UDP-glucose, cereblon-dependent proinsulin degrader.

Insulin secretion is regulated in multiple steps, and one of the main steps is in the endoplasmic reticulum (ER). Here, we show that UDP-glucose induces proinsulin ubiquitination by cereblon, and uridine binds and competes for proinsulin degradation and behaves as sustainable insulin secretagogue. Using insulin mutagenesis of neonatal diabetes variant-C43G and maturity-onset diabetes of the young 10 (MODY10) variant-R46Q, UDP-glucose:glycoprotein glucosyltransferase 1 (UGGT1) protects cereblon-dependent proinsulin ubiquitination in the ER. Cereblon is a ligand-inducible E3 ubiquitin ligase, and we found that UDP-glucose is the first identified endogenous proinsulin protein degrader. Uridine-containing compounds, such as uridine, UMP, UTP, and UDP-galactose, inhibit cereblon-dependent proinsulin degradation and stimulate insulin secretion from 3 to 24 h after administration in ß-cell lines as well as mice. This late and long-term insulin secretion stimulation is designated a day sustainable insulin secretion stimulation. Uridine-containing compounds are designated as proinsulin degradation regulators.

UDP-Glucose: A Cereblon-Dependent Glucokinase Protein Degrader.

We previously reported that glucokinase is ubiquitinated and degraded by cereblon with an unknown endogenous glucokinase protein degrader. Here, we show that UDP-glucose is a glucokinase protein degrader. We identified that both glucose and UDP-glucose bind to glucokinase and that both uridine and UDP-glucose bind to cereblon in a similar way to thalidomide. From these results, UDP-glucose was identified as a molecular glue between cereblon and glucokinase. Glucokinase produces glucose-6-phosphate in the pancreas and liver. Especially in ß-cells, glucokinase is the main target of glucose for glucose-induced insulin secretion. UDP-glucose administration ubiquitinated and degraded glucokinase, lowered glucose-6-phosphate production, and then reduced insulin secretion in ß-cell lines and mice. Maturity-onset diabetes of the young type 2 (MODY2) glucokinaseE256K mutant protein was resistant to UDP-glucose induced ubiquitination and degradation. Taken together, glucokinase ubiquitination and degradation signaling might be impaired in MODY2 patients.

R1526 residue in arginine/proinsulin binding domain of UGGT1 is involved in proinsulin binding.

Arginine releases proinsulin from binding to UGGT1 in the endoplasmic reticulum (ER). PSIPRED analysis showed that the arginine/proinsulin binding domain (A/PBD) in the C-terminal region of UGGT1 forms a disordered region, which is flexible and outside of the main protein structure. Both arginine and proinsulin may easily access the disordered region of A/PBD. Using the SNP library, two variants, Q1518∗ and R1526C, were identified in this region. UGGT1Q1518∗ protein is a deficient form of A/PBD and ER-retention signal (ERRS). UGGT1Q1518∗ protein in cell analysis reveals that mutated protein is mainly secreted from the cells because it lacks ERRS. We found another UGGT1 variant, UGGT1R1526C. At the molecular level, less interaction of proinsulin with UGGT1 was observed in both human UGGT1R1526C and mouse UGGT1L1518C with/without arginine. However, UGGT1R1526C and UGGT1WT interact with arginine similarly. We identified several amino acid residues for the arginine and proinsulin interaction. Here, the R1526 residue of UGGT1 is involved in proinsulin-interaction and is not involved in arginine-interaction.

Embryonic Pericytes Promote Microglial Homeostasis and Their Effects on Neural Progenitors in the Developing Cerebral Cortex.

