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The Journal of Neuroscience, March 15, 2003, 23(6):2193
Mutant Huntingtin Causes Context-Dependent Neurodegeneration in
Mice with Huntington's Disease
Zhao-Xue
Yu,
Shi-Hua
Li,
Joy
Evans,
Ajay
Pillarisetti,
He
Li, and
Xiao-Jiang
Li
Department of Human Genetics, Emory University School of Medicine,
Atlanta, Georgia 30322
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ABSTRACT |
Huntington's disease (HD) mouse models that express N-terminal
huntingtin fragments show rapid disease progression and have been used
for developing therapeutics. However, light microscopy reveals no
significant neurodegeneration in these mice. It remains unclear how
mutant huntingtin induces neurodegeneration. Using caspase staining,
terminal deoxynucleotidyl transferase-mediated biotinylated UTP nick
end labeling, and electron microscopy, we observed that N171-82Q
mice, which express the first 171 aa of mutant huntingtin, displayed
more degenerated neurons than did other HD mouse models. The
neurodegeneration was also evidenced by increased immunostaining for
glial fibrillary acidic protein and ultrastructural features of
apoptosis. R6/2 mice, which express exon 1 of mutant huntingtin, showed
dark, nonapoptotic neurons and degenerated mitochondria associated with
mutant huntingtin. In HD repeat knock-in mice (HdhCAG150), which
express full-length mutant huntingtin, degenerated cytoplasmic
organelles were found in both axons and neuronal cell bodies in
association with mutant huntingtin that was not labeled by an antibody
to huntingtin amino acids 342-456. Transfection of cultured cells with
mutant huntingtin revealed that an N-terminal huntingtin fragment
(amino acids 1-208 plus a 120 glutamine repeat) caused a greater
increase in caspase activity than did exon 1 huntingtin and longer
huntingtin fragments. These results suggest that context-dependent
neurodegeneration in HD may be mediated by different N-terminal
huntingtin fragments. In addition, this study has identified
neurodegenerative markers for the evaluation of therapeutic treatments
in HD mouse models.
Key words:
Huntington; polyglutamine; neurodegeneration; apoptosis; ultrastructure; transgenic
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Introduction |
Huntington's disease (HD) is
characterized by progressive neurodegeneration that occurs primarily in
the striatum and extends to other brain regions as the disease
progresses (Vonsattel et al., 1985 ). These other regions include the
cerebral cortex, hypothalamus, and brainstem (Cudkowicz and Kowall,
1990; Kremer et al., 1990; Sotrel et al., 1993; Jackson et al., 1995).
As a result, patients with HD show progressive movement disorder,
memory loss, and psychiatric abnormalities until death (Harper,
1991). However, the lack of well preserved postmortem human
brain tissue has been an obstacle to detailed characterization of
neurodegeneration at the ultrastructural level and during the early
stages of HD.
Studies of several HD mouse models have confirmed that
polyglutamine (Q) expansion in huntingtin causes neurological
phenotypes. HD transgenic mice expressing smaller N-terminal mutant
huntingtin (Davies et al., 1997; Schilling et al., 1999) develop more
progressive phenotypes than those expressing longer N-terminal
huntingtin (Laforet et al., 2001) or full-length mutant huntingtin
(Reddy et al., 1998; Hodgson et al., 1999). Of these HD transgenic
mice, R6/2 and N171-82Q mice have been extensively studied and used for
drug screens because of their rapid disease progression (Andreassen et
al., 2001; Ferrante et al., 2002, Hockly et al., 2002; Keene et al.,
2002). R6/2 mice express the HD exon 1 protein containing 115-150Q, and
N171-82Q mice express the first 171 aa with 82Q. Although these HD mice
display severe phenotypes and early death, usually at 3-6 months after
birth, no prominent neurodegeneration has been found in their brains.
In contrast, HD transgenic mice expressing full-length mutant
huntingtin with a shorter repeat than 150Q or at a lower expression
level than that of endogenous huntingtin develop neurodegeneration
despite their slow disease progression (Reddy et al., 1998; Hodgson et
al., 1999). Because N-terminal mutant huntingtin fragments are more
toxic than full-length mutant huntingtin (Hackam et al., 1998) and may
accumulate in different subcellular sites to mediate cellular toxicity
(Lunkes et al., 2002), it would be necessary to examine different HD
mice using more sensitive assays. Examination at the ultrastructural level should reveal whether neurodegeneration in vivo is
caused by full-length huntingtin or its N-terminal fragments.
Identification of specific neuropathological changes in various HD
mouse models will also help in evaluating the therapeutic effects of
drugs on these models.
In this study, we examined the neuropathology in various HD mouse
models including N171-82Q mice and HdhCAG150 mice, which express 150Q
in the endogenous mouse huntingtin (Lin et al., 2001). With the
antibody EM48, which sensitively detects mutant huntingtin in the
brain, we performed electron microscopy and found that N171-82Q mice
had significantly more apoptotic neurons than other HD mouse models
examined. The results suggest that N-terminal huntingtin sequences may
specify different types of neuronal degeneration in HD and also provide
neurodegenerative markers for evaluating therapeutic effects on HD
mouse models.
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Materials and Methods |
HD mice. R6/1 and R6/2 mice [B6CBA-TgN (HDexon1)61
and 62], which express exon 1 of the human mutant HD gene
containing 115-150 CAGs (Mangiarini et al., 1996), were
obtained from The Jackson Laboratory (Bar Harbor, ME).
