RESEARCH ARTICLE
Loss of small GTPase Rab7 activation in prion infection
negatively affects a feedback loop regulating neuronal
cholesterol metabolism
Received for publication, August 24, 2022, and in revised form, December 11, 2022 Published, Papers in Press, January 7, 2023,
https://doi.org/10.1016/j.jbc.2023.102883

Pearl Cherry1,2 , Li Lu1,2, Su Yeon Shim1,2, Vincent Ebacher2, Waqas Tahir1,2 , Hermann M. Schatzl1,2,
Samia Hannaoui1,2, and Sabine Gilch1,2,*
From the 1Calgary Prion Research Unit, Department of Comparative Biology & Experimental Medicine, Faculty of Veterinary
Medicine, and 2Hotchkiss Brain Institute, Cumming School of Medicine, University of Calgary, Calgary, Alberta, Canada

Edited by Elizabeth Coulson
Prion diseases are fatal and infectious neurodegenerative
diseases that occur in humans and animals. They are caused by
the misfolding of the cellular prion protein PrPc into the in-
fectious isoform PrPSc. PrPSc accumulates mostly in endoly-
sosomal vesicles of prion-infected cells, eventually causing
neurodegeneration. In response to prion infection, elevated
cholesterol levels and a reduction in membrane-attached small
GTPase Rab7 have been observed in neuronal cells. Here, we
investigated the molecular events causing an impaired Rab7
membrane attachment and the potential mechanistic link with
elevated cholesterol levels in prion infection. We demonstrate
that prion infection is associated with reduced levels of active
Rab7 (Rab7.GTP) in persistently prion-infected neuronal cell
lines, primary cerebellar granular neurons, and neurons in the
brain of mice with terminal prion disease. In primary cerebellar
granular neurons, levels of active Rab7 were increased during
the very early stages of the prion infection prior to a significant
decrease concomitant with PrPSc accumulation. The reduced
activation of Rab7 in prion-infected neuronal cell lines is also
associated with its reduced ubiquitination status, decreased
interaction with its effector RILP, and altered lysosomal posi-
tioning. Consequently, the Rab7-mediated trafficking of low-
density lipoprotein to lysosomes is delayed. This results in an
impaired feedback regulation of cholesterol synthesis leading
to an increase in cholesterol levels. Notably, transient over-
expression of the constitutively active mutant of Rab7 rescues
the delay in the low-density lipoprotein trafficking, hence
reducing cholesterol levels and attenuating PrPSc propagation,
demonstrating a mechanistic link between the loss of
Rab7.GTP and elevated cholesterol levels.

Prion diseases or transmissible spongiform encephalitis are
invariably fatal and infectious neurodegenerative diseases
caused by the misfolding of the cellular prion protein PrPc into
the infectious and aggregation prone isoform called PrPSc.
PrPSc is the main if not the only component of prions and
accumulates in the brains of infected individuals (1). This
* For correspondence: Sabine Gilch, sgilch@ucalgary.ca.

© 2023 THE AUTHORS. Published by Elsevier Inc on behalf of American Society for
BY license (http://creativecommons.org/licenses/by/4.0/).
pathogenic conversion of PrPc into PrPSc is triggered by a direct
physical interaction between the two isoforms, inducing a
conformational change in the PrPc structure from a predomi-
nant alpha helical to a beta sheet–rich structure (2, 3). This
results in the distinct biochemical features of PrPSc such as
partial resistance to protease treatment and detergent insolu-
bility (4, 5). Prion diseases occur in humans and other mam-
mals and are characterized by the deposition of amyloid-like
PrPSc deposits, spongiosis, astrogliosis, and progressive
neuronal loss (6, 7). Human prion diseases include
Creutzfeldt–Jakob disease (CJD), which is mainly sporadic in
origin (8); genetic forms, e.g., fatal familial insomnia and
Gerstmann–Sträussler–Scheinker syndrome (9, 10); and the
infectiously acquired forms of the disease such as variant CJD
and Kuru (11, 12). All prion diseases are invariably fatal and
have no curative treatment or prophylaxis available to date (13).

The cellular prion protein PrPc is a
glycosylphosphatidylinositol-anchored plasma membrane pro-
tein that localizes to lipid rafts, which are membrane micro-
domains rich in cholesterol (14–18). It has been suggested that
in prion-infected cells PrPc encounters PrPSc in lipid rafts, in
multivesicular bodies, and in the recycling endosomes, whereby
PrPSc induces the conformational change of PrPc into the in-
fectious PrPSc (19–24). Concomitant with PrPSc accumulation,
an increased expression of cholesterogenic genes has been
observed in prion-infected neuronal cell lines and primary
neurons, as well as in the hippocampus of preclinical mice
infected with scrapie prions (25, 26). Defects in cholesterol
metabolism are also reflected by an increased accumulation of
cholesteryl esters in prion-infected cells and mice (27).
Increased cellular cholesterol levels upon prion infection are
partly attributed to a reduced cholesterol efflux from prion-
infected cells, resulting from a reduced expression of
cholesterol-24 hydroxylase (Cyp46A1) and an altered distribu-
tion of ATP-binding transporter cassette A1 (ABCA1) away
from lipid rafts on the cell surface (28, 29). Furthermore,
distinct alterations in vesicular trafficking are evident upon
prion infection, including an impaired post-Golgi trafficking of
proteins to the plasma membrane (30) and retrograde axonal
trafficking in motor neurons of prion-infected mice (31).
J. Biol. Chem. (2023) 299(2) 102883 1
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Loss of active Rab7 in prion infection impairs cholesterol metabolism
Enlarged early endosomes in the brains of patients with CJD
(32) and the accumulation of abnormal and distorted lysosomes
resulting in reduced autophagosome turnover (33) indicate that
prion infection negatively affects the maturation of endosomes
to lysosomes. Along the same line, previous findings from our
group have highlighted that the membrane association of Rab7
is reduced in prion-infected neuronal cells, which consequently
leads to a reduced lysosomal acidification and degradation (34).

Rab7 belongs to a class of small GTPases, which undergo
tight regulation through an activation cycle. Rab activation is
mediated by the guanine nucleotide exchange factors (GEFs),
which induce a GDP to GTP exchange. Active Rab proteins
exist in the GTP bound form and are tethered by prenylation
to vesicle membranes, where they exert their functions by
interacting with the effector proteins. Guanine activating
proteins catalyze the hydrolysis of GTP to GDP, rendering
Rab-GDP, which is cytosolic and inactive (35, 36).

In this study we have investigated the role of Rab7 in the
upregulation of cholesterol levels because of its critical func-
tion in endocytic trafficking and cholesterol metabolism. Rab7
plays an important role in the endosome to the late endosome
(LE) transition. It interacts with the Rab7 interacting lysosomal
protein (RILP) and facilitates LE/autophagosome fusion with
lysosomes (37) and acidification of the lysosomes (38). Rab7
also mediates the movement of lysosomes on microtubules to
the positive or minus end of the cell by differentially inter-
acting with FYVE and coiled-coil domain autophagy adaptor 1
(FYCO1) and RILP, respectively (39–41). Furthermore, it is
involved in the retrograde trafficking of cargo from endosomes
to the trans-Golgi network via its interaction with components
of the retromer complex (42), as well as in the transport of
cargo to the lysosomes (43, 44).

Notably, expression of a dominant-negative mutant of Rab7
inhibited the trafficking of low-density lipoprotein (LDL) to
the lysosomes and its degradation (45, 46). Hence, we hy-
pothesized that the reduced membrane association of Rab7
observed in prion infection is causally linked to the impair-
ments in cholesterol metabolism. We found that prion infec-
tion is associated with a loss of Rab7 activation (Rab7.GTP),
likely due to compromised ubiquitination, in prion-infected
neuronal cell lines, primary neurons, and neurons in prion-
infected mouse brains. However, the loss of Rab7.GTP is a
dynamic process upon de novo infection of primary cerebellar
granular neurons (CGNs), and cell type specific in prion-
infected mouse brains. The reduction of Rab7.GTP is paral-
leled by an impaired lysosomal trafficking of LDL and,
consequently, aberrant feedback regulation of cholesterol
synthesis. Overexpression of a constitutively active mutant of
Rab7 partially rescues the lysosomal transport of LDL and
reduces cholesterol levels and PrPSc propagation in prion-
infected neuronal cells.

