Tubular polymers derived from Helix pomatia beta-hemocyanin.

Upon trypsinolysis Helix pomatia beta-hemocyanin forms long tubular structures, which appear to be linear polymers of hemocyanin molecules from which the collar structure has been removed. Polyacrylamide gel electrophoresis in the presence of sodium dodecylsulfate shows that only few peptide bonds are hydrolyzed by trypsin. The structure of the polymers has been investigated by electron microscopy, combined with optical diffraction. Preliminary X-ray diffraction data are presented. Functional properties of the polymers are similar to those of the native protein. Both show a calciumion-dependent co-operativity of oxygen binding and a Bohr effect. The results suggest that the collar of a hemocyanin molecule has no special function in the process of (co-operative) oxygen binding, different from that of the wall of the molecule.     

Binding of carbon monoxide to alpha-hemocyanin and beta-hemocyanin from Helix pomatia.

The binding of carbon monoxide to alpha and beta-hemocyanin from the snail Helix pomatia was studied under equilibrium conditions. Homotropic interactions upon carbon monoxide binding were much weaker than upon the binding of oxygen. Heterotropic interactions (Bohr effect and calcium-ion effect), however, were just as strong as in the case of the binding of oxygen. For alpha-hemocyanin a linkage has been observed between the binding of carbon monoxide and a change in quaternary structure of the protein.     

Kinetics of the Bohr effect in the reaction of Helix pomatia beta-hemocyanin with oxygen.

The timecourse of the uptake of Bohr protons during oxygenation of β-hemocyanin from the vineyard snail Helix pomatia has been studied. It may be concluded that all the Bohr protons are taken up during the conformational change of the protein from the low- to the high oxygen affinity state, a process which appears to be rate limiting at high ligand concentration.     

Discrimination of tertiary and quaternary Bohr effect in the O2 binding of Helix pomatia beta-hemocyanin

Simultaneous determination of proton uptake and oxygen binding has been carried out on Helix pomatia beta-hemocyanin under equilibrium conditions in the absence of buffer and at different initial pH values. Oxygen-binding isotherms of unbuffered H. pomatia beta-hemocyanin, in the presence of phenol red as pH indicator, have been determined employing a thin-layer apparatus. Application of this very accurate technique allows monitoring of proton uptake (or release) coupled to O2-binding also at extremes of saturation which are often difficult to explore and analyze. The data have been analyzed within the framework of the cooperon model (M. Brunori, M. Coletta and E. Di Cera, Biophys. Chem. 23 (1986) 215) and compared with those obtained in the presence of buffer. Comparison of pH changes with ligand binding of the T state over all the saturation range has allowed us to discriminate and obtain quantitative estimates of the Bohr protons associated with both oxygenation of the T state and quaternary allosteric transition; no protons are taken up or released during oxygenation of the R state. These results differ quantitatively from those obtained in the presence of buffer, which alters significantly the T state contribution to the overall Bohr effect.     

Fluorescence study of steroid hormone binding activity of Helix pomatia agglutinin

Helix pomatia agglutinin (HPA) is a N-acetylgalactosamine (GalNAc) binding lectin, found in the reproductive gland of a Roman snail. The present study has shown that HPA, in addition to its carbohydrate binding capacity possesses a hydrophobic binding activity. This protein binds with high affinity (k(D)=1.9-2.4 microM) steroid hormones: testosterone and progesterone, identified as putative ligands for the animal lectin HPA. Additionally, we have found that this lectin also interacts with adenine (k(D)=5.4+/-0.5 microM) and arylaminonaphthalene sulfonate TNS (k(D)=12+/-0.3 microM). Binding of HPA to hormones and adenine was accompanied by a significant increase of the intrinsic Trp fluorescence (up to 50%), characterizing the conformational changes in the lectin molecule. The hyperbolic shape of the binding curves indicated one high affinity site for the two steroid hormones and adenine, and more than one hydrophobic site for TNS, showed by the sigmoidal curve fit and Hill coefficient of (n(H)=1.5+/-0.2). Hormones and adenine compete for an identical binding site, suggested to occupy the central hydrophobic cavity of the HPA hexamer. Fluorescence resonance energy transfer (FRET) was applied to calculate the intramolecular distance between TNS and Trp chromophores.     

Effect of FMRFamide on the electrical and plastic properties of identified Helix pomatia neurons

Effect of the neuropeptide FMRFamide on two types of nerve cells differing in plastic properties: habituating and non-habituating to rhythmic intracellular stimulation, has been studied. FMRFamide causes a slow developing, continuously growing depolarisation and an increase of input resistance of the most part of habituating cells resulting in inhibition of their habituation to intracellular stimulation. No desensitisation of cells to the action of FMRFamide was observed. The data obtained by using Ca-ionophore, imidazole and caffeine show that the effect of the peptide may be caused by inhibition of Ca-dependent K-conductance and depends on cAMP metabolism. FMRFamide exerts a less pronounced action on non-habituating cells and does not change their plastic properties. Inhibition by FMRFamide of the habituation at the level of electroexcitable membrane may play a significant part in regulation of neuronal plasticity.     

