Biochemical strategy of survival of the freshwater mollusc Lymnaea stagnalis at near-zero temperatures

Effect of an autumn-winter decrease of the environmental temperature on changes of the content of free amino acids and reducing sugars was studied in tissue fluids of the freshwater mollusc L. stagnalis. At a decrease of the temperature to 4 and 0 degrees C at the autumn period, concentration of free alanine rose several times; an increase of histidine, glutamate, glycine, and serine concentrations was less pronounced. Accumulation of methionine, leucine, isoleucine, tyrosine, and phenylalanine was revealed at 0 degree C. In the state of long hypobiosis (at 4 degrees C), pools of all amino acids fell 4-8 times; essential amino acids, except for lysine, were not detected at all. Both at the summer and at the autumn periods, high concentrations of free fructose and glucose were revealed. In the process of hypobiosis the fructose pool decreased almost 35, while the glucose pool--12 times. Maltose that was absent in summer was found at 4 and 0 degree C as well as after 2.5 months of hypobiosis. The changes of the studied parameters in L. stagnalis in response to hypothermia are compared with the corresponding parameters of changes in cryoresistant animals in response to negative temperatures.     

Communication compartments in the post-trochal ectoderm of the mollusc Lymnaea stagnalis

Cell-to-cell communication via gap junctions provides a pathway for the transfer of small molecules and ions which may be significant for control of metabolic cooperation, cell proliferation, and differentiation. We have assessed the patterns of gap junctional communication in embryos of the mollusc Lymnaea stagnalis during the subdivision of the post-trochal ectoderm into developmental domains. We have microinjected the tracer Lucifer Yellow CH and subsequently analyzed its transfer to other cells. The post-trochal ectoderm of mollucs develops the shell field, the foot, and the stomodeum anlagen. We have found that the cells within the separate anlagen are well dye-coupled but poorly coupled to cells of adjacent anlagen. These results indicate that in Lymnaea embryos the specification of the different developmental domains is associated with the development of corresponding dye-coupling compartments.     

Antioxidative protection in the central nervous ganglia of a mollusc Lymnaea stagnalis at modulation of activity of the NO-ergic system

In experiments on molluscs Lymnnaea stagnalis the state of antioxidative protection is studied in central nervous ganglia during a long-term activation (inhibition) of synthesis of nitric monoxide (NO) in the body. Effect of the blocker of NO-synthase N(G)-nitro-L-arginine (L-NNA) at the background of enhancement of pulmonary respiration has been established to be associated with a rise of levels of reduced glutathione and TBK-active products in the nervous tissue at preservation of a relatively high superoxide dismutase activity and a low glutathione peroxidase activity as compared with control group and the animals treated with the metabolic precursor of NO synthesis L-arginine. In spite of the revealed disturbances of balance of the body pro- and antioxidative system, DNA electrophoresis detected no products of its degradation, which can indicate the absence of massive programmed death of the nervous tissue cells in Lymnaea stagnalis during modulation of activity of the NO-ergic system.     

Effect of acute temperature change on lung respiration of the mollusc Lymnaea stagnalis

• 1.Temperature-dependent effects on respiratory behaviour as well as the corresponding temperature-dependent activities of identified neurons within the respiratory network of the pulmonate snail Lymnaea stagnalis were investigated.
• 2.Lymnaea lung ventilation terminated at low temperatures (under 10 °C) while temperature elevation increased ventilation rates. The respiratory central pattern generator (CPG) functioning was relatively quiescent at temperatures under 12.5±0.44 °C.
• 3.Identified CPG neurons (RPeD1, VD4, VD1/RPaD2) and the respiratory network motor neurons (Vi- and RPa-cells) were found to exhibit varied temperature-dependent electrophysiological parameters (action potential frequency and amplitude, resting potential value) between cell types.
• 4.The observed alterations in the electrical activity of the Lymnaea respiratory network neurons underlie the marked changes of respiratory behaviour observed in the intact animal during temperature changes.

     

Ultrastructural organization of giant neurones of the mollusc Lymnaea stagnalis under different environmental temperatures.

