Expression of DNA repair genes and its relevance for DNA repair in peripheral immune cells of patients with posttraumatic stress disorder.

Posttraumatic stress disorder (PTSD) involves elevated levels of cellular oxidative stress which jeopardizes the integrity of essential cell compartments. Previously, we demonstrated higher levels of DNA lesions in peripheral blood mononuclear cells (PBMCs) in PTSD. Retaining vital levels of DNA integrity requires cells to mobilize compensatory efforts in elevating their DNA-repair capacity. Accordingly, we hypothesized to find increased expression rates of the DNA-repair genes X-ray repair cross complementing 1 (XRCC1), poly (ADP-ribose) polymerase 1 (PARP1), and polymerase ß (Polß) in PBMCs of PTSD patients as compared to controls, leading to functionally relevant changes in DNA-repair kinetics. In a cohort of 14 refugees with PTSD and 15 without PTSD, we found significantly higher XRCC1 expression in PTSD patients than controls (U = 161.0, p = 0.009, Cohen's r = 0.49), and positive correlations between the severity of PTSD symptoms and the expression of XRCC1 (rS = 0.57, p = 0.002) and PARP1 (rS = 0.43, p = 0.022). Higher XRCC1 (F = 2.39, p = 0.010, η2p = 0.10) and PARP1 (F = 2.15, p = 0.022, η2p = 0.09) expression accounted for slower repair of experimentally X-ray irradiation-induced DNA damage, highlighting the possible physiological relevance of altered DNA-repair gene expression in PTSD. Our study provides first evidence for a compensatory regulation of DNA-repair mechanisms in PTSD. We discuss the implications of increased DNA damage and altered DNA-repair mechanisms in immune senescence, premature aging, and increased physical morbidity in PTSD.

The burden of overweight: Higher body mass index, but not vital exhaustion, is associated with higher DNA damage and lower DNA repair capacity.

BACKGROUND/OBJECTIVES: DNA damage and the capacity to repair damaged DNA have been associated with the pathogenesis of several diseases such as cancer. While it is well known that external mutagenic agents can induce DNA damage, less is known about endogenous contributors to genomic instability. The aim of this study was to investigate whether excess body weight as a physiological factor and vital exhaustion as a psychological factor would be associated with basal levels of DNA damage as well as DNA repair capacity. SUBJECTS/METHODS: In a cross-sectional between-subject design we recruited 53 apparently healthy men within the normal to non-obese overweight range (mean BMI: 25.2 ± 0.5) who were either vitally exhausted (VE) (VE-score ≥ 10) or non-exhausted (VE-score ≤ 3). Vital exhaustion was assessed using the Maastricht Vital Exhaustion Questionnaire. We assessed DNA damage and repair in terms of strand breaks in PBMCs by means of the automated Fluorimetric Detection of Alkaline Unwinding (FADU) assay. DNA repair capacity was assessed by repeatedly measuring the amount of intact DNA up to 90 min after standardized X-irradiation of the cells. RESULTS: General linear models revealed that elevated levels of basal DNA damage (ß=-0.34, p=0.013, f=0.33) as well as impaired capacity to repair damaged DNA (F(1/50)=5.40, p=0.024, f=0.33) with increasing BMI, but not with vital exhaustion (p's ≥ 0.63). CONCLUSION: Our findings point to DNA integrity impairments with increasing BMI, already in the overweight range, and suggest impaired DNA repair as a potential underlying molecular mechanism. In contrast, the psychological factor vital exhaustion was not associated with DNA damage or DNA repair capacity.

Kinetics and Interrelations of the Renin Aldosterone Response to Acute Psychosocial Stress: A Neglected Stress System.

CONTEXT: The renin-angiotensin-aldosterone system (RAAS) plays an important role in cardiovascular homeostasis and its dysfunction relates to negative health consequences. Acute psychosocial stress seems to activate the RAAS in humans, but stress kinetics and interrelations of RAAS parameters compared with a nonstress control group remain inconclusive. OBJECTIVE: We systematically investigated in a randomized placebo-controlled design stress kinetics and interrelations of the reactivity of RAAS parameters measured in plasma and saliva to standardized acute psychosocial stress induction. METHODS: 58 healthy young men were assigned to either a stress or a placebo control group. The stress group underwent the Trier Social Stress Test (TSST), while the control group underwent the placebo TSST. We repeatedly assessed plasma renin, and plasma and salivary aldosterone before and up to 3 hours after stress/placebo. We simultaneously assessed salivary cortisol to validate successful stress induction and to test for interrelations. RESULTS: Acute psychosocial stress induced significant increases in all endocrine measures compared with placebo-stress (all P ≤ .041). Highest renin levels were observed 1 minute after stress, and highest aldosterone and cortisol levels 10 and 20 minutes after stress, with salivary aldosterone starting earlier at 1 minute after stress. Renin completed recovery at 10 minutes, cortisol at 60 minutes, salivary aldosterone at 90 minutes, and plasma aldosterone at 180 minutes after stress. Stress increase scores of all endocrine measures related to each other, as did renin and cortisol areas under the curve with respect to increase (AUCi) and salivary and plasma aldosterone AUCi (all P ≤ .047). CONCLUSIONS: Our findings suggest that in humans acute psychosocial stress induces a differential and interrelated RAAS parameter activation pattern. Potential implications for stress-related cardiovascular risk remain to be elucidated.