Expression of MUC2-mucin in colorectal adenomas and carcinomas of different histological types

The expression of mucin MUC2 was investigated in normal colonic tissue, in colonic adenomas and in carcinomas of the mucinous and non-mucinous type. The latter were subdivided into carcinomas originating from the adenoma-carcinoma sequence (ACS) and de novo (DN) carcinomas. The expression was assayed by immunohistochemistry with the monoclonal anti-MUC2 antibody CCP58 and by mRNA semiquantitation. MUC2 protein epitope CCP58 was strongly expressed in 21 % of normal colonic tissues, in 40% of villous and in 48% of tubular adenomas. Mucinous carcinomas exhibited strong expression in 72%, ACS carcinomas in 21 % and DN adenocarcinomas in none of the tumors investigated. Compared with the adjacent non malignant tissue (transitional mucosa), CCP58 epitope expression in the tumor was higher in 74% of mucinous carcinomas, but equal or lower in 69% of ACS carcinomas and in 100% of de novo carcinomas. The alterations of MUC2 expression detected by immunohistochemistry in adenocarcinomas were confirmed on mRNA level. These data indicate that the MUC2 expression pattern is different in the 3 carcinoma types investigated. MUC2 over-expression occurs in the adenomatous tissue. It is always maintained in mucinous carcinomas, but frequently decreased in non-mucinous ACS carcinomas. DN carcinomas are most frequently associated with decreased expression of MUC2. © 1994 Wiley-Liss, Inc.     

Role of site-specific promoter hypomethylation in aberrant MUC2 mucin expression in mucinous gastric carcinomas

In the present work we investigated the methylation levels of mucin gene (MUC)2 promoter region in normal gastric mucosa and mucinous gastric carcinoma in order to access if the observed de novo expression of the intestinal mucin MUC2 in mucinous gastric carcinoma is associated with changes in MUC2 promoter methylation status. The results obtained by methylation-sensitive single nucleotide primer extension suggest that MUC2 expression in gastric cells is regulated by promoter methylation and further indicate that two specific cytosine guaine dinucleotide (CpG) sites may play a particularly important regulatory role.     

De novo expression of the Muc2 gene in pancreas carcinoma cells is triggered by promoter demethylation.

It has been established that mucin-producing variants of different subtypes of pancreatic carcinomas, including the intraductal papillary and ductal mucinous tumors, have usually a more favorable prognosis. Intraductal papillary and ductal mucinous tumors have also been shown to ectopically express the intestinal mucin gene MUC2. The mechanism of the de novo expression of this gene in tumors may have potential implications for the modulation of its behavior. We studied, therefore, the mechanism of the de novo expression of MUC2 in pancreas carcinoma cells in vitro. The MUC2 gene promoter is methylated in the nonexpressing pancreatic cell line PANC-1 and is not methylated in the expressing cell line BxPC-3. The promoter is silenced by methylation as shown by reporter expression assays. De novo expression of MUC2 in PANC-1 cells is triggered by treating the cells with a pharmacological inhibitor of DNA methylation (5-aza-2'-deoxycytidine). There was no decrease or loss of expression of the methyltransferase DNMT1 in the MUC2-producing cells. These data show that the de novo expression of the MUC2 gene in pancreas carcinoma cells is associated with promoter demethylation. They warrant further investigations on the relationship between MUC2 promoter demethylation in pancreatic cancer and the prognosis of carcinoma patients.     

Mucin expression in mucinous carcinoma and other invasive carcinomas of the breast.

To investigate mucin expression in breast cancer, immunohistochemical staining was performed on 30 mucinous carcinomas and 95 non-mucinous invasive carcinomas. MUC2 expression was detected in all mucinous carcinomas, but only in 11.1% of invasive ductal carcinomas, and in none of the invasive lobular carcinomas and medullary carcinomas. MUC1 is often expressed in invasive breast carcinoma, but not in medullary carcinoma. Strong cytoplasmic staining was seen in invasive ductal carcinoma, in contrast to surface membrane staining in mucinous carcinoma and intracytoplasmic vacuole staining in invasive lobular carcinoma. CA19-9 and CA50 expression in more than 25% of tumor cells was seen in 17.2 and 16.0% of invasive ductal carcinomas, respectively, but not in mucinous carcinomas. CA125 and human gastric mucin were rarely expressed in breast cancer, irrespective of histologic type.     