Our study has portrayed the significant involvement of
aberrant Rab7 function in prion infection at different stages,
and the implications of its loss in function, reflected by the
impairments in LDL trafficking, which culminates in an
upregulated cellular cholesterol metabolism in prion-infected
neuronal cells.
2 J. Biol. Chem. (2023) 299(2) 102883
Results

Prion infection is associated with reduced Rab7 activation

We have described previously that prion infection is asso-
ciated with reduced membrane attachment of Rab7, but the
total levels of Rab7 remain unaltered (34), which indicates a
compromised activation status of Rab7. Hence, we quantita-
tively analyzed the levels of endogenous active Rab7
(Rab7.GTP) in N2a cells persistently infected with 22L prions
(termed 22L-N2a) compared with uninfected N2a cells by
immunofluorescence (IF) experiments. The presence of PrPSc

in the 22L-N2a cells was confirmed by PrPSc-specific staining
after GdnCl denaturation and confocal microscopy (Fig. 1A).
We observed a significant reduction of active Rab7 in 22L-N2a
cells as compared with the uninfected cells (Fig. 1, B and C).
Since Rab7 is mainly attached to late-endosomal/lysosomal
membranes and is important for lysosomal maturation (43),
we also analyzed the levels of lysosomal associated membrane
protein (Lamp1), a common marker for lysosomes and its
colocalization coefficient with active Rab7 (Fig. 1, B and C).
We found that these parameters were significantly reduced
upon 22L prion infection. This is in accordance with our
previous findings of a defective lysosomal maturation process
in prion-infected neuronal cells (34). A similar significant
reduction of active Rab7 was also observed in 22L-prion-
infected CAD5 cells (22L-CAD5) (Fig. S1), demonstrating that
it was not a cell line–specific effect.
Kinetics of Rab7 activation during de novo prion infection of
cerebellar granular neurons

To study the kinetics of the loss of Rab7.GTP levels and
confirm its physiological relevance, we tracked Rab7.GTP
levels in response to de novo prion infection of CGN cultures.
Successful de novo 22L-prion infection of CGN cultures was
confirmed by the detection of PrPSc by IF assay upon GdnCl
denaturation (Fig. S2A). A progressive increase in the intensity
of PrPSc staining was observed from 1 day post infection (DPI)
to 5 DPI, whereas the mock-infected CGN cultures were
negative. Surprisingly, at the very early stages of infection (1
DPI), we detected a significant increase in the levels of active
Rab7 and in its colocalization with Lamp1 in 22L-infected
CGN cultures compared with the mock-infected control
CGNs (Fig. 2, A and B). At the later stages of infection,
concomitant with the increase in PrPSc levels (5 DPI), a
reduction of active Rab7 and its colocalization with Lamp1 was
observed (Fig. 2, C and D), consistent with our findings in the
neuronal cell lines persistently infected with 22L prions.
However, the overall levels of Rab7 increased from 1 DPI to 5
DPI in 22L-infected CGN, despite a loss in the levels of active
Rab7 (Fig. 2, E and F). Overview images are included in
Figure SF 2b, 2c, and 2d.
Prion infection reduces Rab7 ubiquitination and effector
interactions in cell culture

Next, we investigated in more detail the consequences
of reduced Rab7 activation upon prion infection. We



Figure 1. Prion infection reduces the levels of active Rab7 in N2a cells. A, 22L-N2a cells were treated with 6 M GdnCl to detect PrPSc signals after
probing with anti-PrP antibody (4H11). B, N2a and 22L-N2a cells were probed with anti-Rab7-GTP (green) and anti-Lamp1(red) antibodies and imaged using
confocal microscopy. C, fluorescence intensity was quantified from 10 different fields of view, which approximately amounts to 300 cells per experiment.
Three independent experiments have been conducted with results concurrent with the one depicted here. Unpaired t test was used to analyze the sta-
tistical significance between different groups, and the results are summarized in Table S1. The error bars indicate the standard deviation.

Loss of active Rab7 in prion infection impairs cholesterol metabolism
studied the interaction of Rab7 with its ubiquitous inter-
actor RILP (39, 47) by subjecting N2a and 22L-N2a cells
overexpressing EGFP-tagged wildtype Rab7 (WT-Rab7) to
an immune pull-down assay. We demonstrated that the
interaction of WT-Rab7 with RILP is significantly reduced
in 22L-N2a cells (Fig. 3A). In addition, we observed an
altered distribution of lysosomes in 22L-N2a cells, indic-
ative of an impaired RILP-mediated anterograde trafficking
of lysosomes to the perinuclear region (Fig. 3B). The levels
of proteinase K (PK)-resistant PrPSc in the WT-Rab7-
transfected cells were confirmed by immunoblotting
(Fig. S3).
J. Biol. Chem. (2023) 299(2) 102883 3



Figure 2. Kinetics of Rab7 activation in de novo prion infection of primary cerebellar granular neurons. A, mock- and 22L prion-infected CGNs were
probed with anti-Rab7 GTP and anti-Lamp1 antibodies and subjected to immunofluorescence experiment and confocal microscopy at 1 DPI. B, fluorescence
intensity of Rab7-GTP and its weighted colocalization coefficient with Lamp1 at 1 DPI. C, mock- and 22L prion-infected CGNs were probed with anti-Rab7
GTP and anti-Lamp1 antibodies and subjected to immunofluorescence experiment and confocal microscopy at 5 DPI. D, fluorescence intensity of Rab7-GTP
and its weighted colocalization coefficient with Lamp1 at 5 DPI. E, mock- and 22L prion-infected CGNs at 1 DPI and 5 DPI were probed with anti-Rab7
antibody and subjected to immunofluorescence staining and confocal microscopy. F, fluorescence intensity of total Rab7 levels at 1 DPI and 5 DPI. The
fluorescence intensities and weighted colocalization coefficients were quantified from 10 different fields of view, which approximately amounts to 300 cells
per group. Three independent experiments have been conducted with concurrent results with the one depicted here. Statistical tests used and the results
are summarized in Table S1. The error bars indicate the standard deviation. To provide an overview, low-magnification images of Figure 2, A, C and E are
shown in SF 2b, c, and e, with the boxes indicating the image area shown in here.

Loss of active Rab7 in prion infection impairs cholesterol metabolism
Rab7 is posttranslationally modified by ubiquitination,
which is important for its membrane association and for
facilitating interactions with effector proteins (48, 49). There-
fore, we analyzed the Rab7 ubiquitination status upon prion
infection. We observed that ubiquitination of Rab7 is signifi-
cantly compromised in 22L-N2a cells (Fig. 3C).
4 J. Biol. Chem. (2023) 299(2) 102883
Prion infection reduces Rab7 effector interactions in vivo
To verify our findings in prion-infected cell lines and pri-

mary neurons, we studied the Rab7 activation status in brains
of mice infected with 22L prions harvested at the terminal
stage of clinical disease and brains of age-matched mock-
infected mice by IF. Surprisingly, we found an increased level



Figure 3. Impaired Rab7 effector interactions in 22L-N2a cells. A, N2a and 22L-N2a cells were transfected with GFP-tagged WT-Rab7 and subjected to
immune pull-down with anti-GFP nanobody-coupled agarose beads and subjected to immunoblotting with anti-RILP antibody. The quantitative analysis of
the RILP signal normalized to the amount of GFP-tagged WT-Rab7 levels after stripping these membranes with methanol is also shown. B, immunofluo-
rescence images depicting the localization of lysosomes, by probing with anti-Lamp1 antibody in N2a and 22L-N2a cells as visualized by the maximum
intensity projections of the z-stack sections, obtained by confocal microscopy. All confocal images are representative of five fields of view from three
independent experiments. Statistical significance was evaluated using the unpaired t test. The dashed and dotted lines in the violin plot depict the median
and the lower and the upper quartiles of values, respectively. C, N2a and 22L-N2a cells were transfected with GFP-tagged WT-Rab7 and subjected to
immune pull-down with anti-GFP nanobody-coupled agarose beads and subjected to immunoblotting, with anti-ubiquitin antibody. Quantitative analysis
of the Ub-Rab7 signal normalized to the amount of GFP-tagged WT-Rab7 levels after stripping these membranes with methanol is also shown. Unpaired t
test was used to analyze the statistical significance between different groups from three or more independent experiments, and the results are summarized
in Table S1. The error bars indicate the standard deviation.

