Project description:Background & Aims: Colorectal adenoma is a major precancerous lesion in colorectal cancer (CRC), and the adenoma-carcinoma sequence is a well-known multistep progression to CRC caused by the accumulation of genetic mutations. Accumulating evidence suggests that intra-tumor heterogeneity in CRC is influenced not only by genetic alterations, but also by non-genetic mechanisms. However, in adenomas, the non-genetic mechanisms remain largely unknown. Methods: Organoids were isolated from colorectal adenoma tissue. Single cells derived from patient-derived adenoma organoids were evaluated for their proliferative potential. The growth patterns of single-cell-derived spheroids were divided into two groups (D-/S-pattern) and the molecular mechanisms underlying the differences in growth patterns were examined. Results: Organoids were established from 31 colorectal adenomas from 19 patients. Some adenomas showed heterogeneity in the proliferative potential of single cells, as observed in CRC, and this heterogeneity was regulated by non-genetic mechanisms. IGF2BP3 was identified as a differentially expressed gene between organoids with different growth patterns and was found to be a key regulator of the high proliferative potential of adenomas. IGF2BP3 positively regulated MYC expression at the transcriptional level and negatively regulated it at the translational level. This promoted high proliferative potential with high levels of oxidative phosphorylation, while allowing cells to avoid MYC-induced cell death. IGF2BP3 affected the tumorigenicity of mouse adenomas in vivo. Conclusion: Intra-tumor heterogeneity in growth potential is acquired at the precancerous stage in the adenoma-carcinoma sequence of colorectal carcinogenesis, and IGF2BP3 plays an important role in regulating MYC levels. These findings provide new insights into the non-genetic regulation of adenomas during CRC development.

Project description:Background & Aims: Colorectal adenoma is a major precancerous lesion in colorectal cancer (CRC), and the adenoma-carcinoma sequence is a well-known multistep progression to CRC caused by the accumulation of genetic mutations. Accumulating evidence suggests that intra-tumor heterogeneity in CRC is influenced not only by genetic alterations, but also by non-genetic mechanisms. However, in adenomas, the non-genetic mechanisms remain largely unknown. Methods: Organoids were isolated from colorectal adenoma tissue. Single cells derived from patient-derived adenoma organoids were evaluated for their proliferative potential. The growth patterns of single-cell-derived spheroids were divided into two groups (D-/S-pattern) and the molecular mechanisms underlying the differences in growth patterns were examined. Results: Organoids were established from 31 colorectal adenomas from 19 patients. Some adenomas showed heterogeneity in the proliferative potential of single cells, as observed in CRC, and this heterogeneity was regulated by non-genetic mechanisms. IGF2BP3 was identified as a differentially expressed gene between organoids with different growth patterns and was found to be a key regulator of the high proliferative potential of adenomas. IGF2BP3 positively regulated MYC expression at the transcriptional level and negatively regulated it at the translational level. This promoted high proliferative potential with high levels of oxidative phosphorylation, while allowing cells to avoid MYC-induced cell death. IGF2BP3 affected the tumorigenicity of mouse adenomas in vivo. Conclusion: Intra-tumor heterogeneity in growth potential is acquired at the precancerous stage in the adenoma-carcinoma sequence of colorectal carcinogenesis, and IGF2BP3 plays an important role in regulating MYC levels. These findings provide new insights into the non-genetic regulation of adenomas during CRC development. The gene expression profiles of S-pattern (CP1-5, CP3-5, and CP9-1) and D-pattern (CP1-1, CP3-2, and CP9-2) patient-derived adenoma organoid lines were compared using microarray analysis.

Project description:Approximately two decades ago, Vogelstein and Fearon proposed the adenoma-carcinoma sequence of sporadic CRC development and illustrated the accumulation of genetic alterations during the stepwise progression, thereby providing a guideline for clinical practice. Although the detection and excision of precancerous lesions could prevent colorectal cancer and reduce mortality, 6% of adenomas will ultimately develop into colorectal cancer. Thus, this genetic model for colorectal tumorigenesis may not completely reflect the complex essence of the disease and whether the mode of initiation of the events in the multistep progression affects the outcome of CRC is still unknown. In this study, mRNA and miRNA expression profiling was performed with human colorectal tissues, including normal mucosa, adenoma and adenocarcinoma. Then, an integrated approach was adopted to establish the regulatory interaction networks that were correlated with colorectal carcinogenesis. Finally, a 55-gene signature whose expression was down-regulated in precancerous lesions compared to normal tissue was identified as a potential early indicator of CRC survival. The results suggested that genes related to immunity and homeostasis played a critical role in protection against adenoma initiation and that the altered molecular events that influence colorectal cancer prognosis may be set in an early, precancerous stage. Four types of human colorectal tissues were selected by colonoscopic resection or colorectal surgery, including 12 normal mucosae, 21 low-grade adenomas (mild or moderate atypical hyperplasia), 30 high-grade adenomas (severe atypical hyperplasia or carcinoma in situ) and 25 adenocarcinomas. Gene expression profiling analysis of these samples was performed using Agilent 4x44K human whole genome gene expression microarray (G4112F).

