Effects of physical training on the metabolic profile of rats exposed to chronic restraint stress

Reis, Carlos H.O.; Manzolli, Sabriny G.; Santos, Leonardo dos; Silva, Ariana A.; Lima-Leopoldo, Ana Paula; Leopoldo, André S.; Bocalini, Danilo S.

doi:10.1016/j.clinsp.2024.100411

Abstract

Introduction:

Despite strong evidences supporting the protective role of exercise against stress-induced repercussions, the literature remains inconclusive regarding metabolic aspects. Therefore, this study aimed to evaluate the effect of Physical Training (PT) by swimming on the metabolic parameters of rats subjected to restraint stress.

Methods:

Wistar rats (n = 40) were divided into four groups: Control (C), Trained (T), Stressed (S), and Trained/Stressed (TS). The restraint stress protocol involved confining the animals in PVC pipes for 60 minutes/day for 12 weeks. Concurrently, the swimming PT protocol was performed without additional load in entailed sessions of 60 minutes conducted five days a week for the same duration. The following parameters were analyzed: fitness progression assessed by the physical capacity test, body mass, serum level of glucose, triglyceride, cholesterol and corticosterone, as well as glycemic tolerance test, evaluated after glucose administration (2 g/kg, i.p.).

Results:

Trained groups (T and TS) exhibited enhanced physical capacity (169 ± 21 and 162 ± 22% increase, respectively) compared to untrained groups (C: 9 ± 5 and S: 11 ± 13% increase). Corticosterone levels were significantly higher in the S group (335 ± 9 nmoL/L) compared to C (141 ± 3 nmoL/L), T (174 ± 3 nmoL/L) and TS (231 ± 7 nmoL/L), which did not differ from each other. There were no significant changes in serum glucose, cholesterol, and triglyceride levels among the groups. However, the glycemic curve after glucose loading revealed increased glycemia in the S group (area under curve 913 ± 30 AU) but the TS group exhibited values (673 ± 12 AU) similar to the groups C (644 ± 10 AU) and T (649 ± 9 AU).

Conclusion:

Swimming-based training attenuated stress-induced corticosterone release and prevented glucose intolerance in rats, reinforcing the importance of exercise as a potential strategy to mitigate the pathophysiologi-cal effects of stress.

Keywords:
Stress; Glucose Tolerance; Physical exercise and fitness

HIGHLIGHTS

Swimming training significantly prevented stress-induced corticosterone increase in rats.

Serum glucose, cholesterol and triglyceride were unchanged by chronic stress or exercise.

Chronic stress protocol induced glucose intolerance in the rats.

The training preserved the normal glycemic response after glucose loading in stressed rats.

Introduction

Stress is considered a state of homeostasis disruption characterized by specific and generalized adaptive responses to a perceived threat, challenge, or demand caused by psychological, environmental or physiological agents.¹1 Chrousos GP, Gold PW. The concepts of stress and stress system disorders. Overview of physical and behavioral homeostasis. JAMA 1992;267(9):1244–52. It can be categorized as either acute or chronic, both eliciting Sympathetic Nervous System (SNS) hyperactivity, catecholamine release, and dysregulation of the Hypothalamic-Pituitary-Adrenal (HPA) axis, resulting in elevated production of glucocorticoids ‒ cortisol in humans and corticosterone in rodents,²2 Ströhle A. Physical activity, exercise, depression and anxiety disorders. J Neural Transm 2009;116(6):777–84. recognized as primary stress indicators.³3 Andersen ML, Bignotto M, Machado RB, Tufik S. Different stress modalities result in distinct steroid hormone responses by male rats. Braz J Med Biol Res 2004;37(6):791–7.

While short-term stress responses help individuals cope with immediate challenges, chronic or severe stress can adversely affect both physical and mental health, contributing to the development of pathological conditions, particularly cardiovascular diseases.⁴4 Kivimäki M, Steptoe A. Effects of stress on the development and progression of cardiovascular disease. Nat Rev Cardiol 2018;15(4):215–29. Additionally, the increased SNS and HPA activities are associated not only with increased heart rate and blood pressure, and suppression of the immune system but also with insulin resistance⁷7 Guzzoni V, Sanches A, Costa R, Souza LB, Firoozmand LT, Abreu ICME, et al. Stress-induced cardiometabolic perturbations, increased oxidative stress and ACE/ACE2 imbalance are improved by endurance training in rats. Life Sci 2022;305:120758. and increased serum levels of glucose and lipids.⁵5 Tank AW, Lee WD. Peripheral and central effects of circulating catecholamines. Compr Physiol 2015;5(1):1–15.