N171-82Q mice [B6C3F1/ TgN(HD82Gln)81Dbo], which express the
first 171 aa with 82 glutamines (Schilling et al., 1999), were also
obtained from The Jackson Laboratory. HD repeat knock-in
mice (HdhCAG150), which have a repeat length of 150 CAGs in the
endogenous mouse HD gene, were generated as described previously (Lin
et al., 2001). Breeding pairs of HdhCAG150 mice were provided by Dr.
Peter Detloff (University of Alabama, Birmingham, AL). All mice were
bred and maintained in the animal facility at Emory University. The
genotyping of transgenic mice was performed using methods described
previously (Mangiarini et al., 1996; Schilling et al., 1999; Lin et
al., 2001).
Antibodies. EM48, a rabbit polyclonal antibody against the
N-terminal region (amino acids 1-256) of human huntingtin, was generated during our previous studies (Gutekunst et al., 1999). EM121
was generated using glutathione-S-transferase fusion
proteins containing amino acids 342-456 of human huntingtin. Purified
fusion proteins were used as antigens for Covance Inc.
(Denver, PA) to generate rabbit antisera. Other antibodies used
included a mouse monoclonal antibody against glial fibrillary acidic
protein (GFAP; Chemicon, Temecula, CA) and a rabbit
polyclonal antibody against the activated form of caspase-3 (Cell
Signaling Technology, Beverly, MA).
Light microscopy and terminal deoxynucleotidyl
transferase-mediated biotinylated UTP nick end labeling. Mice were
anesthetized and then perfused intracardially with PBS, pH 7.2, for 30 sec, followed by 4% paraformaldehyde in 0.1 M phosphate buffer (PB, pH 7.2). The brains were
removed, cryoprotected in 30% sucrose at 4°C, and sectioned at 40 µm using a freezing microtome. Free-floating sections were preblocked
in 4% normal goat serum (NGS) in PBS, 0.1% Triton X-100, and
avidin (10 µg/ml) and then incubated with huntingtin antibody at room
temperature for 24 hr. For light microscopy, the immunoreactive product
was visualized with the avidin-biotin complex kit (ABC Elite;
Vector Laboratories, Burlingame, CA). Controls included
brain sections from age-matched wild-type mice.
Terminal deoxynucleotidyl transferase-mediated biotinylated UTP nick
end labeling (TUNEL) was performed on brain sections using an in
situ cell death detection kit from Roche Molecular Biochemicals (Indianapolis, IN) according to the manufacturer's instructions. After perfusion with 4% paraformaldehyde, the mouse brain was cut into sections using a microtome. The tissue sections were
fixed with 4% paraformaldehyde in PBS and then treated with 0.3%
Triton X-100 in PBS for 30 min. After washes with PBS, the sections
were incubated with fluorescein-12-dUTP and terminal transferase in the
buffer provided with the kit. Counterstaining with Nissl (cresyl
violet) was also performed to reveal the total number of neurons examined.
Quantification of GFAP- and TUNEL-positive cells. Light
microscopic graphs were taken using a Zeiss (Oberkochen,
Germany) Axioskop 2 microscope connected to a Spot-RT digital camera
(Diagnostic Instruments, Sterling Heights, MI). All of the images were
captured using the same parameters and saved in a computer for
analysis. Each group of HD mouse models consisted of three to four
mice. Every sixth brain section (240 µm distance) of these mice was selected through the striatum or cortex, providing six to eight sections for examining each mouse brain. We adopted a grid stereologic method as reported previously (Manoonkitiwongsa et al., 2001) to
measure GFAP staining of glial cell bodies and processes. Briefly, all
micrographs were taken at a magnification of 630×, providing high-resolution images (53.62 × 38.1 cm or 1520 × 1080 pixels). Using Adobe Photoshop 5.0 software (Adobe
Systems, San Jose, CA), the images were adjusted at a threshold
level of 128 so that GFAP signals could be unambiguously identified.
The adjusted images were analyzed in a 5040 point grid in which points
on the GFAP-labeled areas were counted. The percentage of these points
of the 5040 point grid in each micrograph was used to represent the
relative density of GFAP labeling in glial cells and also used for comparison.
To count TUNEL-positive neurons and cells labeled by anti-caspase-3,
each micrograph (53.62 × 38.1 cm) at a magnification of 200× was
examined. The percentage of TUNEL-positive neurons of cresyl
violet-labeled cells was used for comparison. For each brain, six to
eight randomly selected sections were counted, and the mean ± SD
was obtained from three mice for each group.
Electron microscopic immunocytochemistry. For
electron microscopy, mice were fixed by perfusion with PBS containing
4% paraformaldehyde and 0.2% glutaraldehyde. After perfusion, the
brain was removed, postfixed with 4% paraformaldehyde in PB for 6-8
hr, and then sectioned using a vibratome. For immunogold labeling,
brain sections were incubated with EM48 in PBS containing 4% NGS for
24-48 hr at 4°C. After washes with PBS, Fab fragments of goat
anti-rabbit secondary antibodies (1:50) conjugated to 1.4 nm gold
particles (Nanoprobes Inc., Stony Brook, NY) in PBS with 4% NGS were
added to the section and incubated overnight at 4°C. After rinsing in PBS, sections were fixed again in 2% glutaraldehyde in PB for 1 hr,
silver-intensified using the IntenSEM kit (Amersham
Biosciences, Buckinghamshire, UK), and osmicated in 1%
OsO4 in PB.
All sections used for electron microscopy were dehydrated in ascending
concentrations of ethanol and propylene oxide/Eponate 12 (1:1) and
embedded in Eponate 12 (Ted Pella Inc., Redding, CA).
