Alireza Lotfi1, Mitra Soleimani1, Nazem Ghasemi2. 1. Department of Anatomical Sciences, School of Medicine, Isfahan University of Medical Sciences, Isfahan, Iran. 2. Department of Anatomical Sciences, School of Medicine, Isfahan University of Medical Sciences, Isfahan, Iran. Electronic Address: n_ghasemi@med.mui.ac.ir.
Neurodegeneration is a feature of several debilitating
and progressive disorders characterized by chronic loss
of neurons in the nervous system. Demyelination is one of
the most important causes of neurological disability (1, 2).
Multiple sclerosis (MS) is a chronic inflammatory disease
characterized primarily by demyelination and progressive
neurodegeneration in the central nervous system (CNS).
Oligodendrocyte death due to focal immune cell
infiltration is the primary cause of demyelination and
has an important role in the pathogenesis of MS (3).
Hence, the prevention of oligodendrocyte death by the
use of natural compounds, such as curcumin (4) and AST
may decrease the adverse complications developed in
demyelinating disorders.AST (3, 3’-dihydroxy-ß, ß’-carotene-4, 4’-dione) is a
natural red fat-soluble xanthophyll carotenoid produced
by marine microorganisms, gaining considerable attention
by researchers in recent years. Studies examined the
protective properties of AST indicate that its protective
roles are due to three main effects: anti-oxidative, antiinflammation,
and anti-apoptotic effects. It has been reported that AST has anti-oxidative properties ten
times more than some carotenoids, such as lutein,
canthaxanthin, and zeaxanthin, as well as a hundred
times more than vitamin E (5).In addition, other experiments demonstrated that
AST has a protective impact against primary brain
damages, as well as the destruction of neurons and
blood-brain barrier (BBB) disruption, cerebral edema,
and impaired nerve function through suppressing brain
inflammation (6).Additional works also demonstrated other effects of
AST, including anti-lipid peroxidation and anticancer
activity (7, 8).These protective properties mostly pertain to the
unique chemical structure of AST, the presence of
hydroxyl and keto moieties on each ion ring. This
unique nature confers the ability to AST to be esterified,
posing a higher antioxidant activity and a more polar
nature than other carotenoids (9). Neuroprotective
properties of AST have been evaluated in animal
models, and its protective roles have been addressed by several research groups (5, 10-13). Some parts of
these beneficial roles are attributed to the ability of
AST in crossing the BBB (10).Utilizing animal models of neurodegenerative
diseases has been enhancing the knowledge of molecular
pathogenesis which is responsible for the onset and
development of MS and other potentially disabling
neurodegenerative disorders (14). Among different
protocols that have been introduced for producing an
animal model of MS, CPZ is the well-stablished one
to study demyelination and remyelination in rodent
models of MS (15).In this study, we designed an experiment to assess
the impact of AST in the amelioration or prevention of
demyelination in a rat model of MS.
Materials and Methods
Ethics statement
This experimental study was performed at the
Isfahan University of Medical Sciences (Isfahan,
Iran). All experimental procedures were conducted
in compliance with the guidelines of the Iranian
Committee of Animal care and approved by the Ethics
Committee of Isfahan University of Medical Sciences
(Ethics#IR.MUI.MED.REC.1398.037).
Animals
Forty male Wistar rats, weighing 150-200 g, were
purchased from the Royan Institute, Isfahan, Iran.
Rats were housed for seven days, before the start of
the experiment, in constant environmental conditions,
at a temperature of 22 ± 2˚C with free access to food
and water and a 12:12 light/dark cycle.
Behavioral test
The Basket behavioral test evaluates motor
coordination and sensorimotor deficits in rodent
models of CNS disorders (4). For this purpose, rats
were placed in the center of a rectangular basket (60
cm in length and 50 in width), and then the basket was
overturned and the delay in dropping rats from the
ceiling of the basket was determined over 180 seconds,
and eventually the mean of these times (seconds) were
recorded. The experiment was conducted triplicate.
Production of a rat model of multiple sclerosis
Animals were randomly divided into four groups.