Several strategies have been explored to combat stress-related complications.⁸8 Nunomura M, Teixeira LAC, Caruso MRF. Nível de estresse em adultos após 12 meses de prática regular de atividade física. Rev Mackenzie Educação Física Esporte 2004;3 (3):125–34.,⁹9 Moraes C, Sampaio RC. Oxidative stress and aging: role of physical exercise. Motriz 2010;16(2):506–15. Among these, physical exercise stands out as a clinically important tool in the control of stress symptoms.¹⁰10 Blumenthal JA, Emery CF, Walsh MA, Cox DR, Kuhn CM, Williams RB, et al. Exercise training in healthy Type A middle-aged men: effects on behavioral and cardiovascular responses. Psychosomatic Med 1988;50:418–33. Increased physical activity and reduced sedentary behavior are particularly crucial strategies in preventing, managing, and treating various stages of functional impairment caused by chronic stress.⁸8 Nunomura M, Teixeira LAC, Caruso MRF. Nível de estresse em adultos após 12 meses de prática regular de atividade física. Rev Mackenzie Educação Física Esporte 2004;3 (3):125–34.,¹¹11 Lipp MNL. Controle do estresse e hipertensão arterial sistêmica. Rev Bras Hipertens 2007;14(2):89–93.,¹²12 Nascimento TB, Campos DHS, Leopoldo AS, Lima-Leopoldo AP, Okoshi K, Cordellini S, et al. Chronic stress improves the myocardial function without altering L-type Ca+2 channel activity in rats. Arq Bras Cardiol 2012;99(4):907–14.

Actually, a Silva et al.⁶6 Silva AA, Perilhão MS, Portes LA, Serra AJ, Tucci PJF, Leopoldo AS, et al. Physical exercise attenuates stress-induced hypertension in rats but not the impairments on the myocardial mechanics. J Hypertens 2022;40(3):528–35. study conducted on rats exposed to chronic stress and physical training showed that adaptations induced by exercise attenuate stress-induced hypertension in rats but not the impairments on the myocardial mechanics. The significance of physical exercise is further evidenced by previous studies⁸8 Nunomura M, Teixeira LAC, Caruso MRF. Nível de estresse em adultos após 12 meses de prática regular de atividade física. Rev Mackenzie Educação Física Esporte 2004;3 (3):125–34.,¹¹11 Lipp MNL. Controle do estresse e hipertensão arterial sistêmica. Rev Bras Hipertens 2007;14(2):89–93. that have demonstrated positive outcomes in clinical indicators of stress. Furthermore, physical exercise had been considered such effective strategy to reduce blood pressure,¹³13 Tanaka H, Basset Jr DR, Howley ET, Thompson DL, Ashraf M, Rawson FL. Swimming training lowers the resting blood pressure in individuals with hypertension. J Hypertens 1997;15:651–7. improved blood glucose control,¹⁴14 Vancea DMM, Vancea JN, Pires MIF, Reis AM, Moura RB, Dib SA. Effect of frequency of physical exercise on glycemic control and body composition in type 2 diabetic patients. Arq Bras Cardiol 2009;92(1):23–30. increased insulin sensitivity,¹⁵15 Mediano MFF, Barbosa JSO, Sichieri R, Pereira RA. Efeito do exercício físico na sensibilidade à insulina em mulheres obesas submetidas a programa de perda de peso: um ensaio clínico. Arq Bras Endocrinol Metab 2007;51(6):993–9. enhanced immune response,¹⁶16 Leandro CG, Nascimento E, Manhães-de-Castro R, Duarte JA, de Castro CMMB. Exercício físico e sistema imunológico: mecanismos e integrações. Rev Port Ciênc Desp 2002;2(5):80–90. and improved functional capacity.¹⁷17 Downing J, Balady GJ. The role of exercise training in heart failure. J Am Coll Cardiol 2011;58(6):561–9.

