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The Journal of Neuroscience, July 1, 1998, 18(13):4966-4972
Activity-Dependent Development of Calcium Regulation in Growing Motor Axons
Gregory A. Lnenicka, Kathleen F. Arcaro, and John M. Calabro Neurobiology Research Center, Department of Biological Sciences, University at Albany, State University of New York, Albany, New York 12222
ABSTRACT
Top
Abstract
Introduction
In cultured nerve cord explants from the crayfish (Procambarus clarkii), the normal impulse activity levels of growing motor axons determine their response to Ca2+ influx. During depolarization or Ca2+ ionophore application, normally active tonic motor axons continue to grow, whereas inactive phasic motor axons retract and often degenerate. To determine the role of Ca2+ regulation in this difference, we measured the intracellular free Ca2+ concentration ([Ca2+]i) with fura-2. Growth cones from tonic axons normally had a higher [Ca2+]i than those from phasic axons. When depolarized with 60 mM K+, growth cones and neurites from phasic axons had a [Ca2+]i three to four times higher than did those from tonic axons. This difference in Ca2+ regulation includes greater Ca2+-handling capacity for growing tonic axons; the increase in [Ca2+]i produced by the Ca2+ ionophore 4-bromo-A23187 (0.25 µM) is four to five times greater in phasic than in tonic axons, and the decline in [Ca2+]i at the end of a depolarizing pulse is three to four times faster in tonic axons than phasic ones. Blocking impulses in growing tonic axons for 2-3 d with tetrodotoxin reduces their capacity to regulate [Ca2+]i. Thus, growing tonic and phasic axons have differences in Ca2+ regulation that develop as a result of their different activity levels. These activity-dependent differences in Ca2+ regulation influence axon growth and degeneration and probably influence other neuronal processes that are mediated by changes in [Ca2+]i.
Key words: calcium regulation; activity-dependent; fura-2; cell culture; growth cones; crayfish
INTRODUCTION
Intracellular Ca2+ is important in the control of many neuronal processes, such as transmitter release (Katz, 1969
), membrane excitability (Turrigiano et al., 1994
Studies of crayfish motor axons growing in cell culture suggest that the development of differences in Ca2+ regulation are related to the level of impulse activity. Depolarization inhibits the growth of normally inactive phasic motor axons, eventually producing retraction and often degeneration, whereas growing tonic motor axons normally continue to advance during depolarization (Arcaro and Lnenicka, 1997
In previous studies, differences in Ca2+ regulation have been shown to influence neuronal growth and survival. Cultured Helisoma neurons with weak Ca2+ regulation show greater neurite retraction and degeneration during Ca2+ influx than those with stronger Ca2+ regulation (Mills and Kater, 1990
To examine the relationship between impulse activity and the development of Ca2+ regulation, we have examined the increase in [Ca2+]i produced by high-K+ solutions and Ca2+ ionophores in the growth cones and neurites from phasic and tonic axons. Our results show that during prolonged depolarization [Ca2+]i goes much higher in growing phasic axons than in tonic axons. This difference in Ca2+ regulation involves greater Ca2+-handling capacity for tonic axons than for phasic axons. The development of these differences in Ca2+ regulation are activity-dependent, because eliminating impulse activity in growing tonic axons reduces their Ca2+-handling capacity. The implications of these activity-dependent changes in Ca2+ regulation for the growing axon are discussed.
MATERIALS AND METHODS
Preparation of cultures. Nerve cord explant cultures were prepared from crayfish (Procambarus clarkii), which were obtained from Atchafalaya Biological Supply (Raceland, LA), and maintained at 20°C in shallow, aerated tanks. Abdominal nerve cords were removed from crayfish with carapace lengths of 1.5-2.5 cm and plated in defined culture medium, as described previously (Arcaro and Lnenicka, 1995
High-K+ depolarization and ionophore application. Motoneurons were depolarized with medium containing 60 mM K+. Correct osmolarity was maintained by compensating for the increased KCl with an equal reduction in NaCl. Recordings of resting membrane potentials from the motor giant, the largest of the phasic motor neurons, showed that the addition of 60 mM K+ reduced the resting membrane potential from approximately
80 to
Measurement of [Ca2+]i. Growing axons were loaded with fura-2 by incubating the cultures in medium containing 2 µM fura-2 AM (Molecular Probes, Eugene, OR) for 50-60 min. Fura-2 AM (1 mM) in DMSO was added to culture medium at a 1:500 dilution. After loading with fura-2, growing axons were imaged with a 40× objective (Nikon Fluor; numerical aperture, 1.3) on an inverted microscope (Nikon Diaphot 200) equipped with an intensified CCD camera (VS-2525 intensifier and 200E CCD camera; Video Scope International, Herndon, VA). Fura-2 was excited by passing light from a 75 W xenon arc lamp through bandpass filters of 340 ± 7 or 380 ± 8 nm (Chroma Technology, Brattleboro, VT). A Lambda-10 optical filter changer (Sutter Instrument Co., Novato, CA) was used to switch between excitation wavelengths. Typically, illumination intensity was attenuated with an ND4 filter. The excitation and emission wavelengths were separated with a 410 nm dichroic mirror, and emitted light was then passed through a 510 ± 20 nm barrier filter. Metafluor software (Universal Imaging, West Chester, PA) was used for controlling the shutter, filter wheel, and image acquisition, as well as subsequent analysis.