Loss of active Rab7 in prion infection impairs cholesterol metabolism
of Rab7-GTP staining in GFAP-positive astrocytes in the 22L-
infected mouse brains. This colocalization of Rab7-GTP with
astrocytes was not observed in the mock-infected control. On
the contrary, cells positive for Rab7-GTP in the control retain
a neuron-like morphology, but the signal from such cells is not
evident in 22L-infected brain slices (Fig. 4A).

Next, we performed immune pull-down assays with anti-
Rab7-GTP antibody in brain homogenates of mice infected
with 22L prions at the terminal stage and of age-controlled
mock-infected mice. We observed an increased level of
Rab7-GTP in 22L-brain homogenate (BH) with respect to the
control (Fig. 4, B and C). This increased level of Rab7-GTP
likely originates from astrocytes that are highly positive for
Rab7-GTP (Fig. 4A). Also, the total level of Rab7 protein in the
whole brain homogenate of the 22L-infected mice was
increased, evident by the increased immune reactivity of Rab7
in the input fraction used in the immune pull-down assay,
when equal amounts of mock-BH and 22L-BH were subjected
to the assay (Fig. 4B). Despite high levels of active Rab7, its
canonical interaction with RILP is significantly reduced in the
J. Biol. Chem. (2023) 299(2) 102883 5



Figure 4. Impaired Rab7 effector interactions in prion-infected mouse brain homogenates. A, brain sections from terminal mock- and 22L prion-
infected mice were subjected to immunofluorescence experiments by probing with anti-active Rab7 and anti-GFAP antibodies. Mock-BH and 22L-BH
(Input; 50%) were subjected to an immune pull-down assay with the anti-Rab7-GTP antibody (Beads) and probed with B) anti-Rab7 antibody (* is
nonspecific band) and the signal was (C) quantitatively analyzed from three independent experiments. Mock-BH and 22L-BH were subjected to an immune
pull-down assay with the anti-Rab7-GTP antibody and probed with (D) anti-RILP antibody and the signal was (E) quantitatively analyzed from three in-
dependent experiments. Unpaired t test was used to analyze the statistical significance between different groups, and the results are summarized in
Table S1. The error bars indicate the standard deviation.

Loss of active Rab7 in prion infection impairs cholesterol metabolism
22L-BH compared with the mock-BH (Fig. 4, D and E). This
suggests the existence of differential Rab7 interactors in as-
trocytes compared with neurons.
The effect of prion infection in cholesterol feedback regulation

Prion infection is associated with elevated cholesterol levels
(25–28). We show that this phenotype is sustained in 22L-
CAD5 cells and the de novo infected CGN cultures (5 DPI) at
the free cholesterol levels as visualized by the filipin staining
(Fig. 5, A and B) and in 22L-CAD5 cells also at the mRNA level
of de novo cholesterogenic genes such as 3-hydroxy 3-methyl-
glutaryl-coenzyme A reductase (HMGCoAr), low density li-
poprotein receptor (LDLR), and sterol-C4-methyl oxidase like
gene (Sc4mol) (Fig. 5C). In contrast to the mock-infected
CGNs, the intensity of filipin staining in 22L-CGNs at 5 DPI
6 J. Biol. Chem. (2023) 299(2) 102883
was very distinct and more punctate at the plasma membrane
enriched with free cholesterol (Fig. 5B). Notably, at 5 DPI we
also observed a loss of Rab7 activation in 22L-CGN cultures
(Fig. 2B). Inspired by this observation and previous studies
describing the importance of Rab7 in regulating cholesterol
metabolism (45, 50), we investigated the potential Rab7-
mediated mechanisms leading to cholesterol accumulation
upon prion infection. To this end, we analyzed the cholesterol
feedback regulation in 22L-CAD5 cells upon lipid starvation
and repletion conditions, compared with uninfected CAD5
cells. We observed that, upon lipid starvation (+-, Fig. 5D),
CAD5 cells significantly upregulate HMGCoAr expression by
about 4-fold compared with CAD5 cells grown in complete
media, which mimics the steady-state supply of lipids (–). On
the contrary, 22L-CAD5 cells upregulate the cholesterol levels
only 2-fold under lipid starvation, compared with the control



Figure 5. Prion infection leads to an impaired cholesterol feedback regulation resulting in elevated cholesterol levels. A, CAD5 and 22L-CAD5 cells
and (B) CGN and 22L-GGN cultures (5 DPI) were subjected to filipin staining, signals were quantified, and statistical analysis was done using an unpaired
Student t test. C, gene expression analysis of the de novo transcription of cholesterogenic genes HMGCoAr, LDLR, and Sc4mol by RT-qPCR in 22L-CAD5 cells
with respect to uninfected CAD5 cells. The gene expression levels are expressed as fold change with respect to the CAD5 cells after normalizing to the actin
mRNA levels. D, CAD5 and 22L-CAD5 cells were grown in lipid-deficient medium for 16 h and the regulation of HMGCoAr gene expression on lipid

Loss of active Rab7 in prion infection impairs cholesterol metabolism

J. Biol. Chem. (2023) 299(2) 102883 7



Loss of active Rab7 in prion infection impairs cholesterol metabolism
22L-CAD5 cells (Fig. 5D). When we analyzed the absolute
change in the HMGCoAr gene expression upon lipid starva-
tion in 22L-CAD5 cells, by adding up the elevated levels of
HMGCoAr at the steady state (�2-fold; Fig. 5C) with that
upon lipid starvation (�2.3-fold; Fig. 5D), we found that it
amounts to a total 4-fold increase in the HMGCoAr mRNA
levels, similar to what we have observed in CAD5 cells after
lipid starvation (Fig. 5E). This suggests that the mechanistic
regulation in 22L-CAD5 cells to detect cholesterol deficits is
intact. Yet, when there is a steady supply of cholesterol, 22L-
CAD5 cells mimic a partially lipid-starved state, triggering de
novo cholesterol synthesis (Fig. 5C). To analyze further the
feedback regulation in cholesterol metabolism we supple-
mented the cells with 50 μg/ml LDL for 5 h after starvation.
Then, the changes in HMGCoAr mRNA levels in CAD5 and
22L-CAD5 cells upon lipid repletion (++; Fig. 5F) were
analyzed and compared with its levels at lipid starvation (+-;
Fig. 5F). In CAD5 cells, there was an efficient feedback regu-
lation on lipid repletion, apparent by the �70% reduction in
HMGCoAr mRNA. On the contrary, in 22L-CAD5 cells, the
feedback regulation was compromised, resulting only in an
�55% reduction in the expression of HMGCoAr gene,
significantly different from the transcriptional reduction in
CAD5 cells. Hence, we conclude that the LDL-mediated
feedback regulation of de novo cholesterogenic gene expres-
sion is impaired in 22L-CAD5 as these cells could not sense
the LDL repletion as efficiently as the CAD5 cells.

Prion infection leads to an impairment of LDL trafficking

To analyze the reason behind an inefficient feedback regu-
lation of cholesterol metabolism upon repletion with LDL in
prion-infected cells, we studied the trafficking of LDL to the
early endosomes, the Golgi complex, and the lysosomes. We
conducted pulse-chase experiments to determine the transport
of Dil-LDL (3,30-dioctadecylinocarbocyanine–low-density li-
poprotein) to different compartments by analyzing its coloc-
alization with different organelle markers such as Rab5 for the
early endosomes, Rab6 for the Golgi complex, and Lamp1 for
the lysosomes. The PrPSc levels in 22L-CAD5 cells were
confirmed by IF assay (Fig. S4A). We observed an increased
colocalization of Dil-LDL with Rab5 in 22L-CAD5 cells
compared with the control CAD5 cells, which is indicative of a
delayed exit of LDL from Rab5-positive early endosomes
(Fig. 6, A–C). Since the Golgi complex (51) and the lysosomes
are the two sites from where the LDL-derived cholesterol ex-
erts its regulatory effects on cholesterol biosynthesis from the
endoplasmic reticulum (ER), we analyzed the trafficking of
LDL to the lysosomes and the Golgi apparatus. We found a
decreased colocalization of Dil-LDL with the Rab6-positive
Golgi complex (Fig. 7, A–C) and the Lamp1-positive late
starvation (+-), with respect to the CAD5 and 22L-CAD5 cells grown in complete
expression on lipid-starved state in CAD5 cells and 22L-CAD5 cells. F, CAD5
replenished with 50 μg/ml of LDL for 5 h. The regulation of the HMGCoAr gen
with respect to the lipid-starved CAD5 and 22L-CAD5 cells (+-), was analyzed by
independent experiments. Unpaired t test was used to analyze the statistica
analysis using the �Sídák multiple comparisons test was performed for multiple
standard deviation.

