Expression of mutant huntingtin in glial cells contributes to neuronal excitotoxicity

doi:10.1083/jcb.200508072

A correction to this article has been published: Shin et al., J. Cell Biol. 172 (6) 953
Published 19 December 2005. doi:10.1083/jcb.200508072
The Rockefeller University Press, 0021-9525 $8.00
JCB, Volume 171, Number 6, 1001-1012

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Expression of mutant huntingtin in glial cells contributes to neuronal excitotoxicity

Ji-Yeon Shin, Zhi-Hui Fang, Zhao-Xue Yu, Chuan-En Wang, Shi-Hua Li, and Xiao-Jiang Li

Department of Human Genetics, Emory University School of Medicine, Atlanta, GA 30322

Correspondence to Xiao-Jiang Li: xiaoli{at}genetics.emory.edu

Top
Abstract
Introduction
Results
Discussion
Materials and methods
References

Huntington disease (HD) is characterized by the preferentialloss of striatal medium-sized spiny neurons (MSNs) in the brain.Because MSNs receive abundant glutamatergic input, their vulnerabilityto excitotoxicity may be largely influenced by the capacityof glial cells to remove extracellular glutamate. However, littleis known about the role of glia in HD neuropathology. Here,we report that mutant huntingtin accumulates in glial nucleiin HD brains and decreases the expression of glutamate transporters.As a result, mutant huntingtin (htt) reduces glutamate uptakein cultured astrocytes and HD mouse brains. In a neuron–gliacoculture system, wild-type glial cells protected neurons againstmutant htt-mediated neurotoxicity, whereas glial cells expressingmutant htt increased neuronal vulnerability. Mutant htt in culturedastrocytes decreased their protection of neurons against glutamateexcitotoxicity. These findings suggest that decreased glutamateuptake caused by glial mutant htt may critically contributeto neuronal excitotoxicity in HD.

Abbreviations used in this paper: AD, Alzheimer's disease; DHK,dihydrokainate; DIV, days in vitro; GFAP, glial fibrillary acidicprotein; GLT-1, glutamate transporter-1; GLAST, glutamate/aspartatetransporter; HD, Huntington's disease; htt, huntingtin; MAP2,microtubule-associated protein 2; MSNs, medium-sized spiny neurons;MTT, 3-(4,5-dimethyl thiazol-2-yl)-2,5-diphenyl tetrazoliumbromide; PolyQ, polyglutamine.

Introduction

Top
Abstract
Introduction
Results
Discussion
Materials and methods
References

Expansion of a polyglutamine (PolyQ) tract in huntingtin (htt)causes the preferential degeneration of striatal neurons inpatients with Huntington's disease (HD) despite the widespreadexpression of htt in neuronal and nonneuronal cells. The factthat HD transgenic mouse models can develop neurological symptomswithout obvious neurodegeneration indicates that early neuronalinjury and dysfunction are the major causes of neuropathologicphenotypes in these mice. Consistently, early neuronal injurycaused by mutant htt can lead to reactive gliosis in many HDmouse models (Reddy et al., 1998; Lin et al., 2001; Yu et al., 2003)and in postmortem brains of HD patients (Myers et al., 1991;Sapp et al., 2001). Recent studies show that transgenicmice expressing mutant htt only in cortical neurons do not haveobvious gliosis and other pathologies, suggesting that cell–cellinteractions play a critical role in HD pathology (Gu et al., 2005).However, little is known about the role of glia htt inHD neuropathology, despite findings that htt is also expressedin glial cells (Singhrao et al., 1998; Hebb et al., 1999).

Glial cells constitute 90% of the cells in the brain and provideneurons with nutrition, growth factors, and structural support.They also protect against excitotoxicity by clearing excessexcitatory neurotransmitters from the extracellular space (Maragakis and Rothstein, 2001).This protective function may be particularlyrelevant to the selective degeneration of medium-sized spinyneurons (MSNs) in the striatum in HD and the theory of excitotoxicityfor HD pathogenesis (Coyle and Schwarcz, 1976; Beal, 1994).MSNs are innervated by glutamatergic axons, and overstimulationof glutamate receptors induces cell death or excitotoxicity.The involvement of excitotoxicity in HD is supported by considerableevidence. First, administration of NMDA receptor agonists tothe striatum of normal animals causes a selective loss of MSNsand neurological symptoms similar to those seen in HD patients(Coyle and Schwarcz, 1976). Second, NMDA receptor antagonistseffectively reduce excitotoxicity in HD animal models (Greene et al., 1993).Furthermore, HD transgenic mouse models showincreased NMDA receptor activity in neurons (Cepeda et al., 2001;Zeron et al., 2002). The abundant glutamatergic afferentsto MSNs and the unique NMDA receptor subunit composition inMSNs (Calabresi et al., 1998; Kuppenbender et al., 2000; Li et al., 2003)may confer their preferential vulnerability inHD, especially when the glutamatergic input is increased orthe clearance of extracellular glutamate is decreased.

Clearance of extracellular excitatory neurotransmitters is largelyperformed by glutamate transporters (GLT-1 and GLAST) in astrocytes,which is the major subtype of glia (Maragakis and Rothstein, 2001).It has been found that mutant htt can reduce the expressionlevel of glutamate transporter-1 (GLT-1) in the brains of HDtransgenic mice and Drosophila melanogaster (Lievens et al., 2001,2005; Behrens et al., 2002). It remains unclear whethermutant htt directly affects glial function and, more important,how glial dysfunction contributes to neuropathology. The presentstudy provides evidence that NH₂-terminal mutant htt in glialcells reduces glial glutamate uptake, and this glial dysfunctionmay critically contribute to neuronal excitotoxicity.

Results

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Abstract
Introduction
Results
Discussion
Materials and methods
References

Intranuclear htt aggregates in glial cells
We used an antibody (EM48) to htt and performed immunogold labelingto examine brains from R6/2 mice that express HD exon1 proteinwith a 115–150-glutamine repeat. EM48 sensitively detectsaggregated htt in HD brain (Li et al., 2000), enabling us toidentify htt nuclear aggregates in glial cells in the striatumof R6/2 mice (Fig. 1 A). Glia can be classified as microglia,astrocytes, or oligodendrocytes. They are distinguished fromneurons by a condensed nuclear envelope, a small and irregularshape, and a limited cytoplasmic area with sparse content. Microglialcells often show highly condensed nuclear membranes. Identificationof astrocytes is primarily based on the presence of fibrilswithin their processes, and oligodendrocytes are often recognizedby their association with groups of myelinated nerve fibers.The ultrathin sections used for electron microscopy might nothave allowed us to definitively identify astrocytes containinghtt aggregates, as a single plane of an ultrathin section couldhave been too thin to show both htt aggregates and the distinguishingmorphological features of the cell. However, some glial cells,which displayed a highly condensed nuclear membrane and a smallcytoplasmic space, contained intranuclear aggregates (Fig. 1,A–C). The nuclear htt aggregates in these glial cellsare clearly smaller than neuronal nuclear inclusions (Fig. 1D). Small glial nuclear inclusions were observed in the striatum(Fig. 1 A) and cortex (Fig. 1, B and C) of R6/2 mice 11–12wk old. We also observed some hypertrophic and dark glial cellswith increased electron density in R6/2 mice. These cells didnot show visible cytoplasmic organelles and, in many cases,engulfed neuronal bodies or processes (Fig. S1, A and B, availableat http://www.jcb.org/cgi/content/full/jcb.200508072/DC1). Thehypertrophic glial cells are smaller and darker than the previouslyidentified dark neurons (Turmaine et al., 2000; Yu et al., 2003),which often have long neuronal processes that have begun todegenerate (Fig. S1, C and D). Like dark neurons, the degeneratingglial cells were not frequently observed and did not show httaggregates, suggesting that glial dysfunction rather than degenerationis more important for HD pathology.

