TRP channels in disease

“Transient receptor potential” cation channels (TRP channels) play a unique role as cell sensors, are involved in a plethora of Ca²⁺-mediated cell functions, and play a role as “gate-keepers” in many homeostatic processes such as Ca²⁺ and Mg²⁺ reabsorption. The variety of functions to which TRP channels contribute and the polymodal character of their activation predict that failures in correct channel gating or permeation will likely contribute to complex pathophysiological mechanisms. Dysfunctions of TRPs cause human diseases but are also involved in a complex manner to contribute and determine the progress of several diseases. Contributions to this special issue discuss channelopathias for which mutations in TRP channels that induce “loss-“ or “gain-of-function” of the channel and can be considered “disease-causing” have been identified. The role of TRPs will be further elucidated in complex diseases of the intestinal, renal, urogenital, respiratory, and cardiovascular systems. Finally, the role of TRPs will be discussed in neuronal diseases and neurodegenerative disorders.     

Linkage of Retinal to Opsin

RHODOPSIN, the visual pigment of vertebrate rods, has been shown to consist of a chromophore (11-cis retinal) bound to a protein (opsin)^1–2. It has been proposed that the linkage is a Schiff base between phosphatidyl ethanolaniine (PE) and retinal and that when exposed to light, the retinal migrates from PE to the ε-amino-group of a lysine residue in opsin^3–7. Most of the support for this theory comes from the observation that N-retinylidenephosphatidylethanolamine (N-RPE) can be extracted in the dark from rod outer segments (ROS)^3,4. Furthermore, N-retinylphosphatidylethanolamine (N-RH₂PE) has been extracted from ROS preparations after treating the visual pigment with acid and NaBH₄—conditions which are assumed fix retinal to its “native” binding site through a secondary amine linkage⁷. All these studies, however, were carried out on crude extracts of ROS in various detergents. These crude extracts contain large amounts of phospholipid and retinal which is not bound to opsin. Thus, the isolation of N-RPE from crude ROS extracts does not necessarily point to its involvement in the binding of retinal to opsin. In contradiction to these reports are findings that purified visual pigment contains no phospholipid^9,10 and that the molar concentration of N-RPE in bovine ROS is less than that of rhodopsin¹¹. We have taken advantage of the observation that visual pigment in the outer segment disks is continually being renewed¹² to label the rhodopsin with ³H-retinal and to show in yet another way that N-RPE does not exist in purified visual pigment.     

Modulation of the reaction cycle of the Na<Superscript>+</Superscript>:Ca<Superscript>2+</Superscript>, K<Superscript>+</Superscript> exchanger

Ca²⁺ concentration in retinal photoreceptor rod outer segment (OS) strongly affects the generator potential kinetics and the receptor light adaptation. The response to intense light stimuli delivered in the dark produce potential changes exceeding 40 mV: since the Ca²⁺ extrusion in the OS is entirely controlled by the Na⁺:Ca²⁺, K⁺ exchanger, it is important to assess how the exchanger ion transport rate is affected by the voltage and, in general, by intracellular factors. It is indeed known that the cardiac Na⁺:Ca²⁺ exchanger is regulated by Mg-ATP via a still unknown metabolic pathway. In the present work, the Na⁺:Ca²⁺, K⁺ exchanger regulation was investigated in isolated OS, recorded in whole-cell configuration, using ionic conditions that activated maximally the exchanger in both forward and reverse mode. In all species examined (amphibia: Rana esculenta and Ambystoma mexicanum; reptilia: Gecko gecko), the forward (reverse) exchange current increased about linearly for negative (positive) voltages and exhibited outward (inward) rectification for positive (negative) voltages. Since hyperpolarisation increases Ca²⁺ extrusion rate, the recovery of the dark level of Ca²⁺ (and, in turn, of the generator potential) after intense light stimuli results accelerated. Mg-ATP increased the size of forward and reverse exchange current by a factor of ∼2.3 and ∼2.6, respectively, without modifying their voltage dependence. This indicates that Mg-ATP regulates the number of active exchanger sites and/or the exchanger turnover number, although via an unknown mechanism. Proceedings of the XVIII Congress of the Italian Society of Pure and Applied Biophysics (SIBPA), Palermo, Sicily, September 2006.     

