Postnatal Day Research Articles

Leptin reduces LPS‐induced A1 reactive astrocyte activation and inflammation via inhibiting p38‐MAPK signaling pathway

AbstractNeurotoxic A1 reactive astrocytes are induced by inflammatory stimuli. Leptin has been confirmed to have neuroprotective properties. However, its effect on the activation of A1 astrocytes in infectious inflammation is unclear. In the current study, astrocytes cultured from postnatal day 1 Sprague–Dawley rats were stimulated with lipopolysaccharide (LPS) to induce an acute in vitro inflammatory response. Leptin was applied 6 h later to observe its protective effects. The viability of the astrocytes was assessed. A1 astrocyte activation was determined by analyzing the gene expression of C3, H2‐D1, H2‐T23, and Serping 1 and secretion of pro‐inflammatory cytokines IL‐6 and TNF‐α. The levels of phospho‐p38 (pp38) and nuclear factor‐κB (NF‐κB) phosphor‐p65 (pp65) were measured to explore the possible signaling pathways. Additionally, an LPS‐induced inflammatory animal model was established to investigate the in vivo effects of leptin on A1 astrocytic activation. Results showed that in the in vitro culture system, LPS stimulation caused elevated expression of A1 astrocyte‐specific genes and the secretion of pro‐inflammatory cytokines, indicating the activation of A1 astrocytes. Leptin treatment significantly reversed the LPS induced upregulation in a dose‐dependent manner. Similarly, LPS upregulated pp38, NF‐κB pp65 protein and inflammatory cytokines were successfully reduced by leptin. In the LPS‐induced animal model, the amelioratory effect of leptin on A1 astrocyte activation and inflammation was further confirmed, showed by the reduced sickness behaviors, A1 astrocyte genesis and inflammatory cytokines in vivo. Our results demonstrate that leptin efficiently inhibits LPS‐induced neurotoxic activation of A1 astrocytes and neuroinflammation by suppressing p38‐MAPK signaling pathway.

Postnatal Enrichment Corrects Deficits in Perineuronal Net Formation and Reversal Learning in Adult Mice Exposed to Early Adversity.

Childhood neglect is associated with cortical thinning, hyperactivity, and deficits in cognitive flexibility that are difficult to reverse later in life. Despite being the most prevalent form of early adversity, little is currently understood about the mechanisms responsible for these neurodevelopmental abnormalities, and no animal models have yet replicated key structural and behavioral features of childhood neglect/deprivation. To address these gaps, we have recently demonstrated that mice exposed to impoverished conditions, specifically limited bedding (LB), exhibit behavioral and structural changes that resemble those observed in adolescents who have experienced severe neglect. Here, we show that LB leads to long-term deficits in reversal learning, which can be fully reversed by briefly exposing LB pups to enrichment (toys) in their home cage from postnatal days 14 to 25. Reversal learning failed to induce normal c-fos activation in the orbitofrontal cortex (OFC) of LB mice, a deficit that was normalized by early enrichment. Additionally, LB decreased the density of parvalbumin-positive cells surrounded by perineuronal nets (PV+PNN+) and increased the ratio of glutamatergic to inhibitory synapse densities in the OFC, deficits that were also reversed by enrichment. Degradation of PNN in the OFC of adult mice impaired reversal learning, reduced c-fos activation, and increased the ratio of glutamatergic to inhibitory synapse densities in the OFC to levels comparable to those observed in LB mice. Collectively, our findings suggest that postnatal deprivation and enrichment impact the formation of PV+PNN+ cells in the OFC, a developmental process that is essential for cognitive flexibility in adulthood.

Temporal Regulation of Myopia and Inflammation-Associated Pathways in the Interphotoreceptor Retinoid-Binding Protein Knockout Mouse Model

