Gastropod mollusc aliphatic alcohol oxidase: subcellular localisation and properties

The digestive gland and other tissues of several species of terrestrial gastropod mollusc contain an aliphatic alcohol oxidase activity (EC1.1.3.13). The enzyme is FAD dependent, consumes oxygen and generates hydrogen peroxide and the corresponding aldehyde. Saturated primary alcohols are favoured as substrates with octanol preferred with an apparent K_m of 3–4 μM. The activity is clearly distinguishable from previously reported molluscan aromatic alcohol oxidase (EC1.1.3.7) on the basis of FAD dependence, sensitivity to heat treatment and high salt concentration and with regard to substrate preferences. The aliphatic alcohol oxidase is membrane associated and most likely localised to the endoplasmic reticulum. Extraction of membranes with 1% Igipal solubilises the enzyme in active form. This enzyme is a further example of an oxidase apparently restricted to molluscs.     

A new property of twitchin to restrict the “rolling” of mussel tropomyosin and decrease its affinity for actin during the actomyosin ATPase cycle

A new evidence on the regulatory function of twitchin, a titin-like protein of molluscan muscles, at muscle contraction has been obtained at studying the movements of IAF-labeled mussel tropomyosin in skeletal ghost fibers during the ATP hydrolysis cycle simulated using nucleotides and non-hydrolysable ATP analogs. For the first time, myosin-induced multistep changes in mobility and in the position of mussel tropomyosin strands on the surface of the thin filament during the ATP hydrolysis cycle have been demonstrated directly. Unphosphorylated twitchin shifts the tropomyosin towards the position typical for muscle relaxation, decreases the tropomyosin affinity to actin and inhibits its movements during the ATPase cycle. Phosphorylation of twitchin by the catalytic subunit of protein kinase A reverses this effect. These data imply that twitchin is a thin filament regulator that controls actin-myosin interaction by “freezing” tropomyosin in the blocked position, resulting in the inhibition of the transformation of weak-binding states into strong-binding ones during ATPase cycle.     

Effect of Male Accessory Gland Products on Egg Laying in Gastropod Molluscs

In internally fertilizing animals, seminal fluid is usually added to the spermatozoa, together forming the semen or ejaculate. Besides nourishing and activating sperm, the components in the seminal fluid can also influence female physiology to augment fertilization success of the sperm donor. While many studies have reported such effects in species with separate sexes, few studies have addressed this in simultaneously hermaphroditic animals. This video protocol presents a method to study effects of seminal fluid in gastropods, using a simultaneously hermaphroditic freshwater snail, the great pond snail Lymnaea stagnalis, as model organism. While the procedure is shown using complete prostate gland extracts, individual components (i.e., proteins, peptides, and other compounds) of the seminal fluid can be tested in the same way. Effects of the receipt of ejaculate components on egg laying can be quantified in terms of frequency of egg laying and more subtle estimates of female reproductive performance such as egg numbers within each egg masses. Results show that seminal fluid proteins affect female reproductive output in this simultaneous hermaphrodite, highlighting their importance for sexual selection.     

Alkaline earth metal content of human bones at the site of «S'Illot des Porros» (Iron age,Mallorca, Spain)

The aim of this study is to establish the basic diet of the people inhumed at the site of Porros by analysing some of the alkaline earth metals present in human and animal bones. The site is a Talayotic necropolis established in the small island of «S'Illot des Porros» (Mallorca, Spain) during the 6th to 2nd century B.C. In this island the only evidence of human activity to be found is the necropolis; the corresponding settlement site is unknown. The results show that the diet of these people was based on a fundamentally marine economy perhaps mollusc collecting. This outcome agrees with a coastal location for the settlement site.     

Neural correlates of settlement in veliger larvae of the gastropod,Crepidula fornicata

Settlement behavior of molluscan veliger larvae prior to metamorphosis requires cessation of swimming, accomplished by arrest of prototrochal cilia on the margin of the velum (the larval swimming organ). Ciliary arrest in larvae of gastropods is mediated by an action potential that occurs synchronously across the velum as a consequence of electrical coupling between the prototrochal ciliated cells. We developed a preparation for extracellular recording of such ciliary arrest spikes from intact swimming and crawling veliger larvae of the caenogastropod Crepidula fornicata, using a fine wire electrode. Ciliary arrest spike rates during bouts of substrate crawling were significantly higher than those recorded during preceding swimming periods in larvae that were competent for metamorphosis, but not in precompetent larvae. Spike rates were similar on clean polystyrene substrates, and on substrates that had been coated with a natural cue for metamorphosis (mucus from conspecific adults). We used immunohistochemical methods to localize neuromodulators that might regulate the function of velar cilia. Labeled terminals for serotonin, FMRFamide, and tyrosine hydroxylase (an enzyme for catecholamine synthesis) were located in positions consistent with modulatory effects on the prototrochal ciliated cells. Prototrochal ciliary arrest spike rates and beat frequencies were measured in isolated velar lobes from competent larvae, which were exposed to serotonin, FMRFamide, and dopamine (10^?5 mol L^?1). Serotonin abolished arrest spiking and increased beat frequency; dopamine also increased beat frequency, and FMRFamide depressed it. Competent larvae tested in a small static water column swam to the top of the column when exposed to serotonin, but occupied lower positions than controls when in the presence of dopamine and FMRFamide. The larval nervous system appears to regulate velar functions that are critical for settlement behavior, and is likely to do so by integrating different sensory modalities in an age‐dependent manner.     

