Involvement of CB2 signalling pathway in the development of osteoporosis by regulating the proliferation and differentiation of hBMSCs.

The aim of the present study was to explore the potential mechanism underlying the involvement of CB2 in osteoporosis. Micro-CT was utilized to examine femur bone architecture. Also, real-time PCR and Western blot analysis were utilized to detect the effect of 2-AG on the expression of CB2 and Notch, or the interaction between CB2 and Notch 2. 2-AG treatment up-regulated BMD, Tb.Sp and SMI in OVX mice, whereas proportion of bone volume in total volume (BV/TV), trabecular thickness (Tb.Th), trabecular number (Tb.N) and bone mineral density (BMD) were decreased in 2-AG-treated OVX mice. Accordingly, 2-AG administration up-regulated Notch 1 expression in OVX mice but had no effect on CB2 and Notch 2 expression. Meanwhile, 2-AG administration promoted the differentiation of hBMSCs in OVX mice, while exhibiting no effect on the proliferation of hBMSCs. Furthermore, in the cellular models, 2-AG treatment also up-regulated Notch 1 expression but had no effect on CB2 and Notch 2 expression, while Notch 1 shRNA had no effect on CB2 and Notch 2 expression. 2-AG promoted cell proliferation and differentiation, which were inhibited by Notch 1 shRNA. NICD had no effect on CB2 level but increased Notch 1 expression, and CB2 shRNA decreased CB2 and Notch 1 expression. Finally, CB2 shRNA inhibited cell proliferation and differentiation, whereas NICD promoted proliferation and differentiation of hBMSCs. Our results provided further evidence for the association of CB2 gene with BMD and osteoporosis, and identified CB2 as a promising target for the treatment of osteoporosis.

[Xylazine Produced Analgesic Effect via Inhibits Hyperpolarization-activated Cyclic Nucleotide-gated Ion Channels Currents].

OBJECTIVE: To investigate the analgesic mechanism of xylazine by inhibiting the activation of hyperpolarized cyclic nucleotide-gated (HCN) ion channels. METHODS: HCN subchannel 1 (HCN1) knockout mice (HCN1-/-) and HCN1 wild type mice (HCN1+/+) were intraperitoneally injected with physiological saline and xylazine (10, 20, 30, and 40 mg/kg). Mechanical pain test and tail flick test were used to test the analgesic effect of xylazine by using the percentage of the maximal possible effect (%MPE); The control group and test groups of different concentrations of xylazine (12.5, 25, 50, and 100 µmol/L) were set up using HEK 293 cells transfected HCN1 plasmid and HCN subchannel 2 (HCN2) plasmid, respectively. The activated current of hyperpolarized HEK 293 cells expressing HCN1 and HCN2 ion channels and the inhibition rate of xylazine on hyperpolarization-activated currents were recorded using a whole cell patch clamp. RESULTS: The results demonstrated that %MPE of the mechanical pain stimuli test and the thermal radiation stimuli test increased with the higher concentration of xylazine injected for both HCN1+/+ mice and HCN1-/-mice. When injecting xylazine by 30 mg/kg and 40 mg/kg, the %MPE of mechanical pain stimuli test for HCN1-/- mice were %MPE= (62.06±14.72) % and %MPE= (69.92±16.09) %, respectively; and the percentages of tail flick tests were (52.50±1.97) % and %MPE= (64.74±6.34) %, respectively. But for HCN1+/+ mice, the percentages of mechanical pain stimuli test were %MPE= (75.47±8.06) % and %MPE= (86.35±11.31) %; respectively, and the percentage of tail flick tests were %MPE= (57.83±4.82) % and (74.98±9.35) %. The analgesic effect results of the mechanical pain test and tail flick test of HCN1+/+ mice were significantly different from HCN1-/- mice ( P<0.05). Whole-cell patch clamp test results showed that xylazine had inhibitory effects on the currents of HCN1 and HCN2 ion channels, and the hyperpolarization-activated currents inhibition rate of HCN1 by xylazine (12.5-100 µmol/L) was between (24.62±23.62) %- (62.40±15.48) %; V1/2 of HCN1 was between (-79.58±1.56) mV- (-98.95±3.57) mV. The Ih inhibition rate of HCN2 by xylazine (12.5-100 µmol/L) was between (29.19±17.82) %- (80.02±6.64) %; with V1/2 of HCN2 between (-102.17±1.36) mV- (-117.48±2.38) mV. CONCLUSION: Xylazine showed better analgesic effect on HCN1+/+ mice than HCN1-/- mice. Xylazine can produce analgesic effect by inhibiting HCN ion channel currents.

Highly Efficient Carbon Monoxide Capture by Carbanion-Functionalized Ionic Liquids through C-Site Interactions.

A novel method for the highly efficient and reversible capture of CO in carbanion-functionalized ionic liquids (ILs) by a C-site interaction is reported. Because of its supernucleophilicity, the carbanion in ILs could absorb CO efficiently. As a result, a relatively high absorption capacity for CO (up to 0.046 mol mol-1 ) was achieved under ambient conditions, compared with CO solubility in a commonly used IL [Bmim][Tf2 N] (2×10-3  mol mol-1 ). The results of quantum mechanical calculations and spectroscopic investigation confirmed that the chemical interaction between the C-site in the carbanion and CO resulted in the superior CO absorption capacities. Furthermore, the subsequent conversion of captured CO into valuable chemicals with good reactivity was also realized through the alkoxycarbonylation reaction under mild conditions. Highly efficient CO absorption by carbanion-functionalized ILs provides a new way of separating and converting CO.

