Invest Clin 64(4): 505 - 512, 2023 https://doi.org/10.54817/IC.v64n4a7
Corresponding autor. Jesús Alberto Mosquera-Sulbarán. Instituto de Investigaciones Clínicas “Dr. Américo Negrette”,
Facultad de Medicina, Universidad del Zulia, Maracaibo, Venezuela. E-mail: mosquera99ve@yahoo.com
Nuclear and cytoplasmic expressions
of the receptor for advanced glycation
end products (RAGE) in the rat central
nervous system.
Jesús Mosquera-Sulbarán1, Adriana Pedreáñez2, Yenddy Carrero1
and Catherina Peña1
1 Instituto de Investigaciones Clínicas “Dr. Américo Negrette”, Facultad de Medicina,
Universidad del Zulia, Maracaibo, Venezuela.
2 Cátedra de Inmunología, Escuela de Bioanálisis, Facultad de Medicina, Universidad
del Zulia, Maracaibo, Venezuela.
Keywords: RAGE; ligands; nucleus; cerebral cortex; cerebellum.
Abstract. The receptor for advanced glycation end products (RAGE) is a
transmembrane protein involved in the induction of inflammatory processes
and oxidative stress after interacting with its ligands on the cell surface. Lo-
calization on the cell surface is necessary for interaction with the ligands. This
study aimed to determine the expression of RAGE in different parts of the nor-
mal rat brain and cerebellum using the immunofluorescence technique. Sev-
eral cerebral cortex layers (molecular/granular layers: M/GL; pyramidal layer:
PL) and the hypothalamus were analyzed, as well as the molecular layer (CML)
and the granular layer (CGL) of the cerebellum. Cells with RAGE-positive nu-
clei were generally observed in the brain’s cerebral cortex and cerebellum. In
the M/GL, cells with different degrees of positivity in the nucleus and cyto-
plasm accompanied by RAGE-positive material in the adjacent extracellular
space were observed, and RAGE-positive material in the neuropile. Pyramidal
neurons presenting various degrees of nuclear RAGE-positive material budding
and cells with different degrees of nuclear and cytoplasmic positivity were ob-
served in PL. The hypothalamus showed a high number of cells with RAGE-
positive granules adjacent to the nucleus and in the cytoplasm; nuclei remained
negative. Many positive nuclei were observed in CML; they were scarce in CGL.
These data suggest the storage of RAGE at the nuclear and cytoplasmic levels
in healthy rats and hypothesize the possible translocation of this molecule to
the cell surface in pathological conditions.
506 Mosquera-Sulbarán et al.
Investigación Clínica 64(4): 2023
Expresión nuclear y citoplasmática del receptor para
compuestos de glicosilación avanzada en el sistema nervioso
central de la rata.
Invest Clin 2023; 64 (4): 505 – 512
Palabras clave: RAGE; ligandos; núcleo; corteza cerebral; cerebelo.
Resumen. El receptor para compuestos de glicosilación avanzada (RAGE)
es una proteína transmembrana involucrada en la inducción de procesos infla-
matorios y en el estrés oxidativo después de su interacción con sus ligandos en
la superficie celular. La localización de este receptor en la superficie celular es
necesaria para su interacción con sus ligandos. El objetivo de este estudio fue
determinar la expresión de RAGE en las diferentes partes del cerebro y cerebelo
de la rata normal. Mediante la utilización de técnicas de inmunofluorescencia
se analizaron varias capas de la corteza cerebral (capas molecular/granular:
CM/G; capa piramidal: CP) y el hipotálamo. Las capas molecular (CMC) y la
capa granular (CGC) del cerebelo fueron también analizadas. Se observaron
células con el núcleo positivo para RAGE tanto en cerebro como cerebelo.
En CM/G se apreciaron células con diversos grados de positividad para RAGE
acompañadas de material positivo para RAGE en el espacio extracelular adya-
cente y en la neuropila. En la CP se observaron neuronas piramidales presen-
tando diversos grados de gemación de material nuclear positivo para RAGE y
diversas células con diferentes grados de positividad nuclear y citoplasmática.
