Upload
others
View
9
Download
0
Embed Size (px)
Citation preview
1
Impulsivity, decreased social exploration, and executive
dysfunction in a mouse model of frontotemporal dementia
Ann van der Jeugd1,2, Ben Vermaercke2, Glenda M. Halliday3, Matthias Staufenbiel4,
and Jürgen Götz1,*
1Clem Jones Centre for Ageing Dementia Research (CJCADR), Queensland Brain
Institute (QBI), University of Queensland, St Lucia Campus (Brisbane), QLD 4072,
Australia; 2Laboratory of Biological Psychology, Brain and Cognition, University of
Leuven, 3000 Leuven, Belgium; 3Neuroscience Research Australia, Barker Street,
Randwick, NSW 2031, Australia; 4German Centre for Neurodegenerative Diseases
(DZNE), Hertie Institute for Clinical Brain Research, University of Tübingen, D-
72076 Tübingen, Germany
*Author for correspondence: Tel: +61-7-334.66329; Fax: +61 7 3346 6301; Email:
Abstract
Frontotemporal lobar degeneration (FTLD) is a neurodegenerative disorder, a major
subset of which is characterized by the accumulation of abnormal forms of the protein
tau, leading to impairments in motor functions as well as language and behavioral
alterations. Tau58-2/B mice express human tau with the P301S mutation found in
familial forms of FTLD in neurons. By assessing three age cohorts of Tau58-2/B mice
in a comprehensive behavioral test battery, we found that the tauopathy animals
showed age-dependent signs of impulsivity, decreased social exploration and
executive dysfunction. The deficit in executive function was first limited to decreased
spatial working memory, but with aging this was extended to impaired instrumental
short-term memory. Tau pathology was prominent in brain regions underlying these
behaviors. Thus, Tau-58-2/B mice recapitulate neurological deficits of the behavioral
variant of frontotemporal dementia (bvFTD), presenting them as a suitable model to
test therapeutic interventions for the amelioration of this variant.
2
Keywords: Behavior; executive function; frontotemporal dementia; frontotemporal
lobar degeneration; social exploration; tau
Highlights
• Tau58-2/B mice present with a tau pathology in cortical areas implicated in
bvFTD.
• Tau58-2/B mice exhibit motor and sensory gating anomalies at an early age.
• With aging the mice show decreased sociability but no altered exploration.
• The mice further display increased risk-taking behaviors and executive
deficits.
• First limited to spatial working memory, it later extends to instrumental
memory.
1. Introduction
Frontotemporal lobar degeneration (FTLD) is a form of dementia that is characterized
by atrophy of the frontal and temporal lobes and deposition of the microtubule-
associated protein tau (Galimberti and Scarpini, 2010; Rademakers et al., 2012;
Sieben et al., 2012). Under physiological conditions, tau is mainly localized to the
axon of mature neurons where it binds to and stabilizes microtubules; however, tau
has also been found in the dendritic compartment where the protein has a role in
targeting the kinase Fyn to the dendritic spines (Ittner et al., 2010). Under
pathological conditions such as FTLD, tau becomes hyperphosphorylated and forms
filaments that eventually form microscopic lesions known as neurofibrillary tangles
(NFTs) (Ittner et al., 2015). FTLD has been difficult to diagnose due to the
heterogeneity of the associated symptoms, which affect behavior, language and
cognition (Bigio, 2013; Mendez, 2004; Seltman and Matthews, 2012).
Frontotemporal dementia (FTD) as the clinical presentation of FTLD is the
second most common type of presenile dementia and the fourth most common type of
senile dementia, although it is among the more costly due to its symptom
characteristics (Neary et al., 2005; Seltman and Matthews, 2012). Clinically, FTD is
divided into three subtypes: a behavioral variant (bvFTD) that affects social skills,
3
emotions, personal conduct, and self-awareness, semantic dementia that compromises
language comprehension, and motor variants leading to muscle wasting (Hodges et
al., 2004). BvFTD presents with changes in social behavior and conduct, such as loss
of social awareness and social withdrawal, restlessness and poor impulse control
leading to compulsive behaviors including stereotyped hair-pulling and skin picking
(Eslinger, Moore, Anderson, & Grossman, 2011; Lindau et al. 2000; Mendez &
Perryman, 2002; Pressman & Miller, 2014; Snowden et al., 2001, 2003). At later
stages, FTD patients develop deficits in executive function: they have problems
planning, coordinating and executing simple tasks (Harciarek and Cosentino, 2013;
Huey et al., 2009; Johns et al., 2009; Moy et al., 2004; Stopford et al., 2012). In
addition to the characteristic behavioral changes, the clinical features of FTD can be
complicated by neurological signs, such as motor neuron signs, parkinsonism,
and gait disturbances, with some patients developing motor problems resulting from
motor neuron pathology (Devenney et al., 2015; Merrilees et al., 2010).
To elucidate the contribution of hyperphosphorylated tau pathology to the
behavioral manifestations and cognitive deficits observed in FTD, we analyzed the
tau expression pattern and studied the effects of tau overexpression by subjecting
P301S tau transgenic Tau58-2/B (Tg) mice to a behavioral test battery probing for
signs and symptoms relevant for FTD. We analyzed Tau58-2/B mice of three age
groups to investigate whether with progressive tau accumulation this would be
associated with more pronounced behavioral changes. We found that this
murine model is histologically characterized by progressive deposition of
hyperphosphorylated forms of tau in neurons. In addition, we found deficits in
behaviors modeling the symptoms of bvFTD, including increased impulsivity and
risk-taking behaviors, decreased social interest, and executive dysfunction. The
distinctive behavioral phenotype was augmented with advanced age, reflecting the
age-dependent tauopathy that characterizes the Tau58-2/B mice. Together, this set of
FTD-like phenotypic traits and a distinct brain pathology renders the Tau58-2/B strain
a suitable model for bvFTD, with the prospect of determining whether therapeutic
interventions also ameliorate the phenotype that characterizes the behavioral variant
of FTD.
2. Materials and methods
4
2.1. Mouse models. Tau58-2/B mice (Tg) express the human 0N4R tau isoform
together with the P301S mutation under control of a murine Thy1.2 promoter on a
C75Bl/6 background (Tau58, Novartis Institutes for Biomedical Research, Basel,
Switzerland). Mice from the Novartis colony were separately shipped to Australia to
establish independent colonies. One colony was mainly analyzed histologically (van
Eersel et al., 2015). We established a separate colony by continued breeding of Tau58
onto a C57BL/6 background, generating Tau58-2/B mice. Non-transgenic littermates
(wild-type, Wt) were included as controls.
2.2. Experimental design. For behavior, mice were divided into the following age
groups: 2-3 months, 6-7 months, and 10-11 months. Animals were housed in groups
of 2–5 animals per cage. They were kept on a 12 h light/dark cycle (light on at
8:00 AM, with testing during the light period) with free access to food and water
unless otherwise stated. For behavioral experiments, the Tau58-2/B mice were
directly compared with Wt littermates (5 males and 5 females per genotype per age-
group), and tested cross-sectionally using the following experimental sequence:
SHIRPA screen, open field, social exploration, light/dark box, Y-maze, and puzzle-
box (Supplementary Table 1, Supplementary Table 2). For histological studies (n=3
per age group), the 6-7 month group was used after the behavioral data had been
obtained (by then 7-8 months old) and the 10-11 month group after the behavioral
data had been obtained (by then 11-12 months old). A separate batch of 16 months
old Tau58-2/B mice was included for histology. All animal experiments were
approved by the Animal Ethics Committees of the University of Queensland and all
procedures complied with the statement on animal experimentation issued by the
National Health and Medical Research Council of Australia.
2.3. Histology. Animals were anesthetized, perfused, and brains removed and post-
fixed in 4% paraformaldehyde at 4 °C overnight, dehydrated, and then embedded in
paraffin. Seven µm-thick brain sections were cut with a microtome in the frontal or
sagittal plane and mounted on silane-coated slides. Brains of 7-8, 11-12, and 16
month-old Tau58-2/B mice were analyzed for the presence of pathological tau species
(Xia et al., 2015) (Fig 1). The following anti-tau antibodies were used: pSer235
(1:500, Thermo Scientific), pSer422 (1:500, Thermo Scientific), AT8
5
(pSer202/pThr205 Tau, 1:500, Thermo Scientific), AT100 (pThr212/pSer214 Tau,
1:500, Thermo Scientific), AT180 (pThr231/pThr235 Tau, 1:500, Thermo Scientific),
and HT7 (pan Tau, 1:500, Thermo Scientific), which recognizes total tau.
