Electrical signals and their physiological significance in plants

Electrical excitability and signalling, frequently associated with rapid responses to environmental stimuli, are well known in some algae and higher plants. The presence of electrical signals, such as action potentials (AP), in both animal and plant cells suggested that plant cells, too, make use of ion channels to transmit information over long distances. In the light of rapid progress in plant biology during the past decade, the assumption that electrical signals do not only trigger rapid leaf movements in 'sensitive' plants such as Mimosa pudica or Dionaea muscipula, but also physiological processes in ordinary plants proved to be correct. Summarizing recent progress in the field of electrical signalling in plants, the present review will focus on the generation and propagation of various electrical signals, their ways of transmission within the plant body and various physiological effects.     

Transhydrogenase activity in mammalian cells in vitro: Its possible physiological significance

Summary Transhydrogenase (NADH:NADP oxidoreductase, EC 1.6.1.1.) activity has been demonstrated in mammalian cells cultured in vitro. Levels of activity of this enzyme were 10- to 20-fold higher in H4-II-E-C3 cells derived from the minimal deviation Reuber hepatoma than in three other cell lines tested. H4 cells lack the abibility to reduce nicotinamide adenine dinucleotide phosphate by the glucose 6-phosphate dehydrogenase reaction. This raised the question of the physiological significance of transhydrogenase in these cells. This work was supported by Grant P513 from the American Cancer Society.     

Localization, physiological significance and possible clinical implication of gastrointestinal melatonin.

The gastrointestinal tract (GIT) is a major source of extrapineal melatonin. In some animals, tissue concentrations of melatonin in the GIT surpass blood levels by 10-100 times and the digestive tract contributes significantly to melatonin concentrations in the peripheral blood, particularly during the day. Some melatonin found in the GIT may originate from the pineal gland, as the organs of the digestive system contain binding sites, which in some species exhibit circadian variation. Unlike the production of pineal melatonin, which is under the photoperiodic control, release of GI melatonin seems to be related to periodicity of food intake. Melatonin and melatonin binding sites were localized in all GI tissues of mammalian and avian embryos. Postnatally, melatonin was localized in the GIT of newborn mice and rats. Phylogenetically, melatonin and melatonin binding sites were detected in GIT of numerous mammals, birds and lower vertebrates. Melatonin is probably produced in the serotonin-rich enterochromaffin cells (EC) of the GI mucosa and can be released into the portal vein postprandially. In addition, melatonin can act as an autocrine or a paracrine hormone affecting the function of GI epithelium, lymphatic tissues of the immune system and the smooth muscles of the digestive tube. Finally, melatonin may act as a luminal hormone, synchronizing the sequential digestive processes. Higher peripheral and tissue levels of melatonin were observed not only after food intake but also after a long-term food deprivation. Such melatonin release may have a direct effect on the various GI tissues but may also act indirectly via the CNS; such action might be mediated by sympathetic or parasympathetic nerves. Melatonin can protect GI mucosa from ulceration by its antioxidant action, stimulation of the immune system and by fostering microcirculation and epithelial regeneration. Melatonin may reduce the secretion of pepsin and the hydrochloric acid and influence the activity of the myoelectric complexes of the gut via its action in the CNS. Tissue or blood levels of melatonin may serve as a marker of GI lesions or tumors. Clinically, melatonin has a potential for a prevention or treatment of colorectal cancer, ulcerative colitis, irritable bowel syndrome, children colic and diarrhea.     

The peroxidase-catalysed oxidation of a chalcone and its possible physiological significance

1. Crystalline horseradish peroxidase catalysed the oxidation of 2',4,4'-trihydroxychalcone (isoliquiritigenin) in the presence of trace amounts of hydrogen peroxide under aerobic conditions. One atom of oxygen was consumed for each molecule of substrate. 2. The reaction course comprised a lag phase and a linear phase. The optimum pH for the linear phase of the reaction was about 7.5. The length of the lag phase decreased with increasing pH. It is suggested that the chalcone anion is the actual substrate for the reaction. 3. No evidence for the production of reducing free radicals or perhydroxyl radicals during the reaction could be found. 4. 4',7-Dihydroxyflavonol and 4',6-dihydroxyaurone were isolated from the reaction mixture. The immediate products of the reaction may have included 3,4',7-trihydroxyflavanone and 4',6-dihydroxy-2-(alpha-hydroxybenzyl)coumaran-one, which can be readily converted non-enzymically into the flavonol and aurone respectively. 5. A similar reaction was catalysed by cell-free extracts of hypocotyls of Phaseolus vulgaris. 6. The physiological significance of the reaction is discussed in terms of a possible free-radical mechanism. An analogy may exist between flavonoid biosynthesis and lignin formation.     

