Lynch syndrome (LS), also known as hereditary non-polyposis colorectal cancer, is the most common hereditary colorectal cancer (CRC) syndrome and accounts for 2-5% of all colorectal cancer cases 1 . Germline mutations in any of the four mismatch repair (MMR) genes, MLH1 2 , MSH2 3 , MSH6 4 and PMS2 5 , are the underlying cause of LS. Subjects carrying a mutation in one of the MMR genes have a higher risk for developing colorectal cancer, but also for endometrial carcinoma and malignancies of the stomach, small bowel, ovaries, upper uroepithelial tract, biliary tract, skin and brain 6 7 8 9 .

The colorectal cancer risk in LS is dependent on sex and the MMR gene involved. The reported lifetime risk for colorectal cancer in the literature varies from 28-100% in males and 25-83% in females 7 10 11 12 13 14 15 16 17 18 . The risk of developing endometrial carcinoma ranges from 30-71% and the risk of other LS-associated cancers is less than 10-15% 9 . Furthermore, some studies have suggested that extracolonic cancers are more often observed in MSH2 mutation families compared to MLH1 mutation families 13 19 . MSH6 mutation families probably have a milder clinical phenotype with a later onset of both CRC and EC and clustering of endometrial carcinoma 17 . The risks in PMS2 mutation families are largely unknown. One study reported that PMS2 mutation families have a milder phenotype compared to MLH1 and MSH2 families 20 .

Unfortunately, the precise lifetime risk for CRC and endometrial carcinoma may be biased because the families selected in previous studies were mainly selected on basis of clustering of CRC or fulfilment of clinical criteria (Amsterdam II criteria). Furthermore, it was not always clear whether the affected subjects were proven mutation carriers. In addition, most studies have only evaluated lifetime risks for MLH1 and MSH2 mutations, while studies evaluating MSH6 mutation families are sparse. The most efficient way to calculate the lifetime risks of CRC and EC in Lynch syndrome would be to calculate these risks based on a cohort of proven mutation carriers. Therefore, the aim of the present study was to calculate the cumulative lifetime risks for CRC and EC in Lynch syndrome using a cohort of proven MLH1, MSH2 and MSH6 mutation carriers.

In this study, we evaluated 246 individuals from 67 families with a proven mismatch repair gene mutation to determine the cumulative lifetime risk of developing cancer. Previous studies have shown different lifetime risks for developing CRC in Lynch patients.

One of the first studies evaluating the lifetime risk reported a lifetime risk for CRC at age 75 years of 92% in males and 83% in females 10 . Most later studies reported somewhat similar risks for CRC ranging from 65-100% in males and 30-63% risk in females 7 11 12 13 . A more recently published study reported the lowest lifetime risk for CRC so far, 27% for males and 22% for females at age 70 years 15 . All these studies only evaluated the risks associated with MLH1 and MSH2 mutations. Thirty one percent of the families included in our study carried an MSH6 mutation. This frequency is higher than previously reported 4 21 22 23 . Studies evaluating the lifetime risks of cancer amongst MLH1, MSH2 and MSH6 families are sparse. A study evaluating the risk in 20 MSH6 families showed that colorectal cancer was less frequent and developed 10 years later in MSH6 compared to MLH1 and MSH2. In addition a significant higher lifetime risk of endometrial carcinoma of 71% in MSH6 mutation carriers with a later age of onset (54 years vs. 48 and 49 years for MLH1 and MSH2) was reported 17 . A German study comparing 27 MSH6 mutation families with 156 MLH1 and MSH2 mutation families confirmed the lower risk and later age of onset of CRC in MSH6 families 24 . These results were also confirmed by a recently published British study, but this study only included 11 proven MSH6 mutation carriers 18 .

Our study indicates that, however the cumulative risks of cancer at age 70 years in MLH1, MSH2 and MSH6 mutation carriers is similar, each mutated gene has a distinguishable cancer risk profile. In MSH6 mutation carriers the risk at age 70 years for developing CRC was the lowest in both male (54%) and female (30%) when compared to carriers of MLH1 and MSH2 mutations.

