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Sparser Representation of Experiencein Aged Rat Lateral Entorhinal Cortex
Item Type text; Electronic Thesis
Authors Comrie, Alison Emelie
Publisher The University of Arizona.
Rights Copyright © is held by the author. Digital access to this materialis made possible by the University Libraries, University of Arizona.Further transmission, reproduction or presentation (such aspublic display or performance) of protected items is prohibitedexcept with permission of the author.
Download date 21/05/2018 19:15:27
Link to Item http://hdl.handle.net/10150/624949
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Abstract
The hippocampus undergoes biological changes with age that mediate memory
dysfunction. The hippocampus is highly connected to lateral entorhinal cortex (LEC), which is
thought to represent non-spatial features of experience, including odors. We aimed to discover if
LEC neuronal populations are selectively activated by distinct odors, and hypothesized that
aging alters these activity patterns. After training adult and aged rats to run laps around a track,
one behavioral group experienced two run sessions, 20 minutes apart, with the same set of
odors (AA) added around the track each time, while another group had distinct odor sets (AB).
mRNA of the immediate-early gene Arc is localized to discrete neuronal compartments based
on the time since activation. We used fluorescence in situ hybridization and confocal
microscopy to visualize the subcellular distribution of Arc mRNA to identify the neurons
activated during each session. The behavioral experiences induced elevated LEC activity, but
population activity failed to distinguish between distinct odor sets. This suggests that LEC
populations stably represent higher order features of experience. Additionally, a lower
proportion of LEC neurons participated during behavior in aged than in young rats. A decrease
in neuron activation could reflect a reduction or refinement of LEC network function.
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Acknowledgements
This work was supported by R01 AG003376, F32 AG033460, the McKnight Brain
Research Foundation, and HHMI 5200006942. Additionally, I would like to thank Dr. Carol
Barnes for extensive mentoring, Dr. Jim Lister for conducting the behavioral portion of the
experiment and for guidance, Dr. Monica Chawla for histological training, Doug Cromey for
miscroscopy training, Jeri Meltzer and Hana Davis for assistance with image analysis, Dr.
Rachel Samson for assistance with statistical modeling, Michael Montgomery for technical
assistance, and Michelle Carroll, Michelle Albert, and Luann Snyder for administrative
assistance.
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Introduction
Normal aging in the absence of pathology entails cognitive changes including memory
deficits in humans and other mammals. The great majority – 86 percent – of people over the
age of 71 are not demented, but have healthy cognitive aging (Plassman et al., 2007).
Therefore, it is critical to establish an understanding of the biological changes that underlie
normal age-related memory decline.
The hippocampus is a brain region that undergoes characteristic changes with age that
mediate episodic memory dysfunction in rodents and humans. For example, aged rats have
impaired spatial memory. The neural basis of this behavioral problem involves hippocampal
place fields that inappropriately remap when a rat explores a familiar environment (Barnes,
Suster, Shen, & McNaughton, 1997) and fail to remap in a novel environment (Sava & Markus,
2008). These and other age-related changes in hippocampal neural population activity may
arise in part from altered activity in connected brain regions such as the entorhinal cortex (EC).
Despite the fact that the EC provides major inputs into many subregions of the
hippocampus, the aging of the EC remains poorly characterized. The EC and hippocampus are
anatomically heterogeneous, but the hippocampus primarily receives projections from
superficial layers of EC and sends back-projections to deep layers of EC (Figure 1). Therefore,
examining the activity of superficial EC neurons informs us about the influence of EC projections
to the hippocampus, while studying the activity of deep EC neurons provides insight into the
influence of hippocampal projections to EC. The EC has two functional subdivisions: the better-
studied medial EC (MEC) and understudied lateral EC (LEC). MEC plays a role in spatial
information processing and spatial memory, however, the basic functions of LEC are not
understood. In contrast to neurons in MEC, LEC neurons do not predominantly fire in a
spatially-selective manner (Deshmukh & Knierim, 2011; Hargreaves, Rao, Lee, & Knierim,
2005). LEC neurons receive significant inputs from olfactory areas, piriform cortex, and
perirhinal cortex (Figure 1), and the rodent and monkey connectivity patterns are comparable
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(Burwell & Amaral, 1998; Canto, Wouterlood, & Witter, 2008; Insausti, Herrero, & Witter, 1997).
These regions are implicated in processing information about odors and objects, corroborating
the idea that the LEC responds preferentially to local, non-spatial, external attributes of
experiences (Knierim, Neunuebel, & Deshmukh, 2014). For example, neurons in LEC have
been reported to fire in response to individual features of the environment including objects and
odors (Young, Otto, Fox, & Eichenbaum, 1997; Zhu, Brown, & Aggleton, 1995). It remains
unclear whether a distributed population code represents items in an environment, but this
would be consistent with the finding that some LEC neurons responded to a specific subset of a
group of objects in an open exploration task, rather than to one or all objects (Deshmukh &
Knierim, 2011). Furthermore, the stability of LEC responses across multiple experiences is not
understood, and may be impacted by environmental complexity, brain state, attention, context,
stimulus novelty, and salience (de Curtis & Paré, 2004; Kajiwara, Takashima, Mimura, Witter, &
Iijima, 2002; Rodo, Sargolini, & Save, 2017). If any of the functional properties of superficial
layers of LEC are disrupted in aging, then the hippocampus would be subject to altered inputs,
which may impact output and therefore deep layers of LEC.