Changes in physiological properties of frog taste cells following denervation

The structure of the taste organ and the physiological propertiesof the taste cell of the bullfrog (Rana catesbeiana) after theglossopharyngeal nerve transection were investigated. The frogtaste organ is composed of taste, supporting and basal cells.As nerve terminals within the taste organ degenerated, nerveresponses to mechanical, chemical and electrical stimuli graduallydeclined and finally ceased in 7 days during the summer and15 days during the winter. However, the taste cells still hadresting potentials and responded to four basic taste stimuliby generating receptor potentials with the various lengths ofduration, even 140 days after denervation. The glossopharyngealnerve transection affected the magnitude of resting potentialssignificantly. However, the taste, supporting and basal cellsmaintained their normal structures 140 days after surgery. Itis concluded, therefore, that neural dependency of the frogtaste organ is not as great as that in mammals.     

Effects of calcitonin gene-related peptide on rat soleus muscle excitability: mechanisms and physiological significance

Intense exercise causes a large loss of K(+) from contracting muscles. The ensuing elevation of extracellular K(+) ([K(+)](o)) has been suggested to cause fatigue by depressing muscle fiber excitability. In isolated muscles, however, repeated contractions confer some protection against this effect of elevated K(+). We hypothesize that this excitation-induced force-recovery is related to the release of the neuropeptide calcitonin gene-related peptide (CGRP), which stimulates the muscular Na(+)-K(+) pumps. Using the specific CGRP antagonist CGRP-(8-37), we evaluated the role of CGRP in the excitation-induced force recovery and examined possible mechanisms. Intact rat soleus muscles were stimulated to evoke short tetani at regular intervals. Increasing extracellular K(+) ([K(+)](o)) from 4 to 11 mM decreased force to approximately 20% of initial force (P < 0.001). Addition of exogenous CGRP (10(-9) M), release of endogenous CGRP with capsaicin, or repeated electrical stimulation recovered force to 50-70% of initial force (P < 0.001). In all cases, force recovery could be almost completely suppressed by CGRP-(8-37). At 11 mM [K(+)](o), CGRP (10(-8) M) did not alter resting membrane potential or conductance but significantly improved action potentials (P < 0.001) and increased the proportion of excitable fibers from 32 to 70% (P < 0.001). CGRP was shown to induce substantial force recovery with only modest Na(+)-K(+) pump stimulation. We conclude that the excitation-induced force recovery is caused by a recovery of excitability, induced by local release of CGRP. The data suggest that the recovery of excitability partly was induced by Na(+)-K(+) pump stimulation and partly by altering Na(+) channel function.     

Biosynthesis and degradation of anandamide and 2-arachidonoylglycerol and their possible physiological significance

N -arachidonoylethanolamine (anandamide) was the first endogenous cannabinoid receptor ligand to be discovered. Dual synthetic pathways for anandamide have been proposed. One is the formation from free arachidonic acid and ethanolamine, and the other is the formation from N -arachidonoyl phosphatidylethanolamine (PE) through the action of a phosphodiesterase. These pathways, however, do not appear to be able to generate a large amount of anandamide, at least under physiological conditions. The generation of anandamide from free arachidonic acid and ethanolamine is catalyzed by a degrading enzyme anandamide amidohydrolase/fatty acid amide hydrolase operating in reverse and requires large amounts of substrates. As for the second pathway, arachidonic acids esterified at the 1-position of glycerophospholipids, which are mostly esterified at the 2-position, are utilized for the formation of N -arachidonoyl PE, a stored precursor form of anandamide. In fact, the actual levels of anandamide in various tissues are generally low except in a few cases. 2-Arachidonoylglycerol (2-AG) was the second endogenous cannabinoid receptor ligand to be discovered. 2-AG is a degradation product of arachidonic acid-containing glycerophospholipids such as inositol phospholipids. Several investigators have demonstrated that 2-AG is produced in a variety of tissues and cells upon stimulation. 2-AG acts as a full agonist at the cannabinoid receptors (CB1 and CB2). Evidence is gradually accumulating and indicates that 2-AG is the most efficacious endogenous natural ligand for the cannabinoid receptors.In this review, we summarize the tissue levels, biosynthesis, degradation and possible physiological significance of two endogenous cannabimimetic molecules, anandamide and 2-AG.     

The release of ATP triggered by transmitter action and its possible physiological significance: retrograde transmission.

1. When a slice of electric organ of Torpedo is stimulated and superfused with a solution containing a firefly lantern extract, it is possible to measure the release of ATP after each nerve impulse as a light emission. 2. The postsynaptic action of released ACh induces the release of ATP by the postsynaptic cell. Most of the released ATP is of postsynaptic origin. 3. Ion fluxes associated with depolarization, or depolarization itself, trigger the release of ATP from postsynaptic and presynaptic membranes (synaptosomes). 4. ATP is able to block ACh release; a postsynaptic "retrograde transmission" able to control presynaptic transmitter release is possible.     