Bielschowsky silver staining was employed to reveal NFTs (Ke et al., 2009).
2.4. Murine neurobehavioral screen and motor abilities. A comprehensive
modified SHIRPA screen (Rafael et al., 2000; Rogers et al., 1997) was performed.
Using this test battery, physical characteristics, sensory reactions and reflexes, as well
as motor abilities were investigated (for a complete checklist and photos of the setups
used see Supplementary Data). The collected physical characteristics included the
body weight and general appearance. Next, mouse behavior was observed which
included transfer behavior, spontaneous activity, and the occurrence of tremors,
palpebral closure and gait (Supplementary Fig 1). Subsequently, reactions to simple
stimuli such as touch escape, trunk curl, and the reaching reflex, Preyer reflex, and the
toe pinch reflex were assessed. Finally, basic motor abilities were measured using the
grip strength, wire hanging and accelerating Rotarod tests.
2.5. Exploratory behavior, sociability and anxiety. General exploration and social
exploration (Callaerts-Vegh et al., 2012; Crawley, 1985) were examined using a 30 ×
30 cm2 square arena of Plexiglas. Animals were placed in the experimental room
30 min before the test started. They were then placed individually in the arena (600
lux) for 10 min, where their movement was recorded using EthoVision video tracking
equipment and software (Noldus, Wageningen, The Netherlands). Total distance
traveled and velocity were included as measures of locomotor activity. Time spent
exploring the center (within an imaginary inner square of 20 x 20 cm) and the corners,
and the number of visits to the center and corners were recorded as a measure of
anxiety-like behaviors. In addition, heat maps were generated using a custom-made
program to examine anxiety and thigmotaxis (wall-hugging behavior) (Van Der Jeugd
et al., 2013).
For the assessment of sociability, the open field arena contained a cage with a
diameter of 10 cm and a height of 20 cm holding an unfamiliar mouse of the same
gender. Again, total distance traveled and velocity were included as measures of
locomotor activity. The time exploring the stranger mouse (within an imaginary
6
annulus of 5 cm around the cage containing the mouse), and the number of visits to
the center of the arena was recorded as a measure of social exploration.
2.6. Anxiety, impulsivity and risk-taking behaviors. The light/dark box arena
consisted of a Plexiglas box divided by a small underpass into two compartments: a
larger brightly lit zone (58 cm long, 28 cm wide, 750 lux) and a smaller covered dark
zone (15 cm long, 28 cm wide) (Crawley, 1985; Tasan et al., 2009). Prior to the test,
animals were habituated to the dark for 30 min. They were then placed in the dark
chamber of the apparatus facing away from the door and tracked for 5 min using
EthoVision software (Noldus). The latency to the first entry into the light, the time
spent in the illuminated area, and the number of transitions were recorded as
indications of impulsivity and anxiety. In order to assess risk-taking behaviors in
more detail (Baeta-Corral and Giménez-Llort, 2014; Varty et al., 2002), the frequency
of stretch-attendance postures (with the animal stretching forward into the underpass
and then retracting to its original position) was also monitored.
2.7. Executive function. Spatial working memory was tested with the spontaneous
alternation behavior (SAB) paradigm (Hughes, 2004; Lalonde, 2002; Naert et al.,
2013). Testing occurred in a Y-shaped maze with three white, transparent plastic arms
arranged at 120° angles (9 cm wide, 40 cm long arms, 30 cm deep). The mouse was
placed in the start arm of the Y-maze and allowed to freely explore the three arms in a
5 min trial (extra maze cues were present on the walls). The number of arm entries
and the number of triads were recorded in order to calculate the percentage of SAB.
An entry occurred when all four limbs were within the arm.
To assess problem solving capacities and short-term memory (STM), the mice
were subjected to the puzzle box (Ben Abdallah et al., 2011; Galsworthy et al., 2005).
The arena consisted of a Plexiglas box divided into two compartments by a small
underpass: a larger brightly lit zone, the start box (58 cm long, 28 cm wide, 750 lux)
and a smaller covered dark zone, the goal box (15 cm long, 28 cm wide). Mice
underwent a total of six trials over two consecutive days, with three trials per day: the
day started with a training session followed by two puzzle sessions (on day 1 these
were two dig trials, and on day 2 two plug trials). Mice were deprived of food two
days prior to the test (while their body weight was maintained at approximately 85%
of its initial weight), and food pellets were presented in the goal box. On training
7
trials, mice were introduced into the start zone, and taught to move into the goal zone
through a narrow underpass (~ 4 cm wide) separating the two compartments. For the
burrowing trials, the underpass was filled with sawdust and the mice had to dig their
way through. For the plug trials, a square, cotton plug that mice had to pull with their
paws to enter the goal zone obstructed the underpass. Time to enter the goal box was
measured (with a cut-off of 3 min, thus a 180 s penalty was given when the animal
did not solve the puzzle).
2.8. Statistics. ANOVA was used to determine genotype, and gender and interaction
effects between the three age groups. All data are represented as means (± SEM), and
p < 0.05 was considered statistically significant (* for differences between genotypes,
# for differences between gender).
3. Results
3.1. Tau transgenic Tau58-2/B mice present with a widespread, progressive
tauopathy
In tauopathy, progressive hyperphosphorylation of tau, in particular at pathologic
epitopes, occurs as disease progresses, concomitant with NFT formation. To
determine the progression of tau pathology in Tau58-2/B mice, the mice were
histologically analyzed with a set of phospho-tau-specific antibodies (pS235, pS422,
AT8, AT100, and AT180) as well as human tau-specific antibody HT7 (Fig 1A-E). At
8 months of age, Tau58-2/B mice display subtle deposition of hyper-phosphorylated
tau mainly in the CA1 region of the hippocampus and the cortex (Table 1). With age,
the mice developed a more pronounced tau pathology, with hyperphosphorylated tau
being found in the cortex, hippocampus, and cerebellum as shown for 12 months of
age. As the mice aged even further, histological analysis revealed NFT deposits;
Bielschowsky silver staining of sagittal sections demonstrated stained NFT-like
structures and neuronal cell bodies in the hippocampus, throughout the whole frontal
cortex including the anterior cingulate cortex and orbitofrontal cortex, and in the
cerebellum and brainstem (Fig 1B'-E').
3.2. Higher arousal and reduced neuromotor abilities in Tau58-2/B mice
8
Assessing the physical characteristics of the mice we found that the Tg mice had a
lower body weight than age-matched Wt mice, at all ages tested (three categories: 2-3
months (F1,19=13.71, p = 0.003), 6-7 months (F1,19=39.98, p = 0), and 10-11 months
(F1,19=21.21, p = 0.001)) (Table 2). Evaluating the existence of whiskers we did not
find a difference between Tg and Wt animals. However, when assessing the
constitution of the fur this showed that the 10-11 month-old Tg mice had more bald
patches and wounds than their Wt littermates, which was not seen for the two younger
age groups (10-11 months: F1,19=48.52, p < 0.001). When observing the mice for
habituation of activity in a new environment, Tg mice were indistinguishable from Wt
age-controls. However, we noted some tremors and a less fluid gait in 6-7 and 10-11
month-old Tg mice compared to age-matched Wt mice (tremor: 6-7 months:
F1,19=7.33, p = 0.02; 10-11 months: F1,19=25.96, p < 0.001; gait: 10-11 months:
F1,19=5.15, p = 0.038).
In terms of sensorimotor reflexes, we found no difference in visual acuity by
reaching reflex, or nociceptive sensation as measured by toe pinch and trunk curl.
