The effect of β-hydroxy-β-methylbutyrate (HMB) on the morphology of skeletal muscle after concurrent training

Teixeira, Giovana Rampazzo; Gobbo, Luis Alberto; Santos, Nilton José dos; Araújo, Rafael Gavassa de; Santos, Carolina Cabral dos; Malheiro, Olga Cristina de Mello; Castoldi, Robson Chacon; Camargo-Filho, Jose Carlos Silva; Papoti, Marcelo

doi:10.1590/S1980-6574201600030010

Abstract

The aim of the present study was to investigate the effects of β-hydroxy-β-methylbutyrate (HMB) supplementation in association with concurrent training on morphological soleus muscle of rats. Wistar male rats were divided randomly into four groups: Control (C), Supplemented (S), Training (T) and Training + Supplemented (TS). Groups S and TS received 76mg/kg/day of HMB and the training groups (T and TS) were inserted into concurrent training program 3 times/week for 8 weeks. HMB had positive effects either on body composition of the animals or in type II muscle fibers. The concurrent exercise training was able in reducing the total fat mass as well as in increasing the diameter of muscle fibers. Our findings shows that HMB had an anti-catabolic effect with reference to the parameters of volume, weight and morphology of the soleus muscle, and there was a positive interaction between HMB supplementation and concurrent exercise training.

Keywords:
concurrent training; HMB; soleus muscle; supplementation; Wistar rats

Introduction

Nutrition, combined with physical training, is an important tool in sports practice, in an attempting to reduce fatigue and to give the athletes better recovery and yield. Indeed, many athletes try to enhance physical performance training by different approaches and supplementation is one of a nutritional strategy.¹1. Maughan RJ, Burke LM. Practical nutritional recommendations for the athlete. Nestle Nutrition Institute Workshop Series, 2011; 69:131-149.

Beta-hydroxy-beta-methylbutyrate (HMB) has been considered as an agent of empowerment to elevate strength levels, enhancing size skeletal muscle and preventing its collapse when combined with exercise training. It may even attenuate the loss of muscle mass induced by Acquired Immunodeficiency Syndrome - HIV²2. Clark RH, Feleke G, Din M, Yasmin T, Singh G, Khan FA et al. Nutritional Treatment for Acquired Immunodeficiency Virus-Associated Wasting Using β-Hydroxy-β-Methylbutyrate, Glutamine, and Arginine: A Randomized, Double-Blind, Placebo-Controlled Study. J Parenter Enteral Nutr. 2000; 24:133-139.. In addition, HMB improves strength increases fat metabolism, suppress muscle proteolysis, activates myogenic cell proliferation and differentiation, as well as provides an adequate amount of cholesterol precursor³3. Wilson J, Wilson GJ. Contemporary issues in protein requirements and consumption for resistance trained athletes. J Int Soc Sports Nutr. 2006; 3:7-27.^{), (}⁴4. Ransone J, Neighbors K, Lefavi R, Chromiak J. The effect of beta-hydroxy beta-methylbutyrate on muscular strength and body composition in collegiate football players. J Strength Cond Res, 2003;17:34-39.^{), (}⁵5. Eley HL, Russell ST, Baxter JH, Mukerji P, Tisdale MJ. Signaling pathways initiated by beta-hydroxy-beta-methylbutyrate to attenuate the depression of protein synthesis in skeletal muscle in response to cachectic stimuli. Am J Physiol. 2007; 293:E923- E931.^{), (}⁶6. Kornasio R, Riederer I, Butler-Browne G, Mouly V, Uni Z, Halevy O. Beta-hydroxy-beta-methylbutyrate (HMB) stimulates myogenic cell proliferation, differentiation and survival via the MAPK/ERK and PI3K/Akt pathways. Biochim Biophys Acta, 2009; 1793:755-763.^{), (}⁷7. Gallagher PM, Carrithers JA, Godard MP, Schulze KE, Trappe SW. Beta-hydroxy-beta-methylbutyrate ingestion, Part I: effects on strength and fat free mass. Med Sci Sports Exerc, 2000; 32:2109-2115.. HMB is a byproduct of the metabolism of leucine which is synthesized from a-ketoisocaproate (KIC) in the liver and in the cytosol of hepatocytes, and also in muscle cells⁸8. Pimentel GD, Rosa JC, Lira FS, Zanchi NE, Ropelle ER, Oyama LM et al. b-Hydroxy-b-methylbutyrate (HMb) supplementation stimulates skeletal muscle hypertrophy in rats via the mTOR pathway. Nutr Metabol, 2011; 8:11.. It is first converted to ß-hydroxy-ß-methylglutaryl coenzyme A (HMG-CoA) and can follow two distinct metabolic pathways: the first occurs through the action of the enzyme HMG-CoA reductase, which is a limiting factor for the synthesis of cholesterol when there is a large demand for the formation of cell membranes (such as occurs in periods of cell growth and muscle repair), which converts HMG-CoA to cholesterol. The second occurs by the action of the enzyme HMG-CoA synthetase which converts HMG-CoA to acetyl-CoA, which is a substrate for power generation⁸8. Pimentel GD, Rosa JC, Lira FS, Zanchi NE, Ropelle ER, Oyama LM et al. b-Hydroxy-b-methylbutyrate (HMb) supplementation stimulates skeletal muscle hypertrophy in rats via the mTOR pathway. Nutr Metabol, 2011; 8:11.. Adaptations to exercise training and improvement in physical performance are highly specific to the type of exercise. Concurrent training refers to a program that combines strength with aerobic endurance training in the same session, as well as the possible antagonistic adaptations resulting from these two abilities⁹9. McCarthy JP, Pozniak MA, Agre JC. Neuromuscular adaptations to concurrent strength and endurance training. Med Sci Sports Exerc, 2002; 34:511-519.^{), (}¹⁰10. Gomes RV, Aoki MS. Suplementação de Creatina Anula o Efeito Adverso do Exercicio de Endurance sobre o subsequente desempenho de Força. Rev Bras Med Esporte, 2005; 11:131-134.. The reason for choosing concurrent training is due to the possibility of achievements of the benefits of strength training and endurance simultaneously in a single training session¹¹11. Leveritt M, Abernethy PJ, Barry BK, Logan PA. Concurrent Strength and Endurance Training: the influence of dependent variable selection. J Strength Cond Res. 2003; 17:503-508.. Thus, HMB supplementation might be an important factor to minimize the opposing effects of different metabolism recruited by concurrent training.

A previous study reported that aerobic exercise training performed primarily as part of a concurrent training program may inhibit the strength as consequence of the anaerobic training when compared with strength training performed alone¹²12. Collins MA, Snow TK. Are adaptations to combined endurance and strength training affected by sequence of training? J Sports Sci. 1993; 11:485-491.. It is well-known that aerobic training increases maximal oxygen consumption, thereby improving cardiorespiratory fitness and increasing mitochondrial density in muscle, among other benefits¹³13. Hakkinen K, Alen M, Kraemer WJ, Gorostiaga E, Izquierdo M, Rusko H et al. Neuromuscular adaptations during concurrent strength and endurance training versus strength training. Eur J Appl Physiol. 2003; 89:42-52.. On the other hand, strength training promotes an increase in lean body mass and increases the cross-sectional area of skeletal muscle fibers¹²12. Collins MA, Snow TK. Are adaptations to combined endurance and strength training affected by sequence of training? J Sports Sci. 1993; 11:485-491.^{), (}¹³13. Hakkinen K, Alen M, Kraemer WJ, Gorostiaga E, Izquierdo M, Rusko H et al. Neuromuscular adaptations during concurrent strength and endurance training versus strength training. Eur J Appl Physiol. 2003; 89:42-52.^{), (}¹⁴14. Dudley GA, Fleck SJ. Strength and Endurance Training: are they mutually exclusive? Sports Med. 1987; 4:79-85.. Both, resistance and endurance exercise, stimulate the rate of mixed muscle protein synthesis, an aggregate measure of all muscle proteins. Moreover, resistance training increases myofibrillar proteins (actin and myosin), whereas endurance training increases mitochondrial proteins¹⁵15. Carraro F, Stuart CA, Hartl WH, Rosenblatt J, Wolfe RR. Effect of exercise and recovery on muscle protein synthesis in human subjects. Am J Physiol. 1990; 259:E470- E476.^{), (}¹⁶16. Chesley A, MacDougall JD, Tarnopolsky MA, Atkinson SA, Smith K. Changes in human muscle protein synthesis after resistance exercise. J Appl Physiol. 1992; 73:1383-1388..

