Suppression of Cathepsins B and L Causes a Proliferation of Lysosomes and the Formation of Meganeurites in Hippocampus

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Volume 17, Number 11, Issue of June 1, 1997 pp. 4006-4021
Copyright ©1997 Society for Neuroscience

Suppression of Cathepsins B and L Causes a Proliferation of Lysosomes and the Formation of Meganeurites in Hippocampus

Eric Bednarski¹, Charles E. Ribak², and Gary Lynch¹
¹ Center for the Neurobiology of Learning and Memory, and ² Department of Anatomy and Neurobiology, University of California, Irvine, California 92697

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Cultured hippocampal slices exhibited prominent ultrastructural features of brain aging after exposure to an inhibitor ofcathepsins B and L. Six days of treatment with N-CBZ-L-phenylalanyl-L-alanine-diazomethylketone(ZPAD) resulted in a dramatic increase in the number of lysosomesin the perikarya of neurons and glial cells throughout the slices.Furthermore, lysosomes in CA1 and CA3 pyramidal cells were notrestricted to the soma but instead were located throughout dendriticprocesses. Clusters of lysosomes were commonly found within bulgingsegments of proximal dendrites that were notable for an absenceof microtubules and neurofilaments. Although pyknotic nuclei weresometimes encountered, most of the cells in slices exposed toZPAD for 6 d appeared relatively normal. Slices given 7 d of recoverycontained several unique features, compared with those processedimmediately after incubation with the inhibitor. Cell bodies ofCA1 neurons were largely cleared of the excess lysosomes but hadgained fusiform, somatic extensions that were filled with fusedlysosomes and related complex, dense bodies. These appendages,similar in form and content to structures previously referredto as "meganeurites," were not observed in CA3 neurons or granulecells. Because meganeurites were often interposed between cellbody and axon, they have the potential to interfere with processesrequiring axonal transport. It is suggested that inactivationof cathepsins B and L results in a proliferation of lysosomesand that meganeurite generation provides a means of storing residualcatabolic organelles. The accumulated material could be eliminatedby pinching off the meganeurite but, at least in some cases, thisaction would result in axotomy. Reduced cathepsin L activity,increased numbers of lysosomes, and the formation of meganeuritesare all reported to occur during brain aging; thus, it is possiblethat the infusion of ZPAD into cultured slices sets in motiona greatly accelerated gerontological sequence.
Key words: lysosomal hydrolase; meganeurite; ageing; Alzheimer's disease; hyperplasia; dysfunction; neurodegeneration; aged; cortex

INTRODUCTION

Infusion of chloroquine or leupeptin into the lateral ventricles of young rats causes the appearance of morphological featuresthat are normally seen only in the aged brain. These include anaccumulation of lipofuscin (Ivy et al., 1984, 1989a; Nunomuraand Miyagishi, 1993), a build-up of abnormally phosphorylatedtau proteins in neuronal perikarya and dendrites (Ivy et al.,1989b; Takauchi and Miyoshi, 1995), increased levels of potentiallyamyloidogenic fragments (Hajimohammadreza et al., 1994), a declinein dopamine D₂ receptors in striatum (Shibata et al., 1992), anddistended initial segments of axons (Cavanagh et al., 1993). Chloroquineis an acidotropic agent that disrupts protein degradation in lysosomes(Ohkuma, 1987), whereas the predominant action of leupeptin isto block cysteine proteases (Toyo-Oka et al., 1978; Neff et al.,1979). Accordingly, lysosomal cysteine proteases are the likelycommon targets of the drugs and, from the results cited above,it would appear that a subgroup of these enzymes is closely linkedto well-established correlates of brain aging. These conclusionsraise the possibility that naturally occurring reductions in theactivities of particular lysosomal cysteine proteases are responsiblefor some of the alterations that emerge in brain in later life.Of interest with regard to this idea is the report that the activityof cathepsin L, one of the most efficient of lysosomal cysteineendopeptidases (Kirschke and Barrett, 1985; Bohley and Seglen,1992), decreases by 90% from 2 to 28 months in the neocortex,hippocampus, striatum, and cerebellum of the rat (Nakanishi etal., 1994). Age-related losses do not occur for all cysteine lysosomalhydrolases; the activity of cathepsin B is reported to remainrelatively constant in brain throughout the life span of the ratexcept in the striatum, where it increases in old age (Nakanishiet al., 1994). In all, then, the effects induced by leupeptin/chloroquinemay be aspects of a brain-aging progression normally initiatedby declines in the activity of a select group of lysosomal proteases.

Additional experimental work on the above ideas would be facilitated by compounds that have a greater degree of selectivityfor the pertinent enzymes and by test systems that allow for preciseapplications of drugs as well as for reliable collection of physiological/biochemicalmeasures of drug effects. Recent efforts in these directions havemade use of (1) the compound N-CBZ-L-phenylalanyl-L-alanine-diazomethylketone(ZPAD), a selective inhibitor of cathepsins B and L (Green andShaw, 1981; Pliura et al., 1992), and (2) newly introduced techniquesfor preparing and maintaining cultured hippocampal slices. Regardingthe latter, Muller et al. (1993) found that slices prepared fromrats in the second postnatal week and supported in an interfacechamber develop and stably maintain a number of adult characteristicsnot typically found in organotypic cultures. A system such asthis could have considerable advantages for testing the effectsof chronic drug administration on variables specific to the adultbrain (see Bahr et al., 1995a).