Project description:Approximately two decades ago, Vogelstein and Fearon proposed the adenoma-carcinoma sequence of sporadic CRC development and illustrated the accumulation of genetic alterations during the stepwise progression, thereby providing a guideline for clinical practice. Although the detection and excision of precancerous lesions could prevent colorectal cancer and reduce mortality, 6% of adenomas will ultimately develop into colorectal cancer. Thus, this genetic model for colorectal tumorigenesis may not completely reflect the complex essence of the disease and whether the mode of initiation of the events in the multistep progression affects the outcome of CRC is still unknown. In this study, mRNA and miRNA expression profiling was performed with human colorectal tissues, including normal mucosa, adenoma and adenocarcinoma. Then, an integrated approach was adopted to establish the regulatory interaction networks that were correlated with colorectal carcinogenesis. Finally, a 55-gene signature whose expression was down-regulated in precancerous lesions compared to normal tissue was identified as a potential early indicator of CRC survival. The results suggested that genes related to immunity and homeostasis played a critical role in protection against adenoma initiation and that the altered molecular events that influence colorectal cancer prognosis may be set in an early, precancerous stage. Four types of human colorectal tissues were selected by colonoscopic resection or colorectal surgery, including 15 normal mucosae, 39 low-grade adenomas (mild or moderate atypical hyperplasia), 20 high-grade adenomas (severe atypical hyperplasia or carcinoma in situ) and 33 adenocarcinomas. MicroRNA expression profiling analysis of these samples was performed on Agilent 8×16K Human miRNA Microarray V3 (G4470C).

Project description:Approximately two decades ago, Vogelstein and Fearon proposed the adenoma-carcinoma sequence of sporadic CRC development and illustrated the accumulation of genetic alterations during the stepwise progression, thereby providing a guideline for clinical practice. Although the detection and excision of precancerous lesions could prevent colorectal cancer and reduce mortality, 6% of adenomas will ultimately develop into colorectal cancer. Thus, this genetic model for colorectal tumorigenesis may not completely reflect the complex essence of the disease and whether the mode of initiation of the events in the multistep progression affects the outcome of CRC is still unknown. In this study, mRNA and miRNA expression profiling was performed with human colorectal tissues, including normal mucosa, adenoma and adenocarcinoma. Then, an integrated approach was adopted to establish the regulatory interaction networks that were correlated with colorectal carcinogenesis. Finally, a 55-gene signature whose expression was down-regulated in precancerous lesions compared to normal tissue was identified as a potential early indicator of CRC survival. The results suggested that genes related to immunity and homeostasis played a critical role in protection against adenoma initiation and that the altered molecular events that influence colorectal cancer prognosis may be set in an early, precancerous stage.

Project description:Approximately two decades ago, Vogelstein and Fearon proposed the adenoma-carcinoma sequence of sporadic CRC development and illustrated the accumulation of genetic alterations during the stepwise progression, thereby providing a guideline for clinical practice. Although the detection and excision of precancerous lesions could prevent colorectal cancer and reduce mortality, 6% of adenomas will ultimately develop into colorectal cancer. Thus, this genetic model for colorectal tumorigenesis may not completely reflect the complex essence of the disease and whether the mode of initiation of the events in the multistep progression affects the outcome of CRC is still unknown. In this study, mRNA and miRNA expression profiling was performed with human colorectal tissues, including normal mucosa, adenoma and adenocarcinoma. Then, an integrated approach was adopted to establish the regulatory interaction networks that were correlated with colorectal carcinogenesis. Finally, a 55-gene signature whose expression was down-regulated in precancerous lesions compared to normal tissue was identified as a potential early indicator of CRC survival. The results suggested that genes related to immunity and homeostasis played a critical role in protection against adenoma initiation and that the altered molecular events that influence colorectal cancer prognosis may be set in an early, precancerous stage.