However, when evaluating the acoustic acuity we found that this elicited a stronger
flinch response to the sound in 6-7 and 10-11 month-old Tg mice as compared to their
respective age-matched Wt controls (6-7 months: F1,19=41.25, p < 0.001; 10-11
months: F1,19=27.40, p < 0.001). When evaluating Tg mice for the touch escape
response, we also found a higher response in 10-11 month-old Tg mice (10-11
months: F1,19=5.15, p = 0.038). Finally, assessing the motor abilities of the mice, we
found that 10-11 month-old Tg mice were impaired in muscular grip strength
(maximal grip: 10-11 months: F1,19=31.67, p < 0.001; mean grip: 10-11 months:
F1,19=108.07, p < 0.001). Also, in the wire hang test, aged Tg mice fell off faster than
Wt mice (6-7 months;: F1,19=6.74, p = 0.025; 10-11 months: F1,19=39.62, p < 0.001).
Finally, in the accelerating Rotarod test, a similar outcome was observed (maximal
latency on the rod: 6-7 months: F1,19 = 21.21, p = 0.001; 10-11 months: F1,19=28.10, p
< 0.001; - mean latency on the rod: 6-7 months: F1,19=26.1, p < 0.001; 10-11 months:
F1,19=37.11, p < 0.001). When investigating the main effect of gender (Supplementary
Results), differences were observed for weight: at all ages males weighed more than
females, irrespective of their genotype. However, in Tg male mice we observed more
tremors, bald patches and wounds compared to their female Tg and male Wt controls.
Also, in the grip test, both Wt and Tg males outperformed females as measured by
9
maximum and mean pulling force. Overall, Tau58-2/B mice presented with an overall
increase in nervous behavior and arousal at young ages, neuromotor deficits at adult
ages, and a lower body weight at all ages.
3.3. Tauopathy mice show no alterations in general exploratory behavior or
anxiety
To examine general exploratory behavior and anxiety, mice were observed in the
open field test. Total path length and velocity were included as measures of locomotor
activity; however, no changes in velocity or overall distance traveled were found
between the genotypes at any of the ages tested (Fig 2A). Time spent in the center and
corners were recorded as a measure of anxiety, and were found to be unaltered
between genotypes at all ages examined (Fig 2B). Numbers of center and corner visits
were unaltered; this was also confirmed by displaying the data in heat plots (Fig 2C).
No gender differences were found in this test. As indicated above, these findings
showed no differences in locomotor activity because the overall spontaneous
locomotion and general motor activity was not altered between the genotypes, nor
was there any evidence for an anxiolytic or anxiogenic profile in the Tau58-2/B mice.
3.4. Tauopathy mice have deficits in social exploration
The social exploration test is used to study social interactions in mice. No change in
total distance travelled or velocity was found in Tg compared to Wt mice at any age
tested (Fig 3A). The time spent in the center of the field (within an imaginary annulus
of 5 cm around the cage containing the stranger mouse) was recorded as a measure of
social exploration. Interestingly, decreased exploration of stranger mice in 6-7 and 10-
11 month-old Tg mice was observed compared to Wt littermates (6-7 months: F1,19 =
12.19, p = 0.006; 10-11 months: F1,19=4.70, p = 0.047) (Fig 3B). This was confirmed
by the number of entries into the center of the arena which differed between
genotypes: Tg mice visited the center with the stranger mouse less frequently than Wt
mice (6-7 months: F1,19 = 14.63, p = 0.03; 10-11 months: F1,19=14.70, p = 0.037) (data
not shown). Heat plots verified that there were fewer activity hot spots near the cage
containing the stranger mouse in Tg mice from 6 months onwards (Fig 3C). No
gender differences were found in this test. Thus, importantly, although Tg mice did
10
not show altered overall exploration levels per se, they were more reluctant to explore
another mouse.
3.5. Increased impulsivity and risk-taking behaviors in tauopathy mice
The light/dark box is used in the assessment of anxiety and risk-taking behaviors. The
latency to the first entry into the light and the time spent in each of the two
compartments was assessed to measure impulsivity and anxiety. We found that Tg
mice spent more time in the illuminated area than Wt mice at all ages (2-3 months:
F1,19=7.34; p = 0.019; 6-7 months: F1,19 = 11.11, p = 0.007; 10-11 months: F1,19=16, p
= 0.0001) (Fig 4A). Moreover, we found Tg mice to emerge faster from the
illuminated area than Wt mice (2-3 months: F1,19=14.09, p = 0.003; 10-11 months:
F1,19=5.06, p = 0.032) (Fig 4B). We found a gender main effect in the latency to enter
the illuminated area at 6-7 months (F1,19 = 5.024, p = 0.041), with females entering the
illuminated area faster than males. There was no difference in the number of
transitions between the dark and light compartments between the groups (data not
shown). Furthermore, we found fewer stretch-attend postures in Tg mice at 6-7 and
10-11 months compared to their age-matched Wt littermates (6-7 months: F1,19 = 9.73,
p = 0.01; 10-11 months: F1,19=17.64, p = 0.001) (Fig 4C). Hence, one may conclude
that the Tg mice act more impulsively and erratically.
3.6. Tauopathy mice have deficits in executive function
To assess executive function we first subjected the mice first to the Y-maze that
measures spatial working memory. We found that total entries into the Y-maze arms
did not differ between Tg and Wt mice, at any of the ages tested (data not shown).
However, the percentage of SAB was significantly different between the genotypes,
with Tg mice making fewer alternations compared to age-matched Wt mice, with an
interaction effect for gender at 6-7 months (main genotype effect: F1,19 = 15.63, p =
0.002; genotype x gender interaction effect: F1,19 = 6.82, p = 0.024), and at 10-11
months (main genotype effect: F1,19 = 53.39, p < 0.001; genotype x gender interaction
effect: F1,19 = 5.602, p = 0.032) (Fig 5A). Heat plots verified this lack of SAB in the
Tg mice (Fig 5B). Next, in the puzzle box paradigm, mice were presented with
several puzzles of increasing difficulty. In the first phase, a simple emergence test
11
from the brightly lit arena into the dark goal box, none of the mice were impaired
(data not shown). However, in the second phase, that required the mice to dig their
way to reach the goal box, Tg mice failed the test from 10 months onwards (F1,19 =
16.446, p = 0.001) (Fig 5C). Moreover, on the next day thus requiring intact STM,
both the 6-7 and 10-11 month-old Tg mice were found to be impaired (6-7 months:
F1,19 = 12.46, p = 0.005; 10-11 months: F1,19 = 30.44, p < 0.01) (Fig 5D). No gender or
genders x genotype interaction effects were found in this test. In conclusion, the Tg
mice display specific executive function deficits as shown by working and STM
impairments.
4. Discussion
Various aspects of tauopathy have been modeled in mice, but the behavioral aspects
that specifically characterize FTD have been less explored. In our study we found that
the P301S human tau transgenic Tau58-2/B strain displays a bvFTD-like phenotype.
Specifically, we found that this murine model is characterized by the deposition of
hyperphosphorylated forms of tau in neurons in frontal and temporal brain areas, and
presents with consistent deficits in behaviors resembling the symptoms of bvFTD,
including decreased social behavior, impulsivity and increased risk-taking behaviors
and impairments in executive function.
Previous studies have shown that motor performance is impaired in Tau58-2/B
mice as assessed in the Rotarod, beam and horizontal pole tests (van Eersel et al.,
2015). In the present study, we were able to replicate the progressive genotype-linked
differences in the Rotarod (however at half the speed in our study), wire hang and
grip strength tests, but now add to this a more comprehensive behavioral analysis,
addressing aspects of FTD-like behaviors. For instance, we found that Tau58-2/B
animals had tremors and displayed a less fluid gait. Indeed, in FTD patients,
extrapyramidal symptoms including akinesia, Parkinsonian gait and resting tremor
have been reported (Diehl-Schmid et al., 2007). Upon inspection of the cerebellum
and brainstem, regions known to contribute to motor problems, we found tau
pathology in the older Tg mice.
Moreover, we found evidence for increased arousal and reactivity to sensory
stimuli, an aspect of sensory gating that is observed in individuals with FTD and
Alzheimer's disease (Gibbons et al., 2008; Grunwald et al., 2003; Knight et al., 1999;
12
Landqvist Waldö et al., 2014; Perriol et al., 2005; Takeuchi et al., 2011). In our study,
we observed that Tau58-2/B mice were more sensitive to an unexpected stimulus, as
measured by a higher startle response in the Preyer reflex and touch escape assay. In
two related P301S murine models it had been discovered that prepulse inhibition
(PPI), another marker of sensorimotor gating, is altered (Koppel et al., 2014;
Takeuchi et al., 2011). However, we were prevented from performing a PPI assay
with our mice because of the motor weakness that characterizes the aged Tg animals.