Therefore, we hypothesized that HMB supplementation may modify the metabolism of muscle fibers, preventing loss of lean body mass, increasing muscular fibers diameter and contributing to the adjustment of oxidative/glycolytic metabolism of the muscle fibers promoted by concurrent training. Considering the importance of supplementation and its impact on the sports field, the aim of this study was to investigate the effects of HMB supplementation on the anthropometric, morphological and physiological parameters of Wistar rats undergoing concurrent training.

Methods

Animals and experimental procedure

Twenty-two male Wistar adult rats from the Central Animal Laboratory, UNESP, Botucatu - SP, who were approximately 60 days of age, were used. The animals were maintained in polyethylene, solid bottomed cages (40x30x15cm) covered with a coarse sawdust substrate under controlled light and temperature conditions (12 hours of light and 12 hours of darkness) and 20 to 25ºC, respectively, and provided with filtered water and Labina of Purina - Food LTDA Alisul Ind. ad libitum. After the period of environmental adaptation, the animals were randomly divided into four groups: Control (C) - the animals remained in their cages, with water, were fed ad libitum and received no physical stimulation (n=6); Supplementation with HMB (S) - the animals remained in their cages, with water, were fed ad libitum, received no physical stimulus, but they were supplemented daily with HMB (n=6); training (T) - the animals were submitted to the protocol of concurrent training (n=5); training + HMB supplementation (TS) - the animals underwent the concurrent training protocol and were supplemented daily with HMB (n=5). The experimental design followed the rules and ethics of experimentation on animals adopted by the Ethics Committee for animal research of FCT/UNESP - Presidente Prudente, Protocol 03/2011.

HMB supplementation

The oral protein supplementation HMB (Trade Mark Arnold Nutrition Inc., Hollywood, FL) was initiated simulataneously with the concurrent training period (81 days of age). HMB supplementation was given by gavage (30 minutes before the concurrent training protocol) in a single dose comprising 76mg/kg/day, a dosage equivalent to that used in studies involving HMB supplementation in humans, which corresponds to about 3 to 6 g / day of HMB for a subject of 80 kilograms⁷7. Gallagher PM, Carrithers JA, Godard MP, Schulze KE, Trappe SW. Beta-hydroxy-beta-methylbutyrate ingestion, Part I: effects on strength and fat free mass. Med Sci Sports Exerc, 2000; 32:2109-2115.. Both supplemented groups (S and TS) received the dose at the same time.

Concurrent training program

At 60 days of age, the animals of all groups began their adaptation to the water environment with the purpose of reducing stress from the exercise. For the groups assigned to concurrent training (T and TS) the adaptation period took place over three weeks (21 days) with swimming sessions with increasing intensities in individual PVC cylindrical tanks (120x60cm) with a controlled temperature (31 ± 1ºC), 30 minutes per session, frequency of three times a week. After the last adaptation section, the animals had interval the 48h for physical tests.

At 81 days of age, the animals in the training groups began receiving sessions of concurrent training, starting with aerobic training, followed by anaerobic training with no break between them. The aerobic endurance training consisted of a swimming session for thirty-eight minutes conducted in PVC cylindrical tanks. A vest was placed on the anterior chest region of the animal with a constant overload, equivalent to 50% of the body weight of each animal, as previously established in the lactate minimum test, corresponding to 70% of the anaerobic threshold¹⁷17. Teixeira GR, Fávaro WJ, Pinheiro PFF, Chuffa LGA, Amorim JPA, Mendes LO et al. Physical exercise on the rat ventral prostate: Steroid hormone receptors, apoptosis and cell proliferation. Scand J Med Sci Sports. 2012; 22:86-92.. In the strength training, the animals were subjected to sessions of jumps performed in a cylindrical PVC container (90x60cm) containing water at 30º ± 1ºC with a depth of 40 cm¹⁸18. Harri M, Kuusela P. Is swimming exercise or cold exposure for rats? Acta Physiol Scand. 1986; 126:189-197.. The physical training program occurred for eight consecutive weeks. The jump sessions in the liquid medium were composed of four sets of ten jumps with an interval equivalent to 1 minute between sets.

Determination of Aerobic and Anaerobic Performances

The aerobic and anaerobic performances were admitted as intensity timeout (Tlim). For the determination of these variables the protocol validated by Tegtbu¹⁹19. Tegtbur U, Busse MW, Braumann KM. Estimation of an individual equilibrium between lactate production and catabolism during exercise. Med Sci Sports Exerc. 1993; 25:620-627., for humans, applied to rats by Voltarelli²⁰20. Voltarelli FA, Gobatto CA, Mello MAR. (2002). Determination of anaerobic threshold in rats using the lactate minimum test. Braz J Med Biol Res. 2002; 35: 1389-1394. and adapted for these animals by Araujo²¹21. Araujo GG, Papoti M, Manchado FB, Mello MA, Gobatto CA. Protocols for hyperlactatemia induction in the lactate minimum test adapted to swimming rats. Comp Biochem Physiol, 2007; 148:88-92. was used. This procedure for assessment of anaerobic performance served as a method to induce hyperlactemia with a load corresponding to 13% of body weight (BW). The animals performed two efforts in the first phase of the test, the first lasting 30s, and after an interval of 30s, a second effort with the same load until exhaustion (Tlim). Blood samples (25μL) were collected from a cut at the tip of the tail with the aid of graded capillary tubes during the exercise tests and placed in minutes 1, 3, 5, 7 and 9 after Tlim for determining the peak of lactate concentration (mmol/L).

Immediately after nine minutes of passive range, the rats were subjected to incremental exercise test to determine the intensity of lactate minimum (aerobic performance) corresponding to the balance between production and removal of lactate. The loads were equivalent to 4.0, 4.5, 5.0, 5.5, 6.0 and 7.0% of BW of each animal. Each stage of the progressive protocol consisted of five minutes with 30s interval for determination of blood lactate. After analysis in a lactimeter (YSI Spring Model Sport - 1500) by electrochemical method, the relation obtained between lactate concentration and load (percentage of body weight) was adjusted by a polynomial equation of order 2, and LM was considered the derivative zero of this adjustment. Thus, the overload used for physical training was identified (percent body weight) to each animal.

Anthropometric, histological and histochemical analyses

During the experiment, the animals were subjected to measurement of body weight. Body weight was measured using an electronic scale (Shimadzu BL3200H, with a precision of 0.01 g). To evaluate the weight gain, the calculation of body mass gain was adopted, using the formula²²22. Novelli ELB, Diniz YS, Galhardi CM, Ebaid GMX, Rodrigues HG, Mani F. et al. Anthropometrical parameters and markers of obesity in rats. Lab Animal. 2007; 41:111-119.:

Δ = Final weight - Initial weight.

Body mass index was calculated as body weight (g)/length², in cm².

At 140 days of age the animals were euthanized with an overdose of sodium pentobarbital (100mg/kg) applied intraperitoneally, 48 h after the last training session. After laparotomy, the abdominal-pelvic liver, renal fat and epididymal fat were removed for weighing. Samples of the ventral portion of the soleus muscle were collected and weighed. A portion of the soleus was fixed by immersion in buffered formaldehyde solution (PBS + 10% formaldehyde) and then soaked in paraplastic (Paraplast Plus, McCormick, St. Louis, MO, USA). Cuts, 4 mm in thickness, were made and used for general morphology analysis with H/E.