However, if considering the research with basic approaches, the knowledge of physical exercise interventions by swimming to treat and in preventing metabolic outcomes associated with stress is still unclear. To understand the effects of stress in a more invasive way, protocols used in animal models are developed to advance the discovery of the mechanisms involved in stress, as well as the physiological and morphological repercussions¹⁸18 Alves-Rezende MCR, Kusuda R, Alves LMN, Felipini RC, Okamoto R, Okamoto T, et al. Efeito do estresse crônico de contenção sobre o reparo de cavidades ósseas: estudo histológico em tíbia de ratos. Rev Odontol Aracatuba 2009;30(2):71–6. and understanding the interaction between various stimuli associated with physical activity.¹⁹19 Burder-Nascimento T, Campos DHS, Cicogna AC, Cordellini S. Chronic stress improves NO– and Ca2+ flux-dependent vascular function: a pharmacological study. Arq Bras Cardiol 2015;104(3):226–33. Thus, this study aimed to evaluate the effect of physical training by swimming on the metabolic parameters of rats subjected to restraint stress.

Material and methods

Animals and experimental groups

Twenty-nine male young Wistar rats (10‒12 weeks-old), weighing 200‒250g, were sourced from the Animal Facility at the Federal University of Espirito Santo for inclusion in this study. The animals were housed individually in cages, provided with “ad libitum” water and Nuvital CR-1 rat feed, in a controlled environment maintained at the temperature of approximately 22°C, humidity at 54%, and a 12-hour light/dark cycle. All protocols were in accordance with the recommendations of the National Council for Animal Experimentation. This study was previously approved by the Institutional Ethics Committee on Animal Use (number 21/2021).

The animals were randomly divided into four experimental groups as follows: Control (C; n = 10), consisting of animals that remained at rest for twelve weeks; Trained (T; n = 10), with animals that underwent twelve weeks of swimming training; Stressed (S; n = 10), animals that remained at rest and submitted to restraint stress for twelve weeks; and Trained/Stressed (TS; n = 10), comprising animals that underwent twelve weeks of swimming training while simultaneously being subjected to restraint stress.

Physical exercise protocol

The swimming exercise protocol follows the procedures previously established by this group.²⁰20 Bocalini DS, Carvalho EV, de Souza AF, Levy RF, Tucci PJ. Exercise training-induced enhancement in myocardial mechanics is lost after 2 weeks of detraining in rats. Eur J Appl Physiol 2010;109(5):909–14. The training program began with a 6-day adaptation phase, during which animals swam for 10 minutes on the first day, with each subsequent session adding ten minutes until completing 60 minutes per session. Then, a training phase was applied and maintained (60 minutes per session, five days a week) for 12 weeks. The pool water was constantly agitated using a pump to prevent the animals from diving or floating during the sessions, and a thermostat-controlled electric heating system maintained the water temperature between 32–34°C, according to recommendations for rodent exercise regimes.²¹21 Kregel KC, Allen DL, Booth FW, Fleshner MR, Henriksen EJ, Much TI, et al. Resource book for the design of animal exercise protocols. 1rd ed. American Physiological Society; 2006.

Chronic stress protocol

Chronic stress was attained using immobilization individually in a Polyvinyl chloride (PVC) cylinder. Restraint stress is a widely utilized model of emotional stress in animal studies.¹²12 Nascimento TB, Campos DHS, Leopoldo AS, Lima-Leopoldo AP, Okoshi K, Cordellini S, et al. Chronic stress improves the myocardial function without altering L-type Ca+2 channel activity in rats. Arq Bras Cardiol 2012;99(4):907–14.,²²22 Malta MB. Efeitos adaptativos induzidos pelo estresse crônico imprevisível nos receptores do fator liberador de corticotrofina tipo 2 e de glicocorticóides no sistema nervoso central de ratos [tese]. São Paulo: Universidade de São Paulo; 2012. In the present study, animals were individually restrained in an opaque PVC cylinder (brown), measuring 20 cm in length and 6 cm in diameter, with closed ends and perforations for air circulation and maintenance of the ambient temperature at 25°C. This restraint lasted for 60 minutes per day, five days a week, over 12 weeks, according to established protocol.¹²12 Nascimento TB, Campos DHS, Leopoldo AS, Lima-Leopoldo AP, Okoshi K, Cordellini S, et al. Chronic stress improves the myocardial function without altering L-type Ca+2 channel activity in rats. Arq Bras Cardiol 2012;99(4):907–14.,²²22 Malta MB. Efeitos adaptativos induzidos pelo estresse crônico imprevisível nos receptores do fator liberador de corticotrofina tipo 2 e de glicocorticóides no sistema nervoso central de ratos [tese]. São Paulo: Universidade de São Paulo; 2012. This confinement severely restricts the animal movement, allowing only respiratory movements. In addition, the animal was kept away from contact with feces and with the tail raised, since these factors could intensify the stress stimulus beyond the intended level.

