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The Journal of Neuroscience, November 1, 2002, 22(21):9340-9351
Abundant Tau Filaments and Nonapoptotic Neurodegeneration in
Transgenic Mice Expressing Human P301S Tau Protein
Bridget
Allen1, *,
Esther
Ingram2, *,
Masaki
Takao3, *,
Michael J.
Smith1,
Ross
Jakes1,
Kanwar
Virdee1,
Hirotaka
Yoshida1,
Max
Holzer1,
Molly
Craxton1,
Piers C.
Emson4,
Cristiana
Atzori5,
Antonio
Migheli5,
R. Anthony
Crowther1,
Bernardino
Ghetti3,
Maria Grazia
Spillantini2, and
Michel
Goedert1
1 Medical Research Council Laboratory of Molecular
Biology, Cambridge CB2 2QH, United Kingdom, 2 Brain Repair
Centre and Department of Neurology, University of Cambridge, Cambridge
CB2 2PY, United Kingdom, 3 Department of Pathology and
Laboratory Medicine, Indiana University, Indianapolis, Indiana
46202-5120, 4 Department of Neurobiology, Babraham
Institute, Cambridge CB2 4AT, United Kingdom, and
5 Laboratory of Neuropathology, Department of Neuroscience,
University of Turin, 10126 Turin, Italy
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ABSTRACT |
The identification of mutations in the Tau gene in
frontotemporal dementia and parkinsonism linked to chromosome 17 (FTDP-17) has made it possible to express human tau protein with
pathogenic mutations in transgenic animals. Here we report on the
production and characterization of a line of mice transgenic for the
383 aa isoform of human tau with the P301S mutation. At 5-6 months of
age, homozygous animals from this line developed a neurological phenotype dominated by a severe paraparesis. According to light microscopy, many nerve cells in brain and spinal cord were strongly immunoreactive for hyperphosphorylated tau. According to electron microscopy, abundant filaments made of hyperphosphorylated tau protein
were present. The majority of filaments resembled the half-twisted
ribbons described previously in cases of FTDP-17, with a minority of
filaments resembling the paired helical filaments of Alzheimer's
disease. Sarkosyl-insoluble tau from brains and spinal cords of
transgenic mice ran as a hyperphosphorylated 64 kDa band, the same
apparent molecular mass as that of the 383 aa tau isoform in the human
tauopathies. Perchloric acid-soluble tau was also phosphorylated at
many sites, with the notable exception of serine 214. In the spinal
cord, neurodegeneration was present, as indicated by a 49% reduction
in the number of motor neurons. No evidence for apoptosis was obtained,
despite the extensive colocalization of hyperphosphorylated tau protein
with activated MAP kinase family members. The latter may be involved in
the hyperphosphorylation of tau.
Key words:
hyperphosphorylation; MAP kinase family; neurodegeneration; tauopathy; tau filaments; Tau gene mutations
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INTRODUCTION |
Abundant filaments made of
hyperphosphorylated microtubule-associated protein tau constitute a
defining characteristic of a number of neurodegenerative diseases,
including Alzheimer's disease, Pick's disease, progressive
supranuclear palsy, corticobasal degeneration, and frontotemporal
dementia and parkinsonism linked to chromosome 17 (FTDP-17) (Lee et
al., 2001 ). The discovery of coding region and intronic mutations in
the Tau gene in FTDP-17 has firmly established that
dysfunction of tau protein can cause neurodegeneration and dementia
(Hutton et al., 1998; Poorkaj et al., 1998; Spillantini et al.,
1998a).
In adult human brain, six tau isoforms are expressed from a single gene
by alternative mRNA splicing (Goedert et al., 1988, 1989a,b; Andreadis
et al., 1992; Poorkaj et al., 2001). They differ by the presence or
absence of 29 and 58 aa inserts located in the N-terminal half and an
additional 31 aa insert located in the C-terminal half. Inclusion of
the latter, which is encoded by exon 10 of the Tau gene,
gives rise to the three isoforms with four microtubule-binding repeats
each. The other three isoforms have three repeats each. In normal
brain, similar levels of three-repeat and four-repeat tau isoforms are
expressed (Goedert and Jakes, 1990). Known mutations in the
Tau gene in FTDP-17 are either missense, deletion, and
silent mutations in the coding region or intronic mutations located
close to the splice donor site of the intron after exon 10. Functionally, they lead to a reduced ability of tau to interact with
microtubules and/or a change in the ratio of three-repeat to
four-repeat tau isoforms, resulting in the relative overproduction of
four-repeat tau (Hasegawa et al., 1998; Hong et al., 1998; Hutton et
al., 1998; Spillantini et al., 1998a; Yoshida et al., 2002). Some
coding region mutations also promote the assembly of tau protein into
filaments (Goedert et al., 1999; Nacharaju et al., 1999). In FTDP-17,
the age of onset of disease varies, depending on the Tau
mutation. The same is true of the magnitude of the functional effects
produced by individual mutations.
Mutation P301S in exon 10 of Tau causes an early onset of
clinical signs and has strong functional effects, as evidenced by a
reduced ability of mutant tau protein to promote microtubule assembly
and a marked stimulatory effect on tau filament assembly (Bugiani et
al., 1999; Goedert et al., 1999; Sperfeld et al., 1999; Yasuda et al.,
2000; Morris et al., 2001). Here we describe the production and
characterization of a line of transgenic mice that express, under the
control of the murine thy1 promoter, the 383 aa isoform of
human tau with the P301S mutation. At 5-6 months of age, homozygous
animals developed motor symptoms characterized by a severe paraparesis.
Brain and spinal cord contained insoluble hyperphosphorylated tau
protein that migrated on gels at the same position as filamentous tau
from human tauopathies. By electron microscopy, abundant tau filaments
were found. In the spinal cord, neurodegeneration was present, as
evidenced by a significant reduction in the number of motor neurons.