The number of rats per group was determined by ten
rats, by means of the power analysis calculations. To
produce a rat model of MS, the CPZ suspension was
prepared by the use of CPZ powder (Sigma-Aldrich,
USA) and 1% methylcellulose (Sigma-Aldrich, USA).
To prepare AST (Sigma-Aldrich, USA), AST powder
were dissolved in dimethyl sulfoxid (DMSO, Gibco,
USA) to reach a homogenous solution. Rats were fed as planned per group. The control group was fed with
normal chow for four weeks. The CPZ group was
treated with 2 ml CPZ (0.6%), by gavage, daily for
4 weeks (16). The sham group was first treated with
2 ml CPZ (0.6%) and after 12 hours treated with 2
ml DMSO, by gavage, daily for 4 weeks (this was
done to reject any possibility of repairmen effects of
DMSO as the solvent of AST). The AST group first
received CPZ 0.6% and after 12 hours received 2 ml
AST (3 mg/kg/day) (17), daily for 4 weeks. Animals
in all groups were weighed 3 times per week during
chemical administrations until they were sacrificed.
Tissue samples from all groups were processed at the
same time within the same experiment.
Craniotomy and dissection of the corpus callosum
Animals were sacrificed by performing deep
anesthesia using ketamine/xylazine (100/10 mg/kg,
Sigma-Aldrich, Germany) and decapitated. The brains
were removed by craniotomy of the vertex, weighed
precisely and then immersed in the fixative solution
of formaldehyde and formalin (10%, Sigma-Aldrich,
USA) for more than 24 hours. After washing with
a 0.1 M phosphate buffer (Sigma-Aldrich, USA),
the brains were sectioned at the coronal plane and
using its natural cleavage plane, the corpus callosum
identified and dissected, removing samples of the
mid-body. After tissue processing, the blocks were
cut in sections of 5- and 6-ىm of thickness, and these
sections were used for Luxol Fast Blue (LFB) staining
and immunohistochemistry technique.
Immunohistochemistry
After tissue processing by use of ethanol, xylene
and paraffin (Asia Pajohesh, Iran), serial sections (5-
μm thick) of the brain samples were prepared using a
microtome. After de-paraffinization and rehydration,
the slices were pre-treated using the method of heatinduced
epitope retrieval with sodium citrate buffer
(pH=6) and 1 mM EDTA buffer (pH=8) (Gibco,
USA) for 20 minutes, washed-out three times with
PBS (Gibco, USA). Then, the slices were incubated
with special antibodies against A2B5, a marker of
oligodendrocyte precursor cells (Abcam, USA) and
MOG, a myelin oligodendrocyte glycoprotein (Abcam,
USA), and then washed-out with PBS. Then, goat antimouse
-FITC (2 μg/ml, Abcam, USA) and rabbit antigoat-
FITC (Sigma-Aldrich, USA) were used as the
secondary antibody at room temperature for 1 hour.
Finally, nuclear counterstaining was conducted using
4, 6 Diamino-2-phenylindole, dilactate (DAPI) and
in order to quantitative analysis, the total numbers
of positive cells were counted in a minimum total of
200 cells per slide in six sections per sample using
.uorescence microscope (Olympus bx51, Japan).
Meanwhile, all IHC analyses were repeated at least
three times.
Luxol Fast Blue staining
After deep anesthesia, perfusion fixation was done
by use of cold PBS and 4% paraformaldehyde. In the
following, corpus callosum dissection was performed,
and in order to post-.xation, formalin solution (10%)
was used at 4°C overnight. Subsequently, paraffin
slices (6 µm) were prepared. Then sections were
dewaxed and cleared in 100% and 95% ethanol and then
were stained in a solution of LFB (0.1% w/v, Sigma-
Aldrich, USA), 10% acetic acid and ethanol (95%, Asia
Pajohesh, Iran) overnight at 56°C. Sections then were
differentiated by rinsing in 95 % ethanol, 0.05% lithium
chloride solution (Asia Pajohesh, Iran) followed by 70
% ethanol. Differentiation continued in distilled water
until unmyelinated tissue appeared white (18).