Figure 1 Simplified summary of relevant circuitry. Superficial lateral entorhinal cortex (LEC) receives
inputs from piriform cortex (PIR) and perirhinal cortex (PRC). Superficial LEC projects to different
subregions of the hippocampus (DG, CA1, CA3), while deep LEC receives hippocampal back-projections.
Deep LEC sends projections down to cortical areas including PIR and PRC.
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During normal aging, LEC and hippocampal neuron numbers are preserved, although in
the hippocampus, synaptic connections are compromised with age and are associated with
cognitive decline (Geinisman, de Toledo-Morrell, Morrell, Persina, & Rossi, 1992; Merrill, Chiba,
& Tuszynski, 2001; Nicholson, Yoshida, Berry, Gallagher, & Geinisman, 2004; Rasmussen,
Schliemann, Sørensen, Zimmer, & West, 1996; Smith, Adams, Gallagher, Morrison, & Rapp,
2000). In contrast, the LEC is vulnerable to neurodegeneration in early stages of Alzheimer’s
disease for unknown reasons (Braak & Braak, 1992). Biochemical changes have been observed
in the aged EC that could mediate population-level alterations, including reduced reelin and
synaptophysin expression (Stranahan, Haberman, & Gallagher, 2011). A better understanding
of behaviorally-relevant age-related changes in EC neural population activity will be important
for understanding how the aged EC may impact hippocampal function, and how EC function
may be impacted by back-projections from the aged hippocampus.
Interestingly, odor and object discrimination of similar stimuli are impaired with age,
although odor detection thresholds are not (Burke & Wallace, 2011; Yoder et al., 2017). This
age-related impairment could be due in part to LEC dysfunction, as fine odor discrimination is
lost upon LEC silencing by muscimol (Chapuis et al., 2013). Additionally, odor memory and odor
perception deficits are characteristic preclinical signs of a number of neurodegenerative
diseases, including Alzheimer’s Disease (Devanand et al., 2000; Mesholam, Moberg, Mahr, &
Doty, 1998; Segura et al., 2013). Studying how LEC ages in conjunction with behaviors that
involve olfaction may therefore be useful in the development of diagnostic tests and novel
therapies for aged individuals.
The LEC is clearly well-positioned to represent features of an environment that are
combined with spatial information in the hippocampus to form multimodal episodic memories
that are impaired with age. However, the role of the LEC in representing and discriminating odor
experiences and how the corresponding neural population activity may change with age remain
unknown.
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To probe these questions, we employed a histological method to examine the activation
of populations of neurons in adult and aged rats during olfactory experiences. We monitored
activity-dependent expression of the immediate early gene Arc to assess the neural ensembles
activated at two behavioral time points per rat. In contrast to high-density electrophysiological
recordings, this approach provided a large sample size of tens of thousands of neurons.
Additionally, we could ensure that we were assessing principal neuron activity, as Arc is
expressed only in principal neurons, not interneurons or glia (Vazdarjanova et al., 2006).
Cellular compartment analysis of temporal activity by fluorescence in situ hybridization
(catFISH) enabled us to fluorescently label Arc mRNA that is expressed by strongly activated
neurons (Guzowski, McNaughton, Barnes, & Worley, 1999). As time passed between the first
and second behavioral epochs, the Arc mRNA was translocated with tightly regulated kinetics
from the nuclei to the cytoplasm of the neurons. The labelled tissue was visualized and neurons
were characterized based on the localized, subcellular distribution of Arc mRNA (see Methods).
Neurons activated in the first behavioral epoch had cytoplasmic Arc signal, neurons activated in
the second behavioral epoch had nuclear Arc mRNA foci, and neurons activated in both were
“double-labelled” in the cytoplasm and nucleus.
The behavioral design included two epochs with distinct or repeated odors, intended to
induce LEC neural population activation (and reactivation) in adult and aged rats. Rats were
trained to run in alternating clockwise and counterclockwise laps on a circular track in a constant
spatial environment. After training, one behavioral group (AA) experienced the same set of 6
odors mixed in sand in ramekins in the same order around the track during two 5-minute
running sessions (adult mean = 7.4 laps/session, aged mean = 9.8 laps/session) separated by
20 minutes. A second group (AB) also experienced two running sessions, but the odor stimuli
were completely distinct between the first and second time points.