Purpose Myopia is a complex disorder with etiology involving an interplay between several genetic and environmental factors. Interphotoreceptor retinoid-binding protein (IRBP) is found in the subretinal space and is crucial in the visual cycle. The interphotoreceptor retinoid-binding protein knockout mouse (IRBP KO) was established as a model system to understand myopia and retinal degeneration. The current study investigated genes associated with myopia, retinal homeostasis, and inflammation in IRBP KO. Methods RNA from retinas of congenic IRBP KO and wild-type C57BL/6J (WT) mice at postnatal day 5 (P5), P40, and P213 were subjected to digital droplet PCR (ddPCR) using a Bio-Rad automated droplet generator and QX200 reader. Target genes were selected based on genome-wide association studies, animal models, myopia studies, and other genes associated with retinal homeostasis and inflammation. HPRT, a housekeeping gene, was used for normalization. An average expression ratio (target/HPRT) and standard deviation (SD) were calculated. ANOVA assessed statistical significance, and a p < 0.05 was considered significant. Results The ddPCR data analysis indicated that numerous myopia and inflammation-associated genes were differentially regulated in IRBP KO retinas with distinct temporal variation (upregulated at P5, decreased at P40, and no change at P213 relative to WT). C1qa, Gjd2, Sntb1, and Vsx2 emerged as top genetic candidate pathways. Compared with WT, immunoblotting analysis of C1qa showed no significant differences at P5 but significantly increased protein levels at P7 in IRBP KOs. Vsx2 remained unaltered at P5 and P7 in KO when compared with WT. Conclusions Data analysis indicated significant contributions from C1q, Gjd2, Sntb1, and Vsx2 genes in IRBP deficiency.

WDR64, a testis-specific protein, is involved in the manchette and flagellum formation by interacting with ODF1

The WD40 repeat (WDR) domain is present in a wide range of proteins, providing sites for protein‒protein interactions. Recent studies have shown that WDR proteins play indispensable roles in spermatogenesis, such as in spermatocyte division, sperm head formation and flagellar assembly. In this study, we identified a novel testis-specific gene, WDR64, which has the typical characteristics of WD40 proteins with two β-propellers, and is highly conserved in Mammalia. RT-PCR and Western blot results revealed that WDR64 was highly expressed in testis. WDR64 protein was weakly expressed at postnatal Day 7, increased substantially at postnatal Day 28 and maintained at high levels thereafter. Further immunofluorescence demonstrated that WDR64 was localized posterior to the nucleus in steps 8–14 spermatids in line with the dynamic localization of manchette, moved to the flagella in steps 15–16 spermatids, and localized at the midpiece of the flagellum in mature spermatozoa. To explore the function of WDR64, we performed immunoprecipitation‒mass spectrometry (IP‒MS) to screen its interacting proteins and found that WDR64 interacted with ODF1 to form a complex. The WDR64/ODF1 complex is located at the manchette during nucleus shaping and finally at the midpiece of the mature spermatozoa tail, suggesting that it may be involved in the assembly of the manchette and flagella during spermiogenesis. Our findings provide the first understanding of the expression pattern of WDR64 and its potential molecular mechanism in spermiogenesis.

Environmental enrichment and sex, but not n-acetylcysteine, alter extended-access amphetamine self-administration and cue-seeking

There are no approved therapeutics for psychostimulant use and recurrence of psychostimulant use. However, in preclinical rodent models environmental enrichment can decrease psychostimulant self-administration of low unit doses and cue-induced amphetamine seeking. We have previously demonstrated that glutamate-dependent therapeutics are able to alter amphetamine seeking to amphetamine-associated cues only in enriched rats. In the current experiment, we will determine if enrichment can attenuate responding and cue-induced amphetamine seeking during extended access to a high dose of intravenous amphetamine. We will also determine if N-acetylcysteine (NAC), a glutamate dependent therapeutic, can attenuate amphetamine seeking in differentially reared rats. Female and male Sprague-Dawley rats were reared in enriched, isolated, or standard conditions from postnatal day 21–51. Rats were trained to self-administer intravenous amphetamine (0.1 mg/kg/infusion) during twelve 6-hour sessions. During the abstinence period, NAC (100 mg/kg) or saline was administered daily. Following a cue-induced amphetamine-seeking test, astrocyte densities within regions of the medial prefrontal cortex (mPFC) and nucleus accumbens (ACb) were quantified using immunohistochemistry. Environmental enrichment decreased responding for amphetamine and during the cue-induced amphetamine-seeking test. NAC did not attenuate cue-induced amphetamine seeking or alter astrocyte density. Across all groups, female rats self-administered less amphetamine but responded more during cue-induced amphetamine seeking than male rats. While amphetamine increased astrocyte densities within the ACb and mPFC, it did not alter mPFC astrocyte densities in female rats. The results suggest that enrichment can attenuate responding during extended access to a high dose of amphetamine and the associated cues. Sex alters amphetamine-induced changes to astrocyte densities in a regionally specific matter.