Gene expression analysis
In order to evaluate gene expression, real-time polymerase chain reaction (RT-PCR)
analysis of MOG, MBP, and PDGFR-α was
performed according to the SYBR Green master mix protocol. According to our previous
study, Total RNA was extracted from the brain corpus callosum by using RNeasy micro kit
(Qiagen, GmBH, Germany) and then, 2 μg of RNA was used for cDNA synthesis using RevertAid
First Strand cDNA Synthesis Kit (Fermentas, Germany) (19). Finally, quantitative real-time
PCR was done using Thermal Cycler Rotor-Gene in a total volume of 20 μl containing Power
SYBR Green master mix (2x), forward and reverse Primers (0.5 μM), cDNA (30 ng/μl) and H2O
with the following cycling conditions: 1 cycle of denaturation (95˚C for 5 minutes) which
followed by a 40 cycle amplification (at 95˚C for 15 seconds) and the extension cycle (at
60˚C for 40 seconds). The primer sequences used for RT-PCR analysis in this study are
listed in Table 1.Primer sequences
Data analysis
Immunohistochemistry, behavior test, RT-PCR, and LFB results were analyzed using the SPSS software
version 25.0 (SPSS Inc., Chicago, IL, USA). One-way
ANOVA was conducted, followed by Tukey’s post hoc
test. In addition, all data were shown as mean ± standard
error of the mean (mean ± SEM).
Results
Basket behavior test
The basket behavioral test was performed at the end of
every week for a total of 4 weeks. During this study, the
comparison of behavioral results demonstrated that the
use of AST increases the average latency to fall compared
to sham and CPZ groups. Unlike the AST group, in CPZ
and sham groups, the average latency to fall was decreased
significantly from the first week (P≤0.05, Fig.1).
Fig.1
The comparison of latency to fall in different groups. In the Cuprizone
and sham groups, the average latency to fall was decreased significantly
from the first week in comparison with the Astaxanthin group (P<0.05). *;
P<0.05 and ***; P<0.001.
The comparison of latency to fall in different groups. In the Cuprizone
and sham groups, the average latency to fall was decreased significantly
from the first week in comparison with the Astaxanthin group (P<0.05). *;
P<0.05 and ***; P<0.001.
Histological observation of cuprizone-induced
demyelination in rats
LFB staining of coronal sections of corpus callosum
observed under ×40 magnification. Myelinated axons
were stained blue. Achievement of MS induction in rat
models was confirmed by prominent demyelination in
CPZ group and vehicle group. While the control group
represented blue colored bands indicating the presence of
myelinated axons (Fig.1). In the AST group, majority of
axons stained blue, while few axons were stained pink,
confirming the inhibitory effects of AST in demyelination.Moreover, calculating the myelin density by the
ImageJ software, revealed that the myelin density of
corpus callosum in tissue sections of the AST group was
significantly higher than that of CPZ and sham groups
(Fig.2).
Fig.2
Illustration of LFB in coronal sections of the brain of Wistar rats to assess myelin
status, after treatment with CPZ. A. The blue colured region indicates the presence of
myelin. In the control group, a distinct delineated pattern of areas without (pink)
and with stained myelin (blue) is observable. In CPZ and sham groups, there is a
significant reduction in the myelin contents in the corpus callusom, indicated by an
asterisk. In the AST group, induced with CPZ and treated with AST, a sharply
delineated pattern is identifiable. B. The total integrated density of
myelin calculated by ImageJ software (scale bar: 200 μm). LFB; Luxol Fast Blue, CPZ;
Cuprizone, AST; Astaxanthin, and *; P<0.05.
Illustration of LFB in coronal sections of the brain of Wistar rats to assess myelin
status, after treatment with CPZ. A. The blue colured region indicates the presence of
myelin. In the control group, a distinct delineated pattern of areas without (pink)
and with stained myelin (blue) is observable. In CPZ and sham groups, there is a
significant reduction in the myelin contents in the corpus callusom, indicated by an
asterisk. In the AST group, induced with CPZ and treated with AST, a sharply
delineated pattern is identifiable. B. The total integrated density of
myelin calculated by ImageJ software (scale bar: 200 μm). LFB; Luxol Fast Blue, CPZ;
Cuprizone, AST; Astaxanthin, and *; P<0.05.IHC results indicated that the mean percentage of positive
cells for MOG and A2B5 proteins were significantly higher
in the AST group compared with the CPZ group, 56 ± 2.7
and 59.7 ± 5.2, respectively (Figes.3, 4).
