Role of vasopressin V(₁A) receptor in the urethral closure reflex in rats

An enhanced urethral closure reflex via the spinal cord is related to urethral resistance elevation during increased abdominal pressure. However, with the exception of monoamines, neurotransmitters modulating this reflex are not understood. We investigated whether the vasopressin V(?A) receptor (V(?A)R) is involved in the urethral closure reflex in urethane-anesthetized female rats. V(?A)R mRNA was highly expressed among the vasopressin receptor family in the total RNA purified from lamina IX in the spinal cord L6-S1 segment. In situ hybridization analysis of the spinal L6-S1 segment confirmed that these positive signals from the V(?A)Rs were only detected in lamina IX. Intrathecally injected Arg?-vasopressin (AVP), an endogenous ligand, significantly increased urethral resistance during an intravesical pressure rise, and its effect was blocked by the V(?A)R antagonist. AVP did not increase urethral resistance in rats in which the pelvic nerves were transected bilaterally. Urethral closure reflex responses to the intravesical pressure rise increased by up to threefold compared with the baseline response after AVP administration in contrast to no increase by vehicle. In addition, intravenously and intrathecally injected V(?A)R antagonists decreased urethral resistance. These results suggest that V(?A)R stimulation in the spinal cord enhances the urethral closure reflex response, thereby increasing urethral resistance during an abdominal pressure rise and that V(?A)R plays a physiological role in preventing urine leakage.     

Role of proteolytic activation of protein kinase Cδ in the pathogenesis of prion disease

Prion diseases are infectious and inevitably fatal neurodegenerative diseases characterized by prion replication, widespread protein aggregation and spongiform degeneration of major brain regions controlling motor function. Oxidative stress has been implicated in prion-related neuronal degeneration, but the molecular mechanisms underlying prion-induced oxidative damage are not well understood. In this study, we evaluated the role of oxidative stress-sensitive, pro-apoptotic protein kinase Cδ (PKCδ) in prion-induced neuronal cell death using cerebellar organotypic slice cultures (COSC) and mouse models of prion diseases. We found a significant upregulation of PKCδ in RML scrapie-infected COSC, as evidenced by increased levels of both PKCδ protein and its mRNA. We also found an enhanced regulatory phosphorylation of PKCδ at its two regulatory sites, Thr505 in the activation loop and Tyr311 at the caspase-3 cleavage site. The prion infection also induced proteolytic activation of PKCδ in our COSC model. Immunohistochemical analysis of scrapie-infected COSC revealed loss of PKCδ positive Purkinje cells and enhanced astrocyte proliferation. Further examination of PKCδ signaling in the RML scrapie adopted in vivo mouse model showed increased proteolytic cleavage and Tyr 311 phosphorylation of the kinase. Notably, we observed a delayed onset of scrapie-induced motor symptoms in PKCδ knockout (PKCδ^−/−) mice as compared with wild-type (PKCδ^+/+) mice, further substantiating the role of PKCδ in prion disease. Collectively, these data suggest that PKCδ signaling likely plays a role in the neurodegenerative processes associated with prion diseases.     

Adaptive plasticity in the spinal stretch reflex: An accessible substrate of memory?

The study of the substrates of memory in higher vertebrates is one of the major problems of neurobiology. A simple and technically accessible experimental model is needed. Recent studies have demonstrated long-term adaptive plasticity, a form of memory, in the spinal stretch reflex (SSR). The SSR is due largely to a two-neuron monosynaptic arc, the simplest, best-defined, and most accessible pathway in the primate central nervous system (CNS). Monkeys can slowly change SSR amplitude without a change in initial muscle length or alpha motoneuron tone, when reward is made contingent on amplitude. Change occurs over weeks and months and persists for long periods. It is relatively specific to the agonist muscle and affects movement. The salient features of SSR adaptive plasticity, combined with clinical and laboratory evidence indicating spinal cord capacity for intrinsic change, suggest that SSR change eventually involves persistent segmental alteration. If this is the case, SSR plasticity should be a powerful model for studying the neuronal and synaptic substrates of memory in a primate.     

