The discovery of the carcinoembryonic antigen (CEA) as a tumor marker for colorectal cancer some 50 years ago became the first step in the identification of a much larger family of 12 carcinoembryonic antigen-related cell adhesion molecules (CEACAMs) with surprisingly diverse functions in cell adhesion, in intracellular and intercellular signaling, and during complex biological processes such as cancer progression, inflammation, angiogenesis, and metastasis. The development of proper molecular and biochemical tools and mouse models has enabled bidirectional translation of the CEACAM network biology. Indeed, CEACAM1, CEACAM5, and CEACAM6 are now considered valid clinical biomarkers and promising therapeutic targets in melanoma, lung, colorectal, and pancreatic cancers. These fascinating proteins illustrate how a better understanding of the CEACAM family of cell adhesion molecules reveals their functional link to the underlying disease and lead to new monitoring and targeting opportunities.
The crosstalk between inflammation and tumorigenesis is now clearly established. However, how inflammation is elicited in the metastatic environment and the corresponding contribution of innate immunity pathways in suppressing tumor growth at secondary sites are poorly understood. Here, we show that mice deficient in Nlrp3 inflammasome components had exacerbated liver colorectal cancer metastatic growth, which was mediated by impaired interleukin-18 (IL-18) signaling. Control of tumor growth was independent of differential cancer cell colonization or proliferation, intestinal microbiota effects, or tumoricidal activity by the adaptive immune system. Instead, the inflammasome-IL-18 pathway impacted maturation of hepatic NK cells, surface expression of the death ligand FasL, and capacity to kill FasL-sensitive tumors. Our results define a regulatory signaling circuit within the innate immune system linking inflammasome activation to effective NK-cell-mediated tumor attack required to suppress colorectal cancer growth in the liver.
Homozygous mice overexpressing Claudin-6 (Cldn6) exhibit a perturbation in the epidermal differentiation program leading to a defective epidermal permeability barrier (EPB) and dehydration induced death ensuing within 48 h of birth [Turksen, K., Troy, T.C., 2002. Permeability barrier dysfunction in transgenic mice overexpressing claudin 6. Development 129, 1775-1784]. Their heterozygous counterparts are also born with an incomplete EPB; however, barrier formation continues after birth and normal hydration levels are achieved by postnatal day 12 allowing survival into adulthood. Heterozygous Inv-Cldn6 mice exhibit a distinct coat phenotype and histological analysis shows mild epidermal hyperkeratosis. Expression of K5 and K14 is aberrant, extending beyond the basal layer into the suprabasal layer where they are not co-localized suggesting that their expression is uncoupled. There is also atypical K17 and patchy K15 expression in the basal layer with no K6 expression in the interfollicular epidermis; together with marked changes in late differentiation markers (e.g. profilaggrin/filaggrin, loricrin, transglutaminase 3) indicating that the normal epidermal differentiation program is modified. The expression compartment of various Cldns is also perturbed although overall protein levels remained comparable. Most notably induction of Cldn5 and Cldn8 was observed in the Inv-Cldn6 epidermis. Heterozygous Inv-Cldn6 animals also exhibit subtle alterations in the differentiation program of the hair follicle including a shorter anagen phase, and altered hair type distribution and length compared to the wild type; the approximately 20% increase in zig-zag hair fibers at the expense of guard hairs and the approximately 30% shorter guard hairs contribute to coat abnormalities in the heterozygous mice. In addition, the transgenic hair follicles exhibit a decreased expression of K15 as well as some hair-specific keratins and express Cldn5 and Cldn18, which are not detectable in the wild type. These data indicate that Cldn6 plays a role in the differentiation processes of the epidermis and hair follicle and supports the notion of a link between Cldn regulation and EPB assembly/maintenance as well as the hair cycle.
It is widely recognized that the claudin (Cldn) family of four tetraspan transmembrane proteins is crucial for tight junction assembly and permeability barrier function; however, the precise role of the tail and loop domains in Cldn function is not understood. We hypothesized that the cytoplasmic tail domain of Cldn6 is crucial for membrane targeting and hence epidermal permeability barrier (EPB) formation. To test this hypothesis via a structure-function approach, we generated a tail deletion of Cldn6 (C⌬187) and evaluated its role in epidermal differentiation and EPB formation through its forced expression via the involucrin (Inv) promoter in the suprabasal compartment of the transgenic mouse epidermis. Even though a functional barrier formed, Inv-C⌬187 mice displayed histological and biochemical abnormalities in the epidermal differentiation program and stimulation of epidermal cell proliferation in both the basal and suprabasal compartments of the interfolliclar epidermis, leading to a thickening of the epidermis after 1 week of age that persisted throughout life. Although some membrane localization was evident, our studies also revealed a significant amount of not only Cldn6 but also Cldn10, Cldn11, and Cldn18 in the cytoplasm of transgenic epidermal cells as well as the activation of a protein-unfolding pathway. These findings demonstrate that the overexpression of a tail truncation mutant of Cldn6 mislocalizes Cldn6 and other Cldn proteins to the cytoplasm and triggers a postnatal increase in proliferation and aberrant differentiation of the epidermis, emphasizing the importance of the Cldn tail domain in membrane targeting and function in vivo.Claudins (Cldns) comprise a family of integral membrane proteins involved in the formation of tight junction (TJ) fibrils, which are responsible for the formation and maintenance of the epidermal permeability barrier (EPB) (36,38,40,42). Recent studies indicate that Cldn6 overexpression (34, 40) and Cldn1 deletion mutants (15) are associated with EPB defects in vivo and that the level of Cldn expression appears to be crucial for EPB integrity and function (34,38,40). Knowledge of the overall structure-function of the Cldn family of proteins is limited; however, they are known to have three distinct and characteristic functional domains: (i) four transmembranespanning regions, (ii) two extracellular loops responsible for permeability barrier formation within the paracellular space and specific ion selectivity residing within the first external loop (8,43,44), and (iii) a cytoplasmic C terminus that functions to anchor to the cytoskeleton, apparently through scaffolding molecules such as zonula occludens 1 (ZO-1) (12,22,36,38,42,43). It has been demonstrated that PDZ-binding sequences at the C terminus of the Cldn cytoplasmic tail are responsible for their association with other PDZ domain proteins (16,19,22). However, although predicted to be important, the role of the tail domain in the targeting of Cldn proteins to the membrane as well as the regulation of their f...
Background: Despite the fact that morphological and physiological observations suggest that the tight junction (TJ)-based permeability barrier is modified/disrupted in tumorigenesis, the role of members of the Claudin (Cldn) family of TJ proteins is not well-understood. Using a well-established two-stage chemical carcinogenesis model, we investigated the temporal and spatial changes in expression of those Cldns that we have previously demonstrated to be important in epidermal differentiation and the formation of the epidermal permeability barrier, i.e., Cldn1, Cldn6, Cldn11, Cldn12 and Cldn18.
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