Fig.3
MOG and A2B5 stained of the corpus callosum in control, Cuprizone, sham, and Astaxanthin groups. The statistical analysis of MOG and A2B5 staining
according to the relative optical density. The presence of MOG-positive cells (green) and A2B5 positive cells (green) were significantly higher in Astaxanthin group
as compared to Cuprizone and sham groups. Astaxanthin alleviated demyelination in Cuprizone-induced rat corpus callosum (scale bar: 200 μm).
Fig.4
The comparison of A2B5 and MOG expression in all experimental groups. In the Astaxanthin group, the mean percentage of cells which express
A2B5 and MBP markers was statistically significant in comparison with Cuprizone and sham groups (P<0.05). *; P<0.05.
MOG and A2B5 stained of the corpus callosum in control, Cuprizone, sham, and Astaxanthin groups. The statistical analysis of MOG and A2B5 staining
according to the relative optical density. The presence of MOG-positive cells (green) and A2B5 positive cells (green) were significantly higher in Astaxanthin group
as compared to Cuprizone and sham groups. Astaxanthin alleviated demyelination in Cuprizone-induced rat corpus callosum (scale bar: 200 μm).The comparison of A2B5 and MOG expression in all experimental groups. In the Astaxanthin group, the mean percentage of cells which express
A2B5 and MBP markers was statistically significant in comparison with Cuprizone and sham groups (P<0.05). *; P<0.05.Real-time PCR results of gene expression analysis in four experimental groups indicated
that mRNA expression of the MOG, MBP, and
PDGFR-α genes were higher in AST group compared to CPZ group and the
sham group that represented similar expression pattern for these genes (Fig.5).
Fig.5
Comparative analysis of MBP, MOG and PDGFR-α
markers in different groups. The relative expression levels of A.
MBP, B.
MOG, and
C.
PDGFR-α genes that were evaluated by the real-time polymerase
chain reaction. The expression of all three genes increased significantly in the
Astaxanthin group compared to Cuprizone and sham groups.
Comparative analysis of MBP, MOG and PDGFR-α
markers in different groups. The relative expression levels of A.
MBP, B.
MOG, and
C.
PDGFR-α genes that were evaluated by the real-time polymerase
chain reaction. The expression of all three genes increased significantly in the
Astaxanthin group compared to Cuprizone and sham groups.
Discussion
We concluded that consumption of AST modulated
demyelination and oligodendrocyte death as well as
muscle weakness in CPZ-induced rat model of MS.
MS is a chronic inflammatory CNS disease leading to
primary demyelination is featured with focal plaques
(20). Some natural products already have been suggested
to contribute to the alleviation of demyelination in
demyelinating diseases (21). However, the mechanism of their effects rarely confirmed scientifically. AST
is a natural product of aquatic microorganisms that
recently has gained strong attention from medical
and life science research (5). It is a lipophilic terpene
and a metabolite of zeaxanthin. The presence of
the hydroxyl and keto moieties on each ionone ring
explains some of its unique features, namely, the
ability to be esterified, higher antioxidant activity and
a more polar nature than other carotenoids and so, AST
is considered as a suitable multi-target pharmacological
agent (9, 22). Due to its unique chemical structure, AST
can cross the BBB (23). This property has conferred AST
particular attention in research implementing in the realm
of neurodegenerative disorders. Moreover, since the late
onset of extensive neuronal death in neurodegenerative
diseases is related to oxidative damage, and due to proven
anti-oxidative effects of AST (11), CNS is considered
one of its key target organs and has been as particular
interest as co-treatments in neurodegenerative diseases.