Expression of mucin core proteins, trefoil factors, APC and p21 in subsets of colorectal polyps and cancers suggests a distinct pathway of pathogenesis of mucinous carcinoma of the colorectum

Mucin core proteins are expressed in a tissue and cell type specific manner in the normal gastrointestinal tract. Aberrant expression of mucin core proteins have been reported in colorectal neoplasms. To examine the relationship between subsets of colorectal polyps and non-mucinous and mucinous adenocarcinomas of the colorectum, we evaluated the frequency of the expression of cell lineage associated mucin core proteins (MUC5AC and MUC2), trefoil factors (TFF1 and TFF3), and APC and p21 in these tissues. An immunohistochemical study was performed in 10 normal rectal mucosa samples (NM) 21 hyperplastic polyps (HP), 20 serrated adenomas (SA), 25 tubular adenomas (TA), 13 tubulovillous adenomas (TVA), 7 villous adenomas (VA), 42 non-mucinous colorectal cancers (NMC), and 19 mucinous colorectal cancers (MC). A higher frequency of ectopic expression of gastric foveolar mucin, MUC5AC, and the expression of intestinal goblet cell mucins, MUC2, was observed respectively in HP (100%, 100%), SA (85%, 85%), TVA (85%, 85%), and VA (100%, 100%), compared to TA (32%, p<0.002; 36%, p<0.01). MC (68%, 100%) also showed a higher frequency of the expression of MUC5AC and MUC2 compared to NMC (31%, p=0.001; 38%, p<0.001), and TFF1 showed similar patterns of expression. APC protein and p21 were also expressed at a higher frequency in HP (100%, 100%), and SA (67%, 83%), than in TA (29%, p<0.03; 46%, p<0.05). MC (68%, 100%) showed a higher frequency of expression of APC protein and p21 than NMC (19%, p<0.001; 45%, p<0.01). Our results showed that MUC2 expression and de novo ectopic expression of MUC5AC and TFF1 are more frequent in HP, SA, TVA, VA, and MC than in TA and NMC. These results suggest that simultaneous activation of differentiation pathways of goblet cells and gastric foveolar cells may occur predominantly in the pathogenesis of HP, SA, TVA, VA, and MC, while the pathogenesis of TA and NMC are less likely to involve these processes.     

HLA antigens in colorectal tumours--low expression of HLA class I antigens in mucinous colorectal carcinomas

Expression of HLA antigens and beta 2-microglobulin was studied by immunoperoxidase staining of frozen sections of 9 mucinous and 10 nonmucinous colorectal adenocarcinomas, 1 cloacogenic carcinoma, 12 colorectal adenomas and 4 samples of normal colorectal mucosa using monoclonal antibodies (MAbs). Staining results were related to histopathological features. HLA Class I antigens were strongly expressed in morphologically normal colorectal epithelium, in all adenomas tested and in all non-mucinous carcinomas. In contrast, expression of HLA class I antigens by the majority of tumour cells was present in only 2 of the 9 mucinous carcinomas, whereas 2 of these mucinous carcinomas were completely negative. In the mucinous carcinomas a striking scarcity of mononuclear inflammatory infiltrate, especially around the mucus accumulations, was observed. HLA class II antigen expression was not detected in normal epithelium and was only focally present in 1 of the 12 adenomas. In 6 out of the 20 carcinomas tested between 20% and 90% of the tumour cells were stained by MAbs against HLA class II antigens. Apart from the low expression of HLA class I antigens in mucinous carcinomas no relationship was found between expression of HLA antigens and histological features of the tumours. The relative poor prognosis of mucinous colorectal carcinoma as reported in the literature may be associated with low expression of HLA class I antigens and scant mononuclear inflammatory infiltrate, which may be a reflection of a weak immune response to the tumour cells.     

