Human Menstrual Blood-Derived Stromal Cells Promote Recovery of Premature Ovarian Insufficiency Via Regulating the ECM-Dependent FAK/AKT Signaling.

POI is characterized by "absent not abnormal" menstruation with hormonal disorders in woman younger than 40 years of age, and etiological and pathophysiological mechanisms underlying the POI development have not been clearly defined. Recently, due to advantages such as abundant sources and non-invasive methods of harvest, MenSCs have been emerging as a promising treatment strategy for the recovery of female reproductive damage. Here, we demonstrated that MenSCs graft in POI mice after CTX treatment could restore ovarian function by regulating normal follicle development and estrous cycle, reducing apoptosis in ovaries to maintain homeostasis of microenvironment and modulating serum sex hormones to a relatively normal status. Moreover, MenSCs participated in the activation of ovarian transcriptional expression in ECM-dependent FAK/AKT signaling pathway and thus restored ovarian function to a certain extent. MenSCs transplantation was proved to be an effective way to repair ovarian function with low immunogenicity, suggesting its great potential for POI treatment.

Attenuation of autophagy impacts on muscle fibre development, starvation induced stress and fibre regeneration following acute injury.

Autophagy has been implicated as a major factor in the development of a number of diseases of skeletal muscle. However, its role in skeletal muscle homeostasis is still evolving. We examined skeletal muscle architecture in a mouse model, Atg16L1, where autophagy is attenuated but importantly still present. We show that muscle fibres from Atg16L1 mice were smaller than wild-type counterparts, proving a role for this process in the growth of these cells. We show that mild attenuation of autophagy results in accelerated muscle loss during the initial phase of acute starvation. Furthermore, we show that regeneration of skeletal muscle following cardiotoxin (CTX) mediated injury is slower in the Atg16L1 mouse compared to wild-type. Lastly, we show that autophagy controls the integrity of the sarcolemma. Attenuated autophagy makes muscle fibres more susceptible to infiltration by circulating immunoglobulins following muscle injury with CTX. These fibres internalise dystrophin and nNOS. Importantly these fibres are able to restore dystrophin and nNOS localisation and do not die. In conclusion, these studies shed new light into the ability of skeletal muscle fibres to cope with injury and establish a link between the fine-tuning of autophagy and skeletal muscle regeneration.

Characterization of the σ-Pore in Mutant hKv1.3 Potassium Channels.

BACKGROUND/AIMS: The replacement of the amino acid valine at position 388 (Shaker position 438) in hKv1.3 channels or at the homologue position 370 in hKv1.2 channels resulted in a channel with two different ion conducting pathways: One pathway was the central, potassium-selective α-pore, that was sensitive to block by peptide toxins (CTX or KTX in the hKv1.3_V388C channel and CTX or MTX in the hKv1.2_V370C channel). The other pathway (σ-pore) was behind the central α-pore creating an inward current at potentials more negative than -100 mV, a potential range where the central α-pore was closed. In addition, current through the σ-pore could not be reduced by CTX, KTX or MTX in the hKv1.3_V388C or the hKv1.2_V370C channel, respectively. METHODS: For a more detailed characterization of the σ-pore, we created a trimer consisting of three hKv1.3_V388C α-subunits linked together and characterized current through this trimeric hKv1.3_V388C channel. Additionally, we determined which amino acids line the σ-pore in the tetrameric hKv1.3_V388C channel by replacing single amino acids in the tetrameric hKv1.3_V388C mutant channel that could be involved in σ-pore formation. RESULTS: Overexpression of the trimeric hKv1.3_V388C channel in COS-7 cells yielded typical σ-pore currents at potentials more negative than -100 mV similar to what was observed for the tetrameric hKv1.3_V388C channel. Electrophysiological properties of the trimeric and tetrameric channel were similar: currents could be observed at potentials more negative than -100 mV, were not carried by protons or chloride ions, and could not be reduced by peptide toxins (CTX, MTX) or TEA. The σ-pore was mostly permeable to Na+ and Li+. In addition, in our site-directed mutagenesis experiments, we created a number of new double mutant channels in the tetrameric hKv1.3_V388C background channel. Two of these tetrameric double mutant channels (hKv1.3_V388C_T392Y and hKv1.3_V388C_Y395W) did not show currents through the σ-pore. CONCLUSIONS: From our experiments with the trimeric hKv1.3_V388C channel we conclude that the σ-pore exists in hKv1.3_V388C channels independently of the α-pore. From our site-directed mutagenesis experiments in the tetrameric hKv1.3_V388C channel we conclude that amino acid position 392 and 395 (Shaker position 442 and 445) line the σ-pore.