Ultrathin sections (60 nm) were cut using a Leica Ultracut S ultramicrotome. Thin sections were counterstained with 5% aqueous uranyl acetate for 5 min followed by Reynolds lead citrate for 5 min
and examined using a Hitachi (Tokyo, Japan) H-7500
electron microscope.
Huntingtin transfection and Western blotting. PRK
expression vectors encoding the HD exon 1 protein containing 150Q
(HD-exon 1), the first 208 aa of human huntingtin containing 23 (23Q-208) or 120 (120Q-208) glutamine repeats, or truncated huntingtin
[amino acids 1-508 (120Q-508) and 1-945 (120Q-945)] with a 120 glutamine repeat were obtained from our previous study and transfected
into human embryonic kidney (HEK) 293 cells (Gutekunst et al., 1999; H. Li et al., 2000). Transfected cells were resuspended in PBS with a
protease inhibitor mixture (1×, P8340; Sigma, St. Louis, MO), PMSF (100 µg/ml), and 1% Triton X-100. The cells were
homogenized for 10 sec and centrifuged at 800 × g for
5 min at 4°C. The supernatant was used for Western blotting with an
ECL kit (Amersham Biosciences). Approximately 50 µg of
protein was loaded on each lane of the SDS gel.
Caspase activity and cell viability assays. Fluorometric
assays of caspase-3 and caspase-9 activity were performed using kits obtained from Bio-Rad (Hercules, CA), as reported
previously (Zhou et al., 2001). Cultured HEK293 cells were transiently
transfected with mutant huntingtin or the PRK vector for 48 hr in six
well plates. After washing with PBS, the cells were lysed in lysis buffer containing (in mM): 10 Tris-HCl, 10 NaH2PO4/NaHPO4,
pH 7.5, 130 NaCl, and 10 sodium pyrophosphate, as well as 1% Triton X-100. To measure caspase activity, 200 µl of 2× assay buffer containing (in mM): 40 PIPES, pH 7.2, 200 NaCl,
20 dithiothreitol, and 2 EDTA, as well as 0.2% w/v CHAPS and 20%
sucrose were added to a tube, with a final concentration of 10 ng/µl
of the peptide substrate (Ac-DEVD-AFC for caspase-3 and
LEHD-7-amino-4-trifluoromethyl cumarin for caspase-9). Cell
lysates (40 µg of protein) were added to the tube to start the
reaction. When the caspase inhibitor (DEVD or LEHD-fmk) was used
to measure the specificity of the assay, it was added to cell lysates
at a concentration of 10 or 20 µM for 30 min
before adding the specific caspase substrate. The background was
obtained with the same assay buffer without cell lysate or substrate.
The reaction was incubated at 37°C for 1 hr, followed by measuring
the cleaved caspase products with a fluorescence plate reader (Fluostar
Galaxy; BMG Labtechnologies, Durham, NC) set at 460 nm
excitation and 520 nm emission.
HEK293 cells were plated in six well dishes and transfected with 1 µg
per well of huntingtin constructs as described above. HEK293 cells
transfected with the PRK vector alone served as a control. After
transfection for 72 hr using Lipofectamine, the viability of the
transfected cells was then determined by a modified 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl tetrazolium bromide (MTS)
assay using a microplate reader (SPECTRAmax Plus; Molecular Devices,
Sunnyvale, CA) (S. H. Li et al., 2000).
Statistical analysis. Statistical significance was assessed
by using Student's t test and Sigma Plot 4.11 software,
with p < 0.05 indicating statistical significance.
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Results |
GFAP staining of HD mouse brain
Immunocytochemical staining of GFAP has been used to identify
reactive gliosis, an early marker of CNS damage in HD (Hedreen and Folstein, 1995). We compared GFAP staining among different HD mouse
models, with a focus on the striatum because this region is a primary
site of injury in HD. The densities of GFAP labeling in glial cell
bodies and processes in these HD mice were measured. Compared with
age-matched wild-type mouse striatum, N171-82Q mouse striatum showed a
remarkable increase in GFAP immunoreactivity, indicated by intense
labeling throughout astroglial cell bodies and their fibrous processes.
The increased GFAP staining was found in the brains of N171-82Q mice at
3 months of age and became prominent at 4-5 months of age (Fig.
2A). The striatum of R6/2 mice at 12 weeks of age
displayed some glial cells with increased GFAP staining. However, the
overall number of GFAP-labeled glial cells was not increased in R6/2
mice compared with that of their littermates or other HD mice. We also
examined R6/1 mice, which express the same exon 1 huntingtin but live
longer than R6/2 mice. Even at 9 months of age, there was still little
GFAP staining in the striatum in R6/1 mice (data not shown). HdhCAG150
mice at 5-6 months of age did not show intense GFAP immunoreactivity.
A significant increase in GFAP immunoreactivity was observed in the
striatum of HdhCAG150 mice at 14 months of age, as reported previously (Lin et al., 2001). However, this increase was not as great as that in
N171-82Q mice. Of the HD mice examined, N171-82Q mice showed the
strongest induction of GFAP in the striatum (Fig. 1B). The
increased GFAP staining was also observed in other brain regions in
N171-82Q mice, including the cortex, hippocampus, and hypothalamus (data not shown), suggesting that N171-82Q mice have the most severe gliosis.
Expression of mutant huntingtin in HD mouse brain
To examine whether the increased GFAP immunoreactivity observed is
indeed associated with different types of mutant huntingtin rather than
the different expression levels of these transgenic proteins, we
immunostained HD mouse brains with EM48, an antibody that was generated
with the first 256 aa of human huntingtin (Gutekunst et al., 1999). It
is apparent that R6/2 and R6/1 mouse brains showed more intense EM48
immunoreactivity than the brains of N171-82Q mice and HdhCAG150 mice,
because more nuclear EM48 labeling and a greater density of nuclear and
neuropil aggregates were seen in R6/2 and R6/1 brains. Hdh150CAG mice
at 14 months of age showed the weakest nuclear staining and the fewest
nuclear or neuropil inclusions in the brain (Fig.
