Hypoxic conditions can be found in many situations such
as high altitude, diving, and chronic obstructive pulmonary
disease (COPD). Globally, COPD is considered as a leading
cause of death and disability (1). Hypoxic conditions
result in lower levels of circulating oxygen (2) and 4-week
exposure to hypoxia produces systemic hypoxia in rats as
manifested by pulmonary hypertension, and increased right
ventricular systolic pressure (3). These hypoxic signs present
special challenges to homeostasis because of their effects
on sympathetic outflow and vascular smooth muscle.It is generally accepted that chronic systemic hypoxia,
whether due to high altitude or imposed experimentally by a
hypoxic or hypobaric chamber, induces physiological adaptations
that help to compensate the impaired O2
transport to tissues.
Enhancing red blood cell production (e.g.by administration
of erythropoietin (Epo) has been shown to modulate the
ventilatory response to reduced oxygen supply and critically
help the organism to cope with increased oxygen demand (4).
Exposure to hypoxia has been associated with an increase
in the production of reactive oxygen species (ROS) that are
generated during the re-oxygenation phase of intermittent and
continuous hypobaric hypoxia and contribute to physiological
responses (5) such as pulmonary hypertension and vasoconstriction
as well as neomuscularization and thickening of the
media and adventitia of pulmonary arterioles.Weight loss due to exposure to chronic hypoxia may
reflect multiple changes in cardiovascular function, hormone
production, energy metabolism, and other aspects
of cellular and systemic physiology (4). ROS may cause
cell membrane damage, and prevent the maintenance of
ionic gradient which can lead to detrimental effects on
structure and function of tissues (6, 7), impairment in ATP
production and tissue inflammation. Oxidative stress (OS)
refers to an imbalance between generation of ROS and
the ability of endogenous antioxidant systems to scavenge
ROS, where ROS overwhelms antioxidant capacity (5, 8).Furthermore hypoxic condition increases the levels of inflammatory
cytokine such as IL-1ß, IL-18 and tumor necrosis
factor-alpha (TNF-α) (9). Also, hypoxia increases levels
of lipid peroxidation-while reduces glutathione reductase
activity and number of epididymal sperm (10). Evident
changes observed following hypoxia-induced lipid peroxidation
have been reported (11). These changes are partially
attenuated by supplementation of antioxidants such as melatonin
and ascorbate but there is no report about the effect
of flaxseed on male reproductive system affected by
hypoxia. The major components of flaxseed are the essential
n-3 fatty acid, a-linolenic acid (ALA), lignans such as
secoisolariciresinol diglucoside (SDG) and carbohydrates
such as mucilages containing arabinoxylans. ALA is orally
bioavailable and may be stored or converted into longer
chain n-3 fatty acids such as eicosapentaenoic acid (EPA)
and docosahexaenoic acid (DHA) and other bioactive lipid
metabolites (12). SDG is metabolized to the mammalian
lignans, enterodiol and enterolactone, in the intestine (13);
recent research has demonstrated the ability of lignans to
scavenge hydroxyl radicals suggesting a potent antioxidant
activity for lignans. lignans are biologically active phytochemicals
with anticancer and antioxidant potential (14).
Docosahexaenoic acid has been shown to increase sperm
motility in men (15).Improvement of vascular endothelial cell function, enhancement
of vascular reactivity and compliance, modulation
of lipid metabolism and reduction of inflammatory
cytokine production have been noted as the underlying
mechanisms through which poly unsaturated fatty acid
(PUFA) exert their beneficial effects (16) . In mammalian
sperm, lipids especially n-3 fatty acids are dominantly
present. Previous studies have shown that n-3 fatty acids
are also present in human sperm (15). Their protective
mechanisms include induction of anti-inflammatory transcriptional
pathways , reducing the intracellular Ca2+ levels,
suppression of vascular proliferation, and improvement
of cell membrane integrity (17). Little information
is available regarding the effect of dietary flaxseed supplementation
on male rats’ reproductive system following
exposure to hypoxia. The objective of the present study
was to investigate the effect of flaxseed supplementation
on testes structure and sperm parameters of hypoxic rats.