Aphicidal efficacy of scorpion- and spider-derived neurotoxins.

Insect-specific neurotoxins that act within the insect hemocoel (body cavity) represent an untapped resource for insect pest management. On the basis of recent advances made in development of appropriate delivery systems for transport of these toxins from the insect gut, across the gut epithelium to their target site, we screened neurotoxins derived from scorpion or spider venom for efficacy against the pea aphid, Acyrthosiphon pisum, and the green peach aphid, Myzus persicae. Toxins were selected to represent different modes of electrophysiological action, including activity on voltage-gated calcium channels (ω-TRTX-Gr1a, ω-agatoxin Aa4a, ω-hexatoxin-Hv1a), calcium- and voltage-activated potassium channels (charybdotoxin, maurotoxin), chloride channels (chlorotoxin) and voltage-gated sodium channels (LqhαIT). The Bacillus thuringiensis-derived toxin Cyt1Aa was also tested as a positive control for toxicity. In per os bioassays with both aphid species, toxicity was only seen for ω-TRTX-Gr1a and Cyt1Aa. On injection into the hemocoel of A. pisum, LD50 values ranged from 1 to 8 ng/mg body weight, with ω-hexatoxin-Hv1a being the most toxic (1.02 ng/mg body weight). All neurotoxins caused rapid paralysis, with charybdotoxin, maurotoxin and chlorotoxin also causing melanization of injected aphids. These data represent the first comprehensive screen of neurotoxins against aphids, and highlight the potential for practical use of the insect-specific toxin ω-hexatoxin-Hv1a in aphid management.

Induction of GNE in myofibers after muscle injury.

OBJECTIVE: The aim of the present study was to clarify the expression of uridine diphospho-N-acetylglucosamine 2-epimerase/N-acetylmannosamine kinase (GNE) protein and mRNA in damaged or regenerating myofibers. METHODS: We investigated the muscle expression pattern of GNE protein by immunohistochemistry using a murine model involving intramuscular injection of cardiotoxin (CTX), and the expression level of GNE mRNA by quantitative real-time polymerase chain reaction analysis of damaged or regenerating myofibers that had been collected directly from tissue sections using laser-capture microdissection. RESULTS: The expression of GNE protein was increased in severely damaged myofibers as well as in regenerating myofibers with central nuclei, both of which also showed an increase in the expression of GNE mRNA. In regenerating myofibers, immunoreactivity for GNE protein in nuclei relative to that in the cytoplasm was higher at 7 days than at 4 days after CTX injection. CONCLUSION: Our findings suggest that GNE expression is induced when myofibers are damaged or regenerating, and that GNE plays a role in muscle regeneration.

Revealing the molecular determinants of neurotoxin specificity for calcium-activated versus voltage-dependent potassium channels.

Potassium channel dysfunction underlies diseases such as epilepsy, hypertension, cardiac arrhythmias, and multiple sclerosis. Neurotoxins that selectively inhibit potassium channels, alpha-KTx, have provided invaluable information for dissecting the contribution of different potassium channels to neurotransmission, vasoconstriction, and lymphocyte proliferation. Thus, alpha-KTx specificity comprises an important first step in potassium channel-directed drug discovery for these diseases. Despite extensive functional and structural studies of alpha-KTx-potassium channel complexes, none have predicted the molecular basis of alpha-KTx specificity. Here we show that by minimizing the differences in binding free energy between selective and nonselective alpha-KTx we are able to identify all of the determinants of alpha-KTx specificity for calcium-activated versus voltage-dependent potassium channels. Because these determinants correspond to unique features of the two types of channels, they provide a way to develop more accurate models of alpha-KTx-potassium channel complexes that can be used to design novel selective alpha-KTx inhibitors.

Reciprocal effects of glucose on the process of cell death induced by calcium ionophore or H2O2 in rat lymphocytes.