Histological analysis focused on the cell morphology of the soleus muscle tissue: shape, size, color sarcoplasm and nuclei using a light microscope (AxioCam - 2 with digital camera, ERC 5S model AxioCam, Carl Zeiss, Department of Physical Education / FCT UNESP).

For the histochemical analysis another portion of the muscle was frozen in liquid nitrogen at -70ºC. After freezing the soleus muscles were cut on a cryostat microtome with a thickness of 5μm. The sections were incubated in the histochemical reaction Nicotinamide adenine dinucleotide tetrazolium reductase (NADH-TR) a technique modified by Dubowitz²³23. Dubowitz V, Sewry CA, Oldfors A. Muscle biopsy: a practical approach. London: Elsevier Health Sciences, 2013; pp 492. to indicate the presence of oxidative activity, and detect the types of muscle fibers in cross section: slow oxidative type I, fast oxidative glycolytic type IIb and fast glycolytic type IIa. Slides were analyzed and 10 cross sections/animal was photographed under a light microscope (Axiocam - 2, Carl Zeiss, Department of Physical Education FCT/UNESP), and the amount of fiber were determined.

For stereology tissue volume (fiber core and connective tissue) the reticle 160 points of Weibel²⁴24. Weibel ER, Kistler GS, Scherle WF. Pratical stereologigal methods for morfhometric cytology. J Cell Biol. 1996; 30:23-38. was used on the muscle cross-section stained with H/E, 5 animals per group two blades per animal and 10 pictures per slide with a 40x objective using a light microscope AxioCam - 2 model AxioCam HR, Zeiss Department of Physical Education FCT / UNESP.

Statistical Analysis

Statistical analysis was performed using a 2-way analysis of variance (ANOVA) with factors of supplementation and exercise group and its interaction, complemented with the Tukey multiple comparison test to contrast comparisons between parametric data in Tlim, weight and relative weight (g/100g) for total fat, soleus and liver. To compare body weight throughout the intervention and group, a 3-way factor ANOVA (supplement group x exercise group x time) with repeated measures on the last factor were performed. Results were expressed as mean ± standard deviation. Variables not normally distributed were treated for non-parametric statistics (i.e.: median absolute deviation based on the median, confidence interval for the median and coefficient of variation based on the median), using the Kruskal Wallis analysis related to the percentage used in the stereology muscle. The statistical conclusions were made at 5% significance. Details about the methodology can be found in Banzatto and Kronka²⁵25. Banzatto DA, Kronka SN. Experimentação agrícola. Jaboticabal: FUNEP, 1989; p.247.. The statistical software used was IBM SPSS Statistics version 22, GraphPad Instat version 4 and Sigma Plot version 11.0 used for the graphics.

Results

The swimming time to fatigue (Tlim) was used in this study as the anaerobic performance parameter and these values did not change significantly over the phases among groups, with a tendency for the post-training Tlim values to be lower than the pre-training Tlim (Table 1).

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Table 1
Mean values of Tlim pre and post training and variation (∆%) per group of rats.

Body weight did not show significant differences between the groups throughout the intervention (0=0.678); however, significant differences (p<0.001) were verified from week 1 to 9 (Figure 1a). As expected, the rats that practiced concurrent training showed significant lower body weight as compared with control group, approximately 16% in percentage weight gain (Figure 1b). The S group, HMB supplementation only, presented increased body weight as compared with other groups (Figure 1b). The interaction between HMB supplementation and concurrent training promoted an increase in weight gain when compared with exercise animals without supplementation, approximately 21%, (Figure 1b). When analyzing BMI, it was verified significant difference only for the control group, compared with group that received supplementation (p<0.05). Regarding to body mass index, significant difference was found only between the supplemented and control groups (Figure 1c).

Figure 1
(A) Time-course of total body mass (g) during the 8 weeks of training and supplementation: (●) Control, (○) Supplemented, (▼) Trained and (▲) Trained Supplemented.* Significant difference with respect to T. (B) Effect of supplementation and concurrent training on weight gain (g) after 8 weeks of treatment. ^b p<0.05 versus supplemented. (C) Effects of supplementation with HMB and concurrent training on body mass index (g/cm2) of animals. ^b p<0.05 versus supplemented.

The weight and relative weight (g/100g) of whole-body fat mass of animals submitted to physical training (with or without supplementation) exhibited significant lower values when compared with animals that received only supplementation (p=0.016). In addition, relative weight of the soleus was significantly higher for the animals submitted to physical training and to supplementation only (p=0.026). HMB supplementation and concurrent training did not change (p>0.05) soleus and the liver weights, and relative weight of the liver (Table 2).

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Table 2
Total weight (g) and relative weights (g/100g) of total fat, soleus muscle and liver of the Wistar trained rats supplemented with HMB.

The values of the soleus muscle stereology expressed in cm², showed that concurrent exercise training with supplementation promoted a significant increase in the fibers of the soleus muscle as compared with the C group (Table 3). The volume of tissue was significantly lower in S and T groups, comparing with control group. There was a significant increase of nuclei in the S, T and TS groups as compared with control group (Table 3).

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Table 3
Median stereology of the soleus muscle in cm².

Morphological analysis of the control animals showed normal-looking fibers arranged in parallel and peripheral nuclei (Figure 2). The supplementation resulted in a more rounded aspect than the polygonal characteristic of muscle fibers, i.e., an increase in the diameter of muscle fibers in a cross section of the soleus muscle fibers in group S, compared with group C (Figure 2). Furthermore, the S group had a higher quantity of peripheral nuclei distributed per fiber than the C group (Figure 2). The occurrence of micro lesions, characterized by the incidence of leukocyte infiltration into the fibers, or immune cells infiltrating the muscle fiber hypertrophy characteristic of inflammation was observed in groups T, TS and S. The connective tissue (endomysium and perimysium) was lower in trained animals than in control group, suggesting a possible increase in protein synthesis of muscle fibers (Figure 2).

Figure 2
Morphological distribution in cross section (a,c,e,g) and longitudinal (b,d,f,h) soleus muscle. Images (A) and (B) refer to the C group having regular architecture. Images (C) and (D) are the group S, arrow indicating peripheral nuclei and reduction of adjacent connective tissue. * Indicates micro lesions in the longitudinal fibers. Images (E) and (F) the group T, arrow indicating the increase of nuclei wrapped fibers and reduction of tissue. Images (G) and (H) for the TS group. "E" = Endomysium. "P" = Perimysium. ► = Nuclei. ¢ = Blood vessel. Bar= 20μm.

Examining the enzymatic reaction (NADH-TR) we found an increase in cross sections of the fibers IIa and IIb when compared with the number of fibers I in animals from the S, T and TS groups, compared with group C (Figure 3). The enzymatic reaction of muscle fibers in the S and TS groups showed an increase in the quantity of IIa and IIb fibers (totalizing 72% and 75%, respectively) in relation to I fibers (28% and 25%, respectively) compared with other groups (30% for fibers I - control and trained) (Figure 3). The characteristics presented by the muscle fibers showed that training, supplementation and the association of both modified the morphological and metabolic state of the muscle fibers.

Figure 3:
Morphological distribution of a cross section of soleus muscles incubated in the enzymatic reaction NADH-TR. Image (A) is related to group C; Image (B) to the S group; Image (C) the T group and image (D) the TS group. The symbols "*" in the images represent the type I fibers. ► = Peripheral mitochondria.

Discussion

In the present study, we investigated the effects of HMB supplementation on anthropometric, morphological and histochemical parameters in male Wistar rats submitted to eight weeks of concurrent training. The major findings of this study were that HMB promoted changes in body composition and muscle cellular dimensions.

