Lipochondria and the light response of Aplysia giant neurons

The ultrastructure, absorbance, and elemental content of lipochondria present in the cytoplasm of Aplysia giant neurons have been investigated before and after 30–1,200 sec doses of white light at intensities which produce saturated light responses. The effects of exposure to the calcium ionophore A-23187 and to EGTA were also examined. The lipochondria of nonilluminated neurons are membrane-bound, and contain lipids, protein, Na, K, Mg, Ca, Si, Cl, Br, P, and a pigment which is probably β-carotene. The cytoplasm appeared to have little pigment. When neurons were illuminated for 20 min, 60–70% of the lipochondria showed marked ultrastructural alterations, the most notable being the appearance of membranous material. Earlier changes which occur after 30 sec of illumination include the appearance of paracrystalline arrays and mottling. Less than 10% of lipochondria in nonilluminated neurons have a similar appearance. These effects were greatly enhanced in illuminated neurons exposed to the calcium ionophore or EGTA. In nonilluminated neurons, the ionophore also produced ultrastructural changes. In frozen specimens, the calcium content of the most electron dense lipochondria of illuminated neurons was reduced. Other elements which were counted were also reduced. The lipochondria are the main intracellular site of photopigment. They may also act as an intracellular source for calcium which, as the accompanying paper indicated, may mediate phototransduction in Aplysia neurons.     

Lipochondria and the light response of Aplysia giant neurons,.

The ultrastructure, absorbance, and elemental content of lipochondria present in the cytoplasm of Aplysia giant neurons have been investigated before and after 30-1,200 sec doses of white light at intensities which produce saturated light responses. The effects of exposure to the calcium ionophore A-23187 and to EGTA were also examined. The lipochondria of nonilluminated neurons are membrane-bound, and contain lipids, protein, Na, K, Mg Ca, Si, Cl, Br, P, and a pigment which is probably beta-carotene. The cytoplasm appeared to have little pigment. When neurons were illuminated for 20 min, 60-70% of the lipochondria showed marked ultrastructural alterations, the most notable being the appearance of membranous material. Earlier changes which occur after 30 sec of illumination include the appearance of paracrystalline arrays and mottling. Less than 10% of lipochondria in nonilluminated neurons have a similar appearance. These effects were greatly enhanced in illuminated neurons exposed to the calcium ionophore or EGTA. In nonilluminated neurons, the ionophore also produced ultrastructural changes. In frozen specimens, the calcium content of the most electron dense lipochondria of illuminated neurons was reduced. Other elements which were counted were also reduced. The lipochondria are the main intracellular site of photopigment. They may also act as an intracellular source for calcium which, as the accompanying paper indicated, may mediate phototransduction in Aplysia neurons.     

Immunocytochemical localization of a rhodopsin-like protein in the lipochondria in photosensitive neurons of Aplysia californica

Summary Polyclonal antibodies directed against squid opsin were used in immunocytochemical and immunoblot experiments to identify a rhodopsin-like protein in photosensitive neurons of Aplysia. Aldehyde-fixed abdominal and cerebral ganglia were embedded in paraffin for peroxidase anti-peroxidase analysis or used whole for immunofluorescence studies. Ganglia were embedded in Lowicryl K4M for electron-microscope immunocytochemistry. In both the cerebral and abdominal ganglia, light-microscope immunocytochemical results showed reaction product deposited around the neuronal cell periphery corresponding in position to the lipochondria. In the abdominal ganglion, the giant cell R2, located in the right rostral quarter, and neurons in the right caudal quarter were consistently labeled with anti-opsin. Electron-microscopic studies demonstrated ferritin-labeling of the lipochondria in R2 and other immunoreactive neurons. Immunoblot analysis of R2 and cerebral neuron extracts was used to identify two prominent immunoreactive protein bands at 85000 and 67500 molecular weight.     

