Androgen Mitigates Axotomy-Induced Decreases in Calbindin Expression in Motor Neurons

Serious about science: Serious about timing

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):
Year:		Vol:		Page:

HOME | SEARCH | ARCHIVE | SUBSCRIBE | CONTACT | HELP

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in ISI Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via ISI Web of Science (15)

Citing Articles via Google Scholar

Google Scholar

Articles by Pérez, J.

Articles by Kelley, D. B.

Search for Related Content

PubMed

PubMed Citation

Articles by Pérez, J.

Articles by Kelley, D. B.

Previous Article  |  Next Article

Volume 17, Number 19, Issue of October 1, 1997 pp. 7396-7403
Copyright ©1997 Society for Neuroscience

Androgen Mitigates Axotomy-Induced Decreases in Calbindin Expression in Motor Neurons

Julio Pérez and Darcy B. Kelley
Department of Biological Sciences, Columbia University, New York, New York 10027

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Androgens can rescue axotomized motor neurons from cell death. Here we examine a possible mechanism for this trophic actionin juvenile Xenopus laevis: regulation of a calcium-binding protein,calbindin, after axotomy. Western analysis revealed that a monoclonalantibody to calbindin D specifically recognizes a single ~28 kDaband in X. laevis CNS and rat cerebellum. Retrograde transportof peroxidase combined with immunohistochemistry demonstratedthat somata, axons, and synaptic terminals of laryngeal motorneurons in nucleus (N.) IX-X of X. laevis are calbindin-positive.The number of calbindin-positive cells was compared in the intactand axotomized sides of N.IX-X of gonadectomized males that wereeither hormonally untreated or DHT-treated for 1 month. Althoughaxotomy decreased the number of calbindin-positive cells by 86%in hormonally untreated males, the decrease was only 56% in DHT-treatedanimals. Compared with hormonally untreated animals, the numberof calbindin-labeled cells in N.IX-X of DHT-treated males wasincreased in both the intact (14%) and axotomized sides (75%).We conclude that axotomy decreases and that DHT enhances calbindinimmunoreactivity in N.IX-X. Axotomy-induced decrease in calbindinimmunoreactivity precedes cell loss in N.IX-X and may impair thecapacity of motor neurons to regulate cytoplasmic calcium. Androgen-mediatedmaintenance of calbindin expression is thus a candidate cellularmechanism for trophic maintenance of hormone target neurons.
Key words: dihydrotestosterone; motor neuron death; immunohistochemistry; calcium buffer; androgens; calbindin

INTRODUCTION

Androgens are trophic hormones that prevent the loss of motor neurons either during normal development or after axotomy (Nordeenet al., 1985; Hauser and Torand-Allerand, 1989; Yu, 1989; Pérezand Kelley, 1996). Androgens activate transduction pathways ofgene transcription by binding to the androgen receptor (AR), atranscription factor (Berger and Watson, 1989; Beato et al., 1995).In Xenopus laevis, AR is expressed in motor neurons of the nucleus(N.) IX-X that innervate the larynx (Kelley et al., 1975; Pérezet al., 1996). We previously reported that axotomy enhances transcriptionof AR mRNA in laryngeal motor neurons 1 month after axotomy andthat androgen promotes the subsequent survival of axotomized neuronsof N.IX-X (Pérez and Kelley, 1996). In this model, cell lossis delayed until 5 months; this time course permits explorationof mechanisms that lead to cell death and trophic mechanisms ofandrogens that ameliorate motor neuron loss.

An elevation in cytoplasmic calcium is associated with cell death after lesion, including axotomy-induced motor neuron death(Unemiya et al., 1993; George et al., 1995). Intracellular calciumcan be regulated in neurons by the activity of calcium channels,by transport into cellular storage compartments, and by calcium-bindingproteins (for review, see Blaustein, 1988). We focus here on onecalcium-binding protein, calbindin, which may buffer increasedlevels of calcium associated with cell death, thus exerting aprotective action on injured cells (Mattson et al., 1991; Baimbridgeet al., 1992). Some support for a protective role of this proteincomes from the observation that calbindin-positive cells are selectivelyspared after lesions of the CNS. For instance, calbindin-immunopositivehippocampal cells are spared after excitotoxic-induced cell death(Sloviter, 1989; Mattson et al., 1991), after section of the perforantpathway (Peterson et al., 1996), and after degeneration inducedby Ig-G cytotoxicity (Bao-Kuan et al., 1996).

Here we explore whether regulation of calbindin expression is a candidate mechanism for the trophic effects of androgen onaxotomized motor neurons of N.IX-X. We show that calbindin islocalized to the somata and to nerve terminals of motor neuronsin N.IX-X, a result that contrasts with the apparent absence ofcalbindin expression in motor neurons in other animal models (Jandeet al., 1981; García-Segura et al., 1984; Séquier et al., 1991).Axotomy decreases and androgen increases calbindin immunoreactivityin N.IX-X; as a result, androgens mitigate axotomy-induced decreasesin calbindin expression in motor neurons. The results suggestthat one way in which androgens can contribute to motor neuronsurvival is via control of calcium homeostasis by regulation ofcalcium-binding proteins.

