The aging process involves the natural degeneration of all the organs of the body
over time. In this process, muscular atrophy is an important influencing factor.
Muscular atrophy involves the impairment of the major nerves of muscles or a
decrease in the absolute volume and strength of muscles under prolonged under
certain conditions (Bonewald, 2019; Szentesi et al., 2019).Muscle cells are involved in the regeneration of muscle fibers containing mechanical,
chemical, or degenerative lesions through activation, differentiation, and
proliferation (Ceafalan et al., 2014; Karalaki et al., 2009). Differentiation of
myoblasts is essential for the formation of muscle fibers involved in the
development and regeneration of skeletal muscle (Grefte et al., 2007). These monocyte myoblasts proliferate and
differentiate, following which, they fuse with existing muscle fibers to form
multinucleated myotubes and myofibers. Proliferation and differentiation of muscle
cells occur similarly during development and postnatal birth (Schiaffino et al., 2013). Therefore, promotion of myoblast
proliferation and differentiation and induction of myotube hypertrophy should be
beneficial for muscle regeneration and control of muscle mass.Muscle atrophy with aging is accompanied by muscle damage caused by oxidative damage
and malnutrition caused by lack of muscle metabolism. Thus, muscle atrophy is
triggered by increasing muscle protein degradation and decreased protein synthesis
(Zhang et al., 2018). In recent studies,
activation of AMP-activated protein kinase (AMPK) increased muscle atrophy F-box
(MAFbx)/atrogin-1 and muscle RING finger-1 (MuRF-1) via the transcription factor
forkhead box O3a (FoxO3a) (Jaitovich et al.,
2015). This process has been reported to be directly involved in muscle
atrophy by muscle protein degradation through the activation of the
ubiquitin-proteasome pathway (Jaitovich et al.,
2015; Nakashima and Yakabe, 2007;
Tong et al., 2009). Since muscle mass
represents a balance between muscle cell replication, protein synthesis, muscle cell
death and protein degradation (Scicchitano et al.,
2018), increased muscle mass can prevent muscle atrophy by causing an
increase in muscle differentiation and inhibiting muscle loss.Deer antler (Cervi parvum Cornu) is a non-osteolytic horn of
Cervus nippon Temminck or Marcus (Cervus
elaphus L) and has long been used in oriental countries, such as China
and Korea. Deer antler has been reported to contain hexose, pentose, uronic acid,
sialic acid, free amino acids, minerals, prostaglandins, and gangliosides in
glycolipids (Jhon et al., 1999; Sunwoo et al., 1995). Water-soluble proteins,
polypeptides, and free amino acids have been shown to be the main biologically
active components of deer antler (Moreau et al.,
2004). In addition, there is evidence that deer antler extract has strong
potential for promoting bone growth and development (Chen et al., 2015; Shi et al.,
2010). Additionally, Chen et al.
(2014) estimated through microarray analysis that the anti-fatigue effect
of collagen and protein from deer antler extracts is mediated by the increased
expression of genes involved in muscle contraction and development.By evaluating the effect of strengthening muscle differentiation and inhibiting
muscle atrophy by antler extract having various activities, it was attempted to
investigate the possibility of application as a functional material to suppress
muscle atrophy due to aging. Therefore, the effects of deer antler extract on the
promotion of myoblast differentiation and 5-aminoimidazole-4-carboxamide
ribonucleoside (AICAR)-induced muscle atrophy were examined using C2C12
fibroblast.