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MATERIALS AND METHODS |
Antibodies. A panel of anti-tau antibodies was used
(Fig. 1). Antiserum BR133 recognizes the
N terminus of tau; antiserum BR135 is directed against the
microtubule-binding repeat region, and antiserum BR134 is directed
against the C terminus of tau. All three antisera recognize the six
adult human brain and three adult murine brain tau isoforms (Goedert et
al., 1989b; Götz et al., 1995). T14 (a kind gift from Dr. V. M.-Y. Lee, University of Pennsylvania, Philadelphia, PA)
recognizes residues 141-149 of human tau (in the numbering of the
longest human brain tau isoform); it recognizes all human tau isoforms
but fails to recognize murine tau (Kosik et al., 1988). Antiserum MT1
was raised in white Dutch rabbits using the synthetic peptide
ARVASKDRTGNDEK (residues 114-127 of the longest isoform of mouse brain
tau) as the immunogen. MT1 recognizes the three murine brain tau
isoforms but fails to recognize human tau. Alz-50 (a kind gift from Dr.
P. Davies, Albert Einstein College of Medicine, Bronx, NY)
recognizes amino acids 5-15 and 312-322 of tau and is sensitive to
the conformation of tau (Carmel et al., 1996). BR133, BR134, BR135,
Tau14, MT1, and Alz-50 are phosphorylation-independent anti-tau
antibodies. AT270 (Innogenetics, Gent, Belgium) recognizes human and
murine tau phosphorylated at T181 (Goedert et al., 1994); AT8
(Innogenetics) recognizes human and murine tau phosphorylated at S202
and T205 (Goedert et al., 1995); AT100 (Innogenetics) recognizes human and murine tau phosphorylated at T212 and S214 (Zheng-Fischhöfer et al., 1998); pT212 (Biosource, Camarillo, CA) recognizes human and
murine tau phosphorylated at T212 (Woods et al., 2001); CP3 (a kind
gift from Dr. P. Davies) recognizes human and murine tau phosphorylated
at S214 (Jicha et al., 1999); AT180 (Innogenetics) recognizes human and
murine tau phosphorylated at T231 (Goedert et al., 1994); 12E8 (a kind
gift from Dr. P. Seubert, Elan Pharmaceuticals, San Francisco,
CA) recognizes human and murine tau phosphorylated at S262
and/or S356 (Seubert et al., 1995); AD2 (a kind gift from Dr. A. Delacourte, Institut National de la Santé et de la Recherche Médicale U422, Lille, France) and PHF1 (a kind gift from
Dr. P. Davies) recognize human and murine tau phosphorylated at S396 and S404 (Otvos et al., 1994; Buée-Scherrer et al., 1996); PG5 (a
kind gift from Dr. P. Davies) recognizes human and murine tau phosphorylated at S409 (Jicha et al., 1999); AP422 recognizes human and
murine tau phosphorylated at S422 (Hasegawa et al., 1996). In addition
to anti-tau antibodies, tissue sections were also stained with a number
of other antibodies. They included antibodies to  -amyloid (a kind
gift from Dr. V. M.-Y. Lee), parkin (Chemicon, Temecula,
CA), ubiquitin (Dako, Glostrup, Denmark, and Chemicon), the 20S
proteasome (Affiniti, Research Products, Exeter, UK),
phospho-mitogen-activated protein (MAP) kinase kinase 3/6
(Cell Signaling Technology, Beverly, MA), phospho-MAP kinase (clone
12D4; Nanotools, Teningen, Germany), phospho-p38 MAP kinase (Cell
Signaling Technology), phospho-c-Jun N-terminal protein kinase (JNK)
(Cell Signaling Technology), phospho-glycogen synthase kinase-3 (GSK3)
(specific for phosphorylated Y279 of GSK3 and phosphorylated Y216 of
GSK3, clone 5G-2F; Upstate Biotechnology, Lake Placid, NY),
cyclin-dependent kinase 5 (cdk5) (Santa Cruz Biotechnology, Santa Cruz,
CA), the p35 activator of cdk5 (Santa Cruz Biotechnology), Pin1 (N-19;
Santa Cruz Biotechnology), active caspase-3 (PharMingen, San Diego, CA,
and Cell Signaling Technology), cleaved -fodrin (Cell Signaling
Technology), heparan sulfate (Seikagaku Kogyo, Tokyo, Japan), heat
shock protein 25 (Stressgen Biotechnologies, Victoria, Canada), heat
shock protein 70 (Stressgen Biotechnologies), B-crystallin
(Stressgen Biotechnologies), and glial fibrillary acidic protein (GFAP;
Dako).
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Figure 1.
Epitopes of anti-tau antibodies. A bar diagram of
the 441 aa isoform of human tau is shown, with the microtubule-binding
repeat region shown in black. Amino acids recognized by
phosphorylation-dependent antibodies are indicated above
the bar diagram (pS and
pT). The epitopes of phosphorylation-independent
antibodies are shown below the bar diagram.
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Transgenic mice. Site-directed mutagenesis was
used to introduce the P301S mutation (using the numbering of the
longest human brain tau isoform) into the cDNA encoding the shortest
human four-repeat tau isoform (383 aa isoform of human tau). The
mutated cDNA was subcloned into a murine thy1.2 genomic
expression vector (a kind gift from Dr. H. van der Putten, Novartis,
Basel, Switzerland) (Lüthi et al., 1997). This tau
expression construct was produced by subcloning P301S hTau43
cDNA into a unique XhoI site of the expression vector. A
Kozak consensus sequence had been introduced upstream of the initiation
codon. Vector sequences were removed before microinjection. Transgenic
mice were produced by pronuclear injection of (C57BL/6J × CBA/ca)
F1 embryos. Founders were identified by PCR
analysis of lysates from tail biopsies using the primer pair
5'-GGTTTTTGCTGGAATCCTGG-3' and 5'-GGAGTTCGAAGTGATGGAAG-3'. Founder
animals were intercrossed with C57BL/6J mice to establish lines.
Homozygosity was determined by matings with nontransgenic animals.