We have examined the effects of glucose at high concentrations on the process of cell death induced by excessive increase in intracellular Ca(2+) concentration ([Ca(2+)](i)) or oxidative stress in rat lymphocytes. The cell death elicited by the excessive increase in [Ca(2+)](i) seemed to be induced by an activation of Ca(2+)-dependent K(+) channels because the inhibitors for Ca(2+)-dependent K(+) channels attenuated the decrease in cell viability. Glucose at 30-50mM augmented the decrease in cell viability by the excessive increase in [Ca(2+)](i). It was not specific for glucose because it was the case for sucrose or NaCl, suggesting an involvement of increased osmolarity in adverse action of glucose. On the contrary, glucose protected the cells suffering from oxidative stress induced by H(2)O(2), one of reactive oxygen species. It was also the case for fructose or sucrose, but not for NaCl. The process of cell death induced by H(2)O(2) started, being independent from the presence of glucose. Glucose delayed the process of cell death induced by H(2)O(2). Sucrose and fructose also protected the cells against oxidative stress. The reactivity of sucrose to reactive oxygen species is lower than those of glucose and fructose. The order in the reactivity cannot explain the protective action of glucose. Glucose at high concentrations exerts reciprocal actions on the process of cell death induced by the oxidative stress and excessive increase in [Ca(2+)](i).

Characterization of the voltage-activated currents in cultured atrial myocytes isolated from the heart of the common oyster Crassostrea gigas.

Using the macro-patch clamp technique, we show that cardiac myocytes isolated from the heart of the oyster Crassostrea gigas possess several types of voltage-activated ionic currents. (1) A classical non-inactivating potassium current of the IK type that is inhibited by tetraethyl ammonium and shows an outward rectification and a slow activation. (2) A potassium current of the IA type that shows rapid activation and inactivation, and is blocked by 4-amino pyridine or preliminary depolarisation. (3) A potassium calcium-dependent current that is inhibited by charybdotoxin, activated by strong depolarisations and shows a large conductance. (4) A calcium inward current of the L-type that is inhibited by verapamil, cobalt and high concentrations of cadmium. This current is identified in most cells, but a T-type calcium current and classical fast sodium current are only identified in few cells, and only after a strong hyperpolarizing pulse. This suggests that these channels are normally inactivated in cultured cells and are not involved in the spontaneous activity of these cells. When they exist, the fast sodium channel is blocked by tetrodotoxin. The L-type calcium conductance is increased by serotonin. The identification in cultured oyster atrial cells of classical ionic currents, which are observed in most vertebrate species but only in a few species of molluscs, demonstrates that these cells are an interesting model. Moreover the viability and the electrophysiological properties of these cells are not significantly modified by freezing and thawing, thus increasing their usefulness in various bioassays.

Outwardly rectifying currents in guinea pig outer hair cells.

Studies of K+ conductances in hair cells report that big-conductance Ca(2+)-dependent K+ (BK) channels carry parts of the outwardly rectifying currents. Lin et al. (1995) suggested that in guinea pig outer hair cells (OHCs) a portion of these currents is carried via a voltage-dependent and Ca(2+)-independent K+ channel. The present study tests the hypothesis that there are two separable current components of the outwardly rectifying currents by using patch clamp methods in OHCs to characterize the voltage dependence and sensitivity of the outwardly rectifying currents to channel blockers. Lowering of external Ca2+ caused no change in the currents while charybdotoxin (ChTx; 100 nM), a BK K+ channel blocker, and Cd2+ (200 microM), and L-type calcium channel blocker, abolished about 50% of the currents. Both ChTx and Cd2+ caused a depolarizing shift in the half-activation voltage paralleled by a decrease in the voltage sensitivity. 4-Aminopyridine (4-AP, 0.01 mM), an A-type and delayed rectifier type channel blocker, abolished about 50% of the currents and caused a hyperpolarizing shift in the half-activation voltage together with an increase in the voltage sensitivity. The outwardly rectifying currents were more sensitive to block by 4-AP at membrane voltages around 40 mV compared to voltages around -20 mV. The differences in the current characteristics may be due to two separate channel types, one of which is similar to the delayed rectifier type channels while the other may be similar to the BK Ca(2+)-dependent K+ channels. In addition, the largest outwardly rectifying currents were present in long OHCs with the smallest present in short OHCs.