Sensory gating is highly dependent on the prefrontal cortex (Chao and Knight, 1995;
Knight et al., 1999), a brain area for which we found massive immuno-reactivity for
hyperphosphorylated tau using a series of epitope-specific antibodies, and NFTs as
visualized with Bielschowsky.
Impairment of social interactions, including social withdrawal, loss of
empathy and social misconduct, is one of the core characteristics of FTD (Eslinger et
al., 2011; Hodges, 2013; Passant et al.; Rankin et al., 2005; Savage et al., 2014). We
found that Tau58-2/B animals spend a significantly shorter amount of time with a
stranger mouse than Wt mice. This is in accordance with other studies that found
deficits in social interactions in mouse models resembling clinical FTD, such as in
progranulin-deficient, and senescence-accelerated-prone (SAMP) mice (Filiano et al.,
2013; Meeker et al., 2013; Takeuchi et al., 2011; Yin et al., 2010). It has been
reported that orbitofrontal dysfunction is related to both apathy and disinhibition in
FTD patients (Peters et al., 2006). In accordance with this we noted increased tau
immuno-reactivity and NFT formation by silver staining in 12 month-old Tg animals.
It is noteworthy that with the open field test we did not find evidence for an
altered general exploration in our tau transgenic model. As the exploration of a
stranger mouse is performed in the same arena as the open field test, we conclude that
the decrease in sociability we see in the Tg mice is restricted to exploration of a
stimulus animal.
Our results revealed that in the light/dark box, the Tg mice spent more time in
the illuminated compartment than their age-matched Wt counterparts. This is in
contrast to the findings of the open field test where the Tg mice spent an equal
amount of time in the center and corners compared to the Wt mice. Moreover, when
we assessed marble burying in the mice, we found that Tg mice bury roughly the
same number of marbles within a 30 min period as their age-matched Wt littermates
(data not shown). The marble burying task can be used as an indicator of both
13
obsessive compulsive-like behavior and anxiety-like behavior; however, the neuronal
circuitry of this behavior has not been clearly elucidated (Njung’e and Handley,
1991). For some tau transgenic strains, it has been shown that the mice can be
anxiolytic and/or thigmotactic correlating with a pathology in the amygdala (Baeta-
Corral and Giménez-Llort, 2014; Egashira et al., 2005; Sterniczuk et al., 2010; Van
der Jeugd et al., 2013). Incidentally, obtaining coronal sections, we also found a
prominent accumulation of tau in the amygdala of the Tau58-2/B mice (data not
shown).
Interestingly, our Tg mice emerged faster into the illuminated area than their
Wt littermates after being habituated to the dark half an hour prior to the test. This
could indicate increased (motor) impulsivity and behavioral disinhibition in the Tg
mice. More evidence for impulsivity comes from the increase in risk-taking behavior
that was observed in our Tg animals by decreased stretch-attendance postures in a
fearful situation. In individuals with FTD, cases of pathological stealing, an
excessive gambling or alcohol consumption have been reported (Cruz et al., 2008;
Grochmal-Bach et al., 2009; Manes et al., 2010; Mendez, 2011; Pompanin et al.). All
of these violations can be regarded as disinhibitory deficits, which are pathologically
related to impairments in specific prefrontal cortex regions. For instance, the
ventromedial prefrontal cortex is associated with emotion regulation, the anterior
cingulate cortex with emotional empathy, and the orbitofrontal cortex with
compulsive behavior (Knutson et al., 2015; Mendez, 2010; Starkstein and Robinson,
1997). Related to this, we observed bald patches and in some cases even skin wounds
in 75% of the Tau58-2/B male animals, but only in one Wt mouse. This could be due
to excessive barbering, an abnormal repetitive behavior, which is analogous to human
compulsive hair pulling and skin picking, as commonly observed in FTD patients
(Pompanin et al., 2014). To rule out the possible effect of hetero-barbering or
aggression, in a future study repetitive self-grooming and aggression could be
examined separately. Increased aggression could also be explained by the higher
arousal in male Tg mice as observed by the touch escape and Preyer reflex. In later
stages of the disease, a decline in executive function is often seen in FTD patients
(Eslinger et al., 2011; Harciarek and Cosentino, 2013; Huey et al., 2009; Johns et al.,
2009; Seltman and Matthews, 2012; Shea et al., 2014). To evaluate executive
function, the animals were first subjected to the Y-maze test, which depends on their
intrinsic motivation to explore a novel environment. Notably, our 6-7 and 10-11
14
month-old Tg mice showed a working memory deficit in the Y-maze. In rodents, it
has been shown that the prefrontal cortex and hippocampus are engaged in this spatial
working memory task (Dillon et al., 2008; Naert et al., 2013; Reisel et al., 2002).
Moreover, mice were subjected to several problem-solving tasks requiring not only
intact spatial STM but also an instrumental response. The sequence over two days
(day 1 consisting of two dig trials, day 2 two plug trials) allowed assessing STM for
species-specific instrumental responses (Cowan, 2008). We found that only the 10-11
month-old Tg mice performed worse than their Wt counterparts on the dig trials on
day 1. However, when tested the next day on the plug trials, now also the 6-7 month-
old Tg mice failed, thus suggesting an STM deficit at this age. In support, staining of
brain sections with a panel of antibodies revealed hyperphosphorylated tau species
and NFTs in the hippocampus and prefrontal cortex in the Tg mice.
In FTLD, tau is abnormally phosphorylated, forming fibrillar aggregates that
can be visualized with silver impregnation methods as NFTs. In our Tau58-2/B mice,
we found evidence for progressive tau pathology leading to NFTs, including
phosphorylation of pathological epitopes in brain areas relevant for FTLD.
Bielschowsky silver staining confirmed the presence of NFTs - this was in accordance
with another recently published study using Tau58 mice (van Eersel et al., 2015).
In conclusion, we assessed the behavior of three age groups of Tau58-2/B
mice with a progressive tau hyperphosphorylation in frontal and temporal regions,
focusing on evaluating FTD signs and symptoms. We found that aged Tau58-2/B
mice mimic the three core characteristics of FTD: increased impulsivity and risk-
taking behavior, impairment of social interactions as shown by decreased social
exploration time, and mental rigidity as revealed by poorer working memory and an
inability to resolve problem solving tasks. This finding presents Tau58-2/B mice as a
model to validate therapeutic interventions to ameliorate the behavioral symptoms of
FTD.
Acknowledgements
This study was supported by the Estate of Dr Clem Jones AO, as well as grants from
the Australian Research Council (ARC) [DP130101932] the National Health and
Medical Research Council of Australia (NHMRC) [APP1037746, APP1003150] and
an ARC LIEF grant [LE100100074] to JG. AVdJ and BV are both supported by a
15
FWO postdoctoral fellowship. We thank Linda Cumner, Tishila Palliyaguru, Trish
Hitchcock, and the animal care team for animal maintenance, Gerhard Leinenga and
Dr. Daniel Blackmore for advice regarding the experimental setup, Dr. Robert
Sullivan for histological preparations, Matthew Pelekanos for help with histology,
Luke Hammond for help with imaging, and Rowan Tweedale for reading of the
manuscript.
Appendix A. Supplementary data
Supplementary data to this article can be found online.
16
References
Baeta-Corral, R., Giménez-Llort, L., 2014. Bizarre behaviors and risk assessment in
3xTg-AD mice at early stages of the disease. Behavioural brain research 258,
97–105. doi:10.1016/j.bbr.2013.10.017
Ben Abdallah, N.M.-B., Fuss, J., Trusel, M., Galsworthy, M.J., Bobsin, K., Colacicco,
G., Deacon, R.M.J., Riva, M.A., Kellendonk, C., Sprengel, R., Lipp, H.-P., Gass,
P., 2011. The puzzle box as a simple and efficient behavioral test for exploring
impairments of general cognition and executive functions in mouse models of
schizophrenia. Experimental neurology 227, 42–52.
doi:10.1016/j.expneurol.2010.09.008
Bigio, E.H., 2013. Making the diagnosis of frontotemporal lobar degeneration.