The fura-2 fluorescence ratio (340:380) was used to estimate [Ca2+]i using standard techniques (Grynkiewicz et al., 1985
In many types of cells (e.g., mammalian) fura-2 is not a reliable indicator of Ca2+ concentrations higher than a couple of micromolar because of its high affinity for Ca2+ (Tsien, 1988
The average Ca2+ concentration in neurites or growth cones was determined for individual neurons. These average values were used to determine the overall mean and for statistical analysis using a two-tailed Student's t test. All values were mean ± SE.
RESULTS
[Ca2+]i in growing phasic and tonic axons
Growing neurites extend from the cut ends of the cultured phasic and tonic axons. Growth cones of phasic and tonic neurites advance at similar rates despite greater impulse activity in the tonic axons (Egid and Lnenicka, 1993
Ca2+ levels were measured during days 2-3 of growth, which is a period when the neurites are generally elongating (Egid and Lnenicka, 1993
Depolarization produces a larger increase in [Ca2+]i in growing phasic axons than in tonic ones
When advancing phasic growth cones are depolarized with 60 mM K+ for 40 min, they are initially inhibited and often retract (Arcaro and Lnenicka, 1997
Intracellular Ca2+ was measured in phasic and tonic growth cones during depolarization produced by 60 mM K+ (Fig. 1, top). During the first 10 min of depolarization, [Ca2+]i reached higher levels in phasic than in tonic growth cones (Fig. 2). Subsequently, [Ca2+]i in phasic growth cones gradually increased, whereas [Ca2+]i in the tonic growth cones decreased and plateaued at a lower level. The [Ca2+]i in the neurites was similar to that in the growth cones during this period of depolarization. A number of growth cones and neurites were examined 40-60 min after the beginning of the depolarization. The [Ca2+]i in phasic growth cones (4.61 ± 0.37 µM; n = 37 neurons; n = 70 growth cones) and neurites (5.54 ± 0.33 µM; n = 33 neurons; n = 43 neurites; n = 16 animals) was significantly higher than in tonic growth cones (1.38 ± 0.21 µM; n = 24 neurons; n = 71 growth cones; p < 0.0001) and neurites (1.56 ± 0.33 µM; n = 21 neurons; n = 32 neurites; n = 14 animals; p < 0.0001).
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Figure 1. Ratio map of fura-2 fluorescence showing changes in [Ca2+]i in neurites and growth cones during application of medium containing 60 mM K+ or Br-A23187. Top, Medium containing 60 mM K+ was applied to growing phasic and tonic axons. After 5 min, [Ca2+]i increased in both phasic and tonic growth cones, although the increase was greater in the phasic growth cone than the tonic one. Between 5 and 40 min, [Ca2+]i continued to rise in the phasic growth cone, whereas [Ca2+]i decreased in the tonic growth cone. During this period of depolarization, the phasic growth cone clearly retracts, and the tonic growth cone continues to advance, although some of the finer processes are withdrawn. Bottom, Br-A23187 (0.25 µM) was added to tonic axons grown with normal impulse activity (Tonic) and to tonic axons grown with no impulse activity (TTX-Tonic). After 5 min of Br-A23187 application, [Ca2+]i increased in both tonic and TTX-tonic growth cones. During 5-40 min, [Ca2+]i continued to rise in the TTX-tonic growth cones; however, [Ca2+]i decreased in the tonic growth cone. The TTX-tonic growth cone retracts and the tonic growth cone advances slightly. Thus, the previous history of impulse activity determines the ability of the growing axon to regulate intracellular Ca2+. The scale on the right shows the relationship between the ratio and the gray level.
