Comparison of organ-specific endothelial cells in terms of microvascular formation and endothelial barrier functions.

Every organ demonstrates specific vascular characteristics and functions maintained by interactions of endothelial cells (ECs) and parenchymal cells. Particularly, brain ECs play a central role in the formation of a functional blood brain barrier (BBB). Organ-specific ECs have their own morphological features, and organ specificity must be considered when investigating interactions between ECs and other cell types constituting a target organ. Here we constructed angiogenesis-based microvascular networks with perivascular cells in a microfluidic device setting by coculturing ECs and mesenchymal stem cells (MSCs). Furthermore, we analyzed endothelial barrier functions as well as fundamental morphology, an essential step to build an in vitro BBB model. In particular, we used both brain microvascular ECs (BMECs) and human umbilical vein ECs (HUVECs) to test if organ specificity of ECs affects the formation processes and endothelial barrier functions of an engineered microvascular network. We found that microvascular formation processes differed by the source of ECs. HUVECs formed more extensive microvascular networks compared to BMECs while no differences were observed between BMECs and HUVECs in terms of both the microvascular diameter and the number of pericytes peripherally associated with the microvasculatures. To compare the endothelial barrier functions of each type of EC, we performed fluorescence dextran perfusion on constructed microvasculatures. The permeability coefficient of BMEC microvasculatures was significantly lower than that of HUVEC microvasculatures. In addition, there were significant differences in terms of tight junction protein expression. These results suggest that the organ source of ECs influences the properties of engineered microvasculature and thus is a factor to be considered in the design of organ-specific cell culture models.

Pathological characterization and morphometric analysis of hepatic lesions in SHRSP5/Dmcr, an experimental non-alcoholic steatohepatitis model, induced by high-fat and high-cholesterol diet.

SHRSP5/Dmcr is a newly established substrain of stroke-prone spontaneously hypertensive rat (SHRSP). Recently, high-fat and high-cholesterol (HFC) diet-fed SHRSP5/Dmcr has been reported as a novel rat model of developing hepatic lesions similar to human non-alcoholic steatohepatitis (NASH). The aim of this study was to investigate the detailed pathological conditions induced by HFC diet in SHRSP5/Dmcr rats using molecular biological methods and morphometric analysis. SHRSP5/Dmcr rats at 6 weeks of age were fed on either HFC diet or stroke-prone (SP) diet for 2, 4, 6, 8 and 16 weeks and histopathological changes in the liver, blood chemistry and mRNA expression levels in the liver were investigated. As evidenced by the histopathological examination of the liver of the SHRSP5/Dmcr rats, hepatic steatosis and lobular inflammation were present, with gradual increasing severity from 2 weeks after the introduction of the HFC diet. Partial hepatic fibrosis was detected at 6 weeks and spread over the entire region of the liver with more severe bridging formation by 16 weeks. The degrees of NASH-like hepatic lesions such as steatosis (the size distribution of lipid droplets), inflammation and fibrosis were quantified by morphometric analysis. Eosinophilic inclusion bodies encountered in the hepatocytes had immunoreactivity with Cox-4 and double-membrane walls, identified as mega-mitochondria. Serum ALT and bilirubins, and the mRNA expression levels related to fibrosis were closely correlated with hepatic histopathological changes. The clear feeding time-dependent progression of NASH-like hepatic lesion in HFC diet-fed SHRSP5/Dmcr rats reinforced the conclusion that this strain might be a useful model of NASH and of inflammatory fibrotic liver disease.

CCL2-induced migration and SOCS3-mediated activation of macrophages are involved in cerulein-induced pancreatitis in mice.

BACKGROUND & AIMS: Acute pancreatitis is a common inflammatory disease mediated by damage to acinar cells and subsequent pancreatic inflammation with recruitment of leukocytes. We investigated the pathologic roles of innate immune cells, especially macrophages, in cerulein- and L-arginine-induced acute pancreatitis in mice. METHODS: Acute pancreatitis was induced by sequential peritoneal administration of cerulein to mice. We determined serum concentrations of amylase and lipase, pancreatic pathology, and features of infiltrating mononuclear cells. We performed parabiosis surgery to assess the hemodynamics of pancreatic macrophages. RESULTS: Almost all types of immune cells, except for CD11b(high)CD11c(-) cells, were detected in the pancreas of healthy mice. However, activated CD11b(high)CD11c(-) cells, including Gr-1(low) macrophages and Gr-1(high) cells (granulocytes and myeloid-derived suppressor cells), were detected in damaged pancreas after cerulein administration. CCL2(-/-) mice given cerulein injections developed significantly less severe pancreatitis, with less infiltration of CD11b(high)CD11c(-)Gr-1(low) macrophages, but comparable infiltration of myeloid-derived suppressor cells, compared with cerulein-injected wild-type mice. Parabiosis and bone marrow analyses of these mice revealed that the CD11b(high)CD11c(-)Gr-1(low) macrophages had moved out of the bone marrow. Furthermore, mice with macrophage-specific deletion of suppressor of cytokine signaling 3 given injections of cerulein developed less severe pancreatitis and Gr-1(low) macrophage produced less tumor necrosis factor-α than wild-type mice given cerulein, although the absolute number of CD11b(high)CD11c(-)Gr-1(low) macrophages was comparable between strains. Induction of acute pancreatitis by L-arginine required induction of macrophage migration by CCL2, via the receptor CCR2. CONCLUSIONS: Cerulein induction of pancreatitis in mice involves migration of CD11b(high)CD11c(-)Gr-1(low) macrophage from the bone marrow (mediated by CCL2 via CCR2) and suppressor of cytokine signaling 3-dependent activation of macrophage. These findings might lead to new therapeutic strategies for acute pancreatitis.

Expression of vascular endothelial growth factor (VEGF) associated with histopathological changes in rodent models of osteoarthritis.

Vascular endothelial growth factor (VEGF) and its receptors have recently reported to be expressed in human osteoarthritis (OA), suggesting that VEGF could be implicated in the pathogenesis of this disease. In the present study, expression of VEGF in the articular cartilage was determined in three different OA models: medial meniscectomy and monoiodoacetate (MIA) injection in rats and age-associated spontaneous joint cartilage destruction in guinea pigs. VEGF was detected by immunohistochemical analysis in the regenerative and hypertrophic chondrocytes, perichondrium and osteophyte areas and chondrocyte clones. Stain intensity of VEGF immunoreactivity increased simultaneously with the degree of cartilage destruction and reparation. These results suggest that VEGF is a key factor in the articular cartilage in human OA and animal OA models.