The fine structure of the trout blastoderm, Salvelinus fontinalis (Mitchill)

The Speckled Trout blastoderm at the late high blastula stage is characterized by two different cell populations. The “light” blastomeres comprise one cell type while the “dark” and “medium” blastomeres appear to differ from one another only in degree and thus may be considered as the second type. “Dark” and “medium” blastomeres are irregular in shape, are located centrally and deep in the blastoderm, have an abundance of smooth endoplasmic reticulum with associated 520 Å glycogen particles and a single mitochondrial profile. The “light” blastomeres have randomly arranged glycogen particles in minimal quantities in contrast to the “medium” and “dark” blastomeres and in addition exhibit three mitochondrial profiles, which could however represent artifacts. It is postulated that in the Speckled Trout cellular differentiation has commenced by the third day of incubation at 10°C and that this is manifested visually by the appearance of two different cell populations; the more differentiated “dark” and “medium” blastomeres possibly destined to give rise to the hypoblast and the less differentiated “light” blastomeres.     

The relationship between delayed fluorescence and the H+ gradient in chloroplasts

1. The induction kinetics of delayed fluorescence have been studied in isolated chloroplasts and compared with the kinetics of H⁺ uptake. The slow phase of the delayed fluorescence rise, after replotting on a logarithmic scale, had the same half-rise time as H⁺ uptake.2. The kinetics of decay of the “state” filled during the slow phase of delayed fluorescence induction have been investigated by following the reappearance of the slow phase with increasing dark time after a prior period of illumination.3. The decay of the “state” filled during the slow phase was found to parallel the decay of H⁺ uptake under a variety of conditions in which the ionic environment was varied, or in the presence of ionophores or uncoupling agents.4. It is suggested that the slow phase of the delayed fluorescence induction occurs as a pH gradient develops across the thylakoid membrane, and that the pH gradient is equivalent to the “state”, the decay of which gave rise to a reappearance of the slow phase.     

Development of light-shielding hydrogel for nitrifying bacteria to prevent photoinhibition under strong light irradiation

Microalgae-nitrifying bacteria consortia have gained attention because photooxygenation of algae can supply oxygen to bacteria which eliminates the need for costly mechanical aeration. However, nitrifying bacteria are known to suffer from photoinhibition. In this study, we developed “Light-shielding hydrogel”, in which bacteria were immobilized in hydrogel and light-shielding particles (carbon black) were incorporated, and evaluated its effectiveness to mitigate photoinhibition for bacteria under strong light irradiation. For comparison, “Hydrogel”, in which bacteria were immobilized in hydrogel without carbon black, and “Dispersion” which was simply suspended bacteria were prepared. At 1600 μmol photons m⁻² s^–1, the nitrification performance markedly decreased to 15.1 and 48.0% compared to the dark condition in the Dispersion and the Hydrogel, respectively. Meanwhile, it was successfully maintained for the Light-shielding hydrogel. Our results showed that the effectiveness of light-shielding hydrogel to mitigate photoinhibition on nitrifying bacteria even under strong light irradiation.     

Elevated beta-adrenergic receptor number after chronic propranolol treatment.

Treatment of rats with the beta-adrenergic antagonist propranolol for two weeks leads to a 100% increase in the number of beta-adrenergic receptors ((?) [³H]dihydroalprenolol binding sites) in cardiac particulate fractions. No change in receptor affinity was observed. These findings may l) represent the converse of agonist-induced desensitization which is associated with decreases in beta-receptor number, 2) provide a potential explanation for the clinically observed “propranolol withdrawal syndrome”.     

Sexual selection and sperm competition in primates: What are male genitalia good for?