Between male MSH6 and MSH2 mutation carriers also a significant difference in the age of CRC onset (48 vs. 43 years, p = 0.03) was found and there was a trend in higher age of CRC onset between male MSH6 and MLH1 mutation carriers. For female mutation carriers, no significant differences were found in the mean age of onset of CRC. This can be explained by the fact that female MLH1 and MSH2 mutation carriers still developed CRC at an older age. The lower risk of CRC onset in female MSH6 mutation carriers under the age of 50 years raises the question whether colonoscopic surveillance guidelines in these subjects can be changed. Current guidelines advise to start with biennial colonoscopy surveillance from the age of 20-25 years 25 . In our study population, the youngest affected female MSH6 mutation carrier with CRC was 34 years. Our data and the data from previous studies support that colonoscopic surveillance can be started at an age of 30 years in female MSH6 mutation carriers 17 .

However our numbers are too small to draw definite conclusions, CRC seems to be the predominant cancer in MLH1 mutation carriers. In MSH2 and MSH6 mutation carriers extracolonic cancers appear to contribute more to the similar cumulative lifetime risk of cancer in MLH1, MSH2 and MSH6 mutation carriers. A higher risk of extracolonic-LS-associated cancer was previously reported in MSH2 mutation carriers compared to MLH1 mutation carriers 13 19 . Unfortunately, the number of extracolonic-LS associated cancer (excluding endometrial carcinoma) in our study population was too low to calculate accurate risk estimates for these cancers. In concordance with other studies 17 26 our study indicates that MSH6 carriers have the highest endometrial cancer risk followed by MSH2 and MLH1 mutation carriers. Also, this risk increases sharply after the age of 50 years. In view of the disputable effect of endometrial carcinoma surveillance 27 28 , in female MSH6 carriers aged 45 years or above prophylactic hysterectomy may be suggested in order to decrease the risk for developing endometrial carcinoma 29 . In MSH2 and MLH1 female mutation carriers this option may be more questionable. In MSH2 mutation carriers the risk of other extracolonic and extraendometrial cancers may reduce faith in and benefit of risk reducing surgery. In MLH1 mutation carriers the risk of endometrial cancer may not outweigh the disadvantages of surgery. In case of surgery for another cause, additional hysterectomy should be considered also in MLH1 en MSH2 mutation carriers.

A strength of the present study was that the age related risks where calculated using proven mutation carriers. However, the age related risks might be somewhat lower since not all the unaffected individuals from proven mutation families opted for genetic testing and thus the total number of unaffected mutation carriers in the mutation families may be underestimated. In addition, individuals with a higher risk for mutation carriership, i.e. with an affected first degree relative, more often opt for genetic testing 30 . This may also have introduced some bias with respect to the age related risks. Also, we included the index cases in our study population. Index cases give rise to the suspicion of Lynch syndrome and they always have cancer. This may also have resulted in a slightly higher age related risk. On the other hand, the majority (77%) of not affected mutation carriers was under colonoscopy surveillance, which likely has influenced the age related risks for developing invasive CRC, since colonoscopy surveillance in Lynch syndrome patients is effective in reducing the incidence and mortality of CRC 31 . A limitation of our study was that our study population was not very large (n = 246), and the number of male carriers was 92. This could explain why we did not find a significant difference in both the mean age of CRC onset and the age related risk between male MLH1, MSH2 and MSH6 mutation carriers.

In conclusion, the present study indicates that, although the cumulative risks at age 70 years of LS related cancer in MLH1, MSH2 and MSH6 mutation carriers are similar, each mutated gene has a distinguishable cancer risk profile. It underlines that female MSH6 mutation carriers have a distinct clinical phenotype with a lower CRC risk and a higher risk for developing endometrial carcinoma. Starting with biennial colonoscopic surveillance at an age of 30 years instead of an age of 20-25 years in female MSH6 mutation carriers is more suitable. Moreover, in female MSH6 mutation carriers prophylactic hysterectomy may be considered from an age of 45 years.

The present study indicates that each mutated MMR gene has a distinguishable cancer risk profile. Female MSH6 mutation carriers have a lower CRC risk and a higher risk for developing endometrial carcinoma. Starting with biennial colonoscopic surveillance at an age of 30 years in female MSH6 mutation carriers is more suitable and prophylactic hysterectomy may be considered from an age of 45 years.

CRC: colorectal cancer; EC: endometrial cancer; LS: Lynch syndrome; MMR: mismatch repair; UV: unclassified variant.

The authors declare that they have no competing interests.

DR participated in the data collection, performed the statistical analyses and helped to draft the manuscript. AW conceived of the study and participated in the data collection. ML helped to draft the manuscript. DD participated in the data collection. CT participated in the data collection. ES participated in the design of the study and assisted in the statistical analysis. EK helped to draft the manuscript. All authors read and approved the final manuscript.