Materials and Methods
Materials
Dulbecco’s modified Eagle’s medium (DMEM), fetal bovine serum
(FBS), horse serum (HS), and penicillin/streptomycin (PS) were purchased from
WELGENE (Daegu, Korea) and were used for cell culture and differentiation. AICAR
and 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl tetrazolium bromide (MTT) were
obtained from Sigma-Aldrich Chemical (St. Louis, MO, USA). Dried antler
(Cervus canadensis) from adult male Korean elk was obtained
from Kwang Dong Pharmaceutical (Seoul, Korea). According to the previous report,
antler water extract (HWE) and fermented antler (FE) were prepared. The antler
powder was extracted by refluxing for 3 h at 95°C after adding 8 times
the amount of water. Fermented antler was extracted by adding 8 times the amount
of phosphate buffer (PBS, 50 mM, pH 6.0) the antler powder, fermenting it with
Bacillus subtilis for 48 h, and refluxing for 3 h at
95°C. The ultrasonic extract (UE) was extracted by adding 8 times the
amount of PBS to the antler powder for 30 minutes at 120 kHz ultrasonic waves
(AUG-R3-900, Asia Ultrasonic, Bucheon, Korea). After ultrasonic extraction,
reflux extraction was performed at 95°C to obtain an UE. After adding 8
times the amount of PBS (50 mM, pH 7.8) to the antler powder and suspending it,
Alcalase equivalent to 0.5% of the antler powder was added, followed by
hydrolysis at 50°C for 8 h. After hydrolysis, reflux extraction was
performed at 95°C to obtain an antler enzyme hydrolysate (ET). The antler
extracts were concentrated and lyophilized to be used in the further
experiment.
Analysis of collagen
According to the Sunwoo et al. (1998)
method, the collagen content was calculated by multiplying the content of
hydroxyproline by 7. According to the method of Stegemann and Stalder (1967), the content of
hydroxyproline before and after acid hydrolysis with 6 N HCl was measured using
HPLC. A Phenomenex Luna C18 Column (250×4.6 mm, 5 μm) was
employed, using following mobile phase: sodium acetate buffer (pH 4.3)
containing 3% glacial acetic acid and acetonitrile were mixed with 650
and 350 mL, respectively. The flow rate was 1 mL/min, hydroxyproline was
identified at a wavelength of excitation 260/emission 330 nm, and the injection
quantity was 20 μL. The collagen content was calculated by multiplying
the difference by 7 to the hydroxyproline content before and after acid
hydrolysis.
Cell culture and differentiation
The myoblast cell line C2C12 used in this study was purchased from the American
Type Culture Collection (Manassas, VA, USA). C2C12 myoblasts were maintained at
37°C and 5% CO2 using a growth medium containing
90% DMEM, 10% FBS, and 100 unit/mL PS. To maintain cells at an
appropriate density, they were passaged every 48 h. Differentiation medium
containing 90% DMEM, 10% HS, and 100 unit/mL PS was used to
differentiate C2C12 myoblasts into myotubes. To confirm the morphological
changes during the differentiation process, an inverted microscope (Inverted
microscope, Carl Zeiss, Gottingen, Germany) was used to observe cells at a
magnification of 200×.
Cell viability
The cell viability of C2C12 cells was measured using an MTT assay. C2C12 cells
were seeded into a 96-well plate at a concentration of 1×106
cells/mL the day before the experiment. Deer antler extracts (0–1,000
μg/mL) were incubated with cells for 24 h. Subsequently, the culture
supernatant was discarded and 5 mg/mL MTT dissolved in DMEM was added to each
well; the plate was then covered with aluminum foil to create dark conditions
and incubated for 2 h. After removing the MTT solution, 100 μL of
dimethyl sulfoxide was added to the cells and left for 2 h. The absorbance was
measured at 540 nm using a microplate reader (Molecular Devices, Sunnyvale, CA,
USA).
Jenner-Giemsa staining and measurement of myotube length and diameter
Myotube length and diameter were measured using images obtained through
Jenner-Giemsa staining of C2C12 differentiated cells (Veliça and Bunce, 2011). The cultured cells were
washed with PBS, fixed with 100% methanol for 5 min, and air dried for 10
min. The Jenner staining solution (Sigma-Aldrich, St. Louis, MO) was diluted
3-fold with 1 mM sodium PBS (pH 5.6); 1 mL of this solution was incubated in the
wells for 5 min and then the cells were washed with distilled water. The cells
were then incubated for 10 min at 25°C with 1 mL Giemsa stain diluted
1:20 with 1 mM sodium PBS (pH 5.6) and then washed again with water. Cells in
each well were observed using a MM-400 microscope (Nikon, Tokyo, Japan) and
photographed in nine randomly selected areas using a digital microscope camera
JENOPTIK ProgRes speed Xtcore 3 and the ProgRes Image Capture
Software (Jenoptik Optical Systems GmbH, Jena, Germany). Myotube length and
diameter were measured and quantified using the Image-J software (Scion,
Frederick, MD, USA).
