Objective The observe the effects of interferon-inducible protein-10 (IP-10) on proliferation, migration and capillary tube formation of human retinal vascular endothelial cells (HREC) and human umbilical vein endothelial cells (HUVEC). Methods The chemokine receptor (CXCR3) mRNA of HREC and HUVEC were quantified by reverse transcriptase polymerase chain reaction (RT-PCR). In the presence of the different concentrations of IP-10, the difference in proliferation capacity of HREC and HUVEC were analyzed by cell counting kit-8 (CCK-8) methods. Wound scratch assay and threedimensional in vitro matrigel assay were used for measuring migration and capillary tube formation of HREC and HUVEC, respectively. Results RT-PCR revealed both HREC and HUVEC expressed CXCR3. The proliferation of HREC in the presence of IP-10 was inhibited in a dosagedependent manner (F=6.202,P<0.05), while IP-10 showed no effect on the inhibitory rate of proliferation of HUVEC (F=1.183,P>0.05). Wound scratch assay showed a significant reduction in the migrated distance of HREC and HUVEC under 10 ng/ml or 100 ng/ml IP-10 stimulation (F=25.373, 23.858; P<0.05). There was no effect on the number of intact tubules formed by HREC in the presence of 10 ng/ml or 100 ng/ml IP-10. The number of intact tubules formed by HREC in the presence of 1000 ng/ml IP-10 was remarkably smaller. The difference of number of intact tubules formed by HREC among 10, 100, 1000 ng/ml IP-10 and nonintervention group was statistically significant (F=5.359,P<0.05). Conclusion IP-10 can inhibit the proliferation, migration and capillary tube formation ability of HREC and the migration of HUVEC.
Objective To investigate the effects of heparanase and vascular endothelial growth factor (VEGF) and their correlation in CoCl2 induced human retinal microvascular endothelial cells (HRECs) in an hypoxia model. Methods Human eyes were selected to establish CoCl2induced HRECs hypoxia model in this study. Four experimental groups were studied: normal control group, hypoxia group (CoCl2 100 μmol/L, 48 hours),PI-88 group (specific competitive inhibitor of heparanase: phosphomannopentaose sulfate, PI-88,5 μg/ml, combined with CoCl2 100 μmol/L, 48 hours) and PBS control group. Heparanase, VEGF and Pol Ⅱ expression in HRECs of normal and hypoxia group were analyzed with immunofluorescence. Western blot was used to evaluate the expression of heparanase and VEGF in HRECs of normal, hypoxia, PI88 and PBS control groups. ResultsImmunofluorescence studies showed that the expression of heparanase and VEGF in cytoplasm was intense in hypoxia HRECs, but faint in normal group. Heparanase was also observed in the nucleus of hypoxia HRECs. Western blot results showed that the expression of Hpa and VEGF protein was increased significantly in hypoxia group compared with normal group (Hpa:F=-4。005, P<0.05;VEGF:F=-4.063, P<0.05), and VEGF was decreased in HRECs treated with PI-88(F=5。963, P<0.05). ConclusionsHeparanase is upregulated that resulted in increase of VEGF expression, therefore enhanced angiogenesis in CoCl2 induced hypoxia HRECs.
