Macrophage-mediated vascular permeability via VLA4/VCAM1 pathway dictates ascites development in ovarian cancer
Shibo Zhang, … , Changqing Liu, Huanhuan He
Shibo Zhang, … , Changqing Liu, Huanhuan He
Published December 9, 2020
Citation Information: J Clin Invest. 2021;131(3):e140315. https://doi.org/10.1172/JCI140315.
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Research Article Cell biology Vascular biology

Macrophage-mediated vascular permeability via VLA4/VCAM1 pathway dictates ascites development in ovarian cancer

Abstract

The development of ascites correlates with advanced stage disease and poor prognosis in ovarian cancer. Vascular permeability is the key pathophysiological change involved in ascites development. Previously, we provided evidence that perivascular M2-like macrophages protect the vascular barrier through direct contact with endothelial cells (ECs). Here, we investigated the molecular mechanism and its clinical significance in the ovarian cancer setting. We found that upon direct coculture with the endothelium, M2 macrophages tuned down their VLA4 and reduced the levels of VCAM1 in ECs. On the other hand, ectopically overexpressing VLA4 in macrophages or VCAM1 in ECs induced hyperpermeability. Mechanistically, downregulation of VLA4 or VCAM1 led to reduced levels of RAC1 and ROS, which resulted in decreased phosphorylation of PYK2 (p-PYK2) and VE-cadherin (p–VE-cad), hence enhancing cell adhesion. Furthermore, targeting the VLA4/VCAM1 axis augmented vascular integrity and abrogated ascites formation in vivo. Finally, VLA4 expression on the macrophages isolated from ascites dictated permeability ex vivo. Importantly, VLA4 antibody acted synergistically with bevacizumab to further enhance the vascular barrier. Taking these data together, we reveal here that M2 macrophages regulate the vascular barrier though the VCAM1/RAC1/ROS/p-PYK2/p–VE-cad cascade, which provides specific therapeutic targets for the treatment of malignant ascites.

Authors

Shibo Zhang, Bingfan Xie, Lijie Wang, Hua Yang, Haopei Zhang, Yuming Chen, Feng Wang, Changqing Liu, Huanhuan He

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Figure 2

Decreased VLA4 activation in M2 macrophages cocultured with ECs.

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Decreased VLA4 activation in M2 macrophages cocultured with ECs. (A) KEG...
(A) KEGG pathway analysis of DEGs when comparing M2 versus M1 macrophages from cocultures. (B) Gene expression heatmap of differentially expressed integrin genes from A. (C) Expression of VLA4 in THP-1 macrophages detected by Western blot in different cocultures (n = 3). (D) Localization of VLA4 protein (green) in THP-1 macrophages by immunofluorescence analysis. CD68 (red) stains macrophages. DAPI stains cell nucleus. Scale bar: 20 μm. (E) Representative graph of flow cytometric analysis of active VLA4 levels in different subtypes of THP-1 macrophages from cocultures. (F) p–VE-cad expression in HUVECs cultured with macrophages that were transiently transfected with VLA4-specific shRNAs (shVLA4-a, shVLA4-b) or a control shRNA (shCtrl) (n = 3). (G) p–VE-cad expression in HUVECs from M1 macrophage–coculture system treated with CDP323 (n = 3). (H) p–VE-cad expression in HUVECs cocultured with macrophages that were transiently transfected with a VLA4-specific vector (Ove-VLA4) or a control vector (n = 3). (I) p–VE-cad expression in HUVECs from M2 macrophage–coculture system treated with THI0019 (n = 3). (J) Immunofluorescence analysis of p–VE-cad expression in HUVECs cultured with macrophages that were transiently transfected with a VLA4-specific vector (Ove-VLA4) or a control vector. Scale bar: 20 μm. (K) TRITC-dextran tracer fluorescence from coculture systems in which macrophages transiently transfected with a VLA4-specific vector (Ove-VLA4) or pretreated with THI0019, PS/2, and CDP323 are compared with the respective control (n = 5). Data represent 3 independent experiments. Results are shown as mean ± SD. *P < 0.05; **P < 0.01; ***P < 0.001; ****P < 0.0001, Student’s t test (GI and K) and 1-way ANOVA (C and F).