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Figure 2. [Ca2+]i in phasic and tonic growth cones as a function of time during depolarization with medium containing 60 mM K+. The [Ca2+]i goes higher in phasic growth cones than in tonic growth cones. Mean values were obtained from 19 phasic growth cones from eight animals and 22 tonic growth cones from eight animals.
Thus, the greater depolarization-induced inhibition and degeneration of growing phasic neurites compared with tonic neurites is correlated with higher [Ca2+]i. The fact that [Ca2+]i reaches higher levels in phasic axon growth suggests that the growing phasic axons have greater Ca2+ influx and/or a lower rate of Ca2+ removal than the growing tonic axons.
Ca2+ levels go higher in growing phasic axons than tonic axons after addition of the Ca2+ ionophore Br-A23187
To determine whether the differences in Ca2+ regulation involved differences in Ca2+ removal, we measured [Ca2+]i during perfusion of the Ca2+ ionophore Br-A23187. Although Br-A23187 produced a rapid increase in [Ca2+]i in both phasic and tonic growth cones, the [Ca2+]i reached higher levels in phasic growth cones. During the first 5 min of Br-A23187 application, [Ca2+]i was three to four times greater in phasic growth cones than in tonic ones (Fig. 3). Subsequently, [Ca2+]i gradually increased and then plateaued in phasic growth cones, whereas [Ca2+]i in tonic growth cones decreased before leveling off. After 40 min of ionophore application, [Ca2+]i was approximately eight times greater in phasic growth cones than in tonic growth cones.
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Figure 3. [Ca2+]i in phasic and tonic growth cones plotted as a function of time during application of the Ca2+ ionophore Br-A23187 (0.25 µM). After addition of Br-A23187, [Ca2+]i immediately goes higher in phasic growth cones than in tonic ones. The [Ca2+]i remains extremely high in the phasic growth cones for the duration of the ionophore application. In tonic growth cones, [Ca2+]i decreases after its initial increase. Mean values represent seven phasic growth cones from three animals and nine tonic growth cones from three animals.
The remaining neurites and growth cones in the cultures were examined 40-60 min after the beginning of ionophore application. The [Ca2+]i in phasic growth cones (4.78 ± 0.83 µM; n = 18 neurons; n = 35 growth cones) and neurites (3.47 ± 1.02 µM; n = 12 neurons; n = 18 neurites; n = 6 animals) was significantly higher than in tonic growth cones (1.28 ± 0.31 µM; n = 17 neurons; n = 35 growth cones; p < 0.001) and neurites (0.91 ± 0.16 µM; n = 12 neurons; n = 15 neurites; n = 6 animals; p < 0.05). These results indicate that the growing phasic axons have a reduced capacity to regulate intracellular Ca2+ compared with tonic axons.
The differences in [Ca2+]i for the growing phasic and tonic axons are likely to be underestimations during both depolarization and Br-A23187 application. In both experiments, some phasic axon data were omitted, because the [Ca2+]i went too high to be reliably measured (see Materials and Methods), whereas none of the tonic axon data had to be omitted. In addition, some phasic growth had completely degenerated after 40 min of Br-A23187 treatment, and Ca2+ measurements could not be made during the 40-60 min period. Because the growth cones that degenerated likely had the highest [Ca2+]i, this explains why the measurements of [Ca2+]i in phasic growth cones were higher during the first 40 min than during 40-60 min.
Ca2+ removal after brief depolarizing pulses
To compare Ca2+ regulation in phasic and tonic growth cones further, we examined Ca2+ removal after brief depolarizing pulses. The [Ca2+]i was measured in neurites and growth cones during 60-90 sec depolarizing pulses (60 mM K+). At the end of the pulse, [Ca2+]i declined more rapidly in tonic growth cones than in phasic ones (Fig. 4). Because the decline in [Ca2+]i did not follow a single exponential, we measured the time required for [Ca2+]i to decay to one-half of peak values. The time to one-half decay was significantly greater for phasic growth cones (167 ± 47 sec; n = 7 neurons; n = 17 growth cones) than for tonic growth cones (59 ± 10 sec; n = 5 neurons; n = 14 growth cones; p < 0.05). The differences in Ca2+ removal were not attributable to differences in the peak [Ca2+]i, because the peaks were similar in phasic (3.90 ± 0.83 µM) and tonic growth cones (3.65 ± 1.07 µM). In addition, even when the peak [Ca2+]i in phasic growth cones was lower, Ca2+ removal was still slow (Fig. 4, bottom right).
