The In Vivo Time Course for Elimination of Adrenalectomy-Induced Apoptotic Profiles from the Granule Cell Layer of the Rat Hippocampus

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Volume 17, Number 11, Issue of June 1, 1997 pp. 3981-3989
Copyright ©1997 Society for Neuroscience

The In Vivo Time Course for Elimination of Adrenalectomy-Induced Apoptotic Profiles from the Granule Cell Layer of the Rat Hippocampus

Zhongting Hu, Kazunari Yuri, Hitoshi Ozawa, Haiping Lu, and Mitsuhiro Kawata
Department of Anatomy and Neurobiology, Kyoto Prefectural University of Medicine, Kawaramachi-Hirokoji, Kamigyo-ku, Kyoto 602, Japan

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Although apoptotic cellular degeneration has been reported to be extremely rapid with the use of in vitro models, the timeneeded to clear apoptotic neurons in the in vivo brain is unknown.In this study we used a simple morphological approach to solvethis problem. Four days after adrenalectomy (ADX), all of theoperated rats morphologically displayed hippocampal granule cellapoptosis that was prevented completely by corticosterone replacementimmediately after ADX. Therefore, we intravenously injected therats with corticosterone 4 d after ADX and subsequently maintainedthem on corticosterone replacement in saline drinking water. Thiscorticosterone replacement could protect healthy granule cellspromptly and continuously against hormone-deficient apoptosis,because the normal glucocorticoid receptor immunoreactivity withinthe granule cell nuclei, which disappeared after ADX, was identified1 hr after corticosterone replacement was started, and this effectpersisted for several days. However, this corticosterone treatmentcould not prevent the irreversible apoptosis of the already degeneratedgranule cells at various stages of the same progressive apoptoticprocess. Then we successively traced the disappearance of apoptoticgranule cells throughout the hippocampus at different time pointsby Nissl and silver staining. Given that the apoptotic cells atthe earliest stage of the degenerating process when the ADX ratsreceived corticosterone injection were the last to disappear,the period from corticosterone injection until the disappearanceof the last degenerating debris of apoptotic cells was taken torepresent the time course for elimination of apoptotic neuronsin vivo. We discovered that the elimination of apoptotic granulecells took 72 hr.
Key words: adrenalectomy; corticosterone; granule cell; apoptosis; silver and Nissl staining; chromatin condensation; time course

INTRODUCTION

Cell death is a common phenomenon that plays an important role in the control of the morphology and size of forming tissuesand organs (Wyllie, 1981; Ucker, 1991). Since the emergence ofthe concept of apoptosis (Kerr et al., 1972), numerous studieshave focused on this research field. Under light and electronmicroscope, the typical morphological changes of apoptotic cellstake place in the following sequence: clumping of chromatin againstthe nuclear membrane, condensation of the nucleus and cytoplasm,breaking up of pyknotic cells into apoptotic fragments, and digestionof apoptotic bodies (Kerr et al., 1972; Clarke, 1990; Sloviteret al., 1993b). The different morphological profiles of apoptoticcells are thought to reflect diverse stages of cell degeneration(Kerr et al., 1972; Sloviter et al., 1993a,b). Although severalhypotheses have been proposed to explain the complicated mechanismof apoptosis (Vaux, 1993), there is unanimous agreement that theapoptotic cells are eliminated within a few minutes (Russell etal., 1972; Sanderson, 1976; Matter, 1979; Kerr et al., 1987) andthat apoptotic bodies of diverse forms are observed only withina period of several hours (Wyllie et al., 1980; Busch et al.,1990). However, all of the findings as to the exact time courseof apoptotic cell degeneration were obtained from in vitro experiments(Sanderson, 1976).