Immunoblot analysis. Brains and spinal cords from transgenic
mice were dounce homogenized in 2.5% (v/v) perchloric acid (0.5 ml/gm), allowed to stand on ice for 20 min, and centrifuged for 10 min
at 10,000 × g. The supernatants were dialyzed against
50 mM Tris-HCl, pH 7.4, 1 mM dithiothreitol, and 0.1 mM phenylmethylsulfonyl fluoride (PMSF) and used
for immunoblot analysis, as described previously (Goedert and Jakes,
1990). Comparison of the amount of expressed soluble human tau with
endogenous mouse tau was determined by extracting brain and spinal cord
samples from 5- to 6-month-old homozygous transgenic mice. Tissues were
homogenized in 5 vol of extraction buffer (50 mM
Tris-HCl, pH 7.4, 0.5 M NaCl, 0.1 mM PMSF, 1 µg/ml leupeptin, 1 µg/ml
pepstatin, 1 mM sodium orthovanadate, 50 mM sodium fluoride, and 1 mM -glycerophosphate). After a 15 min
centrifugation at 543,000 × g, the supernatants were
adjusted to 2% 2-mercaptoethanol, boiled for 10 min, chilled on ice
for 10 min, and centrifuged, and the resulting supernatants were then brought to 50% ammonium sulfate. After centrifugation at 543,000 × g, the precipitates were resuspended in 50 mM Tris-HCl, pH 7.4, 0.1 mM
PMSF, 1 µg/ml leupeptin, and 1 µg/ml pepstatin. Dephosphorylation of tau with Escherichia coli alkaline phosphatase (Sigma,
St. Louis, MO) was performed as described previously (Goedert et al., 1992a). The relative tau levels were determined by densitometry using
purified recombinant tau proteins as standards. Various amounts of the
final fractions were run on 10% SDS-PAGE alongside recombinant human
tau proteins and immunoblotted with anti-tau serum BR134. The blots
were developed using enhanced chemiluminescence (Amersham Biosciences,
Arlington Heights, IL), and the bands were scanned (Personal
Densitometer SI; Molecular Dynamics, Sunnyvale, CA) and analyzed using
the IQMac version 1.2 software (Molecular Dynamics). The readings given
by the three mouse tau bands were added together and compared with the
reading given by the single human tau band.
Histology and immunohistochemistry. Brain, spinal cord, and
hindleg muscle from P301S tau transgenic mice were analyzed
histologically. Animals were perfused transcardially with 4%
paraformaldehyde in 0.1 M phosphate buffer, pH
7.2, and the tissues were postfixed for 2 hr. Histological staining and
immunohistochemistry were performed on either 4 µm sections obtained
from paraffin-embedded tissue blocks or 30 µm microtome sections.
Thioflavin S staining and Bodian silver staining were done as described
previously (Yamamoto and Hirano, 1986). For immunohistochemistry,
sections were incubated overnight at 4°C with the primary antibodies.
Immunostaining was visualized using the avidin-biotin system
(Vectastain; Vector Laboratories, Burlingame, CA) and
3,3'-diaminobenzidine (Sigma) as the chromogen. The sections were
counterstained with cresyl violet or hematoxylin and eosin. The
colocalization of activated MAP kinase family members and
hyperphosphorylated tau was investigated by double-labeling
immunofluorescence. Nonspecific binding sites were blocked by
incubating free-floating brain and spinal cord sections for 3 hr at
room temperature with 3% bovine serum albumin (BSA) and 0.1% saponin
in PBS. The tissue sections were then incubated overnight at room
temperature with the following antibodies in the presence of either the
polyclonal anti-tau antibody BR134 or the monoclonal antibody PHF1
(anti-phospho-MAP kinase kinase 3/6, anti-activated MAP kinase,
anti-phospho-JNK, and anti-phospho-p38). The sections were washed five
times in BSA/saponin/PBS and incubated with anti-mouse IgG conjugated
to Alexa-488 (Molecular Probes, Eugene, OR) and anti-rabbit IgG
conjugated to CY3 (Jackson ImmunoResearch, West Grove, PA) for 3 hr at
room temperature. For the colocalization of Pin1 and
hyperphosphorylated tau, tissue sections were subjected to microwave
irradiation for antigen retrieval, followed by the addition of the
polyclonal anti-Pin1 antibody and monoclonal antibody AT100. Donkey
anti-goat CY3 and donkey anti-mouse CY2 (Jackson ImmunoResearch)
were used as secondary antibodies. After washing, sections were mounted
in Vectashield (Vector Laboratories) and imaged with a Radiance 2100 confocal microscope (Bio-Rad, Hercules, CA).
Electron microscopy of tissue sections. Tissues were fixed
in 4% paraformaldehyde, postfixed in 1% osmium tetroxide, and
embedded in Epon. One-micrometer-thick sections were stained with
toluidine blue. Ultrathin sections were stained with uranyl acetate and lead citrate and viewed with a Philips 300 electron microscope. For
immunoelectron microscopy, paraformaldehyde-fixed specimens (1 mm3) were washed in distilled water and
placed in Tris-buffered saline, pH 7.6. Fifty-micrometer-thick sections
were cut using a vibratome. Immunogold labeling with anti-tau antibody
AT8 (1:5) was performed using 10 nm gold particles (Goldmark
Biologicals, Phillipsburg, NJ) conjugated to goat anti-mouse IgG at a
dilution of 1:10. Sections were postfixed in 2.5% glutaraldehyde,
followed by 1% osmium tetroxide, dehydrated through a graded alcohol
series, and embedded in epoxy resin. Semithin sections were stained
with toluidine blue. Ultrathin sections were contrasted with lead
citrate and uranyl acetate and scanned with the electron microscope.
Extraction and characterization of sarkosyl-insoluble tau.
Sarkosyl-insoluble tau was extracted from whole brains and spinal cords
of transgenic mice, as described for cerebral cortex from Alzheimer's
disease brains. The sarkosyl-insoluble material was analyzed by
immunoblotting and electron microscopy. For immunoblotting, SDS-PAGE
and transfers were done, as described previously (Goedert and Jakes,
1990). Dephosphorylation using E. coli alkaline phosphatase was performed as described previously (Goedert et al., 1992a). For
electron microscopy, aliquots of the sarkosyl-insoluble material were
placed on carbon-coated 400 mesh grids and stained with 1% lithium
phosphotungstate. Micrographs were recorded at a nominal magnification
of 40,000× on a Philips EM208S microscope, as described previously
(Crowther, 1991). Procedures for immunoelectron microscopy were as
described previously (Crowther, 1991).
