Abstract
The aim of this study was to relate the density of tumor infiltrating T cells to cancer-specific survival in colorectal cancer, taking into consideration the CpG island methylator phenotype (CIMP) and microsatellite instability (MSI) screening status. The T-cell marker CD3 was stained by immunohistochemistry in 484 archival tumor tissue samples. T-cell density was semiquantitatively estimated and scored 1–4 in the tumor front and center (T cells in stroma), and intraepithelially (T cells infiltrating tumor cell nests). Total CD3 score was calculated as the sum of the three CD3 scores (range 3–12). MSI screening status was assessed by immunohistochemistry. CIMP status was determined by quantitative real-time PCR (MethyLight) using an eight-gene panel. We found that patients whose tumors were highly infiltrated by T cells (total CD3 score ≥7) had longer survival compared with patients with poorly infiltrated tumors (total CD3 score ≤4). This finding was statistically significant in multivariate analyses (multivariate hazard ratio, 0.57; 95% confidence interval, 0.31–1.00). Importantly, the finding was consistent in rectal cancer patients treated with preoperative radiotherapy. Although microsatellite unstable tumor patients are generally considered to have better prognosis, we found no difference in survival between microsatellite unstable and microsatellite stable (MSS) colorectal cancer patients with similar total CD3 scores. Patients with MSS tumors highly infiltrated by T cells had better prognosis compared with intermediately or poorly infiltrated microsatellite unstable tumors (log rank P=0.013). Regarding CIMP status, CIMP-low was associated with particularly poor prognosis in patients with poorly infiltrated tumors (multivariate hazard ratio for CIMP-low versus CIMP-negative, 3.07; 95% confidence interval, 1.53–6.15). However, some subset analyses suffered from low power and are in need of confirmation by independent studies. In conclusion, patients whose tumors are highly infiltrated by T cells have a beneficial prognosis, regardless of MSI, whereas the role of CIMP status in this context is less clear.
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Main
Colorectal cancer is one of the most common malignancies in the western world, and has a lethal outcome in nearly 40% of all diagnosed cases. The current staging system used for therapeutic decision making and prediction of patient survival accurately identifies patients with exceptionally good prognosis (stage I), as well as patients with very poor prognosis (stage IV). However, additional factors are needed in the large subgroup of patients with stage II or III disease, for whom the prognosis and potential benefit of adjuvant chemotherapy are less certain.
Microsatellite instability (MSI) characterizes 10–15% of sporadic colorectal cancer, and has been related to a better patient prognosis compared with microsatellite stable (MSS) colorectal cancer.1, 2 MSI in sporadic colorectal cancer is frequently caused by promoter hypermethylation of the mismatch repair gene MLH13 and is highly associated with the CpG island methylator phenotype (CIMP).4 CIMP-high, or CIMP1, is characterized by hypermethylation in several genes that are unmethylated in normal colorectal tissue and in CIMP-negative colorectal cancer.5 CIMP classification has recently been expanded to define a group of tumors with hypermethylation of an intermediate number of genes, called CIMP-low or CIMP2.6, 7, 8 The importance of CIMP status in predicting colorectal cancer patient survival has been investigated in a number of recent studies. Along with others, we have reported a worse prognosis in colorectal cancer patients with CIMP-low or CIMP-high, compared with CIMP-negative tumors, particularly in combination with MSS.4, 9, 10, 11, 12 However, results from other large studies have not been entirely consistent,13, 14, 15, 16, 17, 18 and consensus has thus not been reached. One factor contributing to the discrepancy of results in the many studies is the lack of information regarding BRAF mutation, which has shown to be a major confounding factor in studies of CIMP status and colorectal cancer patient survival.12, 14, 15, 17 Some studies have focused on the clinical importance of the host response in terms of tumor infiltrating immune cells. Presence of peri- and intratumoral inflammatory cells has consistently been associated with a better prognosis in colorectal cancer.19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33 Many of these reports have been based on routine hematoxylin and eosin stained tissue sections, but an increasing number of studies have used immunohistochemical markers such as the pan T-cell marker CD3. CD3 is a cell surface protein associated with the T-cell receptor.34
CIMP-high and MSI tumors are frequently infiltrated by a large number of T cells.4, 35, 36, 37, 38 However, few large studies of tumor infiltrating T cells and colorectal cancer patient survival have taken into account the potentially confounding effect of MSI screening status,30, 32, 39, 40, 41, 42 and only one other research group has considered CIMP.32, 42 Furthermore, T-cell infiltration can be assessed in various locations within the tumor, such as the tumor front, tumor center, and the intraepithelial compartment, but few studies have evaluated these separately.32, 33, 37, 42, 43, 44, 45, 46, 47 Although a beneficial effect on survival has generally been observed with higher degrees of infiltrating T cells, the prognostic value has varied in reports depending on the T-cell marker used, the compartment evaluated, and the confounders considered.