En el hipotálamo se apreciaron gran número de células expresando gránulos
positivos a RAGE tanto adyacente al núcleo como en el citoplasma; el núcleo
permaneció negativo. Alto número de núcleos positivos se apreciaron en la
capa CMC a diferencia de la capa CGC del cerebelo. Estos hallazgos sugieren
el almacenamiento del RAGE en el núcleo y en el citoplasma en la rata normal
e hipotetizan una posible translocación de esta molécula a la superficie celular
en condiciones patológicas.
Received: 26-11-2023 Accepted: 06-08-2023
INTRODUCTION
The receptor for advanced glycation end
products (RAGE) is a transmembrane protein
and a multireceptor belonging to the immu-
noglobulin superfamily, expressed on the cell
surface and capable of binding to various li-
gands, inducing cell activation, cell dysfunc-
tion, and tissue damage 1, 2. RAGE has been
implicated in various pathophysiological pro-
cesses such as neurodegenerative diseases
and infectious processes 1-3. After RAGE binds
to its ligand, pro-inflammatory processes in-
crease with the induction of pro-inflammato-
ry cytokines and oxidative stress, determin-
ing a vicious circle of inflammation mediated
by the overexpression of the nuclear tran-
scription factor kB (NF-kB) that leads to cell
damage 1,3. Traditionally, the interaction of
RAGE with its ligands at the cell surface level
inducing intracellular signals leading to pro-
inflammatory processes has been reported 4,
RAGE in rat cerebrum and cerebellum 507
Vol. 64(4): 505 - 512, 2023
5. The interaction of RAGE with its ligands in
the central nervous system is of paramount
importance in the induction of neurodegen-
erative diseases 3, 6-8; however, there is little in-
formation about the location of RAGE in cen-
tral nervous system cells in non-pathological
conditions. The present study is focused on
determining by immunohistochemical meth-
ods the location of RAGE in the rat central
nervous system under healthy conditions.
MATERIAL AND METHODS
This study used healthy male Sprague-
Dawley rats (weight 150 to 200 g) (N=10).
All rats had unlimited access to tap water
and food. All animals were euthanized, and
samples from rat cerebrum (including the hy-
pothalamus) and cerebellum were embedded
in Tissue-Tek (Miles, Inc, Diagnostic Division,
Kankakee, Illinois, United States), frozen in
acetone and dry ice, and stored at -70 ºC un-
til use. Cryostat sections (4 µm) from sam-
ples were treated with a rabbit anti-rat RAGE
antibody (5µg/mL: ab3611; Abcam, Cam-
bridge, United Kingdom) to analyze RAGE
brain expression. Rabbit immunoglobulin G
(IgG) in tissues was localized by a secondary
rhodamine-conjugated goat anti-rabbit IgG
at 5µg/mL (Sigma-Aldrich, St. Louis, Mis-
souri, USA). Antibody against a nonrelevant
antigen or normal rabbit serum was used as
the negative control. Sections were mounted
in a solution of p-phenylenediamine in phos-
phate-buffered saline‒glycerol and viewed un-
der an epifluorescent microscope (Axioskop,
Zeiss, Wetzlar, Germany). Positive cells were
expressed as the number of cells per 0.0625
µ2 from 20 randomly selected fields of the
brain or cerebellum. Experiments were per-
formed according to the ethical guidelines of
the committee of bioethical and biosecurity
of FONACIT (Caracas, Venezuela) following
the Guide for the Care and Use of Labora-
tory Animals (National Institutes of Health
Publication No. 8023, revised 1978) and the
committee of bioethics of the Universidad del
Zulia School of Medicine.
Statistical analysis was performed us-
ing GraphPad Prism, version 7.0 (GraphPad
Software, San Diego, USA). Measurement
data with normal distribution is represented
as mean ± standard deviation. For continu-
ous variables that were normally distributed,
differences between groups were determined
by ANOVA and the posttest of Bonferroni. A
p-value < 0.05 was considered to be statisti-
cally significant.
RESULTS
The analysis of different rat cerebrum
and cerebellum areas showed high reactivity
to the anti-RAGE antibody in several areas. At
the level of the cerebral cortex, positive cells
were observed in the molecular/granular lay-
er (M/GL) and the pyramidal layer (PL). Posi-
tive cells were seen in the cerebellum in the
molecular layer (CML) and less frequently in
the cerebellar granular layer (CGL). A high
number of positive cells was observed in the
hypothalamus (Fig. 1). Histological analysis
showed numerous cells with high nuclear
reactivity to the anti-RAGE antibody in M/
GL (Fig. 2). Likewise, cells with negative or
scarcely positive nuclei were found accompa-
nied by cytoplasmic and adjacent extracellu-
lar positive reactivity to RAGE, simulating a
comet.