Nerve cell counts. The numbers of nerve cells in lamina II
(substantia gelatinosa) and lamina IX (somatic motor neurons) of the
lumbar spinal cord were counted in three 6-month-old transgenic mice
and three age-matched controls. We used the atlas of Sidman et al.
(1971) for the macroscopic identification of lumbar segments L2-L3 and
the microscopic identification of laminas II and IX in cross sections.
The widest part of the lumbar enlargement (level L2-L3) was serially
sectioned (8 µm) and stained using hematoxylin and eosin, and laminas
II and IX were identified. A field of each section was digitally
captured using a Spot RT digital camera (Diagnostic Instruments,
Sterling Heights, MI) attached to a Leica (Wetzlar, Germany)
FMLB microscope with a 10× objective. The areas of laminas II
and IX were measured using supplementary software of the digital
camera. In each of the five serial sections from each mouse, the number
of nerve cells was counted manually using a 20× or 40× objective. To
avoid counting the same neuron in consecutive sections, only neurons
with a nucleolus were included. The results were expressed as the mean
neuronal density (number of neurons per millimeter square). Statistical
analyses compared mean neuronal densities of control and transgenic
mice. Hierarchical models were used which made it possible to correlate
the density measurements of the five sections from each mouse
(Goldstein, 1995). Individual mice were coded as random effect and the
type of mouse (control or transgenic) as fixed effect.
Detection of apoptosis. The presence of DNA fragmentation in
single cells was investigated by in situ end-labeling (ISEL) of sections obtained from paraffin-embedded tissue blocks, as described
previously (Migheli et al., 1997). Briefly, sections were pretreated
with 0.5-5 µg/ml proteinase K for 15 min at room temperature.
They were then incubated with 20 U/ml terminal
deoxynucleotidyl transferase (Roche Diagnostics, Indianapolis, IN) and
10 nmol/ml fluorescein-11-deoxyUTP (Roche Diagnostics) for 2 hr at
37°C. The reaction product was revealed with peroxidase-conjugated
anti-fluorescein antibody (Roche Diagnostics) using diaminobenzidine as
the chromogen. For immunohistochemistry with antibodies directed
against activated caspase-3 and cleaved -fodrin, tissue sections
were subjected to microwave irradiation for antigen retrieval. They
were then incubated with 5% ovalbumin for 15 min, followed by a 15 min
incubation with 2% biotin. Immunohistochemistry was performed using
streptavidin-biotin and cobalt chloride-intensified diaminobenzidine
or 3-amino-9-ethylcarbazole as substrate.
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RESULTS |
Production of transgenic mouse lines and
neurological phenotype
The neuron-specific elements of the mouse thy1 promoter
were used to produce transgenic mice expressing the shortest human four-repeat tau isoform with the P301S mutation. Six founders were
obtained, five of which transmitted the transgene in a Mendelian manner. Three of the five lines expressed high levels of human tau
protein in the brain and spinal cord and were used to establish homozygous lines. The present report concentrates on line 2541. At 5-6
months of age, homozygous animals from this line developed a
neurological phenotype that was characterized by general muscle weakness, tremor, and a severe paraparesis. When lifted by the tail,
the mice were unable to extend their hindlimbs. In most animals, an eye
inflammation was also present. Heterozygous animals developed a similar
phenotype at 12-14 months of age.
Expression, phosphorylation, and solubility of mutant human
tau protein
By immunoblotting, a broad transgenic tau band of 52-58 kDa
apparent molecular mass was present in brains and spinal cords from 5- to 6-month-old homozygous transgenic mice (Fig.
2A). It was reactive
with anti-tau serum BR134, which recognizes both human and murine tau,
and with antibody T14, which only recognizes human tau. The transgenic
tau band was not immunoreactive with antibody MT1, which recognizes
murine but not human tau (data not shown). Dephosphorylation with
alkaline phosphatase was used to assess the expression level of
transgenic human tau relative to endogenous mouse tau (Fig.
2A). As shown previously (Götz et al., 1995;
Kampers et al., 1999), dephosphorylated mouse brain tau runs as three
bands that correspond to the three tau isoforms with four repeats. In
transgenic mice, an additional human tau band of 52 kDa was observed
that aligned with the 383 aa isoform of recombinant human brain tau. In
brains and spinal cords from transgenic mice, human tau levels were
approximately twofold higher than the levels of total mouse tau. The
phosphorylation state of perchloric acid-soluble human tau protein from
mouse brain and spinal cord was investigated by immunoblotting using 10 different phosphorylation-dependent anti-tau antibodies (Fig.
2C). The human tau band was strongly immunoreactive with
antibodies AT270, AT8, pT212, AT180, 12E8, AD2, PG5, and AP422. No
reactivity was observed with antibodies AT100 or CP3.
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Figure 2.
Immunoblot analysis of tau protein in brains and
spinal cords from mice of the human P301S tau line. A,
Perchloric acid-soluble tau was extracted from the brain
(B) and spinal cord (SC) of 5- to
6-month-old mice and immunoblotted with anti-tau antibodies BR134 and
T14 before ( ) and after (+) alkaline phosphatase treatment.
Black arrowheads point to the three mouse tau isoforms,
with the white arrowhead pointing to the single
human tau isoform. B, Sarkosyl-insoluble tau was
extracted from brains (B) and spinal cords
(SC) of 5- to 6-month-old transgenic mice and
immunoblotted with T14 before () and after (+) alkaline phosphatase
treatment. M, Mixture of the six recombinant human brain
tau isoforms. C, Reactivities of perchloric acid-soluble
and sarkosyl-insoluble tau with a panel of 10 different
phosphorylation-dependent anti-tau antibodies.
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Sarkosyl-insoluble tau protein was extracted from transgenic mouse
brain and spinal cord. A strong band of 64 kDa apparent molecular mass
was detected by immunoblotting with antibody T14 (Fig.
2B). After dephosphorylation, sarkosyl-insoluble tau
ran at 52 kDa and aligned with the recombinant 383 aa isoform of human tau, as did dephosphorylated perchloric acid-soluble tau (Fig. 2A,B). Sarkosyl-insoluble human tau
protein was strongly immunoreactive with all of the
phosphorylation-dependent anti-tau antibodies, including AT100 and CP3
(Fig. 2C).