The aim of this study was to relate the extent and location of tumor infiltrating T cells to colorectal cancer patient prognosis, and to investigate the potentially confounding effect of MSI screening status and CIMP status.
Patients and methods
Study Design and Patient Selection
Colorectal cancer cases included in this study were from the Colorectal Cancer in Umeå Study (CRUMS), which comprises patients with primary colorectal cancer who underwent curative or palliative tumor resective surgery between 1995 and 2003 at Umeå University Hospital, Sweden. The sample collection had a consecutive intent, and exclusion criteria included insufficient or unavailable tumor tissue sample and insufficient clinical information. After further exclusion of 9 cases in which CD3 staining was unsuccessful, 484 cases (297 colon cancer, 182 rectal cancer, and 5 missing values), were available for this study. Adjuvant chemotherapy was administered to 68 (14%) patients. Preoperative radiotherapy was administered to 110 (60%) rectal cancer patients, of whom 83 received 5 × 5 Gy, and 27 received 25 × 2 Gy.
Verification of diagnoses and classification of tumor characteristics were performed by one pathologist. Information on patient age, sex, and tumor site were extracted from patient records, and vital status and cancer-specific survival were obtained from the Swedish population registry and patient records, respectively. Patients were followed up until spring 2005. The median follow-up time for cases that were still alive at the end of follow-up was 50 months. The tumors have previously been characterized for BRAF V600E mutation status by the Taqman allelic discrimination assay.48, 49
The handling of tissue samples and patient data in this study has been approved by the ethical committee, Umeå University, Umeå, Sweden.
Immunohistochemistry and MSI Screening Status
Colorectal cancer specimens obtained after primary tumor resection were formalin fixed and paraffin embedded according to routine protocols. For immunohistochemical stainings, 4 μm sections were deparaffinized and rehydrated, and antigen retrieval treatment was executed by heating in a microwave oven in citrate pH 6.0 (for CD3) or EDTA pH 8.0 (for MLH1, MSH2, MSH6, and PMS2). Primary polyclonal CD3 (dilution 1:50; Dako, Glostrup, Denmark) or monoclonal MLH1 (clone G168-15; 1:50; BD Biosciences, Pharmingen, San Diego, CA, USA), MSH6 (clone 44; 1:50; BD Biosciences, Pharmingen), PMS2 (clone A16-4; 1:25; BD Biosciences, Pharmingen), or MSH2 (clone FE11; 1:50; Oncogene/VWR, West Chester, PA, USA) antibodies were used. Subsequent steps, including use of 2,3-diaminobenzidine chromogen (iVIEW DAB Detection Kit, Ventana, Illkirch CEDEX, France) for visualization, was carried out in a semiautomatic staining machine (Ventana ES; Ventana).
Non-malignant lymph nodes were used as a positive control for CD3 staining, and non-malignant stromal cells were used as internal positive controls for MLH1, MSH2, MSH6, and PMS2. Cases lacking positivity in control cells were considered uninformative. Tissue samples with tumor cells lacking nuclear staining for MLH1, MSH2, MSH6, or PMS2 were considered to have a positive MSI screening status, which is hereafter referred to as MSI. Negative MSI screening status is hereafter referred to as MSS. MSI screening status could not be determined for 14 patients.