RNA isolation and quantitative real-time reverse-transcription-polymerase
chain reaction (qRT-PCR)
Total RNA from C2C12 cells was extracted using the TRIzol® reagent
(Invitrogen, CA, USA), according to the manufacturer’s protocol. Quality
controlled RNA samples with high optical density ratios were treated with RQ1
RNase-free DNase I (Promega, WI, USA). One microgram of total RNA was reverse
transcribed using SuperScript® III Reverse Transcriptase (Invitrogen)
with oligo d (T) primers. qRT-PCR was performed using the Taqman Gene Expression
Master Mix (Applied Biosystems, Foster City, CA, USA), and quantitative analyses
were conducted using the StepOne plus Software V. 2.0 (Applied Biosystems). All
results were normalized against the expression of the control gene, GAPDH
(NM_008084.2), using the ΔΔCt method (Livak and Schmittgen, 2001). The information of primers for
the qRT-PCR of tested genes related to muscle differentiation and atrophy were
as follows: myogenin differentiation 1 (MyoD1) (NM_010866.2), myogenic
factor 5 (Myf5) (NM_008656.5), AMPK (NM_001013367.3), forkhead box
O3 (FoxO3a) (NM_019740.2), muscle RING-finger protein 1 (MuRF-1)
(NM_001039048.2), and myogenin (NM_031189.2).
Statistical analysis
All experimental results were obtained using the SPSS ver. 18.0 (SPSS, Chicago,
IL, USA) statistical program. Data represent the mean±SD. Differences
among the groups were evaluated by one-way analysis of variance (ANOVA) and
Tukey’s multiple test. Student’s t-test was used
to analyze differences between groups with normally distributed data.
Results and Discussion
Collagen composition and C2C12 cells viability
The collagen content of HWE, ET, UE, and FE, it was 20.09±0.19,
29.07±0.12, 27.32±0.09, 23.58±0.11 μg/mg of extract,
respectively, and it was confirmed that the collagen content of the extract
increased due to fermentation, enzyme, and ultrasonication treatment (Table 1). In particular, the content of
hydroxyproline (4.15±0.02 μg/mg of extract) and protein
(295.05±11.22 mg/g of extract) as well as collagen in ET was higher than
that of other antler extracts.
Table 1.
Protein, hydroxyproline, and collagen content in antler
extracts
Sample
Protein (mg/g)
Hydroxyproline (μg/mg)
Collagen (μg/mg)
HWE
240.66±10.31
2.87±0.03
20.09±0.19
ET
295.05±11.22
4.15±0.02
29.07±0.12
UE
225.08±7.22
3.90±0.01
27.32±0.09
FE
284.68±6.15
3.37±0.02
23.58±0.11
Content value represents the mean±SD.
HWE, hot water extract; ET, enzyme hydrolysate; UE, ultrasonic
extract; FE, how water extract of fermented deer antler.
Content value represents the mean±SD.HWE, hot water extract; ET, enzyme hydrolysate; UE, ultrasonic
extract; FE, how water extract of fermented deer antler.Deer antler extracts, including HWE, FE, ET, and UE were used for the evaluation
of myoblast C2C12 cells differentiation activity. These extracts had protein
contents of 225.1–295.1 mg/g extract (data not shown). Upon evaluation of
the cytotoxicity of the antler extracts against C2C12 cells (Fig. 1), all extracts except the UE did not
show a cytotoxicity of up to 1,000 μg/mL. UE-treated cells showed a cell
viability of 90.7%–88.9% upon treatment with
200–1,000 mg/mL extract. Deer antler extracts were found to have no or
low cytotoxicity at 1,000 μg/mL. Therefore, further experiments were
conducted using up to 200 μg/mL of extracts, with little
cytotoxicity.
Fig. 1.
Cell viability of deer antler extracts on C2C12 cells.
Values are presented as the mean±SD for each group. CON, control
group; HWE, hot water extract; FE, how water extract of fermented deer
antler; ET, enzyme-derived extract; UE, extract prepared by
ultrasonication of deer antler.
Cell viability of deer antler extracts on C2C12 cells.