It is not known how long it takes for apoptotic cells to undergo degeneration in vivo. Especially in the in vivo brain, nomorphological evidence has been presented to demonstrate the timecourse of the lysis of apoptotic neurons. Sloviter et al. (1989)discovered that the adrenalectomy-induced loss of endogenous glucocorticoids,the hormones secreted from the adrenal glands, resulted in selectivecell degeneration within the granule cell layer of the hippocampus,and this result has been replicated in subsequent experiments(Gould et al., 1990; Jaarsma et al., 1992; Sapolsky et al., 1991;Sloviter et al., 1993a). Shortly after adrenalectomy (ADX), ~90%of the operated rats exhibited degeneration of the hippocampalgranule cells (Jaarsma et al., 1992; Sloviter et al., 1993a).Morphological analysis demonstrated that the ADX-induced granulecell death was apoptotic (Sloviter et al., 1993a,b). The ADX-inducedgranule cell apoptosis was prevented completely by supplying theADX rats with saline drinking water containing corticosteroneat the dose of 20 µg/ml solution (Sloviter et al., 1989, 1993a).On the basis of the postulate that cellular apoptosis is irreversibleonce it has been triggered (Kerr et al., 1972) and that the apoptoticcells at the earliest stage of cell degeneration are the lastto disappear, we quickly gave hormone-deficient rats, beginning4 d after ADX, corticosterone replacement, which immediately preventedthe apoptosis of healthy granule cells but not that of the alreadydegenerated granule cells. We then successively traced the morphologicaldisappearance of apoptotic granule cells. We discovered that thedegenerating granule cells had not disappeared until 72 hr afterthe administration of corticosterone was started in the ADX rats.

MATERIALS AND METHODS
Animal treatment All of the rats used in this study were treated in accordance with the guidelines issued by the US National Institutes ofHealth for the humane treatment of experimental animals. The ratswere divided into the following groups:

ADX of young rats induces hippocampal granule cell apoptosis. This experiment was designed to elucidate the distribution andthe morphological profiles of apoptotic granule cells after ADX.Twenty male Sprague Dawley rats, 100 gm body weight (BW), wereadrenalectomized bilaterally under aseptic procedure with ketamineanesthesia. Twelve other rats underwent sham operation as controls.Both the ADX and control groups were provided with 0.9% NaCl indrinking water throughout the experimental course. For the examinationof the appearance of apoptotic granule cells, five ADX and threesham-operated rats were killed at 1, 2, 3, and 4 d after operation.

Corticosterone replacement blocks ADX-induced granule cell apoptosis. This experiment was designed to examine whether corticosteronereplacement in this study could prevent the hippocampal granulecell apoptosis after ADX. Immediately after the ADX and sham operationas described above, corticosterone (Sigma, St. Louis, MO) dissolvedin saline solution at 30 µg/ml was supplied to 20 ADX and 12 sham-operatedrats. Previous studies (Sloviter et al., 1989; Gould et al., 1990)demonstrated that 20-25 µg/ml corticosterone in saline drinkingwater increased the circulating level of corticosterone in ADXrats to the lower normal range and prevented granule cell deathafter ADX. To ensure the effect of corticosterone in protectinghippocampal granule cells from hormone-deficient apoptosis, weused the slightly excess dose of 30 µg/ml. Five ADX and threesham-operated rats were perfused at each of 1, 2, 3, and 4 d afteroperation. The volume of corticosterone consumed by each ADX andsham-operated rat was recorded carefully every day.