Spectral characterization of the neuronal pigments of Aplysia juliana

Spectral analysis at liquid N₂ temperature of the circumesophageal ganglia of Aplysia juliana showed that carotenoids and a hemoglobin-like pigment are contained in concentrations of approx. 25 and 3 μM, respectively, in the whole ganglia. Microspectrophotometrical measurements of Aplysia neurons indicated that the carotenoids reside on lipochondria in a concentration of approx. 38 mM. In addition to lipochondria, two types of pigmented particulate having absorption maxima at about 512 and 525 nm, respectively, were found in the neurons. The neuronal carotenoids consist of violaxanthin, β-carotene and one minor component; among them the first occupies approx. 77% of total carotenoids. Two principal absorption maxima of the carotenoids, when existing in both ganglial homogenates and Triton X-100 extracts, show a red shift of 10 nm compared with those of free pigments in hexan. The red shift may be interpreted as due to the solvation of the carotenoids by surrounding lipids     

In vitro capsaicin-induced cytological changes and alteration in calcium distribution in giant serotonergic neurons of the snail Helix pomatia: a light- and electron-microscopic study

Morphological changes induced by capsaicin were studied in the serotonergic metacerebral giant neurons of the cerebral ganglia of Helix pomatia under in vitro conditions. Capsaicin at a concentration of 10^-4 M caused characteristic structural alterations in the giant serotonergic neurons but did not significantly influence serotonin immunoreactivity in the neurons. At the lightmicroscopic level, the most conspiciuous structural alterations were swelling of the cell bodies, which contained a swollen pale nucleus. Under the electron microscope, the nuclei,mitochondria and the cisternae of the endoplasmic reticulum were swollen in the capsaicin-affected metacerebral giant neurons. Electron-microscopic cytochemical techniques for calcium demonstration revealed electron-dense deposits in the swollen mitochondria and in the cisternae of the endoplasmic reticulum, suggesting an increased Ca²⁺ influx. The serotonergic metacerebral giant neurons could be labelled by cobalt (1 mM) in the presence of capsaicin (10^-4 M) suggesting that capsaicin opens the cation chanels of the capsaicin-sensitive neuronal membrane. The morphological and cytochemical alterations induced by capsaicin in the serotonergic metacerebral giant neurons of Helix pomatia closely resemble those induced in sensory neurons of mammalian dorsal root ganglion.This work was supported by OTKA grants No.: 2477, T016861, T017127 and ETT 587/93     

The Fine-Structural Localization of Phosphatases in Neurosecretory Cells Within the Ganglia of Certain Gastropod Snails

The neurosecretory cells in the cerebral ganglia of the snail,Planorbis trivolvis, have been examined for structural detailsand distribution of phosphatase activities. A more preliminarystudy on the localization of phosphatases in the neurosecretorycells of Helix aspersa has also been made. These neurons inboth species contain typical elementary neurosecretory granuleswhich appear to be elaborated or condensed in the Golgi saccules.Immature elementary granules are identifiable as "primary lysosomes"in that they contain acid phosphatase activity as well as nucleosidephosphatases. The mature elementary granules display no phosphataseactivity. Some saccules of the Golgi are also reactive for severalnucleoside phosphatases, including thiamine pyrophosphatase(TPPase). In Planorbis, TPPase is also present in the cisternaeof the endoplasmic reticulum. Larger, membrane bound, electron-densebodies (lipochondria) are found in close spatial associationwith the Golgi region. These also possess acid phosphatase;in addition, they contain nucleoside diphosphatases and (inPlanorbis) adenosine triphosphatase. Their content of acid phosphataseand the features of their fine structure indicate that theyare lysosomes akin to the dense bodies of vertebrate neurones. The significance and implications of these results are considered,as are other details of the neuronal and glial structure inPlanorbis.     