One hundred twenty-five years ago, in The Descent of Man and Selection in Relation to Sex,¹ Charles Darwin proposed the theory of sexual selection, as distinct from natural selection, to explain why, in some species, males have such magnificent ornaments and, in other species, such impressive weapons. He suggested two processes, which we now term female choice and male-male competition: either females choose particularly ornate males or, alternatively, relatively passive females accept the winner of fights among males. By now, knowledge of species in which the females are more brightly colored or aggressive than males has led to a more general formulation of the principle of sexual selection, in which, instead of “females”, we write “the sex with the lower potential reproductive rate”, and, instead of “male”, “the sex with the higher potential reproductive rate”.²     

Multidimensional Ordered Bifunctional Air Electrode Enables Flash Reactants Shuttling for High‐Energy Flexible Zn‐Air Batteries

Direct growth of electrocatalysts on conductive substrates is an emerging strategy to prepare air electrodes for flexible Zn‐air batteries (FZABs). However, electrocatalysts grown on conductive substrates usually suffer from disorder and are densely packed with “prohibited zones”, in which internal blockages shut off the active sites from catalyzing the oxygen reaction. Herein, to minimize the “prohibited zones”, an ordered multidimensional array assembled by 1D carbon nanotubes and 2D carbon nanoridges decorated with 0D cobalt nanoparticles (referred as MPZ‐CC@CNT) is constructed on nickel foam. When the MPZ‐CC@CNT is directly applied as a self‐supported electrode for FZAB, it delivers a marginal voltage fading rate of 0.006 mV cycle^?1 over 1800 cycles (600 h) at a current density of 50 mA cm^?2 and an impressive energy density of 946 Wh kg^?1. Electrochemical impedance spectroscopy reveals that minimal internal resistance and electrochemical polarization, which is beneficial for the flash reactant shuttling among the triphase (i.e., oxygen, electrolyte, and catalyst) are offered by the open and ordered architecture. This advanced electrode design provides great potential to boost the electrochemical performance of other rechargeable battery systems.     

The allosteric site regulates the voltage sensitivity of muscarinic receptors

Muscarinic receptors (M-Rs) for acetylcholine (ACh) belong to the class A of G protein–coupled receptors. M-Rs are activated by orthosteric agonists that bind to a specific site buried in the M-R transmembrane helix bundle. In the active conformation, receptor function can be modulated either by allosteric modulators, which bind to the extracellular receptor surface or by the membrane potential via an unknown mechanism. Here, we compared the modulation of M₁-Rs and M₃-Rs induced by changes in voltage to their allosteric modulation by chemical compounds. We quantified changes in receptor signaling in single HEK 293 cells with a FRET biosensor for the G_q protein cycle. In the presence of ACh, M₁-R signaling was potentiated by voltage, similarly to positive allosteric modulation by benzyl quinolone carboxylic acid. Conversely, signaling of M₃-R was attenuated by voltage or the negative allosteric modulator gallamine. Because the orthosteric site is highly conserved among M-Rs, but allosteric sites vary, we constructed “allosteric site” M₃/M₁-R chimeras and analyzed their voltage dependencies. Exchanging the entire allosteric sites eliminated the voltage sensitivity of ACh responses for both receptors, but did not affect their modulation by allosteric compounds. Furthermore, a point mutation in M₃-Rs caused functional uncoupling of the allosteric and orthosteric sites and abolished voltage dependence. Molecular dynamics simulations of the receptor variants indicated a subtype-specific crosstalk between both sites, involving the conserved tyrosine lid structure of the orthosteric site. This molecular crosstalk leads to receptor subtype-specific voltage effects.     

