Proinsulin C-peptide inhibits high glucose-induced migration and invasion of ovarian cancer cells.

Proinsulin C-peptide, a biologically active polypeptide released from pancreatic ß-cells, is known to prevent hyperglycemia-induced microvascular leakage; however, the role of C-peptide in migration and invasion of cancer cells is unknown. Here, we investigated high glucose-induced migration and invasion of ovarian cancer cells and the inhibitory effects of human C-peptide on metastatic cellular responses. In SKOV3 human ovarian cancer cells, high glucose conditions activated a vicious cycle of reactive oxygen species (ROS) generation and transglutaminase 2 (TGase2) activation through elevation of intracellular Ca2+ levels. TGase2 played a critical role in high glucose-induced ovarian cancer cell migration and invasion through ß-catenin disassembly. Human C-peptide inhibited high glucose-induced disassembly of adherens junctions and ovarian cancer cell migration and invasion through inhibition of ROS generation and TGase2 activation. The preventive effect of C-peptide on high glucose-induced ovarian cancer cell migration and invasion was further demonstrated in ID8 murine ovarian cancer cells. Our findings suggest that high glucose conditions induce the migration and invasion of ovarian cancer cells, and human C-peptide inhibits these metastatic responses by preventing ROS generation, TGase2 activation, and subsequent disassembly of adherens junctions.

Systemic C-peptide supplementation ameliorates retinal neurodegeneration by inhibiting VEGF-induced pathological events in diabetes.

Diabetic retinopathy (DR) is caused by retinal vascular dysfunction and neurodegeneration. Intraocular delivery of C-peptide has been shown to be beneficial against hyperglycemia-induced microvascular leakage in the retina of diabetes; however, the effect of C-peptide on diabetes-induced retinal neurodegeneration remains unknown. Moreover, extraocular C-peptide replacement therapy against DR to avoid various adverse effects caused by intravitreal injections has not been studied. Here, we demonstrate that systemic C-peptide supplementation using osmotic pumps or biopolymer-conjugated C-peptide hydrogels ameliorates neurodegeneration by inhibiting vascular endothelial growth factor-induced pathological events, but not hyperglycemia-induced vascular endothelial growth factor expression, in the retinas of diabetic mice. C-peptide inhibited hyperglycemia-induced activation of macroglial and microglial cells, downregulation of glutamate aspartate transporter 1 expression, neuronal apoptosis, and histopathological changes by a mechanism involving reactive oxygen species generation in the retinas of diabetic mice, but transglutaminase 2, which is involved in retinal vascular leakage, is not associated with these pathological events. Overall, our findings suggest that systemic C-peptide supplementation alleviates hyperglycemia-induced retinal neurodegeneration by inhibiting a pathological mechanism, involving reactive oxygen species, but not transglutaminase 2, in diabetes.

C-peptide attenuates hyperglycemia-induced pulmonary fibrosis by inhibiting transglutaminase 2.

Proinsulin C-peptide has a protective effect against diabetic complications; however, its role in hyperglycemia-induced pulmonary fibrosis is unknown. In this study, we investigated the inhibitory effect of C-peptide on hyperglycemia-induced pulmonary fibrosis and the molecular mechanism of C-peptide action in the lungs of diabetic mice and in human pulmonary microvascular endothelial cells (HPMVECs). We found that, in the lungs of diabetic mice, C-peptide supplementation using osmotic pumps attenuated hyperglycemia-induced pulmonary fibrosis and expression of fibrosis-related proteins. In HPMVECs, C-peptide inhibited vascular endothelial growth factor-induced adherens junction disruption and endothelial cell permeability by inhibiting reactive oxygen species generation and transglutaminase (TGase) activation. In the lungs, C-peptide supplementation suppressed hyperglycemia-induced reactive oxygen species generation, TGase activation, and microvascular leakage. C-peptide inhibited hyperglycemia-induced inflammation and apoptosis, which are involved in the pathological process of pulmonary fibrosis. We also demonstrated the role of TGase2 in hyperglycemia-induced vascular leakage, inflammation, apoptosis, and pulmonary fibrosis in the lungs of diabetic TGase2-null (Tgm2-/-) mice. Furthermore, we demonstrated a long-term inhibitory effect of systemic delivery of C-peptide using K9-C-peptide hydrogels on hyperglycemia-induced fibrosis in diabetic lungs. Overall, our findings suggest that C-peptide alleviates hyperglycemia-induced pulmonary fibrosis by inhibiting TGase2-mediated microvascular leakage, inflammation, and apoptosis in diabetes.