Physicalfitness assessment

The physical fitness and capacity were assessed in all experimental groups at the beginning and end of the protocols, using the maximal physical capacity test as previously established.²⁰20 Bocalini DS, Carvalho EV, de Souza AF, Levy RF, Tucci PJ. Exercise training-induced enhancement in myocardial mechanics is lost after 2 weeks of detraining in rats. Eur J Appl Physiol 2010;109(5):909–14. Briefly, animals were weighed, and loads equivalent to 10% of their body mass were affixed to their tails to assess physical capacity. The maximum swimming duration until the animal reached complete exhaustion was recorded, with exhaustion defined as submersion for at least 10 seconds.²⁰20 Bocalini DS, Carvalho EV, de Souza AF, Levy RF, Tucci PJ. Exercise training-induced enhancement in myocardial mechanics is lost after 2 weeks of detraining in rats. Eur J Appl Physiol 2010;109(5):909–14.

Blood biomarkers associated with stress

After undergoing a 15-hour fast, glucose, cholesterol and triglyceride concentrations were measured from blood samples collected from the caudal vein using the equipment Accuttrend (Roche Diagnostic Brazil Ltda., Brazil).

Subsequently, rats underwent a glucose tolerance test. Baseline blood samples were obtained from the tail, followed by glucose administration (2 g/kg, i.p.), as protocols were previously established.²³23 Barnes VA, Bauza LB, Treiber FA. Impact of stress reduction on negative school behavior in adolescents. Health Qual Life Outcomes 2003;23(1):10.,²⁴24 Fatani S, Pickavance LC, Sadler CJ, Harrold JA, Cassidy R, Wilding JPH, et al. Diffential vascular dysfunction in response to diets of differing macronutrient composition: a phenomenonological study. Nutr Metab (Lond) 2007;4:1–6. Blood samples were then collected at 30, 60, 120, 180 and 280 minutes post-glucose administration. Glucose levels were determined using the same equipment (Accuttrend, Roche Diagnostic Brazil Ltda., Brazil), and glucose tolerance was analyzed based on the area under the glycemic response curve.

Assessment of stress intensity

After 48 hours of physical fitness assessment, all animals underwent a 12-hour fast and were anesthetized with pentobarbital (Fontoveter Animal Pharmaceuticals and Cosmetics Ltd, Sao Paulo, Brazil) at a dosage of 50 mg/kg and euthanized by decapitation. Blood samples were collected in heparinized tubes, centrifuged at 3000 g for 15 minutes at 4°C, and the serum was stored in an ultra-freezer at –80°C. Corticosterone levels were determined using a specific radioimmunoassay kit (Coat-A-Count Rat Corticosterone – Diagnostic Products Corporation, Los Angeles, USA), with a detection limit of approximately 16 nmoL/L.

Statistical analyses

Data are presented as mean ± Standard Error of Mean (SEM). The DAgostino-Pearson test was applied to analyze the normality distribution. For comparisons, the two-way ANOVA test was used, complemented with Bonferroni’s or Dunn’s post hoc tests, as necessary. All tests and graphics were performed using GraphPad Prism software (version 8.0, GraphPad Softwares Inc., San Diego, CA, USA). The significance level was set at 0.05.

Results

As shown in Fig. 1, there was no significant difference (p > 0.05) in the physical capacity of the groups before the protocols. However, after 12 weeks of training, the groups T (before: 102 ± 23 vs. after: 273 ± 61 seconds) and TS (before: 97 ± 14 vs. after: 256 ± 50 seconds) improved their physical capacity, without distinction between them. Moreover, the physical capacity of the untrained groups remained unchanged after this period (group C, before: 86 ± 45 vs. after: 92 ± 46 seconds and group S, before: 96 ± 33 vs. after: 104 ± 32 seconds). As a result, the training protocol was able to improve 169 ± 21% and 162 ± 22% of the physical capacity of groups T and TS, respectively.

Fig. 1
Values expressed as mean ± SEM of the physical capacity of animals in experimental groups before and after 12 weeks of intervention (* p < 0.05 vs. before; ^† p < 0.05 vs. C; ^‡ p < 0.05 vs. E).