Respiratory behavior in the pond snail Lymnaea stagnalis

Summary This study describes the neural basis of respiratory behavior in a pulmonate mollusc, Lymnaea stagnalis. We describe and identify muscles of the respiratory orifice (pneumostome) and mantle cavity as well as relevant motor neurons innervating these muscles. All of these identified motor neurons are active during spontaneously occurring respiratory behavior and a sporadically occurring synaptic input, termed Input 3, controls the activities of these motor neurons. This spontaneous input can also be recorded from isolated brain preparations, suggesting that the respiratory motor program is generated centrally. However, evidence is also presented that in semi-intact preparations the role of peripheral feedback is important for the initiation and termination of respiratory behavior in Lymnaea.     

Evidence for the short-term regulation of glycolytic flux in the isolated perfused ventricle of the land snail Helix lucorum (L.) after treatment with serotonin (5-hydroxytryptamine)

The glycolytic flux and the regulation of phosphofructokinase (PFK) activity by fructose 2,6-bisphosphate and covalent modification was investigated in isolated ventricles of land snail Helix lucorum perfused with or without serotonin. Serotonin evoked a significant increase in the level of glycolytic intermediates and a threefold increase of glycolytic flux. Studies of saturation curves of PFK for the substrate fructose 6-phosphate at pH similar to intracellular pH of heart muscle showed that serotonin increases enzyme sensitivity to activation by fructose 6-phosphate. Moreover, PFK preparations from ventricles perfused with serotonin exhibited lower K _a values for the activators AMP and fructose 2,6-bisphosphate, compared with the enzyme preparations from serotonin-untreated ventricles. The results suggest that PFK was converted to a more active form when exposed to serotonin. In vitro experiments of PFK phosphorylation showed that the conversion of the enzyme to a more active form was possibly due to its phosphorylation by an endogenous cyclic-AMP-dependent protein kinase. The concentration of fructose 2,6-bisphosphate increased in serotonin-treated ventricles and it exerted a synergistic effect with AMP on the activation of PFK. The bound fraction of glycolytic enzymes increased in the serotonin-treated ventricles only after the 4th min of perfusion. The results suggest that the stimulation of glycolytic flux in the ventricles of H. lucorum in the first minutes of perfusion with serotonin was partly due to the activation of PFK via enzyme molecule covalent modification and to increase of fructose 2,6-bisphosphate. Accepted: 8 April 1997     

GABA-Mediated Synaptic Interaction Between the Visual and Vestibular Pathways of Hermissenda

Abstract: The synaptic convergence of the eyes and the vestibular hair cells in the nudibranch mollusc Hermissenda has been shown previously to mediate the learning of simple visual-vestibular associations. The neurotransmitter mediating this interaction between the visual and vestibular organs was characterized. HPLC chromatography, confirmed by mass spectroscopic analysis, demonstrated endogenous GABA in the statocysts, in a concentration approximately 150 times greater than in the whole CMS. Additional confirmation was provided by immunocytochemical localization of GABA in hair cell axons and branches that converge with photoreceptor terminal branches. Depolarization of the hair cells in the caudal region of the statocyst in response to positive current injection or vibratory stimulation caused a hyperpolarization and a cessation of the type B photoreceptor impulse activity. The inhibition of the B cell was unaffected by addition to the artificial sea water bath of the adrenergic antagonist yohimbine (250 μM), the cholinergic antagonist atropine (250 μM), and the serotonergic antagonist imipramine (50 μM). In contrast, the GABA_A antagonist bicuculline (250 μM) significantly reduced the inhibitory interaction. Moreover, the GABA reuptake inhibitor guvisine (250 μM)M) increased the hyperpolarization. Pressure microapplication of GABA (12.5 or 25 μM) onto the terminal branches of the B cell resulted in a concentration-dependent hyperpolarization and cessation of spikes in the B cell. Depolarization of the caudal hair cell, or direct GABA application, decreased input resistance across the B cell soma membrane. Moreover, removal of chloride from the extracellular solution reduced inhibition of the B cell induced by GABA application or hair cell stimulation. Furthermore, application of the GABA_B agonist baclofen hyperpolarized the type B cell and reduced or eliminated spontaneous impulse activity at the resting membrane potential. The reversal potentials for inhibition induced in all three procedures ranged from ?70 to ?80 mV and were consistent with mixed Cl^- and K⁺ conductances. These results implicate GABA as the endogenous neurotransmitter mediating visual-vestibular interactions in this animal, and suggest a possible role of GABA in visual-vestibular associative learning.     

Neuronal mechanisms underlying behavioral switching in a pteropod mollusc

Summary In the pteropod mollusc Clione limacina, wing retraction takes precedence over spontaneous and continuous swimming, a phenomenon here defined as behavioral switching. The wing retraction system is organized as a simple reflex in which wing mechanoreceptors activate a pair of retraction interneurons which in turn excite at least two pairs of retraction motoneurons.Activation of individual mechanoreceptors does not inhibit swimming or trigger wing retraction. A pair of retraction interneurons can fully suppress swimming when induced to fire at physiological frequencies, and may be both sufficient and necessary for swim inhibition.Retraction interneurons monosynaptically inhibit both swim interneurons and swim motoneurons. Retraction motoneurons inhibit swim motoneurons through a polysynaptic pathway.A model summarizing the neural circuitry underlying behavioral switching in Clione is presented. A comparison of this model with the behavioral choice model in Pleurobranchaea reveals that the overall neural mechanisms for behavioral choice and behavioral switching are similar as both involve dual function interneurons that not only activate their own motor pathway, but also inhibit the competing motor system. While inhibition is biased toward the afferent side of the competing circuit in behavioral choice, it is biased to the efferent side in behavioral switching.