Oxidative Damage Does Not Occur in Striped Hamsters Raising Natural and Experimentally Increased Litter Size.

Xiao-Ya Zhao,Zhi-Jun Zhao,Ji-Ying Zhang,Jing Cao,De-Hua Wang

doi:10.1371/journal.pone.0141604

Abstract

Life-history theory assumes that animals can balance the allocation of limited energy or resources to the competing demands of growth, reproduction and somatic maintenance, while consequently maximizing their fitness. However, somatic damage caused by oxidative stress in reproductive female animals is species-specific or is tissue dependent. In the present study, several markers of oxidative stress (hydrogen peroxide, H2O2 and malonadialdehyde, MDA) and antioxidant (catalase, CAT and total antioxidant capacity, T-AOC) were examined in striped hamsters during different stages of reproduction with experimentally manipulated litter size. Energy intake, resting metabolic rate (RMR), and mRNA expression of uncoupling protein 1 (UCP1) in brown adipose tissue (BAT) and UCP3 in skeletal muscle were also examined. H2O2 and MDA levels did not change in BAT and liver, although they significantly decreased in skeletal muscle in the lactating hamsters compared to the non-reproductive group. However, H2O2 levels in the brain were significantly higher in lactating hamsters than non-reproductive controls. Experimentally increasing litter size did not cause oxidative stress in BAT, liver and skeletal muscle, but significantly elevated H2O2 levels in the brain. CAT activity of liver decreased, but CAT and T-AOC activity of BAT, skeletal muscle and the brain did not change in lactating hamsters compared to non-reproductive controls. Both antioxidants did not change with the experimentally increasing litter size. RMR significantly increased, but BAT UCP1 mRNA expression decreased with the experimentally increased litter size, suggesting that it was against simple positive links between metabolic rate, UCP1 expression and free radicals levels. It may suggest that the cost of reproduction has negligible effect on oxidative stress or even attenuates oxidative stress in some active tissues in an extensive range of animal species. But the increasing reproductive effort may cause oxidative stress in the brain, indicating that oxidative stress in response to reproduction is tissue dependent. These findings provide partial support for the life-history theory.

Highlights

In mammals, reproduction, in lactation, is the most energetically demanding period of a female, during which a dramatic increase in food intake occurs [1]
H2O2 levels did not differ among the three groups in brown adipose tissue (BAT) and liver, whereas they differed significantly in skeletal muscle and the brain
We observed a significant change in the energy intake of striped hamsters during the different stages of reproduction, by which gross energy intake significantly increased in the hamsters during peak lactation compared to that in non-reproductive and post-lactating hamsters

Summary

Introduction

Reproduction, in lactation, is the most energetically demanding period of a female, during which a dramatic increase in food intake occurs [1]. Life-history theory assumes that animals can balance the allocation of limited energy or resources to the competing demands of growth, reproduction, and somatic maintenance while maximizing their fitness [3]. The oxidative stress life-history theory proposes that ROS are produced in direct proportion to metabolic rate as an inevitable consequence of the molecular functioning of mitochondria and the electron transport chain [10]. An animal usually has much higher metabolic rate during lactation, which may cause an increase in ROS production and result in oxidative stress [3,4,7,11,12,13,14]

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