INTRODUCTION
Silk peptide (SP) is a natural biomolecule that has been used in powder or extract
form for a variety of purposes in Asian countries
1, 2. SP comprises biopolymers
produced by silkworm cocoons for protection from the environment during
metamorphosis to the mature moth stage
3. Nowadays, SP is used in various
fields such as biotechnology and biomedicine since it does not cause any side
effects
4,
5.
Recently, in vitro and in vivo studies have shown could stimulate lipolysis and
improve health and exercise performance
1, 6, 7. In 2012, Lee et al
8. reported that
treatment with 1 mg/mL SP + 0.2 nM insulin increases glucose uptake (124 ±
2.5%) via upregulation of glucose transporter type 4 (GLUT4) and decreases fat
accumulation via upregulation of leptin in 3T3-L1 preadipocytes. In addition,
treatment with SP inhibited the differentiation of preadipocytes and adipogenesis by
modulating the peroxisome proliferator-activated receptor alpha (PPAR-α)
signal transduction pathway and decreased body weight and size of adipocytes (86.1
± 2.5%) in a high-fat diet-fed animal model. Furthermore, the addition of 5%
SP to normal diet reduced body weight and abdominal fat in rats. In conclusion, SP
ingestion might reduce adipose tissue by both stimulating lipolysis and inhibiting
lipogenesis. Moreover, 5 weeks of SP treatment with swim training increased fat
oxidation via upregulation of adenosine monophosphate-activated protein kinase
(AMPK) and PPAR-α in liver cells
9. The weights of abdominal and
epididymal fat pads were lower in animals receiving SP treatment along with swim
training than that in untreated animals undergoing swim training only, i.e., SP
intake and/or swimming could activate fat metabolism.
Recently, we used an open circuit calorimetry system to investigate the effects of SP
administration on energy expenditure and substrate utilization in resting mice for
24 h. We found that the administration of SP during 2 weeks of endurance training
(70% of maximum oxygen uptake) increased fat oxidation by about 16% compared to that
reported for the group (not receiving SP)
10. Interestingly, we found that
the maximum oxygen uptake significantly increased after treatment with 800 mg/kg SP
for 2 weeks. Moreover, fat oxidation during a 1-h exercise was 13% higher in the
SP-treated (SP + endurance training) group than that in the non-SP-treated
(endurance training only) group. These results suggest that SP could be an effective
supplement for enhancing fat metabolism when used in combination with endurance
training. However, 800 mg/kg SP is a large amount of worm protein to be consumed by
humans (around 50 g needed for a 60-kg person). In addition, it has still not been
elucidated whether SP treatment along with endurance training could enhance fat
metabolism during exercise in a dose-dependent manner.
Accordingly, the aim of the present study was to determine the optimal SP dose for
enhancing fat metabolism during exercise. This was achieved by investigating the
effects of different SP doses (200, 400, and 800 mg/kg) on energy metabolism during
exercise using the open circuit calorimetry system.
METHODS
Animals
Fifty male ICR mice (6 weeks old) were obtained from Orient Bio Inc. (Seongnam,
Korea). All mice were housed in standard plastic cages (1643 × 766
× 1894 m/m; 5 mice/cage) under controlled conditions of humidity (50%)
and temperature (23 ± 1 °C) with alternating 12-h light/dark
cycles. They were adapted to the laboratory housing conditions for 7 days, and
given free access to water and a non-purified commercial diet (5L79, Orient Bio
Inc.) containing crude protein, 180 g/kg diet; crude fat, 52 g/kg diet; crude
fiber, 52 g/kg diet; minerals, 57 g/kg diet; and carbohydrates, 368 g/kg diet.
The protein, fat, and carbohydrate ratio (%) based on calories was 21:14:65, and
the gross and metabolizable caloric contents of the diet were 4.04 and 3.21
kcal/g, respectively. Details of the experimental design are shown in
Figure 1.
Figure 1.
Experimental design.
Mice were randomly divided into 5 groups; Sed (distilled water), SP0 (distilled
water, 0 mg/kg SP, no training), SP200 (200 mg/kg SP + training), SP400 (400
mg/kg SP + training), and SP800 (800 mg/kg SP + training). All SP groups (SP0,
SP200, SP400, and SP800) underwent training by running on a treadmill 5 times a
week for 2 weeks. SP was dissolved in distilled water and administered to the SP
groups orally intraperitoneally 1 h before the endurance training. The Sed and
SP0 groups received the vehicle (distilled water) only.
Silk peptide
The SP was obtained from Worldway Co., Ltd (Jeoneui, Korea). It is mainly
composed of alanine (34.36%), glycine (27.23%), isoleucine (15.51%), serine
(9.58%), and minor amounts of other amino acids. The detailed composition of SP
is shown in
Table 1.
