The aim of this study was to compare BRAF and KRAS, CpG island methylator phenotype (CIMP), and microsatellite instability (MSI) status in each of the histologic categories, including end-point carcinomas with residual adenoma, of the serrated polyp neoplasia pathway and the traditional (nonserrated) adenoma-carcinoma sequence. Deoxyribonucleic acid (DNA) was extracted from the selected samples and assayed for BRAF, KRAS2 codon12, 13, CIMP using markers hMLH1, MGMT, MINT1, MINT2, p16, and MSI using an assay for BAT25 and BAT26. A BRAF mutation was present in 82% of serrated carcinomas (SCas), 62% of serrated adenomas (SAs), 83% of serrated polyps with abnormal proliferation (SPAPs-syn. sessile serrated adenoma [SSA]), 76% of microvesicular serrated polyps (MVSPs), and was not found in any of the histologic categories of the traditional adenoma-carcinoma sequence. KRAS2 mutations were found in 43% of the goblet cell serrated polyp (GCSP) category, 13% of MVSPs, 7% of SPAPs, and 24% of SAs; in 26% of large traditional adenoma (lTAs) compared with small traditional adenomas (sTAs) (0/30; P<0.005) and in 37.3% of traditional carcinomas (TCa). CIMP-H (>1 marker positive) was significantly more frequent in SPAP, SA, and SCa compared with MVSP (P<0.05); CIMP-H was present in 10% of sTAs but was found more frequently in lTA (44.4%; OR 7.2; P=0.007) and TCa (38.9%; OR 5.8; P=0.007). Higher CIMP levels (4 or more markers positive) were significantly more frequent in advanced categories of the serrated pathway (SAs [31%] and SCas [30%]) compared with lTAs [0%] and TCAs [3.4%] (OR 12.2; P=0.02). MSI-H was identified only in the adenocarcinoma component of SCas (9/11) or in the contiguous SAs (3/7). The findings indicate that a BRAF mutation is a specific marker for a serrated polyp pathway that has its origin in a hyperplastic polyp (MVSP) and a potential end point as MSI carcinoma. CIMP-High (CIMP-H) develops early in this sequence and MSI-H develops late. The data provided a less complete picture of a second serrated pathway, identified by a KRAS2 mutation in SAs, but showed that the progressive stages of both iterations of the serrated neoplasia pathway are separate and distinct from those of the traditional adenoma-carcinoma sequence.
This study describes the detection of colorectal polyps in an average risk-screening cohort at an urban academic medical center. Detection of proximal SSAs increased during the study period. Detection of adenoma, HP, and SSA differed significantly by endoscopist. Classification of HP and SSA differed significantly by pathologist. Endoscopy and pathology practices should consider educational interventions to improve serrated polyp detection and standardize classification.
The aim of this study was to test the hypothesis that mutations of the oncogenes BRAF or KRAS are early events in the putative serrated polyp neoplasia pathway and more advanced pathology is associated with acquired mutator and suppressor gene inactivation by CpG island methylation of promoter regions. We assayed 79 sporadic hyperplastic polyps (HPs) classified according to the schema of Torlakovic et al and 25 serrated adenomas (SAs) for BRAF and KRAS mutations and related the findings to histologic characteristics and CpG island methylation phenotype (CIMP). Mutations at exon 15, codon 599, of BRAF were assayed using an allele-specific PCR (AS-PCR) technique and confirmed in a sample of AS-PCR- positive cases by direct sequencing of exon 15. AS-PCR-negative HPs and SAs were also sequenced on exon 15 and exon 11 to detect additional mutations. PCR-RFLP was used to assay KRAS codon 12 and 13 mutations, and these mutations were further validated by direct sequencing of the KRAS gene. BRAF599 mutations were identified in a total of 55 HPs (69.6%) and KRAS mutations in a total of 13 (16.5%). BRAF599 mutations occurred with similar frequencies among microvesicular serrated polyp (76.3%) and serrated polyp with abnormal proliferation (82.1%) subtypes but less frequently in goblet cell serrated polyps (23.1%). Conversely, KRAS mutations were most frequent in goblet cell serrated polyp (46.2%) and less frequent in microvesicular serrated polyp (13.2%) and serrated polyp with abnormal proliferation (7.1%). BRAF599 and KRAS mutations were present in 15 (60.0%) and 7 (28.0%) of SAs, respectively. BRAF 599 mutation and KRAS were mutually exclusive findings in the polyps studied and one or the other occurred in 68 of 79 (86.1%) HPs and 22 of 25 (88.0%) SAs. CpG island methylation involving 2 or more genes (CIMP-H) was present in 80.0% of SAs, 75% serrated polyp with abnormal proliferations, 47.4% of microvesicular serrated polyps, and 15.4% of goblet cell serrated polyps. SAs were significantly more likely to be CIMP-H than HPs (odds ratio 3.7; 95% confidence interval, 1.27-10.86; P = 0.017). A similar high frequency of KRAS or BRAF mutations across the histologic spectrum of the serrated polyps assayed suggests that these are early events in the serrated polyp neoplasia pathway. In contrast, the association of higher levels of CpG island methylation with more advanced histologic changes suggests that CpG island methylation plays a role in serrated polyp progression toward colorectal carcinoma.