Adaptations to exercise training and improvement in performance are highly specific to the type of exercise. Concurrent training is a combination of strength training and aerobic exercise capacity in the same training session¹⁰10. Gomes RV, Aoki MS. Suplementação de Creatina Anula o Efeito Adverso do Exercicio de Endurance sobre o subsequente desempenho de Força. Rev Bras Med Esporte, 2005; 11:131-134.. However, the best sequence in which to apply the concurrent training is still widely discussed. Several strategies are available for quantifying aerobic performance, where the distance, time or power are preset and throughout the test of time limit (Tlim) the individual must endure constant power until fatigue²⁶26. Bosquet L, Leger L, Legro SP. Methods to determine aerobic endurance. Sports Med. 2002; 32:675-700.. The Tlim obtained in the present study during the induction phase of hyperlactacidemia (13% CP) compared with baseline showed no significant differences despite the concurrent training protocol was sufficient to increase the glycolytic capacity, due to greater number of type I fibers. Thus, further studies are necessary to examine this issue. In rats, determining the aerobic capacity is still controversial. Indeed, a previous study failed to found changes in aerobic capacity after endurance training at intensities of 80, 90 and 100% of anaerobic threshold for 12 weeks²⁷27. Araujo GG, Papoti M, Manchado-Gobatto FB, Mello MA, Gobatto CA. Padronização de um Protocolo Experimental de Treinamento Periodizado em Natação Utilizando Ratos Wistar. Rev Bras Med Esporte. 2010; 16:51-6.. On the other hand, another study found positive changes in the aerobic capacity of rats determined by the lactate minimum test either after four or eight weeks of endurance swimming training²⁸28. Voltarelli FA, Mello MAR, Gobatto CA. Limiar anaeróbio determinado pelo teste do lactato mínimo em ratos: efeito dos estoques de glicogênio muscular e do treinamento físico. Rev Port Ciências Desporto. 2004; 4;16-25.. In the present study, the decrease in aerobic capacity over time seems to be a natural process of the species; however, the concurrent training associated with HMB supplementation did not improve the lactate minimum. In agreement, it was observed a reduction of anaerobic capacity after monotonous training for 12 weeks, because high training volume reduces anaerobic adaptations²⁹29. Araújo GG, Papoti M, Manchado-Gobatto FB, Mello MA, Gobatto CA. (2013). Monitoring chronic physical stress using biomarkers, performance protocols and mathematical functions to identify physiological adaptations in rats. Lab Animals. 2013; 47:36-42..

HMB is converted into ß-hydroxy-ß-methylglutaryl coenzyme A (HMG-CoA), a limiting factor for cholesterol synthesis activated by the formation of cell membranes in cell growth and muscle repair³⁰30. Nissen SL, Abumrad NN. Nutritional role of the leucine metabolite b-hydroxy-h-methylbutyrate (HMB). J Nutr Biochem. 1997; 8:300-311.. The highest expression of body fat in the supplemented group corresponds to the increased cholesterol promoted by HMB synthesis with muscle and fatty tissue as the two main receptors³¹31. Durstine JL, Grandjean PW, Cox CA. Thompshom PD. Lipids, lipoproteins and exercise. J Cardiopulm Rehab Prev. 2002; 22:385-398.. According to a previous study, cholesterol from the HMG-CoA, a co-factor of the pathways of HMB may have actions in the muscle tissue, immune and tissue cells in the mammary gland, promoting responses to differentiation and synthesis of muscle membrane and organelles, increasing cell growth and increasing function³²32. Wilson JM, Grant SC, Lee SR, Masad IS, Park YM, Henning PC et al. Beta-hydroxy-beta-methyl-butyrate blunts negative age-related changes in body composition, functionality and myofiber dimensions in rats. J Int Society Sports Nutr. 2012; 9:18.. Differently, our findings did not observe changes in body weight. However, HMB was able to alter body composition both acting alone or in association with physical training. Thus, we can conclude that there were significant physiological adjustments in the regulatory pathways of the metabolism, favoring smaller storage of triglycerides in visceral tissues when combined with concurrent training.

Previous research has shown that progressive resistance training for 8-21 weeks caused fast-to-slow fiber-type transitions within the fast fiber subtypes and considerable fiber hypertrophy³³33. Staron RS, Karapondo DL, Kraemer WJ, Fry AC, Gordon SE, Falkel JE et al. Skeletal muscle adaptations during early phase of heavy-resistance training in men and women. J Appl Physiol. 1994; 76:1247-1255.^{), (}³⁴34. Kadi F, Thornell LE. Training affects myosin heavy chain phenotype in the trapezius muscle of women. Histochem Cell Biol. 1999; 112:73-78.. In contrast, endurance training for a similar period typically induces fiber atrophy and, depending on the intensity and volume of repeated contractions, may also enhance the proportion of type I fibers³⁵35. Fitzsimons DP, Diffee GM, Herrick RE, Baldwin KM. Effects of endurance exercise on isomyosin patterns in fast- and slow-twitch skeletal muscles. J Appl Physiol. 1990; 68:1950-1955.. Morphological data from the present study demonstrate that concurrent training increased the diameter of the muscle fibers and reduced the adjacent connective tissue. The increase in cross section is an indicator of protein synthesis and/or muscle hypertrophy. During the concurrent training, the animals performed activities at high intensities, resulting in high energy applications as well as the recruitment of muscle groups; thus, several biochemical adaptations at different levels (such as in the liver and muscle tissues) facilitate the mobilization and oxidation triacylglycerol and lead to a conservative effect on lean body mass³⁶36. Hawley JA. Molecular responses to strength and endurance training: Are they incompatible? Appl Physiol Nutr Metab. 2009; 34:355-361.. The greater number of myonuclei as consequence of satellite cell proliferation would result in an elevated potential for transcription, leading to muscle hypertrophy and an increased nuclear protein, showing higher proliferation of markers and inhibition of differentiation-2 and cyclin A³⁷37. Always SE, Pereira SL, Edens NK, Hao Y, Bennett BT. β-Hydroxy-β-methylbutyrate (HMB) enhances the proliferation of satellite cells in fast muscles of aged rats during recovery from disuse atrophy. Exp Gerontolol. 2013; 48:973-84.. Possibly, HMB may have been more effective at suppressing apoptotic pathways associated with muscle loss by attenuating proapoptotic proteins as observed previuosly³⁸38. Hao Y, Jackson JR, Wang Y, Edens N, Pereira SL, Always SE. β-Hydroxy-β-methylbutyrate reduces myonuclear apoptosis during recovery from hind limb suspension-induced muscle fiber atrophy in aged rats. Am J Physiol Regul Integr Comp Physiol. 2001; 301:R701-715.. We also observed that HMB supplementation alone was able to increase muscle fiber, muscle fiber damage and nuclear areas, decrease area of connective tissue, and causes hypertrophy due to micro adjustments indicative of protein. Recently, it was reported that phosphatidic acid (PA), which is a glycoprotein and Ras homolog enriched in brain (Rheb) appears to play a fundamental role in the mechanical regulation of muscle mass enabled through late endosome/lysosome (LEL) in the regulation of mTOR by various growth regulatory inputs such as amino acids, growth factors and mechanical stimuli³⁹39. Jacobs BL, Goodman CA, Hornberger TA. The mechanical activation of mTOR signaling: an emerging role late endosome/lysosomal targeting. J Muscle Res Cell Motil. 2014; 35:11-21.. Resistance-like exercise specifically increased the phosphorylation of the anabolic Akt/mTOR signaling pathway, along with the activation of the translation initiation regulators p70 S6k, 4E-BP1, and eIF2B, but had little effect on the AMPK/PGC-1 pathway. In contrast, endurance-like exercise increased AMPK phosphorylation and PGC-1 protein levels³⁹39. Jacobs BL, Goodman CA, Hornberger TA. The mechanical activation of mTOR signaling: an emerging role late endosome/lysosomal targeting. J Muscle Res Cell Motil. 2014; 35:11-21.. Accordingly, it was proposed that selective activation of either the Akt-mTOR or AMPK-PGC-1 signaling pathways can explain specific adaptive responses to resistance or endurance-like exercise responses⁴⁰40. Atherton PJ, Babraj J, Smith K, Singh J, Rennie MJ, Wackerhage H. Selective activation of AMPK-PGC-1alpha or PKB-TSC2-mTOR signaling can explain specific adap-tive responses to endurance or resistance training-like electrical muscle stimulation. FASEB J. 2005; 19:786-98.. From a regulatory perspective, the notion of an AMPK-Akt master switch is attractive. More recently, however, the hypothesis that HMB might directly stimulate muscle protein anabolism has been proposed. In this respect, a crucial step in the anabolic response is phosphorylation and activation of the mTOR which in turn activates p70S6 kinase (p70S6K) and inhibits 4E-BP1⁴¹41. Gingras AC, Raught B, Sonenberg N. eIF4 initiation factors: effectors of mRNA recruitment to ribosomes and regulators of translation. Ann Rev Biochem. 1999; 68: 913-63.. Phosphorylation of 4E-BP1 induced by growth factors such as insulin and IGF-I has been shown to depend on the Akt/PI3K/mTOR pathway, whereas an Akt-unrelated, mTOR-dependent activation has been proposed to result from increased intracellular amino acid availability⁴¹41. Gingras AC, Raught B, Sonenberg N. eIF4 initiation factors: effectors of mRNA recruitment to ribosomes and regulators of translation. Ann Rev Biochem. 1999; 68: 913-63.^{), (}⁴²42. Shen W, Boyle DW, Wisniowski P, Bade A, Liechty A. Insulin and IGF-I stimulate the formation of the eukariotik initiation factor 4F complex and protein synthesis in C2C12 myotubes independent of availability of external amino acids. J Endocrinol. 2005; 185:275-289.^{), (}⁴³43. Gerlinger-Romero F, Guimarães-Ferreira L, Giannocco G, Nunes MT. Chronic supplementation of beta-hydroxy-beta methylbutyrate (HMβ) increases the activity of the GH/IGF-I axisand induces hyperinsulinemia in rats. Growth Horm IGF Res. 2011; 21:57-62.. Therefore, it seems that the mTOR responds to various stimuli, including mechanical stimuli (physical training) and nutrition (supplementation), promoting cell growth⁴⁴44. Zanchi NE, Nicastro H, Gualano B, Costa AS, Lancha-Junior AH. Suplementação de HMB: relevância clínica e mecanismos de ação. Rev Mackenzie Educação Física Esporte. 2009; 8:123-133.. HMB reduces proteolysis in muscle fiber after strength and endurance exercises, and increases lean body mass and strength levels⁴⁵45. Nissen S, Sharp RL, Panton L, Vukovich M, Trappe S, Fuller JC. β-Hydroxy-β-Methylbutyrate (HMB) Supplementation in Humans Is Safe and May Decrease Cardiovascular Risk Factors. J Nutr, 2000; 130:1937-1945.^{), (}⁴⁶46. Panton LB, Rathmacher JA, Baier S, Nissen SL. Nutritional Supplementation of the Leucine Metabolite b-Hydroxy-b-Methylbutyrate (HMB) During Resistance Training. Nutrition. 2000; 16:734- 739.^{), (}⁴⁷47. Park BS, Henning PC, Grant SC, Lee WJ, Lee SR, Arjmandi BH et al. HMB attenuates muscle loss during sustained energy deficit induced by calorie restriction and endurance exercise. Metabolism. 2013; 62:1718-1729..