MATERIALS AND METHODS
Animals, axotomy, and hormone treatment. Three-month-old postmetamorphic juvenile male frogs (11 animals, 3.0-7.6 gm) obtainedfrom Nasco (Fort Atkinson, WI) were gonadectomized under anesthesiawith 0.1% 3-aminobenzoic acid ethyl ester (MS-222, Sigma, St.Louis, MO). The larynx was accessed through an incision in thebody wall; the right IX-X nerve was separated from the laryngealmuscle and severed, and ~1 cm of the proximal segment was removed.Four males (n = 4) were implanted with a SILASTIC tube (VST 030065,Dow Corning, Midland, MI) containing 5 mg of DHT (5 $alpha$ -17 $beta$ -ol-3-oneandrostan; dihydrotestosterone, Sigma) while four males (hormonallyuntreated) received an empty tube placed into the dorsal lymphsac. One month after gonadectomy, tube implantation and denervationanimals were anesthetized deeply and transcardially perfused with5 ml of 0.6% NaCl, followed by 10 ml of 4% paraformaldehyde in1× PBS (2.6 mM KCl, 1.4 mM KH₂PO₄, 136 mM NaCl, and 8 mM Na₂HPO₄,pH 7.2). The brain and spinal cord (CNS) and the larynx were removedand post-fixed for 2 hr in 4% paraformaldehyde, followed by immersionin 20% sucrose in 1× PBS for 4-12 hr. Sections of the CNS weremounted consecutively onto different slides: the first sectionwas stained with cresyl violet, the second section subjected toimmunohistochemistry, the third section was not processed, andso forth. Three additional gonadectomized and DHT-treated maleswere not axotomized; crystals of horseradish peroxidase (HRP)were inserted into the laryngeal muscle, and the animals wereallowed a survival period of 3 d. Animals were perfused, and cryostatsections of the CNS were obtained as described above.

Immunohistochemistry. Cryostat sections of the CNS and larynx were air-dried, immersed in a methanol-0.5% H₂O₂ solution for30 min, and then washed in 0.1 M Tris-HCl. After a 30 min incubationin a solution containing 2% BSA and 0.3% Triton X-100 in 0.1 MTris-HCl, sections were incubated overnight with mouse monoclonalanti-calbindin D antibody (clone CL-300, C-8666; Sigma), whichhas been used previously to demonstrate calbindin immunoreactivityin the dorsal rhombencephalon of X. laevis (Muñoz et al., 1995).To determine the optimal antibody concentration, we first incubatedsections of the Xenopus CNS with increasing concentrations; a1:400 concentration of calbindin antibody saturated the immunohistochemicalreaction and was used for the comparison of the experimental groups.On the next day, sections were washed and incubated with 1:200biotinylated horse anti-mouse IgG for 30 min and then with avidin-biotin-peroxidasecomplex (ABC) according to the manufacturer's specifications (Vectastain,Vector Laboratories, Burlingame, CA). After washing in Tris buffer,sections were covered with a 0.05% solution of 3 $'$ ,3 $'$ diaminobenzidinein 0.05 M Tris-HCl plus 0.05% H₂O₂ for ~5 min to give a browncytoplasmic reaction. Finally, sections were dehydrated and coverslipped.As a control for specificity, sections of the larynx and the CNSwere incubated without primary antibody, followed by the ABC methodand diaminobenzidine solution, as described above.

For double labeling of motor neurons, sections were incubated first in a diaminobenzidine solution containing 16 mg/ml CoCl₂and 0.05% H₂O₂ to develop the HRP. This reaction produced a darkbrown granular precipitate in the cytoplasm of motor neurons.After washing, sections were incubated with the calbindin antibody,secondary antibody, and ABC method, as described above. The ABCcomplex was visualized by using a 0.003% tetramethylbenzidinesolution (heated to 60°C in 95% ethanol and dissolved in 10 mMsodium tungstate and 0.6 mM ammonium molybdate, pH 6) plus 0.05%H₂O₂ for 2-3 min. Calbindin immunoreactivity appeared as a greencytoplasmic reaction.

To analyze calbindin immunoreactivity at the neuromuscular junction, we killed two additional males (3 months old and 2 yearsold), as described previously. The larynx was removed, and sagittalsections (40 µm) were prepared with a vibratome (Vibratome, series1000). Floating sections were processed immunohistochemically,as described above. After dehydration in a graded series of ethanol,sections of the muscle were immersed in xylene and mounted onslides; muscle fibers were dispersed manually with forceps andthen coverslipped with Permount.

Western blot. Proteins from Xenopus CNS and rat cerebellum were extracted with a Polytron in a solution of 2 mM EDTA, 1% SDS,10% glycerol, and 62.5 mM Tris-HCl, pH 7.0, and stored at $-$ 20°C.Proteins were separated in 12% polyacrylamide gels and transferredelectrophoretically to nitrocellulose in a buffer containing 193mM glycine, 0.025 M Tris, 0.1% SDS, and 20% methanol, pH 8.3.Transfer of proteins was verified by staining the gel with 0.1%Coomassie blue. Lanes containing molecular weight standards (Sigma)were cut out, and blots containing protein samples were treatedwith 5% Carnation nonfat-dried milk in Tris-HCl, pH 7.4, for 2hr. Membranes containing Xenopus samples were incubated with eitheranti-calbindin 1:400 or without antibody at $-$ 4°C overnight. Membraneswith rat samples were incubated with either anti-calbindin 1:400or without antibody for 1 hr at room temperature. After washing,membranes were incubated with biotinylated antibody and ABC reagents(Vector) at room temperature in 50 mM Tris-HCl and 150 mM NaCl,pH 7.4, at concentrations used for immunohistochemistry and accordingto manufacturer's specifications. Immunoreactive bands were visualizedby incubation with diaminobenzidine (5 mg/10 ml in 0.01 M Tris)and 0.005% H₂O₂.

Cell quantification and statistical analysis. At perfusion, control and experimental animals were randomly assigned a numberfrom the total corresponding to both groups. On the day of cryostatsection, slides were labeled with the number of the animal andnumbered sequentially. All reactions were performed on pairs ofsections from hormonally untreated and DHT-treated animals. Thensections containing N.IX-X were selected for quantification. Calbindin-immunopositivecells were recognized by specific, brown staining of the cytoplasm.For both DHT-treated and untreated juveniles, the effects of axotomywere sufficiently dramatic that a truly "blind" analysis was impossible.Counts of numbers of calbindin-positive cells were obtained bya single observer from coded slides without explicit identificationas to treatment group. In material sectioned at 15 µm, N.IX-Xappears on ~20 sections. For each animal the number of cresylviolet-stained and calbindin-positive cells in the intact andaxotomized sides of the entire extent of N.IX-X was determinedfrom tissue sections with a light microscope.

