Frequency and amplitude tuning of nematocyst discharge by proline

Force-dependent discharge of nematocysts in the sea anemone Haliplanella luciae (Verrill)

Sea anemones discharge cnidae ('stinging capsules' including nematocysts) to capture prey and to defend themselves. In the present study, we tested the relationship between the force of test probes striking feeding tentacles and discharge of microbasic p-mastigophore nematocysts into the test probes. In seawater alone, the response curve is bimodal with maximal discharge observed at 0.33 and 1.10 millinewtons (mN) and with minimal discharge at 1.50 mN. Upon activating chemoreceptors for N-acetylated sugars, maximal discharge is observed across a broad range of smaller forces from 0.16 to 0.9 mN before decreasing to a minimum at 1.50 mN. Likewise, in the presence of nearby vibrations at key frequencies, maximal discharge is observed over a broad range of smaller forces before decreasing to a minimum at 1.50 mN. It appears that sensory input indicating proximity of potential prey expands the range of small forces of impact that stimulate maximal discharge (i.e. to less than 1.10 mN) but not at larger forces of impact (i.e. at approximately 1.50 mN). Thus, contact by small prey would stimulate maximal discharge, and all the more so if such contact is accompanied by specific odorants or by vibrations at specific frequencies. Nevertheless, anemones would not maximally discharge nematocysts into large animals that blunder into contact with their tentacles.

Evidence for involvement of TRPA1 in the detection of vibrations by hair bundle mechanoreceptors in sea anemones

A homolog of TRPA1 was identified in the genome of the anemone, Nematostella vectensis (nv-TRPA1a), and predicted to possess six ankyrin repeat domains at the N-terminus and an ion channel domain near the C-terminus. Transmembrane segments of the ion channel domain are well conserved among several known TRPA1 polypeptides. Inhibitors of TRPA1 including ruthenium red decrease vibration-dependent discharge of nematocysts in N. vectensis and Haliplanella luciae. Activators of TRPA1 including URB-597 and polygodial increase nematocyst discharge in the absence of vibrations. Co-immunoprecipitation yields a band on SDS-PAGE gels at the predicted mass of the nv-TRPA1a polypeptide among other bands. Co-immunoprecipitation performed in the presence of antigenic peptide decreases the yield of this and several other polypeptides. In untreated controls, anti-nv-TRPA1a primarily labels the base of the hair bundle with some labeling also distributed along the length of stereocilia. Tissue immunolabeled in the presence of the antigenic peptide exhibits reduced labeling. Activating chemoreceptors for N-acetylated sugars induce immunolabel to distribute distally in stereocilia. In anemones, activating chemoreceptors for N-acetylated sugars induce hair bundles to elongate among several other structural and functional changes. Taken together, these results are consistent with the possibility that nv-TRPA1a participates in signal transduction of anemone hair bundles.

Repair of hair cells following mild trauma may involve extracellular chaperones

Sea anemones were subjected to mild trauma consisting of a 2 min immersion in calcium-depleted seawater. The trauma caused a loss of vibration sensitivity that spontaneously recovered within 50 min of returning the anemones to calcium containing seawater. Apparently, recovery is conferred by proteins contained in fraction gamma, a chromatographic fraction of homogenized mucus collected at the base of anemones allowed to recover from similar trauma. On silver stained SDS-PAGE gels, fraction gamma consists of a single band having an estimated mass of 55 kDa. Fraction gamma is alone sufficient to repair hair bundle mechanoreceptors in anemones. Its biological activity is enhanced in the presence of exogenously supplied ATP, but not GTP nor ADP-ribose. Biotinylated fraction gamma binds to hair bundles. The hypothesis that fraction gamma consists of Hsp60 proteins was tested. Commercial antibodies to Hsp60 label a band at 55 kDa in western blots. Hsp60 antibodies label hair bundles in traumatized anemones but not in untreated controls. Dilute Hsp60 antiserum (but not nonimmune serum) delays the spontaneous recovery of vibration sensitivity in anemones subjected to mild trauma. Thus, fraction gamma likely consists of Hsp60, or a Hsp60-like protein, that functions on the extracellular face of the plasma membrane to restore function to traumatized hair bundles.