Immunohistochemical Evaluation of T-Cell Infiltration
T-cell infiltration of tumors was assessed by semiquantitative estimation of the density of CD3-positive (CD3+) cells, and was scored as 1, no, or sporadic CD3+ cells; 2, moderate numbers of CD3+ cells; 3, abundant occurrence of CD3+ cells; and 4, highly abundant occurrence of CD3+ cells (Figure 1). In each tumor, the density of T-cell infiltration was examined in, and a separate CD3 score was assigned for, the tumor front (CD3+ cells localized in stroma adjacent to the invasive tumor margin), the tumor center (CD3+ cells localized in the stroma within the tumor mass), and the intraepithelial compartment (CD3+ cells localized within tumor cell nests).44 Areas of necrosis were avoided. In cases of heterogeneity, the CD3 score for the tumor front was estimated in the area of deepest invasion. For assessment of tumor center and intraepithelial compartment, at least three random fields were viewed, and in cases of heterogeneity, the score that was most representative for the entire section was assigned. All sections were examined twice by the same observer, and in cases of discrepant scoring, a third estimation was made and set as the final score. Staining was successful for 484 cases, but because of technical limitations, for example, a lack of identifiable tumor invasive front in the investigated tissue sections, a CD3 score for the tumor front, center, and intraepithelial compartment could not be determined in 23, 1, and 6 cases, respectively (total n=29).
Similar to Ogino et al,32 a total CD3 score was calculated as the sum of the CD3 scores in the tumor front, center, and intraepithelial compartment, generating a total CD3 score ranging from 3 to 12. On the basis of the total CD3 score, patients were divided into three equally sized groups with either low (3–4), intermediate (5–6), or high (7–12) total CD3 score.
Methylation Analysis
The MethyLight method (quantitative real-time PCR) and primer and probe sequences used to determine tumor CIMP status in this study have been described in detail elsewhere.49, 50 DNA extracted from formalin-fixed, paraffin-embedded colorectal cancer tissue was bisulfite treated and purified using the EZ DNA methylation kit (Zymo Research, Orange, CA, USA). For all bisulfite-treated DNA samples, one reaction was run for each of the eight genes included in the CIMP panel (CDKN2A, MLH1, CACNA1G, NEUROG1, RUNX3, SOCS1, IGF2, and CRABP1). Although there is no consensus panel for the determination of CIMP status, this eight-gene panel has been thoroughly validated50, 51 and the included methylation marker genes have been used in several large CIMP studies.15, 16, 17, 50 In order to account for the amount of input bisulfite-treated DNA, one reaction amplifying the repetitive ALU sequence was also run for each DNA sample. M.SssI-treated DNA (presumably fully methylated) served as a methylated reference in control reactions to account for the efficiency of PCR amplification, and for use in standard curve reactions. The percentage of methylated reference (PMR) value was calculated for each gene by the following equation: (quantity of the gene-specific reaction of the sample/quantity of the ALU reaction of the sample)/(mean quantity of the gene-specific reaction for the methylated reference sample/mean quantity of the ALU reaction for the methylated reference sample).50 Samples were considered positive for methylation when an exponential amplification curve was present and generated a PMR >10.50 CIMP status was successfully determined for all patients.
Statistics
Correlations between different CD3 scores were determined by non-parametric Spearman's rho, and clinicopathological characteristics of subgroups were compared using non-parametric Kruskal–Wallis tests for continuous variables and χ2 tests for categorical variables. Cancer-specific events were defined as death with known disseminated or recurrent disease, and cases were censored at the end of follow-up or at time of death by other causes. For survival analyses, Kaplan–Meier plots were employed, and differences in survival between groups were tested by log rank tests. In order to take into consideration other clinicopathological factors, multivariate Cox proportional hazard models were employed. On the basis of our previous prognostic study,12 the final multivariate model included sex, age at diagnosis, tumor site, tumor stage, and adjuvant chemotherapy. Patients who died with postoperative complications within 1 month after surgery (n=19), and patients for whom complete follow-up data were lacking (n=19), were excluded from the survival analyses. Missing values for MSI screening status were treated as a separate category in multivariate survival analyses (n=10). All statistical tests were conducted using PASW Statistics 18 (SPSS, Chicago, IL, USA). Findings were considered statistically significant if P<0.05.
Results
CD3 Scores
The distributions of CD3 scores were similar in the tumor front, center, and intraepithelial compartment (Table 1). The CD3 scores in all compartments, and the total CD3 score (the sum of the three measures), were highly correlated (all Spearman correlation coefficients >0.567, and all P<0.0001).