Structure and properties of hemocyanins. XIV. Reassociation of Helix pomatia alpha-hemocyanin

Helix pomatia α-hemocyanin dissociates within minutes into $\text{1}\text{10}$-size and $\text{1}\text{20}$-size molecules, on increase of pH in the alkaline region.The rate and final state of reassociation of $\text{1}\text{10}$-size and $\text{1}\text{20}$-size molecules have been studied, by turbidity measurements and ultracentrifugation, on lowering of pH or on the addition of calcium ions.Reassociation of $\text{1}\text{10}\text{-size}$ molecules proceeds in two phases, with half-times in the order of minutes and one hour, respectively. The slow phase is linked to the disappearance of transitory intermediates, presumably dimers and tetramers of $\text{1}\text{10}$-size molecules.A hysteresis is observed in the final state of pH-dependent and Ca²⁺-dependent dissociation-reassociation.Reassociation of $\text{1}\text{20}$-size molecules depends on the initial (isomeric) state of these molecules. The F(fast sedimenting)-$\text{1}\text{20}$-size molecules reassociate almost completely to whole molecules, whereas the S(slow sedimenting)-form does not reassociate at all.     

Parvalbumin-immunoreactive neurons in the brain of Helix pomatia

Parvalbumin-immunoreactive material was detected in the central nervous system of the snail, Helix pomatia. Each ganglion investigated contained parvalbumin-immunoreactive neurons. The molecular weight of Helix parvalbumin-immunoreactive material as determined by Western blots is about 40 kilodaltons. ⁴⁵Ca²⁺ overlays showed that this protein binds Ca²⁺. In contrast to vertebrates, in Helix neurons parvalbuminlike material was not colocalized with the neurotransmitter gamma-aminobutyric acid (GABA).     

Electrical properties and cell-to-cell communication of the salivary gland cells of the snail, Helix pomatia

The aim of the present study was to assess the cellular mechanism of secretion in the salivary gland of the snail, Helix pomatia, using electrophysiological, electron microscopic and immunohistochemical techniques. A homogeneously distributed membrane potential (-56.6 +/- 9.8 mV) was determined mainly by a K+ -electrochemical gradient and partly by the contribution of the electrogenic Na+ -pump and Cl- conductance. Low resistance electrical coupling sites were identified physiologically. Transmission electron microscopy and innexin 2 antibody revealed the presence of gap-junction-like membrane structures between gland cells. It is suggested that gap-junctions are sites of electrotonic intercellular communication, which integrate the gland cells into a synchronized functional unit in the acinus. Stimulation of the salivary nerve elicited secretory potentials (depolarization) which could be mimicked by local application of acetylcholine, dopamine or serotonin. In voltage-clamp experiments four major conductances were identified: a delayed rectifier (IK), a transient (IA) and a Ca2+ -activated outward K+ current (IK(Ca)) and Ca2+ -inward currents (ICa). It is suggested that one or more of these conductances may give rise to a stimulus activated secretory potential leading to excitation-secretion coupling and subsequent the release of the mucus from the gland cells.     

Food-attraction conditioning in the snail,Helix pomatia

Adult pulmonate snails (Helix pomatia) were released equidistant between two types of food, carrot and potato, respectively. Naive snails moved in different directions and did not locate either food above chance, although both foods were readily eaten upon direct contact. After a single carrot feeding episode, 75% of the carrot-fed snails moved directly towards the carrot and ate it. Conversely, potato-fed snails located the potato in 67% of the cases. Snails that were fed apple or lettuce behaved like naive animals, with the majority of animals (75% in both cases) locating neither the carrot nor the potato.The ability of snails to locate this particular food after a single feeding episode was maintained for at least 11 days, provided that the snails were not exposed to other foods in the interim. If the animals were fed a different food (but still tested for food-finding ability to the initially conditioned food) their orientation preference decreased gradually over a period of 5 days.Although the snails' orientation is based upon olfactory cues, exposure to food odor alone is not sufficient to enable food-finding; additional feeding related stimuli are necessary.These findings indicate that Helix do not possess a predisposition for the foods tested, and further suggest that processes underlying food-finding and food selection are strongly influenced by learning experiences. The conditioning phenomenon underlying food-finding behavior has been called Food-Attraction Conditioning, and appears to be a crucial link between the ecologies of learning and foraging behaviors. The accessibility of the snail's nervous system should permit neuronal analysis of the mechanisms underlying such a unique and complex learning phenomenon.     

Nerve cells of Helix pomatia during hypercapnia

Hypercapnia leading initially to activation of synaptic activity and of pace-maker mechanism is accompanied later by inactivation of the electro-excitable membrane and is completed by loss of chemosensitivity. Restoration of the properties of the neurone following transition to normal atmospheric air develops in reverse order. All hypercapnic changes of the properties of the electroexcitable and chemosensitive membrane take place at a constant level of the membrane potential which points to stability of K-Na-pump.