[Spatial and Temporal Distribution of Chlorophyll a and Its Relationship to Algae and Environmental Factors in Aha Reservoir].

As one of the drinking water sources for Guiyang City in southwest China, the Aha Reservoir has an area of 190 km2 and a volume of 5.42×108 m3. The water depth is less than 30 m, with an average depth of 13 m. Regulated by subtropical humid monsoon climate, it has cool summers and warm winters, with an annual mean air temperature of about 15.3℃ and an annual normal rainfall of approximately 1,129 mm. Impacted heavily by human activity (e.g., untreated industrial and domestic sewage and agricultural non-point pollution sources), the eutrophication problem in the Aha Reservoir has become more serious each year. In order to explore the spatial and temporal distribution characteristics of chlorophyll a (Chl-a) and its relationship to algae and the driving factors in the Aha Reservoir, phytoplankton and water samples were collected in the dry period, normal period, and flood period. The results showed a significant seasonal variation in Chl-a, same as biomass, but not the same as the algal abundance. Highest Chl-a concentration (91 µg·L-1) occurred in the mean season with the dinoflagellate bloom but during dry and wet seasons, they were only 8 µg·L-1 and 16 µg·L-1, respectively. During the dry and flood periods, the Chl-a concentrations in surface waters were slightly higher than the other layers caused by sufficient light and dissolved oxygen. But in the normal period, the Chl-a concentrations in surface waters were far higher than the other layers because of the dinoflagellate bloom assembling in surface waters. Located at the reservoir entrance of Jinzhong River, Dam sampling point owned higher Chl-a concentration than Kuzhong as a result of higher nutrients. Correlation analysis indicated that Dinoflagellate was positively correlated with Chl-a (R=0.798, P<0.01). Chl-a was positively associated with total phosphorus, dissolved oxygen, pH value, and total nitrogen (R=0.762, P<0.01; R=0.792, P<0.01; R=0.658, P<0.01; R=0.388, P<0.05) and it had a negative correlation with the N/P ratio and nitrate nitrogen (R=-0.37, P<0.05; R=-0.435, P<0.05). Stepwise regression analysis showed that TP, N/P ratio, and DO were the most important factors influencing the temporal and spatial distribution of Chl-a. Thermal stratification and water temperature were also the significant factors that could not be ignored.

Multi-Molar Absorption of CO2 by the Activation of Carboxylate Groups in Amino Acid Ionic Liquids.

A new strategy for multi-molar absorption of CO2 is reported based on activating a carboxylate group in amino acid ionic liquids. It was illustrated that introducing an electron-withdrawing site to amino acid anions could reduce the negative inductive effect of the amino group while simultaneously activating the carboxylate group to interact with CO2 very efficiently. An extremely high absorption capacity of CO2 (up to 1.69 mol mol(-1) ) in aminopolycarboxylate-based amino acid ionic liquids was thus achieved. The evidence of spectroscopic investigations and quantum-chemical calculations confirmed the interactions between two kinds of sites in the anion and CO2 that resulted in superior CO2 capacities.

[Inhibition of HCN1 channels by ketamine accounts for its antidepressant actions].

OBJECTIVE: To investigate the roles of hyperolarization-actived cyclic nucleotide-gated channels 1 (HCN1) in antidepressant actions of ketamine (KET). METHODS: Male HCN1 knock out (HCN1-/- ) and wildtype (HCN1+/+ ) C57BL6 mice (8-12 weeks, 20-25 g) were chosen. The depression model of mice was developed by continuously oral administration of low dosage of corticosterone (CORT). The immobility time in forced swimming tests (FST) was used to assess the depressive state of mice. Then the two genotype depressive mice were treated with single intraperitoneal injection of 5 mg/kg ketamine (KET group, n=7) or same volume of normal saline (NS group, n=7) respectively. After treatment, the immobility time at 30 min, 24 h and 7 d after the intraperitoneal injection of ketamine or normal saline in CORT-treated mice were compared. In addition, normal HCN1-/- and HCN1+/+ mice were intraperitoneally injected of BrdU and then treated with 5 mg/kg ketamine (KET group, n=5) or same volume of normal saline (NS group, n= 5) by single intraperitoneal injection. Each group was euthanized for immunohistochemical processing of 5-Bromo-2-deoxyuridine (BrdU)-labeled cells in hippocampus at 24 h after the intraperitoneal injection of saline or ketamine. RESULTS: The immobility time in FST of HCN1-/- mice was less than the HCN1+/+ mice before administration of CORT. It shows that the depressive state of HCN1-/- mice is less intensive than that of HCN1+/+ mice. And the immoblility time in both HCN1-/- and HCN1+/+ mice was increased after oral administration of low dose corticosterone, with an increase in depression. In addition, the comparisons were also made to the reduction of immobility time within 30 min, 24 h and 7 d. At any time point, the reduction of immobility time in HCN1+/+ KET group was higher than those in the other three groups (P<0. 05). Furthermore, there were no statistical significances among the three groups including HCN1-/- KET group, HCN1+/+ NS group, HCN1-/- NS group at any point. The number of newborn neurons were more in HCN1 mice than HCN1+/+ mice after the treatment of normal saline. Compared with the NS group, the number of neonatal neurons labeled by BrdU were increased after the intraperitoneal injection of ketamine in HCN1+/+ mice but not in HCN1-/- mice. CONCLUSION: Inhibition of HCN1 channels by ketamine accounts for its antidepressant actions.