Restorative effects of melatonin on bisphenol a-induced interference of gene expression in hypothalamic pituitary axis following early exposure

Bisphenol-A is a standard monomer used in manufacturing plastics and epoxy resins, and it is widely used in food preservation and packaging. It is an endocrine-disrupting chemical miming the endogenous estradiol hormone. Melatonin regulates sleep-wake cycles and plays essential physiological roles in the body through its antioxidative properties. This research aims to ascertain the impact of Bisphenol A on the hypothalamic-pituitary-ovarian axis and determine melatonin's function on possible BPA-induced effects. Six adult male Wistar rats and 12 adult female Wistar rats of proven fertility were bred and organized into groups. These animals were subjected to subcutaneous injections of high and low doses of bisphenol A from postnatal days 0-3, then oral melatonin. The rats were allowed to mature into full-grown adults and euthanized at 120 ±4 days. The serum and hypothalamic-pituitary-ovarian tissues were collected for various assays. Compared to the control groups, groups administered varying doses of bisphenol A showed significant overexpression of estrogen and androgen receptors. Administration of Melatonin showed some reversal and reparative effects on damage of the hypothalamic pituitary ovarian axis. Elevated estrogen receptor levels induced by Bisphenol A altered receptor function. Melatonin showed some promising reparative effects.

Red Blood Cell Transfusion in European Neonatal Intensive Care Units, 2022 to 2023

Red blood cell (RBC) transfusions are frequently administered to preterm infants born before 32 weeks of gestation in the neonatal intensive care unit (NICU). Two randomized clinical trials (Effects of Transfusion Thresholds on Neurocognitive Outcomes of Extremely Low-Birth-Weight Infants [ETTNO] and Transfusion of Prematures [TOP]) found that liberal RBC transfusion thresholds are nonsuperior to restrictive thresholds, but the extent to which these results have been integrated into clinical practice since publication in 2020 is unknown. To describe neonatal RBC transfusion practice in Europe. This international prospective observational cohort study collected data between September 1, 2022, and August 31, 2023, with a 6-week observation period per center, from 64 NICUs in 22 European countries. Participants included 1143 preterm infants born before 32 weeks of gestation. Admission to the NICU. Study outcome measures included RBC transfusion prevalence rates, cumulative incidence, indications, pretransfusion hemoglobin (Hb) levels, volumes, and transfusion rates, Hb increment, and adverse effects of RBC transfusion. A total of 1143 preterm infants were included (641 male [56.1%]; median gestational age at birth, 28 weeks plus 2 days [IQR, 26 weeks plus 2 days to 30 weeks plus 2 days]; median birth weight, 1030 [IQR, 780-1350] g), of whom 396 received 1 or more RBC transfusions, totaling 903 transfusions. Overall RBC transfusion prevalence rate during postnatal days 1 to 28 was 3.4 transfusion days per 100 admission days, with considerable variation across countries, only partly explained by patient mix. By day 28, 36.5% (95% CI, 31.6%-41.5%) of infants had received at least 1 transfusion. Most transfusions were given based on a defined Hb threshold (748 [82.8%]). Hemoglobin levels before transfusions indicated for threshold were below the restrictive thresholds set by ETTNO in 324 of 729 transfusions (44.4%) and TOP in 265 of 729 (36.4%). Conversely, they were between restrictive and liberal thresholds in 352 (48.3%) and 409 (56.1%) transfusions, respectively, and above liberal thresholds in 53 (7.3%) and 55 (7.5%) transfusions, respectively. Most transfusions given based on threshold had volumes of 15 mL/kg (470 of 738 [63.7%]) and were administered over 3 hours (400 of 738 [54.2%]), but there was substantial variation in dose and duration. In this cohort study of very preterm infants, most transfusions indicated for threshold were given for pretransfusion Hb levels above restrictive transfusion thresholds evaluated in recent trials. These results underline the need to optimize practices and for implementation research to support uptake of evidence.

Developmental cochlear defects are involved in early-onset hearing loss in A/J mice.