Genome-wide molecular characterization of mucinous colorectal adenocarcinoma using cDNA microarray analysis

Mucinous colorectal carcinoma exhibits distinct clinicopathological features compared to non-mucinous colorectal carcinoma. Previous studies have discovered several molecular genetic features in mucinous colorectal carcinomas, but have limitations as they are confined to a small number of molecules. To understand the mucinous colorectal carcinoma system, this study was designed to identify genes that are differentially expressed in mucinous colorectal carcinoma compared to non-mucinous colorectal carcinoma using cDNA microarrays. cDNA microarray experiments were performed using human cDNA 17k chips with 25 mucinous and 27 non-mucinous cancer tissues. Differentially expressed genes (DEGs) were determined by Welch's t-test and more accurate classifiers were selected from the DEGs using the prediction analysis for microarrays (PAM) software package. Array results were validated using quantitative real-time RT-PCR. The identified gene set was functionally investigated through in silico analysis. Sixty-two DEGs were identified and the 50 highest ranking genes could be used to accurately classify mucinous and non-mucinous colorectal carcinomas. The identified gene set included up-regulated TFF1 (4-fold), AGR2 (3.3-fold), FSCN1 (2.2-fold), CD44 (1.5-fold) and down-regulated SLC26A3 (0.2-fold) in MC. TFF1, AGR2 and SLC26A3 were validated by quantitative real-time RT-PCR. The functions of these DEGs were related to tumorigenesis (14 genes), cell cycle progression (6 genes), invasion (2 genes), anti-apoptosis (7 genes), cell adhesion and proliferation (5 genes) and carbohydrate metabolism (3 genes). We suggest that MC has distinct molecular characteristics from NMC and therefore, that the expression signatures of DEGs may improve the understanding of molecular pathogenesis and clinical behaviors in MC.     

Methylation of hMLH1 promoter correlates with the gene silencing with a region-specific manner in colorectal cancer

Microsatellite instability is present in over 80% of the hereditary non-polyposis colorectal carcinoma and about 15-20% of the sporadic cancer. Microsatellite instability is caused by the inactivation of the mismatch repair genes, such as primarily hMLH1, hMSH2. To study the mechanisms of the inactivation of mismatch repair genes in colorectal cancers, especially the region-specific methylation of hMLH1 promoter and its correlation with gene expression, we analysed microsatellite instability, expression and methylation of hMLH1 and loss of heterozygosity at hMLH1 locus in these samples. Microsatellite instability was present in 17 of 71 primary tumours of colorectal cancer, including 14 of 39 (36%) mucinous cancer and three of 32 (9%) non-mucinous cancer. Loss of hMLH1 and hMSH2 expression was detected in nine and three of 16 microsatellite instability tumours respectively. Methylation at CpG sites in a proximal region of hMLH1 promoter was detected in seven of nine tumours that showed no hMLH1 expression, while no methylation was present in normal mucosa and tumours which express hMLH1. However, methylation in the distal region was observed in all tissues including normal mucosa and hMLH1 expressing tumours. This observation indicates that methylation of hMLH1 promoter plays an important role in microsatellite instability with a region-specific manner in colorectal cancer. Loss of heterozygosity at hMLH1 locus was present in four of 17 cell lines and 16 of 54 tumours with normal hMLH1 status, while loss of heterozygosity was absent in all nine cell lines and nine tumours with abnormal hMLH1 status (mutation or loss of expression), showing loss of heterozygosity is not frequently involved in the inactivation of hMLH1 gene in sporadic colorectal cancer.     

Clinicopathological and genetic characteristics of mucinous carcinomas in the colorectum.

We investigated the clinicopathological and genetic characteristics including patients' gender, age, tumour location, growth pattern, Dukes' stage, DNA ploidy, S-phase fraction, PCNA, apoptosis, c-erbB-2, bcl-2, K-ras, p53, DCC and heat shock protein in 32 mucinous carcinomas versus 261 non-mucinous carcinomas in the colorectum. Sixty percent of mucinous carcinomas were located in the right colon, 13% in the left colon and 27% in the rectum (p=0.01). More mucinous carcinomas grew in expanding pattern than non-mucinous carcinomas (66% vs 39%, p=0.005). Compared with non-mucinous carcinoma, mucinous carcinoma had more K-ras mutations (50% vs 25%, p=0.02), but less p53 expression (72% vs 49%, p=0.02) and less apoptotic activity (19% vs 51%, p=0.01). We further confirm that the mucinous carcinoma in the colorectum represents a distinct clinicopathologic and genetic features as compared to non-mucinous tumour, and may have a different biological behaviour.     