Application of elastin-like biopolymer-conjugated C-peptide hydrogel for systemic long-term delivery against diabetic aortic dysfunction.

Due to their short half-lives, repeated administration of anti-hyperglycemic drugs can cause pain, discomfort, tissue damage, and infection in diabetic patients. Therefore, there is a need to develop long-term drug delivery systems to treat diabetes and its complications. C-peptide can prevent diabetic complications, including diabetic vasculopathy, but its clinical application is limited by its short half-life. Here, we developed K9-C-peptide (human C-peptide conjugated to an elastin-like biopolymer) and investigated its long-term influence on hyperglycemia-induced vascular dysfunction using an aortic endothelium model in diabetic mice. Using pharmacokinetics and in vivo imaging, we found that subcutaneously injected K9-C-peptide formed a hydrogel depot that slowly released human C-peptide into the blood circulation for 19 days. Administration of K9-C-peptide, human C-peptide, or K8 polypeptide had no effect on body weight or blood glucose levels. The slow release of C-peptide from K9-C-peptide hydrogels provided prolonged prevention of oxidative stress, inflammatory responses, and endothelial apoptosis in a hyperglycemia-induced vascular dysfunction model using the diabetic mouse aorta. Subcutaneous administration of unbound human C-peptide and K8 polypeptide were used as negative controls and had no effects. These results suggest that K9-C-peptide is suitable for the long-term delivery of human C-peptide for treating vascular dysfunction in diabetic patients.

Anti-metastatic effect of midazolam on melanoma B16F10 cells in the lungs of diabetic mice.

Midazolam is an anesthetic agent commonly used for anesthesia and sedation in surgery. However, there is no information on the role of midazolam in hyperglycemia-induced cancer metastasis to date. In this study, we investigated the effects of midazolam on inhibiting metastases in the lungs of diabetic mice and on human pulmonary microvascular endothelial cells (HPMVECs). Subcutaneous injection of midazolam inhibited hyperglycemia-induced cancer metastasis in the lungs of diabetic mice. Midazolam also prevented the generation of ROS, activation of TGase, and subsequent vascular leakage in the lungs of diabetic mice. Furthermore, in vitro studies with HPMVECs confirmed that midazolam inhibited VEGF-induced intracellular events including ROS generation, TGase activation, and disruption of vascular endothelial-cadherins, thus preventing the permeability of endothelial cells. Notably, midazolam had no direct effect on the migration or proliferation of melanoma cells, instead acting upon endothelial cells. The midazolam-mediated inhibition of VEGF-induced intracellular events was reversed by treatment with the GABAA receptor antagonist flumazenil. These findings suggest that midazolam prevents hyperglycemia-induced cancer metastasis by inhibiting VEGF-induced intracellular events and subsequent vascular leakage via the GABAA receptors in the lungs of diabetic mice.

Insulin prevents pulmonary vascular leakage by inhibiting transglutaminase 2 in diabetic mice.