Materials and Methods
In this experimental study, 24 male Wistar albino rats
(270-300 g, 12-weeks-old) were purchased from Pharmacy
Faculty of Tehran University of Medical Sciences,
Tehran, Iran. Animals were allowed to have access to food
and water. Also, they were kept under 12- hour periods of
light and darkness at 23 ± 2°C. All procedures were carried
out in accordance with the guidelines of the Iranian
Council for use and care of animals and approved by Ethics
Committee of Tehran University of Medical Sciences.
Experimental design
The rats were randomly divided into 4 groups: control (Co),
sham (Sh), hypoxia (Hx) and hypoxia+flaxseed (Hx+Fx).
Hypoxic rats were kept in a hypoxic chamber with a reduced
pressure (oxygen 8% and nitrogen 92% for 4 hours/day for
30 days). The reason for using 8% oxygen is that the rats are
capable to survive at this level of hypoxia which allows us to
measure the patho-physiologic variables in them (18).Control group (Co) was kept under normoxia and had
free access to standard food and water. Sham group (Sh)
was maintained in a hypoxia chamber (but not under hypoxia)
receiving normal oxygen and food. Hypoxia group
(Hx) was exposed to hypoxia 4 hours/day and fed with
normal food. Hx+Fx group: 10% Fx was added to the normal
food of Hx+Fx group after the first hypoxic exposure.
Testis index
At the end of the experimental period, each rat was
weighed and sacrified. Then, the right testis was removed
and weighed. The testicular mass relative to body weight
was determined on day 42 using the following equation:
(testicular/body weight ratio)*100=(%).
Detection of IL-18 levels
At the end of each experiment, blood samples were
collected from the left ventricle. Blood was centrifuged
at 1000 g for 15 minutes and serum was separated for
biochemical analysis. IL-18 levels in serum samples were
quantified by an ELISA kit (zell Bio-GmbH, Germany)
according to the manufacturer’s instructions.
Histological procedure
At the end of the experiment, rats were weighed and
sacrificed and their right testis was removed. The right
testicular (internal spermatic) vein drained directly into
the right common iliac vein in 77.4%, and into the inferior
vena cava in 22.6% of the animals. The left testicular vein
drained into the left common iliac vein in all animals, but
in 90.3% of rats there was also an accessory branch of
the testicular vein draining into the left renal vein (19).
Testes were placed in Bouin’s solution for 24 hours at
room temperature. Later, they were processed, sectioned
and stained with H&E technique. On slices with 5- µm
thickness, the morphometric assessment of seminiferous
tubules was performed. The tubular diameters and germinal
epithelial thickness of seminiferous tubules that were
sectioned transversely were evaluated using light microscopy
(20). In this way, the slides were studied at ×100
magnifications, and in different fields of testis tissue, 20
tubules from each specimen were studied. The analyses
were carried out on images were taken using LABOMED
digital camera (LABOMED, USA). Then, the images
were processed by the image analysis system software
of Image J (ImageJ U. S. National Institutes of Health,
Bethesda, Maryland, USA). Finally, the scale bar was
added to the images (21).
Sperm sampling
The caudal epididymis was used for sperm analysis. Briefly,
epididiymal sperms were collected by slicing the caudal
epididymis in 1 ml of Minimum Essential Medium-a
(MEM-a) medium (P/N 22561-021, Gibco, CA, USA)
after that 9-ml medium was added and samples were incubated
for 10 minutes to allow the sperms to swim into the
medium. The epididymis was then processed for further
analysis.
Sperm count
To enumerate the spermatozoa, the heads of spermatozoa
were counted. For sperm counting, a hemocytometer device
was used. Here, 50 µl of the suspension was mixed with an
equal volume of 2% formalin. Then, 10 µl of this diluted suspension
was transferred to a Neubauer chamber. The sperms
were counted under light microscopy at ×400 (22).
Sperm morphology
A part of sperm sample was used for preparing smears
to evaluate the sperm morphological abnormalities. For
this purpose, 10 µL of suspension was spread onto a glass
slide and allowed to air-dry at room temperature to prepare
a smear. The smears were then stained with Diff-
Quik stain and 200 sperms were then examined under
light microscopy at ×400 (22).