The molecular weight of SP ranges from 150 D to 350 D with an average molecular
weight of about 250 D. SP was dissolved in distilled water and administered to
the SP200, SP400, and SP800 groups; while the Sed and SP0 groups were
administered distilled water orally every day for 2 weeks
2, 10.
Table 1
Amino acid compositions (%) of SP
Amino acid |
Ala |
34.36 |
Phe |
0.87 |
Gly |
27.23 |
Pro |
0.44 |
Iso |
15.51 |
Tyr |
0.41 |
Ser |
9.58 |
His |
0.21 |
Val |
3.49 |
Arg |
0.17 |
Thr |
2.00 |
Met |
0.10 |
Asp |
1.68 |
Lys |
0.10 |
Glu |
1.28 |
Cys |
0.05 |
Ile |
1.25 |
Trp |
0.05 |
Leu |
1.24 |
Sum |
100.00 |
Training method
All mice were adapted to a treadmill training intensity of 15 m/min, 8°
slope for 3 days. The mice were then tested 5 times per week for 2 weeks at the
following training conditions: 20 m/min, 8° slope, 50 min/day for the
first week and 25 m/min, 8° slope, 50 min/day (about 70-75% of maximum
oxygen uptake) for the second week
2, 10, 11.
Energy metabolism alterations during exercise
After 2 weeks of training, energy metabolism was measured during a 1-h exercise
at the training conditions of the second week (25 m/min, 8° slope, 70-75%
of maximum oxygen uptake). Mice were placed in exercise metabolism chambers for
adaptation 2 h before the measurement
10, 12, 13.
Statistical analysis
Data are given as mean ± standard deviation (SD). All statistical analyses
were performed with SPSS version 19.0 software (SPSS, Inc., Chicago, IL, USA).
Oxygen uptake, carbon dioxide production, RER (respiratory exchange ratio),
carbohydrate oxidation, fat oxidation, food intake, and body weight were
analyzed by twoway repeated measures analysis of variance (ANOVA). One-way ANOVA
was used to determine the changes in energy metabolism during exercise and
Bonferroni post-hoc analysis was conducted if significance was obtained.
Differences were considered significant at P < 0.05.
RESULTS
Changes in body weight and food intake
Table 2 shows the
changes in body weight and food intake in Sed, SP0, SP200, SP400, and SP800
groups after 2 weeks of SP treatment and endurance training. There were no
significant differences between the groups in the final body weights (38.82
± 1.6, 37.7 ± 1.4, 38.1 ± 1.7, 37.6 ± 1.5, and 37.7
± 2.0 g) and weight gain (2.9 ± 0.6, 2.30 ± 1.8, 2.52
± 0.8, 2.54 ± 1.6, and 2.44 ± 1.3 g). Nevertheless, food
intake (in g/day and g/2 weeks) was significantly higher in the SP800 group than
in the Sed, SP0, SP200, and SP400 groups.
Table 2
Body weight and food intake changes for 2 weeks treatment Sed, SP0,
SP200, SP400 and SP800 groups
BW |
Sed |
SP0 |
SP200 |
SP400 |
SP800 |
Initial (g) |
35.65 ± 1.2 |
35.42 ± 1.4 |
35.64 ± 1.4 |
35.13 ± 1.7 |
35.26 ± 1.6 |
Final (g) |
38.82 ±
1.6 |
37.7 ±
1.4 |
38.1 ±
1.7 |
37.6 ±
1.5 |
37.7 ±
2.0 |
Gain (g) |
2.9 ± 0.6 |
2.30 ± 1.8 |
2.52 ± 0.8 |
2.54 ± 1.6 |
2.44 ± 1.3 |
Food intake (g/day) |
7.6 ±
1.1 |
7.9 ±
0.18 |
6.5 ±
0.4 |
7.4 ±
0.9 |
10.2 ±
3.1*
|
Food intake (g/2weeks) |
98.2 ± 10.7 |
96.3 ± 0.0 |
87.6 ± 0.2 |
100.5 ± 1.3 |
133.7 ± 2.8*
|
FER |
0.38 ±
0.0 |
0.23 ±
0.2 |
0.34 ±
0.1 |
0.38 ±
0.2 |
0.37 ±
0.1 |
Energy metabolism during exercise
Fat oxidation during the 1-h exercise was calculated from the carbon dioxide
production (VCO2) and oxygen consumption (VO2) values. Two-way ANOVA with
repeated measures for fat oxidation showed that time had a significant
effect (P < 0.001) on fat oxidation, while group (P = 0.107) and
group-by-time interactions (P = 0.534) did not (
Figure 2 A). The levels of fat oxidation
during the 1-h period in the Sed, SP0, SP200, SP400, and SP800 groups were 1.02
± 0.15, 1.04 ± 0.17, 0.98 ± 0.10, 1.14 ± 0.19, and
1.15 ± 0.07 g/kg/h, respectively. Fat oxidation in the SP800 group was 13
and 11% higher than that in the Sed and SP0 groups, respectively (
Figure 2 B). When
investigating fat oxidation at certain time points, it was found to be
significantly higher in the SP800 group than that in the SP0 group at 36, 40,
and 56 min and the Sed group at 2, 4, 6, 8, 12, 14, 16, 20, 40, 46, 50, 52, 56,
and 60 min. However, fat oxidation was significantly higher in the SP400 group
than that in the SP0 group at 34 min only and the Sed group at 46 and 52 min.