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Figure 1. Electron micrographs of HD mouse brains. (A–D) EM48 immunogold labeling of the striatum (A) and cortex (B–D) of R6/2 mice at 12 wk of age. Immunogold-labeled aggregates are present in glial cells (arrows), which show a more condensed nuclear membrane and a smaller sized cytoplasm than do neuronal cells (arrowheads). Bars, 1 µm.

Expression of mutant htt in astrocytes in HD transgenic mouse brains
Because the spectrum of morphological variations among glialcells makes it difficult to define astrocytes containing httaggregates by electron microscopy, we performed immunofluorescentdouble labeling on thin sections (8–10 µm) of frozenbrain. We first examined white matter that was enriched in astrocytesand was devoid of neurons. Astrocytes are the most abundantglial cell type in the brain and can be specifically labeledby antibody to glial fibrillary acidic protein (GFAP). AlthoughGFAP-labeling was prominent in white matter, only a few cellsdisplayed both strong GFAP staining and mutant htt (Fig. 2 A).This is perhaps because strong GFAP staining is only seen inreactive astrocytes that may have an increased capacity to clearmutant htt. We also performed confocal imaging analysis of whitematter and confirmed that mutant htt forms small aggregatesin GFAP-positive glial cells (Fig. 2 B). In addition, groupsof GFAP-positive astrocytes were often found in the striatum(Fig. 2 C) and were not labeled by antibodies to other glialmarkers (myelin basic protein for oligodendrocytes and F4/80for microglia) or the neuronal marker NeuN (not depicted), suggestingthat they are mainly astrocytes. Glial nuclei, when stainedwith the Hoechst dye, are smaller and denser than neuronal nuclei.The small htt aggregates in glial nuclei as well as GFAP stainingof glial processes allowed us to distinguish htt-containingglial cells from neurons that show larger and more intense EM48-labeledaggregates in their nuclei (Fig. 2, A and C). Based on thesecharacteristics, we counted htt-containing glial cells in theHD mouse brains.

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Figure 2. Immunofluorescent labeling of htt-containing glia in R6/2 transgenic mouse brains. (A) Immunofluorescent labeling of brain sections containing white matter (WM) and the central region of the cerebellar cortex (Ctx) in an R6/2 mouse 8 wk old. Mouse antibody to GFAP labeled astrocytes (green) and rabbit EM48 labeled mutant htt (red). The nuclei were labeled with Hoechst dye (blue). (B) Confocal imaging of white matter showing that the nuclei of GFAP-positive glial cells contain htt aggregates (Video 1, available at http://www.jcb.org/cgi/content/full/jcb.200508072/DC1). (C) The striatal section of an R6/2 mouse at 8 wk of age was stained with antibody to GFAP and the nuclear dye Hoechst (top). EM48 immunostaining for htt and merged image are also presented (middle). Bottom panels shows merged images of striatal regions from 12- or 4-wk old R6/2 mice. Arrows indicate glial nuclei that contain EM48 staining. Small puncta represent neuropil aggregates. (D) The percentage of glial cells containing nuclear EM48 staining in the brain striatal sections of R6/2 mice at the age of 4, 8, or 12 wk. (E) The percentage of glial cells with intranuclear htt in the striatum (Str), cortex (Ctx), hippocampus (Hipp), and WM in R6/2 mice at the age of 8–10 wk. The data (mean ± SD) were obtained from three to five mice per group. **, P < 0.01 compared with the samples of 8 or 12 wk old R6/2 mice. Bars: (A) 5 µm; (B) 2.5 µm; (C)10 µm.

Unlike neurons, only some glial cells show intranuclear httlabeling, but the prevalence of nuclear htt aggregates in glialcells is increased with age (Fig. 2 C). In the striatum, 17.6%of glial cells showed intranuclear htt staining at 4–5wk, whereas 42 and 52.6% of glial cells displayed nuclear httat 8–9 and 11–12 wk, respectively (Fig. 2 D). Wealso used an antibody to another glial marker, glutamate/aspartatetransporter (GLAST), and validated the above finding (unpublisheddata). Because EM48 is sensitive to aggregated htt and mightnot label soluble mutant htt, the number of glia expressingmutant htt might be more than what we observed. The progressiveincrease of glial nuclear htt correlates with disease progressionin R6/2 mice, which show significant neurological symptoms at8 wk and often die after 12 wk (Davies et al., 1997). In whitematter, a similar age-dependent increase of intranuclear httwas also seen (Fig. S2, available at http://www.jcb.org/cgi/content/full/jcb.200508072/DC1).Glial htt aggregates seem to be slightly more abundant in thestriatum than in the cortex, hippocampus, and white matter (Fig. 2E), perhaps because of the relatively high density of astrocytesin the striatum (San Jose et al., 2001). However, the accumulationof htt in glial nuclei occurs noticeably later than in neurons(Fig. 2 C), suggesting that glial cells are more capable ofclearing misfolded htt than neuronal cells.

Decreased expression of GLT-1 and glutamate uptake in HD mouse brains
Decreased expression of GLT-1 protein was observed in the HDbrain by Western blotting (Fig. 3, A and B). The expressionof GLT-1 seems to correlate inversely with the age-dependentnuclear accumulation of htt in glial cells, as the brain ofHD mice at 11–12 wk showed a greater reduction of GLT-1than those at 4 wk (Fig. 3, A and B). The expression level ofGLAST appeared to be variable in individual mice, but was notsignificantly decreased in R6/2 mice as compared with littermatecontrols (Fig. S3, A and B, available at http://www.jcb.org/cgi/content/full/jcb.200508072/DC1).Although Hdh CAG knock-in mice did not show a significant reductionof brain GLT-1 and GLAST even at the age of 9 mo, a slight decreaseof GLT-1 expression was observed in the striatum (Fig. S3, Cand D). This finding supports the idea that NH₂-terminal mutanthtt is more toxic than full-length htt in affecting the expressionof GLT-1. Consistent with previous studies (Lievens et al., 2001;Behrens et al., 2002), RT-PCR confirmed that GLT-1 transcriptswere significantly reduced in HD mouse brains, while GLAST transcriptswere slightly decreased (Fig. 3 C).