We previously reported that colon carcinomas, adenomas, and hyperplastic polyps exhibiting a serrated histology were very likely to possess BRAF mutations, whereas when these same advanced colonic lesions exhibited non-serrated histology, they were wild type for BRAF; among hyperplastic polyps, KRAS mutations were found mainly in a non-serrated variant. On this basis, we predicted that hyperplastic aberrant crypt foci (ACF), a putative precancerous lesion found in the colon, exhibiting a serrated phenotype would also harbor BRAF mutations and that non-serrated ACF would not. In contrast, KRAS mutations would be found more often in the nonserrated ACF. We examined 55 ACF collected during screening colonoscopy from a total of 28 patients. Following laser capture microdissection, DNA was isolated, and mutations in BRAF and KRAS were determined by direct PCR sequencing. When hyperplastic lesions were further classified into serrated and non-serrated histologies, there was a strong inverse relationship between BRAF and KRAS mutations: a BRAF V600E mutation was identified in 10 of 16 serrated compared with 1 of 33 non-serrated lesions (P = 0.001); conversely, KRAS mutations were present in 3 of 16 serrated compared with 14 of 33 non-serrated lesions. Our finding of a strong association between BRAF mutations and serrated histology in hyperplastic ACF supports the idea that these lesions are an early, sentinel, or a potentially initiating step on the serrated pathway to colorectal carcinoma. [Cancer Res 2007;67(8):3551-4]
Colorectal cancer (CRC) is a heterogeneous disorder than arises via multiple distinct pathways, such as the serrated pathway, in which serrated polyps (including variants of hyperplastic polyps) are the precursor lesions. Approximately 15-20% of all CRCs arise via the serrated pathway, and these serrated carcinomas are clinically, morphologically, and molecularly distinct from conventional CRCs. The prevention of serrated carcinomas represents an important clinical challenge. Gastroenterologists need to recognize and remove potential precursor lesions and implement a post-polypectomy surveillance program when appropriate. This article focuses on the characteristics and significance of clinically relevant serrated polyps and addresses implications for CRC prevention practices.
Exposure to ubiquitous environmental chemicals, such as polycyclic aromatic hydrocarbons (PAH), may contribute to human breast cancer. In animals, PAH induce tumors in part by activating the aryl hydrocarbon receptor (AhR)/transcription factor. Historically, investigations into AhR-regulated carcinogenesis have focused on AhR-dependent transcriptional regulation of cytochrome P450 (CYP) enzymes which oxidize PAH to mutagenic intermediates. However, recent studies suggest that the AhR directly regulates cell growth. Given the postulated role of the AhR in carcinogenesis, we predicted that: (1) tissue predisposed to PAH tumorigenesis would express the AhR and (2) aberrant AhR and/or AhR-regulated gene expression would accompany malignant transformation. To test these hypotheses, AhR and CYP1 protein and/or mRNA levels were evaluated in rat mammary tumors induced with 7, 12-dimethylbenz[a]anthracene (DMBA), a prototypic PAH and AhR ligand. Results indicate modest AhR expression in normal mammary myoepithelial and ductal epithelial cells. In contrast, high AhR levels were detected in DMBA-induced tumors. Nuclear AhR localization in tumors suggested constitutive AhR activation. In situ hybridization and quantitative RT-PCR assays indicated high AhR mRNA levels in neoplastic epithelial cells. While both AhR-regulated CYP1A1 and CYP1B1 mRNAs were induced in breast tissue within 6 h of DMBA gavage, only CYP1B1 mRNA remained elevated in tumors. These results: (1) help explain targeting of breast tissue by carcinogenic PAH, (2) imply that AhR and CYP1B1 hyper-expression represent molecular biomarkers for, at least, PAH-induced mammary cell transformation, and (3) suggest mechanisms through which the AhR may contribute to carcinogenesis well after exogenous AhR ligands have been eliminated.
Noggin ͉ proliferation ͉ skin S kin morphogenesis leads to the formation of an organ that covers and protects the body from external insults and also results in the development of the hair follicles (HFs) that generate hairs, whose phenotype (length, thickness, shape, and color) varies substantially between distinct anatomical sites of the mammalian body (1-5). Hair fiber production is regulated by epithelial-mesenchymal interactions between the HF epithelium and mesenchyme and occurs only during the growing phase of the hair cycle (anagen), whereas it ceases during HF involution (catagen) and relative resting (telogen; refs. 2 and 6-9).
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