Initial experiments testing the effects of ZPAD on cultured slices found that 4-6 d applications resulted in (1) an increasein the lysosomal concentration of cathepsin D, (2) an escape ofactive cathepsin D from lysosomes, and (3) the appearance of acytosolic tau protein fragment (Bednarski and Lynch, 1996). Thecathepsin D findings are of particular interest, because the activityof this enzyme increases with age in homogenates and extralysosomalcellular fractions of rat brain (Nakamura et al., 1989; Nakanishiet al., 1994). Moreover, enzymatically active cathepsin D occursin proximity to senile plaques (Cataldo and Nixon, 1990) and may,because of its substrates, contribute to other more advanced signsof aging (microtubule disruption) (see Bednarski and Lynch, 1996).

The present studies tested whether suppression of cathepsins B and L results in the appearance of greatly expanded initialsegments of axons ("meganeurites," Purpura and Suzuki, 1976; or"fusiform bodies," Braak, 1979) in hippocampal slices. A relatedgoal of this work was to determine whether inhibition of the proteasescauses an increase in the number of lysosomes, an effect thatwould account for ZPAD-induced increases in cathepsin D, and whetherthis has any relationship to meganeurite formation. Previous workershave hypothesized that expansion of axon initial segments duringaging or as part of a disease process is attributable to lysosomaldysfunction (Purpura et al., 1978; Braak and Goebel, 1979), butit has not been possible to search for connections between changesin lysosomes and the emergence of anatomical abnormalities.

MATERIALS AND METHODS
Cultured hippocampal slices. Hippocampal slices were prepared from 11- to 12-d-old Sprague Dawley rats and maintained in cultureusing methods described by Stoppini et al. (1991). The upper surfacesof the slices were exposed to a humidified, 37°C atmosphere containing5% CO₂. The culture medium was composed of 50% basal medium eagle,25% Earle's balanced salt solution, 25% donor horse serum (GeminiBio-Products, Calabasas, CA), and the following supplements (inmM): 136 NaCl, 2 CaCl₂, 2.5 MgSO₄, 5 NaHCO₃, 3 glutamine, 40 glucose,0.5 ascorbic acid, 20 HEPES buffer, pH 7.3, at 23°C, and 1 mg/linsulin, 5 U/ml penicillin, and 5 mg/l streptomycin. Each of theabove components, with the exception of the horse serum, was obtainedfrom Sigma (St. Louis, MO). During the initial 10 d in culture,slices develop a variety of adult characteristics, including myelination,well-developed dendritic spines, a high synaptic density, andthe capacity for long-term potentiation (Buchs et al., 1993; Mulleret al., 1993; Bahr et al., 1995b; Vanderklish et al., 1996). Sliceswere maintained in vitro at least 9 d before experiments werestarted.

Experiments were initiated by exposing a subset of organotypic slices from a culture plate to 40-45 µM ZPAD (BACHEM Bioscience,Torrance, CA), an inhibitor of cathepsins B and L. A culture platecontained hippocampal explants from one animal only. The basemedium applied to slices (both control and treated) during theexperiments was identical to the culture medium described above,except that the horse serum was heat-treated (35 min at 56°C).Media exposed to control hippocampal slices additionally containeda suitable amount of drug diluent (DMSO). The media were replenishedevery 48-72 hr.

After 2-3 d of treatment, a subset of control and ZPAD-exposed slices were subjected to three different enzymatic assays todetermine the specificity and effectiveness of the inhibitor.Other hippocampal slices were exposed to equivalent doses of theinhibitor for 6 d (n = 5) before being immediately processed forelectron microscopy with their matched control (n = 4) cultures.In addition, a subset of control (n = 3) and ZPAD-treated (n =4) slices was maintained in culture (supplemented with regularculture medium) for an additional 7 d before fixation and processingfor electron microscopy.

