Effects of estradiol-17beta and progesterone supplementation on in vitro nuclear maturation of canine oocytes

Unlike in other domestic animals, in vitro maturation (IVM) of canine oocytes has had limited success. The present study investigated the effect of the estrous cycle and estradiol-17beta (E2) or progesterone (P4) supplementation on in vitro nuclear maturation of canine oocytes recovered from domestic dog ovaries in various reproductive states (follicular, luteal or anestrous stages). Oocytes were cultured in serum-free tissue culture medium (TCM)-199 supplemented with various concentrations of E2 (Exp. 1: 0, 0.1, 1.0 or 2.0 microg/ml) or P4 (Exp. 2; 0, 0.5, 1.0 or 2.0 microg/ml) for 72 h to determine the effective concentration of hormones. In Exp. 3, in order to investigate the synergistic effect of E2 and P4 supplementation, three groups of oocytes were cultured with 2 microg/ml E2 plus various concentrations of P4 (0, 0.5, 1.0 or 2.0 microg/ml). As results, the rate of maturation to metaphase II (MII) stage was significantly higher (P < 0.05) in oocytes from the follicular stage supplemented with 2 microg/ml E2 (14.7%) compared to the other groups (1.5-8.2%). Significantly higher (P < 0.05) maturation rate to MII stage was observed in oocytes from the follicular stage supplemented with 1.0 (10.0%) or 2.0 microg/ml (10.8%) P4 compared to the other groups (0-4.8%). Furthermore, more (P < 0.05) oocytes from the follicular stage supplemented with 2.0 microg/ml of E2 and P4 (16.6%) were matured to MII stage compared to oocytes from the follicular stage supplemented with 2.0 microg/ml E2 alone (10.4%) or the other groups of oocytes (0-7.8%). Interestingly, compared to 2.0 microg/ml E2 alone (10.4%), supplementation of 2 microg/ml E2 + 0.5 microg/ml P4 (3.4%) decreased the maturation of oocytes from the follicular stage to MII stage. In conclusion, the present study demonstrated that supplementation of the culture medium with E2 or P4 alone significantly increased maturation of canine oocyte to MII and that P4 supplementation with E2 further promote or decrease oocyte maturation compared to E2 alone depending on P4 concentration.     

Intracellular messenger function of hydrogen peroxide and its regulation by peroxiredoxins

Hydrogen peroxide (H2O2) accumulates transiently in various cell types stimulated with peptide growth factors and participates in receptor signaling by oxidizing the essential cysteine residues of protein tyrosine phosphatases and the lipid phosphatase PTEN. The reversible inactivation of these phosphatases by H2O2 is likely required to prevent futile cycles of phosphorylation-dephosphorylation of proteins and phosphoinositides. The accumulation of H2O2 is possible even in the presence of large amounts of the antioxidant enzymes peroxiredoxin I and II in the cytosol, probably because of a built-in mechanism of peroxiredoxin inactivation that is mediated by H2O2 and reversed by an ATP-dependent reduction reaction catalyzed by sulfiredoxin.     

Annexin A3 is a potential angiogenic mediator

Angiogenesis is a complex process that is regulated by a variety of angiogenic activators and inhibitors. Disruption of the balanced angiogenesis leads to the progress of diseases such as tumor growth, rheumatoid arthritis, and various blood vessel-related disorders. Even though a number of proteins involved in angiogenesis have been identified so far, more protein factors remain to be identified due to complexity of the process. Here we report that annexin A3 (ANXA3) induces migration and tube formation of human umbilical vein endothelial cells. High level of vascular endothelial growth factor (VEGF), a prominent angiogenic factor, is also detected in conditioned medium obtained from cells transfected with ANXA3 expression plasmid. Reporter assays show that ANXA3 enhances hypoxia-inducible factor-1 (HIF-1) transactivation activity. Taken together, our results suggest that ANXA3 is a novel angiogenic factor that induces VEGF production through the HIF-1 pathway.     