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Figure 3. Decreased expression of glutamate transporter GLT-1 and glutamate uptake in HD mouse brain. (A and B) Western blot analysis of the expression of GLT-1 in brain regions of wild-type (W1-W4) or R6/2 (HD1-HD4) mice at 4 wk (A) and 11–12 wk old (B). The same blots were probed with antibody to tubulin. The signal ratios of GLT-1 to tubulin are shown in the right. (C) RT-PCR analysis of the expression of GLT-1 and GLAST in R6/2 (HD) and wild-type (WT) mouse brain cortex. Transcripts for GLAST and actin were amplified in the same reaction (21 cycles), and the same amounts of cDNA were used for GLT-1 PCR (23 cycles). The ratios (mean ± SEM, n = 3) of GLT-1 (*, P = 0.0079, WT vs. HD) and GLAST (P = 0.11, WT vs. HD) to actin were obtained with densitometry. Panel C is the control RT-PCR without reverse transcriptase. (D) GLT-1–specific glutamate uptake in brain slices of littermate control (WT) and R6/2 (HD) mice at the age of 4–5 and 10–12 wk was obtained with DHK (1 mM) treatment. Data are presented as mean ± SEM (n = 4 each group). *, P < 0.05; **, P < 0.01 compared with WT control.

An interesting question is whether decreased glutamate transporterscan alter glutamate uptake in astrocytes. The activity of GLT-1in astrocytes can be specifically inhibited by dihydrokainate(DHK; Kawahara et al., 2002). Although GLT-1 is present in someneurons under certain conditions (Mennerick et al., 1998), aprevious study using isolated synaptosomes to examine glutamateuptake into neuronal vesicles did not find a significant differencein DHK-specific glutamate uptake between R6/2 and wild-typemouse brains (Lievens et al., 2001). We decided to use brainslices containing the cortex and striatum to measure their uptakeof [³H]glutamate, as the neuron–glia interactions remainintact but the glutamate uptake into astrocytes can be measuredwith DHK in this assay. Consistent with the age-dependent decreasein the expression of GLT-1 in HD mouse brains, DHK-specificglutamate uptake was more significantly affected in slices fromolder R6/2 mice (Fig. 3 D), demonstrating a close associationbetween GLT-1 expression and glutamate uptake in HD brain.

Expression of mutant htt in cultured astrocytes from HD mouse brains
Cell culture provides a good system to validate the specificeffect of mutant htt on glia. As expected, cultured GFAP-positiveastrocytes from R6/2 mice showed intranuclear htt aggregates(Fig. 4 A). Only a fraction of these nuclear aggregates wereubiquitinated (Fig. 4 B), and the formation of these nuclearhtt aggregates increased with culturing time (Fig. 4 C). Thecells containing htt aggregates were not labeled by antibodiesto markers of microglia and oligodendrocytes (not depicted),suggesting that NH₂-terminal mutant htt forms aggregates morereadily in astrocytic nuclei.

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Figure 4. Age-dependent nuclear accumulation of mutant htt in cultured glial cells. (A) Immunofluorescence double labeling showing that GFAP (green) positive astrocytes display htt aggregates (red) in the nuclei of R6/2 glial cells. (B) Some intranuclear htt aggregates are also labeled by antibody to ubiquitin. (C) Immunofluorescent images of cultured glial cells that were cultured for 2 and 12 wk showing the increase of glial htt aggregates with time. (D) Western blotting of cultured astrocytes that were isolated from the cortex of postnatal Hdh CAG(150) knock-in (KI) and littermate control (WT) mice and had been cultured for 4 wk. The blot was probed with antitubulin (bottom) and 1C2 (top), an antibody that is specific to expanded polyQ tracts and reacts with NH₂-terminal htt fragments containing 150Q. Arrow indicates full-length mutant htt. (E) Immunofluorescent images of glial culture from Hdh CAG KI. GFAP (green) positive astrocytes (arrows) contain intranuclear htt (red) aggregates. Some GFAP-negative cells (arrowhead) also show intranuclear htt, suggesting that they might be immature astrocytes or other types of cells. Bars, 5 µm.

To examine whether glial cells expressing full-length mutanthtt also display nuclear aggregates, we cultured glial cellsfrom the brain of Hdh CAG(150) knock-in mice that do not showobvious neuropathology and symptoms but have an age-dependentaccumulation of NH₂-terminal htt in the nuclei of some neurons(Lin et al., 2001). Western blotting verified that NH₂-terminalhtt fragments were generated in cultured knock-in astrocytes(Fig. 4 D). Some astrocytes contained small aggregates in theirnuclei (Fig. 4 E) after 3–4 wk in culture, but relativeto R6/2 glial cells, the number of astrocytes containing nuclearaggregates was considerably lower. An antibody (EM121) to themiddle region of htt (amino acids 342–456) did not revealnuclear htt aggregates in knock-in astrocytes (unpublished data).This is consistent with the fact that the cleavage of full-lengthmutant htt into small NH₂-terminal mutant htt fragments andthe accumulation of these fragments are required for the formationof nuclear aggregates (DiFiglia et al., 1997; Li et al., 2000).

Expression of htt in glial nuclei of HD knock-in mouse and patient brains
Examination of the striatum of Hdh CAG(150) knock-in mice at14–18 mo of age revealed EM48 labeling in the small anddense nuclei of some GFAP-positive glial cells as compared withintense EM48 labeling in large neuronal nuclei (Fig. 5 A). Thepresence of mutant htt in glial nuclei was confirmed by bothconventional microscopy (Fig. 5 A) and confocal imaging (Fig. 5B) of white matter, which clearly showed that some GFAP-positiveglial nuclei contained small htt aggregates. Younger Hdh CAG(150)knock-in mice (<9 mo) were not found to have obvious EM48staining in glial nuclei (unpublished data). suggesting thatthe nuclear accumulation of mutant htt in glia is age dependent.A previous study reported that mutant htt is present in astrocytesof HD patient brains (Singhrao et al., 1998). We also examinedpostmortem brains from late stage (grade-3) HD patients andconfirmed the expression of mutant htt in HD brains by Westernblotting (Fig. 5 C). Despite severe degeneration in grade-3HD brains, some GFAP-positive glial cells still remained inthese brains. Small EM48-labeled aggregates (<0.3 µm)were seen in white matter and were much smaller than neuronalnuclear aggregates that often exceeded 1.5 µm and wereintensively labeled by EM48 (Fig. 5 D). Immunofluorescent doublelabeling verified that the nuclei of GFAP-positive glial cellscontained EM48 immunoreactive aggregates in HD patient brains(Fig. 5 E), which are similar in size to those in glial cellsin Hdh CAG(150) knock-in mice (Fig. 5, A and B) and did notoccur in the brain of Alzheimer's disease (AD) patient (Fig. 5E). We observed that $~$ 12.3% of GFAP-positive cells containedhtt aggregates. Given that EM48 preferentially reacts with aggregatedhtt and that grade-3 HD brains might have lost some glial cellsor their markers, the number of glial cells expressing mutanthtt, especially soluble htt, is likely to be higher.