Multifaceted microglial functions in the developing brain, such as promoting the differentiation of neural progenitors and contributing to the positioning and survival of neurons, have been progressively revealed. Although previous studies have noted the relationship between vascular endothelial cells and microglia in the developing brain, little attention has been given to the importance of pericytes, the mural cells surrounding endothelial cells. In this study, we attempted to dissect the role of pericytes in microglial distribution and function in developing mouse brains. Our immunohistochemical analysis showed that approximately half of the microglia attached to capillaries in the cerebral walls. Notably, a magnified observation of the position of microglia, vascular endothelial cells and pericytes demonstrated that microglia were preferentially associated with pericytes that covered 79.8% of the total capillary surface area. Through in vivo pericyte depletion induced by the intraventricular administration of a neutralizing antibody against platelet-derived growth factor receptor (PDGFR)ß (clone APB5), we found that microglial density was markedly decreased compared with that in control antibody-treated brains because of their low proliferative capacity. Moreover, in vitro coculture of isolated CD11b+ microglia and NG2+PDGFRα- cells, which are mostly composed of pericytes, from parenchymal cells indicated that pericytes promote microglial proliferation via the production of soluble factors. Furthermore, pericyte depletion by APB5 treatment resulted in a failure of microglia to promote the differentiation of neural stem cells into intermediate progenitors. Taken together, our findings suggest that pericytes facilitate microglial homeostasis in the developing brains, thereby indirectly supporting microglial effects on neural progenitors.SIGNIFICANCE STATEMENT This study highlights the novel effect of pericytes on microglia in the developing mouse brain. Through multiple analyses using an in vivo pericyte depletion mouse model and an in vitro coculture study of isolated pericytes and microglia from parenchymal cells, we demonstrated that pericytes contribute to microglial proliferation and support microglia in efficiently promoting the differentiation of neural stem cells into intermediate progenitors. Our present data provide evidence that pericytes function not only in the maintenance of cerebral microcirculation and blood brain barrier (BBB) integrity but also in microglial homeostasis in the developing cerebral walls. These findings will expand our knowledge and help elucidate the mechanism of brain development both in healthy and disease conditions.

Chorionic gonadotropin stimulates maternal hepatocyte proliferation during pregnancy.

The liver increases its size during pregnancy to adapt to metabolic demand associated with pregnancy. Our previous study showed that proliferation of maternal hepatocytes are increased during pregnancy in mice and that estradiol (E2) is one of the candidate hormones responsible for maternal hepatocyte proliferation. Here, we discovered that chorionic gonadotropin (CG) induces maternal hepatocyte proliferation during pregnancy. CG administration was sufficient to stimulate hepatocyte proliferation in non-pregnant mice as well as in cell culture system. We conclude that CG stimulates proliferation in the early pregnancy of maternal hepatocytes. In contrast, estrogen stimulates hepatocyte proliferation in the late pregnancy.

Transient microglial absence assists postmigratory cortical neurons in proper differentiation.

In the developing cortex, postmigratory neurons accumulate in the cortical plate (CP) to properly differentiate consolidating subtype identities. Microglia, despite their extensive surveying activity, temporarily disappear from the midembryonic CP. However, the mechanism and significance of this absence are unknown. Here, we show that microglia bidirectionally migrate via attraction by CXCL12 released from the meninges and subventricular zone and thereby exit the midembryonic CP. Upon nonphysiological excessive exposure to microglia in vivo or in vitro, young postmigratory and in vitro-grown CP neurons showed abnormal differentiation with disturbed expression of the subtype-associated transcription factors and genes implicated in functional neuronal maturation. Notably, this effect is primarily attributed to interleukin 6 and type I interferon secreted by microglia. These results suggest that "sanctuarization" from microglia in the midembryonic CP is required for neurons to appropriately fine-tune the expression of molecules needed for proper differentiation, thus securing the establishment of functional cortical circuit.

Estradiol accelerates liver regeneration through estrogen receptor α.

Background: We previously demonstrated that liver resection triggers estradiol production, which, in turn, induces the proliferation of hepatocytes to promote liver regeneration in mice. In this study, we demonstrated estradiol-induced estrogen receptor alpha (ERα) expression. Methods: To further explore the role of ERα in estradiol-mediated liver regeneration, in the present study, we confirmed impaired liver regeneration ability in ERα knockout mice. Results: Further analysis during liver regeneration revealed a role for ERα in hepatic steatosis, tumor necrosis factor-alpha and interleukin 6 expression, and nuclear factor-κB and signal transducer and activator of transcription 3 DNA-binding activities. Conclusion: Moreover, estradiol administration accelerated liver regeneration through ERα, indicating the feasibility of the estrogen-ERα axis as a target for accelerating the rate of liver regeneration.

Arginine induces IGF-1 secretion from the endoplasmic reticulum.

