Vascular Diseases and Gangliosides
Abstract
:1. Introduction
2. Gangliosides in Vascular and Vascular Associated-Cells (Table.1)
2.1. ECs and Gangliosides
2.2. VSMCs and Gangliosides
2.3. Fibroblasts and Gangliosides
2.4. Inflammatory Cells and Gangliosides
2.5. Other Types of Cells and Gangliosides
3. Relevance to Aging
Author Contributions
Funding
Conflicts of Interest
References
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Cell Type | Sources | Types of Gangliosides | Functional Roles | References |
---|---|---|---|---|
GM 7373 cells (ECs) | Bovine | GM1 | Coreceptor of bFGF | [26] |
BAECs | Bovine | GM2, GM1 | Inhibition of proliferation | [27] |
GM3 | Promotion of proliferation | [27] | ||
HUVECs | Human | GD1a | Enhancement of VEGF-induced signaling, proliferation and migration | [28] |
GM3 | Inhibition of VEGF signaling, angiogenesis and adhesion molecules | [29,30] | ||
HAECs | Human | GM1 | Association with aging and Inhibition of insulin signaling | [31,32] |
VSMCs | Human | GD3 | Modulation of proliferation and apoptosis | [33] |
VSMCs | Mouse | GD3 | Inhibition of PDGF-induced ERK pathway and proliferation | [34] |
GD3 | Inhibition of TNFα-induced MMP9 expression | [34] | ||
VSMCs | Rat | GM2, GM1 | Activation of ERK pathway and promotion of proliferation | [35] |
Fibroblasts (dermal) | Human | GM3, GD1a | Promotion of EGF or bFGF stimulated proliferation | [36,37] |
GD3 | Activation of autophagic process | [38] | ||
Fibroblasts (embryonic) | Mouse | GM3 | Attenuation of FBS stimulated MAPK pathway | [39] |
Fibroblasts (heart) | Rat | GM1 | Protection from apoptosis caused from protein kinase C inhibition | [40] |
Neutrophils | Human | GM1 | Association with maturation | [41,42] |
GM1 | Decrease at early stage of apoptosis | [43] | ||
HMC-1 (mast cell line) | Human | GM3, GM2, GM1, GD1a | Association with maturation | [44] |
Mast cells | Mouse | GM3 | Inhibition of IL-3 stimulated proliferation | [45] |
RBL-2H3 (mast cell line) | Rat | GD1b | Activation and induction of inflammatory cytokines | [46] |
HL-60, U937 (monocyte) | Human | GM3 | Induction of cell differentiation | [47] |
Raw264.7 (macrophage) | Mouse | GM1 | Induction of arginase-1 and MCP-1 | [48] |
T cells | Human | GM3, GM1 | Association with activation | [49] |
CD8+ T cells | Human | GM1 | Increase with IL-2 stimulation | [50] |
CD4+ T cells | Human | GM3, GM1 | Downregulation of CD4 expression | [51] |
Platelets | Human | GD3 | Association with activation | [52,53] |
GM3, GM1 | Induction of activation with Ca2+ mobilization and shape change | [54] | ||
GD2 | Induction of apoptosis | [55] | ||
3T3-L1 (adipocyte) | Mouse | GM3 | Inhibition of insulin signaling | [56] |
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Sasaki, N.; Toyoda, M. Vascular Diseases and Gangliosides. Int. J. Mol. Sci. 2019, 20, 6362. https://doi.org/10.3390/ijms20246362
Sasaki N, Toyoda M. Vascular Diseases and Gangliosides. International Journal of Molecular Sciences. 2019; 20(24):6362. https://doi.org/10.3390/ijms20246362
Chicago/Turabian StyleSasaki, Norihiko, and Masashi Toyoda. 2019. "Vascular Diseases and Gangliosides" International Journal of Molecular Sciences 20, no. 24: 6362. https://doi.org/10.3390/ijms20246362
APA StyleSasaki, N., & Toyoda, M. (2019). Vascular Diseases and Gangliosides. International Journal of Molecular Sciences, 20(24), 6362. https://doi.org/10.3390/ijms20246362