Yulia A. Ryabushkina

Bio: Yulia A. Ryabushkina is an academic researcher from Russian Academy of Sciences. The author has contributed to research in topics: Offspring & Aggression. The author has an hindex of 2, co-authored 5 publications receiving 12 citations. Previous affiliations of Yulia A. Ryabushkina include Novosibirsk State University.

Repeated and single maternal separation specifically alter microglial morphology in the prefrontal cortex and neurogenesis in the hippocampus of 15-day-old male mice.

Abstract: Early-life adversity impairs neuronal plasticity of the developing brain. In rodents, brain maturation processes, including neuro- and synaptogenesis, myelination, microglial maturation, and hypothalamic-pituitary-adrenal (HPA) axis development continue in the postnatal period. In our study, two models of early-life stress were used: repeated maternal separation (MS) from postnatal day (PND) 2 to PND14 for 3 h daily and single maternal deprivation (MD) on PND9 for 24 h. Effects of each type of early-life stress on neuron density, neurogenesis, microglial morphology, and HPA axis programming were studied in 15-day-old male mice. Neither early-life stress paradigm affected the expression of stress-related genes (Crh, Avp, Crhr1, Crhr2, Nr3c1, and Nr3c2) and the serum level of corticosterone on PND15. Immunohistochemical analysis was performed on slices of the hippocampus and prefrontal cortex (PFC) with antibodies against a marker of mature neurons (NeuN), of microglia (Iba1), proliferating cells (Ki67), and immature neurons (DCX). We found higher density of ameboid microglia and intermediate microglia in the PFC in groups MS and MD, respectively, than in a control group. In both stressed groups, a higher number of Ki67-positive cells was noted in the dentate gyrus. Thus, in mice, the process of transformation of ameboid microglia into ramified ones as well as a neurogenesis reduction take place during the second postnatal week, whereas early-life stress can disturb these processes in a stress- and region-dependent manner.

Impact of mothers’ experience and early‐life stress on aggression and cognition in adult male mice

Abstract: The postnatal period is important for brain development and behavioral programming. Here, we hypothesized that females' stressful experience early in life can lead to disruption of mother-offspring interactions with their own progeny. The objective of this study was to assess the effects of mothers' stressful experience, early-life stress, or both on the behavior of adult male mice. In this study, female mice were allowed to raise their pups either without exposure to stress (normal rearing conditions, NC) or with exposure to maternal separation (3 hr/day, maternal separation, MS). Adult F1 female mice who had experienced MS (stressed mothers, SM) or had been reared normally (undisturbed mothers, UM) were used for generating F2 offspring, which was then exposed (or not exposed) to early-life stress. We assessed anxiety-like behavior, exploratory activity, locomotor activity, aggression, and cognition in four groups of adult F2 males (UM+NC, UM+MS, SM+NC, and SM+MS). We found that SM+MS males become more aggressive if agonistic contact is long enough; these results point to a change in their social coping strategy. Moreover, these aggressive males tended to show better long-term spatial memory. Overall, our findings suggest that mothers' early-life experience may have important implications for the adult behavior of their offspring.

Unique Features of the Immune Response in BTBR Mice

Abstract: Inflammation plays a considerable role in the pathogenesis of many diseases, including neurodegenerative and psychiatric ones. Elucidation of the specific features of an immune response in various model organisms, and studying the relation of these features with the behavioral phenotype, can improve the understanding of the molecular mechanisms of many psychopathologies. In this work, we focused on BTBR mice, which have a pronounced autism-like behavioral phenotype, elevated levels of oxidative-stress markers, an abnormal immune response, several structural aberrations in the brain, and other unique traits. Although some studies have already shown an abnormal immune response in BTBR mice, the existing literature data are still fragmentary. Here, we used inflammation induced by low-dose lipopolysaccharide, polyinosinic:polycytidylic acid, or their combinations, in mice of strains BTBR T+Itpr3tf/J (BTBR) and C57BL6/J. Peripheral inflammation was assessed by means of a complete blood count, lymphocyte immunophenotyping, and expression levels of cytokines in the spleen. Neuroinflammation was evaluated in the hypothalamus and prefrontal cortex by analysis of mRNA levels of proinflammatory cytokines (tumor necrosis factor, Tnf), (interleukin-1 beta, Il-1β), and (interleukin-6, Il-6) and of markers of microglia activation (allograft inflammatory factor 1, Aif1) and astroglia activation (glial fibrillary acidic protein, Gfap). We found that in both strains of mice, the most severe inflammatory response was caused by the administration of polyinosinic:polycytidylic acid, whereas the combined administration of the two toll-like receptor (TLR) agonists did not enhance this response. Nonetheless, BTBR mice showed a more pronounced response to low-dose lipopolysaccharide, an altered lymphocytosis ratio due to an increase in the number of CD4+ lymphocytes, and high expression of markers of activated microglia (Aif1) and astroglia (Gfap) in various brain regions as compared to C57BL6/J mice. Thus, in addition to research into mechanisms of autism-like behavior, BTBR mice can be used as a model of TLR3/TLR4-induced neuroinflammation and a unique model for finding and evaluating the effectiveness of various TLR antagonists aimed at reducing neuroinflammation.