Clinical Characteristics According to Total CD3 Score
In order to compare tumors with low, intermediate, and high densities of infiltrating T cells, tumors were divided into three subgroups comprising total CD3 scores 3–4, 5–6, and 7–12. A similar approach was recently used in a study by Ogino et al.32 A high total CD3 score was associated with lower stage and lower grade (Table 2). Rectal cancer patients who received preoperative radiotherapy more often had a low total CD3 score (Table 2). On the basis of this and previous findings,52 preoperatively radiated tumors were considered separately in survival analyses, and were excluded from the results below unless otherwise stated.
Cancer-Specific Survival and CD3 Scores
A high total CD3 score, as well as high CD3 scores in the tumor front, center, and intraepithelial compartment, were associated with a longer cancer-specific survival (Figure 2 and Supplementary Figure S1). The longer cancer-specific survival in patients with a high total CD3 score was statistically significant in multivariate analyses adjusted for sex, age, tumor site, tumor stage, and adjuvant chemotherapy (multivariate hazard ratio (HR), 0.57; 95% confidence interval (CI), 0.31–1.00; Table 3). HRs for high CD3 scores in the tumor front, center, and intraepithelial compartment were similar to those of a high total CD3 score (data not shown).
The longer cancer-specific survival in patients with a high total CD3 score was consistent in analyses stratified by stage. Although these analyses suffered from low power, statistical significance was reached for stage II, in which multivariate HR for high versus low total CD3 score was 0.25 (95% CI, 0.08–0.75; Supplementary Figure S2).
Cancer-Specific Survival by Combined Total CD3 Score and MSI Screening Status
Cancer-specific survival was longer in MSI compared with MSS tumor patients, although the difference was not statistically significant (5-year cancer-specific survival 72 and 57%, respectively; log rank P=0.078; Table 4). MSI was associated with a high total CD3 score and high CD3 scores in the tumor front and intraepithelially (Tables 1 and 2). However, addition of MSI screening status to the multivariate model in Table 3 did not affect the HRs for total CD3 score. In analyses combining total CD3 score and MSI screening status, 5-year cancer-specific survival was highest in patients with a high total CD3 score and either MSI or MSS (87 and 83%, respectively; Table 4; Figures 3a–d), and lowest in cases with low total CD3 score and either MSI or MSS (51 and 39%, respectively; Table 4; Figures 3a–d). MSI screening status was not an independent predictor of cancer-specific survival when included in the same multivariate model as total CD3 score (data not shown). Patients with MSS tumors with a high total CD3 score had longer cancer-specific survival compared with MSI tumors with an intermediate or low total CD3 score (log rank P=0.013; Figures 3a–d). When comparing cancer-specific survival in patients within the same total CD3 score subgroup, no statistically significant differences were found between MSI and MSS tumor patients (Table 4; Figures 3a–d).
Cancer-Specific Survival by Combined Total CD3 Score and CIMP Status
As previously reported for patients in CRUMS,12 CIMP-low patients had a poorer prognosis compared with CIMP-negative, which was of borderline statistical significance in multivariate analyses (5-year cancer-specific survival 52 and 63%, respectively; multivariate HR for CIMP-low, 1.47; 95% CI, 0.98–2.20; Table 4). Cancer-specific survival was similar in CIMP-high and CIMP-negative tumor patients (Table 4). CIMP status was associated with CD3 scores in the tumor center and intraepithelial compartment (P=0.036 and 0.001, respectively; Table 1), but not with CD3 score in the tumor front, or with total CD3 score (P>0.05; Tables 1 and 2). Addition of CIMP status to the multivariate model in Table 3 had no effect on the HRs for total CD3 score. Total CD3 score and CIMP status were both independent predictors of cancer-specific survival when included in the same multivariate model (data not shown).
In patients with a low total CD3 score, CIMP-low was associated with a reduced cancer-specific survival compared with CIMP-negative (Figure 3e). This finding was statistically significant in multivariate analyses (multivariate HR for CIMP-low, 3.07; 95% CI, 1.53–6.15; Table 4). In contrast, no statistically significant differences in cancer-specific survival were found between CIMP-low and CIMP-negative patients with intermediate or high total CD3 score (Figures 3f–g; Table 4). No statistically significant differences in cancer-specific survival were found between CIMP-high and CIMP-negative patients, regardless of total CD3 score (Figures 3e–h; Table 4).