We quantified the proportion of total neurons activated in each epoch under the
hypothesis that neural population activity in LEC would stably represent repeated odor
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experiences and selectively represent distinct odor experiences – and that these patterns would
be impacted by age. Detection of a significant proportion of double-labeled neurons in the AA
condition would provide evidence for stable representation of repeated experience, while
double-labeled neurons in the AB condition would provide evidence that the same population of
cells can represent distinct odor experiences. A higher proportion of single-labeled (cytoplasmic
or nuclear positive) neurons in the AB condition would support the idea that different sets of
LEC neurons were activated by different odorants. These patterns may be affected by age and
may differ between the superficial and deep layers of LEC. For example, deficits in superficial
LEC could drive changes in the hippocampus. Alternatively, effects of age may be exaggerated
in deep layers of LEC due to defective inputs from the aged hippocampus. These age-related
changes may together contribute to memory deficits observed in aged animals.
Methods
Subjects and behaviors
Twenty-three adult (9 months) and 24 aged (24 months) experimentally naïve male
Fischer 344 rats (from the National Institute of Aging’s colony, Wilmington, MA) participated in
the experiment. Rats were individually housed in transparent cages (44 cm deep x 23 cm wide x
20 cm tall) in a colony room with a reverse 12-hour light-dark cycle. All behavioral testing took
place during the dark cycle. Prior to behavioral testing, each animal was handled by
experimenters for 10 minutes for 2 days. Rat weights were monitored throughout the course of
the experiment. Rats were provided water with ad libitum access for the duration of the
experiment, and rodent chow pellets (Teklad, Harlan Laboratories) with ad libitum access until
behavioral testing and diet restriction began.
Rats completed the spatial and visually-cued versions of the Morris water maze task as
previously described (Morris et al., 1982; Barnes et al., 1996) to assess spatial memory and to
test for blindness. Data were analyzed with ANY-maze software (data not shown here).
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After completion of the water maze protocols, food deprivation began, and health was
closely monitored for one week. Food was restricted to maintain 85% original body weight, and
diet consisted of a mash made of rat chow, STAT (PRN Pharmacal, Pensacola, FL) and apple
sauce (Motts’ brand, Plano, TX). Rats were each trained to run clockwise and counterclockwise
laps around a circular track (48 inches diameter). Before training, rats were familiarized with the
track environment for 15 minutes of free exploration with crushed food pellets sprinkled around
the track. Training took place for 10 minutes daily for 1 week prior to the experiment day. The
track had a divider to indicate the beginning and end of a lap, and rats were rewarded at both
ends with a mixture of mash and vanilla-flavored nutrition shake (Ensure brand, Abbott
Laboratories) that was dispensed by hand in plastic trays. On the last 2 training days, sand-filled
ramekins were placed on the track to acclimate the rats to the objects. The ramekins were small
enough that rats had more than half of the track width to pass the ramekins. However, the rats
were also close enough to the ramekins that they could whisk and explore them. This exposure
ensured that the ramekins were not novel objects on experimental days.
Animals from each age group were randomly assigned into positive control, negative
control, and two behavioral groups (AA and AB). On experiment day, the AA and AB rats each
completed two 5-minute epochs of running on the circular track for food reward, separated by
20 minutes in their home cages (Figure 2). Rats were transported between their home cages,
the behavioral testing room, and the room in which sacrifice took place in towel-lined pots to
minimize exposure to extraneous stimuli. Unlike during training, 6 distinct odors were mixed into
the ramekins around the track on experiment day. Rats in the AA group experienced the same
odors in the same order around the track for both track running epochs. These A odors were
nutmeg, coffee, sage, ginger, smoky paprika, and cumin. Rats in the AB group experienced a
distinct odor set during each epoch; first, the aforementioned A odors, and then the B odors.
The B odors were black pepper, cinnamon, baby powder, ground clove, pumpkin spice, and
garlic powder. One teaspoon of the powdered odor was mixed into 10 teaspoons of sand in
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each ramekin. The behavioral testing room and any potential visuospatial cues were constant
across behavioral epochs.
Figure 2 Behavioral paradigm. Adult and aged rats each completed clockwise and counterclockwise
laps on a circular track for food reward at both sides of the barrier for 5 minutes. 6 odors were spaced out
around the track in ramekins. After 20 minutes in the home cage, rats underwent a second behavioral
epoch with either the repeated A odors (A-F) or distinct B odors (G-L).
Upon completion of the second epoch of track running, rats were anesthetized in a bell
jar filled with isoflurane and then decapitated with a guillotine. Rats from the negative control
group were sacrificed from their home cages to assess baseline Arc expression (Cage Control,
CC), and rats from the positive control group underwent Maximal Electroconvulsive Shock
(MECS) 5 minutes before sacrifice to induce Arc expression in all possible neurons. All handling
and experimental procedures were in accordance with the University of Arizona Institutional
Animal Care and Use Committee protocols.
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Tissue processing
Brains were rapidly extracted and hemisected immediately upon sacrifice and flash-
frozen in -70°C isopentane in a mixture of dry ice and ethanol to preserve Arc mRNA. Left
hemispheres were stored in a -80°C freezer. Blocks of 8 hemispheres were made using OCT
Compound (Ted Pella, Inc., Redding, CA) and each 2 x 4 block included hemispheres to
represent each experimental condition; an adult and an aged animal of each control (CC,
MECS) and behavioral (AA, AB) group. Six total blocks were made. Blocks were cut into 20
micron coronal sections in a cryostat and sections were mounted on Super Frost Plus slides
(VWR), then stored at -80°C.