Assay for the determination of cathepsin B and L activities. Cathepsin activities were determined using a modified versionof a method described previously (Barrett and Kirschke, 1981).Briefly, control and ZPAD-treated hippocampal slices were collectedin ice-cold buffer containing 20 mM Tris, 0.30 M sucrose, and1 mM EDTA, pH 7.4, and centrifuged at 12,000 × g for 5 min at4°C. The supernatants were aspirated, and the pellets were resuspendedin lysis buffer (55.2 mM KH₂PO₄, 11.5 mM NaHPO₄, 4 mM EDTA, pH4.7). After tip sonication and Bradford (1976) analyses, samplescontaining 40 µg of protein were maintained at 20°C for 18-24hr, diluted into assay buffer (340 mM sodium acetate, 60 mM aceticacid, 4 mM EDTA, and freshly prepared 8 mM dithiothreitol, pH5.4), bath sonicated for 30 sec, and centrifuged at 12,000 × gfor 12 min at 4°C. The soluble fraction was removed and co-incubatedwith 20 µM N-CBZ-Phe-Arg-7-amido-4-methylcoumarin (Sigma), a substratefor cathepsins B and L, at 37°C for 10 min. To determine the specificcontributions of the two proteases, other tubes were supplementedwith 0.75 µM CA-074 (Peptides International, Louisville, KY),a specific inhibitor of cathepsin B (Kakegawa et al., 1993; Inubushiet al., 1994). The activity of cathepsin L, determined as thefraction insensitive to CA-074, was completely suppressed when0.25 µM chymostatin (Sigma) was added to the assay. Enzyme assayswere terminated with the addition of ice-cold buffer containing70 mM acetic acid, 30 mM sodium acetate, and 100 mM iodoaceticacid, pH 4.3, and the amount of 7-amido-4-methylcoumarin liberatedfrom substrate was quantified using a fluorescence spectrophotometerequipped with 360 nm excitation and 430 nm emission filters. Valuesobtained for the enzymatic activities of cathepsins B and L weretransformed to nanomoles of 7-amido-4-methylcoumarin (Sigma) beforethe calculations comparing control and experimental samples wereperformed.

Determination of calpain activity in control and ZPAD-exposed slices. Calpain activity assays were performed in situ by exposingcontrol and ZPAD-infused slices to 200 µM NMDA for 45 min. Sliceswere then harvested into ice-cold harvest buffer (5 mM HEPES,0.32 M sucrose, 1 mM EDTA, 1 mM EGTA, 0.02% NaN₃, 10 mg/l antipain,and 2 mg/l each of leupeptin, aprotonin, and pepstatin, pH 7.4),and centrifuged at 12,000 × g for 5 min at 4°C. Pellets were resuspendedin an estimated 10× volume of lysis buffer (8 mM HEPES, 1 mM EDTA,0.3 mM EGTA, and the same protease inhibitors mentioned above,pH 8.0) and tip-sonicated. After Bradford analyses, 100 µg ofprotein from each sample was denatured by boiling for 5 min with2.5% (wt/vol) SDS and 3% (wt/vol) $beta$ -mercaptoethanol then subjectedto SDS-PAGE on 3-17% linear gradient gels (Laemmli, 1970). Resolvedproteins were transferred to nitrocellulose, and breakdown productswere labeled using antibodies to the calpain I-mediated N-terminalfragment of $alpha$ -spectrin. This antibody has been described previously(Bahr et al., 1995c). After primary antibody incubations, immunoblotswere washed and exposed to alkaline phosphatase-conjugated goatanti-rabbit IgG. Immunobands were visualized using the 5-bromo-4-chloro-3-indolyl-phosphateand nitro blue tetrazolium substrate system. Development was terminatedbefore band intensity was saturated. A computerized image analysissystem was used to quantify the mean optical density and areaof each immunoband. The product of these two values was used tocompare the specific immunoreactivities of the various samples.

Electron microscopy. Control and ZPAD-infused slices were fixed in an ice-cold solution of PBS, pH 7.5, containing 4% paraformaldehydeand 1% glutaraldehyde. After 2 hr, this solution was aspirated,and the slices were washed three times in PBS. Slices were post-fixedin 2% osmium tetroxide (in 0.1 M phosphate buffer) for 1 hr, dehydratedin a series of graded alcohols, and embedded in Polybed-812. Semithin(1 µm) sections were cut from the embedded specimens and stainedwith 0.1% toluidine blue. These sections were used to locate thesubregion of hippocampus (CA1, CA3, or dentate gyrus) to be examinedultrastructurally. After the peripheral regions of the specimenwere trimmed away, thin sections were cut with a diamond knife,mounted on Formvar-coated slot grids, stained with uranyl acetateand lead citrate, and examined with a Philips (Mahwah, NJ) CM10electron microscope.

