| Literature DB >> 32486344 |
Chisa Shimada1,2, Rui Xu1,2, Linah Al-Alem1,2, Marina Stasenko3, David R Spriggs1,4, Bo R Rueda1,2,5.
Abstract
Ovarian cancer is known for its aggressive pathological features, including the capacity to undergo epithelial to mesenchymal transition,Entities:
Keywords: chemoresistance; galectins; immune suppression; invasion; metastasis; ovarian cancer
Year: 2020 PMID: 32486344 PMCID: PMC7352943 DOI: 10.3390/cancers12061421
Source DB: PubMed Journal: Cancers (Basel) ISSN: 2072-6694 Impact factor: 6.639
Figure 1A schematic showing the different galectin structures and members of each (A). Galectins have been shown to play a role in altering many functions in cancer, including angiogenesis, apoptosis, tumor growth, immune escape, immune cell adhesion, cell transformation and metastasis/invasion (B).
Figure 2Oncogenic H-Ras plays a major role in tumor transformation via two major pathways, PI3K/AKT and MEK/ERK [73,74]. H-Ras recruits intracellular Gal-1 from the cytosol. This interaction enhances H-Ras-mediated cell transformation. Since Gal-1 has no effect on the membrane localization of inactive H-Ras, Ras activation, via GTP binding is needed for the H-Ras/Gal-1 interaction. Gal-1 is then able to enhance H-Ras-GTP, leading to an increase in Raf-1 recruitment, which culminates in a sustained activation of the MEK-ERK pathway and enhanced cell transformation [63].
Expression, localization, cellular distribution, proposed function, and biomarker relevance for galectins in ovarian cancer.
| Galectin | Histological Subtypes | Distribution | Cellular | Function in | Prognosis |
|---|---|---|---|---|---|
| Gal-1 | Serous | Tumor cell | Nucleus, Cytoplasm [ | Mediate EMT, cell proliferation, migration, invasion, and cell signaling | Higher levels of Gal-1 in the peritumoral stroma associated with poor PFS [ |
| Gal-3 | Serous | Cancer cell | Cytoplasm | Contributing to stem-like properties [ | High Gal-3 cytoplasmic expression correlated with poor PFS [ |
| Gal-7 | Serous | Epithelial cell [ | Nucleus, Cytoplasm [ | Down-regulation of Gal-7 expression inhibited tumor cell proliferation [ | Higher levels had a more inferior OS [ |
| Gal-8 | Serous | Tumor cell [ | Nucleus [ | None found | High expression in epithelial component correlated with chemoresistance |
| Gal-9 | Serous | Cancer | Cytoplasm | Inhibiting cell proliferation and pushing cells towards apoptosis [ | High expression presented more often with low tumor stage, lower grading, and younger age [ |
Figure 3Gal-3 is involved in cell adhesion regulation, migration, invasion, angiogenesis, and metastasis. The specific extracellular Gal-3 function depends on the polymerization of Gal-3 into pentameric complexes. The action of Galectin 3 depends on glycan binding partners. These complexes link to glycans of high complexity (e.g., N-glycosylation lactosamine tetra-antennary forms and the Thomsen–Fredenreich antigen on O-glycans, especially in cancer. Through carbohydrate binding and polymerization to pentamers, Gal-3 forms a lattice and regulates the position of growth factor receptors, including EGFR, integrins and proteins like MUC16.
Figure 4Galectin-3 as an inhibitor of the apoptotic response. Gal-3 can translocate from the cytosol and/or the nucleus to the mitochondria, inhibiting stressors of the mitochondrial membrane potential and subsequent release of Cyt C. In response to apoptotic stimuli, Gal-3 can translocate to the mitochondria and interact with Bax and prevent its function, as well as other pro-apoptotic Bcl-2 family members, subsequently preventing the formation of pro-death promoting homodimers.