The involvement of arl-5b in the repair of hair cells in sea anemones

The subcellular processes involved in repair of hair cells are not well understood. Sea anemones repair hair bundle mechanoreceptors on their tentacles after severe trauma caused by 1-h exposure to calcium-depleted seawater. Repair is dependent on the synthesis and secretion of large protein complexes named "repair proteins." A cDNA library on traumatized anemone tissue was probed using polyclonal antibodies raised to a specific chromatographic fraction of the repair protein mixture. An ADP-ribosylation factor-like protein, Arl-5b, was identified. The amino acid sequence of the Arl-5b protein in sea anemones is similar to that among several model vertebrates and humans. A polyclonal antibody raised to a peptide of the anemone Arl-5b labels some but not all hair bundles in healthy control animals. The abundance of labeled hair bundles significantly increases above healthy controls after trauma and continuing through the first hour of recovery. Dilute anti-Arl-5b blocks the spontaneous repair of hair bundle mechanoreceptors, suggesting that Arl-5b acts on the extracellular face of the plasma membrane. Immunoelectron microscopy indicates that Arl-5b is located along the length of stereocilia including sites in the vicinity of tip links. We propose that Arl-5b is involved in installing replacement linkages into damaged hair bundle mechanoreceptors.

Adaptable defense: a nudibranch mucus inhibits nematocyst discharge and changes with prey type

Nudibranchs that feed on cnidarians must defend themselves from the prey's nematocysts or risk their own injury or death. While a nudibranch's mucus has been thought to protect the animal from nematocyst discharge, an inhibition of discharge by nudibranch mucus has never been shown. The current study investigated whether mucus from the aeolid nudibranch Aeolidia papillosa would inhibit nematocyst discharge from four species of sea anemone prey. Sea anemone tentacles were contacted with mucus-coated gelatin probes, and nematocyst discharge was quantified and compared with control probes of gelatin only. Mucus from A. papillosa inhibited the discharge of nematocysts from sea anemone tentacles. This inhibition was specifically limited to the anemone species on which the nudibranch had been feeding. When the prey species was changed, the mucus changed within 2 weeks to inhibit the nematocyst discharge of the new prey species. The nudibranchs apparently produce the inhibitory mucus rather than simply becoming coated in anemone mucus during feeding. Because of the intimate association between most aeolid nudibranchs and their prey, an adaptable mucus protection could have a significant impact on the behavior, distribution, and life history of the nudibranchs.

AA. The behavioral and developmental physiology of nematocysts

Nematocysts are the nonliving secretions of specialized cells, the nematocytes, which develop from multipotent stem cells. Nematocysts are the means by which coelenterates capture prey and defend against predation. The 25 or more known types of nematocysts can be divided into to four functional categories: those that pierce, ensnare, or adhere to prey, and those that adhere to the substrate. During development a collagenous cyst, which may contain toxins, forms; a hollow thread, which becomes coiled as it invaginates, develops. Maturing nematocyte–nematocyst complexes migrate to their discharge sites and are deployed in specific patterns. The mechanisms of pattern determination are not clear. Discharge of nematocysts appears to involve increases in intracapsular osmotic pressure consequent upon release of bound calcium within the capsule; the eversion of the filament may depend upon release of structural tension consequent upon a loss of zinc from the thread. Evidence exists that discharge is initiated as a calcium-dependent exocytosis, triggered by an electrical signal resulting from the transduction of mechanical stimuli received at the nematocyte's cnidocil. Chemical signals transduced in adjacent sensory cells alter the frequency response of the nematocyte. In opposition to the nematocyte–nematocyst independent effector hypothesis, excitatory and inhibitory neuronal input appears to regulate discharge.

Hair bundle motility induced by chemoreceptors in anemones

Most hair bundles are essentially fixed with respect to frequency specificity. However, hair bundles in sea anemones are dynamically tuned by actin-dependent changes in length. Tuning to low frequencies is accomplished by activation of chemoreceptors to N-acetylated sugars resulting in hair bundle elongation. We report here that following sugar-induced tuning of hair bundles, membrane currents reverse polarity in hair cells during unidirectional mechanical stimulation. Reversal in polarity of currents with sugar stimulation is inhibited if hair bundle elongation is blocked by pretreatment with cytochalasin D. A re-examination of morphological changes to hair bundles reveals a sugar-induced reorientation of stereocilia in addition to elongation with chemosensitization. In controls, hair bundles are noticeably twisted. With sugar stimulation stereocilia become oriented more parallel to the long axis of the hair bundle. This sugar-induced change in orientation is similarly inhibited by cytochalasin D pretreatment. Based on these results, we present a model wherein anemone hair bundle twisting serves as a built-in safety mechanism to preserve linkages likely to be subjected to potentially damaging tension during tuning. The twisted hair bundles can untwist while elongating to relieve excessive tension on extracellular linkages between stereocilia critical to mechanosensitivity.