Sperm viability assay
In order to study the sperm viability, 10 µl of sperm suspension
was mixed with 2 µl Eosin-y 0.05%. Slides were prepared
and incubated for two minutes at room temperature before
evaluation at ×400 magnifications using light microscopy. Two
hundred sperms were counted for each sample. Dead sperms
appeared pink and live sperms were not stained (22).
Sperm motility
One to two drops of the sperm suspension were placed
on a glass slide and motile sperms were counted immediately
using light microscopy (22).
Tissue preparation for enzyme assay
Rat testes were rapidly removed and manually homogenized
in cold phosphate buffer (pH=7.4) and debris was
removed by centrifugation at 3500 g for 10 minutes. Then,
50 mg of supernatant was homogenized in 10 volumes of
KH2PO4 (100 mmol) buffer and was centrifuged at 12,000
g for 30 minutes at 4ºC. The supernatant was collected and
used for enzymes and MDA levels studies (23).
Measurement of total anti-oxidant capacity and lipid
peroxidation
Total antioxidant capacity was measured based on the
absorbance of the 2,2'-azinobis-3-ethylbenzothiazoline-
6-sulfonic acid (ABTS+) radical cation. The pre-formed
radical monocation ± of 2,2'-azinobis-(3-ethylbenzothiazoline-
6-sulfonic acid) (ABTS•+) is generated by oxidation
of ABTS with potassium persulfate and is reduced in
the presence of such hydrogen-donating antioxidants. The
influences of both the concentration of a given antioxidant
and duration of reaction on the inhibition of the radical
cation absorption are taken into account when determining
the antioxidant activity (24). A common method for
measuring MDA, referred to as the thiobarbituric acid-
reactive-substances (TBARS) assay, is based on its reaction
with Thiobarbituric acid (TBA) followed by reading
the absorbance at 532 nm. Thiobarbituric acid substance
assay is a method to quantify malondialdehyde concentration
by spectrophotometry (25).
Statistical analyses
Data were statistically analyzed using SPSS-22 (IBM
crop., Armonk, NY, USA) software. All data were expressed
as mean ± standard errors of mean (SEM), median and interquartile
range (IQR). At first, the normality of variables
was checked using the Kolmogorov-Smirnov test. Then, for
analyzing the differences among four groups of study, one
way-ANOVA test and Tukey-post hoc test were chosen if the
distribution of data were normal (for sperm parameters, testicular/
body weight ratio, diameter of seminiferous tubules,
MDA level and TAC). Otherwise, nonparametric test of
Kruskal-Wallis was carried out (for thickness of the germinal
epithelium). The statistical significance level was set at 0.05.
Results
Model confirmation
Using one way-ANOVA test, serum levels of IL-18
were compared to confirm state of hypoxia. Tukey post
hoc test showed a significant difference in serum levels of
IL-18 in rat exposed to 30-days hypoxia (0.08 ± 0.05 pg/
ml) compared to control (0.51 ± 0.08 pg/ml, P=0.0001)
and Sham (0.52 ± 0.08 pg/ml, P=0.0001) groups (Fig .1).
Fig.1
Effects of hypoxia on serum levels of IL-18 (pg/ml) in rats following hypoxia.
*; P<0.05 compared to control and sham groups, Co; Normal group that
received normal oxygen levels and normal food, Sh; Sham group maintained
in hypoxia chamber with normal oxygen levels and food, and Hx;
Animals were exposed to hypoxia and received normal food.
Effects of hypoxia on serum levels of IL-18 (pg/ml) in rats following hypoxia.
*; P<0.05 compared to control and sham groups, Co; Normal group that
received normal oxygen levels and normal food, Sh; Sham group maintained
in hypoxia chamber with normal oxygen levels and food, and Hx;
Animals were exposed to hypoxia and received normal food.
Effects of flaxseed on the body weight and testicular
mass/body weight ratio in rats with hypoxia
The effect of oral Fx on the testicular/body weight ratio was evaluated in rats after hypoxia. According to the
ANOVA test, the testicular mass/body weight were significantly
different in the studied groups (P=0.0001, Fig .2).
A significant difference was observed in the testicular
mass/body weight of Hx (0.54 ± 0.01%) and Hx+Fx
(0.56 ± 0.1%) groups compared to control (0.6 ± 0.1%,
P=0.003 and P=0.027, respectively) and sham (0.61 ±
0.1%, P=0.001 and P=0.009, respectively) groups (Fig .2).