Immunohistochemical and histochemical staining of mutant human
tau protein
The cellular distribution of tau protein was investigated in
brains and spinal cords from 5- to 6-month-old transgenic mice by using
phosphorylation-dependent and phosphorylation-independent anti-tau
antibodies (Figs. 3,
4; see Fig. 1 for antibody epitopes). Strong labeling of nerve cell bodies and processes was observed in most
brain regions. For instance, in the cerebral cortex and the hippocampal
formation, numerous nerve cells were immunopositive (Figs.
3A,B, 4A). In
frontal and temporal cortices, they were concentrated in layers 2, 4, and 5. The largest number of tau-immunoreactive nerve cells was present
in the brainstem and spinal cord. Figure 3 shows the staining in a
number of regions using the phosphorylation-dependent anti-tau antibody
AT8. Overall, the tau staining was either homogenous or had the
appearance of circumscribed inclusions. In some cells, particularly in
the cerebral cortex, it was distinctly granular.
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Figure 3.
Tau protein immunoreactivity in brains and spinal
cords from mice of the human P301S tau line. The
phosphorylation-dependent anti-tau antibody AT8 was used to stain the
cerebral cortex (A, B), amygdala
(C), dentate nucleus of the cerebellum
(D), brainstem (E,
F), and spinal cord (G,
H). The transgenic mice used were 5 months old.
Scale bars: A, 40 µm (for A-C,
E, F); D, 60 µm
(for D, H); G, 250 µm.
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Figure 4.
Tau protein immunoreactivity and silver staining
in brains and spinal cords from mice of the human P301S tau line. The
human-specific, phosphorylation-independent anti-tau
antibody T14 was used to stain the cerebral cortex
(A) and spinal cord (F).
The phosphorylation-dependent anti-tau antibodies AP422
(B) and CP3 (C) were used
to stain the cerebral cortex. The phosphorylation-dependent anti-tau
antibodies 12E8 (D) and AT180
(E) were used to stain the brainstem. The
phosphorylation-dependent anti-tau antibody AT100 was used to stain the
spinal cord (G). Bodian silver staining of the
amygdala is shown in H. The transgenic mice used were 5 months old. Scale bars: A, 125 µm (for
A-D, G); E, 250 µm;
F, 100 µm; H, 40 µm.
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Immunoreactive nerve cells were observed with the
phosphorylation-dependent anti-tau antibodies AT8, AT100, CP3,
AT180, 12E8, PHF1, PG5, and AP422. Overall, the largest number of
stained cells was observed with AT8, followed by AP422, AT180, and PG5.
Fewer cells were labeled by AT100 and CP3, with the smallest number of
cells being stained by 12E8 and PHF1. Antibody AD2 gave a staining pattern similar to that seen for PHF1. Regional differences were observed. For instance, strong and widespread staining for 12E8 was
present in the spinal cord but not in the cerebral cortex. Staining
with antibodies AP422, CP3, 12E8, AT180, and AT100 is illustrated in
Figure 4. The phosphorylation-independent, human-specific anti-tau
antibody T14 labeled numerous nerve cells (Fig.
4A,F), as did Alz-50, BR133,
and BR134. In contrast, antibody MT1, which is specific for murine tau,
gave only diffuse neuropil staining. Antibodies directed against
ubiquitin, parkin, the 20S proteasome, heparan sulfate, heat shock
protein 25, heat shock protein 70, B-crystallin, cdk5, and the p35
activator of cdk5 failed to stain the tau-positive cells. Most nerve
cells were stained by the anti-phospho-GSK3 antibody, regardless of
whether they were immunoreactive for human tau. No staining for
-amyloid was observed. Sections of brain and spinal cord from
transgenic mice were also stained with the Bodian silver stain and
thioflavin S. Numerous nerve cells were silver positive (Fig.
4H) and fluorescent with thioflavin S (Fig. 5). The thioflavin S fluorescence was
weak (Fig. 5A-C) and resembled that given by the Pick
bodies of sporadic Pick's disease (Fig. 5D).
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Figure 5.
Thioflavin S fluorescence in brains and spinal
cords from mice of the human P301S tau line. Amygdala
(A), brainstem (B), and
spinal cord (C) from 6-month-old transgenic mice.
D, Entorhinal cortex from a case of Pick's disease.
Note the weak green fluorescence against a
yellowish-green background in A-C and
the similarly weak fluorescence intensity of Pick bodies against a
green background in D. Some of the
positive cells in A-C are indicated by
arrows, as are two positive Pick bodies in
D. Scale bar, 80 µm.
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Electron microscopy of tau filaments
Large numbers of abnormal filaments were observed in the cytoplasm
and processes of nerve cells from 5- to 6-month-old transgenic mice.
Representative sections of cerebral cortex, brainstem, and spinal cord
are shown in Figure 6. The filaments were
oriented randomly and were not membrane bound. Most filaments appeared ribbon like, with approximate diameters of 5-15 nm. According to
immunoelectron microscopy on tissue sections, the filaments were
strongly labeled by the phosphorylation-dependent anti-tau antibody AT8
(Fig. 6C,D).
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Figure 6.
Electron microscopy and immunoelectron microscopy
of nerve cells in brains and spinal cords from mice of the human P301S
tau line. A, B, Cerebral cortex;
C, D, brainstem; E,
F, spinal cord. B, D,
F, Higher magnifications of parts of the cytoplasmic
regions from A, C, and E.
Note the large numbers of abnormal filaments in the cytoplasm and
apical dendrite. The electron micrographs in C and
D show immunogold labeling of filaments using the
phosphorylation-dependent anti-tau antibody AT8. Scale bars:
C, 1.5 µm; E, 5.5 µm (for
A, E); F, 300 nm (for
B, D, F).
