Frameshift mutations of immunomodulatory BTN2A1, BTN2A2, and BTNL3 genes in colon cancers.

The butyrophilin family genes are immunoregulatory genes with either immune stimulatory or inhibitory functions. In the present study, we analyzed three butyrophilin genes, BTN2A1 (immune-stimulatory), BTN2A2 (inhibitory), and BTNL3 (stimulatory) genes in sporadic colon cancers (CCs). By the mutation analysis, we identified the frameshift mutations of BTN2A1, BTN2A2, and BTNL3 genes in 2, 4, and 8 CCs in microsatellite instability-high (MSI-H) CCs (2.1-8.4% of MSI-H), respectively, but not the microsatellite stable (MSS) CCs. Four of 16 MSI-H CCs (25%) exhibited regional heterogeneous mutations (RHM) of BTN2A1, BTN2A2, and BTNL3 genes. In immunohistochemistry, BTNL3 expression was lost in approximately 30% of CCs, and BTN2A2 loss was minimal in CCs (around 3%) irrespective of the MSI status. Our study revered that butyrophilin family genes BTN2A1, BTN2A2, and BTNL3 harbored multiple levels of gene alterations at frameshift mutations, RHMs, and expression losses in CCs, suggesting that butyrophilin family genes could contribute to CC pathogenesis by altering immune responses.

Genes with dual proto-oncogene and tumor suppressor gene activities are frequently altered by protein losses in colon cancers.

Cancer genes are largely categorized into tumor suppressor gene (TSG) and proto-oncogene, but many have dual activities depending on the cellular context. In the present study, we analyzed DYRK1B, ESRP1, MTSS1, ADAMTS1, and INPP5F genes known to possess the dual activities in sporadic colon cancers (CCs). By the mutation analysis, we identified DYRK1B, ESRP1, MTSS1, ADAMTS1, and INPP5F frameshift mutations in 2, 2, 3, 3, and 1 CCs in instability-high (MSI-H) cases (1.1-3.2% of MSI-H CCs), respectively, but not microsatellite stable (MSS) cases. One CC showed regional heterogeneous mutations (RHM) of ESRP1 mutation. Immunohistochemistry identified protein expression of ESRP1, MTSS1, and ADAMTS1 in the CCs, revealing that approximately 30% of CCs lost the protein expression irrespective of the MSI status. Our study showed that dual TSG and proto-oncogene genes DYRK1B, ESRP1, MTSS1, ADAMTS1, and INPP5F harbored low incidences of inactivating mutations, but that the protein losses were frequent in CCs. Our study suggests a possibility that the dual-function genes could be altered mainly at the expression level, which might contribute to CC pathogenesis.

Concurrent inactivating mutations and expression losses of RGS2, HNF1A, and CAPN12 candidate tumor suppressor genes in colon cancers.

Microsatellite instability-high (MSI-H) colorectal cancer (CRC) is different from microsatellite stable (MSS) CRC concerning biological, and clinical features. In MSI-H CRCs, defects of mismatch repair genes produce increased mutation accumulation in repetitive DNA sequences. To see whether candidate tumor suppressor genes (TSGs) are altered in MSI-H CRC, we studied frameshift mutation and protein expression of candidate TSGs of RGS2, HNF1A, HNF1B, CAPN12, RCBTB2, ATE1, PKNOX1, and USP19. We found frameshift mutations of RGS2 in 5 (5%), HNF1A in 6 (6%), HNF1B in 2 (2%), CAPN12 in 3 (3%), RCBTB2 in 4 (4%), ATE1 in 2 (2%), PKNOX1 in 2 (2%), and USP19 in 2 (2%) MSI-H CRCs. However, we found no such mutations in MSS CRCs. RCBTB2, CAPN12, HNF1A, and HNF1B frameshift mutations revealed the regional difference in the same tumors. In addition, we identified loss of RGS2, HNF1A, and CAPN12 protein expression irrespective of MSI phenotype in 13-29% of CRCs. The results indicate that many TSGs harbor concurrent inactivating mutations and protein loss in MSI-H CRCs with intratumoral mutational heterogeneity, and that MSS CRCs are altered by protein losses. These alterations could contribute to CRC development and underlying mechanisms and consequences of the TSG alterations remain to be clarified.