The ultrastructure of identified giant neurones of the visceral ring of Lymnaea stagnalis ganglion alters with the seasonal change of the animal and, experimentally, from the inactive physiological state (winter time or at +4 degrees C) to an active one (spring-summer time or at +18 degrees C). The ultrastructural organization of the active animal's neurones is characterized by morphological alteration pointing to an increased metabolic activity, viz., an increased number of nucleoli, an enlarged surface of nuclear membrane and an increase in the nuclear membrane pores, appearance of a zone of free ribosomes near the nuclear membrane, changing the structure of cytosomes, abundant granular endoplasmic reticulum, increase in the number of mitochondria.     

Pacemaking mechanism of the afterdischarge of the ovulation hormone-producing caudo-dorsal cells in the gastropod mollusc Lymnaea stagnalis

The ovulation hormone-producing caudo-dorsal cells (CDC) of Lymnaea stagnalis have three states of excitability (active, inhibited, and resting), which are related to the egg-laying cycle. Active state CDC produce a firing pattern of prolonged spiking activity (1 spike/2 s), which in the animal occurs shortly before egg laying. In preparations it is evoked as an afterdischarge upon repetitive stimulation of CDC. The afterdischarge is not synaptically driven, but rests on a pacemaking mechanism. CDC are silent in the inhibited and resting states, which follow egg laying. In these states the membrane potential is mainly dependent on [K⁺]₀. In the active state the ratio of the K⁺, Na⁺, and Ca²⁺ permeabilities has changed considerably, probably resulting from an increased permeability to Na⁺ and Ca²⁺. The firing rate in the afterdischarge is dependent on the membrane potential, which is confirmed experimentally by varying [K⁺]₀.[Na⁺]₀ and [Ca²⁺]₀ directly influence the firing rate. Firing stops in Na⁺-free saline, but is enhanced by Ca²⁺-free or high-Mg²⁺ saline. TTX does not affect firing. Relatively high concentrations of Co²⁺ and La³⁺ (2 × 10^?3M) strongly inhibit CDC. Regular firing can be changed into bursting by various means, such as high K⁺ or addition of 1 mM Ba²⁺. Bursting normally occurs at the beginning of the afterdischarge. Postburst hyperpolarizations are reduced in Ca²⁺-free saline and by low Co²⁺ (10^?4-5 10^?4M). Active CDC are driven by a pacemaking mechanism constituted by a voltage-dependent Na⁺/Ca²⁺ channel and a Ca²⁺-dependent K⁺ channel, thus resembling that of bursting pacemakers. The pacemaking mechanism is inactive in the resting and inhibited state.     

Transmitter-dependent involvement of the respiratory interneurons in the locomotor rhythm in the pulmonate mollusc Lymnaea

Pedal cell RPeD1 of the pond snail L. stagnalis becomes involved in a central rhythm identified as an activity of the central pattern generator (CPG) for locomotion. The RPeD1 rhythm developed as driven by a synaptic input in isolated CNS preparations treated with 0.05 mM serotonin (5HT) or 0.1 mM 5-hydroxytryptophan (5HTP). The 5HT-induced co-ordinated rhythmic activity was retained by each of two pedal ganglia after complete isolation thus suggesting that the respective CPG lies entirely within the pedal portion of the CNS and is paired. The findings suggest that the RPeD1 switching from one network to another represents a neurotransmitter-dependent phenomenon.     

Molecular cloning of G protein alpha subunits from the central nervous system of the mollusc Lymnaea stagnalis.

The central nervous system of the pond snail, Lymnaea stagnalis, contains many large, identified neurons which can be easily manipulated making it an advantageous model system to elucidate in vivo the architecture of neuronal signal transduction pathways. We have isolated three cDNA clones encoding G protein alpha subunits that are expressed in the Lymnaea CNS, i.e. G alpha o, G alpha s and G alpha i. The deduced proteins exhibit a very high degree of sequence identity to their vertebrate and invertebrate counterparts. The strong conservation of G protein alpha subunits suggests that functional insights into G protein-mediated signalling routes obtained through the experimental amenability of the Lymnaea CNS will have relevance for similar pathways in the mammalian brain.     