For nuclear and cell diameters (length between the most distant limits of the nuclei or perikarya), three to four nonconsecutivesections containing N.IX-X of all animals were selected at spacedintervals throughout the dorsoventral extent of the nucleus. Anaverage of four cells from each section on each side was chosenrandomly and measured with the aid of a calibrated ruler in themicroscope ocular. To avoid double counts, we followed two strategies:first, only cells with both cytoplasmic labeling and a visiblenucleus were counted. Second, the number of cells was determinedfrom alternating horizontal sections separated by 30 µm. Becausethe largest nuclear diameter evaluated in this study was 8.6 µm,no cell was counted twice. No stereological correction for samplingerrors (Abercrombie, 1946) was applied because the diameter ofthe cell nucleus did not change with DHT treatment, nor did itdiffer between intact and axotomized sides. All values given aremean ± SD. Differences in the nuclear and cell diameters, thenumber of cresyl violet-stained cells, and the number of calbindin-positivecells were evaluated by a two-way ANOVA with two between-groupfactors (treatment, hormonally untreated vs DHT-treated; axotomy,intact vs axotomized sides) followed, when required, by a posthoc Student's two-tailed t test (n = 4 per group).

RESULTS

Calbindin expression in motor neurons of N.IX-X
N.IX-X is located immediately caudal to the fourth root of cranial nerve IX-X (Fig. 1C). Neurons of N.IX-X are embedded inthe white matter of the brainstem lateral to the inferior reticularformation (Simpson et al., 1986). In N.IX-X, cell perikarya andneurites were immunolabeled with the calbindin antibody (Fig.1A). Calbindin expression elsewhere in the rhombencephalon waslimited to the Purkinje cells of the cerebellum, cells of thedorsal tegmental area of the medulla, and sparse cells in thereticular formation and central gray as well as the dorsal rhombencephaliccalbindin-expressing nuclei previously described by Muñoz etal. (1995). The dorsal tegmental area of the medulla and the inferiorreticular formation are the major sources of afferent input toN.IX-X (Wetzel et al., 1985). In addition to laryngeal motor neurons,cells in the trigeminal and facial nuclei were labeled with thecalbindin antibody; no motor neurons in the spinal cord displayedcalbindin immunoreactivity (data not shown). Specificity of immunoreactivitywas confirmed by the absence of any immunohistochemical reactionin control sections (data not shown).
Fig. 1. A, Intact motor neurons in N.IX-X of a DHT-treated animal double-labeled with HRP (brown reaction) and calbindin (green reaction).N.IX-X is heterogeneous with respect to calbindin expression:some HRP-labeled motor neurons express calbindin (arrowheads);some motor neurons do not (stars). Some cells with motor neuron-likemorphology were not labeled with HRP (v). B, Detail of a motorneuron in N.IX-X; calbindin immunoreactivity is localized to bothcytoplasm and dendrites. C, Axons from motor neurons of N.IX-Xwere immunolabeled with calbindin in the laryngeal nerve (arrowhead).D, Within the larynx, unmyelinated axons and Schwann cells associatedwith myelinated axons (arrowhead) were immunolabeled with calbindinantibody. E, Synaptic terminals at the laryngeal neuromuscularjunction were immunoreactive for calbindin antibody. Scale bars:A, 50 µm; B, 10 µm; C, 100 µm; D, E, 25 µm.
[View Larger Version of this Image (102K GIF file)]

In DHT-treated animals motor neurons retrogradely labeled with HRP were either calbindin-immunopositive or -negative and wereintermingled within N.IX-X, indicating that a subpopulation ofmotor neurons expresses the protein (Fig. 1A). In the absenceof specific markers we cannot determine whether interneurons orglial cells in N.IX-X also express calbindin. Most calbindin-positivecells of N.IX-X that were not labeled with HRP had a motor neuron-likemorphology (Fig. 1A); because injection of HRP may not have reachedall motor neuron terminals, these cells also may have been laryngealmotor neurons. In motor neurons, calbindin immunoreactivity waslocalized to both the cytoplasm and dendrites (Fig. 1B). In addition,calbindin was present in axons of the N.IX-X nerve as they leftthe brainstem (Fig. 1C). When the nerve was followed to its targetlaryngeal muscle, calbindin immunoreactivity was seen in unmyelinatedaxons, in Schwann cells that form the myelin sheath (Fig. 1D),and in terminals of laryngeal axons at the neuromuscular junction(Fig. 1E). Muscle fibers were not immunoreactive for the calbindinantibody. Calbindin immunoreactivity was found in laryngeal axonsin the innervated muscle, whereas no calbindin reaction was foundin the denervated side of either hormonally untreated or DHT-treatedanimals; denervation was confirmed with neurofilament immunolabelingof axons, and denervated muscle was severely atrophied (data notshown). These results indicate that motor neurons do not reinnervatethe muscle after 1 month of axotomy, DHT treatment, or both.

The specificity of the calbindin antibody was analyzed by Western blot of proteins from rat cerebellum and Xenopus brain (Fig.2). One band at ~28 kDa was immunolabeled in protein samples fromboth species. Immunolabeling of this protein was absent in membranesthat were not incubated with the calbindin antibody. Because themolecular weight of the labeled protein is that expected for calbindinand because Western analysis revealed a protein of similar sizein rat cerebellum (where Purkinje cells express high levels ofcalbindin; Jande et al., 1981), it is most likely that the immunolabelingreported here represents calbindin-D28k expression in the CNSof X. laevis.
Fig. 2. Western blot of total proteins extracted from rat cerebellum or Xenopus brain. Proteins were resolved in 12% SDS-PAGE andtransferred to nitrocellulose. Blots were probed with (+) or without( $-$ ) calbindin antibody; one band of ~28 kDa, according to molecularweight markers (right), was labeled in both species.
[View Larger Version of this Image (68K GIF file)]

Effects of axotomy and DHT treatment on calbindin immunoreactivity of N.IX-X
Once it was established that motor neurons of N.IX-X contain calbindin, we next analyzed the effect of axotomy and DHT treatmenton the expression of this protein.