Methods for detection and measurement of hydrogen peroxide inside and outside of cells

Hydrogen peroxide (H₂O₂) is an incompletely reduced metabolite of oxygen that has a diverse array of physiological and pathological effects within living cells depending on the extent, timing, and location of its production. Characterization of the cellular functions of H₂O₂ requires measurement of its concentration selectively in the presence of other oxygen metabolites and with spatial and temporal fidelity in live cells. For the measurement of H₂O₂ in biological fluids, several sensitive methods based on horseradish peroxidase and artificial substrates (such as Amplex Red and 3,5,3’5’-tetramethylbenzidine) or on ferrous oxidation in the presence of xylenol orange (FOX) have been developed. For measurement of intracellular H₂O₂, methods based on dihydro compounds such as 2’,7’-dichlorodihydrofluorescein that fluoresce on oxidation are used widely because of their sensitivity and simplicity. However, such probes react with a variety of cellular oxidants including nitric oxide, peroxynitrite, and hypochloride in addition to H₂O₂. Deprotection reaction-based probes (PG1 and PC1) that fluoresce on H₂O₂-specific removal of a boronate group rather than on nonspecific oxidation have recently been developed for selective measurement of H₂O₂ in cells. Furthermore, a new class of organelle-targetable fluorescent probes has been devised by joining PG1 to a substrate of SNAP-tag. Given that SNAP-tag can be genetically targeted to various subcellular organelles, localized accumulation of H₂O₂ can be monitored with the use of SNAP-tag bioconjugation chemistry. However, given that both dihydro- and deprotection-based probes react irreversibly with H₂O₂, they cannot be used to monitor transient changes in H₂O₂ concentration. This drawback has been overcome with the development of redox-sensitive green fluorescent protein (roGFP) probes, which are prepared by the introduction of two redox-sensitive cysteine residues into green fluorescent protein; the oxidation of these residues to form a disulfide results in a conformational change of the protein and altered fluorogenic properties. Such genetically encoded probes react reversibly with H₂O₂ and can be targeted to various compartments of the cell, but they are not selective for H₂O₂ because disulfide formation in roGFP is promoted by various cellular oxidants. A new type of H₂O₂-selective, genetically encoded, and reversible fluorescent probe, named HyPer, was recently prepared by insertion of a circularly permuted yellow fluorescent protein (cpYFP) into the bacterial peroxide sensor protein OxyR.     

Mutagenesis and modeling of the peroxiredoxin (Prx) complex with the NMR structure of ATP-bound human sulfiredoxin implicate aspartate 187 of Prx I as the catalytic residue in ATP hydrolysis

The catalytic cysteine of certain members of the peroxiredoxin (Prx) family can be hyperoxidized to cysteinesulfinic acid during reduction of peroxides. Sulfiredoxin is responsible for the ATP-dependent reduction of cysteinesulfinic acid (SO2H) of hyperoxidized Prx. Here we report the NMR solution structure of human sulfiredoxin (hSrx), both with and without bound ATP, and we model the complex of ATP-bound hSrx with Prx. Binding ATP causes only small changes in the NMR structure of hSrx, and the bound ATP conformation is quite similar to that seen for the previously reported X-ray structure of the ADP-hSrx complex. Although hSrx binds ATP, it does not catalyze hydrolysis by itself and has no catalytic acid residue typical of most ATPase and kinase family proteins. For modeling the complex, the ATP-bound hSrx was docked to hyperoxidized Prx II using EMAP of CHARMM. In the model complex, Asn186 of Prx II (Asp187 of Prx I) is in contact with the hSrx-bound ATP beta- and gamma-phosphate groups. Asp187 of Prx I was mutated to alanine and asparagine, and binding and activity of the mutants with hSrx were compared to those of the wild type. For the D187N mutant, both binding and hydrolysis and reduction activities were comparable to those of the wild type, whereas for D187A, binding was unimpaired but ATP hydrolysis and reduction did not occur. The modeling and mutagenesis analyses strongly implicate Asp187 of Prx I as the catalytic residue responsible for ATP hydrolysis in the cysteinesulfinic acid reduction of Prx by hSrx.     

Non-classical membrane trafficking processes galore

Dogmatic views of how proteins and other cellular components may traffic within and between eukaryotic cells have been challenged in the past few years. Beyond the classical secretory/exocytic pathway and its established players, other pathways of cell surface membrane transport, generally termed “unconventional secretion,” are now better understood. More insights have also been gleaned on the roles of secreted or shedding microvesicles, either exosomal or ectosomal in origin, in unconventional secretion. Recent works have also revealed key molecular components, particularly the Golgi reassembly stacking protein (GRASP), and the importance of stress‐induced autophagy, in unconventional exocytic transport. This GRASP and autophagy‐dependent (GAD) mode appears to underlie the unconventional exocytosis of many soluble and membrane cargoes. Likewise, recent findings have revealed transport processes that contrast the classically known mitochondria import, namely vesicular transport from the mitochondria to peroxisomes and lysosomes. Mitochondria‐peroxisomal targeting of mitochondria‐derived vesicles appears to involve the retromer complex, which was classically associated with endosome‐Golgi membrane traffic. The routes of intracellular membrane transport and communications between eukaryotic organelles now appear far more complex that one would have imagined 10 years ago. J. Cell. Physiol. 227: 3722–3730, 2012. © 2012 Wiley Periodicals, Inc.     

