| Literature DB >> 34209658 |
Taylor C Brown1,2, Narendra V Sankpal1, William E Gillanders1,2.
Abstract
Epithelial cell adhesion molecule (Entities:
Keywords: cancer stem cells (CSCs); circulating tumor cells (CTCs); epithelial cancers; epithelial cell adhesion molecule (EpCAM); epithelial-to-mesenchymal transition (EMT); metastasis
Year: 2021 PMID: 34209658 PMCID: PMC8301972 DOI: 10.3390/biom11070956
Source DB: PubMed Journal: Biomolecules ISSN: 2218-273X
Figure 1EpCAM has six domains. The protein consists of 314 amino acids. The signal peptide (SP) is typically cleaved, but is shown here. This is followed by the N-terminal domain (ND), the type-1 thyroglobulin domain (TY-1), and the carboxyl-terminal domain (CD). EpCAM has a single pass transmembrane domain (TM) and an intracellular domain (EpICD).
Figure 2The regulation of EpCAM during EMT occurs through a double-negative feedback loop. In epithelial cells (left panel), EpCAM forms homophilic adhesions and promotes epithelial homeostasis. EpCAM can also inhibit ERK signaling (a potent mediator of EMT) and its gene targets, including SNAI2, EGR1, FOS, JUN, ATF3, and others. In mesenchymal cells (right panel), ERK pathway signaling silences EpCAM expression. ERK2 binds the EpCAM promoter at an ERK2-binding consensus sequence and directly inhibits EpCAM gene expression. ERK2 also induces EMT transcription factors, including SNAI2, that in turn also inhibit EpCAM transcription.
Figure 3Regulated intramembrane proteolysis of EpCAM modulates EMT. EpEX and EGF simulate RIP, which is mediated by TACE and PSEN2 enzymatic cleavage. This occurs, in part, through ERK signaling. Upon EpCAM cleavage, EpICD is transported into the nucleus. EpICD binds FHL2, LEF1, and β-catenin to form a nuclear DNA binding complex that promotes transcription of target genes and in turn causes tumor growth and EMT. EpCAM has also been shown to be a negative regulator of E-cadherin. This may free β-catenin for downstream signaling with EpICD.
EpCAM is associated with migration and invasion modulation via various signaling pathways and mechanisms.
| Cell Type & Cell Line | Associated Signaling Pathway/Mechanism | Promotes/Inhibits | Reference |
|---|---|---|---|
| Head and Neck Squamous Cell Carcinoma: FaDu and Kyse-30 | EpEX & EGFR | Inhibits | [ |
| Nasopharyngea S Carcinoma: S18, 6-10B, and HONE1 | PTEN/AKT/mTOR | Promotes | [ |
| Esophageal Squmous Cell Carinoma: Kyse-30 and Kyse-520 | EMT | Inhibits | [ |
| Lung Cancer: A549 and NCI-H446 | MTA1 | Promotes | [ |
| Benign Breast: MCF-10A and Human Mammary Epithelial Cells | ERK & EMT | Inhibits | [ |
| Breast Cancer: MDA-MB-231 | E-Cadherin & α,β-catenin | Promotes | [ |
| Breast Cancer: MDA-231 and CA1a | AP-1 | Promotes | [ |
| Breast Cancer: MCF-7 | TGF-β1 | Promotes | [ |
| Breast Cancer: MDA-MB-231 | NF-κβ | Promotes | [ |
| Breast Cancer: MCF-7, T47D, SkBR3, MDA-MB-231, and Hs578t | EMT | Both | [ |
| Kideny: MDCK | ERK, Claudin-7, & actomyosin contractility | Inhibits | [ |
| Colon: HCT116 | EpEX & EpICD | Promotes | [ |
| Endometrial: Ishikawa and RL95-2 | Adhesion formation & EpICD | Both | [ |
| Ovarian: SKOV3 & OVCAR4 | ERK | Inhibits | [ |
| Prostate: KrasG12D & p53L/L mouse knockout prostate cancer model | KRAS & p53 | Promotes | [ |
| Langerhans cells: Knockout mice model | Decrease adhesiveness | Promotes | [ |
| Embryonic and Colon: Xenopus laevis and Caco-2 and SW480 | nPKC and myosin regulation | Promotes | [ |