On the mechanism of stimulation of H+ transport in gastric mucosa by Ca++ ionophore A23187: I. Pathways for cytosolic calcium increase

The pathways for cytosolic Ca⁺⁺ increase under A23187 stimulation of H⁺ secretion were studied in the isolated gastric mucosa of the toad $\text{Bufo marinus}$. A23187 produced a more potent stimulation of secretion when added to the mucosal side which did not contain calcium. Measurements of ionophore incorporation by fluorometric methods indicated that A23187 incorporates into oxyntic cells intracellularly. The presence of divalent cations inhibited incorporation. This may be the reason for a more potent action when A23187 was added from the mucosal side. With-drawal of calcium from serosal solution largely inhibited the secretory response to A23187 added to the mucosal side. Reintroduction of calcium into the serosal side in the presence of ionophore elicited H⁺ secretion. The results are consistent with an uptake of A23187 from the mucosal side into cellular organelles and basolateral membranes. Calcium entry through the serosal side may be responsible for triggering secretion. Although A23187 likely releases calcium from intracellular stores, its rate of release may not be sufficient to bring about a full stimulation of secretion in serosal-Ca⁺⁺-free conditions.     

Cold resistance of the brain during hibernation. Temperature sensitivity of the partial reactions of the Na+, K+-ATPase.

The regulatory effect of calcium added in vitro on 25-hydroxycholecalciferol metabolism was studied in kidney mitochondria and in renal tubules from vitamin D-deficient chicks. The addition of calcium (0.05 – 0.2 mm) to mitochondrial suspensions prepared with calcium-chelating agents caused a marked and dose-related stimulation of 1-hydroxylation. A sharp decline in the activity was induced by higher concentrations of calcium (0.3 – 0.7 mm). A similar but less striking biphasic effect of calcium on 1-hydroxylation was observed in mitochondria prepared in the absence of calcium chelating agents. The effect of calcium was not a consequence of accelerated mitochondrial translocation of either exogenous NADP or Mg²⁺ but was related to mitochondrial calcium content. The addition of inhibitors of the calcium uptake, i.e., LaCl₃ or ruthenium red, or a calcium ionophore (A 23187) significantly inhibited the calcium-induced stimulation of the 1-hydroxylation reaction. Similar calcium effects were also observed in renal tubules isolated from intact, but not from parathyroidectomized, vitamin D-deficient chicks. These data strongly suggest that mitochondrial calcium plays an important role in the regulation of 1-hydroxylase activity in kidney.     

Intracellular calcium release at fertilization in the sea urchin egg.

Fertilization or ionophore activation of Lytechinus pictus eggs can be monitored after injection with the Ca-sensitive photoprotein aequorin to estimate calcium release during activation. We estimate the peak calcium transient to reach concentrations of 2.5–4.5 μM free calcium 45–60 sec after activation and to last 2$\text{3}\text{?}$ min, assuming equal Ca²⁺ release throughout the cytoplasm. Calcium is released from an intracellular store, since similar responses are obtained during fertilization at a wide range of external calcium concentrations or in zerocalcium seawater in ionophore activations. In another effort to estimate free calcium at fertilization, we isolated egg cortices, added back calcium quantitatively, and fixed for observation with a scanning electron microscope. In this way, we determined that the threshold for discharge of the cortical granules is between 9 and 18 μM Ca²⁺. Therefore, the threshold for the in vitro cortical reaction is about five times the amount of free calcium, assuming equal distribution in the egg. This result suggests that transient calcium release is confined to the inner subsurface of the egg.     

Active calcium transport and calcium-dependent membrane phosphorylation in human peripheral blood lymphocytes