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Figure 4. Changes in [Ca2+]i in phasic and tonic growth cones and neurites produced by brief depolarizations. Pulses of 60 mM K+ (bars) were applied to growing phasic and tonic axons in six animals, and changes in [Ca2+]i were measured. Top, Representative results for phasic and tonic growth cones. Phasic and tonic growth cones with similar peak [Ca2+]i are compared. Bottom, Representative results from phasic and tonic neurites. Phasic and tonic neurites with similar widths and peak [Ca2+]i are compared. On the left, the phasic and tonic neurites are 7 and 6 µm wide, respectively. On the right, phasic and tonic neurites are 5 and 6 µm wide, respectively. Note that at the end of the pulse, [Ca2+]i consistently declined more rapidly in tonic growth cones and neurites than in phasic ones.
These differences in Ca2+ removal do not appear to result from differences in growth cone size or shape. That is, if Ca2+ removal results from extrusion of Ca2+ across the plasma membrane, the surface-to-volume ratio would be expected to influence the rate at which [Ca2+]i declines. When Ca2+ removal was compared in phasic and tonic neurites, which generally have a uniform shape, we obtained results similar to those for growth cones (Fig. 4). Ca2+ levels took significantly longer to decay to one-half of peak values in phasic neurites (216.5 ± 58.9 sec; n = 5 neurons; n = 11 neurites), which had a mean width of 7 µm compared with tonic neurites (60.5 ± 19.4 sec; n = 5 neurons; n = 14 neurites; p < 0.05), which had a mean width of 5 µm. Similar differences were also seen when neurites of similar width were compared. Eliminating all phasic neurites >7 µm resulted in a mean width of 5 µm and a time to one-half decay of 187.3 ± 18.3 sec (n = 3 neurons; n = 7 neurites), which was also significantly greater than the tonic neurite values (p < 0.01). These results support faster Ca2+ removal by growing tonic axons compared with growing phasic axons.
Differences in Ca2+ regulation are activity-dependent
To determine whether the differences in Ca2+ regulation were activity-dependent, the impulse activity in the tonic axons was eliminated by adding 1 µM TTX during their growth. After 2-3 d of growth in TTX, the Ca2+-handling capacity of these inactive tonic axons was examined by measuring changes in [Ca2+]i after the addition of Br-A23187 (Fig. 1, bottom). These results were compared with the previous measurements obtained from tonic axons grown in normal medium. During 40 min of ionophore application, the inactive tonic growth cones showed weak Ca2+ regulation; [Ca2+]i continued to increase during ionophore application (Fig. 5). These results were different from the control tonic axons and more similar to the normally inactive phasic axons. Similar differences between inactive and control tonic axons were also seen when [Ca2+]i was compared 40-60 min after the beginning of ionophore application. The [Ca2+]i in the inactive tonic growth cones (3.15 ± 0.60 µM; n = 15 neurons; n = 37 growth cones) and neurites (2.96 ± 0.56 µM; n = 14 neurons; n = 21 neurites) was significantly greater than in the control tonic growth cones (1.28 ± 0.31 µM; n = 17 neurons; n = 35 growth cones; p < 0.01) and neurites (0.91 ± 0.16 µM; n = 12 neurons; n = 15 neurites; p < 0.01). These results clearly show that axons growing with greater impulse activity develop greater Ca2+-handling capacity.
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Figure 5. Differences in Ca2+ regulation for tonic axons grown with or without impulse activity. The Ca2+-handling capacity was compared in tonic axons grown in the presence of TTX with tonic axons grown in normal medium. The [Ca2+]i was measured in inactive tonic growth cones during 40 min of Br-A23187 application. These values are compared with those obtained from tonic growth cones grown in normal medium (Fig. 3). Note that the [Ca2+]i continued to increase in the inactive tonic growth cones in contrast to control tonic growth cones in which [Ca2+]i declined after the initial increase.