Presynaptic inhibition of spinal α motoneurons in humans adapted to different types of motor activity

Changes in the presynaptic inhibition of spinal α motoneurons were studied in athletes during motor activities of different types. In the state where muscles were at relative rest, the presynaptic inhibition of spinal α motoneurons of the m. soleus was stronger in samboists (athletes specializing in the martial art of sambo) and sprinters than in long-distance runners. In samboists performing repeated static efforts, the presynaptic inhibition of spinal α motoneurons became stronger from one trial to the next. Both technique training and strength training enhanced the presynaptic inhibition of spinal α motoneurons, this enhancement being greater after strength training.     

A differential behavior of α-amylase, in terms of catalytic activity and thermal stability, in response to higher concentration CaCl2

A differential relationship was observed between thermal stability and catalytic activity of α-amylase in the presence of different concentrations of CaCl(2). The enzyme displays optimum catalytic activity in the presence of 1.0-2.0 mM CaCl(2). Further addition of CaCl(2) leads to inhibition of the enzyme, however, at the same time the enzyme gains an additional resistance against thermal denaturation. It was evident that the enzyme is thermodynamically more stable (compared to the active enzyme) in the presence of inhibitory concentration of CaCl(2). For example, the thermal transition temperature (T(m)) of optimally active α-amylase was found to be 64±1°C, whereas, for the less active enzyme (in the presence 10 mM CaCl(2)) the value was determined to be 71±1°C. Similarly, the activation energy of thermal inactivation (Ea) was found to be 228±12 kJ/mol and 291±15 kJ/mol for the optimally active enzyme and the enzyme in the presence of 10 mM CaCl(2), respectively. Biophysical analysis of different states of the enzymes in response to variable calcium level indicates no significant change in the secondary structure in response to different concentration of CaCl(2), however the less active but thermodynamically stable enzyme (in the presence of higher concentration of CaCl(2)) was shown to have relatively more compact structure. The results suggest that the enzyme has separate catalytic and structure stabilizing domains and they significantly vary in their functional attributes in response to calcium level.     

Change in the power of EEG activity in the α range in response to tonic nociceptive stimulation of the distal joint of the little finger

Examination of 12 healthy volunteers aged 20–56 years was performed to study the EEG changes caused by a tonic squeeze of the distal joint of the little finger of the left and then the right hand. This stimulation caused painful sensations of different intensity (pain on the right was stronger). Spectral power was measured in the ( ₁ (8–10.5 Hz) and (₂ ranges (10.5–13 Hz) under different conditions. Weak pain led to an increase in the power of the (₁ and ₂ ranges in the occipital regions. With strong pain, the power of ₁ waves increased bilaterally in the posterior regions (O ₁, O ₂, T ₆), as well as in the left frontal region (F ₃, F ₇). The powers of the ₁ and ₂ ranges substantially increased relative to the background level after the strong nociceptive stimulation ceased. This finding testified to a latent and inertial character of its effect on the -wave parameters.Translated from Fiziologiya Cheloveka, Vol. 31, No. 2, 2005, pp. 77–84.Original Russian Text Copyright © 2005 by Garkavenko, Gorkovenko, Mankovskaya, Shevko, Lyskov, Kostyukov.     

Regulated binding of importin-α to protein kinase Cδ in response to apoptotic signals facilitates nuclear import

PKCδ translocates into the nucleus in response to apoptotic agents and functions as a potent cell death signal. Cytoplasmic retention of PKCδ and its transport into the nucleus are essential for cell homeostasis, but how these processes are regulated is poorly understood. We show that PKCδ resides in the cytoplasm in a conformation that precludes binding of importin-α. A structural model of PKCδ in the inactive state suggests that the nuclear localization sequence (NLS) is prevented from binding to importin-α through intramolecular contacts between the C2 and catalytic domains. We have previously shown that PKCδ is phosphorylated on specific tyrosine residues in response to apoptotic agents. Here, we show that phosphorylation of PKCδ at Tyr-64 and Tyr-155 results in a conformational change that allows exposure of the NLS and binding of importin-α. In addition, Hsp90 binds to PKCδ with similar kinetics as importin-α and is required for the interaction of importin-α with the NLS. Finally, we elucidate a role for a conserved PPxxP motif, which overlaps the NLS, in nuclear exclusion of PKCδ. Mutagenesis of the conserved prolines to alanines enhanced importin-α binding to PKCδ and induced its nuclear import in resting cells. Thus, the PPxxP motif is important for maintaining a conformation that facilitates cytosplasmic retention of PKCδ. Taken together, this study establishes a novel mechanism that retains PKCδ in the cytoplasm of resting cells and regulates its nuclear import in response to apoptotic stimuli.     