In the present study, NADH-TR oxidative staining was used for the differentiation of three muscle fiber types. The results suggest that HMB supplementation and concurrent training, individually or in association, promoted muscular adaptations, converting fibers into slow twitch or fast type I fibers in fiber type IIb and type IIa promoting the remodeling of muscle fibers.

Skeletal muscle in obese individuals exhibits reduced oxidative capacity, increased glycolytic capacity, and a decreased percentage of type I ﬁbers⁴⁸48. Tanner CJ, Barakat HA, Dohm GL, Pories WJ, MacDonald KG, Cunningham PRG, et al. Muscle fiber type is associated with obesity and weight loss. Am J Physiol Endocrinol Metab., 2002; 282:E1191- E1196.^{), (}⁴⁹49. Hickey MS, Carey JO, Azevedo JL, Houmard JA, Pories WJ, Israel RG et al. Skeletal muscle fiber composition is related to adiposity and in vitro glucose transport rate in humans. Am J Physiol Endocrinol Metab. 1995; 268:E453-457.. A prevalence of type II ﬁbers may thus result in the partitioning of lipid towards storage in skeletal muscle (i.e., intramuscular triglyceride) or adipose tissue rather than oxidation within skeletal muscle, resulting in a positive fat balance. Indeed, it was reported that rodents that gained the most mass with high-fat feedings possessed signiﬁcantly fewer type I ﬁbers than their littermates that gained little or no weight⁵⁰50. Mrad JA, Yakubu F, Lin D, Peters JC, Atkinson JB, Hill JO. Skeletal muscle composition in dietary obesitysusceptible and dietary obesity-resistant rats. Am J Physiol Regul Integr Comp Physiol. 1992; 262:684-688..

In conclusion, concurrent training in association with HMB supplementation showed positive effects on body composition as well as on skeletal muscle fibers in rats. HMB prevented the loss of fat mass and increased the diameter of the muscle fibers in cross-section, contributing to a change in oxidative metabolism / glycolytic fibers.

Acknowledgments

The authors would like to thank The Laboratory of Histology and Histochemistry for the collaboration on histochemical techniques, and PIBIC - Proc. No. 106235/2012-5, for financial support.