Ascorbic acid deficiency accelerates aging of hepatic stellate cells with up-regulation of PPARγ

Senescent cells have been observed in certain aged or damaged tissues. However, the information about the effects of aging on liver cells is limited. In the present study, we have examined age-related histological changes in the livers of senescence marker protein knockout (SMP30-/-) mice, which are considered as a murine aging model due to the more sensitive response to apoptotic reagents and due to their shorter life span. In livers of old SMP30-/- mice, numerous hepatic stellate cells (HSCs) were hypertrophic and contained abundant microvesicular lipid droplets in cytoplasm. We have found that the expression of peroxisome proliferators-activated receptor γ (PPARγ), which is a protein related to lipid metabolism and HSC quiescence, was increased in hypertrophic HSCs by aging and vitamin C (VC) deficiency, whereas these phenomena were dramatically reduced by antioxidant treatment. Therefore, these prominent phenotypic changes can be considered as aging markers in the livers of animals which are subjected to antioxidant property evaluation.     

Roles of four Arabidopsis u-box e3 ubiquitin ligases in negative regulation of abscisic Acid-mediated drought stress responses

AtPUB18 and AtPUB19 are homologous U-box E3 ubiquitin ligases in Arabidopsis (Arabidopsis thaliana). AtPUB19 is a negative regulator of abscisic acid (ABA)-mediated drought responses, whereas the role of AtPUB18 in drought responses is unknown. Here, loss-of-function and overexpression tests identified AtPUB18 as a negative regulator in ABA-mediated stomatal closure and water stress responses. The atpub18-2atpub19-3 double mutant line displayed more sensitivity to ABA and enhanced drought tolerance than each single mutant plant; therefore, AtPUB18 and AtPUB19 are agonistic. Stomatal closure of the atpub18-2atpub19-3 mutant was hypersensitive to hydrogen peroxide (H(2)O(2)) but not to calcium, suggesting that AtPUB18 and AtPUB19 exert negative effects on the ABA signaling pathway downstream of H(2)O(2) and upstream of calcium. AtPUB22 and AtPUB23 are other U-box E3 negative regulators of drought responses. Although atpub22atpub23 was more tolerant to drought stress relative to wild-type plants, its ABA-mediated stomatal movements were highly similar to those of wild-type plants. The atpub18-2atpub19-3atpub22atpub23 quadruple mutant exhibited enhanced tolerance to drought stress as compared with each atpub18-2atpub19-3 and atpub22atpub23 double mutant progeny; however, its stomatal behavior was almost identical to the atpub18-2atpub19-3 double mutant in the presence of ABA, H(2)O(2), and calcium. Overexpression of AtPUB18 and AtPUB19 in atpub22atpub23 effectively hindered ABA-dependent stomatal closure, but overexpression of AtPUB22 and AtPUB23 in atpub18-2atpub19-3 did not inhibit ABA-enhanced stomatal closure, highlighting their ABA-independent roles. Overall, these results suggest that AtPUB18 has a linked function with AtPUB19, but is independent from AtPUB22 and AtPUB23, in negative regulation of ABA-mediated drought stress responses.     

Altered expression of γ-secretase components in animal model of major depressive disorder induced by reserpine administration

Altered expression of neurotrophic factors as well as neuroinflammation is commonly associated with Major depressive disorder (MDD) and Alzheimer's disease (AD). To investigate whether or not reserpine-induced MDD affects the expression of AD-related proteins, the expression of γ-secretase components and substrate were measured in brains of ICR mice following reserpine treatment for 15 days. In active avoidance test, total response time and peak slightly increased in the 2 mg/kg reserpine (RSP2)-treated group compared to vehicle-treated group (P<0.05). Expression and phosphorylation of MKP-1, which is a key factor in MDD pathology, were both higher in the RSP2-treated group than the vehicle- and 1 mg/kg reserpine (RSP1)-treated groups (P<0.02). Furthermore, full-length expression of amyloid precursor protein (APP) was enhanced in the RSP1 and RSP2-treated groups compared to the vehicle-treated group, whereas expression of γ-secretase components decreased (P<0.03). Among the three components of the γ-secretase complex, nicastrin protein underwent the largest decrease in expression, as detected by Western blotting (P<0.03). Therefore, the data presented here provide additional evidence about the pathological correlation between MDD and AD.