RESULTS

The morphology of cultured hippocampal slices
The morphology of control slices maintained in culture for 15-17 d was similar to that described previously (Buchs et al.,1993). Figure 1A is a photomicrograph of a toluidine blue-stainedsemi- thin section through CA1 of an untreated slice. The cytoplasmof these cells is unremarkable, and the somata are characterizedby the presence of large centrally located nuclei. Electron micrographsof the CA1 subfield of control hippocampal slices demonstratedthe appearance of a variety of cytoplasmic organelles within pyramidalcells, including occasional electron-dense lysosomes scatteredthroughout the cytoplasm (Fig. 2A). The lysosomes of CA1 and CA3neurons were 0.1-0.5 µm in diameter, dimensions similar to thoseobtained with in vivo material (Peters et al., 1991). Apical dendritesof hippocampal neurons contained prominent, longitudinally orientedneurofilaments and microtubules together with numerous spine synapses;as is the case for hippocampus in vivo, lysosomes were rare inthe dendritic ramifications (Fig. 2B). There were no evident differencesbetween control slices collected on culture days 15-17 and thosegiven an additional week in culture.
Fig. 1. A, Light micrograph of a semithin section through CA1 of an untreated (control) cultured hippocampal slice maintained in vitrofor 16 d. Several pyramidal neurons (P) are shown with their contiguousapical (a) or basal (arrowheads) dendrites. A basophilic organelle(arrow) can be seen clearly in one CA1 neuron. Magnification,1200×. B, Light micrograph of CA1 neurons from a semithin sectionobtained from a cultured slice exposed to ZPAD, an inhibitor ofcathepsins B and L, from culture day 11-16. The pyramidal cells(P) show many of the same features as those in A, including centrallylocated nuclei, apical (a) dendrites, and basal (arrowheads) dendrites.Inspection of the cytoplasm of these neurons, however, revealsa dramatic increase in the number of basophilic punctate structures(arrows). Note that many neurons show an asymmetrical distributionof the darkly stained granules in that more are found in the basalportion of their cell bodies. Magnification, 1200×.
[View Larger Version of this Image (189K GIF file)]

Fig. 2. A, Electron micrograph of a CA1 pyramidal cell from a control cultured hippocampal slice. The nucleus (N) is centrally locatedand surrounded by numerous cytosolic organelles, including a fewlysosomes (arrow). This slice was maintained in culture for 16d. Magnification, 6200×. B, Electron micrograph of a section ofthe apical dendrite from a control CA1 pyramidal cell. This portionof the process features prominent microtubules (arrow), smallerneurofilaments, and a synapse (open arrow). Magnification, 32,000×.
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Effects of chronic ZPAD treatment on the activity of cathepsins B and L
The selectivity of the irreversible inhibitor was determined by subjecting control and ZPAD-treated slices to three differentproteolytic assays. First, treatment of cultured hippocampal sliceswith 40 µM ZPAD for 3 d resulted in a reduction in the activityof cathepsin B to 0.6 ± 0.2% (mean ± SEM) that of control levels(p < 0.001, two-tailed t test, n = 3). Second, the activity ofcathepsin L was suppressed by 97.8 ± 0.1% in ZPAD-treated slices(p < 0.001, two-tailed t test, n = 3). Third, two previous daysof ZPAD infusion did not attenuate the production of N-terminalproteolytic fragments of spectrin by 45 min of NMDA receptor stimulation.Under these experimental conditions, the optical density of spectrinbreakdown product immunobands was equal in NMDA-exposed slicestreated with and without ZPAD (76 ± 16 vs 77 ± 17, p > 0.5, two-tailedt test, n = 5 for each). Numerous studies have shown that theassayed spectrin breakdown products (~150 kDa) provide an accurateindex of recent calpain activity (Lee et al., 1991; Bednarskiet al., 1995). Together, then, these findings indicate that ZPADeffectively inhibited cathepsins B and L, but did not significantlysuppress calpain in situ.

Morphological changes induced by ZPAD
Photomicrographs of slices exposed to ZPAD for 6 d revealed that a great majority of neurons throughout all subfields of hippocampuscontained large numbers of basophilic densely stained granules(Fig. 1B). The granules appeared to be preferentially containedwithin the basal soma of several CA1 pyramidal cells. Electronmicroscopy confirmed that the dark granules were lysosomes. Figure3A is an electron micrograph of a CA1 neuron from a treated slice;as is evident, numerous lysosomes surround the nucleus and extendinto the proximal dendrites. Note also that small dendritic processesadjacent to the cell body also contain lysosomes, a feature notseen in control material. Most of the lysosomes were larger thannormal (measuring 0.73 ± 0.07 µm in diameter in CA3 neurons, n= 108), with a minority being irregularly shaped and containingboth vacuoles and twisted membranes (Fig. 3B). Finally, despitespreading throughout much of the dendritic cytoplasm, lysosomeswere rarely observed in the axon hillock and axon initial segmentsof CA1 neurons from ZPAD-treated slices (Fig. 4A,B). It shouldbe noted that lysosomal hyperplasia was not restricted to neurons;astrocytes and oligodendrocytes of ZPAD-infused slices also containedabnormally elevated numbers of lysosomes (data not shown).
Fig. 3. A, Montage of electron micrographs showing a CA1 neuron from a cultured hippocampal slice exposed to ZPAD for 6 d. Numerouslysosomes (arrows) are located in the apical portion of the perikaryonand proximal apical dendrites. The nucleus (N) appears normal.Magnification, 4700×. B, Enlargement of a portion of the soma.The milieux of some lysosomes contain twisted membranes (largearrow); other lysosomes have vacuoles of various sizes (open arrow).Mitochondria (small arrow) appear normal. Magnification, 26,500×.
[View Larger Version of this Image (221K GIF file)]