Archives of pathology & laboratory medicine 137, 314–25.
doi:10.5858/arpa.2012-0075-RA
Callaerts-Vegh, Z., Leo, S., Vermaercke, B., Meert, T., D’Hooge, R., 2012. LPA(5)
receptor plays a role in pain sensitivity, emotional exploration and reversal
learning. Genes, brain, and behavior 11, 1009–19. doi:10.1111/j.1601-
183X.2012.00840.x
Chao, L.L., Knight, R.T., 1995. Human prefrontal lesions increase distractibility to
irrelevant sensory inputs. Neuroreport 6, 1605–10.
Cowan, N., 2008. What are the differences between long-term, short-term, and
working memory? Progress in brain research 169, 323–38. doi:10.1016/S0079-
6123(07)00020-9
Crawley, J.N., 1985. Exploratory behavior models of anxiety in mice. Neuroscience
and biobehavioral reviews 9, 37–44.
Cruz, M., Marinho, V., Fontenelle, L.F., Engelhardt, E., Laks, J., 2008. Topiramate
may modulate alcohol abuse but not other compulsive behaviors in
frontotemporal dementia: case report. Cognitive and behavioral neurology :
official journal of the Society for Behavioral and Cognitive Neurology 21, 104–
6. doi:10.1097/WNN.0b013e31816bdf73
Devenney, E., Vucic, S., Hodges, J.R., Kiernan, M.C., 2015. Motor neuron disease-
frontotemporal dementia: a clinical continuum. Expert review of
neurotherapeutics 15, 1–14. doi:10.1586/14737175.2015.1034108
17
Diehl-Schmid, J., Schūlte-Overberg, J., Hartmann, J., Förstl, H., Kurz, A.,
Häussermann, P., 2007. Extrapyramidal signs, primitive reflexes and
incontinence in fronto-temporal dementia. European journal of neurology : the
official journal of the European Federation of Neurological Societies 14, 860–4.
doi:10.1111/j.1468-1331.2007.01773.x
Dillon, G.M., Qu, X., Marcus, J.N., Dodart, J.-C., 2008. Excitotoxic lesions restricted
to the dorsal CA1 field of the hippocampus impair spatial memory and extinction
learning in C57BL/6 mice. Neurobiology of learning and memory 90, 426–33.
doi:10.1016/j.nlm.2008.05.008
Egashira, N., Iwasaki, K., Takashima, A., Watanabe, T., Kawabe, H., Matsuda, T.,
Mishima, K., Chidori, S., Nishimura, R., Fujiwara, M., 2005. Altered depression-
related behavior and neurochemical changes in serotonergic neurons in mutant
R406W human tau transgenic mice. Brain research 1059, 7–12.
doi:10.1016/j.brainres.2005.08.004
Eslinger, P.J., Moore, P., Anderson, C., Grossman, M., 2011. Social cognition,
executive functioning, and neuroimaging correlates of empathic deficits in
frontotemporal dementia. The Journal of neuropsychiatry and clinical
neurosciences 23, 74–82. doi:10.1176/appi.neuropsych.23.1.74
Filiano, A.J., Martens, L.H., Young, A.H., Warmus, B.A., Zhou, P., Diaz-Ramirez,
G., Jiao, J., Zhang, Z., Huang, E.J., Gao, F.-B., Farese, R. V, Roberson, E.D.,
2013. Dissociation of frontotemporal dementia-related deficits and
neuroinflammation in progranulin haploinsufficient mice. The Journal of
neuroscience : the official journal of the Society for Neuroscience 33, 5352–61.
doi:10.1523/JNEUROSCI.6103-11.2013
Galimberti, D., Scarpini, E., 2010. Genetics and biology of Alzheimer’s disease and
frontotemporal lobar degeneration. International journal of clinical and
experimental medicine 3, 129–43.
Galsworthy, M.J., Paya-Cano, J.L., Liu, L., Monleón, S., Gregoryan, G., Fernandes,
C., Schalkwyk, L.C., Plomin, R., 2005. Assessing reliability, heritability and
general cognitive ability in a battery of cognitive tasks for laboratory mice.
Behavior genetics 35, 675–92. doi:10.1007/s10519-005-3423-9
Gibbons, Z.C., Richardson, A., Neary, D., Snowden, J.S., 2008. Behaviour in
amyotrophic lateral sclerosis. Amyotrophic lateral sclerosis : official publication
18
of the World Federation of Neurology Research Group on Motor Neuron
Diseases 9, 67–74. doi:10.1080/17482960701642437
Grochmal-Bach, B., Bidzan, L., Pachalska, M., Bidzan, M., Łukaszewska, B., Pufal,
A., 2009. Aggressive and impulsive behaviors in Frontotemporal dementia and
Alzheimer’s disease. Medical science monitor : international medical journal of
experimental and clinical research 15, CR248–54.
Grunwald, T., Boutros, N.N., Pezer, N., von Oertzen, J., Fernández, G., Schaller, C.,
Elger, C.E., 2003. Neuronal substrates of sensory gating within the human brain.
Biological psychiatry 53, 511–9.
Harciarek, M., Cosentino, S., 2013. Language, executive function and social
cognition in the diagnosis of frontotemporal dementia syndromes. International
review of psychiatry (Abingdon, England) 25, 178–96.
doi:10.3109/09540261.2013.763340
Hodges, J.R., 2013. Alzheimer’s disease and the frontotemporal dementias:
contributions to clinico-pathological studies, diagnosis, and cognitive
neuroscience. Journal of Alzheimer’s disease : JAD 33 Suppl 1, S211–7.
doi:10.3233/JAD-2012-129038
Hodges, J.R., Davies, R.R., Xuereb, J.H., Casey, B., Broe, M., Bak, T.H., Kril, J.J.,
Halliday, G.M., 2004. Clinicopathological correlates in frontotemporal dementia.
Annals of neurology 56, 399–406. doi:10.1002/ana.20203
Huey, E.D., Goveia, E.N., Paviol, S., Pardini, M., Krueger, F., Zamboni, G., Tierney,
M.C., Wassermann, E.M., Grafman, J., 2009. Executive dysfunction in
frontotemporal dementia and corticobasal syndrome. Neurology 72, 453–9.
doi:10.1212/01.wnl.0000341781.39164.26
Hughes, R.N., 2004. The value of spontaneous alternation behavior (SAB) as a test of
retention in pharmacological investigations of memory. Neuroscience and
biobehavioral reviews 28, 497–505. doi:10.1016/j.neubiorev.2004.06.006
Ittner, L.M., Halliday, G.M., Kril, J.J., Götz, J., Hodges, J.R., Kiernan, M.C., 2015.
FTD and ALS-translating mouse studies into clinical trials. Nature reviews
Neurology 11, 360–366. doi:10.1038/nrneurol.2015.65
Ittner, L.M., Ke, Y.D., Delerue, F., Bi, M., Gladbach, A., van Eersel, J., Wölfing, H.,
Chieng, B.C., Christie, M.J., Napier, I.A., Eckert, A., Staufenbiel, M.,
Hardeman, E., Götz, J., 2010. Dendritic function of tau mediates amyloid-beta
19
toxicity in Alzheimer’s disease mouse models. Cell 142, 387–97.
doi:10.1016/j.cell.2010.06.036
Johns, E.K., Phillips, N.A., Belleville, S., Goupil, D., Babins, L., Kelner, N., Ska, B.,
Gilbert, B., Inglis, G., Panisset, M., de Boysson, C., Chertkow, H., 2009.
Executive functions in frontotemporal dementia and Lewy body dementia.
Neuropsychology 23, 765–77. doi:10.1037/a0016792
Ke, Y.D., Delerue, F., Gladbach, A., Götz, J., Ittner, L.M., 2009. Experimental
diabetes mellitus exacerbates tau pathology in a transgenic mouse model of
Alzheimer’s disease. PloS one 4, e7917. doi:10.1371/journal.pone.0007917
Knight, R.T., Staines, W.R., Swick, D., Chao, L.L., 1999. Prefrontal cortex regulates
inhibition and excitation in distributed neural networks. Acta psychologica 101,
159–78.