Estrogen receptor 1 modulates circadian rhythms in adult female mice

Estradiol influences the level and distribution of daily activity, the duration of the free-running period, and the behavioral phase response to light pulses. However, the mechanisms by which estradiol regulates daily and circadian rhythms are not fully understood. We tested the hypothesis that estrogens modulate daily activity patterns via both classical and “non-classical” actions at the estrogen receptor subtype 1 (ESR1). We used female transgenic mice with mutations in their estrogen response pathways; ESR1 knock-out (ERKO) mice and “non-classical” estrogen receptor knock-in (NERKI) mice. NERKI mice have an ESR1 receptor with a mutation in the estrogen-response-element binding domain, allowing only actions via “non-classical” genomic and second messenger pathways. Ovariectomized female NERKI, ERKO, and wildtype (WT) mice were given a subcutaneous capsule with low- or high-dose estradiol and compared with counterparts with no hormone replacement. We measured wheel-running activity in a light:dark cycle and constant darkness, and the behavioral phase response to light pulses given at different points during the subjective day and night. Estradiol increased average daily wheel-running, consolidated activity to the dark phase, and shortened the endogenous period in WT, but not NERKI and ERKO mice. The timing of activity onset during entrainment was advanced in all estradiol-treated animals regardless of genotype suggesting an ESR1-independent mechanism. We propose that estradiol modifies period, activity level, and distribution of activity via classical actions of ESR1 whereas an ESR1 independent mechanism regulates the phase of rhythms.     

Simulated cell trajectories in a stratified gas–liquid flow tubular photobioreactor

The fluid dynamic environment within a photobioreactor is critical for performance as it controls mass transfer of photosynthetic gases (CO₂ and O₂) and the mixing environment of the algal culture. At a cellular level, light fluctuation will occur when cells move between the “light”, well-illuminated volume of the culture near the light source and the “dark”, self-shaded zone of the culture. Controlled light/dark frequency may increase the light to biomass yield and prevent photoinhibition. Knowledge of cell trajectories within the reactor is therefore important to optimize culture performance. This study examines the cell trajectories and light/dark frequencies in a stratified gas–liquid flow tubular photobioreactor. Commercially available computational fluid dynamics software, ANSYS Fluent, was used to investigate cell trajectories within the half-full solar receivers at different liquid velocities and reactor tube diameters. In the standard configuration 96-mm solar receiver tube, the light/dark cycle frequencies ranged from 0.104 to 0.612?Hz over the liquid velocity range of 0.1 to 1?m s^?1. In comparison, the smaller diameter 48- and 24-mm tubes exhibit higher light/dark frequencies, 0.219 to 1.30?Hz and 0.486 to 2.67?Hz, respectively.     

Blockade of a Retinal cGMP-gated Channel by Polyamines

The cyclic nucleotide–gated (CNG) channel in retinal rods converts the light-regulated intracellular cGMP concentration to various levels of membrane potential. Blockade of the channel by cations such as Ca²⁺ and Mg²⁺ lowers its effective conductance. Consequently, the membrane potential has very low noise, which enables rods to detect light with extremely high sensitivity. Here, we report that three polyamines (putrescine, spermidine, and spermine), which exist in both the intracellular and extracellular media, also effectively block the CNG channel from both sides of the membrane. Among them, spermine has the greatest potency. Extracellular spermine blocks the channel as a permeant blocker, whereas intracellular spermine appears to block the channel in two conformations—one permeant, and the other non- (or much less) permeant. The membrane potential in rods is typically depolarized to approximately −40 mV in the dark. At this voltage, K _1/2 of the CNG channel for extracellular spermine is 3 μM, which is 100–1,000-fold higher affinity than that of the NMDA receptor-channel for extracellular spermine. Blockade of the CNG channel by polyamines may play an important role in suppressing noise in the signal transduction system in rods.     

Two-enzyme active transport in vitro with ph induced asymmetrical functional structures.: III. Discussions based on numerical treatments of the time-dependent evolutions

Three complementary models have been considered in which pH gradients (step function. linear pH or linear H^?) impose asymmetry on a two-enzyme mixture. If the “combined pH dependences” of enzymes is pro-asymmetrical, the pH gradient induces an asymmetrical distribution of potential activities (“latent” asymmetry of functional structure). When substrate is added, “developed” asymmetry of effective activities appears which results in “substrate space wave” and pumping when the catalysed reaction couple is “inversible”. It is shown that only one steady state exists for a given boundary condition and is attained when the “combined effective activity” of enzymes is nil: the stationary flux with symmetrical boundaries or the stationary load with moving boundaries is proportional to “effective global activities” of enzymes. “Equivalent square models” could be proposed that would be able to describe “functional” or “permanent” structure pumps as well. These models belong to the thermodynamic branch and the asymmetrical “space wave” substrate concentration profiles obtained must be distinguished from dissipative structures. It appears that such primary active transport pumps are chemical equivalents of heat pumps.     