Project description:Colorectal adenomas are common precancerous lesions with the potential for malignant transformation to colorectal adenocarcinoma. Endoscopic polypectomy provides an opportunity for cancer prevention, however, recurrence rates are high. We collected formalin-fixed paraffin-embedded tissue of fourteen primary adenomas with recurrence, fourteen primary adenomas without recurrence, and fourteen matched pair samples (primary adenoma and the corresponding recurrent adenoma). These samples were analysed by array-based comparative genomic hybridisation (aCGH) to understand the dynamics of copy number alterations (CNAs) and to identify molecular markers to predict recurrence. ACGH analysis confirmed the genetic landscape specific for colorectal tumorigenesis, i.e., CNAs of chromosomes 7 (13.7%), 13q (13.7%), 18 (5.8%) and 20q (13.7%). CNAs were detected in 41/51 (80.4%) of colorectal adenomas (2N). Focal aberrations (≤10 Mbp) were mapped to chromosome bands 6p22.1-p21.33 (33.3%), 7q22.1 (31.4%) and 16q21 (29.4%). Gains of CDX2 were exclusively seen in adenomas with recurrence compared to adenomas without recurrence. However, the average number of copy alterations failed to discriminate primary adenomas with recurrence from primary adenomas without recurrence.

Project description:Genetic and epigenetic alterations are a fundamental aspect of colorectal cancer formation. There is considerable heterogeneity between colorectal cancers regarding the mutations and methylated genes they carry, and this heterogeneity may arise early in the polyp-cancer sequence. However, our understanding of the epigenetic alterations and gene mutations in colon adenomas and their relation to colorectal cancer is incomplete. Thus, we have assessed the methylome in normal colon mucosa, tubular adenomas, and colorectal adenocarcinomas and have determined the relationship of these findings between adenomas and cancer in the colon. Genome-wide alterations in DNA methylation were found in the normal colon mucosa adjacent to colorectal cancer, tubular adenomas, and colorectal cancer. Three subgroups of CRCs and two subgroups of adenomas were identified on the basis of their DNA methylation patterns. The adenomas separated into a high-frequency methylation class (Adenoma-H) and a low-frequency methylation class. The adenoma-H polyps have a methylated DNA signature similar to non-CIMP CRCs, whereas those of the Adenoma-L class have a similar methylation pattern to normal colon mucosa. The CpGs that account for these signatures are located in intragenic/intergenic regions, which suggests that these two groups of adenomas arise from different stem cell populations. We conducted genome-wide array-based studies and comprehensive data analyses of aberrantly methylated loci in 41 normal colon samples, 42 colon adenomas, and 64 colorectal cancers. Supplementary file 'GSE48684_Matrix_signal_intensities_1.txt.gz': includes the unmethylated and methylated signal intensities from Samples GSM1183439-GSM1183561. Supplementary file 'GSE48684_Matrix_signal_intensities_2.txt.gz': includes the unmethylated and methylated signal intensities from Samples GSM1235135-GSM1235158.

Project description:Genetic and epigenetic alterations are a fundamental aspect of colorectal cancer formation. There is considerable heterogeneity between colorectal cancers regarding the mutations and methylated genes they carry, and this heterogeneity may arise early in the polyp-cancer sequence. However, our understanding of the epigenetic alterations and gene mutations in colon adenomas and their relation to colorectal cancer is incomplete. Thus, we have assessed the methylome in normal colon mucosa, tubular adenomas, and colorectal adenocarcinomas and have determined the relationship of these findings between adenomas and cancer in the colon. Genome-wide alterations in DNA methylation were found in the normal colon mucosa adjacent to colorectal cancer, tubular adenomas, and colorectal cancer. Three subgroups of CRCs and two subgroups of adenomas were identified on the basis of their DNA methylation patterns. The adenomas separated into a high-frequency methylation class (Adenoma-H) and a low-frequency methylation class. The adenoma-H polyps have a methylated DNA signature similar to non-CIMP CRCs, whereas those of the Adenoma-L class have a similar methylation pattern to normal colon mucosa. The CpGs that account for these signatures are located in intragenic/intergenic regions, which suggests that these two groups of adenomas arise from different stem cell populations.

Project description:Aberrant activation of WNT signaling and loss of BMP signals represent the two main alterations leading to the initiation of colorectal cancer (CRC). Here we screen for genes required for maintaining the tumor stem cell phenotype and identify the zinc-finger transcription factor GATA6 as key regulator of the WNT and BMP pathways in CRC. GATA6 directly drives the expression of LGR5 in adenoma stem cells while it restricts BMP signaling to differentiated tumor cells. Genetic deletion of Gata6 in mouse colon adenomas increases the levels of BMP factors, which signal to block self-renewal of tumor stem cells. In human tumors, GATA6 represses BMP4 gene expression through binding to a regulatory region that has been previously linked to increased susceptibility to develop CRC. Thus, GATA6 creates a permissive environment for tumor stem cell expansion by controlling the major signaling pathways that influence CRC initiation. Total RNA from biological replicates of VillinCreERT2Gata6+/+Apcfl/fl and VillinCreERT2Gata6fl/flApcfl/fl colon adenoma tumor organoids grown for one week in control media (see growth protocol).Total RNA was extracted using the TRIzolM-BM-. Plus RNA Purification Kit (Life Technologies).