A cresyl violet Nissl stain was performed on a series of every tenth section (200 microns
apart) to identify sections containing lateral entorhinal cortex (LEC, Figure 3). Permount
(Thermo Fisher Scientific Inc.) was used to coverslip stained sections. Cytoarchitectonic
markers were used to identify LEC; ventral to the lateral sulcus, sparse layer I, large island cells
in layer II, sparse lamina dissecans layer IV, dense layers V/VI with smaller neurons. These
layers contrast the cytoarchitecture of the neighboring perirhinal cortex and pyriform cortex, and
were therefore used to select 3 consecutive sections containing LEC per hemisphere for
histology. Nonconsecutive sections were only used in the case of damaged tissue.
Figure 3 LEC image locations. 4 images were taken per section (see boxes); 2 superficial and 2 deep. 3
consecutive sections of left LEC were imaged per animal, resulting in 12 images collected in total per rat.
Paxinos & Watson, 2008
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Cellular compartment analysis of temporal activity by fluorescence in situ hybridization
(catFISH) was carried out for immediate-early gene Arc mRNA on the selected sections
(Guzowski et al., 1999). In summary, a plasmid containing Arc cDNA was used to generate a
riboprobe labeled with digoxigenin. The digoxigenin labeled Arc antisense riboprobe was
hybridized with tissue overnight. The probe was detected with anti-digoxigenin-HRP conjugate
and visualized with cyanine-3-labeled tyramide. Nuclei were counterstained with DAPI in
Vectashield mounting medium (Vector Laboratories, Inc., Burlingame, CA) and sealed with nail
polish. The nuclear stain enabled differentiation of cytoplasmic and nuclear Arc mRNA.
Imaging and analysis
A Leica SP5-II resonant scanner confocal microscope (Leica Microsystems, Buffalo
Grove, IL) was used to take four image volumes per section; two superficial and two deep
images (Figure 3). Images were captured with a 40x/1.25NA PL Apo oil immersion objective at
1024 x 1024 pixel resolution through the depth of the entire section, in 1 micron steps.
The detector gain and amplifier offset settings for imaging the DAPI signal were adjusted
to easily differentiate non-neuronal cells from neurons. Non-neuronal nuclei have a smaller,
rounder shape, with bright and uniformly distributed signal. This contrasts with the larger, less
regular shape, and sparser signal distribution of neuronal nuclei (Vazdarjanova et al., 2006).
The detector gain and amplifier offset settings for Arc signal were adjusted to capture an
image that reproduced the signal observed through the eyepiece. The settings were established
for each slide based on controls, and were only adjusted across sections within a slide to
accommodate cases of uneven staining. The experimenter who collected images was blind to
the age and behavioral treatment that corresponded to each section.
Images were analyzed offline with ImageJ software. Only neurons with all or part of the
nucleus in the median 20% of the image z-stack and fully contained in the x and y planes were
characterized to avoid sampling error from partial cells. Neurons were differentiated from non-
neuronal cells using the DAPI signal before overlaying the Arc signal to avoid bias. The
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compartmentalization of the Arc signal was used to classify each neuron (Figure 4) as nuclear
positive (Nuc+), cytoplasmic positive (Cyto+), double-labelled (Dbl+), or negative (Neg). Nuc+
classifications were made when a neuronal nucleus contained one or two distinct puncta
spanning at least three optical planes. Cyto+ classifications were made when the Arc signal was
outside of and surrounding at least half of a neuronal nucleus. Dbl+ classifications were made
when both nuclear foci and cytoplasmic staining occurred on the same neuronal nucleus, and
Neg classifications were made when Arc signal was neither present in nor around a neuronal
nucleus. Image counters were blind to the age and experimental condition for each section.
Images from all age groups and behavioral conditions were distributed among people
classifying cellular localization of Arc mRNA in this study.
Figure 4 Neuron classification. (a) Double-labelled neuron with Arc mRNA (red) in the DAPI-labeled
nucleus (blue) and in the cytoplasm. This cell was active in both the first and second behavioral epoch.
(b) Cytoplasmic positive neuron with Arc mRNA in the cytoplasm of the neuron, surrounding the nucleus.
This cell was active during the first behavioral epoch. (c) Nuclear positive neuron with Arc mRNA foci in
the nucleus. This cell was active during the second behavioral epoch.
Counts in each category were converted to percentages of total number of neurons for
each image volume. A Generalized Linear Mixed-effects Model (GLMM) was employed in R.
The glmerMod function from the lme4 package was used (Bates, Mächler, Bolker, & Walker,
2015), applying the following general equation: η = Xβ + Zγ.
The GLMM differs from a standard generalized linear model in that there is a random
effects term (Zγ) in the linear predictor expression (in addition to the fixed effects term (Xβ)).