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Figure 5. Expression of mutant htt in the brains of Hdh CAG(150) knock-in mice and HD patient. (A) Immunofluorescent double labeling of the striatum of heterozygous Hdh CAG(150) knock-in mice at 14–18 mo old. Arrows indicates the nuclei (blue) of GFAP (green)-positive glial cells containing EM48 labeling (red), and arrowhead indicates a neuronal nucleus, which shows more intense EM48 labeling. (B) High magnification graphs of confocal images of white matter of heterozygous Hdh CAG(150) knock-in mice. Arrows indicate glial nuclei (blue) containing EM48 labeling (red). (C) Western blotting of caudate-putamen tissues from HD and Alzheimer's disease (AD; Control) patients. The blot was probed with antiactin (bottom) and 1C2 antibody (top). (D) Light microscopic graphs of glial cells (arrows in upper panel) in white matter and neurons in the cortex (bottom) in the EM48 stained HD brain sections. (E) Immunofluorescent double labeling of white matter of HD patient brain with rabbit anti-htt (EM48) and mouse anti-GFAP. Mutant htt (red) forms aggregates (arrow) in the nucleus (blue) of an astrocytic cell that shows intense GFAP staining (green) in its processes. The control is the AD brain section. Bars, 2 µm.

Expression of htt in cultured astrocytes by adenoviral infection
To identify the pathological changes that are specifically associatedwith an expanded repeat, we infected glial cells with adenoviralvectors expressing GFP fusion protein containing the first 208amino acids of human htt with 23Q (htt-23Q) or 130Q (htt-130Q).Htt-23Q was predominantly diffuse in the cytoplasm, though itsoverexpression resulted in small puncta or aggregates in thecytoplasm but not in the nucleus. However, expanded polyQ causedhtt-130Q to form significantly larger and more abundant inclusionsin both the cytoplasm and nucleus (Fig. 6 A). Also, nuclearaccumulation and aggregation of htt-130Q were elevated by treatmentwith the proteasome inhibitor N-acetyl-leucinal-leucinal-norleucinal(Fig. 6 B, ALLN). All of these results indicate a specific nuclearaccumulation of htt mediated by a large polyQ tract.

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Figure 6. PolyQ-mediated intranuclear htt accumulation in glial cells. (A) Immunofluorescent images of adenovirus-infected astrocytes that express GFP-htt containing a 23- (23Q) or 130- (130Q) glutamine repeat. Immunostaining with EM48 confirms that htt-130Q is located in the nucleus and forms nuclear aggregates. Nuclei are stained with Hoechst. (B) Proteasomal inhibition by ALLN (10 µg/ml) for 5 d significantly increases the formation of nuclear aggregates of htt-130Q, but not htt-23Q, in infected glial cells. (C) MTT assay of cultured glial cells infected by adenoviral-GFP (+GFP), htt-23Q (+23Q), or htt-130Q (+130Q) for 9 d. (D) MTT assay of astrocytes from R6/2 mice (HD) or littermate controls (WT) cultured for 6 or 8 wk. The data are presented as mean ± SEM (n = 3–4) and p values for 6- and 8-wk group comparisons (WT vs. HD) are 0.23 and 0.014, respectively. Bars, 5 µm.

Adenoviral infection resulted in >80% of cultured glial cellsexpressing mutant htt. Unlike cultured neuronal cells in whichNH₂-terminal mutant htt can cause nuclear or neuritic fragmentation(Saudou et al., 1998; Li et al., 2000), htt-containing glialcells did not show obvious changes in their morphology at differenttimes after viral infection. We then examined the viabilityof cultured glial cells using 3-(4,5-dimethyl thiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) assays. Interestingly, astrocytesinfected with either htt-23Q or htt-130Q and HD astrocytes fromR6/2 mice showed an increase in MTT value (Fig. 6, C and D).Reactive astrocytes often have activated proliferation and increasedmitochondrial respiration, which are reflected by increasedMTT values (Setkowicz and Janeczko, 1998; Norton, 1999). Overexpressedor misfolded polyQ proteins might induce reactive astrocytes,resulting in increased proliferation and mitochondrial respirationthat lead to a high MTT value. Although electron microscopyrevealed degenerated glia in HD mouse brain, this glial pathologymay occur in vivo or result from neuronal injury. We could notfind any evidence that mutant htt directly kills cultured glialcells in vitro, even in the presence of cocultured neurons (unpublisheddata), suggesting that mutant htt is more likely to cause glialdysfunction rather than degeneration.

Decreased expression of glutamate transporters in astrocytes expressing mutant htt
Next, we examined whether mutant htt in astrocytes directlyaffects the expression of glutamate transporters. Western blotsrevealed that the basal level of GLT-1 was lower in culturedastrocytes from R6/2 mouse brains than those from littermatecontrols (Fig. 7 A), whereas the basal level of GFAP did notdiffer. We then treated the astrocytes with dibutyryl cyclicadenosine monophosphate (dBcAMP), which can significantly increasethe expression of GLT-1 by regulating its transcription (Eng et al., 1997).The difference in the expression of GLT-1, butnot GFAP, between control and R6/2 astrocytes was enhanced bydBcAMP treatment (Fig. 7, A and B), suggesting that mutant httnegatively affects gene transcription of GLT-1. The expressionof GLAST in HD glial cells and its up-regulation by dBcAMP werealso reduced as compared with wild-type cells (Fig. 7, A and B),but this reduction was not as great as the change in GLT-1.Because GLAST expression is not significantly decreased in HDbrains (Lievens et al., 2001; Behrens et al., 2002), in vivoneuron–glia interactions may attenuate the inhibitoryeffect of mutant htt on the protein expression of GLAST in thebrain.

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Figure 7. Decreased expression of GLT-1 in glial cells expressing mutant htt. (A and B) Western blots of cultured astrocytes from R6/2 (HD) and littermate control (WT) mice. Astrocytes that had been cultured 4–6 wk and treated with (+) or without (–) 0.25 mM dBcAMP were examined by Western blotting with antibodies to GFAP and GLT-1. The same blots were also probed with an antibody to tubulin. Two blots (a, b) containing different cell samples are presented. (C) Densitometric analysis of signals of immunoreactive bands. The ratios (mean ± SEM, n = 3–4) of GLAST (*, P = 0.045, WT vs. HD), GLT-1 (*, P = 0.013; **, P < 0.001 WT vs. HD), and GFAP to tubulin. (D) Western blot analysis of the expression of htt-23Q and htt-130Q in adenovirus-infected glial cells. Bracket indicates the stacking gel in which aggregated htt-130Q is present. GLT-1 expression is reduced in htt-130Q astrocytes cocultured with cortical or striatal neurons. (E) [³H]Glutamate uptake assays of astrocytes infected with htt-23Q or htt-130Q. Note that the glutamate uptake in htt-130Q–infected cells is lower than in htt-23Q infected cells. The data are presented as mean ± SEM (*, P < 0.05; **, P < 0.01). The Vmax of [³H]glutamate uptake in htt-23Q and htt-130Q infected cells was 11.1 ± 0.84 and 7.3 ± 1.21 nmol/min/mg protein, respectively. There was no significant difference in the apparent glutamate Kms (37.7 ± 3.24 and 38.6 ± 6.3 for htt-23Q and htt-130Q, respectively).

