Individual Differences In Expression Research Articles

Cellular mechanisms underlying the development and expression of individual differences in the hypothalamic-pituitary-adrenal stress response

Several years ago Levine, Denenberg, Ader, and others described the effects of postnatal “handling” on the development of behavioral and endocrine responses to stress. As adults, handled rats exhibited attenuated fearfulness in novel environments and a less pronounced increase in the secretion of the adrenal glucocorticoids in response to a variety of stressors. These findings clearly demonstrated that the development of rudimentary, adaptive responses to stress could be modified by environmental events. We have followed these earlier studies, convinced that this paradigm provides a marvellous opportunity to examine how subtle variations in the early environment alter the development of specific neurochemical systems, leading to stable individual differences in biological responses to stimuli that threaten homeostasis. In this work we have shown how early handling influences the development of certain brain regions that regulate glucocorticoid negative-feedback inhibition over hypothalamic-pituitary-adrenal (HPA) activity. Specifically, handling increases glucocorticoid (type II corticosteroid) receptor density in the hippocampus and frontal cortex, enhancing the sensitivity of these structures to the negative-feedback effects of elevated circulating glucocorticoids, and increasing the efficacy of neural inhibition over ACTH secretion. These effects are reflected in the differential secretory pattern of ACTH and corticosterone in handled and nonhandled animals under conditions of stress. In more recent years, using a hippocampal cell culture system, we have provided evidence for the importance of serotonin-induced changes in cAMP levels in mediating the effect of postnatal handling on hippocampal glucocorticoid receptor density. The results of these studies are consistent with the idea that environmental events in early life can permanently alter glucocorticoid receptor gene expression in the hippocampus, providing evidence for a neural mechanism for the development of individual differences in HPA function.

Differential effects of an early housing manipulation on cocaine-induced activity and self-administration in laboratory rats

Several reports in the literature suggested that environmental influences which are reflected in the social housing conditions of the rat may play a role in the expression of individual differences in drug self-administration. The present experiments were performed in order to further examine the effects of early housing manipulations, as reflected by grouped or isolation housing, on cocaine-induced behavioral responding. The first study examined the effects of this manipulation on the locomotor stimulant properties of cocaine. The results suggested that grouped housing produced a significantly greater increase in cocaine-induced locomotion than was observed in animals housed in isolation. Experiment 2 examined the effects of housing manipulations on the self-administration of cocaine under a continuous reinforcement schedule. Differences in the rate of cocaine self-administration were only observed at the lowest dose tested. Responding at all other doses was equivalent, including the optimal dose for both groups, suggesting that the housing manipulations failed to affect the reinforcing efficacy of cocaine. The present investigation suggests that, while the early housing manipulation produced a differential sensitivity in rats to the stimulant properties of cocaine, the same manipulation failed to alter the sensitivity of rats to the reinforcing properties of cocaine as assessed through self-administration.

Aromatase activity in quail brain: correlation with aggressiveness.

Testosterone (T) triggers aggressive behavior in males of many vertebrate species; however, the neural and hormonal basis of individual differences in the frequency or intensity of aggressive behavior is still debated. Using the Japanese quail (Coturnix coturnix japonica), a species in which individuals exhibit a wide range of aggressiveness in nature and the laboratory, together with a newly devised test procedure for quantifying aggressiveness, we recently demonstrated that aggression is estrogen dependent. Here we extend these studies by testing the hypothesis that aromatization in brain is a rate-limiting step in the expression of individual differences in aggressiveness. Using procedures previously validated for this species, aromatase and 5 alpha- and 5 beta-reductase activities were estimated in selected brain regions of reproductively active male quail by measuring conversion of [3H]androstenedione to [3H]estrone, [3H]5 alpha-androstanedione, and [3H]5 beta-androstanedione, respectively. In Exp 1, behaviorally inexperienced test birds were killed 90 sec after a single behavioral test. Aggressiveness of individuals in this group, as determined by pecking and locomotor activity in response to visualization of a conspecific, ranged 3- to 4-fold from high to low. Aromatase activity in the posterior hypothalamus (PHYP) was significantly higher in males rated high for aggressiveness than in animals rated low (1.04 vs. 0.59 pmol/h.mg protein; P less than 0.02). Similar differences were observed in the anterior hypothalamus/preoptic area (AHPOA) but were not significant. In Exp 2, sexually mature males were behaviorally tested eight times over 22 days and killed 24 h after the final test. Aggressiveness varied 5-fold from high to low, although the rating in a given bird remained constant with time and repeat testing. Aromatase activity in the AHPOA was significantly greater in birds rated high for aggressiveness than in low aggressiveness birds (3.77 vs. 2.80 pmol/h.mg protein; P less than 0.02). In addition, when AHPOA aromatase in all birds was plotted against behavioral intensity, there was a 2-fold variation and a significant positive correlation (r = 0.556; P less than 0.02). Similar differences were observed in PHYP, but these were of borderline significance. By contrast, aromatase levels outside the AHPOA and PHYP were unrelated to behavior. Moreover, in both Exp 1 and 2, 5 alpha- and 5 beta-reductase activities in AHPOA, PHYP, and other brain regions; plasma T, 5 alpha-dihydrotestosterone, and total estrogens; and relative testicular weights were not consistently related to aggression.(ABSTRACT TRUNCATED AT 400 WORDS)

Strabismus: factors in anticipating its occurrence.

Summary The genetic approach familiar to most clinicians is the Mendelian (or qualitative) approach, while quantitative genetics is still a generally unfamiliar one. However, quantitative genetics can be an extremely useful method for the study of continuously varying characteristics, including both human abnormalities and normal ranges of expression of individual differences This report is a summary of studies using quantitative genetics to determine if there is a relationship between genetic factors influencing ocular functions, as measured by clinical examination, and genetic factors influencing the occurrence of strabismus The purpose of this was to provide a means to predict the probability of the occurrence of strabismus in offspring of “nonaffected” parents. In this study, at least two measures appear to have some predictive value: reduced vergence ability and refractive errors In practical terms, this means that parents who collectively have both very low vergence ability and refractive errors, even though neither manifests strabismus, could be advised that any offspring are at risk for strabismus and therefore should be examined at a very early age The potential for early identification of individuals with unaffected parents who are at risk for certain abnormalities is sufficient to make application of quantitative genetics worthwhile in clinical medicine.