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Isolated filaments were also characterized using sarkosyl-insoluble
preparations extracted from brains and spinal cords of transgenic mice
(Fig. 7). Labeling with antibodies
against tau (see Fig. 1 for antibody epitopes) revealed reasonably
abundant tau-containing filaments of rather irregular appearance but
predominantly of two morphologies (Fig. 7). The majority resembled
"half-twisted" ribbons, with an apparent width varying between 5 and 10 nm and with a very variable spacing between cross-overs. A
minority of filaments (Fig. 7I,L)
were more like Alzheimer-paired helical filaments with a cross-over
spacing of ~70-80 nm. The filaments were strongly labeled by
phosphorylation-independent antibodies BR133 and BR134, raised against
the N- and C-terminal regions of tau, but not by BR135, whose epitope
lies in the repeat region. They were also labeled by the human
tau-specific antibody T14. In contrast, only a small number of
filaments were labeled by the mouse tau-specific antibody MT1. The
filaments were not labeled by an anti-ubiquitin antibody. The filaments
were labeled by a range of phosphorylation-dependent anti-tau
antibodies but not 12E8, whose epitope lies in the repeat region.
Similar labeling patterns were found, where tested, for filaments from
brain and spinal cord.
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Figure 7.
Immunoelectron microscopy of
isolated filaments prepared by sarkosyl extraction of brains and spinal
cords from mice of the human P301S tau line. A-E,
Phosphorylation-independent anti-tau antibodies; F,
anti-ubiquitin antibody (Ub); G-L,
phosphorylation-dependent anti-tau antibodies. In each case, the
antibody is named above the panel. The
filaments in C and G came from spinal
cord, the rest from brain. Antibodies BR135, Ub, and 12E8 did not label
the filaments. Most filaments resembled half-twisted ribbons
(A-H, J, K),
whereas some filaments were reminiscent of paired helical filaments
(I, L). The transgenic mice used were
5-6 months old. Scale bar, 100 nm.
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Nerve cell numbers in the spinal cord
In ventral gray matter from 6-month-old homozygous human
P301S tau mice, a reduction in the number of motor neurons and an increase in the number of glial cells were observed (Fig.
8A,B). Neuronal cell bodies were often swollen or severely atrophic. In some
instances, pyknotic neurons were surrounded by glial cells, suggestive
of neuronophagia. Nerve cell counts showed a 49% reduction in the
number of motor neurons in the anterior horn of the spinal cord from
transgenic mice compared with age-matched controls (Fig. 8C). Occasional severely atrophic neurons may not have been
counted, because they lacked a visible nucleolus. The estimated mean
was 8.14/mm2 in control mice and
4.02/mm2 in transgenic mice
(p < 0.0001), with an estimated difference of
4.12/mm2 (95% confidence interval of
2.8-5.4). In contrast, the neuronal density in the substantia
gelatinosa was not significantly different between control and
transgenic mice (p > 0.7). The respective estimated means were 502.6 and 494.3, with an estimated difference of
8.3/mm2 (95% confidence interval of
38.3 to 54.9). The reduction in the number of motor neurons was
accompanied by a reactive astrocytosis, as detected by a marked
increase in GFAP staining (Fig.
9A,B). In hindlimb skeletal muscle from transgenic mice, groups of atrophic, angulated muscle fibers were frequently observed amid normal-looking fibers, indicative of denervation atrophy (Fig. 9C).
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Figure 8.
Nerve cell loss in spinal cords from mice of the
human P301S tau line. A, B, Hematoxylin
and eosin-stained sections of the ventral gray matter of the spinal
cord (level L2-L3) from a 6-month-old control mouse
(A) and a transgenic mouse
(B) of the same age. Swollen, abnormal
material-containing motor neurons are indicated by
arrows. Arrowheads point to atrophic
motor neurons, with dashed arrows pointing to pyknotic
cells that are surrounded by glial cells, suggestive of neuronophagia.
C, Graph showing the density of motor neurons (expressed
as number of neurons per millimeter square) in the anterior horn of the
lumbar spinal cord from 6-month-old control and human P301S tau
transgenic mice. Nerve cell numbers were determined in five consecutive
sections from each animal, with the density of motor neurons from each
section being represented by a circle. The results are
expressed as the means ± SEM (n = 3);
*p < 0.0001. Scale bar: A, 60 µm
(for A, B).
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Figure 9.
Astrocytosis in the spinal cord and denervation
atrophy in skeletal muscle from mice of the human P301S tau line.
A, B, The ventral gray matter of the
spinal cord (level L2-L3) from a 6-month-old control mouse
(A) and a transgenic mouse
(B) of the same age was stained with an
anti-glial fibrillary acidic protein antibody. Note the weak
immunoreactivity in A and the much stronger staining in
B, as reflected in a large number of immunopositive
astrocytic cell bodies and coarse processes. C, Hindlimb
skeletal muscle from a transgenic mouse was stained with toluidine
blue. Groups of atrophic, angulated muscle fibers are indicated by
arrows. Scale bars: A, 50 µm (for
A, B); C, 60 µm.
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Staining with apoptosis markers
Apoptotic profiles, as identified by ISEL and immunoreactivity of
activated caspase-3 and cleaved -fodrin, were extremely rare or
absent in brains and spinal cords from 5- to 6-month-old transgenic
mice. (Fig.
10A,C,E).
The number of caspase-3-positive cells never exceeded one or two in the
entire brain. These cells, which were found at the same frequency in
brains from control mice, were located primarily in the cerebral cortex
and hippocampus. Brain sections from 8-d-old citron
kinase / mice (Di Cunto et al., 2000)
and 1-d-old control mice were used as positive controls. They showed
apoptotic cells in the external granular layer of the cerebellum (Fig.
10B,D,F).
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Figure 10.
ISEL, staining of activated caspase-3, and
staining of cleaved -fodrin in spinal cords from mice of the human
P301S tau line. A, B, ISEL;
C, D, staining of activated caspase-3;
E, F, staining of cleaved -fodrin. The
sections in A, C, and E
are from spinal cords of 6-month-old human P301S tau transgenic mice.
The sections in B and D are from the
cerebellum of 8-d-old citron kinase/ mice, and
the section in F is from the cerebellum of a 1-d-old
control mouse. No specific reaction product is seen in
A, C, and E. Some of the
immunopositive cells in B, D, and
F are indicated by arrows. Scale bar:
F, 50 µm (for A-F).