Oxido-reduction kinetics of Signal II slow in tris-washed chloroplasts

In this report, we characterize the relationship between species “Z” (giving rise to EPR Signal II fast) and “D” (EPR Signal II slow) in triswashed chloroplasts.At pH 8.5 an externally added donor phenylenediamine competes with D for Z⁺ reduction after its oxidation by a flash. The reduction of Z⁺ by D occurs within some milliseconds. In a subsequent dark period, D⁺ is reduced by PD, the reaction rate being independant of phenylenediamine concentration. These results are consistent with the hypothesis of an equilibrium between Z⁺D and ZD⁺, the reduction of D by phenylenediamine occuring via Z. At lower pH's, the connection between Z and D is looser: a high concentration of phenylenediamine which reduces rapidly Z⁺, is very slow in reducing D⁺ and the subsequent photooxidation of D is less efficient.     

GROWTH AND CELL CYCLE OF TWO CLOSELY RELATED RED TIDE-FORMING DINOFLAGELLATES: GYMNODINIUM NAGASAKIENSE AND G. CF. NAGASAKIENSE1

Small-sized vegetative cells were found to co-occur with normal-sized cells in populations of the European bloom-forming dinoflagellate Gymnodinium cf. nagasakiense Takayama et Adachi, currently known as Gyrodinium aureolum Hulburt, but not in populations of the closely related Japanese species Gymnodiniumn agasakiense. We examined how cell size differentiation may influence growth and cell cycle progression under a 12:12-h light: dark cycle in the European taxon, as compared to the Japanese one. Cell number and volume and chlorophyll red fluorescence in both species varied widely during the photocycle. These variations generally appeared to be related lo the division period, which occurred at night, as indicated by the variations of the fraction of binucleated cells (mitotic index) as well as the distribution of cellular DNA content. “Small” cells of G. cf. nagasakiense divided mainly during the first part of the dark period, although a second minor peak of dividing cells could occur shortly before light onset. In contrast, “large” cells displayed a sharp division peak that occurred 9 h after the beginning of the dark period. The lower degree of synchrony of “small” cells could be a consequence of their faster growth. Alternatively, these data may suggest that cell division is lightly controlled by an endogenous clock in “large” cells and much more loosely controlled in “small” cells. Cells of the Japanese species, which were morphologically similar to “large” cells of the European taxon, displayed an intermediate growth pattern between the two cell types of G. cf. nagasakiense, with a division period that extended to most of the dark period.     

Secondary structural and “active site” momologies between nerve growth factor and insulin

Secondary structural elements, α-helix, β-sheet and turns, of nerve growth factor (NGF) were predicted by the method of Chou and Fasman. Analysis of the prediction results showed the presence of domain structure in NGF; the second half of the polypeptide chain showed a secondary structural “pattern” very similar to the first half. Comparison of the secondary structure of NGF and proinsulin showed significant homology between the B-chain, which has the “active site”, and NGF^25–54 The homology is reinforced by the identification of a pentapeptide sequence in NGF which is very similar to the “active site” sequence of insluin essential for receptor binding and agonist activity. The present alignment of insulin and NGF is however different from that proposed earlier on the basis of sequence data alone.     