Fig. 4. A, Electron micrograph of the basal portion of a CA1 pyramidal cell soma from a ZPAD-treated slice. Although numerous lysosomes(arrows) encircle the nucleus (N) and are found within the proximalspan of a basal dendrite (d), none are observed in the axon hillock(h) and initial segment (is) within this section. Vacuole-containinglysosomes (open arrows) are also evident within the perikaryalcytoplasm. Magnification, 8300×. B, Enlargement of the axon initialsegment (is). Note the dense axolemmal undercoating, microtubulebundling, cisternal organelle (arrow), mitochondria (arrowheads),and paucity of lysosomes. Magnification, 15,000×.
[View Larger Version of this Image (217K GIF file)]

Despite the dramatic increase in lysosome number, other subcellular organelles (e.g., mitochondria, Golgi complexes, and cisternaeof endoplasmic reticulum) of most neurons in slices exposed toZPAD appeared normal (Figs. 3A,B, 4A, 5A). Synapses were frequentand had normal constituents including vesicle-containing terminals,spines, and postsynaptic densities (Fig. 5A-C) that were not detectablydifferent in appearance than those in control slices. However,pyknotic neurons were occasionally encountered, particularly infield CA3 (Fig. 6A).
Fig. 5. A, Electron micrograph of a CA3 apical dendrite from a ZPAD-treated slice. Most lysosomes are located either adjacent to thenucleus (N) or found clustered within a bulging segment of theapical dendrite (d). A spine is evident distal to the dendriticbulge (arrow). A satellite cell (S) is present alongside the dendrite.Magnification, 8000×. B, Enlargement of the dendritic bulge. Intactmicrotubules and neurofilaments are not apparent within the twolysosomal assemblages. Note the presence of several synapses (arrows).Magnification, 15,000×. C, Enlargement of the dendritic spine(sp) noted in A and accompanying mossy fiber (m). Magnification,22,000×.
[View Larger Version of this Image (221K GIF file)]

Fig. 6. A, Electron micrograph of a portion of the CA3 field at the junction of the cell body layer and stratum radiatum of a slicetreated with ZPAD for 6 d. At the bottom of the field, a row oflysosomes (arrow) is found in an apical dendrite (d). Note thatthe dendrite also contains vacuolated lysosomes (open arrow).A pyknotic nucleus (P) can be seen adjacent to this dendrite.Membrane-bound cellular processes containing lysosomes and mitochondriaare located around the compacted nucleus. Magnification, 13,500×.B, Micrograph of a section of CA3 stratum radiatum from a treatedhippocampal slice. A large lysosome (large arrow) fills most ofa swollen secondary dendrite. Flanking the lysosome are two spines(small arrows). Magnification, 15,000×.
[View Larger Version of this Image (192K GIF file)]

In some large dendrites, generally those of field CA3, groups of lysosomes formed parallel aggregates that were flanked byarrays of intact microtubules and neurofilaments (Fig. 5A,B).In such cases, it appeared that a segregation had occurred betweenthe longitudinally oriented cytoskeleton and the lysosomes. Proximaldendritic segments adjacent to large accumulations of lysosomeswere often distended (Fig. 5A). Rows of lysosomes were also found200-300 µm from the cell bodies in the more distal dendritic tree(Fig. 6A); some secondary dendrites contained isolated lysosomesthat were larger than the diameter of the initial portion of thebranch (Fig. 6B). The above effects of ZPAD were found in allsubdivisions of hippocampus, although, as noted, some were moreprominent in the CA3 neurons.

Effects of a 7 d recovery period on ZPAD-induced changes in hippocampal ultrastructure
Slices treated with ZPAD for 6 d and then allowed 1 week to recover contained lysosomes significantly smaller than those describedpreviously. Measurements taken from electron micrographs of fieldCA3 indicated that the lysosomes were 52% smaller than beforerecovery (p < .001, two-tailed t test, n = 128). Profiles indicativeof the fusion of multiple lysosomes were found throughout thepyramidal cell fields. The fused structures, which were not commonin slices collected immediately after the termination of ZPADtreatment, contained electron-dense heterogeneities, whorled membranes,and vacuoles. Given their size and appearance, it can be assumedthat the fused dense bodies (FDBs) were composed of secondarylysosomes, postlysosomal compartments, and autophagic vacuoles(for a description of similar profiles, see Samorajski et al.,1964; Dunn, 1990).