To examine whether the decreased expression of GLT-1 is associatedwith expanded polyQ and also occurred in the presence of neurons,we cultured adenovirus–htt–infected glial cellswith cortical or striatal neurons. Aggregated htt was seen inhtt-130Q–infected glial cells in EM48 Western blots (Fig. 7D). Because EM48 preferentially reacts with mutant and aggregatedhtt (Li et al., 2000), htt-130Q and htt-20Q might be expressedat a similar level. GLT-1, but not tubulin, was significantlyreduced in htt-130Q infected glial cells. Densitometry analysisconfirmed that this decrease was associated with expanded polyQ(unpublished data). Furthermore, htt-130Q infected astrocytesshowed a significant reduction in uptake of [³H] glutamate ascompared with htt-23Q astrocytes (Fig. 7 E). Because the Vmax,but not the Km, of [³H]glutamate uptake was decreased in htt-130Qastrocytes (Fig. 7 E), expanded polyQ appears to reduce thenumber of glutamate transporters in these glial cells. Thisfinding is consistent with the decreased expression of GLT-1and GLAST in cultured R6/2 glial cells.

Protection against htt-mediated neuronal toxicity by glial cells
To determine whether glia can protect against neuronal htt cytotoxicity,we infected cultured neurons with adenoviral GFP, htt-23Q, andhtt-130Q constructs, and then cocultured them with wild-typeastrocytes. In the absence of glial cells, htt-130Q neuronsgenerally showed a decrease in the staining of microtubule-associatedprotein 2 (MAP2) (Fig. 8 A), a neuron-specific protein whosedecrease reflects early neurodegeneration (Matesic and Lin, 1994).When htt-130Q neurons were cocultured with wild-typeglial cells, the number of MAP2-positive neurons was significantlyincreased (Fig. 8 B). The NMDA receptor blocker MK801 (dizocilpinemaleate), which increases the survival of cultured neurons (Driscoll et al., 1991),also increased the number of MAP2-positive neuronsexpressing htt-130Q (Fig. 8 B).

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Figure 8. Htt-mediated neurotoxicity in glia–neuron coculture. (A) Cultured cortical neurons were infected with adenoviral htt-23Q or htt-130Q for 24 h. The infected neurons were then cultured with or without wild-type glial cells or MK801 (10 µM) and labeled by antibodies to htt (top), MAP2 (middle), and Hoechst (bottom). Htt-130Q–infected neurons show decreased MAP2-staining (arrows). (B) The percentage of MAP2-positive neurons and apoptotic neurons with nuclear DNA fragmentation in the presence or absence of wild-type glial cells or MK801. (C) Cultured glial cells (4–6 wk) infected with adenoviral htt-23Q or htt-130Q were cocultured with wild-type cortical neurons. EM48 immunofluorescence staining of glia–neuron coculture shows that htt-23Q is distributed in the cytoplasm whereas htt-130Q accumulates in the nuclei (arrows) of infected glial cells. The size of nuclei of cultured glial cells is often larger than that of cultured cortical neurons. There is a decrease in the number of MAP2-positive neurons in the coculture with htt-130Q–infected glial cells. Nuclei were stained with Hoechst (blue). (D) The percentage of MAP2-positive neurons and apoptotic cells in the presence of adenoviral infected glial cells. Neurons were treated with or without MK801 (10 µM). The data (mean ± SEM) were obtained by counting the number of degenerated cells and the total number of nuclei per image. **, P < 0.01 compared with neurons cocultured with glial cells. Bars, 10 µm.

Glial htt promotes neuronal vulnerability
The preceding experiments examined glial protection for neuronsin which mutant htt was overexpressed. Overexpressed mutanthtt in neurons activates NMDA receptors and triggers many otherpathological pathways, such as caspase cascades (Cepeda et al., 2001;Zeron et al., 2002; Li and Li, 2004), which could counteractglial protection. Thus, a more important issue is whether mutanthtt, when expressed in glia, can reduce their ability to protectneurons. To address this issue, we placed wild-type neuronson glia that had been infected with adenoviral htt. After >3–4wk in culture, astrocytes displayed larger nuclei than neuronalnuclei and lacked MAP2 immunostaining, allowing us to definitivelydistinguish them from neurons in the coculture. We did not observea significant change in neuronal morphology after coculturingwith adenoviral htt-infected astrocytes for 4–5 d. However,after >7–8 d, a significant decrease in the number ofMAP2-positive neurons was seen in the presence of htt-130Q infectedastrocytes (Fig. 8 C). Because cultured neurons normally startto express NMDA receptors at 7–8 d in vitro (DIV), weadded MK801 to block glutamate receptors. MK801 (10 µM)significantly increased the number of MAP2-positive neurons(Fig. 8 D and Fig. S4 [available at http://www.jcb.org/cgi/content/full/jcb.200508072/DC1]),also suggesting that mutant htt in cultured glia can promoteneuronal glutamate excitotoxicity in vitro.

To assess the specific protective effect of astrocytes in theremoval of extracellular glutamate from the medium, we placedastrocytes, which were cultured on coverslips, on the top ofneuronal cells without direct contact during 1 h stimulationwith glutamate or NMDA. The astrocytes were removed after stimulation,and neurons were cultured in the absence of astrocytes for 24h. Stimulation of 15–17 DIV striatal neurons with 0.1mM glutamate in the absence of astrocytes led to a marked reductionin MAP2-positive neurons, whereas the presence of wild-typeastrocytes significantly increased the number of MAP2-positiveneurons (Fig. 9, A, B, and D). This glial protection was diminishedby the glutamate transporter blockers (Fig. S5, available athttp://www.jcb.org/cgi/content/full/jcb.200508072/DC1). NMDA(0.4 mM), whose neuronal toxicity is independent of glutamatetransporters, elicited a similar reduction of MAP2-positiveneurons in the absence or presence of astrocytes (Fig. 9, B and E).Also, cultured neurons were more sensitive to glutamate(0.1 mM) than to NMDA (0.4 mM; Fig. 9 A). Thus, this coculturesystem allowed us to specifically examine the ability of glialcells to remove extracellular glutamate and to protect neuronsfrom glutamate excitotoxicity.