Circadian variations of adenosine level in blood and liver and its possible physiological significance

The role of adenosine as a possible physiological modulator was explored by measuring its concentration in different tissues during a 24-hour period. Initially the circadian variations of adenosine and other purine compounds such as inosine, hypoxanthine, uric acid and adenine nucleotides were studied in the rat blood. A daily cyclic response was observed, with low levels of adenosine from 08.00 - 20.00 h, followed by an increase from this time on. Inosine and hypoxanthine levels were elevated during the day and low at night. The uric acid changes observed indicate that the decrease in purine catabolism coincides with a decrease in inosine and hypoxanthine levels and an increase in adenosine. The blood adenine nucleotides, energy charge and phosphorylation potential remained constant during the day and showed oscillatory changes during the night. Similar studies were made in the liver, a primary source of circulating purines. Liver adenosine was high during the night while inosine and hypoxanthine remained low along the 24 hours. The results suggest that liver purine metabolism might participate in the maintenance and renewal of the blood purine pool and in the energy state of erythrocytes in vivo.     

Metals and phosphate in the chloragosomes of Lumbricus terrestris and their possible physiological significance

Summary The chloragog cells of the earthworm Lumbricus terrestris contain numerous granules, chloragosomes, which were analyzed for metals and phosphate by histochemistry, by use of an electron microscope X-ray microprobe (EMMA), and by chemical analysis of chloragosome preparations. Inorganic and organic phosphate each accounts for about 3% of the chloragosome dry mass, Ca for 2–3%, Zn for 1–3% and Mg for 0.2–0.4%. Carbonate is not present in chloragosomes. The average molar ratios CaMgZntotal PO₄ are 10.10.31. The CaPO₄ ratio is fairly constant (correlation coefficient 0.99), while the ZnPO₄ ratio varies considerably. It is concluded that Ca is bound in the form of inorganic CaHPO₄ and organic ROPO ₃Ca (or possibly Ca-polyphosphate complexes). Mg may also be phosphate-bound, while Zn probably is not. Chemical analysis of the calciferous glands revealed a high concentration of Ca, small amounts of Mg and phosphate, but no Zn. It is concluded that Zn is not excreted through the calciferous gland.Storage of Ca in the chloragocytes and excretion of CaCO₃ by the calciferous gland may be physiologically linked. Regulation of the concentrations of Ca and HCO₃ ^–ions in the blood and coelomic fluid may assist in equalization of osmotic pressures during dehydration and rehydration. This regulation may be a major function of the chloragosomes.The chloragosomes were discussed in relation to the spherites of various arthropods and molluscs and to the cytosomes of anoxia-tolerating molluscs.I wish to thank Theodore A. Hall for the use of the EMMA-4 microprobe facility, T.C. Norrnann for help in performing the microprobe analysis, Bruno Hansen for the improved zinc determination method and Annette Prentø for performing the chemical analyses. This work was supported by the Danish Natural Science Research Council (grant 511-3522). The EMMA-4 facility is supported by a grant from the British Science Research Council     

Villin is a possible marker of receptor cells in frog taste organs

We investigated lingual taste organs of four frog species mainly by means of fluorescence immunohistochemistry for villin, calbindin, and serotonin. Cells immunoreactive for villin appeared in the taste organs of all the species used. These villin-immunostained cells were basoapically elongated in shape and extended up to the apical surface. They were also immunoreactive for calbindin. On the other hand, serotonin-immunoreactive cells, identified as Merkel-like basal cells, were immunonegative for villin. Considering the present results combined with those of studies by other research groups, the villin-immunostained cells were postulated to function as taste receptors.     

Electrical properties and gustatory responses of various taste disk cells of frog fungiform papillae

We compared the electrical properties and gustatory response profiles of types Ia cell (mucus cell), Ib cell (wing cell), and II/III cell (receptor cell) in the taste disks of the frog fungiform papillae. The large depolarizing responses of all types of cell induced by 1 M NaCl were accompanied by a large decrease in the membrane resistance and had the same reversal potential of approximately +5 mV. The large depolarizing responses of all cell types for 1 mM acetic acid were accompanied by a small decrease in the membrane resistance. The small depolarizing responses of all cell types for 10 mM quinine-HCl (Q-HCl) were accompanied by an increase in the membrane resistance, but those for 1 M sucrose were accompanied by a decrease in the membrane resistance. The reversal potential of sucrose responses in all cell types were approximately +12 mV. Taken together, depolarizing responses of Ia, Ib, and II/III cells for each taste stimulus are likely to be generated by the same mechanisms. Gustatory depolarizing response profiles indicated that 1) each of Ia, Ib, and II/III cells responded 100% to 1 M NaCl and 1 mM acetic acid with depolarizing responses, 2) approximately 50% of each cell type responded to 10 mM Q-HCl with depolarizations, and 3) each approximately 40% of Ia and Ib cells and approximately 90% of II/III cells responded to 1 M sucrose with depolarizations. These results suggest that the receptor molecules for NaCl, acid, and Q-HCl stimuli are equivalently distributed on all cell types, but the receptor molecules for sugar stimuli are richer on II/III cells than on Ia and Ib cells. Type III cells having afferent synapses may play a main role in gustatory transduction and transmission.     