2A). Despite the lower
EM48 immunoreactivity in their brains, both N171-82Q and HdhCAG150 mice
had a greater number of GFAP-positive cells than R6/2 and R6/1 mice
(Fig. 1), suggesting that the increased
GFAP staining is more related to the nature, not the quantity, of
expressed mutant huntingtin.
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Figure 1.
GFAP staining of HD mouse striatum.
A, Brain striatal sections from N171-82Q (4 months old),
age-matched control [wild type (WT), 4 months
old], R6/2 (3 months old), and HdhCAG150 knock-in (14 months old) mice
were immunostained with an antibody against GFAP. Increased GFAP
immunoreactivity of astroglial cell bodies and their fibrous processes
is present in N171-82Q and HdhCAG150 mouse striatum. Scale bar, 84.6 µm. B, Density of GFAP staining in the striatum of
different HD mouse models. The density was determined by counting grid
points containing GFAP immunoreactive signal in micrographs at 630×
magnification. Data are presented as the percentage (means ± SD)
of a 5040 point grid in each micrograph and were obtained from three to
four mice for each group. WT, Wild-type littermates (4 months old) of the same strain as N171-82Q mice. *p < 0.05 and **p < 0.01 compared with WT.
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Figure 2.
Immunostaining of HD mouse striatum.
A, The striatum of N171-82Q (4 months old), HdhCAG150
knock-in (14 months old), R6/1 (8 months old), and R6/2 (3 months old)
mice were stained with EM48, which specifically reacts with mutant
huntingtin and its aggregates. Note that both nuclear inclusions and
neuropil aggregates are present in all of the HD mouse brains examined,
although they are more abundant in R6/2 and R6/1 mice.
B, The striatum of HdhCAG150 was also labeled by the
antibody EM121, which reacts with huntingtin amino acids 359-429. Only
diffuse cytoplasmic staining was seen in HD mice, with a pattern
similar to that of the wild-type (WT) mice. Scale
bar, 10.8 µm.
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Because only small N-terminal huntingtin fragments are able to form
huntingtin inclusions in the nucleus and neuropil (DiFiglia et al.,
1997; Gutekunst et al., 1999; H. Li et al., 2000), we wanted to examine
whether aggregates seen in HdhCAG150 mice were formed by small
N-terminal huntingtin fragments. To do so, we developed a rabbit
antibody (EM121) against huntingtin amino acids 342-456. This antibody
reacted with diffuse huntingtin in the cytoplasm of neurons. No
aggregates or inclusions were observed with EM121 in HdhCAG150 mice,
suggesting that huntingtin aggregates may be formed of N-terminal
mutant huntingtin smaller than the first 342 aa (Fig.
2B).
Apoptotic neurons in N171-82Q mouse brain
Previous studies using hematoxylin and eosin and silver stains or
counting cell numbers did not reveal obvious neuronal loss in N171-82Q
or HdhCAG150 mice (Schilling et al., 1999; Lin et al., 2001). We
decided to examine HD mice with a more sensitive assay that detects
activated caspase-3, an executive molecule whose cleavage and
activation are involved in various apoptotic pathways. We could not
find any significant labeling of R6/2 mouse brains by the antibody
against activated caspase-3. However, we observed a number of intensely
labeled neurons in the striatum and cortex of N171-82Q mouse brains at
4.5 months of age, but not in the brains of wild-type mice even at 14 months of age (Fig. 3A-C).
Similar positive neurons were also seen in the hypothalamus and
preoptic area, consistent with the widespread expression of transgenic
mutant huntingtin in the brains of N171-82Q mice (data not shown).
However, very few neurons showed immunoreactivity for activated
caspase-3 in HdhCAG150 mice at 4 to 14 months of age (data not shown).
The increased immunostaining of neurons for activated caspase-3
appeared to be specific to N171-82Q mice.
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Figure 3.
Caspase-3-activated neurons in N171-82Q mouse
brain. The cortex of a wild-type control mouse at 14 months of age
(A) and the striatum (B)
and cortex (C) of N171-82Q mice at 4.5 months of age were stained with an antibody against the activated form
of caspase-3. Positively stained neurons (arrows) are
present in the N171-82Q mouse brain regions. Inset,
High-magnification micrograph of a neuron containing activated
caspase-3. Scale bars, 32 µm.
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We also performed TUNEL to examine the relative percentage of apoptotic
neurons in different HD mouse brains. The result showed that N171-82Q
mice had the greatest number of TUNEL-positive neurons compared with
wild-type littermates, HdhCAG150, and R6/2 mice (Fig.
4). TUNEL-labeled product was found in
the nucleus, reflecting a nuclear DNA strand break or an apoptotic
event (Fig. 4A). Furthermore, more TUNEL-positive
neurons in N171-82Q mice appeared as the animals became older (Fig.
4B). This result is consistent with the progression of HD phenotypes in N171-82Q mice. The cortex appeared to have more
TUNEL-positive neurons than the striatum, perhaps because of the higher
expression level of the transgene in the cortex (Schilling et al.,
1999).
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Figure 4.
TUNEL-positive neurons in N171-82Q mouse brain.