Immunological evidence that anemone repair proteins include replacement linkages

In response to damage to hair bundles caused by exposure to calcium free buffers, sea anemones secrete large protein complexes named 'repair proteins' that rapidly restore structural integrity and function to hair bundles. A specific chromatographic fraction of the repair protein mixture, named 'fraction beta', has biological activity comparable to the complete repair protein mixture (Watson et al., 1998, Hear. Res. 115, 119-128). In this study, we find that polyclonal antibodies raised against deglycosylated fraction beta specifically bind fraction beta on Western blots. Anti-fraction beta delays the normal recovery of vibration sensitivity in experimental animals (i.e., those with hair bundles damaged by calcium free buffers). Moreover, anti-fraction beta disrupts vibration sensitivity in control animals (i.e., those with healthy hair bundles). Experimentally damaged hair bundles subsequently exposed to repair protein and then processed for immunoelectron microscopy show labeled linkages interconnecting stereocilia of the hair bundle. Immunofluorescence microscopy confirms strong labeling of hair bundles treated with repair proteins and only weak labeling of tips of hair bundles from control animals. Immunofluorescence microscopy indicates stores of repair proteins in gland cells of the body column in control animals and in gland cells of the mouth in experimental animals. Repair biological activity is confirmed in column purified homogenates of these tissues. Apparently repair proteins are delivered to damaged hair bundles in mucus carried by beating cilia.

ATP enhances repair of hair bundles in sea anemones

Hair bundle mechanoreceptors of sea anemones are similar to those of the acousticolateralis system of vertebrates (Watson, Mire and Hudson, 1997, Hear. Res. 107, 53-63). Anemone hair bundles are repaired by 'repair proteins' secreted following a complete loss of structural integrity and loss of function caused by 1 h exposure to calcium free seawater. Exogenously supplied repair proteins (RP) restore structural integrity to hair bundles and restore vibration sensitivity in 7-8 min (Watson, Mire and Hudson, 1998, Hear. Res. 115, 119-128). We here report that exogenously supplied ATP enhances the rate by which RP restore vibration sensitivity. A bimodal dose response to ATP indicates maximal enhancement at picomolar and micromolar concentrations of ATP. At these concentrations of ATP, vibration sensitivity is restored in 2 min. These data suggest that at least two ATPases exhibiting different binding affinities for ATP are involved in the repair process. Whereas the higher affinity site is specific for ATP, the lower affinity site does not discriminate between ATP and ADP. Nucleotidase cytochemistry localizes ATPase activity in isolated repair proteins. In the absence of exogenously added RP, sea anemones secrete and consume ATP during the 4 h recovery period after 1 h exposure to calcium free seawater. In the presence of exogenously added RP, ATP is secreted and then consumed within 10 min. Quinacrine cytochemistry localizes possible stores of ATP in the apical cytoplasm of sensory neurons located at the center of the hair bundle. According to our model, ATP is secreted by the sensory neuron after its hair bundle loses structural integrity. Hydrolysis of ATP by repair proteins is essential to the repair process.

A comparison of hair bundle mechanoreceptors in sea anemones and vertebrate systems

Hair bundle mechanoreceptors of the acousticolateralis system of vertebrates are similar to hair bundles found on tentacles of sea anemones, primitive marine invertebrates. In each case, hair bundles consist of actin-based stereocilia interconnected by extracellular linkages. Recently, considerable attention has been directed to one class of linkages called "tip links." Tip links interconnect the tip of one stereocilium to the adjacent, taller stereocilium. According to the currently favored hypothesis for signal transduction, tip links may be "gating springs" that gate cation channels opened during deflection of the hair bundle. To depolarize the membrane, deflections must be directed so as to induce strain on the tip links. Deflections in the opposite direction lead to hyperpolarization of the membrane. Hair cells adapt to prolonged deflection of hair bundles. Whereas in some vertebrates, adaptation is incomplete (i.e., the current fails to return to baseline), adaptation in anemones appears to be complete. Signal transduction is reversibly blocked by agents thought to interact with the transduction channel including streptomycin. In addition, signal transduction is abolished following exposure to agents thought to attack tip links including calcium-depleted buffers or elastase. Hair cells of lower vertebrates can be replaced by division and differentiation of supporting cells. In chickens, a repair system exists wherein tip links are replaced via a mechanism that does not involve protein synthesis. The repair mechanism of anemones involves synthesis of new proteins that may constitute replacement linkages and accessory proteins that attach the linkages to appropriate integral proteins.