Knutson, K.M., Dal Monte, O., Schintu, S., Wassermann, E.M., Raymont, V.,
Grafman, J., Krueger, F., 2015. Areas of Brain Damage Underlying Increased
Reports of Behavioral Disinhibition. The Journal of neuropsychiatry and clinical
neurosciences appineuropsych14060126.
doi:10.1176/appi.neuropsych.14060126
Koppel, J., Jimenez, H., Azose, M., D’Abramo, C., Acker, C., Buthorn, J.,
Greenwald, B.S., Lewis, J., Lesser, M., Liu, Z., Davies, P., 2014. Pathogenic tau
species drive a psychosis-like phenotype in a mouse model of Alzheimer’s
disease. Behavioural brain research 275, 27–33. doi:10.1016/j.bbr.2014.08.030
Lalonde, R., 2002. The neurobiological basis of spontaneous alternation.
Neuroscience and biobehavioral reviews 26, 91–104.
Landqvist Waldö, M., Santillo, A.F., Gustafson, L., Englund, E., Passant, U., 2014.
Somatic complaints in frontotemporal dementia. American journal of
neurodegenerative disease 3, 84–92.
Lindau, M., Almkvist, O., Kushi, J., Boone, K., Johansson, S.E., Wahlund, L.O.,
Cummings, J.L., Miller, B.L., 2000. First symptoms--frontotemporal dementia
versus Alzheimer’s disease. Dementia and geriatric cognitive disorders 11, 286–
93. doi:17251
Manes, F.F., Torralva, T., Roca, M., Gleichgerrcht, E., Bekinschtein, T.A., Hodges,
J.R., 2010. Frontotemporal dementia presenting as pathological gambling.
Nature reviews Neurology 6, 347–52. doi:10.1038/nrneurol.2010.34
20
Meeker, H.C., Chadman, K.K., Heaney, A.T., Carp, R.I., 2013. Assessment of social
interaction and anxiety-like behavior in senescence-accelerated-prone and -
resistant mice. Physiology & behavior 118, 97–102.
doi:10.1016/j.physbeh.2013.05.003
Mendez, M.F., 2011. Pathological stealing in dementia: poor response to SSRI
medications. The Journal of clinical psychiatry 72, 418–9.
doi:10.4088/JCP.10l06440gry
Mendez, M.F., 2010. The unique predisposition to criminal violations in
frontotemporal dementia. The journal of the American Academy of Psychiatry
and the Law 38, 318–23.
Mendez, M.F., 2004. The accuracy of clinical criteria for the diagnosis of
frontotemporal dementia. International journal of psychiatry in medicine 34,
125–30.
Mendez, M.F., Perryman, K.M., 2002. Neuropsychiatric features of frontotemporal
dementia: evaluation of consensus criteria and review. The Journal of
neuropsychiatry and clinical neurosciences 14, 424–9.
Merrilees, J., Klapper, J., Murphy, J., Lomen-Hoerth, C., Miller, B.L., 2010.
Cognitive and behavioral challenges in caring for patients with frontotemporal
dementia and amyotrophic lateral sclerosis. Amyotrophic lateral sclerosis :
official publication of the World Federation of Neurology Research Group on
Motor Neuron Diseases 11, 298–302. doi:10.3109/17482961003605788
Moy, S.S., Nadler, J.J., Perez, A., Barbaro, R.P., Johns, J.M., Magnuson, T.R., Piven,
J., Crawley, J.N., 2004. Sociability and preference for social novelty in five
inbred strains: an approach to assess autistic-like behavior in mice. Genes, brain,
and behavior 3, 287–302. doi:10.1111/j.1601-1848.2004.00076.x
Naert, A., Gantois, I., Laeremans, A., Vreysen, S., Van den Bergh, G., Arckens, L.,
Callaerts-Vegh, Z., D’Hooge, R., 2013. Behavioural alterations relevant to
developmental brain disorders in mice with neonatally induced ventral
hippocampal lesions. Brain Research Bulletin 94, 71–81.
doi:10.1016/j.brainresbull.2013.01.008
Neary, D., Snowden, J., Mann, D., 2005. Frontotemporal dementia. The Lancet
Neurology 4, 771–80. doi:10.1016/S1474-4422(05)70223-4
Njung’e, K., Handley, S.L., 1991. Evaluation of marble-burying behavior as a model
of anxiety. Pharmacology, biochemistry, and behavior 38, 63–7.
21
Passant, U., Elfgren, C., Englund, E., Gustafson, L.,. Psychiatric symptoms and their
psychosocial consequences in frontotemporal dementia. Alzheimer disease and
associated disorders 19 Suppl 1, S15–8.
Perriol, M.-P., Dujardin, K., Derambure, P., Marcq, A., Bourriez, J.-L., Laureau, E.,
Pasquier, F., Defebvre, L., Destée, A., 2005. Disturbance of sensory filtering in
dementia with Lewy bodies: comparison with Parkinson’s disease dementia and
Alzheimer's disease. Journal of neurology, neurosurgery, and psychiatry 76,
106–8. doi:10.1136/jnnp.2003.035022
Peters, F., Perani, D., Herholz, K., Holthoff, V., Beuthien-Baumann, B., Sorbi, S.,
Pupi, A., Degueldre, C., Lemaire, C., Collette, F., Salmon, E., 2006.
Orbitofrontal dysfunction related to both apathy and disinhibition in
frontotemporal dementia. Dementia and geriatric cognitive disorders 21, 373–9.
doi:10.1159/000091898
Pompanin, S., Jelcic, N., Cecchin, D., Cagnin, A.,. Impulse control disorders in
frontotemporal dementia: spectrum of symptoms and response to treatment.
General hospital psychiatry 36, 760.e5–7.
doi:10.1016/j.genhosppsych.2014.06.005
Pressman, P.S., Miller, B.L., 2014. Diagnosis and management of behavioral variant
frontotemporal dementia. Biological psychiatry 75, 574–81.
doi:10.1016/j.biopsych.2013.11.006
Rademakers, R., Neumann, M., Mackenzie, I.R., 2012. Advances in understanding
the molecular basis of frontotemporal dementia. Nature reviews Neurology 8,
423–34. doi:10.1038/nrneurol.2012.117
Rafael, J.A., Nitta, Y., Peters, J., Davies, K.E., 2000. Testing of SHIRPA, a mouse
phenotypic assessment protocol, on Dmd(mdx) and Dmd(mdx3cv) dystrophin-
deficient mice. Mammalian genome : official journal of the International
Mammalian Genome Society 11, 725–8.
Rankin, K.P., Kramer, J.H., Miller, B.L., 2005. Patterns of cognitive and emotional
empathy in frontotemporal lobar degeneration. Cognitive and behavioral
neurology : official journal of the Society for Behavioral and Cognitive
Neurology 18, 28–36.
Reisel, D., Bannerman, D.M., Schmitt, W.B., Deacon, R.M.J., Flint, J., Borchardt, T.,
Seeburg, P.H., Rawlins, J.N.P., 2002. Spatial memory dissociations in mice
lacking GluR1. Nature neuroscience 5, 868–73. doi:10.1038/nn910
22
Rogers, D.C., Fisher, E.M., Brown, S.D., Peters, J., Hunter, A.J., Martin, J.E., 1997.
Behavioral and functional analysis of mouse phenotype: SHIRPA, a proposed
protocol for comprehensive phenotype assessment. Mammalian genome : official
journal of the International Mammalian Genome Society 8, 711–3.
Savage, S.A., Lillo, P., Kumfor, F., Kiernan, M.C., Piguet, O., Hodges, J.R., 2014.
Emotion processing deficits distinguish pure amyotrophic lateral sclerosis from
frontotemporal dementia. Amyotrophic lateral sclerosis & frontotemporal
degeneration 15, 39–46. doi:10.3109/21678421.2013.809763
Seltman, R.E., Matthews, B.R., 2012. Frontotemporal lobar degeneration:
epidemiology, pathology, diagnosis and management. CNS drugs 26, 841–70.
doi:10.2165/11640070-000000000-00000
Shea, Y.F., Ha, J., Chu, L.-W., 2014. Comparisons of clinical symptoms in
biomarker-confirmed Alzheimer’s disease, dementia with Lewy bodies, and
frontotemporal dementia patients in a local memory clinic. Psychogeriatrics : the
official journal of the Japanese Psychogeriatric Society. doi:10.1111/psyg.12103
Sieben, A., Van Langenhove, T., Engelborghs, S., Martin, J.-J., Boon, P., Cras, P., De
Deyn, P.-P., Santens, P., Van Broeckhoven, C., Cruts, M., 2012. The genetics
and neuropathology of frontotemporal lobar degeneration. Acta
neuropathologica 124, 353–72. doi:10.1007/s00401-012-1029-x
Snowden, J.S., Bathgate, D., Varma, A., Blackshaw, A., Gibbons, Z.C., Neary, D.,
2001. Distinct behavioural profiles in frontotemporal dementia and semantic
dementia. Journal of neurology, neurosurgery, and psychiatry 70, 323–32.