Therefore, in the present study, in order to investigate the
neuroprotective effects of AST, the composition of the
CPZ was used for induce a toxic model of MS and finally,
the laboratory tests were performed on brain tissue.CPZ (oxalic acid bis-cyclohexylidene hydrazide),
is a copper chelator that induces highly reproducible
demyelination in the CNS and extensively used to create a
model of demyelinating disease (24). By the third week of
CPZ treatment, consistent demyelination can be observed
in the corpus callosum, the largest white matter tract in
the rodent brain (25). So, in order to induce MS in rats,
we treated male Wistar rats with 0.6% CPZ, daily for four
weeks.LFB stained sections displayed corpus callosum with defined borders of the corpus callosum,
and there was a sharply delineated differentiation between white (blue) and gray matter
(pink) in the control group. However, in CPZ-induced groups, CPZ and Sham, the myelin
density, evaluated with the ImageJ software was shrunk, and no defined borders were
observable in the stained samples. Four weeks after treatment with AST, the sections of LFB
staining represented a corpus callosum that was significantly well- delineated and with
cohesive texture compared to the shrunk texture were seen in CPZ group and Sham group. In
justifying this result, it can be said that AST due to cross the BBB is able to carry out
its neuroprotective effects at high levels and thus prevent myelin destruction. Another
relevant finding of the current study was that AST is able to induce a significant delay in
climbing down the basket wire wall in comparison to CPZ and sham groups. This result is
consistent with a recent study which has also shown that AST can improve sensorymotor
function through modulating specific cell signaling pathways in a rat model of spinal cord
injury (26). For justifying this outcome, it can be said that AST is capable of improving
the neural dysfunction, caused by CPZ by preventing demyelination and increasing the
transmission of neural impulses. Finally, we evaluated the influences of CPZ and AST on
oligodendrocytes. Progenitor cells of oligodendrocytes are widely scattered in CNS and are a
constant reservoir for oligodendrocyte replacement and remodeling. To detect impairment
effects of CPZ, and repairment influences of AST on rat model of MS, we stained corpus
callosum section, in all our four groups, with two oligodendrocyte proteins, MOG and A2B5.
MOG, myelin oligodendrocyte glycoprotein, expressed on the outer membrane of myelin sheath
and oligodendrocytes, and exclusively found within the CNS. Giving the late commencement of
MOG expression in myelination, it is believed that MOG plays a role in the maintenance of
the myelin sheath and may serve as a potential marker in oligodendrocyte maturation.
Therefore, MOG could potentially function as a cell surface marker of matured
oligodendrocytes (27). During OPC differentiation, cells sequentially express A2B5, PDGFR-α,
and MBP (28). Our stained sections of corpus callosum for MOG and A2B5 represented
significant positive staining for both antibodies in the AST group than CPZ and sham groups.
This may underpin the ameliorative effects of AST on oligodendrocyte death or even its
oligodendrogenic effects. To confirm the obtained IHC results, we assessed the real-time PCR
expression of MOG, MBP, and PDGFR-α genes
in the corpus callosum in all groups. The results demonstrated that the expression of all
three genes decreased significantly in CPZ and sham groups than the control group,
indicating the destructive effects of CPZ in a rat model of MS.Moreover, the expression of all three genes was higher in AST group compared to the CPZ and
sham groups. This may represent that AST due to its antioxidant and neuroprotective effects,
is capable of preventing the death of oligodendrocytes which induced by CPZ. Besides, since
MOG and PDGFR-α have a sequential expression pattern in oligodendrocyte maturation, it could
be suggested that AST may infuse oligodendrogenesis from progenitors to mature
oligodendrocytes.
Conclusion
AST may reduce demyelination and oligodendrocyte
death in MS rat model. Either AST stimulates the
proliferation of oligodendrocytes, or it prohibits death of
pre-existing oligodendrocyte is an issue to be confirmed.
Authors: A M Adamo; P M Paez; O E Escobar Cabrera; M Wolfson; P G Franco; J M Pasquini; E F Soto Journal: Exp Neurol Date: 2006-02-14 Impact factor: 5.330
Authors: Lorenza Speranza; Mirko Pesce; Antonia Patruno; Sara Franceschelli; Maria Anna de Lutiis; Alfredo Grilli; Mario Felaco Journal: Mar Drugs Date: 2012-04-10 Impact factor: 6.085
Authors: C Joakim Ek; Mark D Habgood; Ross Dennis; Katarzyna M Dziegielewska; Carina Mallard; Benjamin Wheaton; Norman R Saunders Journal: PLoS One Date: 2012-08-29 Impact factor: 3.240
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