Except for the increase in FDBs and reduction in the size of lysosomes, field CA3 appeared little changed from the end ofZPAD infusion to the end of washout. However, alterations in additionto these were observed in the other hippocampal regions afterthe recovery period. These are grouped below into five categories.First, a reduction in the number of lysosomes in cell bodies andproximal dendrites of CA1 neurons was evident in recovered slicesrelative to slices processed immediately after ZPAD exposure (compareFigs. 7A and 3A). This observation was unique to CA1 neurons.Second, lysosomes and FDBs were observed in the axon hillock andaxon initial segments of CA1 neurons and granule cells. Mossyfiber terminals were commonly filled with lysosomal bodies, suggestingthat granule cells routinely transported lysosomes and/or FDBsdown their axons. In accord with this, solitary lysosomes wereobserved frequently in granule cell axons of the hilus. CA1 pyramidalcells were notable for large numbers of lysosomal bodies withinthe axon hillock region. Third, many CA1 neurons and granule cellsexhibited somal expansions. Although some of the protuberanceswere located away from the basal pole of the perikarya, most wereinterposed between cell body and axon initial segment (Fig. 7A,B).The latter processes (meganeurites) were greatly extended, fusiform,and observed only in CA1 neurons. All of the somal expansions,regardless of size or location, contained mitochondria, ribosomes,and significant accumulations of lysosomes and FDBs. However,the interiors of longer meganeurites (>40 µm) were noticeablydifferent from those of the less developed expansions. The proximalsegments of these meganeurites had organized rows of FDBs somewhatlike the configuration of lysosomes frequently found in the dendritesof ZPAD-treated slices (see Fig. 6A). At increasing distancesfrom the cell soma, unusually electron-dense and vacuolated FDBswere fused into aggregates that nearly spanned the entire widthof the neuronal process (Fig. 8A,B). It is noteworthy that lysosomesand FDBs, although numerous in the fusiform expansions, were rarelyseen in the contiguous axon initial segments. Fourth, groups ofmembrane-encircled processes filled with mitochondria, filamentousaggregates, and FDBs were frequently observed in the CA1 subfield(Fig. 8C). These apparent neurites were extremely rare in thedentate gyrus. The neurites were occasionally wrapped in myelinand had contents resembling those in the distal aspects of meganeurites(compare Fig. 8, B and C). Astrocytes were commonly associatedwith groups of FDB-filled neurites (Figs. 9A,B). Fifth, lysosomesin CA1 neurons were frequently located in unusually close appositionto cellular membranes. Rows of lysosomes, similar to those describedpreviously after 6 d of ZPAD treatment, were now present in themost lateral aspects of dendritic processes (compare Fig. 10A-Cand 6A).
Fig. 7. A, Montage of electron micrographs of a CA1 neuron 7 d after the conclusion of ZPAD exposure. Although the nucleus (N), soma,and axon initial segment (is) appear normal, the location of theaxon initial segment is distally displaced by a fusiform expansion(arrows) of the axon hillock region (meganeurite). The cytosolof the meganeurite, unlike that of the axon and soma, containsmany lysosomes. Magnification, 6200×. B, Enlargement of the indicatedportion of the fusiform expansion. Magnification, 18,500×. C,Enlargement of the region containing the axon initial segment.Note that this region contains several mitochondria (arrowheads)and a few lysosomes. Magnification, 18,500×.
[View Larger Version of this Image (159K GIF file)]

Fig. 8. A, Montage of electron micrographs showing the distal portion of a meganeurite from a treated CA1 pyramidal cell. The lengthof the meganeurite is more than twice the diameter of the parentsoma (data not shown). Note that a columnar organization of lysosomesand FDBs is found within the proximal aspects of the meganeurite(top of field). FDBs at the more distal regions of the process(bottom of field), however, are compacted into larger dense bodies(DB). Magnification, 6200×. B, Enlargement of the more distalsegment of the meganeurite. The circular aggregates are composedof FDBs and vacuoles. Note the presence of mitochondria (arrowheads)that appear normal. Magnification, 20,000×. C, Micrograph of amembrane-bound cellular profile filled with FDBs observed in CA1stratum oriens of a ZPAD-treated slice. Magnification, 13,500×.
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Fig. 9. A, CA1 of a slice maintained in culture for 1 week after ZPAD treatment. An astrocyte (a) is adjacent to several FDB-ladencellular processes. Magnification, 8500×. B, Enlargement of twoof the processes. Note the presence of filaments between the twoprofiles and the discontinuous nature of the membrane encirclingthe process on the left. Magnification, 18,000×.
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Fig. 10. A, Electron micrograph of a portion of CA1 depicting an apical dendrite (d) of a ZPAD-exposed slice. Clusters of FDBs lineup adjacent to an irregular dendritic membrane. Magnification,19,000×. B, A cellular process filled with FDBs apposes a concavityof a distal CA1 meganeurite. Magnification, 16,000×. C, Lysosomesfill a dendritic protrusion. Note the vesicles containing residualcatabolic organelles and whorled bodies (arrow) beside the excrescence.Magnification, 20,000×.
[View Larger Version of this Image (190K GIF file)]

DISCUSSION
Incubating cultured hippocampal slices for 6 d with an inhibitor of cathepsins B and L caused a massive increase in the numberof lysosomes. This effect provides an explanation for the earlierobservation that inhibition of these enzymes results in a rapidlydeveloping increase in the activity and concentration of the lyso-somal protease cathepsin D (Bednarski and Lynch, 1996). The cellularmechanisms responsible for lysosomal proliferation are subjectsfor additional studies (for discussion, see Cataldo et al., 1996).Cathepsin L, one of the cysteine proteases targeted by the drugused in the present study, is among the most efficient and potentof lysosomal endopeptidases with regard to the initial breakdownof transported proteins (Kirschke and Barrett, 1985; Kominamiet al., 1991; Bohley and Seglen, 1992), and its suppression wouldpresumably lead to the accumulation of incompletely digested proteinsand proteinaceous structures (for discussion, see de Duve andWattiaux, 1966). It is not unreasonable to assume that genes encodinglysosomal enzymes are sensitive to one or more aspects of suchaccumulations; if so, then upregulation of the genes, followedby increases in the number of protease copies, could be the triggerfor the expansion of the primary lysosome population. Experimentsare now in progress to determine whether incubations with ZPADproduce higher concentrations of mRNAs for various lysosomal enzymes.