Axotomy decreases calbindin immunoreactivity in N.IX-X. In hormonally untreated animals a marked decrease in the immunohistochemicalsignal is noted on the axotomized side, as compared with the intactside (Fig. 3A vs B). On the axotomized side of N.IX-X, the decreaseof immunoreactivity in the neuropil is accompanied by an apparentabsence of immunoreactivity in the cytoplasm of cells. An examinationof adjacent cresyl violet-stained sections reveals that the decreasein calbindin immunoreactivity in the axotomized side of N.IX-Xis not attributable to an absence of cells (Fig. 3A $'$ ). In hormonallyuntreated animals, cells of the axotomized side display more intensecresyl violet staining of the cytoplasm than cells of the intactside (Fig. 3A $'$ ,B $'$ ); cell size also is increased, as compared withthe intact N.IX-X (see below). Thus, in hormonally untreated animals,axotomy decreases calbindin immunoreactivity and increases Nisslstaining in the cytoplasm of N.IX-X cells.
Fig. 3. Intact and axotomized sides of N.IX-X in hormonally untreated and DHT-treated animals. Sections were immunolabeled with calbindinantibody, which produced a brown cytoplasmic reaction (A-D), andadjacent sections were stained with cresyl violet (A $'$ -D $'$ ). InN.IX-X of hormonally untreated animals, axotomy caused a strikingdecrease in calbindin immunoreactivity (compare A with B) andan increase in cresyl violet staining of cells (compare A $'$ withB $'$ ). In DHT-treated animals, axotomy caused a decrease in calbindinimmunoreactivity (compare C with D) in cells of N.IX-X but hadno effect on cresyl violet staining (compare C $'$ with D $'$ ). Scalebar, 200 µm.
[View Larger Version of this Image (118K GIF file)]

After DHT treatment, calbindin immunoreactivity was prominent on the intact side of N.IX-X (Fig. 3D). As in hormonally untreatedanimals, less calbindin immunoreactivity was noted on the axotomizedside of N.IX-X (Fig. 3C) than on the intact side (Fig. 3D). However,DHT treatment appeared to preserve calbindin immunoreactivityin the cytoplasm of axotomized side of N.IX-X, as compared withthe axotomized side of hormonally untreated animals (compare Fig.3A and C).

In DHT-treated animals, observation of cresyl violet-stained sections, consecutive to those immunolabeled with calbindin antibody,also confirmed that the decreased calbindin immunoreactivity inthe axotomized side of N.IX-X was not associated with an apparentloss of cells (Fig. 3C $'$ ). In contrast to hormonally untreatedanimals, Nissl staining in the cytoplasm of cells in N.IX-X ofDHT-treated animals did not differ between intact and axotomizedsides (Fig. 3C $'$ ,D $'$ ). In DHT-treated animals, cells of the intactside of N.IX-X were more conspicuous and more intensely stainedthan cells of the intact side of hormonally untreated animals(compare Fig. 3D $'$ and B $'$ ), whereas cells from the axotomized sideof N.IX-X of DHT-treated males did not appear markedly differentfrom untreated males (compare Fig. 3C $'$ and A $'$ ). Together, theseresults suggest that both axotomy and DHT treatment affect thecytoplasmic Nissl staining and calbindin immunoreactivity of cellsin N.IX-X.

Effects of axotomy and DHT treatment on the number and size of cresyl violet-stained cells in N.IX-X
The number of cresyl violet-stained cells in N.IX-X was not affected by 1 month of axotomy with or without DHT treatment.The number of cresyl violet-stained cells in N.IX-X of hormonallyuntreated animals was 233 ± 113 and 199 ± 74 for the intact andaxotomized sides, respectively (n = 4). In DHT-treated animals,the number of cells on the intact side was 209 ± 65 and on theaxotomized side was 201 ± 75 (n = 4). An ANOVA revealed no significantdifferences (p > 0.9). Thus, axotomy is not accompanied by lossof cells, nor does DHT treatment affect the number of cresyl violet-stainedcells in N.IX-X 1 month after treatment.

The size of cells in N.IX-X was affected by treatment (Table 1). There was a significant main effect of both hormone treatment(F_(1,15) = 8.22; p < 0.02) and axotomy (F_(1,15) = 5.09; p < 0.05)on the diameter of perikarya but no significant effect of eithertreatment on nuclear diameter (for both treatments, p > 0.06).In hormonally untreated animals, cell diameter was increased significantlyon the axotomized side (p < 0.03, Table 1). In contrast, therewas no significant difference between sides in nuclear diameter(p > 0.05, Table 1). We conclude that axotomy increases the sizeof neurons in hormonally untreated males.

Table 1. Size of cells in N.IX-X is affected by axotomy and androgen treatment

Hormonally untreated
DHT-treated

Intact Axotomized Intact Axotomized

Cell diameter 9.5 ± 1 15.4 ± 2.6^* 16.2 ± 1.4^** 15.5 ± 3.4

Nuclear diameter 3.9 ± 0.4 6.6 ± 1.8 6.1 ± 1.7 6.3 ± 1.4

Cell and nuclear diameters (µm) in the intact and axotomized sides of N.IX-X of hormonally untreated and DHT-treated animals.Data presented are means ± SD; n = 4 animals in all cases. Inhormonally untreated animals, axotomy increases the cell diameterin N.IX-X (*p < 0.03). In contrast, cell diameters of neuronsfrom the intact and axotomized sides of DHT-treated animals donot differ significantly. On the intact side, DHT treatment increasescell diameter, as compared with untreated animals (**p < 0.001).Neither axotomy nor hormonal treatment significantly affecteddiameters of cell nuclei in N.IX-X (ANOVA, p > 0.5).