Such a model is appropriate for these data because it has multiple levels; the proportion of cells
in each Arc localization category for each image are nested at the level of the individual rat
a. b. c.
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brain, age group, and experimental condition. The proportion of activated neurons (η) has a
binomial error distribution. The matrix of the predictor variables (X) includes Arc localization
(nuclear positive, cytoplasmic positive, double-labelled, negative), age group (adult, aged), layer
(superficial, deep), and behavior (AA, AB, CC, MECS), and β is a vector of the regression
coefficients for the predictor variables. Z is the design matrix for the random effects and γ is a
vector of regression coefficients for the random effects (to account for testing at multiple time
points per rat). In the loss function, the squared error was weighted by the number of neurons
counted in each image. Significance was assessed using the log-likelihood ratio test. Kruskal-
Wallis tests were used in cases where GLMM residuals were not normally distributed.
Bonferroni corrections were made after each analysis. Normality in the distribution of the model
residuals was assessed using scatter plots and quantile-quantile plots.
Results
Total proportion of neurons expressing Arc
To examine the proportion of neurons in lateral entorhinal cortex (LEC) activated by
track running in the presence of odors, adult and aged rats underwent two 5-minute behavioral
epochs separated by 20 minutes in their home cages. Rats in the AA group experienced the
same set of 6 distinct odors around a circular track during both epochs, while rats in the AB
group experienced distinct sets of 6 odors around the track in the first and second epochs. The
mean number of laps completed per session by each behavioral group were: 8.7 for adult AA
rats, 6.2 for adult AB rats, 10.1 for aged AA rats, and 9.6 for aged AB rats. On average, aged
rats completed a slightly higher number of laps per session than did adult rats. The presence of
Arc mRNA was then used as a proxy for neural activity.
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Figure 5 Percentage of neurons expressing Arc. (a) Overall proportion of superficial LEC neurons with
Arc mRNA. (b) Overall proportion of deep LEC neurons with Arc mRNA. (a-b) Behavioral condition, layer,
and age, all significantly affected the percentage of LEC neurons that expressed Arc. Deep layers had
slightly but significantly higher percentages of Arc-expressing neurons than did superficial layers. For
both layers, rats in the AA and AB groups had higher percentages of Arc-expressing LEC neurons than
did rats in the CC group, and lower percentages of Arc-expressing neurons that did rats in the MECS
group. There was no difference in the proportion of Arc-expressing LEC neurons between the AA and AB
groups. Aged rats in the AA and AB groups exhibited a reduction in the percentage of LEC neurons
expressing Arc compared to adult rats, while aged rats in the CC group did not.
If LEC neural populations represented information about the experience of track running
in the presence of odors, then a higher percentage of neurons would express Arc during the AA
and AB conditions than during CC conditions. If distinct odor stimuli were represented by
different neural ensembles, and repeated stimuli reactivated stable neural ensembles, then the
AB condition would induce Arc expression in a higher total percentage of LEC neurons across
epochs than would the AA condition. We found that behavioral condition had a significant effect
on the total percentage of LEC neurons that expressed Arc (GLMM, X2(2) = 72.85, p < 0.0001).
As expected, rats in the MECS group had a higher proportion of Arc-expressing neurons
Superficial LEC Deep LEC a. b.
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compared to rats in the AA, AB, and CC groups (Figure 5). Additionally, rats in the CC group
had a significantly lower proportion of Arc-expressing neurons than rats in the AA, AB, and
MECS groups (Figure 5). There was no significant difference in the overall percentage of cells
that expressed Arc between the rats in the AA and AB groups (GLMM, superficial X2(1) = 0.16,
p > 0.5; deep X2(1) = 0.36, p > 0.5).
Age significantly affected the percentage of LEC neurons with Arc mRNA for rats in the
AA and AB groups (GLMM, superficial X2(1) = 7.38, p < 0.01; deep X2(1) = 5.25, p < 0.05), but
not for rats in the CC group after correcting for multiple testing (Kruskal-Wallis, superficial X2(1)
= 4.27, p > 0.05, deep X2(1) = 1.96, p > 0.1). Adult rats had consistently higher proportions of
LEC neurons with Arc mRNA than did aged rats during the track running behavior in the
presence of odors (Figure 5).
Layer also had a significant effect on the percentage of neurons that expressed Arc
(GLMM, X2(1) = 62.33, p < 0.0001). A significantly higher proportion of neurons had Arc mRNA
in deep LEC than in superficial LEC (Figure 5). However, there was no interaction between
layer and age (GLMM, X2(1) = 0.34, p > 0.5).
Distribution of Arc mRNA across subcellular compartments
To investigate how populations of neurons were activated by repeated (AA) and distinct
(AB) odor experiences while track running, we assessed the subcellular compartmentalization of
Arc mRNA. As a result of the tightly regulated kinetics of activity-induced Arc expression,
neurons activated during the first epoch exhibited cytoplasmic Arc mRNA (Cyto+), and neurons
activated during the second epoch exhibited nuclear Arc mRNA (Nuc+). Neurons activated at
both time points were double-labelled with nuclear and cytoplasmic Arc mRNA (Dbl+).