Fig.2
Effects of oral flaxseed on testicular mass/body weight ratio in rats
following hypoxia.
*; P<0.05 compared to control and sham groups, Co; Normal group that
received normal oxygen levels and normal food, Sh; Sham group maintained
in a hypoxia chamber with normal oxygen levels and food, Hx; Animals were
exposed to hypoxia and received normal food, and Hx+Fx; Animals were
exposed to hypoxia and treated by normal food supplemented with 10% Fx.
Effects of oral flaxseed on testicular mass/body weight ratio in rats
following hypoxia.
*; P<0.05 compared to control and sham groups, Co; Normal group that
received normal oxygen levels and normal food, Sh; Sham group maintained
in a hypoxia chamber with normal oxygen levels and food, Hx; Animals were
exposed to hypoxia and received normal food, and Hx+Fx; Animals were
exposed to hypoxia and treated by normal food supplemented with 10% Fx.
Effects of flaxseed on sperm parameters in rats exposed
to hypoxia
The effects of oral Fx on sperm parameters were evaluated
in rats after hypoxia. The mean sperm count was
significantly different in the studied groups (P=0.0001,
Fig .3). A significant difference (P=0.0001) was observed
in the sperm count between Hx+Fx group (73.02 ± 1.93)
and the Hx group (55.12 ± 3.84) (control=71.78 ± 0.22
and Sham=64.06 ± 6.14) (Fig .3). Moreover, the mean
sperm motility was significantly different among the
studied groups (P=0.025, Fig .3). A significant difference
was found in sperm motility between Hx group (74.76
± 2.27%) and the control (82.35 ± 1.59%, P=0.032) and
sham (80.47 ± 0.67%, P=0.041) groups (P<0.05, Fig .3).
Also, a significant difference was observed in the sperm
motility between Hx+Fx group (83.04 ± 1.52%) and the
Hx group (P=0.028, Fig .3). Based on ANOVA test, a significant
difference was found in sperm viability between
Hx group (60.8 ± 0.85%) and control (83.31 ± 2.5%,
P=0.0001) and sham (82.92 ± 1.5%, P=0.0001) groups
(Fig .3) and a significant difference was observed in the
sperm viability between Hx+Fx group (85.67 ± 1.33%)
and the Hx group (P=0.0001, Fig .3). The mean sperm abnormality
was significantly different among the studied
groups (P=0.0001, Fig .3). A significant difference was
seen in sperm abnormality between Hx group (41 ± 1%)
and control (17 ± 1.1%, P=0.0001) and sham (16 ± 1.3%,
P=0.0001) groups (Fig .3) and a significant difference was
observed in the sperm abnormality between Hx+Fx group
(14 ± 1.2%) and Hx group (P=0.0001, Fig .3).
Fig.3
Effects of oral flaxseed on sperm parameters of rats following hypoxia.
A. Sperm count, B. Sperm motility, C. Sperm viability, and D. Sperm
abnormality.
*; P<0.05 compared to control and sham groups, #; P<0.05 compared to
HX group, Co; Normal group that received normal oxygen levels and normal
food, Sh; Sham group maintained in hypoxia chamber with normal oxygen
levels and food, Hx; Animals were exposed to hypoxia and received
normal food, and Hx+Fx; Animals were exposed to hypoxia and received
normal food supplemented with 10% Fx food.
Effects of oral flaxseed on sperm parameters of rats following hypoxia.
A. Sperm count, B. Sperm motility, C. Sperm viability, and D. Sperm
abnormality.
*; P<0.05 compared to control and sham groups, #; P<0.05 compared to
HX group, Co; Normal group that received normal oxygen levels and normal
food, Sh; Sham group maintained in hypoxia chamber with normal oxygen
levels and food, Hx; Animals were exposed to hypoxia and received
normal food, and Hx+Fx; Animals were exposed to hypoxia and received
normal food supplemented with 10% Fx food.