Values are presented as the mean±SD for each group. CON, control
group; HWE, hot water extract; FE, how water extract of fermented deer
antler; ET, enzyme-derived extract; UE, extract prepared by
ultrasonication of deer antler.Deer antler extracts have been widely used in traditional Chinese medicine for
centuries and are generally believed to provide nourishment, strengthen the
kidneys, strengthen the spleen, strengthen bones and muscles, and promote blood
flow (Wu et al., 2013). Previous studies
have reported that the collagen and protein components of deer antler extracts
are major bioactive substances with effects, such as anti-fatigue, anti-stress
(Fengyan et al., 2001), and bone
growth effects (Niu et al., 2012) and
stimulation of hematopoietic function (Lee et
al., 2012).Kitakaze et al.
(2016) reported that collagen hydrolysates promoted differentiation
and increased size of myoblast C2C12 cells. Hydroxyprolyl-glycine, a collagen
hydrolysate, has been reported to induces myogenic differentiation and root
canal hypertrophy by increasing the size of the root canal and the expression of
root canal specific myosin heavy chain (MyHC) and tropomyosin structural
proteins. Hyp-Gly presumably promotes myogenic differentiation by activating the
PI3K/Akt/mTOR signaling pathway according to peptide/histidine transporter 1 for
entry into cells (Kitakaze et al., 2016;
Li et al., 2016; Niu et al., 2012).
Changes in myotube length and diameter caused by C2C12 cells
differentiation
To determine the degree of myotube differentiation during C2C12 cells
differentiation, Jenner-Giemsa staining was performed on the second and fourth
days of C2C12 cells differentiation to measure changes in myotube morphology,
such as myotube length and diameter (Fig. 2
and 3).
Fig. 2.
Changes in myotube structure during C2C12 cell differentiation, as
observed through Jenner-Giemsa staining.
Values are presented as the mean±SD for each group. CON, control
group; HWE, hot water extract; ET, enzyme-derived extract; UE, extract
prepared by ultrasonication of deer antler; FE, how water extract of
fermented deer antler.
Fig. 3.
Changes in myotube length and diameter during C2C12 cell
differentiation.
Values are presented as the mean±SD for each group. The different
letters indicate statistically significant (p<0.05) differences
among groups, as determined through Tukey’s test. CON, control
group; HWE, hot water extract; ET, enzyme-derived extract; UE, extract
prepared by ultrasonication of deer antler; FE, how water extract of
fermented deer antler.
Changes in myotube structure during C2C12 cell differentiation, as
observed through Jenner-Giemsa staining.
Values are presented as the mean±SD for each group. CON, control
group; HWE, hot water extract; ET, enzyme-derived extract; UE, extract
prepared by ultrasonication of deer antler; FE, how water extract of
fermented deer antler.
Changes in myotube length and diameter during C2C12 cell
differentiation.
Values are presented as the mean±SD for each group. The different
letters indicate statistically significant (p<0.05) differences
among groups, as determined through Tukey’s test. CON, control
group; HWE, hot water extract; ET, enzyme-derived extract; UE, extract
prepared by ultrasonication of deer antler; FE, how water extract of
fermented deer antler.On the second day of cell differentiation, myotube length was increased in cells
treated with deer antler extracts compared with the control group (CON). On the
fourth day, myotube length was increased in cells treated with all deer antler
extracts except for FE. The cells treated with FE showed increased myotube
length at extract concentrations of 50 and 100 μg/mL and shortened
myotube length when treated with extract concentration of 200 μg/mL
(Fig. 3).On day two of cell differentiation, cells treated with deer antler extract showed
a similar diameter to that of CON, but on day four of cell differentiation,
cells showed a tendency to have increased myotube diameter compared to CON
(Fig. 3). Upon treatment of cells with
deer antler extract, myotube length was increased by promoting the myotube
differentiation capacity, and the myotube diameter also tended to increase with
increasing myotube length.In the differentiation phase, the length of myoblasts become increased, fused
with localized cells and converted into tubular multinuclear cells. When
differentiation is induced from myoblasts to myotubes, the number of muscle
fibers increases due to the fusion between cells and the thickening of muscle
fibers also occurs (Bentzinger et al.,
2012; Burattini et al., 2004).
Net protein balance affects the size of individual myotubes and myofibers, where
an increase in net protein levels leads to muscle hypertrophy (White et al., 2010) and contributes to an
increase in skeletal muscle mass (Ontell et al.,
1984).