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Figure 6 Percentage of LEC neurons activated by two behavioral epochs (AA, AB) or non-
behavioral control conditions (CC). Nuc+ indicates activation during the second epoch, Cyto+ indicates
activation during the first epoch, and Dbl+ indicates activation during the first and second epochs. For rats
in the AA and AB groups, we observed a higher proportion of Nuc+ than Dbl+ neurons and a higher
proportion of Dbl+ than Cyto+ neurons, across both superficial and deep layers. Deep layers exhibited a
higher proportion of activated cells than did superficial layers. Adult rats exhibited higher percentages of
activated neurons than did aged rats in the AA and AB, but not CC, conditions.
A significant proportion of double-labelled LEC neurons in rats from the AA and AB
groups would be consistent with the stable population representation of the first and second
epochs. Behavioral condition did not have a significant effect on the percentage of neurons that
expressed Arc when assessing the AA and AB groups alone (Figure 6, GLMM, X2(1) = 0.074, p
> 0.5). But, the AA and AB rats’ Arc expression patterns were significantly different from those
of the CC rats (GLMM, X2(2) = 72.3, p < 0.0001). This reflects the same effect of behavioral
condition, but not odor condition, on localized Arc expression as on total percentage of Arc-
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expressing neurons in Figure 5. Rats in the CC condition had limited Arc expression in all
subcellular compartments, and the percentage of neurons with nuclear Arc mRNA was slightly
higher than the percentages of cytoplasmic positive and double-labelled neurons (Kruskal-
Wallis, X2(2) = 181.64, p < 0.0001). There was neither an effect of age nor layer on the
percentage of neurons expressing Arc for rats in the CC group (Figure 6, Kruskal-Wallis, age
X2(1) = 3.32, p > 0.06; layer X2(1) = 0.53, p > 0.4).
Age significantly affected the percentage of neurons with Arc mRNA in the nucleus,
cytoplasm, or both (Figure 6, GLMM, X2(1) = 8.16, p < 0.005). As in Figure 5, Figure 6 shows
that aged rats in the AA and AB groups had a lower proportion of nuclear positive, cytoplasmic
positive, and double-labelled neurons than did adult rats under the same conditions. An
exception to this pattern occurred in rats from the AA group; in deep LEC layers, adult rats did
not have a higher proportion of nuclear positive neurons than did aged rats. As aforementioned,
no age effect was observed in the rats in the CC group.
Layer also had a significant effect on the percentage of neurons with nuclear and
cytoplasmic Arc mRNA (GLMM, X2(1) = 65.42, p < 0.0001); deep layers had higher proportions
of neurons expressing Arc than did superficial layers (Figure 6). No interaction between age and
layer was observed (GLMM, X2(1) = 1.1, p > 0.2).
Arc mRNA localization within each neuron indicated the activity history of principal cells
during the first and second behavioral epochs. The subcellular compartmentalization of Arc
mRNA had a significant effect on the percentage of LEC neurons that expressed Arc (Figure 6,
GLMM, X2(2) = 2188.2, p < 0.0001). A higher percentage of LEC neurons had Arc mRNA in the
nucleus than in the cytoplasm (Figure 6). Furthermore, the proportion of nuclear positive cells
was greater than the proportion of double-labelled cells (GLMM, X2(1) = 513.17, p < 0.0001),
and the proportion of double-labelled cells was greater than the proportion of cytoplasmic
positive cells (GLMM, X2(1) = 627.86, p < 0.0001). This effect held in all age groups and layers
for rats in the AA and AB groups.
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Discussion
The main novel findings of this experiment are that (1) track running in the presence of
odors elevates the activity of neurons in lateral entorhinal cortex (LEC) in both young and aged
rats, above that of non-behavioral controls. Interestingly, a higher proportion of neurons are
activated in the deep layers of LEC, which receive hippocampal input, than in the superficial
layers. (2) Changing the composition of the odors between the first and second behavioral
epochs does not alter the proportion of active neurons. But, surprisingly, more cells reach Arc
activation thresholds during the second epoch than the first. (3) The proportion of neurons
activated by this behavioral experience was decreased in aged compared to adult rats. There
are at least two possible explanations for these data: the higher order representation of
multimodal experience by LEC is either sharpened or reduced by aging. This problem awaits
future investigation.
LEC population activity is elevated during behavior
Traversing a track in the presence of odors induced an increase in the proportion of
neurons that expressed Arc in superficial and deep LEC in adult and aged rats. This is
consistent with the idea that LEC processes incoming non-spatial information from olfactory
areas and perirhinal cortex (PRC). In fact, 30% of neurons in LEC were activated during the AA
and AB behavioral conditions, above the 6% activated by the non-behavioral control condition.
