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Physiological Stress Responses (physiological + stress_response)

Distribution by Scientific Domains
Life Sciences50%

Selected Abstracts

Physiological stress responses in defensive individuals: Age and sex matter

PSYCHOPHYSIOLOGY, Issue 2 2010
Karine Lévesque
Abstract The association between defensiveness and physiological responses to stress were evaluated in 81 healthy working men and 118 women, aged 20 to 64 years (M=41; SD=11.45). Participants underwent laboratory testing during which they were exposed to interpersonal stressors. Heart rate (HR), heart rate variability (HRV), blood pressure (BP), and salivary cortisol were measured. Defensiveness was evaluated using the Marlowe-Crowne Social Desirability Scale. In women, higher defensiveness was associated with greater BP and HR reactivity to stress (p<.05). In older men, lower defensiveness was associated with increased systolic BP reactivity to stress (p<.02), delayed HRV recovery (p<.02), and greater salivary cortisol levels (p<.02). In conclusion, greater defensiveness was associated with increased reactivity to stress in women whereas in older men, lower defensiveness was associated with elevated cardiovascular, autonomic, and endocrine responses to stress. [source]

Comprehensive proteomic and transcriptomic analysis reveals early induction of a protective anti-oxidative stress response by low-dose proteasome inhibition

PROTEINS: STRUCTURE, FUNCTION AND BIOINFORMATICS, Issue 12 2009
Sven Bieler
Abstract Effective inhibition of the proteasome by high doses of proteasome inhibitors induces apoptotic cell death. In contrast, partial proteasome inhibition by low inhibitor doses mediates a protective cellular stress response. The early targets and mediators of these dose-dependent effects of proteasome inhibitors are unknown. Primary human umbilical cord vein endothelial cells were treated with low and high doses of the proteasome inhibitor MG132 for 2,h. In a combined 2-DE and MS approach, we identified more than 20 new targets of proteasome inhibition. These proteins are involved in cell cycle regulation, signaling, cytoskeletal rearrangement, and cellular stress response. Accompanying Affymetrix analysis revealed that these proteins are not regulated on the transcriptional level but are mainly stabilized by proteasome inhibition. The proteasome-dependent accumulation of the anti-oxidative sensor proteins DJ-1, peroxiredoxin-1 and -6 was accompanied by dose-dependent induction of oxidative stress after 2,h of proteasome inhibition and contributed to the differential transcriptional stress response to low- and high-dose proteasome inhibition: Whereas low-dose proteasome inhibition induces a transcriptional profile reminiscent of a physiological stress response that preconditions and protects endothelial cells from oxidative stress, high inhibitor doses induce massive transcriptional dysregulation and pronounced oxidative stress triggering apoptosis. [source]

In situ on-line toxicity biomonitoring in water: Recent developments

ENVIRONMENTAL TOXICOLOGY & CHEMISTRY, Issue 9 2006
Almut Gerhardt
Abstract ,In situ on-line biomonitoring is an emerging branch of aquatic biomonitoring. On-line biomonitoring systems use behavioral and/or physiological stress responses of caged test organisms exposed in situ either in a bypass system or directly instream. Sudden pollution waves are detected by several existing single-species on-line biomonitors, which until now have been placed mostly in streamside laboratories. However, recent achievements have been multispecies biomonitors, mobile biomonitors for direct in-stream use, development of new instruments, new methods for data analysis and alarm generation, biomonitors for use in soil and sediment, and scientific research supporting responses as seen in on-line biomonitors by linking them to other biological and ecological effects. Mobile on-line monitoring platforms containing an array of biomonitors, biosensors, and chemical monitoring equipment might be the future trend, especially in monitoring transboundary rivers at country borders as well as in coastal zones. [source]

The impact of mineralocorticoid receptor ISO/VAL genotype (rs5522) and stress on reward learning

GENES, BRAIN AND BEHAVIOR, Issue 6 2010
R. Bogdan
Research suggests that stress disrupts reinforcement learning and induces anhedonia. The mineralocorticoid receptor (MR) determines the sensitivity of the stress response, and the missense iso/val polymorphism (Ile180Val, rs5522) of the MR gene (NR3C2) has been associated with enhanced physiological stress responses, elevated depressive symptoms and reduced cortisol-induced MR gene expression. The goal of these studies was to evaluate whether rs5522 genotype and stress independently and interactively influence reward learning. In study 1, participants (n = 174) completed a probabilistic reward task under baseline (i.e. no-stress) conditions. In study 2, participants (n = 53) completed the task during a stress (threat-of-shock) and no-stress condition. Reward learning, i.e. the ability to modulate behavior as a function of reinforcement history, was the main variable of interest. In study 1, in which participants were evaluated under no-stress conditions, reward learning was enhanced in val carriers. In study 2, participants developed a weaker response bias toward a more frequently rewarded stimulus under the stress relative to no-stress condition. Critically, stress-induced reward learning deficits were largest in val carriers. Although preliminary and in need of replication due to small sample size, findings indicate that psychiatrically healthy individuals carrying the MR val allele, gene, which has been recently linked to depression, showed a reduced ability to modulate behavior as a function of reward when facing an acute, uncontrollable stressor. Future studies are warranted to evaluate whether rs5522 genotype interacts with naturalistic stressors to increase the risk of depression and whether stress-induced anhedonia might moderate such risk. [source]

Anxiety, cortisol, and attachment predict plasma oxytocin

PSYCHOPHYSIOLOGY, Issue 3 2007
Mattie Tops
Abstract Oxytocin and attachment seem to interact in suppressing subjective anxiety and physiological stress responses. In this study we investigated the relationships between individual differences in trait attachment scores, state and trait anxiety, plasma cortisol, and plasma oxytocin levels in healthy premenopausal women. Attachment proved to be a strong positive predictor of oxytocin levels, which were also positively predicted by cortisol levels and state and trait anxiety. The relationship between oxytocin and state anxiety was modulated by attachment scores. The present results may help interpreting seeming contradictions in the recent literature on oxytocin, attachment, and stress in humans, by suggesting that context effects determine which relationships are found in different studies: anxiolytic effects of oxytocin in a context of partner support versus stress- or cortisol-induced oxytocin responses in a context of distress or increased cortisol. [source]

Physiological responses of young cross-bred calves immediately after long-haul road transportation and after one week of habituation

ANIMAL SCIENCE JOURNAL, Issue 6 2009
Katsuji UETAKE
ABATRACT We investigated 10 suckling cross-bred calves (Japanese Black (Wagyu) × Holstein) and collected data on the physiological stress responses of the young calves to long-haul road transportation. All calves were male and 21,47 days of age. The calves were obtained at a livestock market and were transported from the market to the university in a commercial livestock vehicle. The total haul distance and time were 306.9 km and 7 h, respectively. The calves were deprived of food and water during transportation. Blood samples, electrocardiograms, and rectal temperatures were collected immediately after transportation and after one week of habituation at the university. Serum pH was significantly lower (P < 0.01), while serum triiodothyronine, aspartate aminotransferase, non-esterified fatty acids (all P < 0.05), and heart rate (P < 0.01) were significantly higher immediately after transportation. The concentrations of blood lactic acid (P = 0.08) and serum alanine aminotransferase (P = 0.06) tended to be higher after transportation. These physiological responses suggest that the stress caused by long-haul transportation causes significant effects on liver function in young calves. [source]