Clinicopathological significance of mucin 2 immunohistochemical expression in colorectal cancer: A meta-analysis

Objective: To evaluate the association between mucin 2 (MUC2) expression and clinicopathological characters of colorectal cancer. Methods: A literature search was performed on December 31, 2010 according to defined selection criteria. We evaluated the correlation between MUC2 (detected by immunohistochemistry) and clinicopathological characters of colorectal cancer. According to the tumor histological type, differentiation, location and TNM staging of colorectal carcinoma, we divided the clinicopathological characteristics into different subgroups. Fixed and random effects models were applied for estimation of the summarized risk ratios (RRs) and 95% confidence intervals (CIs) in different subgroups. Finally, forest plots and funnel plots were created to allow for visual comparison of the results or the effect of publication bias. Results: According with the inclusive criteria, fourteen studies (n=1,558) were eligible for the meta-analysis. We observed a trend towards a correlation of MUC2 higher positivity in mucinous than non-mucinous carcinoma (RR, 2.10; 95% CI, 1.30-3.40; P=0.002) and less positivity in distal than proximal colon (RR, 0.74; 95% CI, 0.64-0.85; P=0.000). There was no statistically significance for the association between MUC2 expression and differentiation or TNM staging of colorectal cancer, but MUC2 overexpression tended to be associated with the presence of T stage tumor (RR, 1.17; P=0.052). Conclusion: MUC2 overexpression was associated with the mucinous and proximal colorectal cancer.     

粘液性大肠癌组织蛋白酶B、D表达与肿瘤浸润

目的组织蛋白酶B(Cathepsin B,CB)在粘液性大肠癌的表达尚未明了.组织蛋白酶D(Cathepsin D,CD)在肿瘤浸润和转移中的作用仍存在争议.本实验目的系探讨粘液性大肠癌CB和CD表达及其与肿瘤浸润转移的关系.方法采用免疫组化方法对48例人不同类型大肠癌CB及CD表达进行半定量检测.结果伴淋巴结转移大肠癌CB和CD表达率高于不伴淋巴结转移大肠癌,差异具显著性(P＜0.05;P＜0.005).粘液性大肠癌CB表达高于非粘液性者,差别具显著性(P＜0.05),但CD表达差异却无显著性意义(P＞0.05).结论提示大肠癌CB和CD表达与肿瘤浸润转移有关,CB在粘液性大肠癌浸润转移中作用可能更为重要.     

Expression of Gal beta 1-4GlcNAc sequences by human gastrointestinal neoplasms and their precursors as detected by Erythrina cristagalli and Erythrina corallodendron lectins

Lectins from Erythrina cristagalli (EGA) and Erythrina corallodendron (ECorA) are well-known to detect type 2 chain oligosaccharides (Gal beta 1-4GlcNAc). These carbohydrate moieties are the biosynthetic precursors of various ABH and Lewis blood group antigens and are therefore also related to tumor-associated carbohydrate antigens. For this reason, we investigated the expression of ECA and ECorA binding sites in a series of gastric, colorectal and pancreatic carcinomas as well as corresponding normal tissues. Additionally, a series of hyperplastic and adenomatous colorectal polyps was analyzed. According to our results, both lectins exhibited a strong reactivity with the great majority of gastrointestinal carcinomas. Regarding gastric carcinomas, a stronger reactivity with intestinal-type compared to the diffuse-type species could be observed. Some poorly differentiated tumors were not or only very faintly stained. In the case of colorectal carcinomas, liver metastases which were investigated comparatively, exhibited the same binding pattern as the primary tumors. Colorectal adenomas were stained in about half of the cases without significant relation to the grade of cellular atypia. Positivity observed in normal epithelia (i.e, gastric superficial epithelia, fundus neck cells and deep pyloric mucous glands, pancreatic acini and ductal structures) is in keeping with histogenetic relations between these normal histological structures and corresponding neoplasms. In areas exhibiting intestinal metaplasia, various portions showed cytoplasmic staining of columnar cells and/or of goblet cell vacuoles. On the other hand, columnar and goblet cells in normal colorectal tissue were only weakly stained in a number of specimens. Therefore, it can be concluded that Gal beta 1-4GlcNAc is overexpressed in neoplastic colorectal tissues. Summarized, ECA and ECorA are suitable tools to analyze the expression of Gal beta 1-4GlcNAc, the common precursor substance of various tumor-associated type 2 chain antigens in neoplastic tissues.     