Figure 2.
Change in the fat oxidation level during a 1-h exercise (A).
The sum of the fat oxidation level during a 1-h exercise (B).
Sed: distilled water, SP0: distilled water with training, SP200: 200
mg/kg SP with training, SP400: 400 mg/kg SP with training, SP800: 800
mg/kg SP with training. # Sed vs. SP400, P < 0.05; * Sed vs. SP800, P
< 0.05; Δ SP0 vs. SP400, P < 0.05; + SP0 vs. SP800, P <
0.05. Values are presented as means ± standard deviations (n =
40).
Two-way ANOVA with repeated measures for carbohydrate oxidation showed
significant time effect (P < 0.001), but not for group (P = 0.393) and
group-bytime interactions (P = 0.545) (
Figure 3). Regarding carbohydrate
oxidation, there was no significant difference among the groups during the 1-h
exercise.
Figure 3.
Change in the carbohydrate oxidation level during a 1-h
exercise. Sed: distilled water, SP0: distilled water with
training, SP200: 200 mg/kg SP with training, SP400: 400 mg/kg SP with
training, SP800: 800 mg/kg SP with training. Values are presented as
means ± standard deviations (n = 40).
DISCUSSION
In the present study, we used an open circuit calorimetry system to investigate the
effect of different doses of SP (200, 400, and 800 mg/kg) on energy metabolism
during a 1-h exercise in mice. We found that treatment with 800 mg/kg SP for 2 weeks
together with endurance training enhanced fat oxidation during a 1-h exercise in the
early (until 20 min after the start) and late (around last 20 min) phases. However,
the total amount of fat oxidation during the 1-h period did not reach a
statistically significant level (fat oxidation in the SP800 group was 13 and 11%
higher than that in the Sed and SP0 groups, respectively). However, lower doses of
SP (200 and 400 mg/kg) had little effect on fat oxidation in mice undergoing
training.
We previously reported that fat oxidation during a 1-h exercise in the SP group (800
mg/kg SP + endurance training for 2 weeks) was 13% higher than that in the untreated
training group
2.
This result was similar to the result of the present study, which demonstrated an
11% increase in fat oxidation in the SP-treated group compared to that reported for
the untreated group. However, we found that lower doses of SP (200 and 400 mg/kg)
had no effect on fat metabolism during exercise. Thus, we concluded that 800 mg/kg
of SP could be effective for training athletes such as long-distance runners.
Interestingly, we observed that daily food intake (g/day) was markedly higher in the
SP800 group than that in the other groups although the final body weight and body
weight gain did not differ among groups. A recent study reported that long-term (8
weeks) administration of SP along with high-fat diet (lard content; 20.69%) reduced
body weight and body fat although food intake did not differ between the
groups
1.
In another study, administration of SP for 5 weeks with swimming exercise decreased
body weight and body fat to a greater extent than that observed with swimming
only
9.
According to the results from Lee et al (2012)
1, the decreased fat accumulation
is mediated by upregulation of leptin in 3T3-L1 preadipocytes. The results of our
study demonstrated that the SP800 group appeared to burn much more fat while doing
physical activity (running). Thus, we cautiously assumed that mice treated with 800
mg/kg SP might utilized more energy during the dark cycle (physical activity period)
as well as during training.
However, the mechanism by which SP intake (800 mg/kg) further enhanced fat oxidation
and showed slight anti-obesity effect with exercise is still unclear. In addition,
the dose of 800 mg/kg body weight of SP would be a very large amount of worm protein
intake per day for human subjects. Thus, further studies are required to elucidate
the molecular mechanisms related to the anti-obesity effect of SP and to search for
strategies to reduce the amount of SP intake, e.g., the combination of SP with other
non-protein supplements to increase fat metabolism.
In conclusion, our results suggest that 800 mg/kg of SP could be the optimal dose for
enhancing fat metabolism in combination with endurance training in mice. In
addition, SP treatment was found to be effective in reducing body weight by
enhancing fat metabolism. However, further studies are required to elucidate the
mechanisms underlying the SP anti-obesity effect and to determine the suitable dose
of SP for enhancing fat metabolism in human subjects.
COMPETING INTERRESTS
The authors declare that they have no competing interests.
Acknowledgments
This study was supported by a grant (NRF-2011-32A-G00050) from the National Research
Foundation, which is funded by the Korean Government.
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