Electrical activity of the sensory afferent pathway in the enteric nervous system.

In this paper we develop a mathematical model for the electrical activity of the afferent pathway, formed from the coupled primary and secondary sensory neurons. The primary sensory neuron possesses the electrical properties of AH neurons and morphological characteristics of Dogiel type II neurons; the secondary sensory neuron displays the tonic type of electrical behavior and has morphological features of Dogiel type III neurons. Free nerve endings of the mechanoreceptor form the receptive field of the pathway. Based on the general principles of the Hodgkin-Huxley description of excitable cells, the model simulates the following sequence of events: stretch of the receptive field initiates the dendritic potential at the mechanoreceptors; the excitation causes soma action potential development at the primary sensory neuron which is followed by soma action potential generation at the secondary sensory neuron. Numerical calculation have shown that the model is capable of reproducing different electrical patterns within the pathway under normal physiological conditions and after treatment with charybdotoxin, iberiotoxin, tetrodotoxin, omega-conotoxin GVIA, A1-A2 purinoceptor agonists, a protein kinase C activator, and a delta-opioid receptor agonist. Comparison of the computational results with the results of experiments conducted on the neurons of the submucous and myenteric plexi of the small bowel demonstrates their good qualitative and quantitative agreement.

Acetylcholine response in guinea pig outer hair cells. II. Activation of a small conductance Ca(2+)-activated K+ channel.

The type of K+ channel involved in the acetylcholine (ACh) evoked response (Ksub; sub stands for suberyldicholine) in guinea pig outer hair cells (OHCs) is still uncertain. The present study tests the hypotheses that Ksub is one of the following: a big conductance Ca(2+)-dependent K+ channel (BK), a small conductance Ca(2+)-dependent K+ channel (SK), a KA type of K+ channel, or a Kn type of K+ channel. Patch-clamp technique in the whole-cell mode was used to record from single guinea pig OHCs. ACh (100 microM) was applied to voltage-clamped OHCs and the ACh-induced currents (IACh) were measured. Charybdotoxin (100 nM) had no effect on IACh, while apamin (1 microM) blocked more than 90% of IACh. Lowering the external Ca2+ concentration caused a hyperpolarizing shift of the IACh monitored as a function of the prepulse voltage. Increasing internal Mg2+ (Mgi2+) concentration caused a reduction in the outward IACh without affecting the inward IACh. The Ksub channel was found to be permeable to Cs+. In Cs+ solutions, IACh was 45% of the IACh in K+ solutions. The block of IACh by apamin, the dependence on extracellular Ca2+, the incomplete block of IACh by Cs+, and the ACh-induced Cs+ currents favor the hypothesis that Ksub belongs to the SK type of channels. An ionotropic/nicotinic nature of the ACh mechanism of action is favored. It is suggested that, in vivo, the amplitude of the ACh-induced hyperpolarization may depend on the Ca2+/Mg2+ ratio inside and outside the cell.

Ca(2+)-activated K+ channels of human and rabbit erythrocytes display distinctive patterns of inhibition by venom peptide toxins.

Despite recent progress in the molecular characterization of high-conductance Ca(2+)-activated K+ (maxi-K) channels, the molecular identities of intermediate conductance Ca(2+)-activated K+ channels, including that of mature erythrocytes, remains unknown. We have used various peptide toxins to characterize the intermediate conductance Ca(2+)-activated K+ channels (Gardos pathway) of human and rabbit red cells. With studies on K+ transport and on binding of 125I-charybdotoxin (ChTX) and 125I-kaliotoxin (KTX) binding in red cells, we provide evidence for the distinct nature of the red cell Gardos channel among described Ca(2+)-activated K+ channels based on (i) the characteristic inhibition and binding patterns produced by ChTX analogues, iberiotoxin (IbTX) and IbTX-like ChTX mutants, and KTX (1-37 and 1-38 variants); (ii) the presence of some properties heretofore attributed only to voltage-gated channels, including inhibition of K transport by margatoxin (MgTX) and by stichodactyla toxin (StK); (iii) and the ability of scyllatoxin (ScyTX) and apamin to displace bound 125I-charybdotoxin, a novel property for K+ channels. These unusual pharmacological characteristics suggest a unique structure for the red cell Gardos channel.