References

¹
Maughan RJ, Burke LM. Practical nutritional recommendations for the athlete. Nestle Nutrition Institute Workshop Series, 2011; 69:131-149.
²
Clark RH, Feleke G, Din M, Yasmin T, Singh G, Khan FA et al. Nutritional Treatment for Acquired Immunodeficiency Virus-Associated Wasting Using β-Hydroxy-β-Methylbutyrate, Glutamine, and Arginine: A Randomized, Double-Blind, Placebo-Controlled Study. J Parenter Enteral Nutr. 2000; 24:133-139.
³
Wilson J, Wilson GJ. Contemporary issues in protein requirements and consumption for resistance trained athletes. J Int Soc Sports Nutr. 2006; 3:7-27.
⁴
Ransone J, Neighbors K, Lefavi R, Chromiak J. The effect of beta-hydroxy beta-methylbutyrate on muscular strength and body composition in collegiate football players. J Strength Cond Res, 2003;17:34-39.
⁵
Eley HL, Russell ST, Baxter JH, Mukerji P, Tisdale MJ. Signaling pathways initiated by beta-hydroxy-beta-methylbutyrate to attenuate the depression of protein synthesis in skeletal muscle in response to cachectic stimuli. Am J Physiol. 2007; 293:E923- E931.
⁶
Kornasio R, Riederer I, Butler-Browne G, Mouly V, Uni Z, Halevy O. Beta-hydroxy-beta-methylbutyrate (HMB) stimulates myogenic cell proliferation, differentiation and survival via the MAPK/ERK and PI3K/Akt pathways. Biochim Biophys Acta, 2009; 1793:755-763.
⁷
Gallagher PM, Carrithers JA, Godard MP, Schulze KE, Trappe SW. Beta-hydroxy-beta-methylbutyrate ingestion, Part I: effects on strength and fat free mass. Med Sci Sports Exerc, 2000; 32:2109-2115.
⁸
Pimentel GD, Rosa JC, Lira FS, Zanchi NE, Ropelle ER, Oyama LM et al. b-Hydroxy-b-methylbutyrate (HMb) supplementation stimulates skeletal muscle hypertrophy in rats via the mTOR pathway. Nutr Metabol, 2011; 8:11.
⁹
McCarthy JP, Pozniak MA, Agre JC. Neuromuscular adaptations to concurrent strength and endurance training. Med Sci Sports Exerc, 2002; 34:511-519.
¹⁰
Gomes RV, Aoki MS. Suplementação de Creatina Anula o Efeito Adverso do Exercicio de Endurance sobre o subsequente desempenho de Força. Rev Bras Med Esporte, 2005; 11:131-134.
¹¹
Leveritt M, Abernethy PJ, Barry BK, Logan PA. Concurrent Strength and Endurance Training: the influence of dependent variable selection. J Strength Cond Res. 2003; 17:503-508.
¹²
Collins MA, Snow TK. Are adaptations to combined endurance and strength training affected by sequence of training? J Sports Sci. 1993; 11:485-491.
¹³
Hakkinen K, Alen M, Kraemer WJ, Gorostiaga E, Izquierdo M, Rusko H et al. Neuromuscular adaptations during concurrent strength and endurance training versus strength training. Eur J Appl Physiol. 2003; 89:42-52.
¹⁴
Dudley GA, Fleck SJ. Strength and Endurance Training: are they mutually exclusive? Sports Med. 1987; 4:79-85.
¹⁵
Carraro F, Stuart CA, Hartl WH, Rosenblatt J, Wolfe RR. Effect of exercise and recovery on muscle protein synthesis in human subjects. Am J Physiol. 1990; 259:E470- E476.
¹⁶
Chesley A, MacDougall JD, Tarnopolsky MA, Atkinson SA, Smith K. Changes in human muscle protein synthesis after resistance exercise. J Appl Physiol. 1992; 73:1383-1388.
¹⁷
Teixeira GR, Fávaro WJ, Pinheiro PFF, Chuffa LGA, Amorim JPA, Mendes LO et al. Physical exercise on the rat ventral prostate: Steroid hormone receptors, apoptosis and cell proliferation. Scand J Med Sci Sports. 2012; 22:86-92.
¹⁸
Harri M, Kuusela P. Is swimming exercise or cold exposure for rats? Acta Physiol Scand. 1986; 126:189-197.
¹⁹
Tegtbur U, Busse MW, Braumann KM. Estimation of an individual equilibrium between lactate production and catabolism during exercise. Med Sci Sports Exerc. 1993; 25:620-627.
²⁰
Voltarelli FA, Gobatto CA, Mello MAR. (2002). Determination of anaerobic threshold in rats using the lactate minimum test. Braz J Med Biol Res. 2002; 35: 1389-1394.
²¹
Araujo GG, Papoti M, Manchado FB, Mello MA, Gobatto CA. Protocols for hyperlactatemia induction in the lactate minimum test adapted to swimming rats. Comp Biochem Physiol, 2007; 148:88-92.
²²
Novelli ELB, Diniz YS, Galhardi CM, Ebaid GMX, Rodrigues HG, Mani F. et al. Anthropometrical parameters and markers of obesity in rats. Lab Animal. 2007; 41:111-119.
²³
Dubowitz V, Sewry CA, Oldfors A. Muscle biopsy: a practical approach. London: Elsevier Health Sciences, 2013; pp 492.
²⁴
Weibel ER, Kistler GS, Scherle WF. Pratical stereologigal methods for morfhometric cytology. J Cell Biol. 1996; 30:23-38.
²⁵
Banzatto DA, Kronka SN. Experimentação agrícola. Jaboticabal: FUNEP, 1989; p.247.
²⁶
Bosquet L, Leger L, Legro SP. Methods to determine aerobic endurance. Sports Med. 2002; 32:675-700.
²⁷
Araujo GG, Papoti M, Manchado-Gobatto FB, Mello MA, Gobatto CA. Padronização de um Protocolo Experimental de Treinamento Periodizado em Natação Utilizando Ratos Wistar. Rev Bras Med Esporte. 2010; 16:51-6.
²⁸
Voltarelli FA, Mello MAR, Gobatto CA. Limiar anaeróbio determinado pelo teste do lactato mínimo em ratos: efeito dos estoques de glicogênio muscular e do treinamento físico. Rev Port Ciências Desporto. 2004; 4;16-25.
²⁹
Araújo GG, Papoti M, Manchado-Gobatto FB, Mello MA, Gobatto CA. (2013). Monitoring chronic physical stress using biomarkers, performance protocols and mathematical functions to identify physiological adaptations in rats. Lab Animals. 2013; 47:36-42.
³⁰
Nissen SL, Abumrad NN. Nutritional role of the leucine metabolite b-hydroxy-h-methylbutyrate (HMB). J Nutr Biochem. 1997; 8:300-311.
³¹
Durstine JL, Grandjean PW, Cox CA. Thompshom PD. Lipids, lipoproteins and exercise. J Cardiopulm Rehab Prev. 2002; 22:385-398.
³²
Wilson JM, Grant SC, Lee SR, Masad IS, Park YM, Henning PC et al. Beta-hydroxy-beta-methyl-butyrate blunts negative age-related changes in body composition, functionality and myofiber dimensions in rats. J Int Society Sports Nutr. 2012; 9:18.
³³
Staron RS, Karapondo DL, Kraemer WJ, Fry AC, Gordon SE, Falkel JE et al. Skeletal muscle adaptations during early phase of heavy-resistance training in men and women. J Appl Physiol. 1994; 76:1247-1255.
³⁴
Kadi F, Thornell LE. Training affects myosin heavy chain phenotype in the trapezius muscle of women. Histochem Cell Biol. 1999; 112:73-78.
³⁵
Fitzsimons DP, Diffee GM, Herrick RE, Baldwin KM. Effects of endurance exercise on isomyosin patterns in fast- and slow-twitch skeletal muscles. J Appl Physiol. 1990; 68:1950-1955.
³⁶
Hawley JA. Molecular responses to strength and endurance training: Are they incompatible? Appl Physiol Nutr Metab. 2009; 34:355-361.
³⁷
Always SE, Pereira SL, Edens NK, Hao Y, Bennett BT. β-Hydroxy-β-methylbutyrate (HMB) enhances the proliferation of satellite cells in fast muscles of aged rats during recovery from disuse atrophy. Exp Gerontolol. 2013; 48:973-84.
³⁸
Hao Y, Jackson JR, Wang Y, Edens N, Pereira SL, Always SE. β-Hydroxy-β-methylbutyrate reduces myonuclear apoptosis during recovery from hind limb suspension-induced muscle fiber atrophy in aged rats. Am J Physiol Regul Integr Comp Physiol. 2001; 301:R701-715.
³⁹
Jacobs BL, Goodman CA, Hornberger TA. The mechanical activation of mTOR signaling: an emerging role late endosome/lysosomal targeting. J Muscle Res Cell Motil. 2014; 35:11-21.
⁴⁰
Atherton PJ, Babraj J, Smith K, Singh J, Rennie MJ, Wackerhage H. Selective activation of AMPK-PGC-1alpha or PKB-TSC2-mTOR signaling can explain specific adap-tive responses to endurance or resistance training-like electrical muscle stimulation. FASEB J. 2005; 19:786-98.
⁴¹
Gingras AC, Raught B, Sonenberg N. eIF4 initiation factors: effectors of mRNA recruitment to ribosomes and regulators of translation. Ann Rev Biochem. 1999; 68: 913-63.
⁴²
Shen W, Boyle DW, Wisniowski P, Bade A, Liechty A. Insulin and IGF-I stimulate the formation of the eukariotik initiation factor 4F complex and protein synthesis in C2C12 myotubes independent of availability of external amino acids. J Endocrinol. 2005; 185:275-289.
⁴³
Gerlinger-Romero F, Guimarães-Ferreira L, Giannocco G, Nunes MT. Chronic supplementation of beta-hydroxy-beta methylbutyrate (HMβ) increases the activity of the GH/IGF-I axisand induces hyperinsulinemia in rats. Growth Horm IGF Res. 2011; 21:57-62.
⁴⁴
Zanchi NE, Nicastro H, Gualano B, Costa AS, Lancha-Junior AH. Suplementação de HMB: relevância clínica e mecanismos de ação. Rev Mackenzie Educação Física Esporte. 2009; 8:123-133.
⁴⁵
Nissen S, Sharp RL, Panton L, Vukovich M, Trappe S, Fuller JC. β-Hydroxy-β-Methylbutyrate (HMB) Supplementation in Humans Is Safe and May Decrease Cardiovascular Risk Factors. J Nutr, 2000; 130:1937-1945.
⁴⁶
Panton LB, Rathmacher JA, Baier S, Nissen SL. Nutritional Supplementation of the Leucine Metabolite b-Hydroxy-b-Methylbutyrate (HMB) During Resistance Training. Nutrition. 2000; 16:734- 739.
⁴⁷
Park BS, Henning PC, Grant SC, Lee WJ, Lee SR, Arjmandi BH et al. HMB attenuates muscle loss during sustained energy deficit induced by calorie restriction and endurance exercise. Metabolism. 2013; 62:1718-1729.
⁴⁸
Tanner CJ, Barakat HA, Dohm GL, Pories WJ, MacDonald KG, Cunningham PRG, et al. Muscle fiber type is associated with obesity and weight loss. Am J Physiol Endocrinol Metab., 2002; 282:E1191- E1196.
⁴⁹
Hickey MS, Carey JO, Azevedo JL, Houmard JA, Pories WJ, Israel RG et al. Skeletal muscle fiber composition is related to adiposity and in vitro glucose transport rate in humans. Am J Physiol Endocrinol Metab. 1995; 268:E453-457.
⁵⁰
Mrad JA, Yakubu F, Lin D, Peters JC, Atkinson JB, Hill JO. Skeletal muscle composition in dietary obesitysusceptible and dietary obesity-resistant rats. Am J Physiol Regul Integr Comp Physiol. 1992; 262:684-688.