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|
Staining of activated MAP kinase family members and the prolyl
isomerase Pin1
The colocalization of activated MAP kinase family members and
hyperphosphorylated tau was investigated by double labeling immunofluorescence in brains and spinal cords from 5- to 6-month-old transgenic mice. Antibodies specific for activated MAP kinase, phospho-JNK, and phospho-p38 labeled the nerve cells that were tau
positive (Fig.
11A-F). The
same was true of an antibody specific for phospho-MAP kinase kinase
3/6, the upstream activator of the p38 MAP kinase family (data not
shown). The observed staining did not result from a cross-reaction with
hyperphosphorylated tau, because the phosphorylation-dependent protein
kinase antibodies failed to recognize the sarkosyl-insoluble 64 kDa tau
band from brains and spinal cords of transgenic mice (data not shown).
By immunoblotting, the antibody specific for phospho-p38 MAP kinase did
not distinguish between p38/stress-activated protein kinase (SAPK)2a, p38/SAPK2b, p38 /SAPK3, and p38 /SAPK4 (data not
shown). Staining of the prolyl isomerase Pin1 was only observed in a
small minority (<1%) of AT100-positive cells in the cerebral cortex, in which some cytoplasmic granules were immunoreactive (Fig.
11G,H). Pin1 staining was not seen in
other brain regions or in the spinal cord.
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Figure 11.
Staining of activated MAP kinase family members
(in red) and the prolyl isomerase Pin1 (in
red) in cerebral cortex from mice of the human P301S tau
line. Colocalization with hyperphosphorylated tau protein (in
green) is shown. A, Anti-activated MAP
kinase; C, anti-phospho-JNK; E,
anti-phospho-p38; G, anti-Pin1. B,
Staining with anti-tau antibody BR134 of the tissue section shown in
A. D, F, Staining with
anti-tau antibody PHF1 of the tissue sections shown in C
and E. H, Staining with anti-tau antibody
AT100 of the tissue section shown in G. Scale bars:
A, 15 µm (for A-F);
G, 15 µm (for G,
H).
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| |
DISCUSSION |
We describe a transgenic mouse line that expresses in nerve cells
four-repeat human tau protein with the P301S mutation. At 5-6 months
of age, homozygous animals developed a neurological phenotype dominated
by a severe paraparesis. By light microscopy, nerve cells in the brain
and spinal cord were strongly immunoreactive for hyperphosphorylated
human tau but not for mouse tau. Many nerve cells were also strongly
silver positive and weakly fluorescent for thioflavin S. The largest
number of tau-positive nerve cells was present in the brainstem and
spinal cord. Numerous positive cells were also observed in other brain
regions, including the cerebral cortex and hippocampus.
By electron microscopy on tissue sections, abundant filaments made of
hyperphosphorylated tau protein were detected throughout the brain and
in the spinal cord. The majority of filaments resembled the
half-twisted ribbons described previously in some cases of FTDP-17
(Spillantini et al., 1998b; Mirra et al., 1999; Rizzini et al., 2000;
Neumann et al., 2001). A minority of filaments were reminiscent of the
paired helical filaments of Alzheimer's disease. Isolated filaments
were decorated by antibodies directed against the N and C termini of
tau but not by BR135, an antibody specific for the microtubule-binding
repeat region, indicating that the repeat region of tau forms part of
the core of the filaments. Identical findings have been reported
previously for synthetic tau filaments (Goedert et al., 1996) and for
filaments isolated from Alzheimer's disease and FTDP-17 brains
(Goedert et al., 1992a, 1994; Hasegawa et al., 1996; Spillantini et
al., 1997). Isolated filaments from transgenic mouse brain and spinal
cord were made of mutant human tau and decorated by a large number of
phosphorylation-dependent anti-tau antibodies. The one exception was
antibody 12E8, whose epitope lies in the repeat region (Seubert et al.,
1995) and was therefore inaccessible in the intact filaments. Isolated
tau filaments were not decorated by anti-ubiquitin antibodies, which
also failed to stain tissue sections from transgenic mice. This is
consistent with previous findings which demonstrated that the
ubiquitination of tau in Alzheimer's disease occurs after filament
assembly (Goedert et al., 1992a; Morishima-Kawashima et al., 1993).
The morphological findings were mirrored at the biochemical level.
Sarkosyl-insoluble tau from transgenic mouse brain and spinal cord ran
as a hyperphosphorylated 64 kDa band that was labeled by all anti-human
tau antibodies tested, including BR135 and 12E8. However, this band was
not labeled by antibody MT1. In human tauopathies, the 383 aa tau
isoform also runs as a hyperphosphorylated 64 kDa band (Goedert et al.,
1992a; Mulot et al., 1994). The biochemical and morphological
characteristics of sarkosyl-insoluble tau from the transgenic mice were
therefore identical to those observed in human tauopathies. Abundant
tau filaments have also been described in sections of brainstems and
spinal cords from mice transgenic for human P301L tau (Lewis et al.,
2000) but not in other mouse lines transgenic for human tau mutants
(Götz et al., 2001a,b; Lim et al., 2001; Tanemura et al., 2001,
2002). Unlike the present findings, tau inclusions were ubiquitin
positive by light microscopy. The characteristics of isolated tau
filaments were not reported (Lewis et al., 2000).
Perchloric acid-soluble tau from transgenic mouse brain and spinal cord
ran as a broad band of 52-58 kDa that was immunoreactive with all
phosphorylation-dependent anti-tau antibodies, except AT100 and CP3. In
conjunction with our previous work (Probst et al., 2000), this provides
the first demonstration of the existence of a pool of soluble tau
protein phosphorylated at many but not all sites before
filament assembly. It also indicates that immunoreactivity for
phospho-S214 closely mirrors the presence of filaments, suggesting that
phosphorylation of this site occurs after filament assembly. In
transgenic mice, AT100 stained only a subset of the nerve cells that
were immunoreactive with other antibodies, such as T14 or AT8,
indicating that only this subset of nerve cells contained tau filaments.