Differential Sensitivity of Macrocarpa and Microcarpa Types of Chickpea （Cicer arietinum L.） to Water Stress： Association of Contrasting Stress Response with Oxidative Injury

Chickpea (Cicer arietinum L.) is particularly sensitive to water stress at its reproductive phase and, under conditions of water stress, will abort flowers and pods, thus reducing yield potential. There are two types of chickpea: (i) Macrocarpa (“Kabuli”), which has large, rams head‐shaped, light brown seeds; and (ii) Microcarpa (“Desi”), which has small, angular and dark‐brown seeds. Relatively speaking, “Kabuli” has been reported to be more sensitive to water stress than “Desi”. The underlying mechanisms associated with contrasting sensitivity to water stress at the metabolic level are not well understood. We hypothesized that one of the reasons for contrasting water stress sensitivity in the two types of chickpea may be a variation in oxidative injury. In the present study, plants of both types were water stressed at the reproductive stage for 14 d. As a result of the stress, the “Kabuli” type exhibited an 80% reduction in seed yield over control compared with a 64% reduction observed for the “Desi” type. The decrease in leaf water potential (Ψ_w) was faster in the “Kabuli” compared with the “Desi” type. At the end of the water stress period, Ψ_w was reduced to ?2.9 and ?3.1 MPa in the “Desi” and “Kabuli” types, respectively, without any significant difference between them. On the last day of stress, “Kabuli” experienced 20% more membrane injury than “Desi”. The chlorophyll content and photosynthetic rate were significantly greater in “Desi” compared with “Kabuli”. The malondialdehyde and H₂O₂ content were markedly higher at the end of the water stress in “Kabuli” compared with “Desi”, indicating greater oxidative stress in the former. Levels of anti‐oxidants, such as ascorbic acid and glutathione, were significantly higher in “Desi” than “Kabuli”. Superoxide dismutase and catalase activity did not differ significantly between the two types of chickpea, whereas on the 10th day, the activities of ascorbate peroxidase, dehydroascorbate reductase, and glutathione reductase were higher in “Desi”. These findings indicate that the greater stress tolerance in the “Desi” type may be ascribed to its superior ability to maintain better water status, which results in less oxidative damage. In addition, laboratory studies conducted by subjecting both types of chickpea to similar levels of polyethylene glycol‐induced water stress and to 10 μ.mol/L abscisic acid indicated a greater capacity of the “Desi” type to deal with oxidative stress than the “Kabuli” type. (Managing editor: Ping He)     

Progestin binding sites in the rat hypothalamus pituitary and uterus

Specific, estrogen-inducible, nuclear radioactivity uptake has been demonstrated in the uterus, pituitary and hypothalamus of immature female rats after injection of a highly potent labelled progestin, R 5020 (17, 21-dimethyl-19-nor-pregna-4, 9-diene-3, 20-dione). A cytoplasmic progestin “receptor” has been characterized in these target tissues by an in vitro Dextran-coated charcoal adsorption method. R 5020 binds with the same intrinsic dissociation constant to the receptor present in these tissues ; it dissociates at the same rate from the uterine and pituitary receptor (k^?1 = 1×10^?2min^?1), but about 6 times slower than progesterone. This evidence, together with the similar hormone specificity in the uterus and pituitary, suggests that the progestin “receptor” is a similar entity in central and peripheral target tissues.     

Adenosine receptors in the central nervous system: relationship to the central actions of methylxanthines

Adenosine has a significant role in many functions of the central nervous system. Behaviorally, adenosine and adenosine analogs have marked depressant effects. Electrophysiologically, adenosine reduces spontaneous neuronal activity and inhibits transsynaptic potentials $\text{via}$ interaction with extracellular receptors. Biochemically, adenosine inhibits adenylate cyclase $\text{via}$ a “high” affinity receptor, and activates adenylate cyclase $\text{via}$ a “low” affinity receptor. These receptors, called “A₁” and “A₂” respectively, show differing profiles for activation by adenosine analogs. Radioactive N⁶-cyclohexyladenosine binds selectively to the “high” affinity receptor. One major class of antagonists is known at adenosine receptors: the alkylxanthines, including caffeine and theophylline. Radioactive 1,3-diethyl-8-phenylxanthine, a particularly potent antagonist, appears to bind to both low and high affinity adenosine receptors. Behavioral, electrophysiological, and biochemical effects of alkylxanthines are consistent with the hypothesis that the central stimulatory actions of caffeine and theophylline are due in large part to antagonism of central adenosine receptors.