The characteristics of the calcium pump were investigated in intact human peripheral blood lymphocytes /PBL/ and in inside-out vesicles prepared from their plasma membranes. Intact PBL were loaded with calcium by a short exposure to A23187 ionophore. After the elimination of the ionophore, calcium-loaded PBL produced an ATP-dependent, external lanthanum sensitive, uphill calcium extrusion. Calcium pump in intact PBL was insensitive to ouabain and /until cellular ATP was provided/ to oligomycin and dinitrophenol. Maximum calcium extrusion rate and the alkali cation sensitivity of the process were similar to those in human red cells. Calcium was partially sequestered by PBL, and this calcium could be released by A23187 ionophore only.Inside-out plasma membrane vesicles prepared from hypotonically lysed PBL showed and ATP + Mg²⁺-dependent uphill calcium uptake. This calcium transport was insensitive to ouabain, oligomycin, or dinitrophenol, while blocked by lanthanum and quercetin. Calmodulin significantly stimulated calcium pumping in EDTA-washed vesicles. ATP-dependent and -independent calcium uptake rates, respectively, showed different calcium concentration dependences.When PBL membrane vesicles were phosphorylated by γ ³²P-ATP, a calcium-induced, hydroxylamine-sensitive incorporation of ³²P was found in 120–150 000 molecular weight proteins. Depending on the way of membrane preparation, the molecular weight of the phosphoprotein was shifted. Similarly to that found in red cell membranes, sensitivity to calmodulin stimulation and partial proteolysis of the calcium pump molecule showed an inverse relationship.     

Calcium uptake and Ca2+-ATPase activity in goat spermatozoa membrane vesicles do not require Mg2+

Microsomal membrane vesicles isolated from goat spermatozoa contain Ca²⁺-ATPase, and exhibit Ca²⁺ transport activities that do not require exogenous Mg²⁺ .The enzyme activity is inhibited by calcium-channel inhibitors,e.g. verapamil and diltiazem, like the well known Ca²⁺ , Mg²⁺-ATPase. The uptake of calcium is ATP (energy)-dependent and the accumulated Ca²⁺ can be completely released by the Ca²⁺ ionophore A23187, suggesting that a significant fraction of the vesicles are oriented inside out     

P2Y1 Receptor Activation of the TRPV4 Ion Channel Enhances Purinergic Signaling in Satellite Glial Cells

Transient receptor potential (TRP) ion channels of peripheral sensory pathways are important mediators of pain, itch, and neurogenic inflammation. They are expressed by primary sensory neurons and by glial cells in the central nervous system, but their expression and function in satellite glial cells (SGCs) of sensory ganglia have not been explored. SGCs tightly ensheath neurons of sensory ganglia and can regulate neuronal excitability in pain and inflammatory states. Using a modified dissociation protocol, we isolated neurons with attached SGCs from dorsal root ganglia of mice. SGCs, which were identified by expression of immunoreactive Kir4.1 and glutamine synthetase, were closely associated with neurons, identified using the pan-neuronal marker NeuN. A subpopulation of SGCs expressed immunoreactive TRP vanilloid 4 (TRPV4) and responded to the TRPV4-selective agonist GSK1016790A by an influx of Ca²⁺ ions. SGCs did not express functional TRPV1, TRPV3, or TRP ankyrin 1 channels. Responses to GSK1016790A were abolished by the TRPV4 antagonist HC067047 and were absent in SGCs from Trpv4^−/− mice. The P2Y₁-selective agonist 2-methylthio-ADP increased [Ca²⁺]_i in SGCs, and responses were prevented by the P2Y1-selective antagonist MRS2500. P2Y₁ receptor-mediated responses were enhanced in TRPV4-expressing SGCs and HEK293 cells, suggesting that P2Y₁ couples to and activates TRPV4. PKC inhibitors prevented P2Y₁ receptor activation of TRPV4. Our results provide the first evidence for expression of TRPV4 in SGCs and demonstrate that TRPV4 is a purinergic receptor-operated channel in SGCs of sensory ganglia.     

SEROTONIN AND FREE AMINO ACID ANALYSIS OF GANGLIA AND ISOLATED NEURONES OF APLYSIA DACTYLOMELA

—The presence of serotonin and different amino acids was investigated in the ganglia and in isolated giant neurones of Aplysia dactylomela. With a few exceptions the pattern of substances was similar in all the ganglia. Of the many identified neurones studied only one giant neurone located in each cerebral ganglion was found to contain serotonin. GABA was detected in most extracts, including those of the serotonin-containing neurone, known cholinergic, and known neurosecretory neurones. Putrescine, recently detected in extracts of nervous tissue and isolated neurones of Helix, was not detected in Aplysia nervous tissue.     