The corticosterone levels (Fig. 2A), as measured in the experimental groups 12 weeks after protocols, was significantly increased in the stressed animals (335 ± 9 nmoL/L) them C (141 ± 3 nmoL/L), T (174 ± 3 nmoL/L) and TS (231 ± 7 nmoL/L). However, the strength training slightly elevated corticosterone levels in nonstressed groups, this exercise protocol was able to partially prevent the corticosterone increase induced by the chronic stress. which also differed from each other. No effects on the basal levels (fasting) of serum glucose (C: 100 ± 4, T: 97 ± 3, S: 100 ± 4, TS: 97 ± 5 mg/dL), cholesterol (C: 161 ± 3, T: 156 ± 4, S: 178 ± 8, TS: 258 ± 2 mg/dL) and triglyceride (C: 123 ± 6, T: 123 ± 6, S: 130 ± 8, TS: 127 ± 9 mg/dL).

Fig. 2
Values expressed as mean ± the SEM of corticosterone levels (Panel A), blood glucose curves after loading test (Panel B) and areas under the glycemic curves (Panel C) of groups C (control), T (trained), S (stressed), and TS (trained stressed) after 12 weeks of intervention (* p < 0.05 vs. C; ^† p < 0.05 vs. T; ^‡ p < 0.05 vs. TS).

In terms of glycemic tolerance, as shown in Fig. 2B, the glucose levels in group S remained consistently higher (p < 0.05) following glucose administration compared to groups C, T, and TS, which showed no significant differences between them. When considering the overall blood glucose patterns throughout this protocol, the area under the curve values (Fig. 2C) for group S (913 ± 30 AU) was notably elevated compared to groups C (644 ± 10 AU), T (649 ± 9 AU), and TS (673 ± 12 AU), with no significant variances observed between the lattes three groups. Together, these findings clearly indicate impaired glycemic control in animals submitted to chronic stress protocol, which was significantly prevented by the strength-training program.

Discussion

Physical inactivity is directly associated with various health risk factors, including stress,²⁶26 Rodriguez-Ayllon M, Cadenas-Sánchez C, Estévez-López F, Muñoz EN, Mora-Gonzalex J, Migueles JH, et al. Role of physical activity and sedentary behavior in the mental health of preschoolers, children and adolescents: a systematic review and meta-analysis. Sports Med 2019;49(9):1383–410. which can diminish life expectancy within the population.²⁵25 Dumith SC, Maciel FV, Borchardt JL, Alam VS, Silveira FC, Paulitsch RG. Health predictors and conditions associated to moderate and vigorous physical activity among adults and elderly from Southern Brazil. Rev Bras Epidemiol 2019;22:e190023. Conversely, regular physical exercise is recognized as an important protective measure against adverse effects of stress⁶6 Silva AA, Perilhão MS, Portes LA, Serra AJ, Tucci PJF, Leopoldo AS, et al. Physical exercise attenuates stress-induced hypertension in rats but not the impairments on the myocardial mechanics. J Hypertens 2022;40(3):528–35. and numerous stress-associated chronic diseases such as cardiovascular diseases, diabetes, obesity²⁷27 Pedersen BK, Saltin B. Exercise as medicine - evidence for prescribing exercise as therapy in 26 different chronic diseases. Scand J Med Sci Sport 2015;25(Suppl 3):1–72. and atherosclerosis.²⁸28 Hong J, Park E, Lee J, Lee Y, Rooney BV, Park Y. Exercise training mitigates ER stress and UCP2 deficiency-associated coronary vascular dysfunction in atherosclerosis. Sci Rep 2021;11(1):15449.

