cancer risk on the parent-of-origin of MMR gene mutations previously observed.
Supporting Information
Figure S1.
Age-adjusted RTL distributions in cancer-affected parents and children with MLH1 and MSH2 gene mutations. The boxes represent the interquartile range of distributions (25th and 75th percentiles); the horizontal lines within the boxes, the medians; and the vertical lines, the 5th and 95th percentiles. Pairwise comparisons using Wilcoxon rank sum test showed no differences in RTL distributions between cancer-affected parents and children with germline mutations in MLH1 (p = 0.65), and between parents and children with mutations in MSH2 (p = 0.67).
https://doi.org/10.1371/journal.pone.0061286.s001
(TIF)
Acknowledgments
We thank all those responsible for genetic counselling and genetic testing as part of the ICO-IDIBELL Hereditary Cancer Program.
Author Contributions
Conceived and designed the experiments: LV NS GC. Performed the experiments: NS LV FB. Analyzed the data: LV EG VM NS. Contributed reagents/materials/analysis tools: MP EG EB MN CL IB VM. Wrote the paper: LV. Revised the article critically for important intellectual content: GC IB MP VM MN NS EB EG CL FB. Final approval of the article: GC IB MP VM MN NS EB EG CL FB.
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