Suppression of cathepsins B and L for 6 d not only increased the number of lysosomes but also led to their translocation intothe dendritic trees of the pyramidal neurons. Interestingly, thedendritic lysosomes were found near the core of primary and secondarybranches and were commonly displaced from longitudinally orientedmicrotubular systems. The latter observation raises the possibilitythat the migration of lysosomes into the dendritic ramificationsis not simply a reaction to the overproduction occurring in thecell bodies but also involves a disturbance of cytoskeletal structuresthat normally maintain the somal compartmentalization of subcellularorganelles. In accord with this idea, previous work has shownthat chemicals that disrupt microtubules cause a movement of lysosomesinto dendrites (Herman and Albertini, 1984; Gorenstein and Ribak,1985), an effect similar to the migration found in the presentstudy. Also pertinent is the finding that ZPAD-treated slicescontain a cytosolic tau fragment produced by extralysosomal concentrationsof cathepsin D (Bednarski and Lynch, 1996). Tau plays a pivotalrole in cross-linking microtubules and in maintaining the integrityof the cytoskeleton (Weingarten et al., 1975; Goode and Feinstein,1994), and its proteolysis by aberrantly located cathepsin D mightwell remove strictures on the movements of the lysosomes. Leakageof cathepsin D from lysosomes into the surrounding cytoplasm withsubsequent cleavage of tau could also account for the microtubulefree zones, in which dendritic lysosomes were found.

CA1 neurons from cultured slices exposed to ZPAD for 6 d and then given 7 d of recovery exhibited the following differencesfrom slices processed immediately after drug incubation: (1) anincrease in the incidence of FDBs; (2) a marked reduction in thenumber of lysosomes and FDBs in the cell bodies; (3) the selectivepresence of lysosomes and FDBs in the axon hillock and initialsegment of the axon; and (4) numerous lysosomes and FDBs withinmeganeurites (fusiform bodies) growing out of the perikarya. Theappearance of the FDBs corresponded to that reported for secondarystructures resulting from the aggregation of multiple lysosomesand their fusion with other organelles and vacuoles (Samorajskiet al., 1964). In the case of the ZPAD-treated slices, the FDBsare likely the result of accumulations of proteins and lipidsincompletely degraded during the 6 d period in which key lysosomalproteases had been inhibited. The clearing of the cell body andthe immediately adjacent growth of meganeurites can reasonablybe assumed to be related events; i.e., it is likely that the meganeuritesare storage sites for excess catabolic organelles. This processmay contribute to neuronal survival. Many cellular functions occurwithin the perikaryal cytoplasm and require specific connectionsand spatial relationships between subcellular organelles; thesecould be disturbed by the presence of numerous lysosomes and largeFDBs. Clearing the perikaryal cytoplasm by sequestering lysosomesinto meganeurites could serve to restore the normal ultrastructureof the soma and thereby circumvent a variety of biochemical problems(Mann and Yates, 1974).

Although meganeurite formation may assist neuronal viability, these somatic appendages ultimately could have detrimental effects.Commonly located between the cell soma and initial portion ofthe axon, meganeurites are positioned to alter negatively theprocesses underlying orthograde and retrograde axonal transport;with time, this would have the effect of depriving the cell oftrophic substances. It is noteworthy that the experimental paradigmproduced meganeurites only in CA1 neurons, because these cellsconstitute the hippocampal subpopulation most vulnerable to degenerationin Alzheimer's disease (AD) (West et al., 1994). Beyond this,it is possible that meganeurites are transitional structures generatedby neurons as part of an exocytotic event (Purpura and Suzuki,1976; Cavanagh et al., 1993). Data obtained from studies on thespinal ganglion suggest that cells remove structures similar toFDBs by pinching off recently generated cytoplasmic protrusions(Spoerri and Glees, 1973). If meganeurites are eventually separatedfrom the parent cell, then their location, commonly proximal tothe axon initial segment, raises the possibility that this releaseevent may result in axotomy.