Neurodegeneration was present in the spinal cord of 6-month-old
transgenic mice, as indicated by a 49% reduction in the number of
motor neurons. Both abnormally enlarged and severely atrophic motor
neurons were observed. In some instances, the latter were surrounded by
glial cells, suggestive of neuronophagia. Moreover, astrocytosis in
spinal cord and denervation atrophy in skeletal muscle were in
evidence. It remains to be determined whether nerve cells were also
lost in the brain. In the spinal cord, tau filament formation thus
correlated with nerve cell death. The same is true of nerve cells in
the human tauopathies (Lee et al., 2001). A similar loss in the number
of motor neurons was also reported in transgenic mice from the human
P301L tau line with filaments (Lewis et al., 2000). In mice transgenic
for wild-type human tau, no tau filaments or nerve cell loss was
observed (Ishihara et al., 1999; Spittaels et al., 1999; Probst et al.,
2000). In contrast, in Drosophila melanogaster expressing
either wild-type or mutant human tau, nerve cell death by apoptosis was
found in the apparent absence of tau filaments (Wittmann et al., 2001;
Jackson et al., 2002).
In the human P301S tau line, no evidence for apoptosis was obtained
when DNA fragmentation and staining for activated caspase-3 and cleaved
-fodrin were studied. This is in contrast to mice transgenic for
human P301L tau, where the presence of terminal deoxynucleotidyl
transferase-mediated biotinylated UTP nick end labeling-positive nerve
cells was reported (Götz et al., 2001a; Ho et al., 2001).
However, the present findings are in line with work on the human
tauopathies, where DNA fragmentation and staining for activated
caspase-3 were not detected (Migheli et al., 1994; Atzori et al., 2001;
Ferrer et al., 2001a).
In human diseases, tau inclusions are known to colocalize with
activated MAP kinase family members, in particular, SAPKs (Hensley et
al., 1999; Perry et al., 1999; Zhu et al., 2000; Atzori et al., 2001;
Ferrer et al., 2001a,b). Similar results were obtained in the human
P301S tau line, where activated MAP kinase, JNK, and p38 colocalized
with hyperphosphorylated tau. The same was not true of other protein
kinases, such as GSK3 and cdk5. MAP kinase and SAPKs phosphorylate tau
at many sites in vitro (Drewes et al., 1992; Goedert et al.,
1992b, 1997; Reynolds et al., 1997), suggesting that they may be
involved in the hyperphosphorylation of tau and that specific
inhibitors of these enzymes (Cohen, 2002) might be therapeutically
beneficial. It remains to be determined whether activation of MAP
kinase and SAPKs precedes the assembly of tau into filaments. Staining
for activated MAP kinase family members was not observed in the
transgenic mouse line ALZ17 (Probst et al., 2000), which expresses
wild-type human tau protein but does not develop abundant tau filaments
(our unpublished observations).
Activation of SAPKs is likely to have additional effects. Both JNK and
p38 have been linked to the induction of apoptosis (Xia et al., 1995),
although their effects are strongly cell and context dependent (Chang
and Karin, 2001). The present findings, together with recent work on
the human tauopathies (Atzori et al., 2001), indicate that in diseases
with a filamentous tau pathology, SAPKs do not activate or regulate an
apoptotic cascade. Like MAP kinase family members, the prolyl isomerase
Pin1 has been reported to colocalize with filamentous tau deposits in
Alzheimer's disease brain (Lu et al., 1999). It was proposed that this
may contribute to nerve cell death through a reduction in the level of
functional Pin1. However, in the mouse line expressing human P301S tau,
Pin1 was only present in a small minority of tau-positive nerve cells in the cerebral cortex, where it localized to cytoplasmic granules.
In conclusion, the transgenic mouse line described here exhibits the
essential features of a human tauopathy, including the formation of
abundant filaments made of hyperphosphorylated tau protein and nerve
cell degeneration. Although in human cases with the P301S mutation in
Tau, both nerve and glial cells in the brain are affected
(Bugiani et al., 1999), in the mouse line, tau deposits are seen only
in nerve cells. The transgenic mice do not exhibit the selective
pattern of nerve cell degeneration characteristic of the human
tauopathy, because they show spinal cord as well as widespread brain
pathology. These differences in selectivity between mouse model and
human disease may have resulted from our use of the murine
thy1 promoter to drive expression of mutant human tau, the
expression of a single isoform of mutant human tau protein on a
wild-type mouse tau background, or a different neuronal vulnerability
to mutant human tau in mice and humans. This notwithstanding, the mouse
line expressing human P301S tau will be of great value for a better
understanding of the molecular mechanisms by which mutant tau protein
causes the dysfunction and death of nerve cells. It may for instance
help to establish whether hyperphosphorylation of tau leads to filament
assembly and whether the accumulation of tau filaments results in the
demise of nerve cells. This may in turn lead to the design of new
therapeutic strategies aimed at preventing tau dysfunction.
| |
FOOTNOTES |
Received June 14, 2002; revised Aug. 22, 2002; accepted Aug. 27, 2002.
*
B.A., E.I., and M.T. contributed equally to this work.
This work was supported by the United Kingdom Alzheimer's Research
Trust, the United Kingdom Medical Research Council, and United States
Public Health Service Grants P30 AG10133 and R01 NS14426. We thank C. Alyea, R. Richardson, and B. Dupree for technical help and Drs. S. Hiu
and A. Perkins for statistical assistance.
Correspondence should be addressed to Dr. Michel Goedert, Medical
Research Council Laboratory of Molecular Biology, Hills Road, Cambridge
CB2 2QH, United Kingdom. E-mail: mg{at}mrc-lmb.cam.ac.uk.
| |
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Down-regulation of WW Domain-containing Oxidoreductase Induces Tau Phosphorylation in Vitro: A POTENTIAL ROLE IN ALZHEIMER'S DISEASE
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F. Chen, M. A. Wollmer, F. Hoerndli, G. Munch, B. Kuhla, E. I. Rogaev, M. Tsolaki, A. Papassotiropoulos, and J. Gotz
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[Abstract]
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J. AVILA, J. J. LUCAS, M. PEREZ, and F. HERNANDEZ
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P. K. Krishnamurthy and G. V. W. Johnson
Mutant (R406W) Human Tau Is Hyperphosphorylated and Does Not Efficiently Bind Microtubules in a Neuronal Cortical Cell Model
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[Abstract]
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M. Goedert
Neurodegenerative tauopathy in the worm
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TOP
ABSTRACT
INTRODUCTION