The concentrations and thermodynamic activities of cations in intact Bryopsis chloroplasts

The internal cation levels of chloroplasts isolated from a green sea alga, Bryopsis maxima, were studied. Atomic absorption spectroscopy, combined with the determination of the sorbitol-impermeable and water-permeable spaces, revealed that chloroplasts contain an extremely high concentration of K⁺ and high levels of Na⁺, Mg²⁺ and Ca²⁺. A method was developed to estimate the thermodynamic activities of monovalent and divalent cations present in chloroplasts. pH changes induced by the addition of an ionophore (plus an H⁺ carrier), which makes the outer limiting membranes of chloroplasts permeable to both a cation and H⁺, were determined. Provided that the external pH was set equal to the internal pH, the internal concentration of the cation was estimated by determining the external cation concentration which gave rise to no electrochemical potential difference of the cation and hence no pH change on addition of the ionophore. The internal pH was determined by measuring distributions of radioactive methylamine and 5,5-dimethyloxazolidine-2,4-dione between the chloroplast and medium (Heldt, H.W., Werdan, K., Milovancev, M. and Geller, G. (1973) Biochim. Biophys. Acta 314, 224–241). The internal pH was also estimated by measuring pH changes caused by the disruption of the outer limiting membrane with Triton X-100. The results indicate that a significant part of the monovalent cations and most of the divalent cations are attracted into a diffuse layer adjacent to the negatively charged surfaces of membranes and proteins, or form complexes with organic and inorganic compounds present in the intact chloroplasts.     

FORMATION OF SEROTONIN BY ISOLATED SEROTONIN-CONTAINING NEURONS AND BY ISOLATED NON-AMINE-CONTAINING NEURONS

Isolated giant serotonin-containing neurons of the cerebral ganglia of Helix pomatia were shown to produce serotonin when incubated with 5-hydroxytryptophan (5-HTP) whereas cells of the buccal ganglia, which are non-amine-containing cells did not. The rate of production was comparable to that for Ach in the isolated neurons of Aplysia. The significance of these results is discussed.     

Biogenesis of the chloroplast phosphate translocator

Calcium-dependent proteolysis of several polypeptides from rat brain and synaptosomal cytosol was observed including proteolysis of polypeptides of M_r 340 000 and 300 000. These latter polypeptides comigrated with high-M_r microtubule-associated proteins of microtubule preparations from brain or synaptosomal cytosol. Calcium influx into intact synaptosomes due to depolarisation with high potassium or veratridine or treatment with the ionophore A23187 did not result in Ca²⁺-dependent proteolysis of any polypeptides. This may be due to the low calcium sensitivity of the protease since no proteolysis of the M_r 340 000 and 300 000 polypeptides was seen in synaptosomal cytosal at < 10 μM free Ca²⁺.     

Role of the DSC1 Channel in Regulating Neuronal Excitability in Drosophila melanogaster: Extending Nervous System Stability under Stress

Voltage-gated ion channels are essential for electrical signaling in neurons and other excitable cells. Among them, voltage-gated sodium and calcium channels are four-domain proteins, and ion selectivity is strongly influenced by a ring of amino acids in the pore regions of these channels. Sodium channels contain a DEKA motif (i.e., amino acids D, E, K, and A at the pore positions of domains I, II, III, and IV, respectively), whereas voltage-gated calcium channels contain an EEEE motif (i.e., acidic residues, E, at all four positions). Recently, a novel family of ion channel proteins that contain an intermediate DEEA motif has been found in a variety of invertebrate species. However, the physiological role of this new family of ion channels in animal biology remains elusive. DSC1 in Drosophila melanogaster is a prototype of this new family of ion channels. In this study, we generated two DSC1 knockout lines using ends-out gene targeting via homologous recombination. DSC1 mutant flies exhibited impaired olfaction and a distinct jumpy phenotype that is intensified by heat shock and starvation. Electrophysiological analysis of the giant fiber system (GFS), a well-defined central neural circuit, revealed that DSC1 mutants are altered in the activities of the GFS, including the ability of the GFS to follow repetitive stimulation (i.e., following ability) and response to heat shock, starvation, and pyrethroid insecticides. These results reveal an important role of the DSC1 channel in modulating the stability of neural circuits, particularly under environmental stresses, likely by maintaining the sustainability of synaptic transmission.     