8 J. Biol. Chem. (2023) 299(2) 102883
endosomal/lysosomal compartments (Fig. 8, A and B) in
22L-CAD5 cells compared with CAD5 cells, indicating an
impaired trafficking of LDL to these organelles. Since Rab7
mediates the transport of LDL (45), we transiently overex-
pressed the constitutively active mutant of Rab7 (Rab7-Q67L)
for 48 h (Fig. S4B) to determine whether this will rescue LDL
trafficking in 22L-CAD5 cells. Rab7-Q67L-transfected 22L-
CAD5 cells were subjected to pulse-chase studies with Dil-
LDL, and we observed that the delay in the trafficking of
LDL to the lysosomes was rescued by the overexpression of
Rab7-Q67L (Fig. 8, C and E). Furthermore, we consistently
observed an increased uptake of Dil-LDL in 22L-CAD5 cells
compared with uninfected cells (Fig. 8, A, B and D). Increased
LDL uptake has been shown to occur upon knockout of the
Rab7-GEF C18orf8 (50). Hence, the increased uptake of LDL
observed upon prion infection could be due to an impairment
in Rab7 activation and is also partially rescued upon Rab7-
Q67L overexpression (Fig. 8, C and D).

Overexpression of Rab7-Q67L reduces cholesterol levels and
prion propagation

The role of Rab7 on cholesterol levels and prion propa-
gation was deduced upon transient overexpression of the
wildtype Rab7, the constitutively active mutant of Rab7
(Rab7-Q67L), and the trans-dominant negative mutant
(Rab7-T22N) in 22L-N2a cells. We conducted the Amplex
red cholesterol assay to detect the total level of cholesterol
in these cells (Fig. 9, A–C). We observed that over-
expression of Rab7-Q67L reduced the total cholesterol
levels in 22L-N2a cells, comparable with the levels of
cholesterol in uninfected N2a cells. Restoring LDL traf-
ficking (Fig. 8C) and hence the feedback regulation mech-
anism could be one way by which the active mutant exerts
this effect. Overexpression of the dominant negative mutant
of Rab7 also reduced the total cholesterol levels in 22L-N2a
cells. However, 22L-N2a cells overexpressing WT-Rab7
retained an elevated cholesterol level, consistent with pre-
vious findings in prion-infected cells (26) and confirming a
defect in Rab7 activation.

Furthermore, we showed that the effect of WT-Rab7 and its
mutants on cholesterol levels correlated with the levels of
PrPSc in 22L-N2a cells (Fig. 9, D and E). WT-Rab7 over-
expression reduced neither the PrPSc levels nor the elevated
cholesterol levels in 22L-N2a cells. Overexpression of the
active mutant of Rab7 and the dominant negative mutant of
Rab7 reduced the PrPSc levels in 22L-N2a cells, along with a
reduction in cholesterol levels (Fig. 9A). Hence, we conclude
that rescuing the impairment in Rab7 activation has beneficial
effects in prion-infected neurons by reducing both cholesterol
levels and PrPSc propagation.
medium (–), was analyzed by RT-qPCR. E, absolute levels of HMGCoAr gene
and 22L-CAD5 cells were grown in lipid-depleted media for 16 h (+-) and
e expression on lipid starvation followed by lipid repletion conditions (++),
RT-qPCR. Statistical significance was determined from at least three or more
l significance between two groups; one-way ANOVA followed by post hoc
groups. The results are summarized in Table S1. The error bars reflect the



Figure 6. Delayed exit of LDL from Rab5-positive early endosomes upon prion infection. CAD5 and 22L-CAD5 cells were pulsed with 200 μg/ml Dil-LDL
for 40 min at 4 �C and chased at 37 �C for 1 hour, fixed and probed with anti-Rab5 antibody, and subjected to immunofluorescence and confocal mi-
croscopy. Confocal images of LDL colocalized with Rab5 in (A) CAD5 cells and (B) 22L-CAD5 cells at the end of 1-h chase at 37 �C. C, quantitative analysis of
the weighted colocalization coefficient of LDL with Rab5 was analyzed from 15 different fields of view, which approximately amounts to 400 cells per
experiment. Three independent experiments have been conducted with concurrent results with the one depicted here. Unpaired t test was used to analyze
the statistical significance between different groups, and the results are summarized in Table S1. The error bars indicate the standard deviation. The arrows
indicate the localization of LDL to Rab5-positive early endosomes.

Loss of active Rab7 in prion infection impairs cholesterol metabolism
Discussion
Previous research has highlighted the importance of

cholesterol, lipid rafts (52–54), and the late endosomes in the
process of prion conversion (21–23, 55–57). Abrogating either
the formation of lipid rafts (19, 20, 52) or late endosome
maturation negatively impacts PrPSc propagation (23). In
addition, it has been shown that prion infection causes an
increase in cholesterogenic gene expression and free choles-
terol in neurons and mouse models (25, 26) and a reduction in
membrane association of Rab7 (34). Here, we demonstrate for
the first time that impairments observed in cholesterol meta-
bolism in prion-infected neurons are related to a loss in Rab7
activation.

Our study presented here on the dynamics of Rab7 activation
in the context of prion infection shows that one of the initial
changes that occurs in prion-infected CGN cultures is an in-
crease in the levels of total and active Rab7 at 1 DPI. This in-
crease in total Rab7, initially accompanied by an increase in
active Rab7 is presumably a cellular response to facilitate
degradation of prion protein aggregates, considering the well-
documented roles of Rab7 in lysosomal maturation, cargo
transport and sorting, and autophagy (37–44). Results from this
study (Fig. 9) and previous studies (23) have shown that
expression of a dominant negative mutant of Rab7 (Rab7-
T22N) interferes with prion propagation. This might indicate
a role of Rab7 in facilitating prion conversion at the early stages
of infection. It has also been shown that Rab7 is a direct
interactor of PrPc and its knockdown leads to a shift in the
localization of PrPc to Rab9-positive endosomes (58). Building
on this information, one of the ways by which the increased
levels of active Rab7 induces prion propagation might be
through an increased trafficking of PrPc to late endosomes,
facilitating its interaction with PrPSc and hence inducing its
conversion. Another possibility would be that, at early stages
after de novo infection, an increased level of active Rab7 triggers
an enhanced lysosomal activity inducing a proteolytic cleavage
of the PrPSc or disaggregation of PrPSc, yielding a PrPSc inter-
mediate (seed), which is more prone to conversion. Previous
studies have shown that inhibiting the proteolytic cleavage of
PrPres, which results in an N-terminally truncated C2 fragment,
by treating prion-infected cell lines with calpain inhibitors
prevents PrPSc accumulation (59). However, this idea is
J. Biol. Chem. (2023) 299(2) 102883 9



Figure 7. Delayed retrograde trafficking of LDL to Rab6-positive Golgi compartment upon prion infection. CAD5 and 22L-CAD5 cells were pulsed
with 200 μg/ml Dil-LDL for 40 min at 4 �C and chased at 37 �C for 1 hour, fixed and probed with anti-Rab6 antibody, and subjected to immunofluorescence
and confocal microscopy. Confocal images of LDL colocalized with Rab6 in (A) CAD5 cells and (B) 22L-CAD5 cells at the end of 1-h chase at 37 �C.
C, quantitative analysis of the weighted colocalization coefficient of LDL with Rab6 was analyzed from 15 different fields of view, which approximately
amounts to 400 cells per experiment. Three independent experiments have been conducted with concurrent results with the one depicted here. Unpaired
t test was used to analyze the statistical significance between different groups, and the results are summarized in Table S1. The error bars indicate the
standard deviation. The arrows indicate the localization of LDL to Rab6-positive Golgi.