In medial entorhinal cortex (MEC), identical AA and AB behavioral conditions induced a similar
increase in neuron activity of 32% between behavioral groups and the non-behavioral control
group (Liang, Lister, & Barnes, 2013 thesis). This finding is consistent with our expectations and
implicates the LEC in participating in the representation of features of the behavioral
experience.
LEC population activity is not affected by altered odor stimuli
An objective of this investigation was to determine how complex odor experiences are
represented on a population scale, if at all, by neurons in LEC, which receive substantial inputs
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from olfactory cortex. Contrary to our expectations, the proportion of neurons with Arc mRNA,
and thus the proportion of neurons activated during the two behavioral epochs, failed to
discriminate between repeated (AA) and distinct (AB) behavioral conditions. Because altering
the odor sets did not affect the overall population activity, the active circuit composition in LEC is
unlikely to directly represent information about specific odorants. The similarity of neural
activation patterns between these two behavioral conditions is not likely to have resulted from
an inability to discriminate the A and B odor sets on a perceptual level, as the odor stimuli were
quite diverse in their chemical structures. In fact, aged rats only show deficits in behavioral
discrimination of odorants when the stimuli are extremely similar in structure, and when carbon
chain length differs by 3 or less carbons (Yoder et al., 2017). Additionally, the failure of
population activation to differentiate repeated and distinct odor conditions does not necessarily
imply that LEC does not contribute to odor information processing; rather, it suggests that LEC
circuits may stably represent complex odor experiences regardless of their unique chemical
constituents. This aligns with the view that, unlike primary sensory areas, neural representations
by higher order association cortices including LEC do not directly correspond to individual
sensory stimuli.
While the catFISH method does reflect active circuit composition, it does not reflect how
many action potentials were generated by a given neuron. It is conceivable, however, that
modulated firing rates could contribute to a more complex representation of odor combinations
through a rate coding mechanism. PRC circuits feed directly into LEC circuits, so it would not be
surprising if these regions shared analogous coding mechanisms. Akin to PRC object fields,
LEC principal neurons increase their firing rates at the locations of objects (Deshmukh,
Johnson, & Knierim, 2012). The persistent activity of neurons across the A and B epochs in the
present experiment may reflect stable representation of the ramekins, which did not differ
between the two experiences, but are still likely to be represented as proximal objects by LEC
Comrie 20
(Tsao, Moser, & Moser, 2013). Nevertheless, the population representation of 3D object stimuli
in LEC remains unknown.
More neurons participated in the second behavioral epoch
A benefit of the Arc catFISH approach over traditional electrophysiological methods is
the ability to track the activity of the same individual neurons – and tens of thousands of them –
across time points. An unexpected finding in these data was the markedly higher proportion of
nuclear positive cells compared to cytoplasmic positive cells in the AA condition. Even though
the environmental stimuli and amount of exposure were constant across the two epochs, 12% of
neurons were activated during the first epoch, while 27% were activated during the second. The
participation of more than double the number of LEC neurons during the second epoch
suggests that LEC neuron activation may be sensitive to some sort of priming by a similar past
experience. For example, the first exposure to the environment may induce action potentials
and Arc expression in a subset of LEC neurons and may induce subthreshold depolarization of
another subset of neurons. The subthreshold depolarizations could mediate increased
excitability of those principal cells, which could then be more likely to spike and transcribe Arc
mRNA during the second epoch.
This pattern of activation was also observed in an unpublished study of rat LEC with a
different behavioral paradigm (Lister, Clasen, Hartzell, Burke, & Barnes, 2011 poster). Lister et
al. showed that a higher proportion of neurons expressed Arc during the second epoch of an
object exploration task than during the first epoch, independent of the objects present. This
pattern of activation is consistent with our findings in LEC during track running. However, unlike
in LEC, in MEC, equal proportions of neurons were activated in the first and second epochs of
an identical track running task (Liang et al., 2013 thesis). This corroborates the functional
distinction between medial and lateral subdivisions of EC. Moreover, the participation of more
LEC neurons upon a second exposure to an environment is not specific to track running, and
may generalize to other behaviors.
Comrie 21
Aging reduced the proportion of active LEC neurons
Another primary aim of this work was to ascertain how aging affects the participation of
large-scale neural circuits during behavior. We found that aged rats in both behavioral
conditions had a reduced proportion of neurons that expressed Arc. There was no age
difference in Arc-expression in non-behavioral controls. Thus, the age-related hypoactivity in
deep and superficial LEC was specific to the behavior conditions. These data suggest that aged
rats have a sparser representation of the track running experience. The reduction may reflect a
more refined and efficient population code, or a weaker representation with diminished
information content. In either case, aging of the LEC may alter the behaviorally-relevant inputs
from superficial LEC to the hippocampus. Furthermore, aging may modify the outputs from deep
LEC to neocortical regions as well as subcortical areas such as the septum, amygdala, striatum,
and thalamus.