Interestingly, extracellular RAGE-positive
areas without cell presence were observed (Fig.
3). Pyramidal neurons with highly positive nu-
clei and positive glial cells were observed in PL
(Figs. 4 and 5). RAGE-positive nuclei present-
ing structures resembling nuclear buds in pyra-
midal neurons were observed (Fig. 5). The cells
of the hypothalamus showed a high frequency
of cytoplasmic RAGE-positive granules but no
nuclear positivity (Figs. 1 and 6).
Nuclear expression of RAGE in the cere-
bellum was observed mainly in the CML, with
a low frequency of positive nuclei in CGL;
however, some cells showed granular cyto-
plasmic positivity in this layer. Purkinje cells
were found to be negative (Figs. 1 and 7).
508 Mosquera-Sulbarán et al.
Investigación Clínica 64(4): 2023
DISCUSSION
In this study, the expression of RAGE
in the rat central nervous system was mainly
limited to the cell nucleus and cytoplasm.
Functionally, RAGE is expressed on the cell
surface, where it interacts with various li-
gands to activate intracellular pathways that
produce a pro-inflammatory and oxidative
stress state 1-3, 6-8.
The presence of this receptor within the
cell nucleus observed in this study suggests a
nuclear function or represents a storage site
for a subsequent trajectory of this receptor
from the nucleus to the cell surface to exert
its functions. Previous studies have shown the
passage of intranuclear molecules to the cy-
toplasm 9-13, suggesting a possible cell surface
expression pathway for RAGE. In this regard,
the immunohistochemical findings of this re-
port show cerebral cells showing decreased
expression of nuclear RAGE accompanied by
increased cytoplasm expression and adjacent
extracellular RAGE-positive material. In ad-
dition, pyramidal neurons showed budding
of RAGE-positive nuclear material, and cells
with cytoplasm RAGE-positive granules were
observed, suggesting a possible nuclear-to-
cytoplasmic pathway.
The presence of RAGE in the nucleus
suggests its nuclear localization prior to its
synthesis, possibly as a storage site, as oc-
curs with the non-histone chromosomal pro-
teins “high mobility group” (HMG) that are
present in the cell nucleus bound to DNA 10,
12 and perform functions such as determi-
nation of nucleosomal structure and stabil-
ity, and binding of transcription factors to
their cognate DNA sequences 14. HMG can
be localized in the nucleus, cytoplasm, and
the extracellular space during some patho-
logical processes where it can interact with
Fig. 1. Expression of the receptor for advanced glyca-
tion end products (RAGE) in the rat central
nervous system. High nuclear expression of
RAGE was observed in the molecular/granular
layer of cerebral cortex and in the molecular la-
yer of the cerebellum. Cells from the hypotha-
lamus did not express nuclear RAGE but a high
number expressed cytoplasmic RAGE in a gra-
nular form. M/GL: molecular/granular layer;
PL: pyramidal layer; CGL: cerebellar granular
layer; CML: cerebellar molecular layer; HIPO:
hippocampus. * p<0.01 vs. PL, CGL, CML.
Fig. 2. Expression of the receptor for advanced
glycation end products (RAGE) in the mole-
cular/granular layer of the cerebral cortex.
A) Panoramic view where a large number of
positive nuclei can be observed. B) Detail.
Arrows: positive nuclei. Cross arrows: nega-
tive nuclei. Original magnification: A: x600;
B: x1000.
RAGE in rat cerebrum and cerebellum 509
Vol. 64(4): 505 - 512, 2023
Fig. 3. Expression of the receptor for advanced
glycation end products (RAGE) in the mo-
lecular/granular layer of the cerebral cor-
tex. A and B) Cells with different degrees
of nuclear and cytoplasmic positivity to
RAGE (arrows). RAGE-reactive extracellu-
lar material is seen in the neuropile (cros-
sed arrow). C) Detail of cell showing weak
nuclear RAGE positivity and high positivity
for cytoplasmic. Note the presence of RA-
GE-positive material adjacent to the cell.
N: nucleus; C: cytoplasm; E: extracellular
space. Original magnification: A and B:
x600; C: x1000.