The time course of the lysis of apoptotic granule cells. Thirty male Sprague Dawley rats (100 gm BW) were adrenalectomizedbilaterally and provided with 0.9% NaCl in drinking water immediatelyafter operation. Twelve sham-operated rats were used as controls.Four days after operation, all of the rats in both groups receivedintravenous injection of corticosterone (1.5 mg in aseptic saline)and then were maintained on corticosterone replacement (corticosteronein saline drinking water at 30 µg/ml) for the durations indicatedbelow. We chose to start the corticosterone replacement at 4 dafter ADX, because this was reported to be an adequate time frameto allow degeneration of numerous cells within the granule celllayer of the adult dentate gyrus (Jaarsma et al., 1992; Sloviteret al., 1993a,b) and because in our preliminary experiments weconfirmed that all rats exhibited granule cell degeneration withvariable morphological profiles within the dentate gyrus at 4d after ADX. The dose of 1.5 mg of injected corticosterone wasdecided after we calculated the daily volume of corticosteronewater consumed by each ADX rat. In the above experiment we observedthe ADX rats daily and noted that each ADX rat drank a volumeof 30-50 ml of corticosterone saline water daily; 30-50 ml of30 µg/ml corticosterone solution contained 0.9-1.5 mg corticosterone.ADX rats that received corticosterone replacement at this volumedaily (0.9-1.5 mg) did not exhibit any degenerating granule cells,suggesting that the corticosterone at this injected volume (1.5mg) could be distributed quickly into all of the hormone-deficientcells and could rapidly protect the healthy granule cells againsthormone-deficient apoptosis. The volume of corticosterone/salinedrinking solution consumed by each ADX or sham-operated rat alsowas recorded every day. At each of 1, 4, 12, 24, 48, and 72 hrafter the start of corticosterone replacement, five ADX and twosham-operated rats were killed. To exclude the possibility thatcorticosterone treatment in our experiment induced possible stressor neurotoxic effects on the rats (Sapolsky, 1985), we weighedall of the rats before perfusion.
Tissue preparation All of the rats in both the sham-operated and ADX groups were anesthetized deeply with ketamine and perfused with 100 ml of0.9% NaCl, followed by 500 ml of 4.0% paraformaldehyde in 0.1M PBS with 2% (v/v) picric acid. The brain was dissected out fromthe skull and post-fixed overnight in the same perfusion solution.Then the brains were immersed in 25% sucrose in 0.1 M PBS for2 d. Brain sections at different thicknesses were cut for differentstaining methods. For Nissl staining, 25-µm-thick sections weremounted directly onto gelatin-coated glass slides and air-dried.The slides were stained with 1.0% cresyl violet, dehydrated, andcoverslipped with Entellan. For silver degeneration and immunohistochemicalstaining, 50-µm-thick sections were cut and collected in 0.1 MPBS.
Silver impregnation stain The silver impregnation procedure described by Gallyas et al. (1980) was used to identify the degenerating granule cells,with our modification to obtain low background staining of thesections. In this staining procedure the sections were washedfirst with distilled water four times for 5 min each. Then theywere immersed in the pretreating solution (containing a 1:1 solutionof 9% NaOH and 1.2% ammonium nitrate) for 10 min, followed by15 min in the impregnation solution (18 ml of 9% NaOH, 12-14 mlof 16% ammonium nitrate, and 125-135 µl of 50% AgNO₃). The sectionswere washed quickly (within 1 min) but vigorously twice with asolution containing 100 µl of 16% ammonium nitrate, 100 ml of5% Na₂CO₃, 300 ml of 95% ethanol, and 700 ml of distilled water.Finally, the sections were immersed in developing solution (300-350µl of 16% ammonium nitrate, 15 ml of 37% formalin, 100 ml of 95%ethanol, 100 ml of 0.5% citric acid, and 285 ml of distilled water)for ~1 min or more. They were washed with 0.5% acetic acid for30 sec to stop the developmental reaction, then with distilledwater, and last with 0.1 M PBS for 5 min each. The sections wereincubated with 5% K₂Cr₂O₇ to reduce the nonspecific backgroundstaining. The sections again were washed with distilled water,followed by 0.1 M PBS, and mounted directly on glass slides, air-dried,dehydrated in a graded alcohol series, cleared, and coverslipped.
Immunohistochemical staining for glucocorticoid receptors Hippocampal sections from all of the ADX and control rats were subjected to immunohistochemical staining for examining theglucocorticoid receptor immunoreactivity (GR-IR) in the granulecell layer of the dentate gyrus. Sections were incubated firstin 2% H₂O₂ and in 2% normal goat serum for 60 min each and thenimmersed in primary antibodies (rabbit anti-GR serum at a dilutionof 1:5000; Morimoto et al., 1996) for 3 d at 4°C. After severalwashes the sections were incubated in biotinylated anti-rabbitIgG for 2 hr (working dilution 1:1000; Boehringer Mannheim Biochemica,Mannheim, Germany) and then, after several more washes, in streptoavidin-peroxidaseconjugate (dilution 1:4000; Boehringer Mannheim) for 2 hr at roomtemperature. The reaction complex on the sections was visualizedin a solution of 0.05% 3,3 $'$ -diaminobenzidine (DAB; Dojin, Kumamoto,Japan) and 0.01% H₂O₂ for 15 min. Sections were mounted on glassslides, air-dried, dehydrated, and coverslipped. For the evaluationof the specificity of our first antibody, several sections fromcontrol rats were incubated with normal rabbit serum (diluted1:500-1000) instead of primary antiserum. No positive immunoreactiveneurons were identified within the hippocampal granule cell layeror other brain structures.
Statistical analysis Nissl-stained hippocampal sections from the rats adrenalectomized for 4 d and the ADX rats at 1, 4, 12, 24, 48, and 72 hrafter corticosterone replacement were used for quantitative analysis.The sections selected for quantitative analysis were ~100 µm apartto avoid the necessity of correcting for twice-counted cells.The number of apoptotic granule cells with different morphologicalprofiles (see Results, Morphological Analysis of Apoptotic GranuleCells) was recorded within the unilateral dentate gyrus. The meansof numbers of apoptotic granule cells with different morphologicalprofiles and the total numbers of apoptotic granule cells persection were calculated. Statistical significance was determinedwith Student's unpaired t test, and the differences in the meansfrom the ADX rats with corticosterone replacement (n = 5 at eachof six time points) and the rats adrenalectomized for 4 d (n =5) were established at p < 0.05.