Total CD3 Score and Cancer-Specific Survival in Preoperatively Radiated Rectal Cancers
A high total CD3 score was less common in rectal cancer tissue that had been preoperatively radiated with 5 × 5 Gy compared with non-preoperatively radiated rectal cancers (14 and 40%, respectively; P=0.002). In both groups, a high total CD3 score was associated with a longer cancer-specific survival (for high versus low total CD3 score, log rank P=0.028 and 0.017, respectively; Supplementary Figure S3).
A high total CD3 score was found in 38% of rectal cancers that were preoperatively radiated with 25 × 2 Gy, which did not differ significantly from non-preoperatively radiated rectal cancers (P=0.837). In survival analysis of this small subgroup of patients (n with total CD3 score and complete follow-up data=21), total CD3 score was not statistically significantly related to cancer-specific survival (data not shown).
Discussion
In this study, colorectal cancer patients whose tumors were densely infiltrated by T cells had a longer cancer-specific survival compared with patients whose tumors were poorly infiltrated. This finding was independent of MSI screening status and CIMP status. Notably, no differences in cancer-specific survival were found between MSI and MSS patients with similar degrees of T-cell infiltration. Thus, the longer survival often reported for MSI1, 2 is, at least partly, dependent on T-cell infiltration. Patients with poorly infiltrated CIMP-low tumors had a particularly poor prognosis. T-cell infiltration and CIMP status, but not MSI screening status, were independent predictors of patient survival. However, subset analyses of MSI and CIMP subgroups suffered from low power, and confirmation by independent data sets is needed.
The first reports of a better prognosis in patients with colorectal tumors highly infiltrated by immune cells,19, 20, 21, 22 have later been confirmed in several large studies including multivariate analysis.24, 25, 26, 27, 28, 29, 30, 31, 32, 33 As in this study, MSI tumors have previously been reported to have a higher degree of T-cell infiltration than MSS tumors.35, 36, 37 Yet the potential confounding effect of MSI screening status on the prognostic importance of T-cell infiltration has been considered in only a minority of reports, of which most,32, 36, 39, 40, 41, 46, 53, 54 but not all,30, 55 found that the better prognosis associated with dense T-cell infiltration was independent of MSI screening status. In this study, a better prognosis was seen in patients with MSS tumors densely infiltrated by T cells compared with poorly or intermediately infiltrated MSI tumors, whereas MSI screening status was not significantly related to prognosis in subgroups of highly and poorly infiltrated tumors separately. Taken together, these results indicate that the density of T cells is an independent prognostic factor, perhaps even more important than MSI screening status.
An increasing amount of evidence supports the importance of identifying subgroups of colorectal cancer based on molecular characteristics, and much attention has recently been paid to the CIMP classification.8, 56, 57 In this study, cancer-specific survival was comparatively high in all patients with tumors highly infiltrated by T cells, regardless of CIMP status. However, in the subgroup of colorectal cancers that were poorly infiltrated by T cells, CIMP-low patients had a poorer prognosis. Only one other research group has considered the potential influence of CIMP status on the relationship between T-cell infiltration and colorectal cancer patient survival.32, 42 As in this study, a beneficial effect of a dense T-cell infiltration, independent of CIMP status, was reported.
Our findings of a beneficial prognosis in colorectal cancer patients with tumors densely infiltrated by T cells were consistent in stage-stratified analyses, and were statistically significant in stage II colorectal cancers. A prognostic marker indicating risk of recurrence and cancer-related death is of particular clinical interest in stage II colorectal cancer, since high-risk patients within this subgroup may potentially benefit from adjuvant chemotherapy, which today is not routinely administered. Together with other stage-stratified results,21, 24, 40, 41, 47, 55, 58 our findings justify the use of tumor infiltrating T cells as a prognostic marker in stage II colorectal cancer.