Glutamate dehydrogenases from tissues of the ribbed mussel Modiolus demissus: ADP activation and possible physiological significance.

Glutamate dehydrogenase (E.C. 14.1.3) was localized in the mitochondria from heart, gill, mantle and hepatopancreas of this euryhaline bivalve mollusc. Activity levels were low (0.1-0.4 mumoles/min/g wet weight) in all tissues when assayed in the glutamate forming direction. Partially purified gill mitochondrial GDH was most active at pH 8.5. The rate in the glutamate deaminating direction was 10-20% of the rate in the glutamate forming direction. ADP at apparent Ka concentrations of micrometer (glutamate formation) and 170 micrometer (glutamate deamination) enhanced GDH activity, 8- and 4-fold respectively. GDH, in vivo, is probably in the activated form and appears to function in glutamate synthesis rather than ammonia formation. However, based on the low activities obtained, the role of GDH in salinity induced amino acid synthesis seems minimal.     

A ligand-induced conformational change of yeast dipeptidase at physiological pH: kinetic consequences and possible regulatory significance.

The hydrolysis of dipeptides by purified yeast dipeptidase (EC 3.4.13.?) shows marked deviations from Michaelis-Menten kinetics over a wide range of pH. Quite anomalous kinetics is observed between pH 6 and 7, indicating a drastic change in the enzyme's properties. A reasonable explanation is provided by the assumption of a conformational transition brought about either by pH shifts or, at a constant pH, by changes in the substrate concentration. The transition, which may have a half-life on the order of minutes under appropriate conditions, is a distinctly cooperative process, with a dependence on ligand concentration higher than first order. The two forms of the enzyme differ clearly from each other with respect to various properties. The magnitudes and pH dependence of the kinetic parameters as well as the type of inhibition (or activation) exerted by amino acids and other ligands are different, as are their heat stabilities and the rates of inactivation by photooxidation of proteolytic degradation. Neither the molecular weight nor the gross conformation of the enzyme changes during the transition, so it seems to be due to a local isomerization affecting mainly the geometry of the active site. The sensitivity of dipeptidase to changes in the concentrations of substrates and other ligands is most pronounced exactly at the values of pH known to prevail in the living yeast cell. Thus the observed effects, which modulate dipeptidase activities within wide and limits, according to the amounts of dipeptides and amino acids present, are likely to play a role in the regulation of the enzyme in vivo.     

Interaction of lactate dehydrogenase with structural cell components: possible physiological significance]

Reversible binding of cytoplasmic enzymes to structural elements of the cell is one of mechanisms of in vitro regulation of enzyme properties. The results on lactate dehydrogenase interactions with myofibrillar proteins and membranes and the changes in enzyme properties induced by these interactions (modification of kinetic parameters and stability) are analyzed. A hypothesis is proposed concerning the functional role of reversible lactate dehydrogenase interactions with structural components of the cell during glycolysis activation.     

Mechanisms of blockade of glutamate receptors channels: the significance for structural and physiological investigations

The mechanism of blocking effect of phenylcyclohexyl derivative, IEM-1925, on ionotropic glutamate receptors of the NMDA and AMPA types has been studied on the rat isolated brain neurons. The whole-cell configuration of patck clanp recording technique was used equilibrium conditions and -80 mV holding potential, the IEM-1925 manifests nonselective action on open channels of both receptors. However, the prominent differences in the mechanism of the blocking effect were revealed. Although IEM-1925 can not enter the closed channels of both types, its molecule are able to leave closed channels of the AMPA but not the NMDA receptors. Hyperpolarization reduces removal of blocker from the open channels of the NMDA receptors. Contrary to that, hyperpolarization facilitates going out of the IEM-1925 to cytozol from both open and closed channels. Evidently, the bloker can pass through the AMPA receptor channels into the cell, and the gating mechanism of these channels is located above the binding site for the blocker. The blocking action of the IEM-1925 on the NMDA and AMPA receptors was compared with its potency to weaken the tremor evoked by subcutaneous injection of arecoline to mice. The observed differences in the mechanisms of action help to explain the ambiguous effects of channel blocking drugs on experimental models of pathological processes.