RESULTS

Adrenalectomy-induced granule cell apoptosis
ADX of young adult rats induced obvious cell degeneration within the granule cell layer of the dentate gyrus shortly afteroperation. We did not observe degenerating granule cells 1 d afterADX in Nissl- and silver-stained sections. The degeneration ofhippocampal granule cells was observed first, in three of fiveoperated rats, 2 d after ADX. Three days after operation, ~80%of the ADX rats exhibited cell degeneration in the granule celllayer. All of the ADX rats exhibited degenerating granule cellswithin the dentate gyrus 4 d after operation (Fig. 1). No obviousdegenerating cells were found in the hippocampal granule celllayer of the sham-operated rats at any of the time points. IndividualADX rats exhibited greatly variable numbers of degenerating granulecells (Fig. 1A,B). The greatest number of degenerating granulecells usually was located in the lateral aspect of the suprapyramidalblade within the granule cell layer. We thus chose the suprapyramidalblade of the granule cell layer obtained 4 d after ADX for thefollowing morphological analyses of degenerating granule cells.
Fig. 1. Silver-stained sections reveal degenerating cells within the suprapyramidal blade of the granule cell layer 4 d after ADX.Numerous silver-impregnated granule cells are seen after ADX.Different ADX rats exhibited varied numbers of the silver-stainedgranule cells (arrows in A, B). Scale bar, 200 µm (for A, B).
[View Larger Version of this Image (85K GIF file)]

Morphological analysis of apoptotic granule cells
Nissl staining revealed a series of typical morphological changes during the course of the granule cell degeneration 4 d afterADX (Fig. 2). These different morphological profiles were consideredto represent cell degeneration at presumed different stages (Kerret al., 1972; Sloviter et al., 1993a,b). To describe these morphologicalchanges simply, we divided different apoptotic profiles into fourdistinct types according to the results of studies on the processof apoptotic cell degeneration (Kerr et al., 1972; Sloviter etal., 1993a,b). The first type included the damaged granule cellsthat exhibited normal size for the nucleus and cell body whilethere were numerous darkly stained bodies within the nucleus (clumpingof nuclear chromatin, Fig. 2A). Degenerating cells in the secondtype showed an extensive and tight condensation of nuclear materialsand cytoplasm into a darkly stained small ball (pyknosis, Fig.2B). The third type consisted of smaller degenerating cells withmorphologic breaking up of the condensed nucleus and cytoplasm.Diverse morphological profiles were found at this type (disassemblyof pyknotic cells, Fig. 2C-E). In the fourth type the condensednucleus and cytoplasm were disassembled into many progressivelysmaller degenerating particles of debris (degenerating debris,Fig. 2F). In almost all of the Nissl-stained hippocampal sectionsobtained 4 d after ADX, the different morphological profiles ofapoptotic granule cells at these four types were observed clearly(Fig. 3). Semiquantitative analysis revealed that ~68.1% of theapoptotic granule cells showed the morphological changes of thesecond and third types. Approximately 6.5% exhibited those offirst type and ~25.4% those of the fourth type. Similar numbersand morphological profiles of apoptotic granule cells were notedin the ADX rats 5-7 d after operation (data not shown). The morphologyof the degenerating granule cells obtained 2 d after ADX mainlyexhibited the patterns at the second and third types of cell degeneration.The degenerating debris was sparse within the granule cell layer.
Fig. 2. Nissl-stained sections show different morphological profiles of apoptotic granule cells 4 d after ADX. These apoptotic profilesare the clumping of chromatin within the nucleus of the normal-sizedgranule cell (the first type, arrow in A), condensation of thedegenerating nucleus and cytoplasm into a darkly stained ball(the second type, arrows in B), gradual disassembly of the pyknoticgranule cells into fragments (the third type, arrows from C-E),and the gradual disappearance of the degenerating debris (thefourth type, small arrows in E, F). Scale bars: in C, 15 µm; inF, 50 µm (applies to A, B, D-F).
[View Larger Version of this Image (133K GIF file)]