Publication Dates

Publication in this collection
Jul-Sep 2016

History

Received
27 Nov 2015
Accepted
10 Apr 2016

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ¹
Maughan RJ, Burke LM. Practical nutritional recommendations for the athlete. Nestle Nutrition Institute Workshop Series, 2011; 69:131-149.

[2] ²
Clark RH, Feleke G, Din M, Yasmin T, Singh G, Khan FA et al. Nutritional Treatment for Acquired Immunodeficiency Virus-Associated Wasting Using β-Hydroxy-β-Methylbutyrate, Glutamine, and Arginine: A Randomized, Double-Blind, Placebo-Controlled Study. J Parenter Enteral Nutr. 2000; 24:133-139.

[3] ³
Wilson J, Wilson GJ. Contemporary issues in protein requirements and consumption for resistance trained athletes. J Int Soc Sports Nutr. 2006; 3:7-27.

[4] ⁴
Ransone J, Neighbors K, Lefavi R, Chromiak J. The effect of beta-hydroxy beta-methylbutyrate on muscular strength and body composition in collegiate football players. J Strength Cond Res, 2003;17:34-39.

[5] ⁵
Eley HL, Russell ST, Baxter JH, Mukerji P, Tisdale MJ. Signaling pathways initiated by beta-hydroxy-beta-methylbutyrate to attenuate the depression of protein synthesis in skeletal muscle in response to cachectic stimuli. Am J Physiol. 2007; 293:E923- E931.

[6] ⁶
Kornasio R, Riederer I, Butler-Browne G, Mouly V, Uni Z, Halevy O. Beta-hydroxy-beta-methylbutyrate (HMB) stimulates myogenic cell proliferation, differentiation and survival via the MAPK/ERK and PI3K/Akt pathways. Biochim Biophys Acta, 2009; 1793:755-763.

[7] ⁷
Gallagher PM, Carrithers JA, Godard MP, Schulze KE, Trappe SW. Beta-hydroxy-beta-methylbutyrate ingestion, Part I: effects on strength and fat free mass. Med Sci Sports Exerc, 2000; 32:2109-2115.

[8] ⁸
Pimentel GD, Rosa JC, Lira FS, Zanchi NE, Ropelle ER, Oyama LM et al. b-Hydroxy-b-methylbutyrate (HMb) supplementation stimulates skeletal muscle hypertrophy in rats via the mTOR pathway. Nutr Metabol, 2011; 8:11.

[9] ⁹
McCarthy JP, Pozniak MA, Agre JC. Neuromuscular adaptations to concurrent strength and endurance training. Med Sci Sports Exerc, 2002; 34:511-519.

[10] ¹⁰
Gomes RV, Aoki MS. Suplementação de Creatina Anula o Efeito Adverso do Exercicio de Endurance sobre o subsequente desempenho de Força. Rev Bras Med Esporte, 2005; 11:131-134.

[11] ¹¹
Leveritt M, Abernethy PJ, Barry BK, Logan PA. Concurrent Strength and Endurance Training: the influence of dependent variable selection. J Strength Cond Res. 2003; 17:503-508.

[12] ¹²
Collins MA, Snow TK. Are adaptations to combined endurance and strength training affected by sequence of training? J Sports Sci. 1993; 11:485-491.

[13] ¹³
Hakkinen K, Alen M, Kraemer WJ, Gorostiaga E, Izquierdo M, Rusko H et al. Neuromuscular adaptations during concurrent strength and endurance training versus strength training. Eur J Appl Physiol. 2003; 89:42-52.

[14] ¹⁴
Dudley GA, Fleck SJ. Strength and Endurance Training: are they mutually exclusive? Sports Med. 1987; 4:79-85.

[15] ¹⁵
Carraro F, Stuart CA, Hartl WH, Rosenblatt J, Wolfe RR. Effect of exercise and recovery on muscle protein synthesis in human subjects. Am J Physiol. 1990; 259:E470- E476.

[16] ¹⁶
Chesley A, MacDougall JD, Tarnopolsky MA, Atkinson SA, Smith K. Changes in human muscle protein synthesis after resistance exercise. J Appl Physiol. 1992; 73:1383-1388.

[17] ¹⁷
Teixeira GR, Fávaro WJ, Pinheiro PFF, Chuffa LGA, Amorim JPA, Mendes LO et al. Physical exercise on the rat ventral prostate: Steroid hormone receptors, apoptosis and cell proliferation. Scand J Med Sci Sports. 2012; 22:86-92.

[18] ¹⁸
Harri M, Kuusela P. Is swimming exercise or cold exposure for rats? Acta Physiol Scand. 1986; 126:189-197.

[19] ¹⁹
Tegtbur U, Busse MW, Braumann KM. Estimation of an individual equilibrium between lactate production and catabolism during exercise. Med Sci Sports Exerc. 1993; 25:620-627.

[20] ²⁰
Voltarelli FA, Gobatto CA, Mello MAR. (2002). Determination of anaerobic threshold in rats using the lactate minimum test. Braz J Med Biol Res. 2002; 35: 1389-1394.

[21] ²¹
Araujo GG, Papoti M, Manchado FB, Mello MA, Gobatto CA. Protocols for hyperlactatemia induction in the lactate minimum test adapted to swimming rats. Comp Biochem Physiol, 2007; 148:88-92.

[22] ²²
Novelli ELB, Diniz YS, Galhardi CM, Ebaid GMX, Rodrigues HG, Mani F. et al. Anthropometrical parameters and markers of obesity in rats. Lab Animal. 2007; 41:111-119.

[23] ²³
Dubowitz V, Sewry CA, Oldfors A. Muscle biopsy: a practical approach. London: Elsevier Health Sciences, 2013; pp 492.

[24] ²⁴
Weibel ER, Kistler GS, Scherle WF. Pratical stereologigal methods for morfhometric cytology. J Cell Biol. 1996; 30:23-38.

[25] ²⁵
Banzatto DA, Kronka SN. Experimentação agrícola. Jaboticabal: FUNEP, 1989; p.247.

[26] ²⁶
Bosquet L, Leger L, Legro SP. Methods to determine aerobic endurance. Sports Med. 2002; 32:675-700.

[27] ²⁷
Araujo GG, Papoti M, Manchado-Gobatto FB, Mello MA, Gobatto CA. Padronização de um Protocolo Experimental de Treinamento Periodizado em Natação Utilizando Ratos Wistar. Rev Bras Med Esporte. 2010; 16:51-6.

[28] ²⁸
Voltarelli FA, Mello MAR, Gobatto CA. Limiar anaeróbio determinado pelo teste do lactato mínimo em ratos: efeito dos estoques de glicogênio muscular e do treinamento físico. Rev Port Ciências Desporto. 2004; 4;16-25.

