Regulation of hepatic oxidative stress by voltage-gated proton channels (Hv1/VSOP) in Kupffer cells and its potential relationship with glucose metabolism.

Voltage-gated proton channels (Hv1/VSOP), encoded by Hvcn1, are important regulator of reactive oxygen species (ROS) production in many types of immune cells. While in vitro studies indicate that Hv1/VSOP regulates ROS production by maintaining pH homeostasis, there are few studies investigating the functional importance of Hv1/VSOP in vivo. In the present study, we first show that Hv1/VSOP is functionally expressed in liver resident macrophage, Kupffer cells, regulating the hepatic oxidative stress in vivo. Our immunocytochemistry and electrophysiology data showed that Hvcn1 is specifically expressed in Kupffer cells, but not in hepatocytes. Furthermore, Hvcn1-deficiency drastically altered the hepatic oxidative stress. The Hvcn1-deficient mice showed high blood glucose and serum insulin but normal insulin sensitivity, indicating that these phenotypes were not linked to insulin resistance. Transcriptome analysis indicated that the gene expression of glycogen phosphorylase (Pygl) and Glucose-6-phosphatase, catalytic subunit (G6pc) were upregulated in Hvcn1-deficient liver tissues, and quantitative PCR confirmed the result for Pygl. Furthermore, we observed higher amount of glucose-6-phosphate, a key sugar intermediate for glucose in Hvcn1-deficient liver than WT, suggesting that glucose production in liver is accelerated in Hvcn1-deficient mice. The present study sheds light on the functional importance of Kupffer cells in hepatic oxidative stress and its potential relationship with glucose metabolism.

Kawai T ，Kayama K ，Tatsumi S ，Akter S ，Miyawaki N ，Okochi Y ，Abe M ，Sakimura K ，Yamamoto H ，Kihara S ，Okamura Y ... -  《-》

Unconventional role of voltage-gated proton channels (VSOP/Hv1) in regulation of microglial ROS production.

It has been established that voltage-gated proton channels (VSOP/Hv1), encoded by Hvcn1, support reactive oxygen species (ROS) production in phagocytic activities of neutrophils (El Chemaly et al. ) and antibody production in B lymphocytes (Capasso et al. ). VSOP/Hv1 is a potential therapeutic target for brain ischemia, since Hvcn1 deficiency reduces microglial ROS production and protects brain from neuronal damage (Wu et al. ). In the present study, we report that VSOP/Hv1 has paradoxical suppressive role in ROS production in microglia. Extracellular ROS production was lower in neutrophils of Hvcn1-/- mice than WT mice as reported. In contrast, it was drastically enhanced in isolated Hvcn1-/- microglia as compared with cells from WT mice. Actin dynamics was altered in Hvcn1-/- microglia and intracellular distribution of cytosolic NADPH oxidase subunit, p67, was changed. When expression levels of oxidative stress responsive antioxidant genes were compared between WT and Hvcn1-/- in cerebral cortex at different ages of animals, they were slightly decreased in Hvcn1-/- mice at younger stage (1 day, 5 days, 3 weeks old), but drastically increased at aged stage (6 months old), suggesting that the regulation of microglial ROS production by VSOP/Hv1 is age-dependent. We also performed brain ischemic stroke experiments and found that the neuroprotective effect of VSOP/Hv1deficiency on infarct volume depended on the age of animals. Taken together, regulation of ROS production by VSOP/Hv1 is more complex than previously thought and significance of VSOP/Hv1 in microglial ROS production depends on age.

Kawai T ，Okochi Y ，Ozaki T ，Imura Y ，Koizumi S ，Yamazaki M ，Abe M ，Sakimura K ，Yamashita T ，Okamura Y ... -  《-》

Mechanistic insight into the suppression of microglial ROS production by voltage-gated proton channels (VSOP/Hv1).

Kawai T ，Tatsumi S ，Kihara S ，Sakimura K ，Okamura Y ... -  《-》

Hv1/VSOP regulates neutrophil directional migration and ERK activity by tuning ROS production.

High-level reactive oxygen species (ROS) production in neutrophils is tightly regulated, as it can damage host cells. Neutrophils also undergo low-level ROS production when stimulated by cytokines or chemoattractants, but its biologic significance remains largely unknown. Voltage-gated proton channels (Hv1/VSOP) activity reportedly supports ROS production in neutrophils; however, we show here that Hv1/VSOP balances ROS production to suppress neutrophil directional migration in the presence of low concentrations of N-formyl-Met-Leu-Phe (fMLF). Neutrophils derived from Hvcn1 gene knockout mice produced more ROS than neutrophils from wild-type mice in the stimulation with fMLF at concentration of 1 µM and nonstimulus condition. They also exhibited stronger chemotactic responses to low concentrations of fMLF than did wild-type neutrophils. Receptor sensitivity to fMLF and evoked Ca2+ responses did not differ between Hv1/VSOP-deficient and wild-type neutrophils. Activation of ERK, but not p38, was enhanced and prolonged during the increased ROS production seen after fMLF stimulation in Hv1/VSOP-deficient neutrophils. Inhibiting ROS production suppressed the enhanced ERK activation in Hv1/VSOP-deficient neutrophils and their directional migration. These results indicate that Hv1/VSOP balances ROS production to reduce ERK signaling and suppress excessive neutrophil migration in response to fMLF. Our findings thus reveal a novel role for ROS in the directional migration of neutrophils.

Okochi Y ，Umemoto E ，Okamura Y 《-》

Regulation of Neutrophil Functions by Hv1/VSOP Voltage-Gated Proton Channels.

Okochi Y ，Okamura Y 《INTERNATIONAL JOURNAL OF MOLECULAR SCIENCES》