There was a significant two-way interaction between hormone treatment and axotomy on the size of the neuronal perikarya (F_(1,15)= 7.4; p < 0.02) that most likely represents a difference in effectsof axotomy on DHT-treated versus untreated animals. In DHT-treatedanimals no significant differences in either nuclear diameter(p > 0.8) or cell diameter (p > 0.7) were noted between cellsfrom the intact and from the axotomized sides of N.IX-X (Table1). Thus, there are no differences in either cell or nucleardiameter of intact and axotomized cells of N.IX-X in animals treatedwith DHT.

Cell size did differ significantly for the intact sides of N.IX-X of DHT-treated and hormonally untreated animals (p < 0.001,Table 1); thus DHT increases the size of intact motor neurons.In contrast, no differences were found for the axotomized sidesof these groups (p > 0.7). Together, the results indicate thatboth axotomy and DHT treatment increase the size of cell bodiesin N.IX-X without significantly affecting nuclear diameter. Theeffect of axotomy and DHT treatment is neither additive nor synergistic,suggesting a limit to the increase of cell size.

Effects of axotomy and DHT treatment on the number calbindin-immunopositive cells of N.IX-X
Androgen and axotomy alter calbindin immunoreactivity in N.IX-X. One month after treatment there was a significant main effectof axotomy on the number of calbindin-positive cells in N.IX-X(F_(1,15) = 27.6, p < 0.001; Figure 4). Axotomy for 1 month wasaccompanied by a decrease in the number of calbindin-immunoreactivecells in hormonally untreated animals (86%) and in DHT-treatedanimals (56%). Thus, whether DHT-treated or untreated, axotomydecreased the number of calbindin-immunoreactive cells in N.IX-X.
Fig. 4. Number of calbindin-immunopositive cells and number of cresyl violet-stained cells (mean ± SD; n = 4 animals per group) countedin the intact and axotomized N.IX-X of hormonally untreated (blackbars) and DHT-treated (white bars) animals 1 month after axotomy.There were no significant differences in the number of cresylviolet-stained cells. There was a significant main effect of hormonetreatment (p < 0.05) and axotomy (p < 0.01) on the number of calbindin-positivecells, but there was no significant interaction between treatments.For the axotomized side, the number of calbindin-immunoreactivecells in the intact sides/number in the axotomized sides × 100is displayed within the bars.
[View Larger Version of this Image (20K GIF file)]

There was a significant main effect of DHT treatment on the number of calbindin-immunopositive cells in N.IX-X (F_(1,15) =5.1, p < 0.05; Fig. 4) but no significant interaction betweenhormone treatment and axotomy (F_(1,15) = 0.35, p > 0.5). For theintact side of N.IX-X, there were 14% more calbindin-positivecells in DHT-treated animals than in hormonally untreated animals.For the axotomized N.IX-X, there were 75% more calbindin-immunopositivecells in DHT-treated animals than in hormonally untreated animals(Fig. 4). We conclude that in both the intact and the axotomizedN.IX-X, there are more calbindin-immunoreactive cells in DHT-treatedthan in hormonally untreated animals.

DISCUSSION
Androgenic steroids have been shown to preserve target motor neurons from cell death both during normal development and inresponse to axotomy (for review, see Breedlove, 1992; Kujawa andJones, 1995). We have examined how androgens exert their protectiveeffects in an experimental model system: axotomized laryngealmotor neurons of juvenile Xenopus laevis. Laryngeal motor neuronsexpress high levels of androgen binding and AR mRNA (Kelley, 1981;Pérez et al., 1996) and thus are targets for this class of hormones.In this system axotomy leads to substantial cell death 5 monthslater; endogenous or exogenous androgen mitigates axotomy-inducedcell loss (Pérez and Kelley, 1996).

What downstream targets of AR activation are involved in the protective effects of androgen? Because elevations in intracellularcalcium accompany injury-induced cell death in many neuronal systems,regulation of calcium homeostasis could contribute to cell preservation.We show here that laryngeal motor neurons express calbindin-D28k,a calcium-buffering protein, that axotomy decreases calbindinimmunoreactivity, and that androgen treatment preserves immunoreactivity.These findings support the hypothesis that androgen regulationof calbindin expression contributes to its trophic actions onaxotomized motor neurons.

Calbindin expression in motor neurons
Motor neurons of N.IX-X retrogradely labeled with HRP were immunolabeled with calbindin antibody. Does this antibody recognizean authentic calbindin protein in the X. laevis CNS? We examinedprotein blots of X. laevis CNS, using a mouse monoclonal antibodywith wide cross-species activity. A single band of the appropriatemolecular weight (28 kDa) was recognized specifically; a bandof the same size also was recognized in rat cerebellum. Althougheach species has a somewhat idiosyncratic pattern of expression(Baimbridge et al., 1992), in all species examined to date calbindinis expressed in cerebellar Purkinje cells; we also saw expressionin this cell type in X. laevis. Taken together, the size of theantigen and its characteristic pattern of expression suggest thata calbindin-D28 kDa is expressed in the CNS of X. laevis.

Expression in motor neurons is unusual for calbindin, so much so that modified motor neurons have been used to study the protectiveeffects of transfected calbindin (Ho et al., 1996). Calbindinexpression in X. laevis is not confined to N.IX-X. Immunopositivecells also were found in the trigeminal and facial nuclei, whereasno label was present in ventral horn of the spinal cord, suggestingthat motor neuron expression may be limited to cranial nerve motornuclei.