Fig. 3. Apoptotic cells with different morphological profiles 4 d after ADX are present within the granule cell layer at the samesection. B-D are higher magnification views of the same siteslabeled by small capital letters B, C, and D in A. The apoptoticcells at the first (arrows in B), second and third (arrows inC, D), and fourth types (small arrow in D) are distributed inthe same section. Most apoptotic granule cells exhibited the morphologicalprofiles at the second and third types. Scale bars: in A, 200µm; in D, 70 µm (for B-D).
[View Larger Version of this Image (118K GIF file)]

Effect of corticosterone replacement on ADX-induced hippocampal granule cell apoptosis
Corticosterone replacement in drinking water (30 µg/ml) immediately after ADX prevented the appearance of silver-impregnatedgranule cells and Nissl-stained apoptotic granule cells in allof the ADX rats at each of the four time points examined. Ourcareful inspection of all of the sections from the rostral toposterior hippocampal granule cell layer in all of the rats failedto reveal any obvious apoptotic granule cells. The sham-operatedrats, which received the same corticosterone treatment as theADX rats, showed no obvious apoptotic granule cells in the hippocampus.Each ADX rat consumed, on average, 30-50 ml of corticosterone-containingwater every day. Corticosterone treatment at this dose did notinduce any abnormal behavior in the rats of either group. Therewas no significant difference in the BW between two groups atany time points. The BW (mean ± SD) 4 d after operation was ~120± 5 gm in the ADX rats and ~125 ± 5 gm in the control rats.

The time course of lysis of apoptotic granule cells induced by ADX
After the start of corticosterone replacement in the rats 4 d after ADX, individual apoptotic granule cells did not disappearfor several hours. Tracing of the distribution of degeneratinggranule cells throughout the hippocampus by silver impregnationstaining revealed apoptotic granule cells up to 48 hr after thestart of corticosterone treatment (Fig. 4). At 72 hr no silver-impregnatedgranule cells could be found at any portion of the hippocampus.The decrease in the number of silver-impregnated cells proceededfrom the inner to the outer portion of the granule cell layer.Nissl staining revealed obvious sequential changes in the morphologicalprofiles of degenerating granule cells at different time points(Fig. 5). At 1 and 4 hr after corticosterone treatment, the morphologicalcharacteristics of degenerating granule cells (Fig. 5A,B) exhibitedno marked difference from those in ADX rats without corticosteronetreatment (shown in Fig. 3). Twelve hours after the start of corticosteronereplacement, no granule cells at the first type (clumping of thechromatin within the nucleus; Fig. 5C) were identified. The mainmorphological feature of degenerating granule cells was pyknosis.Some degenerating debris and broken pyknotic cells were found(Fig. 5C). At 24 hr many pyknotic cells began to break up. Tightlycondensed degenerating cells were not the main morphological featureof degenerating granule cells (Fig. 5D). After corticosteronetreatment for 48 hr, many pyknotic granule cells were broken upinto very small pieces of degenerating debris (Fig. 5E). Chromatincondensation with the nucleus and tightly condensed pyknotic cellswere not observed at this time. The disappearance of apoptoticgranule cells usually took place first at the inner portion ofthe granule cell layer. Seventy-two hours later, all of the apoptoticgranule cells and degenerating debris had disappeared. The resultsof semiquantitative analysis (in Table 1) showed the changesin the number of apoptotic granule cells with diverse morphologicalprofiles at different time points after corticosterone replacementin the rats 4 d after ADX. As the survival time increased, theapoptotic granule cells gradually disappeared (from the clumpingof nuclear chromatin to the degenerating debris) within 72 hr.None of the 30 ADX and 12 sham-operated rats that received corticosteronereplacement displayed any abnormal behavior changes. The BW inthe ADX rat group did not exhibit any significant difference fromthat in the control group at any of six time points. Fewer thanone or two apoptotic granule cells per Nissl-stained section werefound in the hippocampal dentate gyrus of the sham-operated ratsat each of six time points.
Fig. 4. Photomicrographs illustrate the silver-stained granule cells (arrows) after corticosterone replacement in rats 4 d after ADX.A-D show the silver-impregnated cells within the granule celllayer at 1, 12, 24, and 48 hr after corticosterone treatment,respectively. The disappearance of silver-impregnated granulecells was obvious in the inner portion of the granule cell layer.Scale bar, 150 µm.
[View Larger Version of this Image (87K GIF file)]