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Figure 9. Reduced glial protection against glutamate excitotoxicity by mutant htt in R6/2 astrocytes. (A) Cultured rat striatal neurons (15–17 DIV) were stimulated for 1 h with glutamate (0.1 mM) or NMDA (0.4 mM) in the absence (–glia) or presence (+glia) of wild-type rat cortical astrocytes. The astrocytes were removed after the stimulation. Glutamate stimulation caused neurons to degenerate and lose MAP2 staining. Wild-type astrocytes increased MAP2-positive neurons following glutamate (0.1 mM), but not NMDA (0.4 mM) stimulation, suggesting a specific protection resulting from their glutamate uptake. (B) Cultured astrocytes from littermate control (+WT glia) mouse cortex also protected against glutamate neuronal toxicity. Cultured astrocytes from R6/2 (+HD glia) mouse cortex, however, showed a decrease in protection against glutamate (0.1 mM), but not NMDA (0.4 mM), toxicity. (C) Cultured R6/2 astrocytes contained GFAP (green) in the cytoplasm and mutant htt (red) in their nuclei but had normal nuclear morphological appearance (blue). (D) The percentage of MAP2-positive striatal or cortical neurons after glutamate stimulation in the absence (No glia) or presence of wile type (+WT glia) or R6/2 (+HD glia) astrocytes. (E) The percentage of MAP2-positive striatal neurons after NMDA stimulation. The control is the number of cells without excitotoxin stimulation. The data (mean ± SEM) were obtained from four to five independent coculture experiments. *, P < 0.05; *, P < 0.01 as compared with WT astrocytes. Bars: (A and B) 20 µm; (C) 5 µm.

We observed that wild-type astrocytes could protect $~$ 78% of corticalneurons from glutamate toxicity, whereas HD astrocytes fromR6/2 mice provided significantly less protection (43%). Similarresults were also seen in cultured striatal neurons, thoughstriatal neurons were more sensitive than cortical neurons toglutamate toxicity (Fig. 9 D). The increased neuronal excitotoxicityby R6/2 astrocytes is apparently related to glutamate transporters,as NMDA did not cause a significant difference in the numberof MAP2-positive neurons between cocultures with wild-type orR6/2 astrocytes (Fig. 9, B and E). Examination of coculturedastrocytes verified that they expressed intranuclear aggregatedhtt but retained a normal nuclear appearance (Fig. 9 C). Theseresults support the idea that mutant htt in glial nuclei affectsthe expression of glutamate transporters, leading to reducedprotection against glutamate neuronal excitotoxicity.

Discussion

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Expression of mutant htt in glial cells
The present findings suggest that mutant htt in glial cellscan contribute to neuronal dysfunction and excitotoxicity inHD brains. Detection of the expression of mutant htt in glialcells seems to depend largely on the antibodies used, as theprevious study with different antibodies did not identify glialhtt aggregates (Davies et al., 1997). Also, the small size andirregular shape of glial cells made it difficult to identifynuclear htt in these cells. EM48 sensitively detects mutanthtt and its aggregates (Li et al., 2000), allowing us to demonstratethe presence of nuclear htt in glial cells in HD mouse brains.We also demonstrated that cultured astrocytes isolated fromR6/2 mouse brains contain nuclear aggregates, consistent witha previous report that cultured glia from a different exon1htt transgenic mouse model express nuclear htt (Martin-Aparicio et al., 2002).Because HD mice (R6/2) expressing small NH₂-terminalhtt fragments show more glial cells (up to 52.6% in white matterat 12 wk) containing nuclear htt aggregates than Hdh CAG knock-inmice, NH₂-terminal mutant htt seems to be able to accumulatein the nuclei of glial cells. HD mice display some early HDneuropathology in the absence of obvious neurodegeneration.Thus, study of the expression of mutant htt in glial cells inHD mice is important for understanding the role of glial httin early HD pathology. We also observed htt aggregates in thenuclei of $~$ 12.3% of GFAP-positive cells in postmortem brainsof patients with late-stage HD. This number might be underestimatedbecause it did not include cells that express soluble mutanthtt and was obtained from the limited number of grade-3 HD patientbrains. Further quantitative investigation of the expressionof mutant htt in glial cells in HD patient brains, especiallythose at early disease stages, remains to be performed.

Mutant htt and glial dysfunction
Whereas nuclear htt aggregates reflect the accumulation of mutanthtt in cells, soluble mutant htt can also affect cellular function.An important question is whether mutant htt affects glial function.Because glutamate excitotoxicity is thought to be an importantmechanism in HD pathology and astrocytes can prevent this excitotoxicity,we focused on the effect of mutant htt on glutamate uptake inastrocytes. Among the five known glutamate transporters (GLT-1,GLAST, EAAC1, EAAT4, and EAAT5), GLT-1 and GLAST are primarilyexpressed in astrocytes and seem to be the predominant glutamatetransporters in the brain (Maragakis and Rothstein, 2001). Althoughprevious studies have revealed that GLT-1 is decreased in HDmouse brains (Lievens et al., 2001; Behrens et al., 2002), itremains unclear how GLT-1 expression is altered and whetherglial htt affects neuronal viability. Using cultured astrocytes,we have provided direct evidence that mutant htt in glial cellsreduces the expression of GLT-1 and GLAST. Also, dBcAMP-mediatedexpression of GLT-1 and, to a lesser extent, GLAST was impairedby mutant htt. This reduction does not appear to be caused byan altered dBcAMP stimulation by mutant htt, as dBcAMP-mediatedup-regulation of GFAP is not impaired. The promoters of theGLT-1 and GLAST genes contain Sp1-binding sites (Su et al., 2003).Considering that mutant htt binds Sp1 (Dunah et al., 2002;Li et al., 2002), it is possible that Sp1-mediated expressionof GLT-1 and GLAST is affected by intranuclear htt. However,in vivo glia–neuron interaction may counteract the inhibitoryeffect of mutant htt on the expression of GLAST and therebyminimize the reduction of GLAST in HD brains.

Although electron microscopy in the present study identifieddegenerating glial cells in HD mouse brains, the number of degeneratingglial cells is not substantive. Also, overexpression of NH₂-terminalmutant htt did not cause obvious death of cultured glial cellsin vitro. Thus, glial dysfunction may be more important forneuronal toxicity than glial degeneration. In fact, the expressionof glutamate transporters and glutamate uptake are reduced inHD mouse brains and cultured astrocytes without degeneration.

Glial htt and neuropathology
Unlike cultured glial cells, cultured neurons are vulnerableto transfected NH₂-terminal mutant htt (Saudou et al., 1998).However, when neurons that express full-length mutant htt arecultured with glial cells, they do not show increased vulnerabilityto glutamate excitotoxicity (Snider et al., 2003). The intracellularaccumulation of NH₂-terminal mutant htt fragments may be requiredfor neuronal htt toxicity, and the neurons may be protectedfrom this toxicity by glial and other cells. Transgenic micethat express exon-1 mutant htt in many types of cells in thebrain show obvious neuropathology and neurological symptoms(Davies et al., 1997; Gu et al., 2005). In contrast, transgenicmice expressing the same mutant htt only in cortical neuronsdo not have obvious neuropathology and phenotypes, leading tothe idea that cell–cell interactions play an importantrole in HD pathology (Gu et al., 2005). The present study showsthat neurodegeneration caused by overexpressed NH₂-terminalmutant htt in vitro is reduced in the presence of glial cells.

