Tyk2 is a tumor suppressor in colorectal cancer.

Janus kinase Tyk2 is implicated in cancer immune surveillance, but its role in solid tumors is not well defined. We used Tyk2 knockout mice (Tyk2Δ/Δ) and mice with conditional deletion of Tyk2 in hematopoietic (Tyk2ΔHem) or intestinal epithelial cells (Tyk2ΔIEC) to assess their cell type-specific functions in chemically induced colorectal cancer. All Tyk2-deficient mouse models showed a higher tumor burden after AOM-DSS treatment compared to their corresponding wild-type controls (Tyk2+/+ and Tyk2fl/fl), demonstrating tumor-suppressive functions of Tyk2 in immune cells and epithelial cancer cells. However, specific deletion of Tyk2 in hematopoietic cells or in intestinal epithelial cells was insufficient to accelerate tumor progression, while deletion in both compartments promoted carcinoma formation. RNA-seq and proteomics revealed that tumors of Tyk2Δ/Δ and Tyk2ΔIEC mice were immunoedited in different ways with downregulated and upregulated IFNγ signatures, respectively. Accordingly, the IFNγ-regulated immune checkpoint Ido1 was downregulated in Tyk2Δ/Δ and upregulated in Tyk2ΔIEC tumors, although both showed reduced CD8+ T cell infiltration. These data suggest that Tyk2Δ/Δ tumors are Ido1-independent and poorly immunoedited while Tyk2ΔIEC tumors require Ido1 for immune evasion. Our study shows that Tyk2 prevents Ido1 expression in CRC cells and promotes CRC immune surveillance in the tumor stroma. Both of these Tyk2-dependent mechanisms must work together to prevent CRC progression.

IDO1+ Paneth cells promote immune escape of colorectal cancer.

Tumors have evolved mechanisms to escape anti-tumor immunosurveillance. They limit humoral and cellular immune activities in the stroma and render tumors resistant to immunotherapy. Sensitizing tumor cells to immune attack is an important strategy to revert immunosuppression. However, the underlying mechanisms of immune escape are still poorly understood. Here we discover Indoleamine-2,3-dioxygenase-1 (IDO1)+ Paneth cells in the stem cell niche of intestinal crypts and tumors, which promoted immune escape of colorectal cancer (CRC). Ido1 expression in Paneth cells was strictly Stat1 dependent. Loss of IDO1+ Paneth cells in murine intestinal adenomas with tumor cell-specific Stat1 deletion had profound effects on the intratumoral immune cell composition. Patient samples and TCGA expression data suggested corresponding cells in human colorectal tumors. Thus, our data uncovered an immune escape mechanism of CRC and identify IDO1+ Paneth cells as a target for immunotherapy.

Dynamics of CRISPR/Cas9-mediated genomic editing of the AXL locus in hepatocellular carcinoma cells.

Genomic editing using the CRISPR/Cas9 technology allows selective interference with gene expression. With this method, a multitude of haploid and diploid cells from different organisms have been employed to successfully generate knockouts of genes coding for proteins or small RNAs. Yet, cancer cells exhibiting an aberrant ploidy are considered to be less accessible to CRISPR/Cas9-mediated genomic editing, as amplifications of the targeted gene locus could hamper its effectiveness. Here we examined the suitability of CRISPR/Cas9 to knockout the receptor tyrosine kinase Axl in the human hepatoma cell lines HLF and SNU449. The genomic editing events were validated in two single cell clones each from putative HLF and SNU449 knockout cells (HLF-Axl--1, HLF-Axl--2, SNU449-Axl--1, SNU449-Axl--2). Sequence analysis of respective AXL loci revealed one to six editing events in each individual Axl- clone. The majority of insertions and deletions in the AXL gene at exon 7/8 resulted in a frameshift and thus a premature stop in the coding region. However, one genomic editing event led to an insertion of two amino acids resulting in an altered protein sequence rather than in a frameshift in the AXL locus of the SNU449-Axl--1 cells. Notably, while no Axl protein expression could be detected by immunoblotting in all four cell clones, both expression of total Axl as well as release of soluble Axl into the supernatant was observed by ELISA in incompletely edited SNU449-Axl--1 cells. Importantly, a comparative genomic hybridization array revealed comparable genomic changes in Axl knockout cells as well as in cells expressing Cas9 nickase without guide RNAs in SNU449 and HLF cells, indicating vast alterations in genomic DNA triggered by nickase. Together, these data show that the dynamics of CRISPR/Cas9 may cause incomplete editing events in cancer cell lines, as gene copy numbers vary based on genomic heterogeneity.

STAT1 is a sex-specific tumor suppressor in colitis-associated colorectal cancer.

The interferon-inducible transcription factor STAT1 is a tumor suppressor in various malignancies. We investigated sex-specific STAT1 functions in colitis and colitis-associated colorectal cancer (CRC) using mice with specific STAT1 deletion in intestinal epithelial cells (STAT1∆IEC ). Male but not female STAT1∆IEC mice were more resistant to DSS-induced colitis than sex-matched STAT1flox/flox controls and displayed reduced intraepithelial infiltration of CD8+ TCRαß+ granzyme B+ T cells. Moreover, DSS treatment failed to induce expression of T-cell-attracting chemokines in intestinal epithelial cells of male but not of female STAT1∆IEC mice. Application of the AOM-DSS protocol for induction of colitis-associated CRC resulted in increased intestinal tumor load in male but not in female STAT1∆IEC mice. A sex-specific stratification of human CRC patients corroborated the data obtained in mice and revealed that reduced tumor cell-intrinsic nuclear STAT1 protein expression is a poor prognostic factor in men but not in women. These data demonstrate that epithelial STAT1 is a male-specific tumor suppressor in CRC of mice and humans.