Fig. 5. Nissl-stained sections show the morphological changes of the apoptotic granule cells at different times after corticosteronereplacement in the rats 4 d after ADX. At 1 (A) and 4 hr (B) aftercorticosterone replacement, different morphological profiles ofapoptotic cells were identified. Large and medium-sized arrowsin A and B indicate the clumping of chromatin within the nucleusand pyknosis of apoptotic cells, respectively. The main morphologicalprofile of apoptotic cells at 12 hr was pyknosis of degeneratingcells (medium-sized arrows in C) and disassembly of pyknotic cells(open arrows in C). Double small arrows indicate the degeneratingdebris. At 24 hr later, the breaking up of pyknotic cells intofragments became the main morphological feature (open arrows inD). At 48 hr, degenerating debris with different sizes (doublesmall arrows in E) still were observed. The apoptotic cells withclumping of chromatin within the nucleus disappeared from thegranule cell layer at 12, 24, and 48 hr after corticosterone replacement.Scale bar, 80 µm.
[View Larger Version of this Image (178K GIF file)]

Table 1. The number of apoptotic granule cells with different morphological profiles at each time point after corticosterone replacementin the rats 4 d after ADX

Group Clumping of chromatin Pyknosis of apoptotic cells Disassembly of pyknotic cells Apoptotic debris The total number of dying cells

ADX 3.8 ± 1.3 18.6 ± 4.9 19.7 ± 5.1 14.2 ± 4.6 56.3 ± 14.8

1 hr 2.9 ± 1.1 17.8 ± 5.2 18.6 ± 5.7 12.8 ± 3.5 52.2 ± 15.1

4 hr 2.3 ± 1.4 18.1 ± 4.6 17.2 ± 4.1 13.6 ± 3.8 51.1 ± 14.7

12 hr $-$ 17.8 ± 4.7 14.5 ± 3.4 11.8 ± 3.5 44.2 ± 12.6

24 hr $-$ 8.2 ± 3.4^* 13.1 ± 4.8 9.3 ± 2.7 30.6 ± 11.2^*

48 hr $-$ $-$ 4.9 ± 2.5^* 4.7 ± 3.3^* 9.7 ± 4.6^*

72 hr $-$ $-$ $-$ $-$ $-$

Values correspond to means ± SD per section. ( $-$ ) denotes absent, and asterisks indicate levels of significance with respectto ADX rats (p < 0.05).

The change of GR-IR after corticosterone treatment
In our previous investigation (Visser et al., 1996) and the present study we noted that the GR-IR always disappeared withinthe hippocampal granule cell layer or other brain areas aftercomplete ADX, which induced numerous hippocampal apoptotic granulecells. The absence of GR-IR exhibited no relationship with thenumber of apoptotic granule cells. To elucidate whether corticosteronereplacement in ADX rats exerts its effects promptly on the granulecells (Becker et al., 1986; Mendall et al., 1986), we examinedthe GR-IR within the hippocampus after injection of corticosterone.The GR-IR in the hippocampus, including the dentate gyrus, quicklyreappeared 1 hr after corticosterone injection in all of the ADXrats (Fig. 6). The strong GR-IR was distributed consistently throughoutthe whole brain (including the granule cell layer) from 1 hr aftercorticosterone replacement until 72 hr later. There was no obviousdifference in the GR-IR between corticosterone-treated ADX ratsand sham-operated rats at any time points. In our other experiments(data not shown), the reappearance of GR-IR in ADX rat hippocampuscould be observed successively several months after treatmentof ADX rats with corticosterone.
Fig. 6. Photomicrographs illustrating silver-stained granule cells and GR-IR within the hippocampus. In the sham-operated rat no silver-stainedgranule cells were seen (open arrows in A), and the normal GR-IRis present within the granule cell layer (arrows in B). At 4 dpost-ADX, numerous silver-stained cells (arrows in C) and thecomplete disappearance of GR-IR were present in the hippocampus(open arrows in D indicate the granule cell layer). The reappearanceof normal GR-IR in the granule cell layer (arrows in F) was identifiedclearly 1 hr after corticosterone replacement, although many silver-stainedcells (arrows in E) still were distributed within the suprapyramidalblade of the granule cell layer. Scale bars: in E, 200 µm (forA, C, E); in F, 250 µm (for B, D, F).
[View Larger Version of this Image (161K GIF file)]

