Influence of Acute Exercise on DNA Repair and PARP Activity before and after Irradiation in Lymphocytes from Trained and Untrained Individuals.

Maria Moreno-Villanueva,Tabea Hammes,Alexander Bürkle,Markus Gruber,Patrick Thumm,Andreas Kramer,Maria Venegas-Carro

doi:10.3390/ijms20122999

Maria Moreno-Villanueva, Tabea Hammes + Show 5 more

Open Access

https://doi.org/10.3390/ijms20122999

Copy DOI

Abstract

Several studies indicate that acute exercise induces DNA damage, whereas regular exercise increases DNA repair kinetics. Although the molecular mechanisms are not completely understood, the induction of endogenous reactive oxygen species (ROS) during acute exhaustive exercise due to metabolic processes might be responsible for the observed DNA damage, while an adaptive increase in antioxidant capacity due to regular physical activity seems to play an important protective role. However, the protective effect of physical activity on exogenously induced DNA damage in human immune cells has been poorly investigated. We asked the question whether individuals with a high aerobic capacity would have an enhanced response to radiation-induced DNA damage. Immune cells are highly sensitive to radiation and exercise affects lymphocyte dynamics and immune function. Therefore, we measured endogenous and radiation-induced DNA strand breaks and poly (ADP-ribose) polymerase-1 (PARP1) activity in peripheral blood mononuclear cells (PBMCs) from endurance-trained (maximum rate of oxygen consumption measured during incremental exercise V’O2max > 55 mL/min/kg) and untrained (V’O2max < 45 mL/min/kg) young healthy male volunteers before and after exhaustive exercise. Our results indicate that: (i) acute exercise induces DNA strand breaks in lymphocytes only in untrained individuals, (ii) following acute exercise, trained individuals repaired radiation-induced DNA strand breaks faster than untrained individuals, and (iii) trained subjects retained a higher level of radiation-induced PARP1 activity after acute exercise. The results of the present study indicate that increased aerobic fitness can protect immune cells against radiation-induced DNA strand breaks.

Highlights

Regular physical exercise has many health benefits including greater longevity and a reduced risk of cardiovascular disease (CVD), and in particular, coronary heart disease (CHD), stroke, and cancer [1]
We found no difference in endogenous DNA strand breaks between trained and untrained individuals before exercise
We showed that immune cells from endurance-trained individuals with a Ihnigthheerpareesroenbticstcuadpya,cwitye s(Vho’Ow2emdaxth>a5t5immmLu/mneinc/eklgls) frreopmaierendduthraenecxe-vtriavionreaddiinadtiiovnid-iunadlus cwedithDaNA higshterarnaderborbeiackcsa“pfaacsitteyr”(Vth’Oan2muaxn>tr5a5inmedL/imndiniv/kidgu) arlespwaiirtehdlothweaeexrovibvioc rcaadpiaactiitoyn(-Vin’Odu2mceadx

Summary

Introduction

Regular physical exercise has many health benefits including greater longevity and a reduced risk of cardiovascular disease (CVD), and in particular, coronary heart disease (CHD), stroke, and cancer [1]. Endurance exercise, including high-intensity training, has considerable benefits in healthy young and elderly individuals; for example, it has been argued that it improves cardiorespiratory fitness, promotes longevity, slows down aging [3], attenuates age-related reduction in muscle strength [4], and improves visuospatial, verbal memory, and concentration performance in young healthy adults [5]. Resistance exercise provides astronauts with an effective protection against decreases in body mass, muscle strength, bone mass, and aerobic capacity [6]. Several studies have investigated the connection between exercise and DNA repair, suggesting an enhanced DNA repair through regular exercise [9] and a protective effect against radiation-induced DNA damage [10,11,12]. We evaluated similar parameters in lymphocytes derived from trained versus untrained individuals

Objectives

Results

Discussion

Conclusion