Early Life Adversity and Neuropsychiatric Disease: Differential Outcomes and Translational Relevance of Rodent Models

Abstract: It is now well-established that early life adversity (ELA) predisposes individuals to develop several neuropsychiatric conditions, including anxiety disorders, and major depressive disorder. However, ELA is a very broad term, encompassing multiple types of negative childhood experiences, including physical, sexual and emotional abuse, physical and emotional neglect, as well as trauma associated with chronic illness, family separation, natural disasters, accidents, and witnessing a violent crime. Emerging literature suggests that in humans, different types of adverse experiences are more or less likely to produce susceptibilities to certain conditions that involve affective dysfunction. To investigate the driving mechanisms underlying the connection between experience and subsequent disease, neuroscientists have developed several rodent models of ELA, including pain exposure, maternal deprivation, and limited resources. These studies have also shown that different types of ELA paradigms produce different but somewhat overlapping behavioral phenotypes. In this review, we first investigate the types of ELA that may be driving different neuropsychiatric outcomes and brain changes in humans. We next evaluate whether rodent models of ELA can provide translationally relevant information regarding links between specific types of experience and changes in neural circuits underlying dysfunction.

Repeated and single maternal separation specifically alter microglial morphology in the prefrontal cortex and neurogenesis in the hippocampus of 15-day-old male mice.

Abstract: Early-life adversity impairs neuronal plasticity of the developing brain. In rodents, brain maturation processes, including neuro- and synaptogenesis, myelination, microglial maturation, and hypothalamic-pituitary-adrenal (HPA) axis development continue in the postnatal period. In our study, two models of early-life stress were used: repeated maternal separation (MS) from postnatal day (PND) 2 to PND14 for 3 h daily and single maternal deprivation (MD) on PND9 for 24 h. Effects of each type of early-life stress on neuron density, neurogenesis, microglial morphology, and HPA axis programming were studied in 15-day-old male mice. Neither early-life stress paradigm affected the expression of stress-related genes (Crh, Avp, Crhr1, Crhr2, Nr3c1, and Nr3c2) and the serum level of corticosterone on PND15. Immunohistochemical analysis was performed on slices of the hippocampus and prefrontal cortex (PFC) with antibodies against a marker of mature neurons (NeuN), of microglia (Iba1), proliferating cells (Ki67), and immature neurons (DCX). We found higher density of ameboid microglia and intermediate microglia in the PFC in groups MS and MD, respectively, than in a control group. In both stressed groups, a higher number of Ki67-positive cells was noted in the dentate gyrus. Thus, in mice, the process of transformation of ameboid microglia into ramified ones as well as a neurogenesis reduction take place during the second postnatal week, whereas early-life stress can disturb these processes in a stress- and region-dependent manner.

How early maternal deprivation changes the brain and behavior

Abstract: Early life stress can adversely influence brain development and reprogram brain function and consequently behavior in adult life. Adequate maternal care in early childhood is therefore particularly important for the normal brain development, and adverse early life experiences can lead to altered emotional, behavioral, and neuroendocrine stress responses in the adulthood. As a form of neonatal stress, maternal deprivation/separation is often used in behavioral studies to examine the effects of early life stress and for modeling the development of certain psychiatric disorders and brain pathologies in animal models. The temporary loss of maternal care during the critical postpartum periods remodels the offspring's brain and provokes long-term effects on learning and cognition, the development of mental disorders, aggression, and an increased tendency for the drug abuse. Early life stress through maternal deprivation affects neuroendocrine responses to stress in adolescence and adulthood by dysregulating the hypothalamic-pituitary-adrenal axis and permanently disrupts stress resilience. In this review, we focused on how improper maternal care during early postnatal life affects brain development resulting in modified behavior later in life.

Maternal Separation Early in Life Alters the Expression of Genes Npas4 and Nr1d1 in Adult Female Mice: Correlation with Social Behavior.

Abstract: Early-life stress affects neuronal plasticity of the brain regions participating in the implementation of social behavior. Our previous studies have shown that brief and prolonged separation of pups from their mothers leads to enhanced social behavior in adult female mice. The goal of the present study was to characterize the expression of genes (which are engaged in synaptic plasticity) Egr1, Npas4, Arc, and Homer1 in the prefrontal cortex and dorsal hippocampus of adult female mice with a history of early-life stress. In addition, we evaluated the expression of stress-related genes: glucocorticoid and mineralocorticoid receptors (Nr3c1 and Nr3c2) and Nr1d1, which encodes a transcription factor (also known as REVERBα) modulating sociability and anxiety-related behavior. C57Bl/6 mice were exposed to either maternal separation (MS, 3 h once a day) or handling (HD, 15 min once a day) on postnatal days 2 through 14. In adulthood, the behavior of female mice was analyzed by some behavioral tests, and on the day after the testing of social behavior, we measured the gene expression. We found increased Npas4 expression only in the prefrontal cortex and higher Nr1d1 expression in both the prefrontal cortex and dorsal hippocampus of adult female mice with a history of MS. The expression of the studied genes did not change in HD female mice. The expression of stress-related genes Nr3c1 and Nr3c2 was unaltered in both groups. We propose that the upregulation of Npas4 and Nr1d1 in females with a history of early-life stress and the corresponding enhancement of social behavior may be regarded as an adaptation mechanism reversing possible aberrations caused by early-life stress.