DISCUSSION

The time course of lysis of apoptotic granule cells in adult rat dentate gyrus after ADX
It is very difficult to determine directly the time course for elimination of apoptotic cells from the early to late stageof cell degeneration in vivo, because apoptosis proceeds continuouslyin individual cells within the same organ at different times (Kerret al., 1972). Once the tissues are cut, only one time point isshown, which presents difficulty, particularly in the brain. Kerret al. (1972) hypothesized that the process of lysis of apoptoticcells is completed fairly rapidly: apoptotic bodies may form anddisappear within several hours. However, they did not providedirect morphological evidence to support their hypothesis. Althoughan in vitro experiment with blood T-cells and time-lapse microcinematographyrevealed that the process of the disappearance of degeneratingcells was completed within a few hours (Sanderson, 1976), thistime course is probably different from that found in in vivo.Actually, no direct morphological evidence has ever been presentedto demonstrate the time course of lysis of apoptotic cells withinthe adult brain in vivo (Russell et al., 1972; Sanderson, 1976;Matter, 1979; Wyllie et al., 1980; Kerr et al., 1987; Busch etal., 1990). In this study we discovered that the entire processof lysis of apoptotic granule cells from the beginning to theend required ~72 hr. This result is different from the conceptthat the apoptotic cell appearance persists for only a matterof several hours in living tissue (Russell et al., 1972; Kerret al., 1987; Gavrieli et al., 1992). Our results may reflectthe time course for the removal of ADX-induced apoptotic granulecells from the in vivo hippocampus.

Our study demonstrated that loss of corticosterone definitely resulted in hippocampal granule cell degeneration in all ofthe ADX rats and that ADX-induced granule cell apoptosis was blockedcompletely by the treatment with corticosterone in drinking waterimmediately after ADX (Sloviter et al., 1989, 1993a; Gould etal., 1990). These results suggested that corticosterone replacementin this study could protect granule cells continuously againstADX-induced apoptosis. An important hypothesis in this study wasthat injection of 1.5 mg of corticosterone would rescue the uninjuredbut hormone-deficient granule cells promptly from ADX-inducedapoptosis. This hypothesis was supported by several sets of evidence.(1) Our monitoring of the volume of corticosterone consumed byeach ADX rat daily revealed that it ranged from 0.9 to 1.5 mg.The ADX rats receiving corticosterone replacement at this volumedaily did not show any apoptotic granule cells, suggesting thatcorticosterone (1.5 mg injection plus subsequent replacement indrinking water) would be distributed quickly to all of the hormone-deficientcells and would be enough to block granule cell apoptosis (Gouldet al., 1990). (2) The clumping of chromatin within the nucleusof apoptotic granule cells, the morphological profile that wasconsidered as representing the early stage of cell degeneration(Kerr et al., 1972; Gould et al., 1990; Sloviter et al., 1993a,b),was not found throughout the hippocampus at 12 hr after the startof corticosterone treatment, indicating that corticosterone didrescue the viable granule cells promptly from hormone-deficientapoptosis. (3) Previous studies revealed that complete ADX inducedthe disappearance of the immunoreactivity of GR type II corticosteroidreceptors (Reul et al., 1987; Kawata, 1995) within the rat hippocampus(Visser et al., 1996). Whether GR-IR cells exist in the brainis a good indicator of whether corticosterone is present withinthe rat body. Therefore, the reappearance of normal GR-IR afterADX could be considered as the evidence that glucocorticoids exertan effect on cells (Becker et al., 1986; Mendall et al., 1986).In this study we found that the GR-IR in the ADX rat granule cellsnormally reappeared 1 hr after corticosterone replacement, suggestingthat corticosterone rapidly exerted an effect on the granule cells.Last, although all of the control rats received corticosteronereplacement at the same dose daily, none of them exhibited apoptosisgranule cells within the dentate gyrus at any time points, implyingthat corticosterone replacement did not result in granule cellapoptosis. Conversely, although we supplied the ADX rats withadequate corticosterone to block the apoptosis of healthy buthormone-deficient granule cells, there were still apoptotic granulecells in the dentate gyrus up to 48 hr after the start of corticosteronereplacement, validating our second hypothesis that corticosteronereplacement would not protect the already damaged granule cellsfrom irreversible hormone-deficient apoptosis (Kerr et al., 1972).Therefore, the granule cells already injured would continue toundergo apoptosis after corticosterone replacement. Four daysafter ADX, apoptotic granule cells with different apoptotic profileswere identified clearly within the same hippocampal section. Thesemorphological profiles might represent the different stages ofapoptosis in the process of cell degeneration (Kerr et al., 1972,1987; Sanderson, 1976; Wyllie et al., 1980; Busch et al., 1990;Sloviter et al., 1993a,b). Thus, at the time when the ADX ratsreceived corticosterone injection, apoptotic granule cells atdifferent stages of cell degeneration were already present. Sequentially,the apoptotic cells at the latest stage of the degeneration processdisappear earliest (Sanderson, 1976). Conversely, the apoptoticgranule cells at the earliest stage will disappear latest.