A, TUNEL of the cortex of N171-82Q (5 months old),
age-matched control (5 months old), R6/2 (12 weeks old), and Hdh150CAG
(14 months old) mice. The brain sections were also counterstained with
cresyl violet (blue). Arrows indicate
TUNEL-positive neurons. The inset shows a
high-magnification (630×) image in which a neuronal nucleus contains
TUNEL-positive product. B, Quantitative measurement of
the percentage of TUNEL-positive neurons in the cortex and striatum of
HD mouse brains. The total number of neurons was assessed by cresyl
violet staining in each micrograph (200×). N171-82Q mice at the age of
1.5, 3, and 5 months were examined. The ages of other HD mice are the
same as those in A. KI, HdhCAG150 mice;
WT, wild-type mice. *p < 0.05 and
**p < 0.01 compared with wild-type control mice
(n = 3-4).
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We then performed electron microscopy to provide ultrastructural
evidence for degenerating neurons in N171-82Q mice. Electron microscopy
of the cortex frequently revealed degenerated neurons with
a number of apoptotic features. These neurons showed an abnormal nuclear shape with obvious chromatin margination and condensation, which are features of apoptosis (Fig.
5A). The cytoplasm was mildly condensed, but most cytoplasmic organellar structures remained intact
(Fig. 5B). At a more advanced stage of apoptosis, more condensed chromatin or fragmented chromatin was seen in the nucleus (Fig. 5C). Degenerated and dark cytoplasmic
bodies were also seen in some neurons, and these bodies were associated
with the appearance of chromatin condensation (Fig. 5D).
These dark cytoplasmic bodies may be degenerated lysosomal structures.
We also performed EM48 immunogold labeling. Mutant huntingtin and its
inclusions were not found frequently in neurons that appeared to have
reached a late stage of apoptosis. However, in the neurons that began to show nuclear chromatin margination and condensation or were undergoing early apoptosis, mutant huntingtin and its inclusions could
be observed in their nuclei (Fig. 5E). Similar
ultrastructural signs of apoptosis were also evident in the striatum
and hypothalamus of the mutant mice, but not in the brains of
age-matched control mice (data not shown), suggesting that apoptotic
neurons are widely distributed in the brains of N171-82Q mice.
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Figure 5.
Electron microscopy showing degenerated neurons in
the cortex of N171-82Q mouse brain. A, B, An apoptotic
neuron with condensed cytoplasm and abnormal nuclear shape showing
margination and condensation of chromatin. Note that most cytoplasmic
organelles remain intact. The rectangular area in
A is shown in B at higher magnification,
indicating that the mitochondria (arrowhead) appear
normal, whereas the nuclear membrane has chromatin margination
(arrow). C, The nucleus of an advanced
stage of apoptosis showing chromatin condensation and fragmentation.
D, A degenerating neuron with condensed nuclear
chromatin (arrow) and an increased number of dark
cytoplasmic bodies resembling lysosomes (arrowheads).
E, EM48 immunogold labeling showing that a neuron
contains mutant huntingtin and its inclusion (arrow) in
the nucleus. Note that this neuron is undergoing early apoptosis,
characterized by the disintegration of the nuclear membrane and mild
chromatin margination (arrowheads). Scale bars:
A, 1.54 µm; C, 1.77 µm;
D, 0.92 µm: E, 1.45 µm.
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Dark neurons and degenerated mitochondria in R6/2 mice
We could not identify typical apoptotic neurons in R6/2 mice
despite our extensive electron microscopic examination. However, quite
a few dark neurons were found in the brains of these mice, as reported
previously (Turmaine et al., 2000). The degeneration profile of these
neurons was apparently different from that in N171-82Q mice. Dying
neurons in R6/2 mice exhibited a condensed cytoplasm and nucleus (Fig.
6A). However, these
darkened structures never showed membrane blebbing, chromatin
margination and fragmentation, apoptotic bodies, or other apoptotic
features. Dark neurons with similar ultrastructural appearance were
also found in the striatum of R6/1 mice (Fig.
6B).
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Figure 6.
Dark neurons and degenerated mitochondria in R6/2
mice. A, B, Dark degenerating neurons, which do not have
typical chromatin margination and nuclear fragmentation, are present in
an R6/2 mouse at 3 months of age (A) and in an
R6/1 mouse at 8 months of age (B). A glial cell
(gn) is also indicated. C, D,
Degenerated mitochondria were observed in association with EM48
immunogold particles in the brain cortex at 8-10 weeks of age. Note
that the cytoplasmic swelling, vacuolization, enlargement, and
condensation of mitochondria (arrows) are associated
with huntingtin immunogold particles. Degenerated mitochondria are also
enclosed in a lysosome-like structure (D). Scale
bars: A, 4 µm; B, 1.6 µm, C,
D, 0.3 µm.
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In addition, degenerated mitochondria were observed in neurons that
showed normal nuclear and cytoplasmic appearance in the brains of R6/2
mice. Mitochondrial degeneration was evident by their swollen
appearance, disintegration of double membrane and internal
cristas, and darkened internal structures (Fig.
6C,D). Although similar degenerated mitochondria were also
found in N171-82Q and HdhCAG150 mice, degenerated mitochondria in R6/2
mouse brains were more frequently associated with EM48 immunogold
particles. These immunogold particles were either clustered within the
degenerating mitochondria or associated with the surface of the
mitochondrial membrane. A recent study shows that mutant huntingtin is
associated with the surface of mitochondrial membrane in HD mouse brain
(Panov et al., 2002). We observed that mutant huntingtin could also be trapped inside degenerated mitochondria, supporting the role of mutant
huntingtin in mitochondrial dysfunction (Beal, 2000; Panov et al.,
2002). Degenerating mitochondria were also often surrounded by
lysosomal structures (Fig. 6D), suggesting an
advanced stage of degeneration. Such degenerated mitochondria were
found more frequently in R6/2 mice that were >8 weeks of age. The
identification of degenerated mitochondria provides a pathological
basis for the protective effects of drugs against mitochondrial
toxicity in HD mice (Ferrante et al., 2002).