ObjectiveTo observe the expression in vitro and the influence of adenovirus-mediated recombinant Tum5 gene to the proliferation, migration and tubing of Rhesus RF/6A cell under high glucose. MethodsTo construct the adenovirus vector of recombinant Tum5 gene (rAd-Tum5), and then infected RF/6A cell with it. The Flow Cytometry was used to detect the infection efficiency. RF/6A cells were divided into normal group, high glucose (HG)-control group (HG group), empty expression vector group (HG+rAd-GFP), and HG+rAd-Tum5 group. Western blot was used to detect the expression of Tum5. The CCK-8 test was applied to detect the proliferation of RF/6A cell, the Transwell test was applied to detect the migration and the Matrigel test was applied to detect the tubing of RF/6A cell under high glucose. The proliferation, migration and tubing of RF/6A were tested respectively by CCK-8 test, Transwell test and Matrigel test. ResultsThe adenovirus vector of recombinant Tum5 gene was successfully constructed. The infection efficiency of rAd-Tum5 in RF/6A cell was 50.31% and rAd-GFP was 55.13% by the Flow Cytometry. The results of Western blot indicated that Tum5 was successfully expressed in RF/6A cell. The result of CCK-8 test, Transwell test and Matrigel test indicated that there were statistical differences between all groups in proliferation, migration and tubing of the RF/6A cell (F=44.484, 772.666, 137.696;P < 0.05). The comparison of each group indicated that the HG group was higher than normal group (P < 0.05). There were no statistical differences between HG group and HG+rAd-GFP group (P > 0.05). However, the HG+rAd-Tum5 group was less than HG group (P < 0.05), and the same to HG+rAd-GFP (P < 0.05). ConclusionThe adenovirus vector of recombinant Tum5 gene can inhibit the proliferation, migration and tubing of RF/6A cell under high glucose.
ObjectiveTo explore the effects of transthyretin (TTR) on biological behavior of retinal microvascular epithelial cell (RMVEC). MethodsRMVEC was cultured in medium with 0 μmol/L and 4 μmol/L TTR. The proliferation, migration and healing abilities (0, 24, 48 hours) of RMVEC with different concentrations of TTR were measured by methyl thiazol tetrazolium (MTT) assay, transwell assay and scarification test. ResultsMTT assay shows that RMVEC with the concentrations of 4 μmol/L TTR [absorbance (A) value=0.17±0.02] glows faster than with the concentrations of 0 μmol/L TTR (A value=0.40±0.03), the difference was statistically significant (t=15.47, P=0.000 1). The transwell assay shows RMVEC with the concentration of 4 μmol/L TTR [(140±7) cells] migrants faster than RMVEC with the concentration of 0 μmol/L TTR [(227±14) cells], the difference was statistically significant (t=5.44, P=0.000 6). The scarification test shows that the RMVEC with the concentration of 4 μmol/L TTR [(134.4±45.4) μm] heals faster than the RMVEC with the concentration of 0 μmol/L TTR [(330.0±23.1) μm], the difference was statistically significant (t=8.25, P<0.01). The cells in 48 hours and 4 μmol/L group were healed completely, but not healed in 0 μmol/L group. ConclusionTTR can promote the proliferation, migration and healing abilities of RMVEC.
Organoids are three-dimensional structures formed by self-organizing growth of cells in vitro, which own many structures and functions similar with those of corresponding in vivo organs. Although the organoid culture technologies are rapidly developed and the original cells are abundant, the organoid cultured by current technologies are rather different with the real organs, which limits their application. The major challenges of organoid cultures are the immature tissue structure and restricted growth, both of which are caused by poor functional vasculature. Therefore, how to develop the vascularization of organoids has become an urgent problem. We presently reviewed the progresses on the original cells of organoids and the current methods to develop organoids vascularization, which provide clues to solve the above-mentioned problems.
