ABSTRACT
The intracellular conditions required for contraction in the food-gathering tentacle of a marine dinoflagellate Noctiluca miliaris were examined in the isolated tentacle, treated with Triton X-100. The tentacle flexed to its full extent when the pH of the reactivation medium was lowered to 4·0, and extended when it was raised again to its original value. Adenosine triphosphate (ATP) was not needed for the pH-dependent flexion–extension. The flexion was also produced by Ca2+, but in a concentration range more than a thousand times higher than the effective H+ concentration range for producing the flexion. It is concluded that movement of the tentacle in a live specimen of Noctiluca is controlled by membrane potential-regulated cytoplasmic pH.
Introduction
Movement of the food-gathering tentacle of a marine dinoflagellate, Noctiluca miliaris, is controlled by changes in membrane potential, termed the tentacleregulating potentials (TRPs) (Eckert & Sibaoka, 1967). The TRPs are generated across the outer membrane, that is, the protoplasmic membrane which faces the external solution (Oami et al. 1988). In normal sea water, quick flexions of the tentacle are always accompanied by hyperpolarizing spikes of the TRPs (Hisada, 1957). The flexion, however, does not occur in the absence of external Ca2+, even though the spike remains unchanged (Eckert & Sibaoka, 1967; Oami et al. 1988). When Noctiluca cells are stimulated to produce a bioluminescent flash, there is a concomitant flexion of the tentacle (Oami & Naitoh, 1987). The flash is triggered by a stimulus-evoked action potential (the flash-triggering action potential; FTP) (Eckert, 1965), which is generated across a protoplasmic membrane facing the intracellular flotation vacuole (the inner membrane) (Eckert & Sibaoka, 1968). The membrane current responsible for the FTP is carried by H+. The cytoplasmic pH, therefore, may be temporarily lowered by the H+-dependent FTP. The lowered pH, in turn, activates a H+-sensitive flash mechanism (Nawata & Sibaoka, 1979). The pH of the flotation vacuole of Noctiluca is low enough (pH 3·5) to supply H+ for generation of the FTP (Nawata & Sibaoka, 1976). In contrast to the flexion associated with the TRPs, the flash-associated flexion occurs even in low-Ca2+ sea water (Oami & Naitoh, 1987). These observations also implicate H+ in the control of tentacle movement.
To investigate the mechanism by which the tentacle movements are controlled by membrane potential, we examined the effects of some chemicals, especially H+, Ca2+ and ATP, on the isolated tentacle, treated with Triton X-100.
Materials and methods
Specimens of Noctiluca miliaris, cultured in artificial sea water (ASW) as previously described (Oami et al. 1988), were washed with cold ASW (0·1 °C) and kept in it for 10 min. They were then transferred to a cold extraction medium (0·l°C), consisting of 0·02% (by volume) Triton X-100, 10 mmol l−1 EDTA, 100 mmol l−1 KC1 and 30 mmol l−1 Tris-maleate buffer (adjusted to pH 7·0 with NaOH) (Naitoh & Kaneko, 1972), and kept in this solution for 17min. During the extraction, the cell bodies distorted, but the tentacles held their shape. They were then washed with a cold reference medium (0–1 °C), which consisted of 50 mmol l−1 KC1 and 10 mmol l−1 Tris-maleate buffer (pH 7·0), and kept in this solution for several minutes before being tested. An extracted cell was mechanically agitated to detach the tentacle from the cell body. The detached tentacle (200–300 μm in length) was held with a suction pipet (20–30 μm in inner diameter; Fig. 1) by lowering hydrostatic pressure within the pipet. This operation was accomplished in an experimental vessel filled with reference medium (about 0· 8 ml). A reactivation medium, which contained chemicals to be tested, was then introduced into the vessel. More than 95 % of the medium in the vessel was removed prior to introducing the new medium.
A magnified image of the extracted tentacle was recorded on videotape before and after introducing reactivation medium into the vessel. The degree of flexion of the extracted tentacle in each reactivation medium was measured after playback of the recorded images. All the experiments were performed at room temperature (18–23 °C).
Results
In the first series of experiments, the effects of pH on the extracted tentacles were examined. Each reactivation medium consisted of 50 mmol l−1 KC1 and 10 mmol l−1 buffer. Tris-maleate buffer was employed for the pH range from 8·5 to 5·5, and citrate buffer for the range from 5·5 to 3·0.
As shown in Fig. 1, the extracted tentacle, which was more or less straight at pH 8·5 (Al, Bl), flexed as the pH was lowered (Al–6, Bl–4). Some tentacles coiled at pH levels below 5·5 (B5, B6). The flexed or coiled tentacle extended again when the pH was raised to its original value (A7, B7). This pH-controlled flexion-extension could be repeated more than 20 times.
The extracted tentacle always flexed in the proximal region (the basal one-third to one-quarter) towards the cytostome. Moreover, the flexion–extension occurred in a single plane more or less perpendicular to the cell surface. These characteristics of the pH-controlled flexion-extension are very similar to those of the membrane potential-controlled movements of a live tentacle (compare Fig. 1A with 1C). Coiling was also seen in a live tentacle, especially when the specimen was in a Ca2+-rich solution (Fig. ID).
To examine the degree of the flexion quantitatively, we measured the distance between the position of the tip of the tentacle in the reference solution (pH 7·0) and that in each reactivation medium, and expressed it as a value relative to that distance for pH 5·5. About one-third of the extracted tentacles examined coiled when the pH was lower than 5·5. After they had coiled, measurement of the distance was impossible. We therefore used the distance at pH 5·5 as the reference, for the flexion.