Effect of deer antler extract on the expression of myogenic
differentiation-related genes in C2C12 myoblasts
Muscle differentiation is regulated by myogenic regulatory factors (MRFs), such
as MyoD1 and Myf5 (Braun et al., 1992;
Hyatt et al., 2003). The effect of
the antler extract on the expression of muscle differentiation factors MyoD1 and
Myf5 was measured on days two and four of C2C12 cell differentiation,
respectively (Fig. 4). The expression
levels of MyoD1 were not significantly affected by myoblast differentiation on
days two and four, whereas Myf5 expression levels were high on days two and four
compared with the CON. Deer antler extracts significantly increased the
expression level of Myf5 (p<0.05). In particular, it was found that the
level of Myf5 increased in a concentration-dependent manner when the HWE was
added on day four of myogenic differentiation. However, increasing
concentrations of UE and FE tended to decrease the expression level of Myf5.
These results indicated that antler extract was not only involved in increasing
the size (length and diameter) of myotubes, but also in increasing the
expression level of myogenic differentiation factor that promotes myoblast C2C12
cell differentiation.
Fig. 4.
Effects of deer extracts on the relative expression of MyoD1 and Myf5
mRNA in C2C12 cells at two and four days of cell
differentiation.
Values are presented as the mean±SD for each group. The different
letters indicate statistically significant (p<0.05) differences
among groups, as determined by Tukey’s test. CON, normal control;
HWE, hot water extract; ET, enzyme-derived extract; UE, extract prepared
by ultrasonication of deer antler; FE, how water extract of fermented
deer antler; MyoD1, myogenin differentiation 1; Myf5, myogenic factor
5.
Effects of deer extracts on the relative expression of MyoD1 and Myf5
mRNA in C2C12 cells at two and four days of cell
differentiation.
Values are presented as the mean±SD for each group. The different
letters indicate statistically significant (p<0.05) differences
among groups, as determined by Tukey’s test. CON, normal control;
HWE, hot water extract; ET, enzyme-derived extract; UE, extract prepared
by ultrasonication of deer antler; FE, how water extract of fermented
deer antler; MyoD1, myogenin differentiation 1; Myf5, myogenic factor
5.Muscle differentiation is regulated mainly by MRFs, such as MyoD1 and Myf5, which
are involved in establishing myogenic lineages (Braun et al., 1992). Later in muscle differentiation, there is an
increase in the expression of MyHC, a major structural protein of myotubes
(Soundharrajan et al., 2019). Deer
antler extracts were also found to be involved in the increase in the expression
levels of muscle differentiation factors (Fig.
4), which may increase the size of the myotubes (Fig. 3).
Inhibitory activity of deer antler extracts on muscle atrophy factors in
AICAR-induced muscle atrophy in C2C12 cells
As a result of a 0.25–2 mM treatment of AICAR to create a muscle atrophy
model in myoblast cells, AMPK expression increased in an AICAR
concentration-dependent manner (Fig. 5).
C2C12 cells showed no cytotoxicity when treated with 2 mM of AICAR (data not
shown). Therefore, C2C12 cells were treated with 2 mM AICAR to induce muscle
atrophy, and the effect of the inhibition of muscle atrophy through the addition
of antler extracts was confirmed.
Fig. 5.
Effects of AICAR on relative AMPK mRNA expression in C2C12
cells.
Values are presented as the mean±SD for each group. The different
letters indicate statistically significant (p<0.05) differences
among groups, as determined by Tukey’s test. CON, control group;
AICAR, 5-aminoimidazole-4-carboxamide ribonucleoside; AMPK,
AMP-activated protein kinase.
Effects of AICAR on relative AMPK mRNA expression in C2C12
cells.
Values are presented as the mean±SD for each group. The different
letters indicate statistically significant (p<0.05) differences
among groups, as determined by Tukey’s test. CON, control group;
AICAR, 5-aminoimidazole-4-carboxamide ribonucleoside; AMPK,
AMP-activated protein kinase.The effects of deer antler extracts (50 and 200 μg/mL) on the expression
levels of muscle atrophy factors (FoxO3a and MuRF-1) were measured in
AICAR-induced muscle-atrophy cells (Fig.