Laryngeal motor neuron cell bodies, dendrites, axons, and neuromuscular terminals are all immunopositive for calbindin. Inaddition, calbindin also is expressed in Schwann cells wrappingthe laryngeal axons. The widespread distribution of calbindinin different compartments of the cell suggests participation ina variety of functions requiring regulation of free calcium. Themajor proposed role for calbindin is regulating intracellularcalcium availability (Blaustein, 1988; Baimbridge et al., 1992).In hippocampal neurons, reductions in calbindin lead to increasedactivation and inactivation of voltage-gated calcium channels(Kohr and Mody, 1991). Calbindin expression in some systems isassociated with high rates of spontaneous activity and may playa role in sequestering associated calcium elevations (Blaustein,1988). In addition, other calcium-binding proteins (e.g., calmodulin)have been shown to inactivate receptors mediating calcium influx,such as the NMDA receptor (Ehlers et al., 1996). At the presynapticterminal, calbindin does not influence evoked neurotransmitterrelease but does suppress post-tetanic potentiation (Chard etal., 1995). Having established that calbindin is expressed inlaryngeal motor neurons, we explored whether changes in calbindinexpression are associated with motor neuron death or survival.

Calbindin, axotomy, and cell death
We show here that axotomy decreases the number of calbindin-immunoreactive cells in N.IX-X, suggesting that motor neuronsdeprived of access to target muscles downregulate this protein.Not all proteins, however, are decreased in expression by axotomy.In this study, axotomy increased Nissl staining, a change believedto reflect a general increase in protein synthesis in neurons(Barr and Hamilton, 1948; Lieberman, 1971). Axotomy also increasedAR mRNA expression (Pérez and Kelley, 1996). We suggest thatdownregulation of calbindin expression is a specific responseto axotomy that may contribute to the subsequent death of laryngealmotor neurons.

Increased levels of cytoplasmic calcium are associated with cell death in many systems. Changes in calbindin expression havebeen observed in the CNS after injury. For instance, kindlingreduces calbindin content in granule cells of the dentate gyrus(Köhr and Mody, 1991); Renshaw interneurons decrease calbindinimmunoreactivity after axotomy of the presynaptic motor neurons(Sanna et al., 1993), and the number of calbindin-immunopositivecells increases after axotomy of sympathetic ganglion cells (Sánchez-Viveset al., 1994). In patients with Huntington's and Alzheimer's diseases,calbindin expression is downregulated in the forebrain and striatum(Iacopino and Christakos, 1990a).

In motor neurons, analysis of electrophysiological properties after axotomy suggests that these cells experience elevatedintracellular calcium; axotomized motor neurons have a largerafterhyperpolarization potential and faster inactivation of calciumcurrents than intact neurons (Unemiya et al., 1993). Interestingly,these characteristics are reminiscent of the physiology of injuredgranule cells of the hippocampus that lose calbindin expression(Köhr and Mody, 1991). In addition, axonal degeneration in axotomizedmotor neurons is mediated via calcium influx (George et al., 1995).In Xenopus laryngeal motor neurons, a decrease in calbindin immunoreactivityis an early response of motor neurons to axotomy that anticipatescell loss. After axotomy, an impaired buffering capacity resultingfrom decreased calbindin expression may contribute to the elevationof free calcium leading to cell death.

Does the axotomy-induced decrease in calbindin immunoreactivity reflect a decrease in calbindin expression? Calbindin immunoreactivitycan be influenced by calcium levels. In biochemical experimentsthe immunoreactive signals for calbindin in blots from cytosolicextracts of rat cerebellum were directly proportional to calciumconcentration in the incubation buffer; formalin fixation reduced,but did not eliminate, calcium effects (Winsky and Kuznicki, 1996).In hippocampal slices opposite results have been obtained: slicespreincubated in low calcium showed enhanced immunoreactivity,whereas those in high calcium showed decreased immunoreactivity(Dutar et al., 1991). Both of these studies used the same mousemonoclonal anti-calbindin D antibody used here. Changes in calbindinimmunoreactivity induced by axotomy thus may reflect changes inthe state of the protein because of altered intracellular calciumlevels rather than an actual decrease in protein synthesis orstability. The resolution of these issues awaits the cloning ofXenopus calbindin so that regulation of its mRNA can be studied.

Androgens, calbindin, and cell survival
In N.IX-X androgen treatment increases cell survival after axotomy (Pérez and Kelley, 1996) and maintains calbindin immunoreactivity(this study). Expression of calbindin also can be regulated byother steroid hormones. For instance, corticosterone induces calbindinexpression in the hippocampus (Iacopino and Christakos, 1990b),and calbindin mRNA expression is under the control of estrogenin uterine myometrium (Romagnolo et al., 1996).

In both the intact and axotomized sides of N.IX-X, more calbindin-immunoreactive cells were found in DHT-treated animals thanin hormonally untreated animals. Although protective effects ofcalbindin are controversial (Baimbridge et al., 1992), calbindinis thought to protect injured neurons and glial cells from excitotoxicityvia reduction in intracellular calcium levels (Sloviter, 1989;Mattson et al., 1991; Bao-Kuan et al., 1996; Peterson et al.,1996). Calbindin-immunoreactive cells are spared in in vitro assaysof neuronal survival, and calbindin expression is induced by brain-derivedneurotrophic factor, tumor necrosis factor, and neurotrophin-3(NT-3), all of which exert trophic effects on target neurons (Collazoet al., 1992; Mattson et al., 1995; Ventimiglia et al., 1995;Marty et al., 1996). In a model system for amyotrophic lateralsclerosis (IgG-mediated toxicity of hybrid motor neurons), calbindintransfection protects cells from death (Ho et al., 1996). Althoughthe increased expression of calbindin evoked by androgens is notspecific to axotomized cells, it might contribute specificallyto survival by sustaining cell physiology in a state closer tothat of intact motor neurons.

Axotomy induces changes in gene expression: some changes are associated with cell survival and others with neurodegeneration.In laryngeal motor neurons of N.IX-X, axotomy for 1 month inducesupregulation of AR mRNA expression. By facilitating androgen bindingand thus enhancing the expression of androgen target genes, increasedreceptor expression may represent the first step in androgen rescueof motor neurons (Pérez and Kelley, 1996). Another such exampleis the induction of tubulin expression by testosterone in axotomizedfacial motor neurons of hamsters (Jones and Oblinger, 1994), whichmay facilitate axonal regeneration (Yu, 1982; Kujawa et al., 1991).In contrast, axotomy decreases calbindin expression, a changethat may favor calcium-mediated cell death. We conclude that oneexplanation for androgen-mediated cell rescue is increased transcriptionof "survival" genes and that calbindin may be such a gene.