Degenerated neurons and axons in Hdh150CAG mice
In HdhCAG150 mice, very few degenerated neurons with typical
apoptotic features were seen under electron microscopy. However, neurons containing degenerated structures in the cytoplasm were frequently identified. These cytoplasmic structures, which often surrounded vacuoles, might be derived from lysosomes. However, their
presence was not associated with obvious nuclear condensation or
blebbing of the cytoplasm. Neurons containing the degenerated cytoplasmic organelles showed huntingtin inclusions in their nucleus (Fig. 7A). High-magnification
micrographs showed that clusters of electron-dense bodies surrounded a
large number of small vacuoles. Some of these dark bodies had a double
membrane and visible internal cristas (Fig. 7B,
arrows), indicating a mitochondrial origin. Other, darker
structures might represent secondary lysosomes or autolysosomes (Fig.
7B). Despite their unknown nature, these degenerated structures were observed only in the HD brain and not in the wild-type control mice.
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Figure 7.
Degenerated neurons and axons in Hdh150CAG
knock-in mice. A, B, Cytoplasmic organellar degeneration
in HdhCAG150 mouse striatum. A, Several dark cytoplasmic
organelles surround vacuoles (arrowheads). The nucleus
that contains an intranuclear inclusion (arrow) appears
intact, without nuclear fragmentation or condensation.
B, A high-magnification micrograph shows clusters of
electron-dense bodies and dark lysosomal structures that surround many
cytoplasmic vacuoles. Some of these dense bodies show a mitochondrial
origin with internal cristas (arrows). Others may
represent secondary lysosomal bodies (arrowheads).
C-E, Various types of degenerating axons are present in
the striatum of HdhCAG150 mice. Axons are surrounded by disrupted
myelin in which huntingtin aggregates (arrow) are
trapped (C). Degenerated axons contain
dark and swollen organelles (D, E), probably derived
from mitochondria (arrowheads in D).
Scale bars: A, 1 µm; B, 0.63 µm;
C, 0.42 µm; D, 0.41 µm;
E, 0.71 µm.
|
|
Similar cytoplasmic degenerative structures were also found in the
brains of R6/2 mice. Some old HdhCAG150 mice (>14 months of age)
showed very few dark degenerating neurons with a profile similar to
that in R6/2 mice (data not shown). Thus, HdhCAG150 mice shared some
pathological changes that were found in N-terminal huntingtin
transgenic mice. The more specific pathological change in HdhCAG150
mice might be of axonal degeneration. Our previous studies revealed
axonal degeneration in 17- to 22-month-old HD knock-in mice that
express 80 CAG repeats (H. Li et al., 2000). We observed similar
degenerating axons in HdhCAG150 mice at an earlier age (14 months).
These degenerated axons were often surrounded by a disrupted myelin
structure. Although cross sections of axons might not always reveal
mutant huntingtin within axons, we did find some cases in which mutant
huntingtin was associated with degenerated axons (Fig.
7C-E). Mutant huntingtin was trapped or formed aggregates
in the degenerating myelin. Organelles within the degenerated axons
appeared dark and swollen, with no clear membrane-bound structures.
However, their size and shape suggested that they might be derived from
mitochondria. EM121 immunogold labeling was unable to reveal any mutant
huntingtin specifically associated with degenerated myelin and axons in
HdhCAG150 mouse brains (data not shown). Electron microscopic
examination of R6/2 and N171-82Q mouse brains did not reveal such
obvious axonal degeneration. Thus, degenerated axons appear to be
associated with N-terminal mutant huntingtin smaller than the first 342 aa and might occur only in aged HD mice.
N-terminal mutant huntingtin activates caspases differently in
transfected cells
The prominent apoptotic neurons in N171-82Q mice suggest that
different N-terminal huntingtin fragments may activate caspases to
different extents. To test this hypothesis, we examined caspase activities in huntingtin-transfected cells that expressed various N-terminal mutant huntingtin fragments containing 120-150Q [amino acids 1-67 (150Q-exon 1), 1-208 (120Q-208), 1-508 (120Q-508), and
1-945 (120Q-945)]. Western blots showed that these transfected huntingtin proteins were expressed at similar levels (Fig.
8A). Only small
N-terminal mutant huntingtin fragments (150Q-exon 1 and 120Q-208)
formed aggregates that remained in the stacking gel. Consistent with
other studies (Hackam et al., 1998; S. H. Li et al., 2000),
transient transfection of small N-terminal huntingtin into non-neuronal
cells resulted in cytoplasmic localization of the majority of mutant
huntingtin and its aggregates (Fig. 8B), allowing for
comparison of the cytoplasmic effects of transfected huntingtins
containing different protein contexts. To examine whether these
transfected proteins could activate caspase cascades, we first used
fluorometric assays to measure caspase activity quantitatively. The
mutant N-terminal huntingtin (120Q-208) produced the greatest activity
of caspase-3. HD exon 1 huntingtin (150Q-exon 1) also increased
caspase-3 activity, but the degree of this increase was less than that
of the larger N-terminal huntingtin (120Q-208). As the length of
N-terminal huntingtin was elongated further, caspase-3 activity
decreased and became similar to that of vector transfection (Fig.
8C).
View larger version (59K):
[in this window]
[in a new window]
|
Figure 8.