Considering the exercise protocol used in this study, this type of training has been widely employed to investigate the repercussions of physical exercise,⁶6 Silva AA, Perilhão MS, Portes LA, Serra AJ, Tucci PJF, Leopoldo AS, et al. Physical exercise attenuates stress-induced hypertension in rats but not the impairments on the myocardial mechanics. J Hypertens 2022;40(3):528–35. proving effective in enhancing physical capacity,²⁹29 Zhou Q, Deng J, Yao J, Song J, Meng D, Zhu Y, et al. Exercise downregulates HIPK2 and HIPK2 inhibition protects against myocardial infarction. EBioMedicine 2021;74:103713. albeit potentially inducing acute stress-like effects.⁶6 Silva AA, Perilhão MS, Portes LA, Serra AJ, Tucci PJF, Leopoldo AS, et al. Physical exercise attenuates stress-induced hypertension in rats but not the impairments on the myocardial mechanics. J Hypertens 2022;40(3):528–35. In the present study, even the physical capacity of animals subjected to stress was significantly improved by the training protocol, aligning with findings from previous reports.⁶6 Silva AA, Perilhão MS, Portes LA, Serra AJ, Tucci PJF, Leopoldo AS, et al. Physical exercise attenuates stress-induced hypertension in rats but not the impairments on the myocardial mechanics. J Hypertens 2022;40(3):528–35.,³⁰30 Prokic V, Plecevic S, Bradic J, Petkovic A, Srejovic I, Bolevich S, et al. The impact of nine weeks swimming exercise on heart function in hypertensive and normotensive rats: role of cardiac oxidative stress. J Sports Med Phys Fitness 2019;59(12):2075–83. Additionally, serum corticosterone levels in animals exposed to chronic stress were not elevated when combined with physical exercise. Given that glucocorticoids are considered biological markers for chronic stress, elevated levels have been associated with an increased risk of developing conditions such as hypertension, atherosclerosis, and heart failure.²⁷27 Pedersen BK, Saltin B. Exercise as medicine - evidence for prescribing exercise as therapy in 26 different chronic diseases. Scand J Med Sci Sport 2015;25(Suppl 3):1–72.,²⁸28 Hong J, Park E, Lee J, Lee Y, Rooney BV, Park Y. Exercise training mitigates ER stress and UCP2 deficiency-associated coronary vascular dysfunction in atherosclerosis. Sci Rep 2021;11(1):15449.

No changes in glucose, cholesterol, and triglyceride levels were observed in this study, diverging from findings in other studies.³¹31 Chies AB, Corrêa FM, de Andrade CR, Rosa-e-Silva AA, Pereira FC, de Oliveira AM. Vascular non-endothelial nitric oxide induced by swimming exercise stress in rats. Clin Exp Pharmacol Physiol 2003;30(12):951–7.,³²32 Travassos PB, Godoy G, De Souza HM, Curi R, Bazotte RB. Performance during a strenuous swimming session is associated with high blood lactate: pyruvate ratio and hypoglycemia in fasted rats. Braz J Med Biol Res 2018;51 (5):e7057. It is postulated that duration, intensity, and volume of stress exposure may have influenced this outcome. Prior research⁶6 Silva AA, Perilhão MS, Portes LA, Serra AJ, Tucci PJF, Leopoldo AS, et al. Physical exercise attenuates stress-induced hypertension in rats but not the impairments on the myocardial mechanics. J Hypertens 2022;40(3):528–35.,³³33 Pereira MMS, de Melo IMF, Braga VAÁ, Teixeira ÁAC. Wanderley-Teixeira V. Effect of swimming exercise, insulin-associated or not, on inflammatory cytokines, apoptosis, and collagen in diabetic rat placentas. Histochem Cell Biol 2022;157(4):467–79. indicated that different types of exercise confer benefits against stress-induced pathological changes. Thus, as demonstrated in the present study, physical exercise led to enhanced regulation of glycemic control.³⁴34 Horii N, Hasegawa N, Fujie S, Uchida M, Iemitsu K, Inoue K, et al. Effect of combination of chlorella intake and aerobic exercise training on glycemic control in type 2 diabetic rats. Nutrition 2019;63-64:45–50.,³⁵35 Pauli JR, Souza L, Rogatto G, Gomes R, Luciano E. Glicocorticóides e síndrome metabólica: aspectos favoráveis do exercício físico nesta patofisiologia. Rev Port Cien Desp 2007;6(2):17–228. Although the precise mechanism underlying this improvement remains unexplored, increased glucose uptake by the muscle due to the increased amount and activity of the GLUT4 are suggested to play an important role in this response.³⁶36 Radahmadi M, Alaei H, Sharifi MR, Hosseini N. Effect of forced exercise and exercise withdrawal on memory, serum and hippocampal corticosterone levels in rats. Exp Brain Res 2015;233(10):2789–99. Therefore, employing distinct pathways for GLUT4 translocation emerges as a principal mechanism for glucose uptake by skeletal muscle tissue. The energy discrepancy induced by muscle fiber contraction serves as the primary stimulus for AMP-Kinase (AMPKK), an enzyme that activates AMPK, subsequently facilitating the translocation of GLUT4 vesicles to the cell membrane.³⁶36 Radahmadi M, Alaei H, Sharifi MR, Hosseini N. Effect of forced exercise and exercise withdrawal on memory, serum and hippocampal corticosterone levels in rats. Exp Brain Res 2015;233(10):2789–99.