[29] ²⁹
Araújo GG, Papoti M, Manchado-Gobatto FB, Mello MA, Gobatto CA. (2013). Monitoring chronic physical stress using biomarkers, performance protocols and mathematical functions to identify physiological adaptations in rats. Lab Animals. 2013; 47:36-42.

[30] ³⁰
Nissen SL, Abumrad NN. Nutritional role of the leucine metabolite b-hydroxy-h-methylbutyrate (HMB). J Nutr Biochem. 1997; 8:300-311.

[31] ³¹
Durstine JL, Grandjean PW, Cox CA. Thompshom PD. Lipids, lipoproteins and exercise. J Cardiopulm Rehab Prev. 2002; 22:385-398.

[32] ³²
Wilson JM, Grant SC, Lee SR, Masad IS, Park YM, Henning PC et al. Beta-hydroxy-beta-methyl-butyrate blunts negative age-related changes in body composition, functionality and myofiber dimensions in rats. J Int Society Sports Nutr. 2012; 9:18.

[33] ³³
Staron RS, Karapondo DL, Kraemer WJ, Fry AC, Gordon SE, Falkel JE et al. Skeletal muscle adaptations during early phase of heavy-resistance training in men and women. J Appl Physiol. 1994; 76:1247-1255.

[34] ³⁴
Kadi F, Thornell LE. Training affects myosin heavy chain phenotype in the trapezius muscle of women. Histochem Cell Biol. 1999; 112:73-78.

[35] ³⁵
Fitzsimons DP, Diffee GM, Herrick RE, Baldwin KM. Effects of endurance exercise on isomyosin patterns in fast- and slow-twitch skeletal muscles. J Appl Physiol. 1990; 68:1950-1955.

[36] ³⁶
Hawley JA. Molecular responses to strength and endurance training: Are they incompatible? Appl Physiol Nutr Metab. 2009; 34:355-361.

[37] ³⁷
Always SE, Pereira SL, Edens NK, Hao Y, Bennett BT. β-Hydroxy-β-methylbutyrate (HMB) enhances the proliferation of satellite cells in fast muscles of aged rats during recovery from disuse atrophy. Exp Gerontolol. 2013; 48:973-84.

[38] ³⁸
Hao Y, Jackson JR, Wang Y, Edens N, Pereira SL, Always SE. β-Hydroxy-β-methylbutyrate reduces myonuclear apoptosis during recovery from hind limb suspension-induced muscle fiber atrophy in aged rats. Am J Physiol Regul Integr Comp Physiol. 2001; 301:R701-715.

[39] ³⁹
Jacobs BL, Goodman CA, Hornberger TA. The mechanical activation of mTOR signaling: an emerging role late endosome/lysosomal targeting. J Muscle Res Cell Motil. 2014; 35:11-21.

[40] ⁴⁰
Atherton PJ, Babraj J, Smith K, Singh J, Rennie MJ, Wackerhage H. Selective activation of AMPK-PGC-1alpha or PKB-TSC2-mTOR signaling can explain specific adap-tive responses to endurance or resistance training-like electrical muscle stimulation. FASEB J. 2005; 19:786-98.

[41] ⁴¹
Gingras AC, Raught B, Sonenberg N. eIF4 initiation factors: effectors of mRNA recruitment to ribosomes and regulators of translation. Ann Rev Biochem. 1999; 68: 913-63.

[42] ⁴²
Shen W, Boyle DW, Wisniowski P, Bade A, Liechty A. Insulin and IGF-I stimulate the formation of the eukariotik initiation factor 4F complex and protein synthesis in C2C12 myotubes independent of availability of external amino acids. J Endocrinol. 2005; 185:275-289.

[43] ⁴³
Gerlinger-Romero F, Guimarães-Ferreira L, Giannocco G, Nunes MT. Chronic supplementation of beta-hydroxy-beta methylbutyrate (HMβ) increases the activity of the GH/IGF-I axisand induces hyperinsulinemia in rats. Growth Horm IGF Res. 2011; 21:57-62.

[44] ⁴⁴
Zanchi NE, Nicastro H, Gualano B, Costa AS, Lancha-Junior AH. Suplementação de HMB: relevância clínica e mecanismos de ação. Rev Mackenzie Educação Física Esporte. 2009; 8:123-133.

[45] ⁴⁵
Nissen S, Sharp RL, Panton L, Vukovich M, Trappe S, Fuller JC. β-Hydroxy-β-Methylbutyrate (HMB) Supplementation in Humans Is Safe and May Decrease Cardiovascular Risk Factors. J Nutr, 2000; 130:1937-1945.

[46] ⁴⁶
Panton LB, Rathmacher JA, Baier S, Nissen SL. Nutritional Supplementation of the Leucine Metabolite b-Hydroxy-b-Methylbutyrate (HMB) During Resistance Training. Nutrition. 2000; 16:734- 739.

[47] ⁴⁷
Park BS, Henning PC, Grant SC, Lee WJ, Lee SR, Arjmandi BH et al. HMB attenuates muscle loss during sustained energy deficit induced by calorie restriction and endurance exercise. Metabolism. 2013; 62:1718-1729.

[48] ⁴⁸
Tanner CJ, Barakat HA, Dohm GL, Pories WJ, MacDonald KG, Cunningham PRG, et al. Muscle fiber type is associated with obesity and weight loss. Am J Physiol Endocrinol Metab., 2002; 282:E1191- E1196.

[49] ⁴⁹
Hickey MS, Carey JO, Azevedo JL, Houmard JA, Pories WJ, Israel RG et al. Skeletal muscle fiber composition is related to adiposity and in vitro glucose transport rate in humans. Am J Physiol Endocrinol Metab. 1995; 268:E453-457.

[50] ⁵⁰
Mrad JA, Yakubu F, Lin D, Peters JC, Atkinson JB, Hill JO. Skeletal muscle composition in dietary obesitysusceptible and dietary obesity-resistant rats. Am J Physiol Regul Integr Comp Physiol. 1992; 262:684-688.

	C	S	T	TS
Tlim_pre	63.9 ± 14.6	64.8 ± 9.4	69.8 ± 25.5	62.8 ± 13.2
Tlim_post	50.3 ± 3.9	49.0 ± 9.4	54.0 ± 8.8	54.2 ± 15.2
∆%*	-18.5 ± 15.1	-21.7 ± 25.1	-15.8 ± 26.9	-7.2 ± 44.4

					ANOVA model*
Varibles	C	S	T	TS	p	r²
Total fat (g)	9.3±2.1	10.3±3.4	5.8±0.8	6.3±0.9	0.016^a	0.446
Relative weight of total fat	2.2±0.6	2.3±0.6	1.4±1. 6	1.5±0.3	0.015^a	0.450
Weight of the soleus (g)	0.20±0.02	0.23±0.04	0.20±0.02	0.20±0.02	0.163	0.254
Relative weight of the soleus	0.048±0.002	0.051±0.003	0.051±0.003	0.046±0.002	0.026^b	0.411
Weight of the liver (g)	15.6±3.7	16.9±3.6	12.8±1.7	15.9±2.1	0.207	0.242
Relative weight of the liver	3.7±0.8	3.8±0.3	3.2±0.4	3.7±0.4	0.306	0.197

	C	S	T	TS
Area of muscle fiber	108.7(105.7-112.6)^d	113.8(105.3-119.8)	113.3(109.9-114.0)	112.6(112.6-114.4)
Area of connective tissue	20.4 (15.2-22.9)^c,d	13 (9.6-20.2)	13.9 (12.4-17.6)	14.9 (12.4-20.4)
Nuclear area	2.1 (1.8-3.1)^b,c,d	3.3 (2.3-5.4)	3.8 (2.6-4.5)	3.8 (3.3-4.3)

Brasil

Brasil

The effect of β-hydroxy-β-methylbutyrate (HMB) on the morphology of skeletal muscle after concurrent training

Abstract

Introduction

Methods

Animals and experimental procedure

HMB supplementation

Determination of Aerobic and Anaerobic Performances

Anthropometric, histological and histochemical analyses

Statistical Analysis

Results

Discussion

Acknowledgments

References

Publication Dates

History