Loss of active Rab7 in prion infection impairs cholesterol metabolism
conflicted by another study in which calpain inhibitors did not
have any effect on prion propagation and hence more thorough
research is required in this aspect (60). Lysomotrophic agents
and cysteine protease inhibitors also reduce PrPSc propagation,
again indicating the role of lysosomes/late endosomes and
hence indirectly Rab7, in prion conversion (23, 61).

However, at later stages of prion infection, we observed a
significant reduction in the levels of active Rab7, which
negatively affects vesicular trafficking and cholesterol meta-
bolism in prion-infected neurons. This decrease in active Rab7
is observed in prion-infected CGNs at 5 DPI, neuronal cell
lines, and neurons in terminally diseased mice. In the prion-
infected CGNs, it correlates with the increased accumulation
of PrPSc (Fig. S2A) and free cholesterol levels (Fig. 5B), indi-
cating a direct link with PrPSc propagation and elevated
cholesterol levels. It is intriguing that the loss of active Rab7
levels occurs despite an increase in the total Rab7 pool, which
sustains throughout the course of infection. This observation is
in line with an earlier study demonstrating upregulation of
Rab7 levels in CJD and Alzheimer disease (62). It further
shows that availability of Rab7 is not a limiting factor for Rab7
10 J. Biol. Chem. (2023) 299(2) 102883
activation and indicates that the activation process is impaired.
PrPSc propagation occurring at 5 DPI results in the presence of
PrPSc attached to host cell membranes, which might alter the
membrane environment, resulting in reduced Rab7 activation.
We have also shown that the ubiquitination status of Rab7
upon prion infection is reduced. Rab7 is posttranslationally
modified by attachment of ubiquitin at K38 and K191.
Compromised ubiquitination of K38 results in a reduced
membrane association of Rab7 and decreased effector binding
(48). K191 deubiquitination increases the stability of Rab7-
GTP and hence its interaction with RILP (49). Since the
membrane association of Rab7 (34) and its interaction with
RILP are lost upon prion infection, we conclude that ubiq-
uitination at K38 is compromised. This same phenotype is
observed also in autosomal recessive early-onset Parkinson
disease, indicating the existence of common mechanistic
pathways in these two neurodegenerative disorders (48).

In brains of prion-infected, terminally sick mice most of the
active Rab7 localizes to astrocytes. This is complemented by a
study on ischemic stroke where the role of Rab7 in inducing
reactive astrogliosis and glial scar is discussed. Treating the rat



Figure 8. Impaired LDL trafficking to lysosomes upon prion infection. CAD5 and 22L-CAD5 cells were pulsed with 200 μg/ml Dil-LDL for 40 min at 4 �C,
fixed, probed with anti-Lamp1 antibody, and subjected to immunofluorescence and confocal microscopy. Confocal images of LDL colocalized with Lamp1
at the end of 1-h chase at 37 �C in (A) CAD5 cells, (B) 22L-CAD5 cells, and (C) 22L-CAD5 cells transiently overexpressing the Rab7-Q67L mutant. Quantitative
analysis of (D) mean LDL intensity per cell, (E) the weighted colocalization coefficient of LDL with Lamp1 was analyzed from 15 different fields of view, which
approximately amounts to 400 cells per experiment. Three independent experiments have been conducted with concurrent results with the one depicted
here. One-way ANOVA followed by post hoc analysis using Turkey multiple comparisons test was used to analyze the statistical significance, and the results
are summarized in Table S1. The error bars indicate the standard deviation. The arrows indicate the localization of LDL to lysosomes.

Loss of active Rab7 in prion infection impairs cholesterol metabolism
models of ischemic stroke with a Rab7 receptor antagonist
inhibits astrogliosis and attenuates brain atrophy (63). Hence,
treatment of prion-infected mice with the Rab7 receptor
antagonist is a potential strategy to reduce astrogliosis and
ameliorate neurological deficits associated with it. Interest-
ingly, even though there is an overall increase in the levels of
active Rab7 in the 22L-infected brain homogenate, the inter-
action of Rab7 with its canonical effector protein RILP is
reduced.
There is an intricate association between cholesterol levels
and prion propagation. First, PrPSc conversion occurs in lipid
rafts, which are microdomains at the plasma membrane rich in
cholesterol. Many therapeutic strategies to remediate prion
propagation aimed at reducing cholesterol levels and hence
reducing prion propagation (20, 29, 52, 54). Second, prion
infection induces cholesterogenic gene expression and
elevated cholesterol levels in neurons. Hence, another aim of
this study was to elucidate whether Rab7 plays a role in the
J. Biol. Chem. (2023) 299(2) 102883 11



Figure 9. Overexpression of active mutant of Rab7 (Q67L) reduces cholesterol levels and PrPSc propagation in 22L-N2a cells. A, 22L-N2a cells were
transiently transfected with GFP-tagged WT-Rab7 and its mutants (Q67L-Rab7, T22N-Rab7) for 48 h; cells were lysed, and the lysates were subjected to
Amplex red cholesterol assay followed by the normalization of total cholesterol levels to protein concentrations. All normalized cholesterol levels are
represented as a fold change with respect to the normalized cholesterol levels in N2a cells. B, PrPSc levels in the 22L-N2a cells were analyzed by subjecting
cell lysates to PK digestion and immunoblotting with anti-PrP antibody (4H11). C, immunoblots depicting the transfection efficiency of different Rab7
mutants in the 22L-N2a cells. D, 22L-N2a cells were transfected twice in the course of 96 h with EGFP (control), GFP tagged WT-Rab7, and its mutants (Q67L-
Rab7, T22N-Rab7). Cell lysates were subjected to PK digestion or not and probed using anti-PrP antibody 4H11, anti-GFP antibody, and anti-actin. E,
quantitative analysis of the PrPSc levels in response to overexpression of WT-Rab7 and its different mutants in 22L-N2a cells. Statistical analyses were
performed from three or more independent experiments using one-way ANOVA followed by post hoc analysis using the Turkey multiple comparisons test,
and the results are summarized in Table S1. Error bars reflect the standard deviation.

Loss of active Rab7 in prion infection impairs cholesterol metabolism
elevation of cholesterol levels observed upon prion infection
(25–28). In de novo prion-infected CGN cultures, we observed
an increase in cholesterol levels at the time of the reduction of
active Rab7 levels, concurrent with an increased PrPSc accu-
mulation. We have found that 22L-CAD5 cells mimic a
lipid-starved state due to a delay in the Rab7-mediated LDL
trafficking from early endosomes to late endosomes/lysosomes
12 J. Biol. Chem. (2023) 299(2) 102883
and the Golgi complex (45), where LDL is hydrolyzed to
release free cholesterol for cellular needs including feedback
regulation.

The de novo synthesis of cholesterol is under tight regula-
tion at the ER depending on the amount of sterols available to
bind the ER resident proteins INSIG (Insulin induced genes)
and Scap (SREBP [sterol regulatory element binding protein]



Loss of active Rab7 in prion infection impairs cholesterol metabolism
cleavage activating protein). When oxysterols are bound to
INSIGs and cholesterol is bound to Scap, SREBP cleavage in
the Golgi complex and the subsequent transcription of de novo
cholesterogenic genes are inhibited (64–66). Our results and
previous studies (26) provide strong evidence for an impair-
ment in this regulation of the cholesterol feedback in prion-
infected cells. This impairment is likely a result of deficient
levels of LDL hydrolyzed to free cholesterol that is made
available to the ER, due to a delay in LDL trafficking and the
absence of lysosomal-ER contact sites. The cholesterol
generated by LDL hydrolysis is delivered to the limiting
membrane of the late endosome/lysosomes by NPC2 (50) and
exported across the membrane with the help of NPC1 to the
ER via lipid-binding proteins such as oxysterol-binding protein
(OSBP)-related protein 1L (ORP1L) (67), StARD3 (StAR-
related lipid transfer domain-3) (68), and OSBP-related pro-
tein 5 (ORP5) (69) for feedback regulation (67). Both the
export of cholesterol to the late endosome/lysosomes and
cholesterol egress mediated via the tethering of ORP1L with
the VAP (VAMP-associated proteins) at the ER membrane are
Rab7-mediated processes. In the absence of active Rab7, both
processes are likely compromised, and cells gain very little
cholesterol from the incoming LDL. The lysosomal–ER con-
tact sites are necessary for the transfer of cholesterol from the
limiting membrane of the lysosome to the ER. Moreover,
lysosome positioning we observe in prion-infected cells is
similar to that reported of ORP1L knockout cells, supporting
our assumption that other Rab7 effector interactions such as
that with ORP1L might be reduced in prion infections (67).
We also observe an increase in the uptake of LDL in 22L-
CAD5 cells. This is reminiscent of the phenotype observed
upon knock-down of the Rab7-GEF C18orf8 and can also be a
direct consequence of the observed upregulated expression of
LDLR in prion infections (26, 50). Altogether, these findings
are strong evidence that the impairments in LDL metabolism
observed upon prion infection are associated with the reduced
levels of active Rab7. In conclusion, the upregulated synthesis
of de novo cholesterol coupled with the increased LDL uptake
due the loss of active Rab7 levels gives rise to elevated
cholesterol levels upon prion infection.