A more interesting question is whether mutant htt affects glialfunction to contribute to neuropathology. We found that NH₂-terminalmutant htt in glia promoted the death of cultured neurons thatdid not express mutant htt. Mutant htt may affect various functionsof glial cells, including their production of chemokines andneurotrophic factors. While this possibility remains to be explored,the coculture system allowed us to detect the specific effectof removal of extracellular glutamate by glia on neurotoxicity(Fig. 9).

Glial htt and the selective vulnerability of MSNs
MSNs constitute 70–80% of the total number of human striatalneurons and receive glutamatergic afferents from all areas ofthe neocortex, thalamus, and limbic system (Parent and Hazrati, 1995).The specific composition of NMDA receptor subunits couldalso underlie the hypersensitivity of MSNs to glutamate excitotoxicity(Landwehrmeyer et al., 1995; Kuppenbender et al., 2000; Li et al., 2003).In addition, mutant htt in MSNs is found to increasetheir sensitivity to NMDA in brain slices by modulating theactivity or expression of glutamate receptor subunits (Cepeda et al., 2001;Li et al., 2003). All of these characteristicsmake MSNs highly vulnerable to glutamate stimulation. Thus,although NH₂-terminal mutant htt may affect GLT-1 expressionand glutamate uptake in various brain regions, the impairmentof extracellular glutamate removal in the striatum could particularlyincrease the vulnerability of MSNs to glutamate excitotoxicity.Impaired glial glutamate uptake in R6/2 mice may also significantlyincrease extracellular glutamate concentration in the brain(Lievens et al., 2001; Behrens et al., 2002), which, in turn,would raise the threshold of neuronal response to excitotoxinsso that neurons in R6/2 mouse brain are less responsive to exogenouslyadministered NMDA agonists (Hansson et al., 2001).

Conclusion
Glial dysfunction is known to contribute to other neurodegenerativediseases, and wild-type nonneuronal cells can ameliorate motorneuron degeneration in a mouse model of amyotrophic lateralsclerosis (Clement et al., 2003). In addition to its effecton glial nuclei, mutant htt in neurons can cause multiple dysfunctions(Li and Li, 2004) including transcriptional dysregulation andimpaired transport (Gunawardena et al., 2003). Mutant htt inneurons and glia can independently or synergistically affectneuronal function depending on its subcellular accumulationin these cells during disease progression. This study underscoresthe importance of glial protection against neurodegenerationcaused by misfolded polyQ proteins and also provides a new avenuefor studying the pathogenesis of other polyQ diseases in whichthe disease proteins may also be expressed in glial cells.

Materials and methods

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Materials and methods
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Reagents
R6/2 mice and Hdh CAG(150) knock-in mice, which express a 150Qrepeat, were bred and maintained in the animal facility at EmoryUniversity under specific pathogen-free conditions in accordancewith institutional guidelines. Postmortem brain samples of patientswith HD or AD were provided by the Harvard Brain Tissue ResourceCenter. The brain samples were from three female HD patients.Their ages of death were 57 (B5295), 65 (B5297), and 39 (B5299).The postmortem intervals were 18, 25, and 24 h, respectively.The pathological severity of these cases is grade-3, and expandedCAG repeats are 41–47 units. AD patients were female cases(B4842 and B5092) at 61 and 67 yr of age with postmortem interval6.75 and 27 h, respectively.

Rabbit polyclonal antibody (EM48) and mouse monoclonal antibodies(mEM48) against the NH₂-terminal region (amino acids 1–256)of human huntingtin were described in our previous study (Li et al., 2002).Rabbit antibody against GLT-1 (cGLT T88) wasprovided by J. Rothstein (Johns Hopkins University, Baltimore,MD). Rabbit antibody to GLAST was provided by K. Tanaka (TokyoMedical and Dental University, Tokyo, Japan) and Gi. Bonvento(CEA CNRS, Orsay, France). Other antibodies used included mousemonoclonal antibodies against polyglutamine (1C2) and GFAP (Chemicon),MAP2 (AP20; BD Biosciences), monoclonal ${gamma}$ -tubulin (Sigma Aldrich),GLAST (Chemicon), and anti–mouse or –rabbit antibodiesconjugated with Alexa Fluor 488 (Invitrogen). Antibodies tomyelin basic protein (1:500; Chemicon) and a microglial protein(F4/80 1:100, Serotec/Biozol) were also used.

Immunocytochemistry and Western blotting
Electron microscopy was performed as described previously (Li et al., 2000).For Immunofluorescence light microscopy, brainsof R6/2 and littermate control mice were rapidly isolated andcut to sections (8–10 µm) with a cryostat at –20°C.The brain sections were placed on gelatin-precoated glass slides.Mouse and human brain sections were examined with immunofluorescencelabeling as described previously (Li et al., 2000; Zhou et al., 2003).Light micrographs were taken using a microscope (Axiovert200 MOT; Carl Zeiss MicroImaging, Inc.) and a 63x lens (LD-Achroplan63x/0.75) with a digital camera (Orca-100; Hamamatsu) and theOpenlab software (Improvision Inc). To count glial cells containinghtt aggregates in HD mouse brains, random images (five to eight)of white matter or other brain regions in each brain sectionwere captured using LD plan-neofluar lens (20x/0.4 or 40x/0.6)and stored in a computer for counting. Glial cells (15–60)in each image were counted. To examine HD patient brains, westudied three cases of HD patient brains and counted 1,004 GFAP-positivecells in four independent immunocytochemical experiments. ADpatient brain samples were used as the control. Confocal imageanalysis was performed with a confocal microscope system (LSM510 NLO; Carl Zeiss MicroImaging, Inc.).

For Western blots, cultured cells or brain tissues were solubilizedin 1% SDS, and then resuspended in SDS sample buffer and sonicatedfor 10 s. The total lysate was used for Western blotting withthe ECL kit (Amersham). RT-PCR to examine the transcripts ofGLT-1 and GLAST was performed using the same oligonucleotideprimers and methods as described previously (Tortarolo et al., 2004).Oligonucleotide primers for GLAST cDNA and actin wereincluded in the same reaction for amplification with 21 cycles,whereas GLT-1 cDNA was amplified alone with 23 cycles becauseits PCR products had a molecular weight similar to that of actin.

Adenoviral vector construction and preparation
Recombinant adenoviruses were generated according to a previouslyreported protocol (He et al., 1998). Human htt cDNAs codingthe first 208 amino acid plus an additional 23 or 130 glutaminerepeats were fused in-frame to GFP COOH-terminal cDNA, resultingin GFP-htt fusion proteins containing a 23- (htt-23Q) or 130(htt-130Q)-glutamine repeat that were expressed under the controlof a cytomegalovirus (CMV) promoter. The viral titer was determinedby measuring the number of infected HEK293 cells expressingGFP. All viral stocks were adjusted to 10⁹ VP/ml before theiruse.