The effect of huntingtin context on the activation
of caspases in transfected HEK293 cells. A, Western blot
showing the expression of transfected huntingtin containing different
protein sizes. The bracket indicates the
stacking gel in which aggregated huntingtin is present.
B, Immunofluorescence labeling of transfected HEK293
cells expressing 150Q-exon 1, 120Q-208, 120Q-508, and 120Q-945.
C, Caspase-3 and caspase-9 activities of transfected
cells that expressed different huntingtin fragments as indicated. The
data were obtained from the 48 hr transfection of cells of
three independent transfections and were presented as means ± SEM
of control. The control is the activity of nontransfected cells.
D, MTS assays of the viability of huntingtin-transfected
cells. The control is the viability of nontransfected cells. The data
(means ± SD) were obtained from three to four transfections for
72 hr. *p < 0.05 and **p < 0.01 compared with the activity of the vector-transfected cells.
|
|
We also measured the activity of caspase-9, an upstream caspase that is
primarily activated by cytochrome c and in turn activates caspase-3. We saw that 120Q-208 could also increase the activity of
caspase-9 significantly (Fig. 8C), suggesting that this
increase may contribute to the higher activity of caspase-3 in these
cells. Because caspase-3 is also activated by caspase-8 and other
apoptotic pathways, transfected mutant huntingtin that did not
significantly increase caspase-9 activity could trigger other apoptotic
pathways to increase caspase-3 activity. Previous studies showed that
the decreasing protein length of mutant huntingtin could increase the
cellular toxicity of transfected cells in response to
apoptotic stimulation (Hackam et al., 1999). This idea was
also supported by our cell viability assays that, by measuring
mitochondrial dysfunction caused by transfected huntingtin, showed the
most reduced viability in 120Q-208-transfected cells (Fig.
8D). 150Q-exon 1 or 120Q-508 transfection also
reduced cell viability, although its transfection had less of an effect
than 120Q-208 transfection on caspase activity and cell viability.
| |
Discussion |
Our studies demonstrate that transgenic huntingtin containing the
first 171 aa with an expanded glutamine repeat (82Q) causes apoptosis
in the brain. However, expression of the shorter N-terminal huntingtin
(the HD exon 1) and the full-length mutant huntingtin did not result in
typical apoptotic neurons. In vitro experiments using
similar N-terminal huntingtin fragments also showed increased caspase
activity in transfected cells. In addition, axonal degeneration was
frequently found in HD repeat knock-in mice. Thus, mutant huntingtin
may cause different types of neurodegeneration in a context-dependent manner.
The different types of neurodegeneration seen in our studies appear not
to be dependent on the expression levels of transgenic huntingtin or on
having a very long polyglutamine tract. First, it has been reported
that in N171-82Q mice, the expression level of the transgene is
approximately one-third the level of endogenous mouse huntingtin
(Schilling et al., 1999). Immunostaining of brain using EM48 also
showed less huntingtin staining in N171-82Q mice than in R6/2 mice.
Second, the expression of mutant huntingtin with a long repeat (150Q)
in R6/2 and HD repeat knock-in mice did not result in significant
neurodegeneration. Furthermore, transfection of various N-terminal
huntingtin fragments into cultured cells revealed that an N-terminal
huntingtin fragment (1-208), which is similar to the N171-82Q
transgenic protein, produced more caspase activity than the smaller or
longer huntingtin fragments. All of these results suggest that
N-terminal huntingtin sequences are important for various types of neurodegeneration.
The study of HdhCAG150 mice also suggests that N-terminal mutant
huntingtin causes neurodegeneration. It is known that in HD repeat
knock-in models, huntingtin aggregates are formed by N-terminal mutant
huntingtin and become prominent and abundant as the mouse's age
increases (H. Li et al., 2000; Wheeler et al., 2000), perhaps because
the gradual accumulation of N-terminal mutant huntingtin is required
for the formation of huntingtin aggregates. Consistent with that idea,
degenerating neurons and axons were found only in old HdhCAG150 mice.
More importantly, mutant huntingtin proteins associated with the
degeneration were not labeled by the antibody against huntingtin
amino acids 342-456, suggesting that they were small N-terminal
mutant huntingtin fragments. A recent study shows that N-terminal
huntingtin fragments generated from the cleavage at amino acids
104-114 and 146-214 are localized differently in cells (Lunkes et
al., 2002). It remains to be determined whether the same N-terminal
huntingtin fragments are present in HdhCAG150 mice.
In addition to protein context, the toxicity of mutant huntingtin
fragments is also determined by a number of variables. First, polyglutamine length is certainly a primary determinant for cellular toxicity, because expanded polyglutamine repeats can induce
neurological phenotypes in transgenic mice (Ordway et al., 1997) and
apoptosis in cultured cells (Sanchez et al., 1999). Second, cellular
factors that remove huntingtin fragments could inhibit huntingtin
toxicity. Of these factors, chaperones and proteasomes prevent protein
misfolding and degrade misfolded polyglutamine proteins, respectively
(Orr, 2001). Third, aging may affect the function of these cellular factors and contribute to the late-onset pathology in Hdh150CAG mice.