The behaviorally-induced age effect cannot be explained by aged rats completing fewer
laps and having fewer exposures to the environment than did adult rats. In fact, on average,
aged rats completed two more laps per run session than did adult rats. The age effect was also
not due to a simple reduction in number of LEC cells in aged rats, as LEC neuron number is
preserved in aged Fischer 344 rats (Merrill et al., 2001). Age-related changes in MEC activity
are also unlikely to cause the effect observed in LEC, because under the same track running
behavioral conditions, aging failed to alter the proportion of activated MEC neurons (Liang et al.,
2013 thesis).
One possible cause for the age-related decrease in LEC principal cell recruitment during
track running is a reduction in excitation and long-range inhibition from PRC. Aged rats’ PRC
putative interneurons and excitatory neurons both have reduced firing rates compared to those
of adults during track running with objects on the track (Maurer, Burke, Diba, & Barnes, under
revision). Furthermore, as in LEC, fewer principal neurons are recruited during behavior in aged
rat PRC (Burke et al., 2014). PRC neurons are known to target GABAergic LEC neurons, and
Comrie 22
GABAergic PRC neurons in particular have been shown to terminate on GABA-negative
neurons in LEC (Apergis-Schoute, Pinto, & Paré, 2007; Pinto, Fuentes, & Paré, 2006). No direct
evidence for PRC-LEC disinhibition has been shown as of yet. The idea that muted excitation of
PRC neurons would carry forward to LEC principal cells would align with our findings of
hypoactivity in aged LEC. Dampened long-range inhibition from PRC interneurons to LEC
interneurons would also be consistent with our findings, although there is no report at present
that this disinhibitory mechanism exists. The effects of feedforward inhibition from PRC to
principal cells in LEC is less easily explained by our results. An understanding of LEC-PRC
circuitry on this level is critical to clarify how aging in PRC may mediate changes in LEC and
thereby hippocampal circuit activity in the aging brain.
Another possible explanation for the reduced proportion of Arc-expressing neurons after
behavioral experiences could be diminished transcriptional activity by aged LEC principal cells.
In fact, in aged hippocampal granule cells, there is a decrease in levels of Arc transcription in
addition to a lower number of neurons that express Arc during a behavioral task (Penner et al.,
2011). No such behavioral correlates of the present age effect were identified in this experiment,
but it is possible that age-related activity changes in LEC may contribute to cognitive-behavioral
deficits such as in fine odor perception discrimination (Yoder et al., 2017).
LEC changes may contribute to hippocampal dysfunction in aging
This study revealed a difference between the behaviorally-induced activity in deep and
superficial LEC, with a consistently higher proportion of neurons activated in deep than in
superficial layers of LEC. This layer effect was not modulated by age, so it is likely to reflect the
different anatomical circuit relationships and functional roles of superficial versus deep LEC.
The relatively higher proportion of activated neurons in deep layers is consistent with the idea
that efficient and sparse hippocampal codes become more distributed in subsequent levels of
output (Barnes, McNaughton, Mizumori, Leonard, & Lin, 1990). Yet, it is essential to point out
that LEC circuitry is not a simple superficial-input/deep-output region for the hippocampus. The
Comrie 23
layers of LEC are interconnected by both principal cells’ axons and interneurons, and some
inputs target apical dendrites of deep, not just superficial, EC principal neurons (Canto et al.,
2008). Nevertheless, we did not observe differences in the effect of age on superficial and deep
subdivisions of LEC, so we do not have evidence that age-related changes in hippocampal
circuits were reflected by, or exaggerated in, deep LEC.
The LEC is in a position to contribute to the age-related dysfunctions known to occur in
the hippocampus proper. The hippocampus undergoes subregion-specific changes with age:
CA1 place cells inappropriately remap in familiar environments, while CA3 place cells fail to
remap in new environments (Barnes et al., 1997; Wilson, Ikonen, Gallagher, Eichenbaum, &
Tanila, 2005). CA3 also becomes hyperexcitable with age (Robitsek et al., 2015). It is unclear
how age-related behaviorally-induced hypoactivity in LEC fits into the age effects observed in
these varied subregions, because superficial LEC projects directly to DG, CA3, and distal CA1.
Future work that examines and manipulates LEC neural activity in a cell-type- and connectivity-
pattern-specific manner will be critical to dissect how aging of the diverse components of LEC
circuits alter subregional hippocampal functions.
In summary, these findings suggest that while LEC plays a role in representing features
of episodic experiences, changing odor stimuli fails to alter population activity. Activity of these
circuits is more likely to correspond to a complex representation of the experience rather than
specific stimulus features. The hypoactivity in aged LEC likely alters inputs to the hippocampus
and outputs descending to neocortical and subcortical areas. In contrast to PRC and MEC
neurons, LEC neurons are more likely to participate during a second behavioral exposure than
upon the initial behavioral experience. Furthermore, the effect of aging on behaviorally-relevant
LEC activation is neither observed in MEC nor echoed across other target hippocampal
subregions. These observations suggest that LEC is vulnerable to aging in a unique way. The
question of whether a sparser network representation results in maintained, improved, or
reduced cognitive and behavioral function across the lifespan awaits future investigation.
Comrie 24
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