Promoter region methylation does not account for the frequent loss of expression of the Fas gene in colorectal carcinoma

Expression of the apoptosis-promoting Fas gene is frequently reduced or lost during the development of colorectal carcinoma. However, loss of heterozygosity at the Fas locus or Fas gene rearrangements do not account for the loss of expression of Fas, raising the possibility that methylation of the Fas promoter may inhibit gene expression in colorectal carcinomas. We have examined the Fas promoter region CpG island for evidence of hypermethylation in colorectal tumours. Forty-seven specimens of colorectal adenoma and carcinoma, as well as six samples of normal colonic mucosa, were examined by Southern blotting for methylation at HpaII and Cfol sites in this region. No methylation was detected in any of the specimens, suggesting that hypermethylation is not primarily responsible for the loss of expression of the Fas gene during colorectal tumorigenesis.     

Altered phenotype of HT29 colonic adenocarcinoma cells following expression of the DCC gene.

On 18q, frequently deleted in late stage colorectal cancers, a gene, Deleted in Colon Cancer (DCC), has been identified and postulated to play a role as a tumor suppressor gene. DCC is retained in the majority of mucinous tumors, which produce high levels of mucins, and seems to be preferentially expressed in intestinal goblet cells. To investigate whether DCC is related to mucin expression and can modulate the transformed phenotype, we introduced a full-length DCC cDNA into HT29 cells, which can be induced in vitro to express MUC2, the gene that encodes the major colonic mucin. Expression of DCC did not modulate constitutive or induced expression of MUC2, nor did DCC induce a mature goblet cell phenotype. However, HT29 clones expressing high and low levels of DCC protein showed a significant decrease in cell proliferation and tumorigenicity. Furthermore, increased shedding and an elevated rate of spontaneous apoptosis were associated with higher levels of expression of DCC. In summary, while restoration of DCC expression in a human colon carcinoma cell line did not influence expression of differentiation markers, DCC expression did affect the growth and tumorigenic properties of the cells suggesting that DCC can modulate the malignant phenotype of colon cancer.     

Mouse intestinal goblet cells expressing SV40 T antigen directed by the MUC2 mucin gene promoter undergo apoptosis upon migration to the villi

Mucinous colorectal cancers exhibit a characteristic set of molecular genetic alterations and may be derived from progenitor cells committed to the goblet cell lineage. Previously, we demonstrated that the MUC2 mucin gene promoter drives transgene reporter expression with high specificity in small intestinal goblet cells of transgenic mice. On the basis of these experiments, we reasoned that the MUC2 promoter could be used to drive SV40 T antigen (Tag) expression in the same cell type, decoupling them from their normal antiproliferative controls. A line of mice was established (MUCTag6) that expressed Tag in intestinal goblet cells as determined by RNA blot and immunohistochemical analysis. These goblet cells were markedly involuted however, most notably in the villi. Endogenous intestinal MUC2 message levels were reduced to about one third the normal level in these mice. However, absorptive cell lineage markers were comparable with nontransgenics. Bromodeoxyuridine-positive S-phase cells are limited to crypts in nontransgenic intestine but are present in both crypts and villi in MUCTag6. In contrast, mitotic cells were not present in the villi, indicating that MUCTag6 villi goblet cells do not progress into M phase. Apoptotic cells positive for terminal deoxynucleotidyl transferase-mediated dUTP-biotin nick end-labeling were increased more than fourfold in MUCTag6 villi (P < 0.0001), and apoptotic goblet cells were evident. Electron microscopic examination of MUCTag6 intestinal villi revealed the presence of degraded cell remnants containing mucin goblets together with other cell debris, further indicating apoptosis of the goblet cell lineage. Thus, the expression of Tag in intestinal goblet cells releases them from normal antiproliferative controls, causing their inappropriate entry into S phase even after they transverse the crypt/villus junction. They do not, however, progress to M phase. Instead, they undergo apoptosis with a high degree of efficiency in S or G(2) phase. These experiments demonstrate that apoptosis effectively blocks inappropriate goblet cell proliferation in the intestine, supporting its proposed role as an antineoplastic mechanism.     