Fig. 4. Expression of the receptor for advanced glyca-
tion end products (RAGE) in the pyramidal
layer of the cerebral cortex. Pyramidal neu-
rons with high nuclear positivity for RAGE are
appreciated. Arrows: Positive neurons. Cross
arrow: probably a positive glial cell nucleus.
Original magnification: x1000.
Fig. 5. Expression of the receptor for advanced glyca-
tion end products (RAGE) in the pyramidal
layer of the cerebral cortex. A) Nuclear RAGE-
positive pyramidal neurons showing nuclear
budding (small arrows). Cross arrow: positive
neuron without nuclear budding. Thick arrow:
pyramidal neuron dendrite. B) Nuclear RAGE-
positive pyramidal neuron showing nuclear
budding (small arrow). Cross arrow: positive
glial cell nucleus. Thick arrow: neuron axon.
Original magnification: x1000.
510 Mosquera-Sulbarán et al.
Investigación Clínica 64(4): 2023
RAGE 9, 11, 13. There is no information avail-
able on the presence of RAGE in the nucle-
us, and possibly the expression of nuclear
RAGE on the cell surface obeys mechanisms
similar to those of HMG. Binding to DNA
may represent the storage mechanism of
RAGE in the nucleus. In this regard, RAGE’s
ability to bind to DNA 15 and its role in par-
ticipating in DNA double-strand repair pro-
cesses 16 has been reported. Another point
of analysis is the intranuclear role of RAGE
and HMG since the latter represents one of
the RAGE’s ligands 17.
Fig. 6. Expression of the receptor for advanced
glycation end products (RAGE) in hip-
pocampus. A) Overview of hypothalamic
cells, the majority of which are positi-
ve for cytoplasmic granular expression
of RAGE. B) Hippocampal cells presen-
ting positive RAGE granules adjacent to
the nucleus or in the cytoplasm (arrows).
Original magnification: A: x200; B:x600.
Fig. 7. Expression of the receptor for advanced
glycation end products (RAGE) in the ce-
rebellum of normal rats. A) High number
of cells expressing RAGE-positive nuclei
(arrow) in the molecular layer, compared
to low number in the granular layer. Arrow:
positive nucleus. Cross arrow: negative nu-
cleus. B) Scarce presence of RAGE-positive
nuclei (thick arrows) and RAGE-positive
granules (small arrows) in cells of the gra-
nular layer. C) Scarce presence of RAGE-
positive nuclei and RAGE-positive granules
(small arrows) in the granular layer. Negati-
vity was observed in Purkinje cells (arrows).
Cerebellar molecular layer: CML. Cerebellar
Granular layer: CGL. A and B: x200; C: x600.
RAGE in rat cerebrum and cerebellum 511
Vol. 64(4): 505 - 512, 2023
The expression of RAGE in the central
nervous system makes this tissue vulner-
able to inflammatory processes. The role
of RAGE in neurodegenerative processes,
neuroinflammation, Parkinson’s, and Al-
zheimer’s diseases, among other encepha-
lopathies, has been reported 1, 3, 18, 19. Cere-
bral and cerebellar nuclear and cytoplasmic
RAGE could play a role in these patholo-
gies. Perhaps the factors that induce those
pathologies induce the passage of nuclear
and cytoplasmic RAGE to the cell surface.
In conclusion, this report demon-
strates the presence of RAGE as a nuclear
protein and its cytoplasmic expression in
the cerebrum and cerebellum of normal
rats. These data highlight possible stud-
ies on the translocation of RAGE from the
nucleus to the cell surface, on nuclear func-
tions, and on the interaction of RAGE with
HMG in the nucleus.
Conflict of interest
Authors report no conflict of interest
Funding statement
This investigation has no financial sup-
port.
Author’s ORCID
• Jesús A Mosquera-Sulbarán (JMS):
0000-0002-1496-5511
• Adriana Pedreáñez (AP):
0000-0002-3937-0469
• Yenddy Carrero (YC):
0000-0003-4050-4468
• Caterina Peña (CP):
0009-0009-2824-2566
Author Contributions
JMS: conceptualization, methodology,
data curation, writing - original draft, writ-
ing - review & editing. AP: methodology,
software, formal analysis, writing - review &
editing. YC: resources, conceptualization,
methodology, writing - review & editing. CP:
methodology, software, formal analysis.
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