Proline accumulation: A parameter for evaluation of sensitivity of tomato varieties to drought stress?

The pattern of proline accumulation and the growth response were followed in several tomato ( Lycopersicon esculentum Mill.) varieties which were exposed to 7 days of drought stress followed by a 15-day period of rewatering. During dehydration, water potential and leaf elongation rates decreased more in var. 'Hosen' and 'S-5' than in 'LX-11', '1970', 'Pakmor', 'Faculty-16', 'Alcobaca' and '475'. Proline accumulation during stress was greatest in the first two varieties. In 'Hosen' and 'S-5' rewatering resulted in a decrease of proline to control levels, whereas in the other varieties accumulation of proline continued long after turgor had been regained. The extent of this continued accumulation was not correlated with the degree to which each variety was dehydrated. Upon rewatering of the plants the rate of leaf elongation was increased, but the final leaf size as well as whole shoot and root fresh weight of the recovered plants were not colated with the degree of "suffering" that each variety experienced during the drought period. Incubation of detached young tomato leaves in polyethylene glycol solution for 48 h resulted in a substantial accumulation of proline. The varietal differences observed under these conditions were reminiscent of the differential responses in proline accumulation obtained in the intact plants. It is concluded that proline accumulation at the time of dehydration signals drought stress in tomato plants but does not correlate with the overall varietal sensitivity to transient dehydration in recovered plants.     

What role for membranes in determining the higher sodium pump molecular activity of mammals compared to ectotherms?

The major body organs of mammals have sodium pumps that turn over energy (ATP) three to four times faster than those of ectotherms, at the same temperature. To examine if membranes play a role in these differences in molecular activity, membrane cross-over experiments were performed using two representative species, Rattus norvegicus and Bufo marinus. Microsomal membrane of kidney and brain displayed characteristic molecular activity differences (three- to four-fold) between the species. These molecular activity differences could be removed by delipidation. Pre-existing molecular activities and differences could be restored when reconstituted with original membrane. Using the same reconstitution method, species membrane cross-over experiments resulted in toad sodium pumps in rat membrane significantly increasing (≈30–40%) and rat sodium pumps in toad membrane significantly decreasing (≈40%) activities in both kidney and brain. Analysis of membrane composition showed reduced cholesterol content and differences in the fatty acids of phospholipids with higher overall unsaturation in the mammal. The scope for membranes to determine protein performance and its broader implications for metabolism are discussed. Accepted: 17 March 1999     

Cyclosporin A inhibits protein kinase C activity: a contributing mechanism in the development of nephrotoxicity?

Cyclosporin A modifies many intracellular functions in a variety of different cells. This study investigated the potential interaction between cyclosporin A and protein kinase C, as a possible mechanism for the development of nephrotoxicity. The activity of protein kinase C, in the cytosol of renal epithelial cells, was shown to be significantly inhibited in a dose-dependent manner by CSA. Activation of protein kinase C by 12-O-tetradecanoylphorbol-13-acetate (phorbol ester) in rat mesangial cells in culture leads to an increase in PGE2 release. Phorbol ester stimulated PGE2 release was significantly inhibited by cyclosporin A. These results would suggest that intracellular site of action of cyclosporin A, in producing alterations in intracellular function and toxicity, may be at the level of protein kinase C.     

Role of sulfate‐reducing bacteria in corrosion of mild steel: A review

The influence of sulfate‐reducing bacteria on corrosion of mild steel is reviewed, with special emphasis on the effects of biofilm structure and function, medium composition (dissolved oxygen and ferrous ion concentrations) and the physical and chemical properties of iron sulfides. A summary of different corrosion mechanisms is critically discussed, based on electrochemical and rate process analyses. A mechanism is proposed which explains the high corrosion rates observed in the field.     

