Abstract
Individual differences in physiological and biobehavioral adaptation to chronic stress are important predictors of health and fitness; genetic differences play an important role in this adaptation. To identify these differences we measured the biometric, neuroendocrine, and transcriptional response to stress among inbred mouse strains with varying degrees of genetic similarity, C57BL/6J (B), C57BL/6NJ (N), and DBA/2J (D). The B and D strains are highly genetically diverse whereas the B and N substrains are highly similar. Strain differences in hypothalamic-pituitary-adrenal (HPA) axis cross-sensitization were determined by plasma corticosterone (CORT) levels and hippocampal gene expression following 7-weeks of chronic mild stress (CMS) or normal housing (NH) and subsequent exposure to novel acute restraint. Fecal CORT metabolites and body and organ weights were also measured. All strains exposed to CMS had reduced heart weights, whereas body weight gain was attenuated only in B and N strains. Acute stress alone produced larger plasma CORT responses in the D and N strains compared to the B strain. CMS paired with acute stress produced cross-sensitization of the CORT response in the N strain. The N strain also had the largest number of hippocampal transcripts with up-regulated expression in response to stress. In contrast, the D strain had the largest number of transcripts with down-regulated expression following CMS and acute stress. In summary, we observed differential responses to CMS at both the physiological and molecular level among genetically diverse strains, indicating that genetic factors drive individual differences in experience-dependent regulation of the stress response.
Highlights
Stress is a generic term used to describe physiological and behavioral responses to real or perceived challenges (Wang et al, 2013)
Our findings reveal unique systems level responses to chronic stress in females that vary based on genotype
Identification of the genetic factors and systems level interactions driving these differences is critical for identifying susceptible populations and treatment and prevention of the adverse behavioral and health consequences associated with chronic stress
Summary
Stress is a generic term used to describe physiological and behavioral responses to real or perceived challenges (Wang et al, 2013). These responses are integrated over multiple systems (e.g., autonomic, behavioral, endocrine, and immune) with the hypothalamic-pituitaryadrenal (HPA) axis being a main pillar of the neuroendocrine response to stress. The hippocampus is a key negative regulator of HPA axis activity based on previous stress exposure and exhibits structural and functional alterations following chronic stress as well as distinct gene expression changes in response to acute or chronic stress (McEwen, 1999). The critical inhibitory role of this structure on HPA axis activity has been demonstrated through biological and genetic deletion studies (van Haarst et al, 1997; Furay et al, 2006; Herman and Mueller, 2006)
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