AQP4 Aggregation State Is a Determinant for Glioma Cell Fate.
Laura SimoneFrancesco PisaniMaria G MolaManuela De BellisGiuseppe MerlaLucia MicaleAntonio FrigeriAngelo L VescoviMaria SveltoGrazia Paola NicchiaPublished in: Cancer research (2019)
The glial water channel protein aquaporin-4 (AQP4) forms heterotetramers in the plasma membrane made of the M23-AQP4 and M1-AQP4 isoforms. The isoform ratio controls AQP4 aggregation into supramolecular structures called orthogonal arrays of particles (AQP4-OAP). The role of AQP4 aggregation into OAP in malignant gliomas is still unclear. In this study, we demonstrate that AQP4 aggregation/disaggregation into OAP influences the biology of glioma cells. Selective expression of the OAP-forming isoform M23-AQP4 (AQP4-OAP) triggered cell shape changes in glioma cells associated with alterations to the F-actin cytoskeleton that affected apoptosis. By contrast, expression of M1-AQP4 (AQP4-tetramers), which is unable to aggregate into OAP, ameliorated glioma cell invasiveness, improved cell migration, and increased methalloproteinase-9 activity. Two prolines (254 and 296) at the C-terminus tail were shown to be important in mediating the relationship between the actin cytoskeleton and AQP4-OAP and AQP4-tetramers. In conclusion, this study demonstrates that AQP4 aggregation state might be an important determinant in orienting glioma cells to persist or perish. AQP4 disaggregation may potentiate invasiveness potential, whereas AQP4 aggregation may activate the apoptotic path. This study shows a new perspective on the role of AQP4 in brain tumors not necessarily associated with edema formation but with AQP4 aggregation/disaggregation dynamics and their link with the actin cytoskeleton. SIGNIFICANCE: This study demonstrates how AQP4 aggregation influences plasma membrane dynamics to alter cell proliferation, invasiveness, migration, and apoptotic potential in glioma cells.
Keyphrases
- cell proliferation
- cell migration
- cell death
- computed tomography
- poor prognosis
- risk assessment
- stem cells
- magnetic resonance imaging
- single cell
- high resolution
- spinal cord
- climate change
- spinal cord injury
- bone marrow
- endoplasmic reticulum stress
- binding protein
- human health
- signaling pathway
- pi k akt
- contrast enhanced