ObjectiveTo observe the effect of pyrimidine bundle-binding protein-associated splicing factors (PSF) on the function of hypoxia-induced human retinal microvascular endothelial cells (hRMECs).MethodsA three-plasmid system was used to construct lentivirus (LV)-PSF. After LV-PSF infected hRMECs in vitro, the infection efficiency was measured by flow cytometry. Real-time quantitative PCR (RT-PCR) was used to detect the expression of PSF mRNA in hRMECs infected with LV-PSF. The experiment was divided into two parts, in vivo and in vitro. In vivo experiments: 20 healthy C57B/L6 mice at the age of postnatal 7 were randomly divided into normal group, oxygen-induced retinopathy (OIR) group, OIR+LV-Vec group, and OIR+LV-PSF group, each group has five mice. Mice in 3 groups were constructed with OIR models except the normal group and the mice in OIR group were not treated. The mice in the OIR + LV-Vec group and the OIR+LV-PSF group were injected with an empty vector (LV-Vec) or LV-PSF in the vitreous cavity, respectively. The effect of LV-PSF on the formation of retinal neovascularization (RNV) was observed then. In vitro experiments: hRMECs were divided into normal group, hypoxia group, vector group, and PSF high expression group. HRMECs in the normal group were cultured in vitro; hRMECs in the hypoxic group were restored to normal culture conditions for 3 h after 3 h of hypoxia stimulation; hRMECs in the vector group and PSF high expression group were infected with LV-Vec and LV-PSF for 48 h, and hRMECs were returned to normal culture conditions for 24 h with hypoxia stimulation for 3 h. The effect of PSF on cell proliferation was observed by MTT colorimetry. Cell scratch test and Transwell migration experiment were used to observe the effect of PSF on cell migration ability under hypoxia stimulation. RT-PCR was used to observe the mRNA expression of HIF-1α, VEGF and PSF in each group of cells.ResultsThe LV-PSF of stably expressing PSF was successfully constructed. The infection efficiency was 97% determined by flow cytometry. The level of PSF mRNA in hRMECs infected with LV-PSF was significantly increased and detected by RT-PCR. In vivo experiments: The RNV area of the mice in the OIR group and the OIR + LV-Vec group was significantly increased compared to the normal group (t=18.31, 43.71), and the RNV area of the mice in the OIR + LV-PSF group was smaller than that in the OIR group (t=11.30) and OIR + The LV-Vec group (t=15.47), and the differences were statistically significant (P<0.05). In vitro experiments: MTT colorimetry results showed that the proliferative capacity of hRMECs in the hypoxic group was significantly enhanced compared with the normal group (t=2.57), and the proliferative capacity of hRMECs in the PSF high expression group was significantly lower than that of the normal, hypoxic, and vector groups (t=5.26, 5.46, 3.73), the differences were statistically significant (P<0.05). The results of cell scratch test showed that the hRMECs could be stimulated by the hypoxia stimulation for 3 hours to restore the normal condition for 24 hours or 48 hours (t=8.35, 13.84; P<0.05). Compared with the vector group, cell migration rate in the PSF-high expression group was not significant (t=10.99, 18.27, 9.75, 8.93, 26.94, 7.01; P<0.05). Transwell experiments showed that the number of cells stained on the microporous membrane was higher in the normal group and the vector groups, while the number of cells stained in the PSF high expression group was significantly reduced (t=9.33, 6.15; P<0.05). The results of RT-PCR showed that the mRNA expression of HIF-1α and VEGF in hRMECs in the hypoxic and vector groups increased significantly compared with the normal group (t=15.23, 21.09; P<0.05), but no change in the mRNA expression of PSF (t=0.12, 2.15; P>0.05); compared with the hypoxia group and the vector group, the HIF-1α and VEGF mRNA expression in hRMECs in the PSF high expression group were significantly decreased (t=10.18, 13.10; P<0.05), but the PSF mRNA expression increased (t=65.00, 85.79; P<0.05).ConclusionPSF can reduce the RNV area in OIR model mice. PSF may inhibit hypoxia-induced proliferation and migration of hRMECs through the HIF-1α/VEGF signaling pathway.