The increase in the expression and hypomethylation of MUC4 gene with the progression of pancreatic ductal adenocarcinoma

The MUC4 gene could have a key role in the progression of pancreatic cancer, but the quantitative measurement of its expression in clinical tissue samples remains a challenge. The correlations between MUC4 promoter methylation status in vivo and either pancreatic cancer progression or MUC4 mRNA expression need to be demonstrated. We used the techniques of quantitative real-time PCR and DNA methylation-specific PCR combined microdissection to precisely detect MUC4 expression and promoter methylation status in 116 microdissected foci from 57 patients with pancreatic ductal adenocarcinoma. Both mRNA expression and hypomethylation frequency increased from normal to precancerous lesions to pancreatic cancer. Multivariate Cox regression analysis showed that high-level MUC4 expression (P = 0.008) and tumor-node-metastasis staging (P = 0.038) were significant independent risk factors for predicting the prognosis of 57 patients. The MUC4 mRNA expression was not significantly correlated with promoter methylation status in 30 foci of pancreatic ductal adenocarcinoma. These results suggest that high mRNA expression and hypomethylation of the MUC4 gene could be involved in carcinogenesis and in the malignant development of pancreatic ductal adenocarcinoma. The MUC4 mRNA expression may become a new prognostic marker for pancreatic cancer. Microdissection-based quantitative real-time PCR and methylation-specific PCR contribute to the quantitative detection of MUC4 expression in clinical samples and reflect the epigenetic regulatory mechanisms of MUC4 in vivo.     

MeCP2 and promoter methylation cooperatively regulate E-cadherin gene expression in colorectal carcinoma

Reduced expression of E-cadherin (E-cad) owing to aberrant 5'CpG island hypermethylation has been regarded as one of the main molecular events involved in the dysfunction of the cell-cell adhesion system. The molecular mechanisms providing diversity and heterogeneity of E-cad expression in colorectal carcinoma were explored. In 29 cases of colorectal carcinoma in Indonesia, the expression of E-cad was analyzed by immunohistochemical staining, the methylation status of the E-cad promoter was determined by methylation-specific PCR, and the expression of methyl-CpG-binding protein (MeCP) 2 was studied by in situ hybridization. E-cad expression was strong, and no methylation was observed in normal colon mucosa and most of the well-differentiated adenocarcinoma. In contrast, both signet-ring cell carcinoma and mucinous adenocarcinoma showed fully methylated patterns and strong MeCP2 expression. In moderately- and poorly-differentiated adenocarcinomas, however, E-cad expression was rather heterogeneous, especially at the front of invasion and in the dissociated areas, where loss of MeCP2 expression correlated with E-cad reexpression even in the presence of E-cad promoter methylation. We conclude that both CpG methylation of the E-cad promoter and significant MeCP2 expression cooperatively and epigenetically regulate E-cad expression in colorectal cancer. (Cancer Sci 2003; 94: 442–447)     

Mapping of the methylation pattern of the MUC2 promoter in pancreatic cancer cell lines, using bisulfite genomic sequencing

Expression of the MUC2 gene is controlled by the methylation of CpG sites in the promoter region, but the detailed methylation status of this region has yet to be reported. We have mapped the complete methylation status of the MUC2 promoter from position -1989 to position +288 upstream, a region that contains 59 CpG sites, using bisulfite genomic sequencing in two pancreatic cancer cell lines (PANC1, BxPC3) and in isolated normal colon crypts as a control. The MUC2 promoter in PANC1, a cell line that does not express MUC2, was highly methylated (average 87%, complete methylation at 28 of the 59 CpG sites), while the promoter region in the MUC2-expressing BxPC3 cell line (average 43%, complete methylation at 2 of 59 CpG sites) and in MUC2-expressing normal colon crypts (average 33%, no CpG site was completely methylated) were only partially methylated (P<0.0001). 5-Aza-2'-deoxycytidine treatment of PANC1 cells reduced the methylation level (average 36%) and induced MUC2 mRNA expression. However, mRNA expression of AP2, SP1 and CDX2 was not affected by this treatment. Our data provide the first detailed methylation map of the MUC2 promoter region for the first time, using the conversion-specific bisulfite genomic sequencing. Previously unproven methylation sites were detected, and some AP2 and SP1 binding sites showed different methylation levels among PANC1, BxPC3 and colonic crypt cells. Our mapping data provide an essential basis for further studies of methylation-regulated MUC2 inactivation.