Early-life stress increases the survival of midbrain neurons during postnatal development and enhances reward-related and anxiolytic-like behaviors in a sex-dependent fashion.

Clinical studies have suggested that early-life stress (ELS) increases the risk of psychopathologies that are strongly associated with dysfunction of dopaminergic neurotransmission. Thus, ELS may interfere with the development and maturation of the dopaminergic system; however, the mechanisms involved in such interference are poorly understood. In the present study, we investigated the effect of ELS on the survival of specific populations of neurons in the substantia nigra pars compacta (SNc) and ventral tegmental area (VTA) during postnatal development. First, we injected bromodeoxyuridine (BrdU) into pregnant rat dams on embryonic days 12, 13 and 14 to permanently label midbrain neurons. Then, after birth, the dams and litters were subjected to a maternal separation (MS) procedure to model ELS conditions. The number of BrdU+ neurons and the total number of neurons (cresyl violet+, CV+) were estimated in both male and female juvenile, adolescent, and adult rats. Moreover, sucrose preference and anxiety-like behaviors were studied during adulthood. We found that MS permanently increased the number of BrdU+ and CV+ neurons in the VTA of males. In the SNc, a temporary increase in the number of BrdU+ neurons was observed in juvenile MS males; however, only adult MS males displayed an increase in the number of CV+ neurons. Immunofluorescence analysis implied that MS affected the fate of non-dopaminergic neurons. MS males displayed anxiolytic-like behavior and an increase in sucrose preference. These results suggest that ELS induces distinct dysregulation in the midbrain circuitry of males, which may lead to sex-specific psychopathology of the reward system.

The effects of early-life adversity on fear memories in adolescent rats and their persistence into adulthood.

Adolescence is a developmental period characterized by extensive morphological and functional remodeling of the brain. The processes of brain maturation during this period may unmask malfunctions that originate earlier in life as a consequence of early-life stress (ELS). This is associated with the emergence of many psychopathologies during adolescence, particularly affective spectrum disorders. In the present study, we applied a maternal separation (MS) procedure (3h/day, on postnatal days 1-14) as a model of ELS to examine its effects on the acquisition, expression and extinction of fear memories in adolescent rats. Additionally, we studied the persistence of these memories into adulthood. We found that MS decreased the expression of both contextual (CFC) and auditory (AFC) fear conditioning in adolescent rats. Besides, MS had no impact on the acquisition of extinction learning. During the recall of extinction MS animals both, those previously subjected and not subjected to the extinction session, exhibited equally low levels of freezing. In adulthood, the MS animals (conditioned during adolescence) still displayed impairments in the expression of AFC (only in males) and CFC. Furthermore, the MS procedure had also an impact on the expression of CFC (but not AFC) after retraining in adulthood. Our findings imply that ELS may permanently affect fear learning and memory. The results also support the hypothesis that, depending on individual predispositions and further experiences, ELS may either lead to a resilience or a vulnerability to early- and late-onsets psychopathologies.

Early-life stress affects the structural and functional plasticity of the medial prefrontal cortex in adolescent rats.

Early life experiences are crucial factors that shape brain development and function due to their ability to induce structural and functional plasticity. Among these experiences, early-life stress (ELS) is known to interfere with brain development and maturation, increasing the risk of future psychopathologies, including depression, anxiety, and personality disorders. Moreover, ELS may contribute to the emergence of these psychopathologies during adolescence. In this present study, we investigated the effects of ELS, in the form of maternal separation (MS), on the structural and functional plasticity of the medial prefrontal cortex (mPFC) and anxiety-like behavior in adolescent male rats. We found that the MS procedure resulted in disturbances in mother-pup interactions that lasted until weaning and were most strongly demonstrated by increases in nursing behavior. Moreover, MS caused atrophy of the basal dendritic tree and reduced spine density on both the apical and basal dendrites in layer II/III pyramidal neurons of the mPFC. The structural changes were accompanied by an impairment of long-term potentiation processes and increased expression of key proteins, specifically glutamate receptor 1, glutamate receptor 2, postsynaptic density protein 95, αCa(2+) /calmodulin-dependent protein kinase II and αCa(2+)/calmodulin-dependent protein kinase II phosphorylated at residue Thr305, that are engaged in long-term potentiation induction and maintenance in the mPFC. We also found that the MS animals were more anxious in the light/dark exploration test. The results of this study indicate that ELS has a significant impact on the structural and functional plasticity of the mPFC in adolescents. ELS-induced adaptive plasticity may underlie the pathomechanisms of some early-onset psychopathologies observed in adolescents.