Combining the present results with those reported previously on the effects of ZPAD leads to the following hypothesis regardingthe sequence of events set in motion by suppression of cathepsinsB and L. First, a rapid buildup of undigested proteins and macromolecularstructures induces the expression of a subgroup of lysosomal proteasesand an increase in the number of primary lysosomes. Second, leakageof cathepsin D from lysosomes causes the unusual cleavage of severalproteins including tau. Third, local breakdown of the microtubularsystem allows lysosomes to migrate out of the cell body and graduallywork their way toward distal dendrites. Fourth, lysosomes beginforming secondary structures including FDBs. Fifth, FDBs are clearedfrom the soma and dendrites of compromised neurons and commonlycollect at the region of the axon hillock, the basal pole of CA1neurons. Accumulations of FDBs and lysosomes trigger membraneextrusions and meganeurite formation. Sixth, meganeurites arepinched off the cells, in some cases separating the axon fromthe somata (Fig. 11).
Fig. 11. Schematic diagram showing a hypothetical sequence of ZPAD-induced alterations on the fine morphology of CA1 neurons. The perikaryalcytosol of a control CA1 pyramidal cell contains only three lysosomes(cell on far left). Six days of exposure to ZPAD, an inhibitorof cathepsins B and L, result in a dramatic expansion of the lysosomalpopulation (second cell in diagram). CA1 neurons allowed to recoverfor 7 d after ZPAD treatment restore the normal ultrastructureof the soma by sweeping the excess lysosomes and residual bodiesinto the axon hillock and initial segment (middle neuron). Indistal portions of long "meganeurites," lysosomal bodies are fusedinto circular aggregates (fourth cell). The last neuron (on thefar right) depicts a hypothesized outcome of this sequence inwhich subsequent exocytosis of the lysosomal compactions resultsin pyramidal cell axotomy.
[View Larger Version of this Image (15K GIF file)]

Lysosomal proliferation has been observed in neurons of aged rats and humans and in vulnerable cells in AD (Terry et al.,1964; Brizzee et al., 1969; Brunk and Ericsson, 1972; Hinds andMcNelly, 1979; Cataldo et al., 1996). Increased concentrationsand activities of cathepsin D also occur in both conditions (Kenesseyet al., 1989; Nakanishi et al., 1994; Cataldo et al., 1995), andthere is also evidence that these increases are accompanied byleakage of the protease into the cytoplasm (Nakamura et al., 1989).A tau protein fragment similar in size to that generated whentau is exposed to cathepsin D is found in neurofibrillary tangles(Nieto et al., 1990; for discussion, see also Bednarski and Lynch,1996). Translocation of lysosomes into dendrites has been reportedfor aged and AD brains (Terry et al., 1964; Cataldo et al., 1994),and meganeurites emerging from cell bodies are evident from earlyold age onward in human neurons most at risk to degeneration (Braak,1979; Cataldo et al., 1994). Meganeurites may represent storagestructures that are eventually released from neurons. If so, thesomal location of these expansions indicates that neuronal deefferentationmay result from this pinching-off process. Multiple occurrencesof pyramidal cell axotomy would result in synaptic loss, reductionsin white matter volume, deficits in axonal transport, and myelindegradation; these are four prominent features of the aged brain(Burke et al., 1990; Masliah et al., 1993; Peters et al., 1994).It is also the case that at least one aspect of the triggeringevent used in the cultured slice studies occurs during brain aging.As noted, the activity of cathepsin L, one of the two known targetsof ZPAD, is reported to decrease with age in the forebrain ofthe rat (Nakanishi et al., 1994). The inactivation of cathepsinL is not attributable to a drop in the concentration of enzymeand, thus, may reflect some perturbation of intralysosomal conditionsinteracting with its extreme sensitivity to pH (Machleidt et al.,1986; Dufour et al., 1988; for discussion, see also Nakanishiet al., 1994).

In all, then, it is possible that the sequence proposed to follow on selective lysosomal dysfunction in cultured slices isa reproduction of a complex series that occurs during normal brainaging. The present work thus supports the idea that suppressionof lysosomal functioning provides a means for modeling brain aging(Ivy et al., 1984; Ivy, 1992) and extends such effects to includein vitro preparations. It must be said, however, that certainprominent features of brain aging, most notably autofluorescentlipofuscin granules, were not observed in cultured slices afterinhibiting cathepsins (E. Bednarski, unpublished data). This representsa significant difference from the results of in vivo studies usingchloroquine or leupeptin (Ivy et al., 1984). It may be that theproduction of autofluorescent granules observed in vivo resultsnot specifically from cathepsin B and L inhibition, but insteadfrom other cellular or systemic effects of broad-range proteaseinhibitors. Alternatively, cultured slices may lack sequencesoccurring in parallel with lysosomal hyperplasia that contributesignificantly to lipofuscin generation. If the latter possibilityis correct, additional manipulations will be required to obtaina satisfactory approximation of the aged brain.

FOOTNOTES

Received Oct. 2, 1996; revised March 7, 1997; accepted March 12, 1997.

This work was supported by National Institute of Aging Grant AG00538 and National Institute of Mental Health, National ResearchService Award MH14599. We wish to thank Marian Shiba-Noz, JohnHan, Sue Fisher, and Zsolt Toth for technical help.

Correspondence should be addressed to Dr. Eric Bednarski, Center for the Neurobiology of Learning and Memory, University ofCalifornia, Irvine, CA 92697-3800.

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