Effects of flaxseed on diameter of seminiferous tubules
and thickness of the germinal epithelium in rats exposed
to hypoxia
The effects of oral Fx on the diameter of seminiferous tubules
and thickness of the germinal epithelium were evaluated after
hypoxia in rats. According to ANOVA test, the mean diameter
of seminiferous tubules was significantly different in the studied
groups compared to control and sham (P=0.0001, Fig .4). A
significant difference was found in the diameter of seminiferous
tubules of Hx group (10.58 ± 0.34 µm) in comparison to
the control (11.77 ± 0.22 µm, P=0.031) and sham (12.28 ± 0.4
µm, P=0.001) groups (Fig .4) and a significant difference was
observed in diameter of seminiferous tubules of Hx+Fx group
(13.04 ± 0.2 µm) as compared to the Control (P=0.022), sham
(P=0.048) and Hx (P=0.0001) groups (Fig .4). The thickness
of the germinal epithelium was significantly different among
the studied groups (P=0.008, Fig .4). A significant difference
was observed in the thickness of the germinal epithelium of
Hx+Fx [3.5 (IQR: 3.13-3.83) µm] group as compared to the
Hx [2.28 (IQR:2-2.56) µm, P=0.005] group (Fig .4).
Fig.4
Effects of flaxseed on diameter of seminiferous tubules and thickness
of the germinal epithelium in rats exposed to hypoxia. Comparing A.
The diameter of seminiferous tubules and B. Thickness of the germinal
epithelium in different groups.
*; P<0.05 compared to Control and Sham groups, #; P<0.05 compared
to Hx group, Co; Normal group that received normal oxygen levels and
normal food, Sh; Sham group maintained in hypoxia chamber with normal
oxygen levels and food, Hx; Animals were exposed to hypoxia and
received normal food, and Hx+Fx; Animals were exposed to hypoxia and
received normal food supplementated with 10% Fx food.
Effects of flaxseed on diameter of seminiferous tubules and thickness
of the germinal epithelium in rats exposed to hypoxia. Comparing A.
The diameter of seminiferous tubules and B. Thickness of the germinal
epithelium in different groups.
*; P<0.05 compared to Control and Sham groups, #; P<0.05 compared
to Hx group, Co; Normal group that received normal oxygen levels and
normal food, Sh; Sham group maintained in hypoxia chamber with normal
oxygen levels and food, Hx; Animals were exposed to hypoxia and
received normal food, and Hx+Fx; Animals were exposed to hypoxia and
received normal food supplementated with 10% Fx food.
The effects of oral flaxseed on MDA and TAC concentrations
were evaluated after hypoxia in rats exposed to after hypoxia
No significant difference was observed in the mean MDA
among studied groups (control=7.78 ± 0.11 nmol/mg and
sham=7.13 ± 0.09 nmol/mg, Hx=8.57 ± 0.28 nmol/mg and
Hx+Fx=6.7 ± 0.81 nmol/mg) (P=0.075, Fig .5). The mean TAC
was significantly different among the studied groups (P=0.01,
Fig .5). A significant difference was observed in TAC of Hx+Fx
(2.07 ± 0.12 nmol/mg) group compared to control (1.51 ± 0.13
nmol/mg, P=0.011), sham (1.53 ± 0.06 nmol/mg, P=0.014)
and Hx (1.18 ± 0.02 nmol/mg, P=0.001) groups (Fig .5).
Fig.5
Effects of oral flaxseed on MDA and TAC concentrations in rats exposed
to hypoxia. A. MDA and B. TAC concentrations of rats following hypoxia.
MDA; Malondialdehyde, TAC; Total antioxidant capacity, *; P<0.05 compared
to Control and Sham groups, #; P<0.05 compared to Hx group, Co;
Normal group normal oxygen and normal food, Sh; Sham group maintained
in hypoxia chamber with normal oxygen and food, Hx; Animals
were exposed to hypoxia and received normal food, and Hx+Fx; Animals
were exposed to hypoxia and received normal food supplementated with
10% Fx food.
Effects of oral flaxseed on MDA and TAC concentrations in rats exposed
to hypoxia. A. MDA and B. TAC concentrations of rats following hypoxia.