6). Upon AICAR treatment, the expression of AMPK increased in C2C12 cells
and deer antler extract-treated muscle-atrophy cells compared to the CON. The
expression levels of AMPK in deer antler extract-treated cells were higher than
those in cells treated with AICAR alone (CON group). The muscle atrophy factors
FoxO3a and MuRF-1 showed significantly higher expression levels in the AICAR
treated group (CON) than in the normal group (NOR). In deer antler
extract-treated muscle-atrophied cells, the increase in the expression level of
the muscle atrophy factor MuRF-1 tended to be lower than that in the CON group
cells. In particular, the expression level of FoxO3a in deer antler
extract-treated atrophied cells was significantly lower than that in cells
treated with AICAR alone (p<0.05).
Fig. 6.
Effects of deer antler extract on relative mRNA expression of AMPK,
FoxO3a, and MuRF-1 in AICAR-induced muscle-atrophied C2C12
cells.
Values are presented as the mean±SD for each group. Asterisks
indicate significant differences: *** p<0.001
indicates significance of difference compared with the control, as
determined by Student’s t-test. The different letters indicate
statistically significant (p<0.05) differences among groups, as
determined by Tukey’s test. AMPK, AMP-activated protein kinase;
NOR, normal group; CON, control group; HWE, hot water extract; FE, how
water extract of fermented deer antler; ET, enzyme-derived extract; UE,
extract prepared by ultrasonication of deer antler; FoxO3a, forkhead box
O3a; MuRF-1, muscle RING finger-1; AICAR, 5-aminoimidazole-4-carboxamide
ribonucleoside.
Effects of deer antler extract on relative mRNA expression of AMPK,
FoxO3a, and MuRF-1 in AICAR-induced muscle-atrophied C2C12
cells.
Values are presented as the mean±SD for each group. Asterisks
indicate significant differences: *** p<0.001
indicates significance of difference compared with the control, as
determined by Student’s t-test. The different letters indicate
statistically significant (p<0.05) differences among groups, as
determined by Tukey’s test. AMPK, AMP-activated protein kinase;
NOR, normal group; CON, control group; HWE, hot water extract; FE, how
water extract of fermented deer antler; ET, enzyme-derived extract; UE,
extract prepared by ultrasonication of deer antler; FoxO3a, forkhead box
O3a; MuRF-1, muscle RING finger-1; AICAR, 5-aminoimidazole-4-carboxamide
ribonucleoside.Recent studies have shown that muscle atrophy occurs due to increased proteolysis
due to the activation of the ubiquitin-proteasome pathway (Bodine and Baehr, 2014; Jagoe and Goldberg, 2001; Liu et
al., 2016). In particular, muscle atrophy F-box (MAFbx)/atrogin-1 and
MuRF-1, which are muscle-specific ubiquitin ligases, are expressed early in the
muscle atrophy process and are directly involved in muscle protein degradation
(Bodine and Baehr, 2014; Liu et al., 2016). In addition, when muscle
atrophy is induced, expression of genes, such as myogenin and MyoD,
muscle-specific transcription factors involved in myogenic differentiation, is
reduced by activating muscle-specific gene expression (Hyatt et al., 2003; Tintignac et al., 2005).
Inhibitory activity of deer antler extracts on muscle differentiation factors
in AICAR-induced muscle atrophy in C2C12 cells
The expression levels of MyoD1 and myogenin, which are muscle differentiation
factors, were lower than those of normal cells upon treatment with AICAR alone
(Fig. 7). In deer antler
extract-treated muscle-atrophied cells, the expression levels of muscle
differentiation factors MyoD1 and myogenin were higher than those in cells
treated with AICAR alone. The expression levels of MyoD1 in the enzyme-treated
deer antler extract (ET, 200 μg/mL)-treated muscle-atrophied cells were
significantly higher than those of normal cells (p<0.05). In addition,
the expression levels of myogenin in the enzyme-treated deer antler extract (ET,
50 and 200 μg/mL) and fermented deer antler extract (FE, 200
μg/mL)-treated muscle-atrophied cells were significantly higher than that
in normal cells. The treatment of AICAR-induced atrophied cells with deer antler
extract inhibited the expression of the muscle atrophy factors FoxO3a and MuRF1.