The extent of flexion increased as pH was lowered (Fig. 2); slightly over the range between pH 8·5 and 6·0, much more between pH 6·0 and 4·0. It became maximal at pH 4·0. The degree of flexion tended to decrease with further lowering of the pH.
In the next series of experiments, the effects of Ca2+ on the extracted tentacles were examined. Ca2+ concentration in the reactivation medium was changed by addition of 5 mmol l−1 ethyleneglycol-bis(aminoethylether) tetraacetic acid (EGTA)-Ca2+ buffer to the medium for concentrations below 10−5mol l−1 (Porzehl et al. 1964), and by addition of enough CaCl2 for concentrations above 10−5mol l−1. The pH of each reactivation medium was kept constant at 7·0 using 10 mmol l−1 Tris-maleate buffer. When Ca2+ concentration was raised above 1 mmol l−1, the tentacle flexed (Fig. 3). The degree of flexion increased with increasing Ca2+ concentration. The tentacle extended again when the Ca2+ concentration was lowered to its original lowest level. However, the extension was incomplete, and the tentacle remained slightly flexed after the Ca2+ concentration had been lowered.
In the last series of experiments, the effects of some physiologically important ions and of ATP on the degree of flexion were examined at two different pH values. The results obtained are summarized in Table 1. At concentrations as high as 100 mmol l−1, K+ and Na+ produced a slight flexion at pH 7·0, but they showed no effects at pH 5·5. Addition of more than 5 mmol l−1 Mg2+ to the reactivation medium always enhanced the degree at both pH values. Addition of ATP up to 10 mmol l−1 had no effect at either pH. Addition of ATP (0·1–5 mmol l−1) together with Mg2+- (0·1–5 mmol l−1) and Ca2+ (0·01–1 mmol l−1) also had no effect. Substitution of KNO3 for equimolar KC1 in the reference solution did not affect the behavior of the extracted tentacle.
Discussion
Our findings clearly indicate that H+ is the most effective ion in producing flexion of the extracted tentacle. The largest increase in the degree of flexion occurred at H+ concentrations between 10−6 and 10−5mol l−1. It is interesting to note here that various kinds of cellular movement, such as contraction of skeletal muscle fibers of vertebrates (Hellam & Podolsky, 1969), reversed beating of cilia in ciliate protozoans (Naitoh & Kaneko, 1972) and cessation of cytoplasmic streaming in giant algal cells (Hayama et al. 1979), are under the control of bioelectric modulation of cytoplasmic Ca2+ concentration in a similar concentration range (10−7–10−5mol l−1). Contraction of the stalk of the vorticellid protozoans is also controlled by intracellular Ca2+ in this concentration range (Amos, 1971; Amos et al. 1975).
The presence of an H+-sensitive flexion mechanism in the tentacle explains our previous finding that a bioluminescent flash is always accompanied by a flexion of the tentacle (Oami & Naitoh, 1987): the increase in cytoplasmic H+ concentration produced by the FTP (Nawata & Sibaoka, 1979) would activate the H+-sensitive flash and the flexion mechanism simultaneously.
As mentioned previously, external Ca2+ is required for the TRP-associated flexion of the tentacle (Eckert & Sibaoka, 1967; Oami et al. 1988). The hyperpolarizing spike of the TRPs is assumed to drive external Ca2+ into the cytoplasm through calcium channels, which are activated by a slow depolarization preceding the spike (Oami et al. 1988). It is not feasible that the Ca2+ influx raises cytoplasmic Ca2+ concentration to over 100 mmol l−1 to activate the flexion mechanism directly (See Fig. 3). However, it is conceivable that a small increase in cytoplasmic Ca2+ concentration caused by the Ca2+ influx would activate a hypothetical H+ transport system in the inner membrane, and the activated system would then facilitate the transport of H+ from the vacuole into the cytoplasm. This increased cytoplasmic H+ concentration would activate the flexion mechanism. Hypothetical mechanisms for the bioelectrical control of the movements of the tentacle are shown schematically in Fig. 4.
Tentacle flexion of Noctiluca resembles contraction of the stalk of Zootham-nium in its independence of ATP hydrolysis. According to Amos et al. (1975), contraction of the stalk is attributable to conformational changes in a contractile protein of the stalk, spasmin, which is caused by binding of Ca2+ to spasmin. Our findings suggest that flexion of the tentacle is produced by similar conformational changes in a hypothetical protein, elicited by H+, not Ca2+.
Various types of H+-dependent cellular activities have been reported. For example, movement of bacterial flagella (Manson et al. 1977; Matsuura et al. 1977), production of ATP in mitochondria (Mitchell, 1961), actin polymerization in fertilized sea-urchin eggs (Johnson & Epel, 1976) and sol-gel conversion in the protoplasm of amoeboid cells (Hellewell & Taylor, 1979; see also Nuccitelli & Heiple, 1982).
This is the first report of this exceptional motile system among eucaryotic cells. The system is independent of both ATP and Ca2+; instead, it is regulated and energized by H+.
Acknowledgement
This work was supported by grants from Ministry of Education of Japan (411802, 510902, 56105002) and from the Mitsubishi foundation. We thank Dr Carl Johnson of Vanderbild University for reading the manuscript.