We provide further evidence for a direct association be-
tween upregulation of cholesterol metabolism and reduced
active Rab7 in prion infection by overexpression of Rab7-
Q67L, which partially rescues the increased uptake of LDL
and the trafficking of LDL to the lysosomes, thereby reducing
the total cholesterol levels in prion-infected neurons. Parallel
to this, we also see a reduction in cholesterol levels upon
transient overexpression of the dominant negative mutant of
Rab7. Even though contradictory, this observation is justified
by the absence of PrPSc propagation due to the inhibition of
multivesicular body maturation (23), a proposed intracellular
site of prion conversion. The importance of Rab7 in reducing
prion propagation has been shown by the overexpression of
the active mutant of Rab7 (Rab7-Q67L). This reduction is
most probably attained by enhanced lysosomal degradation
and reduction of cholesterol levels; the two processes
compromised upon prion infection with the loss of active
Rab7. However, Yim et al. present conflicting results to our
study in that PrPres levels are not reduced upon the over-
expression of active mutant of Rab7 (23). One reason for this
contradiction may be based on differences in the expression
levels of this Rab7 mutant, as our results have been attained at
high levels of expression of this protein.

Some physiological processes mediated via the Rab7-RILP
axis are EGFR degradation (70), multivesicular body biogen-
esis (70), dynein-mediated lysosomal transport and positioning
(47, 71), regulation of vacuolar ATPase activity, and, hence,
lysosomal acidification (38, 72). EGFR degradation and lyso-
somal acidification were shown to be altered upon prion
infection (34). In the current study, we demonstrate that the
interaction of Rab7 with RILP is reduced in 22L-N2a cells. In
addition, we provide evidence that, in response to the
compromised RILP interaction with Rab7, the anterograde
transport of lysosomes is compromised. The lysosomal motility
and distribution have critical implications in the physiology of
neurons especially in the context of autophagosome clearance
(73–75). Impaired autophagosome turnover has been impli-
cated in many neurodegenerative diseases including Alzheimer
disease (76, 77) and prion diseases (33, 78, 79). Lysosomal
maturation is characterized by the gradual decrease in the pH
of the endocytic vesicles, concomitant with the acquisition of
Rab7 and Lamp1 proteins triggering anterograde movement
toward the nucleus via association with the dynein-dynactin
motor proteins (73, 80). Another factor facilitating antero-
grade movement of lysosomes/autophagosomes is an adequate
cholesterol level through the formation of a Rab7-RILP-ORP1L
tripartite complex, whereas low cholesterol conditions induce
the dispersal of the lysosomes to the cell periphery (40). Hence,
inefficient clearance of autophagosomes observed in prion
diseases could be the result of inappropriate lysosomal posi-
tioning, maturation, and fusion with autophagosomes (75, 81,
82). It is interesting to note here that, despite the high cellular
cholesterol levels in prion infection, a peripheral lysosomal
distribution is observed, contradictory to previously established
results (40). This is because prion infection mainly results in an
increased cholesterol content in the plasma membrane, while
intracellular accumulation of cholesterol in LEs as in NPC
disease causes immobilization of these organelles in the peri-
nuclear region (83).

This study highlights the intricate relationship between
cholesterol accumulation and prion propagation. A schematic
representation of our study on how a loss in Rab7 activation
can lead to elevated cholesterol levels is depicted in Figure 10.
Many neurodegenerative diseases present with similar im-
pairments associated with vesicle trafficking and lysosomal
maturation defects (36). In the case of prion infections, we
have demonstrated that vesicular trafficking defects due to
reduced Rab7 activation can result in elevated cholesterol
levels. Further studies are needed to determine whether
elevated cholesterol levels are implicated in an acceleration of
prion propagation and/or neurodegeneration, or whether it is a
protective mechanism.
J. Biol. Chem. (2023) 299(2) 102883 13



Figure 10. Loss in Rab7 activation results in elevated cholesterol levels upon prion infection. Prion infection results in a reduced activation of Rab7,
which has the following consequences in an infected cell. 1. Trafficking of low-density lipoproteins (LDL) to the late endosomes or lysosomes is impaired. 2.
The interaction of Rab7 with RILP is lost, which significantly impacts lysosomal transport and maturation. 3. The delay in LDL trafficking and reduced
interaction of Rab7 with (Rab7 interacting lysosomal protein) RILP might consequently impact the interactions with the oxysterol-binding protein related
protein 1L (ORP1L) required to facilitate cholesterol egress, which in turn mediates the feedback regulation of cholesterol to the ER resulting in de novo
cholesterol synthesis. 4. The retrograde LDL trafficking to the Golgi complex is also affected, potentially due to a reduced interaction of Rab7 with Vps 35.
Adapted from (36).

Loss of active Rab7 in prion infection impairs cholesterol metabolism
Experimental procedures

Ethics approval

All experiments involving animals were approved by the
University of Calgary Health Sciences Animal Care Committee
according to the guidelines issued by the Canadian Council for
Animal Care. Mouse tissues used in the current study were
derived from infection experiments published previously (84).

Reagents and antibodies

All chemicals were purchased from Sigma unless stated
otherwise. OptiMEM GlutaMAX, Dulbecco’s modified Eagle’s
medium, fetal bovine serum (FBS), penicillin and streptomycin
(P/S), and phosphate buffer saline (PBS) were from Gibco.
Bovine growth serum (BGS) was from HyClone. Transfection
reagents lipofectamine-LTX and lipofectamine 2000 were
purchased from ThermoFisher Scientific. The Alexa Fluor
conjugated secondary antibodies were procured from Ther-
moFisher Scientific and used at 1:500 concentration. Rabbit
14 J. Biol. Chem. (2023) 299(2) 102883
polyclonal anti-RILP (ab140188), rabbit polyclonal anti-Lamp1
(ab24170), mouse monoclonal anti-Rab7 (ab50533), and
mouse monoclonal anti-EGFP (ab184601) antibodies were
procured from Abcam. Rabbit monoclonal anti-Rab5 (C8B1)
and anti-Rab6 (D37C7) antibodies were procured from Cell
Signalling. Rabbit polyclonal anti-GFAP and mouse mono-
clonal anti-ubiquitin antibodies were procured from Novus
Biologicals. Mouse monoclonal anti-active Rab7 (26923)
antibody was procured from New East Biosciences. The PrP
monoclonal antibody 4H11 used in this study has been
described (85).
Cell culture and transfections

The cell lines N2a (ATCC-CCL131; murine neuroblastoma)
(26, 86) and catecholaminergic neuronal cell line CAD5 (336)
were grown in Opti-MEM GlutaMAX media containing 10%
FBS and 10% BGS, respectively, in the presence of 1% P/S, at
37 �C in a humidified 5% CO2 atmosphere. These neuronal cell



Loss of active Rab7 in prion infection impairs cholesterol metabolism
lines persistently infected with the mouse adapted scrapie
strain 22L (22L-N2a; 22L-CAD5) were grown under the same
conditions. 22L-N2a cells were transfected using
Lipofectamine-LTX reagent with pEGFP plasmids expressing
EGFP-fusions with wildtype Rab7 (WT), the constitutively
active mutant (Rab7-Q67L), and the dominant negative
mutant (Rab7-T22 N). Briefly, 24 h and 72 h post seeding of
250,000 cells, they were subjected to transfection with 2 μg of
plasmid DNA and 4 μl of LTX reagent per one 6-cm dish.
After 96 h, the cells were lysed as described (26) and subjected
to immunoblotting. 22L-CAD5 cells were transfected with the
pCDNA3.1 myc Rab7-Q67L mutant for 48 h for the LDL pulse
chase experiment described below using Lipofectamine 2000.
Briefly, 100,000 cells were seeded on 18-mm coverslips in
12-well plates and were transfected with 1 μg of plasmid DNA
and 2.5 μl of Lipofectamine 2000 reagent for 48 h.