Impact of early-life stress on the medial prefrontal cortex functions - a search for the pathomechanisms of anxiety and mood disorders.

Although anxiety and mood disorders (MDs) are the most common mental diseases, the etiologies and mechanisms of these psychopathologies are still a matter of debate. The medial prefrontal cortex (mPFC) is a brain structure that is strongly implicated in the pathophysiology of these disorders. A growing number of epidemiological and clinical studies show that early-life stress (ELS) during the critical period of brain development may increase the risk for anxiety and MDs. Neuroimaging analyses in humans and numerous reports from animal models clearly demonstrate that ELS affects behaviors that are dependent on the mPFC, as well as neuronal activity and synaptic plasticity within the mPFC. The mechanisms engaged in ELS-induced changes in mPFC function involve alterations in the developmental trajectory of the mPFC and may be responsible for the emergence of both early-onset (during childhood and adolescence) and adulthood-onset anxiety and MDs. ELS-evoked changes in mPFC synaptic plasticity may constitute an example of metaplasticity. ELS may program brain functions by affecting glucocorticoid levels. On the molecular level, ELS-induced programming is registered by epigenetic mechanisms, such as changes in DNA methylation pattern, histone acetylation and microRNA expression. Vulnerability and resilience to ELS-related anxiety and MDs depend on the interaction between individual genetic predispositions, early-life experiences and later-life environment. In conclusion, ELS may constitute a significant etiological factor for anxiety and MDs, whereas animal models of ELS are helpful tools for understanding the pathomechanisms of these disorders.

Impact of maternal separation on neural cell adhesion molecules expression in dopaminergic brain regions of juvenile, adolescent and adult rats.

Stressful experiences in the early stages of life can influence brain development and maturation, and they can also increase the risk for some psychiatric disorders; however, the specific mechanisms of this effect are still poorly understood. Neural cell adhesion molecules (NCAM 120, 140, 180 kDa) are known to play an important role in normal brain development and synaptic plasticity. Therefore, we decided to investigate whether maternal separation (MS) in rats, a paradigm which models an early life stress, has any impact on the expression of NCAM proteins in the juvenile, adolescent and adult brains of both male and female rats. Specifically, we focused our efforts on the brain regions associated with dopaminergic neurotransmission. In juvenile rats, MS decreased the levels of NCAM-140 in the substantia nigra (SN) of females and NCAM-180 in the ventral tegmental area of males. During adolescence, a reduction in NCAM-180 levels in the SN and medial prefrontal cortex (mPFC) of MS females was revealed. Finally, in adulthood, a decrease in NCAM-180 expression was observed in the mPFC of MS males. The results that we obtained indicate that early life stress can affect maturation and NCAM-driven plasticity in dopaminergic brain areas at different stages of ontogenesis and with a sex-specific manner.

Impact of postnatal dexamethasone on psychotomimetic effects of MK-801 measured on adult rats.

The present study investigates the impact of dexamethasone (DEX) given in tapering doses in the postnatal period on MK-801-induced locomotor activity and MK-801-evoked deficits of sensorimotor gating of adult rats (60 days old). It has been found that DEX given on postnatal day 1 (0.5 microg/g), day 2 (0.3 microg/g) and day 3 (0.1 microg/g) has no effects on spontaneous locomotor activity and does not influence locomotion observed after MK-801 given in a dose of 0.2 and 0.4 mg/kg. Postnatal DEX treatment did not alter the efficacy of sensorimotor gating and its deficits evoked by MK-801 at a dose of 0.2 and 0.4 mg/kg. However, a slight increase in the amplitude of startle reaction has been noted in DEX-treated animals. In conclusion, the results of the present study indicate that DEX given postnatally in tapering doses, although pharmacologically effective (decrease in a gain of body and brain weight), has no potential pro-psychotic effects and does not influence pharmacologically induced psychoses by MK-801. The above data indicate that apart from other side effects, the therapeutic application of DEX in the postnatal period is possibly safe in terms of the risk for developing schizophrenia.