FOOTNOTES

Received May 29, 1997; revised July 2, 1997; accepted July 21, 1997.

This work was supported by National Institutes of Health Grant NS19949 and by Fellowship EX95 50691740 from the Ministry ofEducation and Science, Spain.

Correspondence should be addressed to Dr. Darcy Kelley, Department of Biological Sciences, Columbia University, 911 Fairchild,New York, NY 10027.

REFERENCES

Abercrombie M (1946) Estimation of nuclear population from microtome sections. Anat Rec 94:239-247.
Baimbridge KG, Celio MR, Rogers JH (1992) Calcium-binding proteins in the nervous system. Trends Neurosci 15:303-308[ISI][Medline].
Bao-Kuan H, Alexianu ME, Colom LV, Mohamed AH, Serrano F, Appel SH (1996) Expression of calbindin-D28k in motoneuron hybrid cells after retroviral infection with calbindin-D28k cDNA prevents amyotrophic lateral sclerosis Ig-G-mediated cytotoxicity. Proc Natl Acad Sci USA 93:6796-6801[Abstract/Free Full Text].
Barr ML, Hamilton JD (1948) A quantitative study of certain morphological changes in spinal motoneurons during axon reaction. J Comp Neurol 89:93-121.
Beato M, Herrlich P, Schütz G (1995) Steroid hormone receptors: many actors in search of a plot. Cell 83:851-857[ISI][Medline].
Berger FG, Watson G (1989) Androgen-regulated gene expression. Annu Rev Physiol 51:51-65[ISI][Medline].
Blaustein MP (1988) Calcium transport and buffering in neurons. Trends Neurosci 11:438-443[ISI][Medline].
Breedlove SM (1992) Sexual dimorphism in the vertebrate nervous system. J Neurosci 12:4133-4142[ISI][Medline].
Chard PS, Jordán J, Marcuccilli CJ, Miller RJ, Leiden JM, Ross RP, Ghadge GD (1995) Regulation of excitatory transmission at hippocampal synapse by calbindin-D28k. Proc Natl Acad Sci USA 92:5144-5148[Abstract/Free Full Text].
Collazo D, Takahashi H, McKay RDG (1992) Cellular targets and trophic functions of neurotrophin-3 in the developing rat hippocampus. Neuron 9:643-656[ISI][Medline].
Dutar P, Potier B, Lamour Y, Emson P, Senut M (1991) Loss of calbindin-28k immunoreactivity in hippocampal slices from aged rats; a role for calcium? Eur J Neurosci 3:839-849[ISI][Medline].
Ehlers MD, Zhang S, Bernhadt JP, Huganir RL (1996) Inactivation of NMDA receptors by direct interaction of calmodulin with the NR1 subunit. Cell 84:745-755[ISI][Medline].
García-Segura LM, Baetens D, Roth J, Norman AW, Orci L (1984) Immunohistochemical mapping of calcium-binding protein immunoreactivity in the rat central nervous system. Brain Res 296:75-86[ISI][Medline].
George EB, Glass JD, Griffin JW (1995) Axotomy-induced axonal degeneration is mediated by calcium influx through ion-specific channels. J Neurosci 15:6445-6452[Abstract/Free Full Text].
Hauser KF, Torand-Allerand CD (1989) Androgen increases the number of cells in fetal mouse spinal cord cultures: implications for motoneuron survival. Brain Res 485:157-164[ISI][Medline].
Ho BK, Alexianu ME, Colom LV, Mohamed AH, Serrano F, Appel SH (1996) Expression of calbindin-D28K in motoneuron hybrid cells after retroviral infection with calbindin-D28K cDNA prevents amyotrophic lateral sclerosis IgG-mediated cytotoxicity. Proc Natl Acad Sci USA 93:6796-6801.
Iacopino AM, Christakos S (1990a) Corticosterone regulates calbindin-D28k mRNA and protein levels in rat hippocampus. J Biol Chem 265:10177-10180[Abstract/Free Full Text].
Iacopino AM, Christakos S (1990b) Specific reduction of calcium-binding protein (28-kilodalton calbindin-D) gene expression in aging and neurodegenerative diseases. Proc Natl Acad Sci USA 87:4078-4082[Abstract/Free Full Text].
Jande SS, Maler L, Lawson DEM (1981) Immunohistochemical mapping of vitamin D-dependent calcium-binding protein in brain. Nature 294:765-767[Medline].
Jones KJ, Oblinger MM (1994) Androgenic regulation of tubulin gene expression in axotomized hamster facial motoneurons. J Neurosci 14:3620-3627[Abstract].
Kelley DB (1981) Locations of androgen-concentrating cells in the brain of Xenopus laevis: autoradiography with ³H-dihydrotestosterone. J Comp Neurol 199:221-231[ISI][Medline].
Kelley DB, Morrell JI, Pfaff DW (1975) Autoradiographic localization of hormone-concentrating cells in the brain of an amphibian, Xenopus laevis. I. Testosterone. J Comp Neurol 164:47-61[ISI][Medline].
Köhr G, Mody I (1991) Endogenous intracellular calcium buffering and the activation/inactivation of HVA calcium currents in rat dentate gyrus granule cells. J Gen Physiol 98:941-967[Abstract/Free Full Text].
Kujawa KA, Jones KJ (1995) Trophic actions of gonadal steroids on neuronal functioning normally and following injury. In: Advances in neuronal science, Vol 2, pp 131-152. JAI Press.
Kujawa KA, Emeric E, Jones KJ (1991) Testosterone differentially regulates the regenerative properties of injured hamster facial motoneurons. J Neurosci 11:3898-3906[Abstract].
Lieberman AR (1971) The axon reaction: a review of the principal features of perikaryal responses to injury. Int Rev Neurobiol 14:49-124[Medline].