Snowden, J.S., Gibbons, Z.C., Blackshaw, A., Doubleday, E., Thompson, J.,
Craufurd, D., Foster, J., Happé, F., Neary, D., 2003. Social cognition in
frontotemporal dementia and Huntington’s disease. Neuropsychologia 41, 688–
701.
Starkstein, S.E., Robinson, R.G., 1997. Mechanism of disinhibition after brain
lesions. The Journal of nervous and mental disease 185, 108–14.
Sterniczuk, R., Antle, M.C., Laferla, F.M., Dyck, R.H., 2010. Characterization of the
3xTg-AD mouse model of Alzheimer’s disease: part 2. Behavioral and cognitive
changes. Brain research 1348, 149–55. doi:10.1016/j.brainres.2010.06.011
Stopford, C.L., Thompson, J.C., Neary, D., Richardson, A.M.T., Snowden, J.S., 2012.
Working memory, attention, and executive function in Alzheimer’s disease and
23
frontotemporal dementia. Cortex; a journal devoted to the study of the nervous
system and behavior 48, 429–46. doi:10.1016/j.cortex.2010.12.002
Takeuchi, H., Iba, M., Inoue, H., Higuchi, M., Takao, K., Tsukita, K., Karatsu, Y.,
Iwamoto, Y., Miyakawa, T., Suhara, T., Trojanowski, J.Q., Lee, V.M.-Y.,
Takahashi, R., 2011. P301S mutant human tau transgenic mice manifest early
symptoms of human tauopathies with dementia and altered sensorimotor gating.
PloS one 6, e21050. doi:10.1371/journal.pone.0021050
Tasan, R.O., Lin, S., Hetzenauer, a., Singewald, N., Herzog, H., Sperk, G., 2009.
Increased novelty-induced motor activity and reduced depression-like behavior
in neuropeptide Y (NPY)-Y4 receptor knockout mice. Neuroscience 158, 1717–
1730. doi:10.1016/j.neuroscience.2008.11.048
Van der Jeugd, A., Blum, D., Raison, S., Eddarkaoui, S., Buée, L., D’Hooge, R.,
2013. Observations in THY-Tau22 mice that resemble behavioral and
psychological signs and symptoms of dementia. Behavioural Brain Research
242, 34–39. doi:10.1016/j.bbr.2012.12.008
Van Der Jeugd, A., Vermaercke, B., Lo, A.C., Hamdane, M., Blum, D., Buée, L.,
D’Hooge, R., 2013. Progressive age-related cognitive decline in tau mice.
Journal of Alzheimer’s Disease 37, 777–788. doi:10.3233/JAD-130110
Van Eersel, J., Stevens, C.H., Przybyla, M., Gladbach, A., Stefanoska, K., Chan,
C.K.-X., Ong, W.-Y., Hodges, J.R., Sutherland, G.T., Kril, J.J., Abramowski, D.,
Staufenbiel, M., Halliday, G.M., Ittner, L.M., 2015. Early-onset axonal
pathology in a novel P301S-Tau transgenic mouse model of frontotemporal lobar
degeneration. Neuropathology and applied neurobiology. doi:10.1111/nan.12233
Varty, G.B., Morgan, C.A., Cohen-Williams, M.E., Coffin, V.L., Carey, G.J., 2002.
The gerbil elevated plus-maze I: behavioral characterization and
pharmacological validation. Neuropsychopharmacology : official publication of
the American College of Neuropsychopharmacology 27, 357–70.
doi:10.1016/S0893-133X(02)00312-3
Xia, D., Li, C., Götz, J., 2015. Pseudophosphorylation of Tau at distinct epitopes or
the presence of the P301L mutation targets the microtubule-associated protein
Tau to dendritic spines. Biochimica et biophysica acta 1852, 913–24.
doi:10.1016/j.bbadis.2014.12.017
Yin, F., Dumont, M., Banerjee, R., Ma, Y., Li, H., Lin, M.T., Beal, M.F., Nathan, C.,
Thomas, B., Ding, A., 2010. Behavioral deficits and progressive neuropathology
24
in progranulin-deficient mice: a mouse model of frontotemporal dementia.
FASEB journal : official publication of the Federation of American Societies for
Experimental Biology 24, 4639–47. doi:10.1096/fj.10-161471
25
Figure legends
Figure 1. Tau58-2/B mice present with a widespread, progressive tauopathy. (A)
Drawing of a mouse sagittal section representing the affected brain regions and their
underlying functions. ACC, anterior cingulate cortex; HC, hippocampus; OFC,
orbitofrontal cortex; PFC, prefrontal cortex; and OFC, orbitofrontal cortex. (B)
Representative sagittal section of the brain of a 12 month-old Tau58-2/B mouse
stained with HT7 for total tau. (B’) Consecutive section impregnated with
Bielschowsky silver staining to visualize NFTs. (C-E, C’-E’) Corresponding higher
magnification images derived from hippocampus (C, C'), prefrontal cortex (D, D'),
and cerebellum (E, E'). Scale bars: 100µm.
Figure 2. Tauopathy mice show no alterations in explorative activity or anxiety.
(A) Total distance moved over a 10 min session in the open field test reveals no
differences in anxiety between wild-type (Wt) and transgenic (Tg) mice. (B) Tau Tg
mice spend the same amount of time as the Wt littermates in the center for all three
age groups assessed. (C) Heat maps reveal no thigmotactic or altered anxiety-like
behavior in Tg compared to Wt mice at any age tested. Representative traveled paths
per genotype are shown.
Figure 3. From 6 months onwards, tauopathy mice display deficits in social
exploration. (A) In the social exploration test, tau Tg mice are indistinguishable from
Wt mice at all age comparisons, when comparing total distance traveled. (B) From 6
months onwards, Tg mice spend less time in the annulus around the cage containing
the stranger mouse compared to the age-matched Wt mice, indicative of impaired
social interaction. (C) Heat maps confirm the decrease in social exploration in Tg
mice. Representative traveled paths per genotype are shown. Brackets indicating
differences between genotypes (*), and gender (#); p* < 0.05; p** < 0.01; p*** <
0.001.
Figure 4. Tauopathy mice show increased impulsivity and risk-taking behaviors.
(A) Tau Tg mice spend more time in the light compartment as compared to Wt mice.
(B) As shown by the decreased latency in the light/dark box, dark-habituated tau Tg
mice emerge faster from the dark into the light than their age-matched Wt counter-
26
parts. (C) From 6 months of age onwards, Tau58-2/B mice show an increased risk-
taking behaviors compared to Wt mice. Brackets indicating differences between
genotypes (*), and gender (#); p* < 0.05; p** < 0.01; p*** < 0.001.
Figure 5. Decreased working memory and adaptive problem solving capacities in
aged tau Tg mice. (A) From 6 months onwards, tau Tg mice make fewer alternations
in the Y-maze. (B) Heat maps confirm the decrease in alteration in 10-11 months-old
Tg mice. Representative traveled paths during the first minute for each genotype are
shown. (C) From 10 months onwards, Tg mice take longer to solve the digging
problem than the age-matched Wt mice as shown by an increased latency to enter the
goal box that contains the food reward. (D) The executive function deficit in aged tau
Tg mice is verified in the second puzzle on day 2 when tau Tg mice fail to solve the
plug test as compared to age-matched Wt mice. Brackets indicating differences
between genotypes (*), and gender (#); p* < 0.05; p** < 0.01; p*** < 0.001.
27
Tables
Table 1. Progressive tau hyperphosphorylation and NFT formation in Tau58-2/B
mice.
Table 2. Differences in general appearance, arousal, and neuromotor per-
formance in Tau58-2/B mice.