Furthermore, stress has been shown to compromise the insulin response.³⁷37 Zito JB, Hanna A, Kadoo N, Tomaszycki ML. Early life stress increases testosterone and corticosterone and alters stress physiology in zebra finches. Horm Behav 2017;95:57–64. Since insulin plays a critical role in regulating blood glucose homeostasis, the development of insulin resistance is one of the main factors contributing to the onset of type II diabetes, a condition already correlated with stress.³⁸38 Lipowska MM, Sadowska ET, Bauchinger U, Koteja P. Stress coping and evolution of aerobic exercise performance: corticosterone levels in voles from a selection experiment. J Exp Biol 2019;222(Pt 20):jeb209593. From this perspective, regular physical exercise has been recognized as an important strategy to improve insulin response.³²32 Travassos PB, Godoy G, De Souza HM, Curi R, Bazotte RB. Performance during a strenuous swimming session is associated with high blood lactate: pyruvate ratio and hypoglycemia in fasted rats. Braz J Med Biol Res 2018;51 (5):e7057. Although our the authors did not evaluate the insulin response in the present study, the authors believe that the preserved glycemic behavior of stressed and trained animals to glucose loading may be justified by an improved insulin response by some mechanisms previously documented in the literature.¹⁴14 Vancea DMM, Vancea JN, Pires MIF, Reis AM, Moura RB, Dib SA. Effect of frequency of physical exercise on glycemic control and body composition in type 2 diabetic patients. Arq Bras Cardiol 2009;92(1):23–30.,³⁵35 Pauli JR, Souza L, Rogatto G, Gomes R, Luciano E. Glicocorticóides e síndrome metabólica: aspectos favoráveis do exercício físico nesta patofisiologia. Rev Port Cien Desp 2007;6(2):17–228. Nonetheless, further studies are needed to confirm this hypothesis.

As evidenced in this study, physical exercise led to a reduction in corticosterone levels²2 Ströhle A. Physical activity, exercise, depression and anxiety disorders. J Neural Transm 2009;116(6):777–84.,³⁹39 Droste SK, Gesing A, Ulbricht S, Muller MB, Linthorst ACE, Reul JMHM. Effects of long-term voluntary exercise on the mouse hypothalamic-pituitary-adrenocortical axis. Endocrinology 2003;144(7):3012–23. and improved regulation of glycemic control.³⁴34 Horii N, Hasegawa N, Fujie S, Uchida M, Iemitsu K, Inoue K, et al. Effect of combination of chlorella intake and aerobic exercise training on glycemic control in type 2 diabetic rats. Nutrition 2019;63-64:45–50. The decrease in corticosterone levels has been linked to a reduction in stress intensity, as observed in previous research;⁴⁰40 Contarteze RVL, Manchado FB, Gobatto CA, de Mello MAR. Biomarkers of stress in rats exercised in swimming at intensities equal and superior to the maximal estable lactate phase. Rev Bras Med Esporte 2007;13(3):150e–4e.,⁴¹ however, further investigations are warranted to fully understand this response. Elevated circulating glucocorticoid levels diminish the sensitivity of hepatic and peripheral tissues to insulin, resulting in increased hepatic glucose production and impaired glucose absorption by muscles and adipose tissue.³⁸38 Lipowska MM, Sadowska ET, Bauchinger U, Koteja P. Stress coping and evolution of aerobic exercise performance: corticosterone levels in voles from a selection experiment. J Exp Biol 2019;222(Pt 20):jeb209593. In line with the authors’s findings, plasma corticosterone levels were found to rise during and up to 1 hour after an episode of acute stress, coinciding with a return to baseline glycemic levels.³⁸38 Lipowska MM, Sadowska ET, Bauchinger U, Koteja P. Stress coping and evolution of aerobic exercise performance: corticosterone levels in voles from a selection experiment. J Exp Biol 2019;222(Pt 20):jeb209593. As demonstrated in the present study, physical exercise attenuated corticosterone levels²2 Ströhle A. Physical activity, exercise, depression and anxiety disorders. J Neural Transm 2009;116(6):777–84.,³⁹39 Droste SK, Gesing A, Ulbricht S, Muller MB, Linthorst ACE, Reul JMHM. Effects of long-term voluntary exercise on the mouse hypothalamic-pituitary-adrenocortical axis. Endocrinology 2003;144(7):3012–23. and improved regulation of glycemic control³⁴34 Horii N, Hasegawa N, Fujie S, Uchida M, Iemitsu K, Inoue K, et al. Effect of combination of chlorella intake and aerobic exercise training on glycemic control in type 2 diabetic rats. Nutrition 2019;63-64:45–50. of the stressed rat. Actually, the decrease in corticosterone levels has been linked to a reduction in stress intensity, as observed in other studies;⁴⁰40 Contarteze RVL, Manchado FB, Gobatto CA, de Mello MAR. Biomarkers of stress in rats exercised in swimming at intensities equal and superior to the maximal estable lactate phase. Rev Bras Med Esporte 2007;13(3):150e–4e.,⁴¹ however, more investigations are warranted to clarify this response. Elevated circulating glucocorticoid levels diminish the sensitivity of hepatic and peripheral tissues to insulin, leading to an increase in hepatic glucose production and impaired absorption by muscles and adipose tissue.³⁸38 Lipowska MM, Sadowska ET, Bauchinger U, Koteja P. Stress coping and evolution of aerobic exercise performance: corticosterone levels in voles from a selection experiment. J Exp Biol 2019;222(Pt 20):jeb209593. In line with the present findings, plasma corticosterone levels were found to increase during and up to 1 hour after an episode of acute stress, coinciding with a return to baseline glycemic levels.³⁸38 Lipowska MM, Sadowska ET, Bauchinger U, Koteja P. Stress coping and evolution of aerobic exercise performance: corticosterone levels in voles from a selection experiment. J Exp Biol 2019;222(Pt 20):jeb209593.