Hair bundles of sea anemones as a model system for vertebrate hair bundles

Sea anemones are marine invertebrates that use hair bundles to detect swimming movements of prey. Prey are captured by nematocysts (stinging capsules) that discharge into the prey. To further characterize anemone hair bundles and to compare hair bundles in anemones with hair bundles in vertebrates, we investigated fine structure and cytochemistry of anemone hair bundles. In addition, using a biological assay based on counting nematocysts discharged into vibrating test probes, we examined sensitivity of vibration detection to aminoglycoside antibiotics, Ca(2+)-free seawater, and amiloride. Like vertebrate hair bundles, anemone hair bundles are composed of stereocilia, possess lateral linkages between stereocilia whose preservation for transmission electron microscopy is enhanced by ruthenium red, and possess tip links morphologically similar to vertebrate tip links. Furthermore, vibration-dependent discharge of nematocysts is reversibly inhibited by 10(-4) M streptomycin and abolished by brief exposure to Ca(2+)-free seawater. However, unlike vertebrate hair bundles, anemone hair bundles appear to be insensitive to amiloride since vibration-dependent discharge of nematocysts is unaffected by up to mM amiloride. Thus, anemone hair bundles may serve as a useful model system for vertebrate hair bundles with the interesting feature of being insensitive to amiloride.

Ultrastructure of neurons and synapses in the tentacle epidermis of the sea anemone Calliactis parasitica

The anatomical organization of neutrons and synaptic pathways in tentacles of sea anemones is poorly understood. Transmission electron microscopy of serial thin sections was carried out on various regions of tentacles of the sea anemone Calliactis parasitica in order to locate and characterize typical epidermal neutrons and synapses. Both surface-oriented sensory cells with ciliary cones and basally located ganglion cells lacking a cilium have Golgi-derived granular or faintly cored vesicles. Similar vesicles are present at synaptic loci on some ganglion and muscle cells. The synaptic contacts on the longitudinal muscle cells are generally en passant rather than terminal. They vary from single neuromuscular synapses to pairs of neurites innervating the same muscle cell or one neurite innervating two or more muscle cells. Both two-way and one-way interneuronal synapses with vesicles aligned at paired synaptic membranes with dense material in a 14-20-nm-wide cleft are present in the epidermal nerve plexus. The vesicles average from 50 to 80 nm in diameter and vary from electron lucent to faintly cored. The results of this study demonstrate the presence of a complex system of epidermal neuronal pathways with specific synaptic loci in this modern representative of a first-evolved nervous system.

Chemoreceptor-mediated polymerization and depolymerization of actin in hair bundles of sea anemones

Hair bundles located on tentacles of sea anemones are morphodynamic mechanoreceptors employed to regulate discharge of nematocysts into swimming prey. Activation of chemoreceptors for N-acetylated sugars is known to induce anemone hair bundles to elongate while shifting discharge to lower frequencies matching those produced by calmly swimming prey. In the continued presence of N-acetylated sugars, activation of proline receptors is known to induce hair bundles to shorten while shifting nematocyst discharge to higher frequencies presumed to correspond to movements produced by wounded, struggling prey. In the present study, N-acetylneuraminic acid (NANA) causes stereocilia to become more intensely fluorescent in confocal optical sections of phalloidin-stained specimens, suggesting that receptors for N-acetylated sugars initiate processes to increase the density of F-actin within stereocilia. Computer analysis of electron micrographs is consistent with this interpretation for large diameter stereocilia but not for small diameter stereocilia. In the continued presence of NANA, proline causes fluorescence intensity of phalloidin to decrease to or below control levels. DNaseI uniformly stains large diameter stereocilia, suggesting that these stereocilia contain a pool of G-actin. Fluorescence intensity of DNaseI in stereocilia is significantly less bright in specimens exposed to NANA alone than in specimens exposed to proline in the continued presence of NANA. It appears that whereas activated receptors for NANA induce G-actin to polymerize in large diameter stereocilia, activated receptors for proline induce F-actin to depolymerize, restoring G-actin pools.