The administration of radiotherapy reduces the density of T cells in and around a rectal cancer,52 which might complicate the relationship between T-cell infiltration and patient prognosis. In this study, however, the longer cancer-specific survival in patients with a higher degree of T-cell infiltration was consistent in preoperatively radiated and non-radiated subgroups. The degree of T-cell infiltration may thus also be a useful predictive marker in the important subgroup of rectal cancer patients who receive 5 × 5 Gy preoperative radiotherapy.
A majority of previous prognostic studies of lymphocytes are based on routine hematoxylin and eosin stained tissue sections, and few other large studies have investigated the potential use of CD3 as a prognostic marker in colorectal cancer.33, 41, 42, 58 Immunohistochemical staining of CD3 marks all T cells, and we could therefore not consider potential effects from different T-cell subtypes, which can be used in combination to refine the prognostic power of individual measurements. However, immunohistochemical staining of CD3 alone has been shown to perform very well in the prediction of colorectal cancer patient survival.58 T-cell infiltration is not homogeneous in colorectal cancer, and attention has therefore also been focused on the predictive values of T cells in different tumor compartments.32, 33, 37, 42, 43, 44, 45, 46, 47 In this study, the separate measurements of T-cell infiltration in the tumor front, center, and intraepithelial compartment were closely correlated and were all positively associated with cancer-specific survival. Two previous studies found that a high total lymphocyte score, similar to that used in this study, more accurately predicted cancer-specific survival compared with any single score separately.32, 58
The main strength of this study was the large patient group, which was well characterized with respect to clinicopathological factors. A number of potential confounders, including sex, age at diagnosis, tumor site, tumor stage, adjuvant chemotherapy, CIMP, and MSI screening status were taken into consideration. The use of a full tissue section from each tumor avoided sampling errors, which may be a concern in studies using tissue microarrays. We also used a validated eight-gene CIMP panel50, 51 and quantitative real-time PCR (MethyLight) methodology, which minimizes the detection of the biologically less relevant lower degrees of hypermethylation.59 MSI screening status was determined by immunohistochemistry for DNA mismatch repair deficiency, which has been reported to have very high sensitivity and specificity for the detection of MSI-high,60, 61, 62 but does not allow for the distinction of MSI-low.63
Despite the sample size of 446 colorectal cancer patients with immunohistochemical and survival data, some analyses, in particular for the small subgroups of MSI and CIMP-high, were limited by low power. Although we did not take into consideration the potential effects of different treatment regimes when adjusting for adjuvant chemotherapy in the multivariate analyses, the patients in this study were diagnosed during a time when treatment regimes were still relatively homogenous within each tumor site and stage. Cases of hereditary non-polyposis colorectal cancer, who are typically MSI and highly infiltrated by lymphocytes64 were not identified in this study. These cases should not exceed 5% of the colorectal cancer cases studied.65 The number of harvested nodes is another interesting confounding factor that our findings were not adjusted for. A recent study by Ogino et al32 found an association between lymphocyte infiltration and patient survival that was independent of the lymph node count, MSI, and CIMP.
In conclusion, our results indicate that a high total CD3 score is predictive of a longer colorectal cancer-specific survival, largely independent of potentially important factors, such as MSI, CIMP, tumor stage, and preoperative radiotherapy. There is a need of future randomized studies that include T-cell infiltration in the treatment decision protocols for adjuvant chemotherapy.
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Acknowledgements
We thank all participants in CRUMS. We also thank Kerstin Näslund, Department of Medical Biosciences, Umeå University, for excellent technical assistance. This study was financially supported by grants from the Swedish Cancer Society (RP), the Cancer Research Foundation in Northern Sweden (AMD, RP, MLH, JR, BVG), the Swedish Research Council (RP), the Faculty of Medicine, Umeå University, Umeå, Sweden (RP, JR), the J C Kempe Memorial Fund (AMD), and the Cutting-Edge Research Grant from the County Council of Västerbotten, Sweden (RP).
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Dahlin, A., Henriksson, M., Van Guelpen, B. et al. Colorectal cancer prognosis depends on T-cell infiltration and molecular characteristics of the tumor. Mod Pathol 24, 671–682 (2011). https://doi.org/10.1038/modpathol.2010.234
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DOI: https://doi.org/10.1038/modpathol.2010.234
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