The Swimmeret System of Crayfish: A Practical Guide for the Dissection of the Nerve Cord and Extracellular Recordings of the Motor Pattern

Here we demonstrate the dissection of the crayfish abdominal nerve cord. The preparation comprises the last two thoracic ganglia (T4, T5) and the chain of abdominal ganglia (A1 to A6). This chain of ganglia includes the part of the central nervous system (CNS) that drives coordinated locomotion of the pleopods (swimmerets): the swimmeret system. It is known for over five decades that in crayfish each swimmeret is driven by its own independent pattern generating kernel that generates rhythmic alternating activity ^1-3. The motor neurons innervating the musculature of each swimmeret comprise two anatomically and functionally distinct populations ⁴. One is responsible for the retraction (power stroke, PS) of the swimmeret. The other drives the protraction (return stroke, RS) of the swimmeret. Motor neurons of the swimmeret system are able to produce spontaneously a fictive motor pattern, which is identical to the pattern recorded in vivo ¹.The aim of this report is to introduce an interesting and convenient model system for studying rhythm generating networks and coordination of independent microcircuits for students’ practical laboratory courses. The protocol provided includes step-by-step instructions for the dissection of the crayfish’s abdominal nerve cord, pinning of the isolated chain of ganglia, desheathing the ganglia and recording the swimmerets fictive motor pattern extracellularly from the isolated nervous system.Additionally, we can monitor the activity of swimmeret neurons recorded intracellularly from dendrites. Here we also describe briefly these techniques and provide some examples. Furthermore, the morphology of swimmeret neurons can be assessed using various staining techniques. Here we provide examples of intracellular (by iontophoresis) dye filled neurons and backfills of pools of swimmeret motor neurons. In our lab we use this preparation to study basic functions of fictive locomotion, the effect of sensory feedback on the activity of the CNS, and coordination between microcircuits on a cellular level.     

Digger wasp versus cricket: mechanisms underlying the total paralysis caused by the predator's venom

The data presented here describe neurophysiological experiments addressing the question of cellular mechanisms underlying the total paralysis of locomotor behavior in crickets occurring after being stung by females of the digger wasp species Liris niger. The Liris venom effects have been studied by both in vivo recordings from identified neurons of the well-described giant fiber pathway and in vitro recordings from cultured neurons isolated from the terminal ganglion of crickets. The total paralysis of the prey is characterized by a general block of action potential generation as well as by a block of synaptic transmission. Intracellular recordings from neurons in intact ganglia under single electrode voltage-clamp conditions, as well as whole-cell patch-clamp recordings from cultured cricket neurons consistently show that the block of action potential generation by the Liris venom is due to a block of voltage-gated sodium inward currents in neurons of the stung ganglia. Furthermore, our data provide evidence that the Liris venom also blocks calcium currents in identified neurosecretory neurons. On the other hand, outward currents are not affected by the Liris venom. The in vitro recordings suggest that the Liris venom contains active venom components, which, at least for the observed block of inward currents, do not require a metabolic modification. Because venom application does not affect the ACh-induced EPSPs in giant interneurons, the Liris venom does not seem to influence the postsynaptic ACh receptors. The possible pre- and postsynaptic sites of venom action and the functional consequences on synaptic transmission within the giant fiber system are discussed.