Arginine is a semi-essential amino acid with multiple functions, including stimulating the secretion of growth hormone (GH) and insulin-like growth factor 1 (IGF-1). IGF-1, which is produced by hepatocytes, plays important roles in cellular metabolism, proliferation, and growth. Previous studies showed that arginine-induced IGF-1 secretion occurs via two pathways: a GH-dependent pathway and an arginine-dependent pathway with an unknown mechanism. In this study, we identified the mechanisms regulating IGF-1 secretion. First, GH stimulates the translation of IGF-1 and increases IGF-1 protein levels, leading to IGF-1 secretion. As observed in fasted mice and hepatocytes cultivated in arginine-depleted medium, decreases in arginine concentrations resulted in IGF-1 retention in the endoplasmic reticulum. Arginine administration reverses this retention, leading to IGF-1 secretion. These data describe a novel IGF-1 secretion control system in the endoplasmic reticulum.

Estrogen induces estrogen receptor α expression and hepatocyte proliferation in late pregnancy.

Partial hepatectomy (PH) induces estradiol production, and then hepatocyte proliferation. Estradiol may play a role in triggering hepatocyte proliferation after PH. In this study, estradiol was injected to the Estrogen Receptor alpha (ERα) or ERß KO mice. No increased hepatocyte proliferation was observed in ERα KO mice, indicates that ERα is involved in estradiol-induced hepatocyte proliferation. The ERα and ERß KO mice are sterile, hence it is impossible to study ERα and ERß function during pregnancy when the estrogen levels are highest. Using conditional mutagenesis technique, we made ERα hepatocyte KO mice, which are fertile. We used these mice for analyzing the hepatocyte ERα function during pregnancy. However, in the control mice, the maternal hepatocyte was proliferated higher in late pregnancy, but no pregnancy-induced hepatocyte proliferation was observed in KO mice. Hence, we conclude that the maternal hepatocyte ERα is involved in estradiol-induced hepatocyte proliferation in late pregnancy.

Apoptosis inhibitor of macrophage protein enhances intraluminal debris clearance and ameliorates acute kidney injury in mice.

Acute kidney injury (AKI) is associated with prolonged hospitalization and high mortality, and it predisposes individuals to chronic kidney disease. To date, no effective AKI treatments have been established. Here we show that the apoptosis inhibitor of macrophage (AIM) protein on intraluminal debris interacts with kidney injury molecule (KIM)-1 and promotes recovery from AKI. During AKI, the concentration of AIM increases in the urine, and AIM accumulates on necrotic cell debris within the kidney proximal tubules. The AIM present in this cellular debris binds to KIM-1, which is expressed on injured tubular epithelial cells, and enhances the phagocytic removal of the debris by the epithelial cells, thus contributing to kidney tissue repair. When subjected to ischemia-reperfusion (IR)-induced AKI, AIM-deficient mice exhibited abrogated debris clearance and persistent renal inflammation, resulting in higher mortality than wild-type (WT) mice due to progressive renal dysfunction. Treatment of mice with IR-induced AKI using recombinant AIM resulted in the removal of the debris, thereby ameliorating renal pathology. We observed this effect in both AIM-deficient and WT mice, but not in KIM-1-deficient mice. Our findings provide a basis for the development of potentially novel therapies for AKI.

Critical role of interferon-α constitutively produced in human hepatocytes in response to RNA virus infection.

Several viruses are known to infect human liver and cause the hepatitis, but the interferon (IFN) response, a first-line defense against viral infection, of virus-infected hepatocytes is not clearly defined yet. We investigated innate immune system against RNA viral infection in immortalized human hepatocytes (HuS-E/2 cells), as the cells showed similar early innate immune responses to primary human hepatocytes (PHH). The low-level constitutive expression of IFN-α1 gene, but not IFN-ß and IFN-λ, was observed in both PHH and HuS-E/2 cells in the absence of viral infection, suggesting a particular subtype(s) of IFN-α is constitutively produced in human hepatocytes. To examine the functional role of such IFN-α in the antiviral response, the expression profiles of innate immune-related genes were studied in the cells with the treatment of neutralization against type I IFN receptor 2 (IFNAR2) or IFN-α itself to inhibit the constitutive IFN-α signaling before and after virus infection. As the results, a clear reduction of basal level expression of IFN-inducible genes was observed in uninfected cells. When the effect of the inhibition on the cells infected with hepatitis C virus (HCV) was examined, the significant decrease of IFN stimulated gene expression and the enhancement of initial HCV replication were observed, suggesting that the steady-state production of IFN-α plays a role in amplification of antiviral responses to control the spread of RNA viral infection in human hepatocytes.