Cerebellum
ACC
Brainstem
A
B
C
D
C’
D’
E’E
Figure 1
B’
A
C
2-3 months 6-7 months 10-11 months0
1000
2000
3000
4000
5000
Dis
tanc
e tra
vele
d (c
m)
Wt femaleWt male
Tg femaleTg male
2-3 months 6-7months 10-11 months
Wt
Tg
2-3 months 6-7 months 10-11 months0
50
100
150
200
250
Tim
e sp
ent i
n ce
nter
(s)
B
Figure 2
A B
C
2-3 months 6-7months 10-11 months
Wt
Tg
2-3 months 6-7 months 10-11 months0
1000
2000
3000
4000
5000
Dis
tanc
e tra
vele
d (c
m)
Wt femaleWt male
Tg femaleTg male
2-3 months 6-7 months 10-11 months0
100
200
300
Tim
e sp
ent i
n ce
nter
(s)
*** ** *
Figure 3
A B
C
2-3 months 6-7 months 10-11 months0
100
200
300
400
500
Tim
e sp
ent i
n lig
ht (s
) Wt femaleWt male
Tg femaleTg male
* ** **** ** ***
2-3 months 6-7 months 10-11 months0
20
40
60
80
Late
ncy
to li
ght (
s)
#
** ** * *
2-3 months 6-7 months 10-11 months0
20
40
60
80
Stre
tche
d po
stur
es (#
)
Wt maleWt female
2-3 months 6-7 months 10-11 months0
20
40
60
80
Str
etch
ed p
ost
ure
s (#
)
***TgWt
2-3 months 6-7 months 10-11 months0
20
40
60
80
Str
etch
ed p
ost
ure
s (#
)
***TgWt
2-3 months 6-7 months 10-11 months0
20
40
60
80
Str
etch
ed p
ost
ure
s (#
)
***TgWt
2-3 months 6-7 months 10-11 months0
20
40
60
80
Str
etch
ed p
ost
ure
s (#
)
***TgWt
** ** *** ***
Tg femaleTg male
Figure 4
A B
2-3 months 6-7 months 10-11 months0
20
40
60
80
100
Alte
rnat
ions
(%) Wt female
Tg female
Wt maleTg male# #
#
#
** ** *** ***
C
2-3 months 6-7 months 10-11 months0
50
100
150
200
Late
ncy
to s
olve
dig
(s)
*** ***
2-3 months 6-7 months 10-11 months0
100
200
300
Late
ncy
to s
olve
plu
g (s
)
** ** *** ***
10-11 months
Wt Tg
D
Figure 5
1
Impulsivity, decreased social exploration, and executive
dysfunction in a mouse model of frontotemporal dementia
Ann van der Jeugd1,2, Ben Vermaercke2, Glenda M. Halliday3, Matthias Staufenbiel4,
and Jürgen Götz1,*
Supplementary Data
Supplementary Results
Gender effects in SHIRPA murine neurobehavioral screen and motor abilities
tests. At any age tested, male mice, regardless of their genotype, weighed more than
female mice (gender main effect at 2-3 months, F1,19=36.42, p < 0.001; 6-7 months:
F1,19=34.33, p < 0.001; 10-11 months: F1,19=31.52, p < 0.001; gender x genotype
interaction effects not significant). Moreover, 10-11 month-old Tg male mice had
more bald patches and wounds than female mice and their Wt counterparts (missing
fur: gender main effect: F1,19=20.83, p < 0.001; gender x genotype effect: F1,19=9.75,
p = 0.007; wounds: gender main effect: F1,19=9.83, p = 0.007; gender x genotype
interaction effect: F1,19=9.83, p = 0.007). Also, male Tg mice of 6-7 months of age
displayed more tremors than their female and Wt counterparts (gender main effect:
F1,19=7.33, p = 0.02; gender x genotype interaction effect: F1,19=7.33, p = 0.02).
Finally, we found higher values in the grip strength test for males than for females
(grip mean: gender main effect at 2-3 months: F1,19=4.83, p = 0.048; gender x
genotype interaction effects not significant - grip max: gender main effect at 6-7
months: F1,19=6.12, p = 0.031; gender x genotype interaction effects not significant).
2
Supplementary Figure 1
Behavioral setups. (A) Open field test, (B) social exploration test, (C) light/dark box,
(D) Y-maze, (E) puzzle box dig trial, and (F) puzzle box plug trial.
3
Supplementary Table 1
Tasks used to compare Tau58-2/B mice to wild-type littermate controls
4
Supplementary Table 2
SHIRPA Murine neurobehavioral screen (based on (Rogers et al., 1997))
Physical factors and gross appearance
• Body weight (g)
• Presence of whiskers o 0 = None o 1 = A few o 2 = Most, but not a full set o 3 = A full set
• Appearance of fur (not counting patches of missing fur)
o 0 = Ungroomed and dishevelled o 1 = Somewhat dishevelled o 2 = Well-groomed (normal)
• Patches of missing fur on body
o 0 = None o 1 = Some o 2 = Extensive
• Wounds
o 0 = None o 1 = Signs of previous wounding o 2 = Slight wounds present o 3 = Moderate wounds present o 4 = Extensive wounds present
Observation of behavior in a novel environment (within a 3 min trial in a tub cage)
• Transfer behavior o 0 = Coma o 1 = Prolonged freeze (>10 sec.), then slight movement o 2 = Extended freeze, then moderate movement o 3 = Brief freeze (a few seconds), then active movement o 4 = Momentary freeze, then swift movement o 5 = No freeze, immediate movement o 6 = Extremely excited
• Spontaneous activity
o 0 = None, resting o 1 = Casual scratch, groom, slow movement o 2 = Vigorous scratch, groom, moderate movement o 3 = Vigorous, rapid/dart movement o 4 = Extremely vigorous, rapid/dart movement
5
• Tremor
o 0 = None o 1 = Mild o 2 = Marked
• Palpebral closure
o 0 = Eyes wide open o 1 = Eyes ½ closed o 2 = Eyes closed
• Gait
o 0 = Normal o 1 = Fluid but abnormal o 2 = Limited movement only o 3 = Incapacity
Reactions to simple stimuli and reflexes
• Touch escape (finger stroke from above, starting light and getting firmer) o 0 = No response o 1 = Mild (escape response to firm stroke) o 2 = Moderate (rapid response to light stroke) o 3 = Vigorous (escape response to approach)
• Trunk curl (grip tail and lift about 30 cm)
o 0 = Absent o 1 = Present
• Reaching reflex (forelimbs extension when lowered by tail from 15cm height)
o 0 = None o 1 = Upon nose contact o 2 = Upon vibrasse contact o 3 = Before vibrasse contact o 4 = Early vigorous extension
• Preyer reflex (loud handclap 30 cm above mouse, watch for pinna reflex)
o 0 = None o 1 = Active retraction, moderate brisk head flick o 2 = Hyperactive, repetitive flick
• Toe pinch (apply gentle lateral compression on hind foot of a tail lifted mouse)
o 0 = None o 1 = Slight withdrawal o 2 = Moderate withdrawal, not brisk o 3 = Brisk, rapid withdrawal o 4 = Very brisk repeated extension and flexion
Grip strength and motor coordination
6
Grip strength was measured using a T-shaped bar connected to a digital dynamometer (Ugo Basile, Comerio, Italy). Mice were placed in such a way that they grabbed the bar spontaneously and were softly pulled backwards by the tail until they released their grip. Ten such readouts were recorded; mean and max pulling force were noted for each mouse. The wire hang test seeks to evaluate motor function. The animal is placed on a wire cage top, which is then inverted and suspended above the home cage for 30 seconds. Grip is scored as following:
o 0 = Active grip o 1 = Difficulty to grasp, but hangs on o 2 = Grasps, but falls of within 10 seconds o 3 = Unable to grasp, falls within seconds o 3 = Falls immediately
Motor coordination and equilibrium were tested using an accelerating Rotarod (Ugo Basile, Comerio, Italy). Mice were tested on four trials, during which the rod accelerated from 4 to 20 rpm in 5 minutes. Consecutive trials were separated by a 2-minute intertrial interval. Latency to falling off the rod was recorded up to 5 minutes; mean and max walking latencies were noted for each mouse.