Effects of intracellular pH and calcium activity on ion currents in internally perfused neurons of the snail Lymnaea stagnalis

The suction pipet method of intracellular dialysis and voltage clamp of cells has proven extremely useful in analysing the electrical properties of cells too small for the application of conventional microelectrode techniques and in larger cells for studying the effects of alterations in the internal ionic composition. Using neurons of the snail Lymnaea stagnalis, we have analysed several problems involved in the latter application of this technique and present several solutions to them. One major problem centers around the degree of control over the ionic composition of the cytoplasm achieved by altering the pipet solution. Using ion-sensitive microelectrodes during internal dialysis, we found that the efficiency of exchange between pipet and cytoplasm was much poorer for highly buffered ions such as H+ and Ca2+, than for K+, for example. Special precautions are described that can help this situation. The second problem involves the study of the effects of low internal pH on ion-channel properties. We summarize evidence for a specific voltage-dependent hydrogen ion channel, current through which becomes prominent at low internal pH. We analyse how the presence of this heretofore unrecognized current can seriously confuse the results of experiments designed to study the effects of low internal pH on other voltage-dependent currents.     

Effects of halothane on feeding motor activity in the snail Lymnaea stagnalis

Snails exposed to the general anaesthetic halothane show an increase in biting plus mouthing movements. Perfusion of the isolated CNS with halothane leads to a period of increased spiking activity, followed by suppression of activity in identified feeding motoneurones in the buccal ganglia. Synaptic inputs to motoneurones from interneurones of the buccal feeding pattern generator are differentially affected. Possible mechanisms underlying the generation of motoneuronal bursting in the presence of halothane are examined.     

The rate of oxygen consumption during embryogenesis of Lymnaea stagnalis (Gastropoda)

We studied the rate of oxygen consumption by the Lymnaea stagnalis embryos. The rate of oxygen consumption increased consistently during embryogenesis. The volume specific rate of oxygen consumption increased initially from the early cleavage stages until the gastrula stage and then decreased gradually to the eclosion of snails. There are three periods in embryogenesis of L. stagnalis, which differ in the coefficients of allometric dependence between the rate of oxygen consumption and volume of embryos: (1) early embryogenesis, when the increase in the rate of oxygen consumption is not accompanied by the growth of volume of the embryos; (2) larval period (trochophore and veliger stages; exponential coefficient k = 0.514), and (3) postlarval period (exponential coefficient k = 0.206).     

The rate of oxygen consumption during embryogenesis of Lymnaea stagnalis (Gastropoda)

We studied the rate of oxygen consumption by the Lymnaea stagnalis embryos. The rate of oxygen consumption increased consistently during embryogenesis. The volume specific rate of oxygen consumption increased initially from the early cleavage stages until the gastrula stage and then decreased gradually to the eclosion of snails. There are three periods in embryogenesis of L. stagnalis, which differ in the coefficients of allometric dependence between the rate of oxygen consumption and volume of embryos: (1) early embryogenesis, when the increase in the rate of oxygen consumption is not accompanied by the growth of volume of the embryos; (2) larval period (trochophore and veliger stages; exponential coefficient k = 0.514), and (3) postlarval period (exponential coefficient k = 0.206).     

Regulation of secretory activity in the albumen gland of the pulmonate snail Lymnaea stagnalis (L.)

The secretory activity of the albumen gland of the freshwater snail Lymnaea stagnalis was studied morphometrically (both at the light- and at the electron-microscope level) and biochemically under the following experimental conditions: (1) glandular tissue was implanted into acceptor snails and the glandular activity of the implants was compared to that of the glands of the donors and acceptors; (2) glandular activity was measured at various periods after oviposition; and (3) the activity was measured during a 24 h cycle (diurnal activity). The results indicate that cellular release of secretion material is regulated by a nervous mechanism, whereas synthetic activity is under hormonal control.