AIMS: Insulin is a central peptide hormone required for carbohydrate metabolism; however, its role in diabetes-associated pulmonary disease is unknown. Here, we investigated the preventative effect of insulin against hyperglycemia-induced pulmonary vascular leakage and its molecular mechanism of action in the lungs of diabetic mice. MAIN METHODS: Vascular endothelial growth factor (VEGF) activated transglutaminase 2 (TGase2) by sequentially elevating intracellular Ca2+ and reactive oxygen species (ROS) levels in primary human pulmonary microvascular endothelial cells (HPMVECs). KEY FINDINGS: Insulin inhibited VEGF-induced TGase2 activation, but did not affect intracellular Ca2+ elevation and ROS generation. Insulin prevented VEGF-induced vascular leakage by inhibiting TGase2-mediated c-Src phosphorylation, disassembly of VE-cadherin and ß-catenin, and stress fiber formation. Insulin replacement therapy prevented hyperglycemia-induced TGase2 activation, but not ROS generation, in the lungs of diabetic mice. Insulin also prevented vascular leakage and cancer metastasis in the diabetic lung. Notably, vascular leakage was not detectable in the lungs of TGase2-null (Tgm2-/-) diabetic mice. SIGNIFICANCE: These findings demonstrate that insulin prevents hyperglycemia-induced pulmonary vascular leakage in diabetic mice by inhibiting VEGF-induced TGase2 activation rather than ROS generation.

Proinsulin C-peptide prevents hyperglycemia-induced vascular leakage and metastasis of melanoma cells in the lungs of diabetic mice.

C-peptide has a beneficial effect against diabetic complications, but its role in hyperglycemia-induced metastasis is unknown. We investigated hyperglycemia-mediated pulmonary vascular leakage and metastasis and C-peptide inhibition of these molecular events using human pulmonary microvascular endothelial cells (HPMVECs) and streptozotocin-induced diabetic mice. VEGF, which is elevated in the lungs of diabetic mice, activated transglutaminase 2 (TGase2) in HPMVECs by sequential elevation of intracellular Ca2+ and reactive oxygen species (ROS) levels. VEGF also induced vascular endothelial (VE)-cadherin disruption and increased the permeability of endothelial cells, both of which were prevented by the TGase inhibitors monodansylcadaverine and cystamine or TGM2-specific small interfering RNA. C-peptide prevented VEGF-induced VE-cadherin disruption and endothelial cell permeability through inhibiting ROS-mediated activation of TGase2. C-peptide supplementation inhibited hyperglycemia-induced ROS generation and TGase2 activation and prevented vascular leakage and metastasis in the lungs of diabetic mice. The role of TGase2 in hyperglycemia-induced pulmonary vascular leakage and metastasis was further demonstrated in diabetic Tgm2-/- mice. These findings demonstrate that hyperglycemia induces metastasis, and C-peptide prevents the hyperglycemia-induced metastasis in the lungs of diabetic mice by inhibiting VEGF-induced TGase2 activation and subsequent vascular leakage.-Jeon, H.-Y., Lee, Y.-J., Kim, Y.-S., Kim, S.-Y., Han, E.-T., Park, W. S., Hong, S.-H., Kim, Y.-M., Ha, K.-S. Proinsulin C-peptide prevents hyperglycemia-induced vascular leakage and metastasis of melanoma cells in the lungs of diabetic mice.

Systematic investigation of protein kinase A substrate proteins using on-chip protein kinase kinetic profiling.

Protein kinases play a critical role in a wide variety of cellular processes through post-translational protein phosphorylation and identification of their substrate proteins is important for understanding the enzymes' mechanism of action and elucidating their functions in physiological and disease processes. However, there have been few systematic investigations of protein kinase substrates due to a lack of high-throughput kinetic assays. Thus, we designed an on-chip protein kinase assay for profiling kinase kinetic parameters by introducing the phosphorylation rate (Vp) under physiological conditions, instead of the maximal velocity (Vmax), in a high-throughput manner. We applied this method to the kinetic analysis of protein kinase A (PKA) for 28 nuclear, cytosolic, plasma membrane, and extracellular target proteins to determine the substrate affinity (Km), Vp (FIATP10/s), and substrate preference (Vp/Km). We then constructed a map of PKA's kinetic parameters with respect to the 28 proteins based on subcellular localization. Thus, the on-chip protein kinase kinetic profiling is an ideal approach for systematically investigating substrate proteins of protein kinases and fully characterizing the enzymes' physiological functions.