MDA; Malondialdehyde, TAC; Total antioxidant capacity, *; P<0.05 compared
to Control and Sham groups, #; P<0.05 compared to Hx group, Co;
Normal group normal oxygen and normal food, Sh; Sham group maintained
in hypoxia chamber with normal oxygen and food, Hx; Animals
were exposed to hypoxia and received normal food, and Hx+Fx; Animals
were exposed to hypoxia and received normal food supplementated with
10% Fx food.
Discussion
Hypoxia is a condition can result in overproduction
of ROS which along with a decrease in the level of antioxidants,
may give rise to oxidative stress. Oxidative
stress as an imbalance between generation of ROS and
ability of endogenous antioxidant systems to scavenge
ROS has adverse influence on testes structure and sperm
parameters.In this study, we found that hypoxia leads to reduction
in the germinal epithelial thickness and some changes in
the serum, testes and sperm parameters in rats also hypoxia
results in excessive formation of ROS. We also
observed that hypoxia increases interstitial space of the
testes, which extends the oxygen diffusion distance and
impairs oxygen delivery to germ cells. It makes germ
cells more susceptible to damage, which was confirmed
by our observation concerning degeneration of germ cells
in hypoxic rats. A similar outcome was reported by other
researchers (26). In the present study, we observed that
flaxseed improves testicular structure as reflected by increased
diameter of seminiferous tubules of Hx+Fx group
as compared to the Hx group and increased thickness of
the germinal epithelium of Hx+Fx group as compared to
the Hx group.Spermatogenesis is vulnerable to hypoxia because spermatogenesis
has a high proliferation rate, damanding notable
oxygen levels in the testes and it has been reported
that breathing 10% O2/90% N2 results in a 24% decrease
in testicular blood flow, but a 23% increase in cerebral
blood flow. These characteristics may attribute to the
morphological changes of spermatogenesis induced by
hypoxia. Besides, a significant decrease in testicular mass
followed by adverse effects on reproductive hormones
such as testosterone was observed (27). In this study
the sperm count, motility and viability significantly decreased
in Hx, but increased in Hx+Fx group which might
indicate that hypoxia affects sperm sperm differentiation
process. We found that flaxseed can improve sperm parameters
following exposure to hypoxia.In our study there was significant reduction in body
weight of Hx+Fx group in comparison to the control
and sham groups. Researchers have observed that doses
of 5 and 10 g of flaxseed fibers result in prolonged
decrease in the levels of ghrelin a hunger-signaling gut
peptide (29).Dissimilar to many other cell types, sperm lipid membranes
contain an exceptionally high percentage of polyunsaturated
fatty acids (PUFAs) that provide the fluidity
to the membrane contraction events associated with fertilization.
However, PUFAs are readily oxidized and produce
malondialdehyde.We reported that lipid peroxidation assessed by MDA
levels in all groups exposed to hypoxia was increase but
the differences among different groups were not significant.
The hypoxia-induced changes in lipid metabolism
were mediated via hepatic stearoyl coenzyme A desaturase
(25, 30). Lipid peroxidation in mice exposed to sever
hypoxia is different from those exposed to moderate hypoxia
and the degree of lipid peroxidation rate depend
on hypoxia intensity (30). Therefore, probably due to this
reason, our result is different from other those of reports.
These adverse effects of hypoxia have also been reported
to decreased the supplementation of antioxidants such as
melatonin and ascorbate (31).This study shows an increase in serum inflammatory
markers (i.e.IL-18) only in group who expose to hypoxia
and higher levels of lipid peroxidation and reduces antioxidant
activity. In addition, we found flaxseed could
effectively counteract peroxidation damage, mediated by
the attenuation of systemic and tissue oxidative stress induced
by Hypoxia. This is reflected by an increase in TAC
values in Hx+Fx group as compared to the Hx group. This
is in agreements with previous studies (26).A high rate of death was observed among animals during
the last time of hypoxia procedure.To confirm the results of this study, we suggest to evaluate
the testicular tissue superoxide dismutase (SOD), catalase
(CAT), glutathione peroxidase (GPx), glutathione
reductase (GRD), and glutathion-S-transferase (GST) activities
to confirm the obtained findings.
Conclusion
The conclusion the present study revealed that flaxseed
as an antioxidant drug can reduce hypoxia-induced damages
in the testes.
Fig.1
Fig.2
Fig.3
Fig.4
Fig.5