However, the protein context of huntingtin is likely to determine the
specific types of cellular toxicity by its influence on protein
interactions or modulations. In support of this idea, a number of
proteins, including huntingtin-associated protein 1 and
huntingtin-interacting protein 1, bind to N-terminal mutant huntingtin, and their binding is altered by polyglutamine expansion (Li
et al., 1995; Kalchman et al., 1997). Interactions of huntingtin with
other proteins are important not only for the regulation of the
function of a protein but also for the subcellular localization of huntingtin. N171-82Q may carry N-terminal huntingtin sequences that
confer pathological events more specific to HD. In contrast, the exon 1 protein, which is shorter than other transgenic huntingtins, is more
likely to be translocated into the nucleus. Its initial effects may
primarily affect gene expression in the nucleus, because a number of
studies have shown that this fragment produces a severe defect at the
transcriptional level in R6/2 mice (Cha et al., 1998; Luthi-Carter et
al., 2002) and stably transfected cells (Li et al., 1999). The smaller
size of the N-terminal region with a longer repeat confers a more
misfolded and aggregated state that can cause cellular toxicity via
multiple pathological pathways, such as recruiting caspases, inhibiting
proteasome function, increasing cellular stress, and affecting
mitochondrial function (Ona et al., 1999; Sanchez et al., 1999; S. H. Li et al., 2000; Bence et al., 2001; Kouroku et al., 2002; Nishitoh
et al., 2002; Panov et al., 2002). A global transcriptional
dysregulation and multiple cytosolic effects mediated by exon 1 huntingtin in the brain may give rise to a severe neurotoxic phenotype
without obvious apoptotic events before the animals die.
Although several previous studies were also unable to show obvious
apoptotic neurons in R6/2 mice (Iannicola et al., 2000; Turmaine et
al., 2000), others using different reagents and assays reported that
R6/2 mouse brain had an increase in the number of TUNEL-positive cells
(Keene et al., 2002) or caspase activity on Western blots (Chen et al.,
2000). It seems that the identification of apoptotic events in HD mouse
brains is also dependent on the experimental conditions and reagents
used. However, under the same conditions, we found that N171-82Q mice
had a greater number of apoptotic neurons than other HD mice,
supporting the role of protein context in mediating neurodegeneration
in HD. The context-dependent cytotoxicity was also observed in
huntingtin-transfected cells in response to apoptotic stimulation
(Hackam et al., 1998, 1999). We have presented new data showing
context-dependent activation of caspases in huntingtin-transfected
cells, which is consistent with the role of huntingtin context in
different degrees of apoptosis in various HD mouse models.
In HD repeat knock-in mice, a large repeat (150Q) appears to facilitate
disease progression, giving rise to more detectable neurological
phenotypes (Lin et al., 2001) and earlier occurrence of
neurodegeneration than those in HD repeat 80Q knock-in mice (H. Li et
al., 2000). In addition to protein context, aging may contribute to
certain types of neurodegeneration such as axonal degeneration. The
short life span of the mouse might prevent obvious neurodegeneration
from occurring, perhaps because the concentration of accumulated
N-terminal huntingtin fragments never becomes high enough to induce
neurodegeneration. In contrast, the expression of N171-80Q huntingtin
results in more apoptotic neurons than do other transgenic huntingtins.
As the length of huntingtin is reduced to exon 1 containing a large
glutamine repeat, polyglutamine-mediated and non-context-dependent
toxicity arises and becomes dominant. As N-terminal huntingtin
fragments become larger, they are less misfolded and less toxic.
Alternatively, larger huntingtin fragments may contain the sequences
that protect against huntingtin toxicity. For example, a recent study
has shown that phosphorylation of serine 421 of huntingtin is required
for protecting against huntingtin toxicity by IGF-1 (Humbert et al.,
2002).
Full-length or other forms of mutant huntingtin may also be pathogenic,
because HdhCAG150 mice show neurological symptoms before the appearance
of neurodegeneration and the formation of huntingtin aggregates (Lin et
al., 2001; Menalled et al., 2002). Neuronal dysfunction and toxicity
can occur in the absence of neurodegeneration. Because
neurodegeneration in the brain provides an objective hallmark for HD,
the study of its relationship with mutant huntingtin in HD mouse models
will be especially helpful in uncovering the mechanisms of the
neuropathology of HD. Identification of the neurodegenerative markers
also helps with the evaluation of therapeutic effects of drugs on HD
mouse models.
The present study provides in vivo evidence that mutant
huntingtin induces different forms of neurodegeneration that are
dependent on protein context. Consistent with this, protein
context-dependent dysregulation of gene expression was reported
recently in HD transgenic mice (Chan et al., 2002). Considering that a
number of N-terminal huntingtin fragments have been found in
vitro and in vivo (DiFiglia et al., 1997; Wellington et
al., 2000; Kim et al., 2001; Mende-Mueller et al., 2001; Gafni and
Ellerby 2002), it is likely that proteolysis produces a wide range of
N-terminal huntingtin fragments, each of which may mediate specific
forms of neuropathology. This may explain the various types of
neurodegeneration found in the brains of patients with HD and HD animal
models, including apoptotic neurons (Dragunow et al., 1995;
Portera-Cailliau et al., 1995; Thomas et al., 1995) and nonapoptotic
neurons (Turmaine et al., 2000). Investigation of the mechanisms by
which these N-terminal sequences confer specific forms of
neurodegeneration would help us to understand the pathogenesis of HD
and to develop effective therapeutic strategies.
| |
FOOTNOTES |
Received Nov. 20, 2002; revised Dec. 26, 2002; accepted Dec. 30, 2002.
This work was supported by National Institutes of Health Grants AG19206
and NS41669. We thank Dr. Peter Deltloff for providing HD repeat
knock-in mice and Huu-Phuc Nguyen for technique assistance.
Correspondence should be addressed to Dr. Xiao-Jiang Li, Department of
Human Genetics, Emory University School of Medicine, 615 Michael
Street, Atlanta, GA 30322. E-mail: xiaoli{at}genetics.emory.edu.
| |
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TOP
ABSTRACT
Introduction
Gene