Cerebellar granular neuronal culture and de novo prion
infection

CGN primary culture was prepared from 5- to 7-day post-
natal (P5-7) newborn C57Bl/6 mice (Charles River). Cere-
bellum of the newborn mice were mechanically extracted and
then enzymatically dissociated as described (87). CGNs were
seeded at a density of 1.9 x 103 cells/mm2 on a 12-well plastic
culture plate with 18-mm sterile cover glasses coated with
10 μg/ml poly-D-lysine. Cells were then cultured in Dulbecco’s
modified Eagle’s medium Glutamax I high glucose supple-
mented with 1% penicillin and streptomycin, 10% FBS (Euro-
Bio), 20 mM KCl, N2 and B27 neuronal supplements (Gibco),
and placed at 37 �C in a humidified 5% CO2 conditions. Prior
to infection, the CGN culture is composed of 95% neurons and
5% astrocytes (87). Hence to maintain them primarily as a
neuronal culture and to reduce astrocyte proliferation, 48 h
post seeding, the medium was supplemented with glucose
(1 mg/ml) along with the antimitotics uridine (10 μM) and
fluorodeoxyuridine (10 μM).

Brains of mock- and 22L-prion-infected mice at the termi-
nal stage of disease were homogenized in 5% (w/v) glucose.
These BHs were then sonicated prior to de novo prion infec-
tion. The CGN cultures were infected with these BHs at a final
concentration of 0.002% throughout the experiment. Samples
were processed at 1 DPI and 5 DPI for IF experiments.

Immunofluorescence and filipin staining

Cells were grown at 80% to 90% confluency on 18-mm
sterile cover glasses in 12-well plates and fixed with 4% para-
formaldehyde (Alfa Aesar) at room temperature (RT) for
20 min. Then they were washed thrice with PBS, permeabilized,
and blocked in a solution of 10% FBS and 0.01% Triton X-100
in PBS (PBSST) for 1 hour. To detect PrPSc-specific signals,
cells were treated with 6 M guanidinium chloride (GdnCl) for
7 min after blocking and probed with anti-PrP (4H11) antibody
as described (85). Otherwise, cells were incubated with primary
antibodies (in PBSST) at their respective working concentra-
tions for 1 hour at RT. The cells were then washed thrice in
PBS and were incubated in appropriate anti-rabbit/mouse–
Alexa dye coupled secondary antibodies (in PBSST) at their
respective dilutions for 1 hour. Samples were washed again
thrice with PBS and mounted on glass slides. Cells were imaged
with a 63× oil immersion objective lens using a Zeiss LSM 700
confocal microscope. Three-dimensional z-stacks were ac-
quired with a step size of 0.3 μm.

For filipin staining, following the fixation and the blocking
steps cells were treated with 125 μg/ml filipin (Sigma) in
PBSST for 2 h and imaged with a 63× oil immersion objective
lens using a Leica DMI3000 B fluorescence microscope.

Immunofluorescence staining of brain sections

Sagittal brain sections (5 μm thick) of mock- and 22L prion-
inoculated FVB mice at terminal stage of disease (84) were
used. Briefly, the paraffin-embedded brain sections were
deparaffinized and rehydrated in sequential washes using
xylene and ethanol (100%, 95%, 80%, 70%, and 0%), followed by
an antigen retrieval step carried out in 10 mM critic acid buffer
(pH 6.0) at high temperature (121 �C) and high pressure using
an instant pot (88). The sections were cooled at RT for 30 min,
washed once in TBS (10 mM Tris-HCl [pH 7.4], 150 mM
NaCl) for 10 min, and blocked in a solution of 10% goat serum
and 0.3% Triton X-100 in TBS for 1 h. This was followed by
primary antibody incubation (rabbit polyclonal anti-GFAP
(1:1500) and mouse active Rab7 antibody (1:50) in the block-
ing solution overnight at 4 �C in a humidifying chamber. The
slides were then washed twice in TBS with 0.05% Tween 20
(TBST) and twice in TBS for 10 min each. The slides were then
incubated with Alexa Fluor 488–conjugated goat anti-rabbit
(1:500) and Alexa Fluor 555–conjugated goat anti-mouse
secondary antibodies in the blocking solution for 1 h at
room temperature followed by two washes in TBST and two
washes in TBS for 10 min each. Coverslips were mounted
using fluorescent mounting medium (Agilent Dako). The brain
sections were imaged using an Olympus VS110-S5 virtual slide
scanner at 20×.

Lipid depletion and repletion experiments

CAD5 and 22L-CAD5 cells were grown in 6-cm dishes in
complete media (OptiMEM+10% BGS+P/S) for 21 h. For lipid
starvation, cells were thoroughly washed with PBS twice before
seeding of 1 × 106 cells in lipoprotein-deficient serum (LPDS)
(Kalen Biomedicals) media (OptiMEM+10% LPDS+P/S) for
16 h. For lipid repletion, cells were replenished with LPDS
media supplemented with LDL (50 μg/ml; Sigma) for 5 h. Cells
grown under these conditions at 85% to 90% confluency were
harvested at their respective experimental endpoints by lysing
them in 1 ml trizol. Lysates were stored at −80 �C for gene
expression studies using quantitative PCR (qPCR).

RNA isolation and quantitative reverse transcriptase–PCR

RNA isolation was carried out by the organic extraction
method. A volume of 200 μl of chloroform was added to the
cells lysed in trizol, vortexed for about 30 s, and left at RT for
5 min for the phase separation to take place. This was followed
by centrifugation at 12,000g for 15 min. The aqueous layer was
J. Biol. Chem. (2023) 299(2) 102883 15



Loss of active Rab7 in prion infection impairs cholesterol metabolism
carefully transferred to a new tube for RNA extraction. RNA
was precipitated by the addition of 500 μl of isopropyl alcohol,
left at RT for 10 min, and then centrifuged at 12,000g for
10 min. The supernatant was removed completely, and the
RNA pellet was washed with 1 ml of 75% ethanol twice by
vortexing, centrifugation, and removal of the supernatant. The
RNA pellet was air dried and dissolved in 25 to 30 μl dH2O.
cDNA synthesized from 1 μg of isolated RNA using Super-
script II Reverse Transcriptase (Invitrogen) and random
primers (Invitrogen) was subjected to quantitative PCR using
Fast SYBRTM Green Master Mix (Applied Biosystems). For
the qPCR cycle, samples were heated at 95 �C for 5 min and
amplified for 40 cycles at 95 �C for 3 s followed by 60 �C for
30 s. The primer sequences used for the gene expression study
of the cholesterogenic genes HMGCoAr, LDLR, and Sc4mol
are as listed below:

50-TTG TGA TTG GAG TTG GCA CC-30 (HMGCoAr-F),
50-CTC TAG GAC CAG CGA CAC AC-30 (HMGCoAr-R),
50-GAG TGT ATC CAT CGC AGC TG-30 (LDLR-F), 50-GAA
TTC ATC AGG TCG GCA GG-30 (LDLR-R), 50-AGC CCC
ACT TCC ACT GTC CA-30 (Sc4mol-F), 50-AAC ATG GCA
GCT AAT CTT CA-30 (Sc4mol-R). β-Actin was used as the
housekeeping gene to normalize the Ct values using the
following primers: 50-CTC AGG AGC AAT GAT CTT GAT-
30 (actin-F) and 50-TAC CAC CAT GTA CCC AGG CA-30

(actin-R). Relative quantification of a given gene expression as
a fold variation of the control was calculated using the delta–
delta Ct method (89).

Dil-LDL pulse chase experiment

CAD5, 22L-CAD5, and 22L-CAD5 cells transfected with
Rab7-Q67L grown at 80% to 90% confluency were washed with
PBS and then incubated with 100 μg/ml Dil-LDL (Thermo-
Fisher) at 4 �C for 40 min. This was followed by a washing step
with PBS to remove excess Dil-LDL. Then LPDS medium was
added to facilitate Dil-LDL uptake. Following this pulse of Dil-
LDL, cells were incubated at 37 �C for a chase period of 1 h
and were washed again with PBS. Cells were then processed
for IF staining and confocal microscopy as described above.