In general, the results of this study suggest that exercise effectively attenuated the stress effects on glucose control and corticosterone levels, thus serving as a protective strategy that influences the hypothalamicpituitary-adrenal axis, and the secretion of Adrenocorticotropic Hormone (ACTH). This reduction in serum corticosterone levels aligns with similar results found in previous studies.⁶6 Silva AA, Perilhão MS, Portes LA, Serra AJ, Tucci PJF, Leopoldo AS, et al. Physical exercise attenuates stress-induced hypertension in rats but not the impairments on the myocardial mechanics. J Hypertens 2022;40(3):528–35.,³⁹39 Droste SK, Gesing A, Ulbricht S, Muller MB, Linthorst ACE, Reul JMHM. Effects of long-term voluntary exercise on the mouse hypothalamic-pituitary-adrenocortical axis. Endocrinology 2003;144(7):3012–23. For instance, by Droste et al.⁴² observed substantial changes in HPA axis regulation and body composition among exercised mice. Notably, their findings included the loss of adrenal asymmetry due to adrenocortical enlargement and sympathoadrenomedullary overstimulation, indicative of potential changes in the sympathoadrenomedullary system and hormonal secretion patterns in the HPA axis. The increased circulating corticosterone levels found in exercised animals compared to controls may be considered as anticipatory and adaptive responses aimed at supporting metabolism in the face of the demand of physical activity, without concomitant increases in ACTH release by the HPA axis.⁴³ Therefore, sympathetic activity in the adrenal medulla serves as a positive modulator of adrenocortical sensitivity to ACTH. Thus, physical exercise appears to attenuate HPA axis activity in response to other stressors, providing an adaptive state with reduced ACTH stimulation,⁴³ which may explain the observed reduction in plasma corticosterone levels.

Conclusion

Animals subjected to restraint stress, even in the absence of basal glycemic alterations, exhibited impaired glycemic control, accompanied by glucose intolerance. However, this response was mitigated by physical training. Given that physical exercise is advocated by the World Health Organization and other health organizations for maintaining health, additional research is warranted to uncover its additional benefits in mitigating the adverse effects of chronic stress. Animals submitted to restraint stress, even in the absence of basal glycemic alterations, exhibited impaired glycemic control characterized by glucose intolerance. However, this alteration was mitigated by physical training. Given that physical exercise is advocated by the World Health Organization and other health organizations for maintaining health, additional research is warranted to uncover its additional benefits in mitigating the adverse effects of chronic stress.

Acknowledgments

The authors would like to thank Fundação de Amparo à Pesquisa do Espírito Santo (FAPES, grants numbers 506/2020, 637/2022, 1007/2022, 2022-VT4KM, 2022-J72BB and 2022-5SBS), Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq, grant number 307749/2021-5) and scientific assistance address to Carlos H. O. Reis. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Funding

This research received no specific grant from any funding agency in the public, commercial, or not-for-profit sectors.

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Publication Dates

Publication in this collection
16 Aug 2024
Date of issue
2024

History

Received
27 Oct 2023
Reviewed
13 Apr 2024
Accepted
28 May 2024

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] Funding

This research received no specific grant from any funding agency in the public, commercial, or not-for-profit sectors.

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