In addition, deer antler extract treatment restored the expression levels of
myoD1 and myogenin to the same or higher levels as those of normal cells.
Fig. 7.
Effects of deer antler extract on relative mRNA expression of MyoD1
and Myogenin in AICAR-induced muscle atrophy in C2C12 cells.
Values are presented as the mean±SD for each group. Asterisks
indicate significant differences: *** p<0.001
indicates significance of difference compared with the control, as
determined by Student’s t-test. The different letters indicate
statistically significant (p<0.05) differences among groups, as
determined by Tukey’s test. NOR, normal group; CON, control
group; HWE, hot water extract; FE, how water extract of fermented deer
antler; ET, enzyme-derived extract; UE, extract prepared by
ultrasonication of deer antler; AICAR, 5-aminoimidazole-4-carboxamide
ribonucleoside.
Effects of deer antler extract on relative mRNA expression of MyoD1
and Myogenin in AICAR-induced muscle atrophy in C2C12 cells.
Values are presented as the mean±SD for each group. Asterisks
indicate significant differences: *** p<0.001
indicates significance of difference compared with the control, as
determined by Student’s t-test. The different letters indicate
statistically significant (p<0.05) differences among groups, as
determined by Tukey’s test. NOR, normal group; CON, control
group; HWE, hot water extract; FE, how water extract of fermented deer
antler; ET, enzyme-derived extract; UE, extract prepared by
ultrasonication of deer antler; AICAR, 5-aminoimidazole-4-carboxamide
ribonucleoside.In Fig. 6, muscle atrophy factors FoxO3a and
MuRF-1 can be seen to be increased upon AICAR treatment, and their increase
results in muscle atrophy. In addition, in Fig.
7, the expression levels of MyoD and myogenin, which are myogenic
factors, can be seen to decrease upon AICAR treatment. However, MuRF-1
expression decreased upon treatment with antler extract, and the expression
factor of myogenesis markers increased. Deer antler extracts seemed to
contribute more to the inhibition of muscle atrophy by increasing the expression
of muscle differentiation factors than by decreasing the expression of muscle
atrophy factors.The increase in skeletal muscle mass occurs due to an increase in muscle protein
synthesis (MPS) compared to muscle protein breakdown (Rennie, 2007). To increase skeletal muscle or inhibit
muscle loss, it is important to have both an increase in myogenic capacity and
an inhibition of muscle loss. Therefore, the supply of high-quality dietary
protein, which is an essential nutrient for promoting muscle and overall
metabolic health, is important (Arentson-Lantz et
al., 2015). Deer horn extract is an excellent source of protein that
is especially rich in collagen type I (Li et
al., 2016). Therefore, the active substances of antler extract to
myogenesis and inhibit the muscle atrophy are presumed to be protein, collagen
and hydroxyproline. It has also been reported that collagen breakdown products,
which form a major component of antlers, are involved in the activation of
mammalian target of rapamycin (mTORC1) and MPS. The mechanistic/mTORC1 pathway
is the central molecular pathway of MPS and is activated by a variety of
stimuli, including, but not limited to, resistance exercise (Bolster et al., 2003), insulin (Conejo et al., 2001), and dietary amino
acids (Gordon et al., 2013). We found
four distinct effects of treating C2C12 cells with antler extract: 1) increase
in myotube size, 2) increase in muscle differentiation factor (MyoD1 and Myf5)
expression, 3) suppression of muscular atrophy factor (FoxO3a and MuRF-1)
expression, and 4) increase in the expression of the muscle differentiation
factors (MyoD1 and myogenin), in a muscle atrophy model.
Conclusion
Several studies have reported that collagen, a major component of deer antler, helps
myogenesis. In this study, experimental results on C2C12 cells suggested that antler
extract has the ability to inhibit muscle atrophy and promote muscle differentiation
by increasing the expression of myoblast differentiation factors MyoD, Myf5 and
myogenin. Further experiments will be conducted to identify muscle differentiation
promoting substances.
Authors: Jon-Philippe K Hyatt; Roland R Roy; Kenneth M Baldwin; V Reggie Edgerton Journal: Am J Physiol Cell Physiol Date: 2003-07-02 Impact factor: 4.249
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Fig. 7.