Background Development of effective treatments for atherosclerosis requires new models that better predict the human immune response. Although T cells are abundant in human atherosclerotic lesions and play a key role in the pathogenesis, the mechanism involved in plaque infiltration remains ill defined. Methods We developed a three-dimensional tissue-culture model to study leukocyte recruitment to human atherosclerotic plaques. In this study, human atherosclerotic plaques obtained during carotid endarterectomy surgery were co-cultured with patient-matching T cells. Exogenous T cells were stained using a multi-factor staining strategy, which involved intracellular fluorescent cell tracker dyes combined with nuclear labels. Flow cytometry was used to assess the presence of the labeled cells within the plaques, and microscopic analysis was performed to examine their localization. Results Flow cytometry and microscopy cell-tracking analysis demonstrated that exogenous T cells successfully migrated into atherosclerotic plaques. Furthermore, infiltrated CD8 + T cells displayed a significant increase of CD69 expression, indicating their activation within the tissue. Blocking chemokine receptors, particularly CXCR4, significantly impaired T cell infiltration, demonstrating that exogenous CD8 + T cells invade plaques through chemotactic migration. Surprisingly, 3D microscopy combined with optical tissue clearing strategy revealed that CXCL12, the sole ligand of CXCR4, mainly accumulated in intraplaque neovessels. Single-cell RNA sequencing (scRNAseq) analysis further confirmed that endothelial cells from intraplaque neovessels were the primary source for CXCL12. Additionally, exogenous T cells were found within and in proximity to these neovessels, suggesting that the CXCL12/CXCR4 axis regulates T cell recruitment through intraplaque neovessels. Conclusions Overall, these findings shed new light on the mechanism of action of CXCL12 in atherosclerosis and demonstrated the potential of the model to advance our understanding of leukocyte accumulation in human atherosclerosis and assist in testing novel pharmacological therapies.

Reactive oxygen species (ROS) derived from NADPH oxidase (NOX) and mitochondria play a critical role in growth factor-induced switch from a quiescent to an angiogenic phenotype in endothelial cells (ECs). However, how highly diffusible ROS produced from different sources can coordinate to stimulate VEGF signaling and drive the angiogenic process remains unknown. Using the cytosol- and mitochondria-targeted redox-sensitive RoGFP biosensors with real-time imaging, here we show that VEGF stimulation in human ECs rapidly increases cytosolic RoGFP oxidation within 1 min, followed by mitochondrial RoGFP oxidation within 5 min, which continues at least for 60 min. Silencing of Nox4 or Nox2 or overexpression of mitochondria-targeted catalase significantly inhibits VEGF-induced tyrosine phosphorylation of VEGF receptor type 2 (VEGFR2-pY), EC migration and proliferation at the similar extent. Exogenous hydrogen peroxide (H2O2) or overexpression of Nox4, which produces H2O2, increases mitochondrial ROS (mtROS), which is prevented by Nox2 siRNA, suggesting that Nox2 senses Nox4-derived H2O2 to promote mtROS production. Mechanistically, H2O2 increases S36 phosphorylation of p66Shc, a key mtROS regulator, which is inhibited by siNox2, but not by siNox4. Moreover, Nox2 or Nox4 knockdown or overexpression of S36 phosphorylation-defective mutant p66Shc(S36A) inhibits VEGF-induced mtROS, VEGFR2-pY, EC migration, and proliferation. In summary, Nox4-derived H2O2 in part activates Nox2 to increase mtROS via pSer36-p66Shc, thereby enhancing VEGFR2 signaling and angiogenesis in ECs. This may represent a novel feed-forward mechanism of ROS-induced ROS release orchestrated by the Nox4/Nox2/pSer36-p66Shc/mtROS axis, which drives sustained activation of angiogenesis signaling program.
Copyright © 2017 the American Physiological Society.

Autophagy is the major intracellular system of degradation, and it plays an essential role in various biological events. Recent observations indicate that autophagy is modulated in response to the energy status of the mitochondrial compartment. However, the exact signaling mechanism that controls autophagy under these conditions remains unclear. In this study, we report that the activation of protein kinase C β (PRKCB), a member of the classical PRKCs, negatively modulates the mitochondrial energy status and inhibits autophagy. Furthermore, cells treated with a pharmacological PRKCB inhibitor, and prkcb knockout MEFs showed an increase in autophagy both in vitro and in vivo, as well as an increased mitochondrial membrane potential (Ψm), suggesting a strong involvement of mitochondrial energy in the modulation of the autophagy machinery. Finally, we show that factors that increase the Ψm oppose the PRKCB-dependent inhibition of autophagy. Altogether, these data underscore the importance of PRKCB in the regulation of autophagy; moreover, the finding that a pharmacological modulation of the Ψm modifies autophagy levels may be useful in fighting pathologies (including various types of cancer and neurodegenerative disorders) that are characterized by reduced levels of autophagy.