Objective To explore morphological recellularization level of bioprosthetic valve scaffold (BVS) and to provide researching means for fabricating tissue engineered heart valve in vitro.Methods The homograft bioprosthetic aortic tube valve was selected as BVS, which was conserved by liquid nitrogen, and its endothelial cells (ECs) were removed by 0.1% sodium dodecylsulphate (SDS). As implantation cells, the endothelial cells (ECs) differentiating from human bone marrow mesenchymal stem cells (MSCs) in vitro were implanted with high-density seeding (gt;10 5 cells/cm2) on the BVS, which was covered by fibronectin (80 μg/ml) in advance. The complex structure was statically cultured in DMEM (high glucose) with 20% FBS and VEGF (10 ng/ml) for about 20 days in vitro and stained by 0.5% AgNO3. The morphological structure was observed and photographed by stereomicroscope to detect the recellularization level. Results The ECs of the bioprosthetic valve were notonly removed completely, but also the collagen fiber and elastic fibers were reserved. The ECs differentiating from MSCs were successfully implanted on the HBS, whose recellularization levels on 7th, 14th and 20th day were 73%, 85%, and 92% respectively. Conclusion AgNO3 staining technique is effective, convenient, and economic in evaluating the recellularization level of BVS. It is an effective method in morphological observation for fabricating tissueengineered heart valve in vitro.
ObjectiveTo observe RNA-Seq analysis of gene expression profiling in retinal vascular endothelial cells after anti-vascular endothecial growth factor (VEGF) treatment.MethodsRetinal vascular endothelial cells were cultured in vitro, and the logarithmic growth phase cells were used for experiments. The cells were divided into the control group and high glucose group. The cells of two groups were cultured for 5 hours with 5, 25 mmol/L glucose, respectively. And then, whole transcriptome sequencing approach was applied to the above two groups of cells through RNA-Seq. Now with biological big data obtained as a basis, to analyze the differentially expressed genes (DEGs). And through enrichment analysis to explain the differential functions of DEGs and their signal pathways.ResultsThe gene expression profiles of the two groups of cells were obtained. Through analysis, 449 DEGs were found, including 297 upregulated and 152 downregulated ones. The functions of DEGs were influenced by regulations over molecular biological process, cellular energy metabolism and protein synthesis, etc. Among these genes, ITGB1BP2, NCF1 and UNC5C were related to production of inflammation; AKR1C4, ATP1A3, CHST5, LCTL were related to energy metabolism of cells; DAB1 and PRSS55 were related to protein synthesis; SMAD9 and BMP4 were related to the metabolism of extracellular matrix. GO enrichment analysis showed that DEGs mainly act in three ways: regulating biological behavior, organizing cellular component and performing molecular function, which were mainly concentrated in the system generation of biological process part and regulation of multicellular organisms. Pathway enrichment analysis showed that gene expressions of the two cell groups were differentiated in transforming growth factor-β (TGF-β) signaling pathway, complement pathway and amino acid metabolism-related pathways have also been affected, such as tryptophan, serine and cyanide. Among them, leukocyte inhibitory factor 9 and bone morphogenetic protein 4 play a role through the TGF-β signaling pathway.ConclusionsHigh glucose affects the function of retinal vascular endothelial cells by destroying transmembrane conduction of retinal vascular endothelial cells, metabolism of extracellular matrix, and transcription and translation of proteins.
Objective To investigate the effect of arginase (Arg) inhibitor N-ω-Hydroxy-L nor-Arginine (nor-NOHA) on high glucose cultured rhesus macaque retinal vascular endothelial cell line (RF/6A) in vitro. Methods The RF/6A cells were divided into the following 4 groups: normal control group (5.0 mmol/L of glucose, group A), high glucose group (25.0 mmol/L, group B), high glucose with 125 mg/L nor-NOHA group (group C), and high glucose with 1% DMSO group (group D). The proliferation, migration ability and angiogenic ability of RF/6A cells were measured by Methyl thiazolyl tetrazolium (MTT), transwell chamber and tube assay respectively. The express of Arg I, eNOS, iNOS mRNA of RF/6A cells were measured by real-time polymerase chain reaction (RT-PCR), Enzyme-linked immuno sorbent assay (ELISA) was used to detect the expression of NO and interleukine (IL)-1b of RF/6A cells. Results The proliferation, migration, and tube formation ability of group A (t=2.367, 5.633, 7.045;P<0.05) and group C (t=5.260, 6.952, 8.875;P<0.05) were significantly higher than group B. RT-PCR results showed the Arg I and iNOS expression in group B was higher than that in group A (t=6.836, 3.342;P<0.05) and group C (t=4.904, 7.192;P<0.05). The eNOS expression in group B was lower than that in group A and group C (t=4.165, 6.594;P<0.05). ELISA results showed NO expression in group B was lower than that in group A and group C (t=4.925, 5.368;P<0.05). IL-1b expression in group B was higher than that in group A and group C (t=5.032, 7.792;P<0.05). Conclusions Nor-NOHA has a protective effect on cultured RF/6A cells in vitro and can enhance its proliferation, migration and tube formation. The mechanism may be inhibiting the oxidative stress by balancing the expression of Arg/NOS.
