Vascular lipid droplets formed in response to TNF, hypoxia, or OA: biochemical composition and prostacyclin generation.

Biogenesis of lipid droplets (LDs) in various cells plays an important role in various physiological and pathological processes. However, the function of LDs in endothelial physiology and pathology is not well understood. In the present work, we investigated the formation of LDs and prostacyclin (PGI2) generation in the vascular tissue of isolated murine aortas following activation by proinflammatory factors: tumor necrosis factor (TNF), lipopolysaccharides (LPS), angiotensin II (AngII), hypoxic conditions, or oleic acid (OA). The abundance, size, and biochemical composition of LDs were characterized based on Raman spectroscopy and fluorescence imaging. We found that blockade of lipolysis by the adipose triglyceride lipase (ATGL) delayed LDs degradation and simultaneously blunted PGI2 generation in aorta treated with all tested proinflammatory stimuli. Furthermore, the analysis of Raman spectra of LDs in the isolated vessels stimulated by TNF, LPS, AngII, or hypoxia uncovered that these LDs were all rich in highly unsaturated lipids and had a negligible content of phospholipids and cholesterols. Additionally, by comparing the Raman signature of endothelial LDs under hypoxic or OA-overload conditions in the presence or absence of ATGL inhibitor, atglistatin (Atgl), we show that Atgl does not affect the biochemical composition of LDs. Altogether, independent of whether LDs were induced by pro-inflammatory stimuli, hypoxia, or OA and of whether they were composed of highly unsaturated or less unsaturated lipids, we observed LDs formation invariably associated with ATGL-dependent PGI2 generation. In conclusion, vascular LDs formation and ATGL-dependent PGI2 generation represent a universal response to vascular proinflammatory insult.

Heterogeneity of chemical composition of lipid droplets in endothelial inflammation and apoptosis.

Lipid droplets (LDs) play regulatory role in various cells but their significance in endothelial pathophysiology is still not well understood. Here, we studied LDs in in situ endothelial cells (ECs) in isolated blood vessels stimulated with pro-inflammatory or pro-apoptotic stimuli using Raman and fluorescence imaging. Endothelial inflammation induced by murine TNF-α (mTNF-α) was featured by overexpression of ICAM-1, vWF, increased production of PGI2, and was associated with the formation of low number of LDs. However in the presence of atglistatin, the inhibitor of triacyclglycerols hydrolysis, the number of LDs significantly increased. In contrast, in endothelium stimulated by human TNF-α (hTNF-α) or FasL, apart from endothelial inflammation, displayed also apoptosis as evidenced by high annexin expression and significant LDs formation. Raman imaging confirmed that LDs were localized in endothelium and revealed significant heterogeneity in biochemical composition of endothelial LDs that dependent on endothelial stimuli. Repertoire of LDs included LDs rich in highly unsaturated lipids, assigned to the inflammation, as well as LDs featured by more saturated lipids linked to apoptosis, where Raman signals indicating content of cholesterol and phospholipids were higher for endothelial apoptosis in comparison to endothelial inflammation. The heterogeneity in chemical composition of LDs suggested more complex pathophysiological role of endothelial LDs then previously appreciated.

3D Raman imaging of systemic endothelial dysfunction in the murine model of metastatic breast cancer.

It was recently reported in the murine model of metastatic breast cancer (4T1) that tumor progression and development of metastasis is associated with systemic endothelial dysfunction characterized by impaired nitric oxide (NO) production. Using Raman 3D confocal imaging with the analysis of the individual layers of the vascular wall combined with AFM endothelial surface imaging, we demonstrated that metastasis-induced systemic endothelial dysfunction resulted in distinct chemical changes in the endothelium of the aorta. These changes, manifested as a significant increase in the protein content (18%) and a slight decrease in the lipid content (4%), were limited to the endothelium and did not occur in the deeper layers of the vascular wall. The altered lipid to protein ratio in the endothelium, although more pronounced in the fixed vascular wall, was also observed in the freshly isolated unfixed vascular wall samples in the aqueous environment (12 and 7% change of protein and lipid content, respectively). Our results support the finding that the metastasis induces systemic endothelial dysfunction that may contribute to cancer progression.