Glial and neuronal cultures
Enriched glial cultures were prepared from 1 to 2 d postnatalrat or mouse pups. Microglia cells were dissociated from theculture after shaking cultured glial cells or enriched for culture.Immunostaining with antibodies to specific makers (GFAP forastrocytes, F4/80 for microglia, and myelin basic protein foroligodendrocytes) was used to identify different types of glialcells. Cultured astrocytes were treated with 0.25 mM dBcAMPfor 7–10 d to increase the expression of glutamate transporters(Eng et al., 1997).

For neuronal culture, mixed neuronal–glial cultures wereprepared from the cerebral cortex and striatum of rat fetusesat embryonic day 17–18. Viable cells were plated at 1x 10⁶ cells/ml on poly-D-lysine–coated plastic cultureplates (Corning Costar) in B27-supplemented Neurobasal medium(Invitrogen). To reduce glial proliferation, we added cytosinearabinoside to the cultures 3 d after plating (5 x 10⁶ M finalconcentration). At 7–8 DIV, the majority of cells weremature neurons with elongated processes, and they were usedfor viral infection. In some experiments, neurons were treatedwith cytosine arabinoside for 6–7 d, and then MK801 (10µM) for 30 min. Cultured neurons were then infected withor without adenoviral vectors for 24 h. After washing, infectedneurons were cocultured with wild-type glial cells that wereon coverslips for 3 d.

For glia–neuron coculture, we first infected astrocytes(4–6 wk) from rat brain cortex with adenoviral GFP, htt-23Q,or htt-130Q for 24 h. After washing, we then isolated corticalor striatal neurons and plated them on the top of infected astrocytesand cultured these neurons in B27-supplemented neurobasal medium.To inhibit the proliferation of newly added glial cells, 2.5x 10⁶ M cytosine arabinoside was added 1 d after plating neurons.The newly isolated glial cells were unable to grow because serumfree media and cytosine arabinoside suppressed their growth.Neurons cocultured with infected astrocytes for more than 4d were then examined.

For neuronal–glial coculture treated with glutamate orNMDA, cortical or striatal neurons (DIV 14–17) were coculturedwith glial cells that were attached to coverslips. The glialcells were facing the cultured neurons without direct contact.The coverslips were placed over the cultured neurons duringstimulation with glutamate or NMDA in B27-supplemented neurobasalmedium for 1 h at 37°C. This glial protection was verifiedby using the glutamate transporter blockers DHK and threo-ß-benzyloxyaspartate.After stimulation, the glial cells on the coverslips were removed,and the medium was changed to fresh drug-free medium. The treatedneurons were cultured for 24 h before immunofluorescent examination.

Glutamate uptake assay
Cortico-striatal brain slices (400 µm, three pieces/brain)from R6/2 and littermate controls at the age of 4–5 or10–12 wk (four animals per group) were prepared with vibratome.The slices were placed in ice-cold artificial CSF (aCSF) ([mM]118 NaCl, 4.8 KCl, 2.6 CaCl₂, 1.2 MgSO₄, 25 NaHCO₃, and 1.2KH₂PO₄, 11 glucose, 0.6 ascorbic acid) with aeration of 95%O₂ 5% CO₂. Half of a slice was preincubated with 1 mM dihydrokainate(DHK; Sigma Aldrich) for 1 h at 37°C, and the other halfwas preincubated without DHK treatment. After preincubation,[³H]L-glutamate was added into solution at a final concentrationof 25 nM and incubated for 15 min. The incubation was terminatedby rapidly removing the solution, and the slices were washedwith 4 ml of ice-cold aCSF buffer three times. Slices were lysedin 0.1% NaOH with sonication, and the radioactivity was determinedusing a liquid scintillation counter. Protein amount of brainslices was measured to normalize counting results. The differencesbetween DHK treated and nontreated samples were obtained toreflect GLT-1–specific glutamate uptake (nmol/mg protein/15min).

For glutamate uptake assay of cultured astrocytes, glial cellspreincubated with 10 mM unlabeled glutamate served as a controlto obtain a background value. Vmax and Km were determined fromEadie-Hofstee plots.

Neuronal degeneration and cell viability assays
Degenerated neurons were identified by their disrupted or reducedneurites and condensed or fragmented nuclear DNA using the samemethod as described previously (Saudou et al., 1998). Culturedneurons were fixed and stained with antibody to MAP2 antibodyfor neuronal cells and Hoechst for nuclear DNA. Fluorescentimages were captured and neurons with normal or degeneratingmorphology were counted. To count cells after immunocytochemistry,10–20 pictures of each experimental group were taken witha 20x objective (Carl Zeiss MicroImaging, Inc.). The imagedareas were chosen randomly from at least three different wellsper experimental group. The controls were neurons that had notbeen treated with excitotoxins. The numbers of MAP2-positiveneurons and apoptotic neurons were expressed as the percentageof total neurons counted. Data were obtained from 4–5independent coculture experiments.

The viability of glial cells was determined by a modified MTTassay using a microplate reader (SPECTRAmax Plus; Li et al., 2002).The absorbance at 490 nm was normalized with the amountof cellular protein used for the assay in a 100-µl reaction.

Statistical analysis
Statistical significance was assessed by using Student's t testor two-way ANOVA test followed by Bonferroni post-hoc analysis.Calculations were performed by SigmaPlot 4.11 and Prism (version4) software. Statistical significance was taken to be P <0.05.

Online supplemental material
Fig. S1 shows electron micrographs of R6/2 mouse brain containingdegenerated neurons and glial cells. Fig. S2 shows an age-dependentincrease of glial cells containing intracellular mutant httin R6/2 mice. Fig. S3 shows Western blot analysis of glutamatetransporters in R6/2 and HD knock-in mouse brains. Fig. S4 showsthat MK801 reduced neurotoxicity in the presence of glial cellsexpressing mutant htt. Fig. S5 shows that glial protection wasinhibited by glutamate transporter blockers. Video 1 shows three-dimensionalimages of a GFAP-positive astrocyte containing htt aggregatesin its nucleus. Online supplemental material is available atavailable at http://www.jcb.org/cgi/content/full/jcb.200508072/DC1.

Acknowledgments

We are grateful to H. Rizvi and A. Orr for their technical assistanceand the members of the Li laboratory for their comments. Wethank J. Rothstein for providing antibody to GLT-1, K. Tanakaand G. Bonvento for antibody to GLAST, R. Wen for adenoviralvectors, W. Chen and S. Warren for advice, and M. Friedman forcritical reading of the manuscript. We also thank Harvard BrainTissue Resource Center for providing HD patient and controlbrain tissues.

This work was supported by grants (AG19206 and NS36232) fromthe National Institutes of Health.

Submitted: 9 August 2005

Accepted: 17 November 2005

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