ObjectiveTo observe the MiSeq sequencing analysis results of fulvic acid (FA) intervention in hypoxia-induced human retinal microvascular endothelial cell (hRMEC) gene expression profile.MethodshRMEC were cultured in vitro and divided into the hypoxia group (hypoxia treatment) and the FA intervention group (FA intervention after hypoxia). The MTT colorimetric method was used to detect the influence of different concentrations and different modes of FA on hRMEC activity. The optimal concentration of FA was chosen. RT-PCR was used to investigated the effect of FA on hypoxia-induced intercellular adhesion molecule-1 (ICAM-1), IL-1β, IL-4, IL-6, IL-6, IL-8, IL-10, MMP-2, TNF-α, TNF-β, other inflammatory factors in hRMEC, and inflammation-related factors mRNA expression. Cells in the hypoxia group and FA intervention group in the logarithmic growth phase were collected. MiSeq sequencing technology was applyed to complete the whole transcriptome sequencing of the two groups of cells, biological data were obtained, and the differentially expressed miRNA were analyzed on this basis. Gene annotation (GO) functionally significant enrichment analysis and Kyoto Encyclopedia of Genes and Genome (KEGG) pathway significant enrichment analysis were used to analyze the functions and signal pathways of differential miRNAs. The expression of inflammatory factors and inflammation-related factors were compared between groups. The expression level of the corresponding miRNA in the cell was regulated by miRNA mimic, and its effect on cell function was observed, so as to judge the effect of the miRNA.ResultsDifferent concentrations and different modes of action of FA had no effect on the cell viability of hRMEC. The mRNA expression of ICAM-1, IL-1β, IL-6 and TNF-β in the hypoxia group hRMEC were significantly up-regulated compared with the normal group, and the difference was statistically significant (t=3.426, 6.011, 5.282, 6.500; P=0.027, 0.004, 0.006, 0.003); the mRNA expression of ICAM-1, IL-6, TNF-α and TNF-β in the FA intervention group hRMEC was significantly lower than that of the hypoxia group, and the difference was statistically significant (t=9.961, 3.676, 3.613, 3.387; P=0.001, 0.021, 0.023, 0.028). There were 14 differentially expressed miRNAs between the hypoxia group and the FA intervention group, of which 9 were up-regulated genes and 5 were down-regulated genes. The predicted target genes of 4 differential miRNAs (hsa-miR-1285-3p, hsa-miR-30d-3p, hsa-miR-3170, hsa-miR-7976) were all ICAM-1. The results of significant enrichment analysis of GO function showed that the functions of differential genes were mainly enriched in the process of cell development, cell differentiation and single organism development. Significant enrichment analysis of the KEGG pathway showed that the differential miRNA expression was highly enriched in the proteoglycan pathway and the cytokine-cytokine receptor interaction pathway in cancer, and the arachidonic acid metabolism pathway and the amphetamine pathway were the more obvious differential expressions.ConclusionFA may affect the expression level of downstream ICAM-1 mRNA by regulating the expression of multiple miRNAs, thereby affecting the inflammatory state of cells after hypoxia-stimulated hRMEC.