Sensitive array-based assay for determination of serological protein kinase A autoantibody levels based on its antigen protein activation.

OBJECTIVES: We investigated the effect of cPKAα conformational states during protein immobilization on an array platform for cPKA autoantibody assays for sensitive and high-throughput profiling of protein kinase A (PKA) autoantibody levels in human sera. DESIGN AND METHODS: We prepared activated human cPKAα protein arrays by addition of cofactors including ATP, MgCl2, and Triton X-100 to incubation buffer. Anti-human cPKAα antibody or PKA autoantibody levels in human sera were analyzed using activated human cPKAα protein arrays. RESULTS: Activation of cPKAα with ATP, Mg(2+), and Triton X-100 enhanced the sensitivity of the assay by increasing the signal/noise ratio and lowering the limit of detection. cPKAα activation also enhanced the sensitivity of cPKA autoantibody detection in human sera. We successfully applied this assay to determine cPKA autoantibody levels in human sera from normal individuals (n=30) and hepatic cancer patients (n=30). CONCLUSIONS: Our results demonstrate that cPKAα activation enhanced the sensitivity of array-based PKA autoantibody assays, and that this assay is suitable for high-throughput analyses of cPKA autoantibodies in human sera.

Dammarenediol-II Prevents VEGF-Mediated Microvascular Permeability in Diabetic Mice.

Diabetic retinopathy is a major diabetic complication predominantly caused by vascular endothelial growth factor (VEGF)-induced vascular permeability in the retina; however, treatments targeting glycemic control have not been successful. Here, we investigated the protective effect of dammarenediol-II, a precursor of triterpenoid saponin biosynthesis, on VEGF-induced vascular leakage using human umbilical vein endothelial cells (HUVECs) and diabetic mice. We overproduced the compound in transgenic tobacco expressing Panax ginseng dammarenediol-II synthase gene and purified using column chromatography. Analysis of the purified compound using a gas chromatography-mass spectrometry system revealed identical retention time and fragmentation pattern to those of authentic standard dammarenediol-II. Dammarenediol-II inhibited VEGF-induced intracellular reactive oxygen species generation, but it had no effect on the levels of intracellular Ca(2+) in HUVECs. We also found that dammarenediol-II inhibited VEGF-induced stress fiber formation and vascular endothelial-cadherin disruption, both of which play critical roles in modulating endothelial permeability. Notably, microvascular leakage in the retina of diabetic mice was successfully inhibited by intravitreal dammarenediol-II injection. Our results suggest that the natural drug dammarenediol-II may have the ability to prevent diabetic microvascular complications, including diabetic retinopathy.

A peptide array-based serological protein kinase A activity assay and its application in cancer diagnosis.

Protein kinase A (PKA) plays a crucial role in several biological processes; however, there is no assay with sufficient sensitivity and specificity to determine serological PKA (sPKA) activity. Here we present an on-chip activity assay that employs cysteine-modified kemptide arrays to determine specific sPKA activity in human sera that eliminates the potential contributions of other kinases with a protein kinase peptide inhibitor. The sensitivity of the on-chip sPKA activity assay was greatly enhanced by Triton X-100, with a 0.01 U mL(-1) detection limit. sPKA activity was determined by subtracting nonspecific sPK activity from total sPK activity. Our assay provided greater sensitivity and specificity and more accurate area under the curve values for gastric cancer compared to the total sPK activity assay. sPKA activities in human sera from patients with hepatic (n = 30), gastric (n = 30), lung (n = 30), and colorectal (n = 30) cancers were significantly higher than those in controls (n = 30, p < 10(-4)), but no significant difference in sPKA activities between normal and inflammation groups was observed. These results demonstrate that the on-chip assay accurately measures sPKA activity in human sera and that the sPKA activity may be a potential biomarker for cancer diagnosis.