Janus-Faced Autophagy: A Dual Role of Cellular Self-Eating in Neurodegeneration?

Autophagy is a highly regulated cellular pathway used by eukaryotic cells to consume parts of their constituents during development or starvation. It is associated with extensive rearrangements of intracellular membranes, and involves the cooperation of many gene products in the regulation and execution phase by largely unknown mechanisms. Recent results strongly indicate the role of autophagy in the degradation of damaged macromolecules, in particular misfolded, aberrant proteins, and in organelle turnover; in mutant mice with reduced autophagy, accumulation of abnormal cytosolic proteins as inclusion bodies and massive cell loss occur similarly to human neurodegenerative disorders. Thus, autophagy seems to prevent neurons from undergoing protein aggregation-induced degeneration. In contrast, we have shown that inactivation of genes involved in autophagosome formation suppresses neuronal demise induced by various hyperactivating ion channel mutations or by neurotoxins in the nematode Caenorhabditis elegans. These results raise the possibility that autophagy may also contribute to excitotoxic necrotic-like cell death. This way, autophagic degradation of cytoplasmic materials might have a dual role in the survival of neurons. Depending on the actual cellular milieu and insulting factor, it can act both as a protector and contributor to neuronal damage.

Addendum to:

Influence of Autophagy Genes on Ion Channel-Dependent Neuronal Degeneration in Caenorhabditis elegans

M.L. Tóth, P. Simon, A.L. Kovács,and T. Vellai

J Cell Sci 2007; 120:1134-41     

Basal protein kinase Cδ activity is required for membrane localization and activity of TRPM4 channels in cerebral artery smooth muscle cells

The melastatin (M) transient receptor potential channel (TRP) channel TRPM4 is a critical regulator of vascular smooth muscle cell membrane potential and contractility. We recently reported that PKCδ activity influences smooth muscle cell excitability by promoting translocation of TRPM4 channel protein to the plasma membrane. Here we further investigate the relationship between membrane localization of TRPM4 protein and channel activity in native cerebral arterial myocytes. We find that TRPM4 immunolabeling is primarily located at or near the plasma membrane of freshly isolated cerebral artery smooth muscle cells. However, siRNA mediated downregulation of PKCδ or brief (15 min) inhibition of PKCδ activity with rottlerin causes TRPM4 protein to move away from the plasma membrane and into the cytosol. In addition, we find that PKCδ inhibition diminishes TRPM4-dependent currents in smooth muscle cells patch clamped in the amphotericin B perforated patch configuration. We conclude that TRPM4 channels are mobile in native cerebral myocytes and that basal PKCδ activity supports excitability of these cells by maintaining localization TRPM4 protein at the plasma membrane.     

A paradox of leaf-trait convergence: why is leaf nitrogen concentration higher in species with higher photosynthetic capacity?

It is well known that leaf photosynthesis per unit dry mass (A_mass) is positively correlated with nitrogen concentration (N_mass) across naturally growing plants. In this article we show that this relationship is paradoxical because, if other traits are identical among species, plants with a higher A_mass should have a lower N_mass, because of dilution by the assimilated carbon. To find a factor to overcome the dilution effect, we analyze the N_mass–A_mass relationship using simple mathematical models and literature data. We propose two equations derived from plant-growth models. Model prediction is compared with the data set of leaf trait spectrum obtained on a global scale. The model predicts that plants with a higher A_mass should have a higher specific nitrogen absorption rate in roots (SAR), less biomass allocation to leaves, and/or greater nitrogen allocation to leaves. From the literature survey, SAR is suggested as the most likely factor. If SAR is the sole factor maintaining the positive relationship between N_mass and A_mass, the variation in SAR is predicted to be much greater than that in A_mass; given that A_mass varies 130-fold, SAR may vary more than 2000-fold. We predict that there is coordination between leaf and root activities among species on a global scale. Kouki Hikosaka is the recipient of the BSJ Award for Young Scientist, 2006.     