DISCUSSION
Depolarization produced higher Ca2+ levels in the phasic axons and growth cones than in tonic ones
During maintained depolarization with 60 mM K+, [Ca2+]i reaches higher levels in phasic neurites and growth cones than in tonic ones; [Ca2+]i in phasic axon growth is three to four times greater than in tonic axon growth at the end of 40 min of depolarization. The [Ca2+]i in phasic growth cones and axons during depolarization or ionophore application was very high and presumably was responsible for their retraction and eventual degeneration (Arcaro and Lnenicka, 1997
There may also be differences in the sensitivity of phasic and tonic growth to Ca2+ because normally the [Ca2+]i in the tonic growth cones is ~70% greater than in phasic growth cones, although they advance at a similar rate (Arcaro and Lnenicka, 1997
Tonic neurites and growth cones have a greater Ca2+-handling capacity than phasic ones
Ca2+ regulation was compared in phasic and tonic growth by adding the Ca2+ ionophore Br-A23187 and monitoring changes in [Ca2+]i. After Br-A23187 application, [Ca2+]i in phasic growth cones plateaued at levels four to five times greater than that observed in tonic growth cones. Thus, under conditions in which the density of Ca2+ influx was presumably similar, the resultant [Ca2+]i is dramatically different. Of course this assumes that the ionophore is incorporated into growing phasic and tonic axons at equal densities, which seems likely. Further evidence for stronger Ca2+ regulation by tonic axon growth was provided by examining Ca2+ removal at the end of a brief depolarizing pulse. After a 60-90 sec depolarizing pulse, the [Ca2+]i decreases more rapidly in tonic growth cones and neurites than in phasic ones. Thus, the differences in Ca2+ regulation include differences in Ca2+ removal; however, we do not know whether there are also differences in Ca2+ entry during depolarization.
The removal of intracellular free Ca2+ involves chelation by Ca2+-binding proteins, sequestration by intracellular organelles, and extrusion across the plasma membrane by the Na+-Ca2+ exchange and Ca2+ATPase (for review, see Miller, 1991
A higher rate of Ca2+ extrusion from growing tonic axons than from phasic ones could be responsible for their lower [Ca2+]i during ionophore application and more rapid decay of [Ca2+]i at the end of depolarizing pulses. According to a model describing the dynamics of residual Ca2+ in crayfish motor terminals, an increase in the rate of Ca2+ extrusion will decrease the [Ca2+]i plateau during a train of impulses and increase the rate of decay of [Ca2+]i at the end of the train (Tank et al., 1995
It appears reasonable that the plasma membrane Na+-Ca2+ exchanger could play a major role in Ca2+ extrusion during the large Ca2+ loads imposed in our experiments. The Na+-Ca2+ exchanger was important in removing intracellular Ca2+ from Helisoma neurons during a large Ca2+ load produced by Br-A23187 (Mills and Kater, 1990
Differences in Ca2+ regulation are activity-dependent
The strong Ca2+ regulation seen in tonic axons appears to result from its high-impulse activity levels during growth. Tonic axons growing in TTX showed weaker Ca2+ regulation than control ones during the application of Br-A23187. The strong Ca2+ regulation produced by high-impulse activity persists for at least 1 hr, and probably much longer, because impulse activity in the tonic axons was blocked for >1 hr before examining their Ca2+ handling (see Materials and Methods).
The activity-dependent strengthening of Ca2+ regulation could involve changes in protein synthesis. For example, the synthesis of Ca2+-binding proteins can be upregulated by increased electrical activity (Lowenstein et al., 1991
Relevance to neuronal physiology
Because [Ca2+]i is so important to neuronal function, the activity-dependent development of Ca2+ regulation could affect a number of neuronal properties. For the developing axon, Ca2+ regulation can affect how impulse activity and environmental cues shape the pattern of growth. In the adult, greater Ca2+-handling capacity could make neurons more resistant to Ca2+ neurotoxicity produced by insults such as excitotoxicity (Choi, 1988
Activity-dependent differences in Ca2+ regulation at motor terminals are likely to influence transmitter release. For example, Ca2+ removal is likely to influence the production of post-tetanic potentiation (PTP), because PTP requires the buildup of residual Ca2+ (Delaney et al., 1989
FOOTNOTES Received Feb. 13, 1998; revised April 6, 1998; accepted April 9, 1998.
This work was supported by National Science Foundation Grant IBN-9511558 (G.A.L.). We thank Drs. John Schmidt and Su Tieman for reviewing this manuscript.
Correspondence should be addressed to Gregory A. Lnenicka, Neurobiology Research Center, Department of Biological Sciences, University at Albany, State University of New York, Albany, NY 12222.
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