Marty S, Carroll P, Cellerino A, Castrén E, Staiger V, Thoenen H, Lindholm D (1996) Brain-derived neurotrophic factor promotes the differentiation of various hippocampal nonpyramidal neurons, including Cajal-Retzius cells, in organotypic slice cultures. J Neurosci 16:675-687[Abstract/Free Full Text].
Mattson MP, Rychlik B, Chu C, Christakos S (1991) Evidence for calcium-reducing and excito-protective roles for the calcium-binding protein calbindin-D28k in cultured hippocampal neurons. Neuron 6:41-51[ISI][Medline].
Mattson MP, Cheng B, Baldwin SA, Smith-Swintosky VL, Keller J, Geddes JW, Scheff KW, Christakos S (1995) Brain injury and tumor necrosis factors induce calbindin D-28k in astrocytes: evidence for cytoprotective response. J Neurosci Res 42:357-370[ISI][Medline].
Muñoz A, Muñoz M, González A, Donkelaar HJT (1995) Anuran dorsal column nucleus: organization, immunohistochemical characterization, and fiber connections in Rana perezi and Xenopus laevis. J Comp Neurol 363:197-220[ISI][Medline].
Nordeen E, Nordeen K, Sengelaub D, Arnold A (1985) Androgens prevent normally occurring cell death in a sexually dimorphic spinal nucleus. Science 229:671-673[Abstract/Free Full Text].
Pérez J, Kelley DB (1996) Trophic effects of androgens: receptor expression and the survival of laryngeal motoneurons after axotomy. J Neurosci 16:6625-6633[Abstract/Free Full Text].
Pérez J, Cohen M, Kelley DB (1996) Androgen receptor mRNA expression in Xenopus laevis CNS; sexual dimorphism and regulation in the laryngeal motor nucleus. J Neurobiol 30:556-568[ISI][Medline].
Peterson DA, Lucidi-Phillipi CA, Murphy DP, Ray J, Gage FH (1996) Fibroblast growth factor-2 protects entorhinal layer II glutamatergic neurons from axotomy-induced death. J Neurosci 16:886-898[Abstract/Free Full Text].
Romagnolo B, Cluzeaud F, Lambert M, Colnot S, Porteau A, Molina T, Tomasset M, Vandewalle A, Kahn A, Perret C (1996) Tissue-specific and hormonal regulation of calbindin-D9k fusion genes in transgenic mice. J Biol Chem 271:16820-16826[Abstract/Free Full Text].
Sánchez-Vives MV, Valdeolmillos M, Martinez S, Gallego R (1994) Axotomy-induced changes in Ca²⁺ homeostasis in rat sympathetic ganglion cells. Eur J Neurosci 6:9-17[ISI][Medline].
Sanna PP, Celio MR, Bloom FE, Rende M (1993) Presumptive Renshaw cells contain decreased calbindin during recovery from sciatic nerve lesions. Proc Natl Acad Sci USA 90:3048-3052[Abstract/Free Full Text].
Séquier JM, Hunziker W, Andressen C, Celio MR (1991) Calbindin D-28k protein and mRNA localization in the rat brain. Eur J Neurosci 2:1118-1126.
Simpson HB, Tobias ML, Kelley DB (1986) Origin and identification of fibers in the cranial nerve IX-X complex of Xenopus laevis: Lucifer yellow backfills in vitro. J Comp Neurol 244:430-444[ISI][Medline].
Sloviter RS (1989) Calcium-binding protein (Calbindin-D28k) and parvalbumin immunocytochemistry: localization in the rat hippocampus with specific reference to the selective vulnerability of hippocampal neurons to seizure activity. J Comp Neurol 280:183-196[ISI][Medline].
Unemiya M, Araki I, Kuno M (1993) Electrophysiological properties of axotomized facial motoneurones that are destined to die in neonatal rats. J Physiol (Lond) 462:661-678[Abstract/Free Full Text].
Ventimiglia R, Mather PE, Jones BE, Lindsay RM (1995) The neurotrophins BDNF, NT3, and NT-4/5 promote survival and morphological and biochemical differentiation of striatal neurons in vitro. Eur J Neurosci 7:213-222[ISI][Medline].
Wetzel D, Haerter U, Kelley D (1985) A proposed neural pathway for vocalization in South African clawed frogs, Xenopus laevis. J Comp Physiol 157:749-761.[Medline]
Winsky L, Kuznicki J (1996) Antibody recognition of calcium-binding proteins depends on their calcium-binding status. J Neurochem 66:764-771[ISI][Medline].
Yu W-HA (1982) Effect of testosterone on the regeneration of hypoglossal nerve in rats. Exp Neurol 77:129-141[ISI][Medline].
Yu W-HA (1989) Administration of testosterone attenuates neuronal loss following axotomy in the brainstem motor nuclei of female rats. J Neurosci 9:3908-3914[Abstract].

Copyright ©1997 Society for Neuroscience   0270-6474/1997/177396-08$05.00/0

This article has been cited by other articles:

C. B. Huppenbauer, L. Tanzer, L. L. DonCarlos, and K. J. Jones
Gonadal Steroid Attenuation of Developing Hamster Facial Motoneuron Loss by Axotomy: Equal Efficacy of Testosterone, Dihydrotestosterone, and 17-{beta} Estradiol
J. Neurosci., April 20, 2005; 25(16): 4004 - 4013.
[Abstract] [Full Text] [PDF]

E. A. Brenowitz and K. Lent
Afferent Input Is Necessary for Seasonal Growth and Maintenance of Adult Avian Song Control Circuits
J. Neurosci., April 1, 2001; 21(7): 2320 - 2329.
[Abstract] [Full Text] [PDF]

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in ISI Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via ISI Web of Science (15)

Citing Articles via Google Scholar

Google Scholar

Articles by Pérez, J.

Articles by Kelley, D. B.

Search for Related Content

PubMed

PubMed Citation

Articles by Pérez, J.

Articles by Kelley, D. B.