A genetic characterization of differences in the sensitivity to radiation-induced malformation frequencies in the mouse strains Heiligenberger,C57Bl,and Heiligenberger × C57Bl

We studied the frequency of malformations induced in two mouse strains (Heiligenberger, C57Bl/6J) by exposure to x-rays 3 h after conception. Whereas there was a high number of malformed fetuses in Heiligenberger mice (mostly gastroschises) on day 19 of pregnancy, C57Bl did not respond to radiation exposure shortly after conception with an increased frequency of malformed fetuses. Cross-breeding of both strains revealed that no statistically significant increase in radiation-induced malformations was obtained in the F₁ fetuses when the father was Heiligenberger and the mother C57Bl. In the opposite case (Heiligenberger mother, C57Bl father a small but statistically significant increase was observed.     

Role of extracellular matrix components in the formation of biofilms and their contribution to the biocontrol activity of Pseudomonas chlororaphis PCL1606

Pseudomonas chlororaphis PCL1606 (PcPCL1606) displays plant-colonizing features and exhibits antagonistic traits against soil-borne phytopathogenic fungi. Biofilm formation could be relevant for the PcPCL1606 lifestyle, and in this study the role of some putative extracellular matrix components (EMC; Fap-like fibre, alginate and Psl-like polysaccharides) in the biofilm architecture and biocontrol activity of this bacterium were determined. EMC such as the Fap-like fibre and alginate polysaccharide play secondary roles in biofilm formation in PcPCL1606, because they are not fundamental to its biofilm architecture in flow cell chamber, but synergistically they have shown to favour bacterial competition during biofilm formation. Conversely, studies on Psl-like polysaccharide have revealed that it may contain mannose, and that it is strongly involved in the PcPCL1606 biofilm architecture and niche competition. Furthermore, the Fap-like fibre and Psl-like exopolysaccharide play roles in early surface attachment and contribute to biocontrol activity against the white root rot disease caused by Rosellinia necatrix in avocado plants. These results constitute the first report regarding the study of the extracellular matrix of the PcPCL1606 strain and highlight the importance of a putative Fap-like fibre and Psl-like exopolysaccharide produced by PcPCL1606 in the biofilm formation process and interactions with the host plant root.     

Protein kinase Cδ contributes to phenylephrine-mediated contraction in the aortae of high fat diet-induced obese mice

The down-regulation of α-adrenoceptor-mediated signaling casacade has been implicated in obesity but the underlying mechanism remains largely unknown. The present study investigated whether inositol 1,4,5-trisphosphate (IP3) receptor and protein kinase C (PKC) were involved in the reduction of α₁-adrenoceptor agonist phenylephrine-evoked contraction in aortae of high fat diet-induced obese (DIO) mice. C57BL/6 mice were fed with a rodent diet containing 45 kcal% fat for 16 weeks to induce obesity. Isolated mouse aortae were suspended in myograph for isometric force measurement. Protein phosphorylations and expressions were determined by Western blotting. In C57BL/6 mouse aortae, phenylephrine-induced contraction was partially inhibited by either IP3 receptor antagonist heparin or PKC inhibitor GFX, and the combined treatment with heparin and GFX abolished the contraction. Phenylephrine-induced contraction was significantly less in the aortae of DIO mice than those of control mice; only GFX but not heparin attenuated the contraction, indicating a diminishing role of IP3 receptor in DIO mice. Western blotting showed the reduced expression and phosphorylation of IP3 receptor and the down-regulated expression of PKC, PKCβ, PKCδ, and PKCζ in DIO mouse aortae. Importantly, PKCδ was more likely to maintain phenylephrine-mediated contraction in DIO mouse aortae because that (1) PKCδ inhibitor rottlerin but not PKCα and PKCβ inhibitor Gö6976, PKCβ inhibitor hispidin, or PKCζ pseudosubstrate inhibitor attenuated the contraction; and (2) PKCδ phosphorylation was increased but phosphorylations of PKCα, PKCβ, and PKCζ were reduced in DIO mouse aortae. The present study thus provides additional insights into the cellular mechanisms responsible for vascular dysfunction in obesity.