On the basis of above analyses, we conclude that corticosterone injection into the ADX rats quickly protected the healthygranule cells from hormone-deficient apoptosis, whereas the alreadydamaged granule cells underwent further degeneration. The ADX-inducedapoptotic granule cells do not all disappear at the same timebecause various apoptotic cells at different stages coexist withinthe hippocampus. The apoptotic cells at the earliest stage ofcell degeneration immediately after the start of corticosteroneinjection disappeared latest. Therefore, the duration from thecorticosterone injection until the time when the last degeneratingdebris disappeared approximately represents the time course ofthe elimination of apoptotic granule cells in the in vivo brain.

Throughout our experiments corticosterone replacement did not induce any obvious cell death in any field of the hippocampusin either the ADX or control rats, and the BW of the control andexperimental groups that received corticosterone treatment didnot decrease at any time points. These results excluded the possibilitythat corticosterone replacement in our experiment exerted possibleneurotoxic or stress effects on the hippocampal neurons (Sapolsky,1985, 1986), although the dose of corticosterone used was 5-10µg/ml higher than that used in previous studies (Sloviter et al.,1989, 1993a; Gould et al., 1990). However, we should emphasizethat this time course is based on a conservative estimate, becausethe disappearance of apoptotic debris as assessed by light microscopymay not coincide with that which would have been observed underelectron microscope. The apoptotic bodies that can be detectedwith light microscope are thought to comprise only a small fractionof the total number of cell remnants present (Kerr et al., 1972).Thus, the time course of the granule cell degeneration would beslightly longer than the time course that we observed. Furtherelectron microscopic analysis is now in progress.

Possibility of corticosterone regulating the time course of granule cell degeneration
At present, we do not know whether corticosterone treatment extends the time course of lysis of apoptotic cells. It has beenreported that ~50% of pyknotic granule cells in the dentate gyrusof postnatal rats contain GR (Gould et al., 1992). Corticosteronemight regulate the apoptotic granule cells at the early stageof the degeneration process. The time course of the eliminationof apoptotic granule cells might change after the alteration ofthe circulating corticosterone level. Therefore, our results reflectonly the time course of the lysis of apoptotic granule cells inthe presence of corticosterone. Experiments furthering our understandingof whether glucocorticoids change the process of apoptosis areneeded.

Potential significance of these findings
Our findings are of interest to other researchers studying the regulation of apoptosis and analyzing the morphological changesof apoptotic cells. With this simple method the time course forclearing apoptotic cells in other apoptotic models could be determined(for example, the apoptotic cell death within the adrenal cortexafter ACTH withdrawal, the apoptotic prostate cells after castration,and so on). With this approach the detailed course for removingapoptotic cells could be clarified, particularly the changes inthe morphological profiles of the apoptotic cells. Furthermore,many neurotrophic factors and proteins have the potential to induceor prevent cell death (Buttyan et al., 1989; Fanidi et al., 1992;Garcia et al., 1992; Komuro and Rakic, 1993; Louis et al., 1993).However, none has attempted to demonstrate whether these factorsinfluence the process of cell death in vivo. Treatment of ADXrats receiving corticosterone replacement with other neurotrophicfactors or regulators, followed by observation of the change inthe lysis of apoptotic granule cells, could supply direct morphologicalevidence pertaining to the effects of these factors on the processof apoptosis in the CNS.

FOOTNOTES

Received Dec. 19, 1996; revised Feb. 18, 1997; accepted March 10, 1997.

This research was supported by grants from the Ministry of Education, Culture, and Science of the Japanese Government to M.K.and by Sasagawa Research Foundation to Z.H. We thank Dr. M. Murakamifor his invaluable help throughout the course of this study.

Correspondence should be addressed to Dr. Zhongting Hu, Department of Anatomy and Neurobiology, Kyoto Prefectural Universityof Medicine, Kawaramachi-Hirokoji, Kamigyo-ku, Kyoto 602, Japan.

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