Immune pull-down assay in cells

N2a and 22L-N2a cells grown at 60% confluency in 6-cm
dishes were transfected with pEGFP plasmid (as control) and
pEGFP WT-Rab7 for 48 h and lysed in 200 μl of ice-cold lysis
buffer (10 mM Tris-Cl [pH 7.5], 150 mM NaCl, 0.5 mM
EDTA, 0.5% NP-40, 1 mM PMSF). Lysates from four plates
were pooled for one immune pull-down assay. The lysates
were placed on ice for 30 min and extensively pipetted every
10 min. The lysates were then centrifuged at 17,000g for
10 min at 4 �C. The supernatant (�800 μl) was transferred to a
precooled tube and diluted in 300 μl of dilution buffer (10 mM
Tris-Cl [pH 7.5], 150 mM NaCl, 0.5 mM EDTA) supple-
mented with 0.5 mM Pefabloc inhibitor. For the immune
pull-down assay, agarose beads with anti-GFP nanobodies
(ChromTek) were equilibrated in 500 μl ice-cold dilution
buffer by centrifugation at 2500g for 5 min at 4 �C and the
16 J. Biol. Chem. (2023) 299(2) 102883
supernatant was discarded. The diluted lysate was added to the
equilibrated beads and was rotated end over end for 3 h at
4 �C. The beads were then sedimented by centrifugation at
2500g and the flow through was discarded. The beads were
washed four times in 1 ml ice-cold wash buffer (10 mM Tris-
Cl [pH 7.5], 150 mM NaCl, 0.5 mM EDTA, 0.05% NP40) by
centrifuging them at 2500g and removing the supernatant.
After the last centrifugation step, the agarose beads were
resuspended in 80 μl of 3× Laemmli buffer and boiled at
100 �C for 10 min. The samples were then subjected to
immunoblotting. In some cases, the immunoblots were strip-
ped with methanol for 10 min and reprobed with the required
antibodies (anti-GFP) to normalize the levels of the proteins
studied by immune pull-down.
Immune pull-down assay in brain homogenate

Mock-infected (age-matched) and 22L-infected mouse brain
homogenates (10% w/v) at the terminal stages of prion disease
(stored at −80 �C) were prepared in lysis buffer (50 mM Tris-
Cl [pH 7.5], 250 mM NaCl, 0.5% Triton X-100 and protease
inhibitor cocktail [1×]) using a mechanical homogenizer (MP
Biomedicals FastPrep-24 Classic Instrument [MP Bio-
medicals]). The lysates were centrifuged at 3000 g, and the
supernatant was collected and subjected to Pierce bicincho-
ninic acid assay for protein quantification. Equal amounts of
protein were subjected to the immune pull-down assay by
overnight incubation with 2 μg of anti-active Rab7 antibody in
lysis buffer in the presence of protease inhibitor cocktail.
Following this, it was incubated with protein A Sepharose
beads (GE Healthcare) for 3 h at 4 �C with rotation. The beads
were washed with lysis buffer 5 times by centrifugation fol-
lowed by the removal of supernatant prior to the final sample
preparation by boiling the sample in 80 μl of 3× Laemmli
buffer for 10 min. The samples were then subjected to further
studies by immunoblotting.
Cell lysis, proteinase K digestion, and immunoblotting

Cell lysis, PK digestion to detect protease-resistant PrPSc,
and immunoblotting were done as described (26). Cell lysis was
carried out in 1 ml lysis buffer (10 mM Tris-Cl [pH 7.5],
100 mMNaCl, 10 mM EDTA, 0.5% Triton-X 100, 0.5% sodium
deoxycholate), and 500 μl was subjected to PK digestion
(20 μg/ml) at 37 �C for 30 min. The digestion was stopped by
the addition of 0.5 mM Pefabloc inhibitor. Proteins were
precipitated in methanol overnight at −20 �C, and the protein
was pelleted by centrifugation at 3500 rpm for 30 min and was
later dissolved in TNE buffer (Tris-Cl [pH 7.5], 150 mM NaCl,
and 5 mM EDTA). The samples were then processed for
immunoblotting after boiling in the appropriate amount of 3×
Laemmli buffer. The remaining undigested 500 μl of cell lysate
(PK-) was processed similarly and was used as a loading control
by probing for actin in the immunoblotting analysis. Chem-
iluminescence signals (Luminata western chemiluminescent
HRP substrate [Millipore Sigma]) were captured using a
ChemiDoc imager (Bio-Rad) or X-Ray films (Fujifilm).



Loss of active Rab7 in prion infection impairs cholesterol metabolism
Densitometric analysis was performed using Image lab software
(Bio-Rad, v6.0.1) or ImageJ.
Amplex red cholesterol assay

22L-N2a cells transfected for 48 h with pEGFP-Rab7 plas-
mids expressing EGFP-WT Rab7, EGFP-Rab7-Q67L, and
EGFP-Rab7-T22N and untransfected control N2a cells were
used. The cells were lysed as described (34) and centrifuged.
The postnuclear supernatant was used for the Amplex red
cholesterol assay (Invitrogen), bicinchoninic acid assay analysis,
and immunoblotting to determine the transfection efficiency.
Briefly, the total cholesterol levels were quantified as recom-
mended by the manufacturer’s instructions and were normal-
ized to the respective protein concentrations of the samples.
Image analysis

The weighted colocalization coefficients were obtained us-
ing the Zeiss Zen image acquisition software (ZEN 2012 SP5
[64 bit]; Release Version14.0.0.0) after the intensity thresholds
were set based on single probe controls. Imaris Cell 9.8 (Ox-
ford Instruments) was used to analyze filipin staining (2D
fluorescence images) and the Lamp1 3D distribution. For fili-
pin quantification of number of puncta per cell, the nuclei and
cells were defined based on the inverted filipin signal and the
smoothed filipin image, respectively, and the filipin puncta
segmentation was done on the original filipin image. This was
necessary for accurate cell separation. For the Lamp1 3D
distribution in cells, the nuclei and vesicles were segmented
based on their respective images, whereas the cells were
defined based on the Lamp1 images following histogram
equalization. Lamp1 distribution was quantified by the mean
vesicle distance from the nucleus calculated from the shortest
distance of each vesicle to the cell nucleus.
Statistical analysis

Statistical analysis was done with GraphPad Prism 9.0
software using either unpaired Student t test when comparing
two groups or one-way ANOVA followed by post hoc analysis
using the �Sídák or Tukey multiple comparisons test when
comparing multiple groups. Results are summarized in
Table S1. Graphs were plotted using GraphPad Prism 9.0, and
the bars represent mean ± SD. All experiments were con-
ducted at least 3 times.
Data availability

All data generated or analyzed during this study are
included in this article and the supporting information.

Supporting information—This article contains supporting
information.

Acknowledgments—This research was funded by grants from the
Alberta Prion Research Institute (#201300001 and #201600035) and
the Canadian Institute of Health Research (#PJT-173385).
Author contributions—P. C., S. G. conceptualization; V. E. formal
analysis; P. C., L. L., S. Y. S., S. H. investigation; W. T., H. M. S.
resources; P. C., S. G. writing – original draft; L. L., S. Y. S., V. E., W.
T., H. M. S., S. H. writing – review & editing; S. G. supervision; S. G.
funding acquisition.

Funding and additional information—S. G. was supported by the
Canada Research Program and P.C. received a University of Calgary
Eyes High Graduate Student Fellowship.

Conflict of interest—The authors declare that they have no conflicts
of interest with the contents of this article. The funders had no role
in the design of the study; in the collection, analyses, or interpre-
tation of data; in the writing of the manuscript; or in the decision to
publish the results.

Abbreviations—The abbreviations used are: BGS, bovine growth
serum; BH, brain homogenate; CJD, Creutzfeldt–Jakob disease; Dil-
LDL, 3,30-dioctadecylinocarbocyanine–low-density lipoprotein;
DPI, day post infection; FBS, fetal bovine serum; GEF, guanine
nucleotide exchange factor; IF, immunofluorescence; LDL, low-
density lipoprotein; LE, late endosome; LPDS, lipoprotein-deficient
serum; PK, proteinase K; qPCR, quantitative polymerase chain re-
action; RILP, Rab7 interacting lysosomal protein.

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