A/J mice exhibited a severe hearing loss (HL) at juvenile stage. Up-to-date, studies on HL in A/J mice have mostly focused on the damage or dysfunction of hair cells (HCs), spiral ganglion neurons (SGNs), and stereocilia. We examined A/J mice at the early postnatal stage and found that the damage and the loss of outer hair cells (OHCs) are not severe enough to explain the profound HL observed at this age, which suggests that other cochlear defects may be responsible for HL. To better understand the mechanisms of early-onset HLin A/J mice, we characterized the pathology of the cochlea from postnatal day 3 to day 21. Our results showed defects in cochlear HC stereocilia and MET channel function as early as 3 days old. We also found abnormal localization and a significant reduction in the number of ribbon synapses in 2-week-old A/J mice. There are also abnormalities in the cochlear nerve innervation and terminal swellings in 3-week-old A/J mice. All of the abnormalities of cochlear existed in the A/J mice were identified in the juvenile stage and occurred before HCs or auditory nerve loss and was the initial pathological change. Our results suggest that developmental defects and subsequent cochlear degeneration are responsible for early-onset hearing loss in A/J mice.

Neuroinflammation and oxidative redox imbalance drive memory dysfunction in adolescent rats prenatally exposed to Datura Stramonium

Although there have been reports indicating that Datura Stramonium (D. stramonium) may induce anticholinergic and neuropsychiatry effects, the compound is still being used for recreational and medicinal purposes while ingestion during pregnancy has been documented. Intriguingly, minimal studies have investigated the potential neurotoxic impact of D. stramonium exposure at various stages of gestation, including its potential implication on neurophysiological well-being later in life. The present study, therefore, examined spontaneous working memory and the expression of specific neurochemicals modulating crucial neural processes in adolescent rats exposed to high and low D. stramonium doses during different stages of gestation. Pregnant rats were orally infused with 150- or 500- mg/kg/day of D. stramonium either during mid- (second week; days 8–14) or late- (third week; days 15–21) gestation, while control rats received PBS at dosing periods. Behavioral characterization of offspring between postnatal days (PD) 40 and 41 in the Y-maze revealed that D. stramonium perturbed spatial working memory in rats, although locomotor activity was generally unaltered. In addition to SOD and nitric oxide downregulation, induction of oxidative stress in the hippocampus and prefrontal cortex (PFC) of young adult rats prenatally exposed to D. stramonium was corroborated by depletion of key antioxidant regulatory elements glutathione peroxidase, glutathione reductase and catalase, which was accompanied by lipid peroxidation shown by increased MDA levels. Whereas increased expression of acetylcholinesterase and LDH was seen in adolescent rats prenatally infused D. stramonium, acetylcholine levels were downregulated in both hippocampal and PFC lysates, suggesting cholinergic and metabolic dysfunctions. Immunohistochemical labelling of GFAP and IBA-1 revealed increased expression of reactive astrocytes and microglia respectively, while the accompanying TNFα upregulation in both the hippocampus (dentate gyrus) and PFC causally linked intrauterine D. stramonium exposure with neuroinflammatory responses postnatally. Overall, our data correlated postnatal spatial working memory dysfunction evoked by D. stramonium exposure during critical stages of embryonic development to oxidative redox impairment, cholinergic disruption and neuroinflammatory perturbations in rats.

Doublecortin-immunoreactive neurons in the piriform cortex are sensitive to the long lasting effects of early life stress.

The olfactory system is a niche of continuous structural plasticity, holding postnatal proliferative neurogenesis in the olfactory bulbs and a population of immature neurons in the piriform cortex. These neurons in the piriform cortex are generated during embryonic development, retain the expression of immaturity markers such as doublecortin, and slowly mature and integrate into the olfactory circuit as the animal ages. To study how early life experiences affect this population of cortical immature neurons, we submitted mice of the C57/Bl6J strain to a protocol of maternal separation for 3 h per day from postnatal day 3 to postnatal day 21. Control mice were continuously with their mothers. After weaning, mice were undisturbed until 6 weeks of age, when they were weighted and tested in the elevated plus-maze, a standard test for anxiety-like behavior, to check for phenotypical effects. Mice were then perfused, and their brains processed for the immunofluorescent detection of doublecortin and the endogenous proliferation marker Ki67. We found that maternal separation induced a significant increase in the body weight of males, but not females. Further, maternally separated mice displayed increased exploratory-like behavior (i.e., head dipping, velocity and total distance traveled in the elevated plus maze), but no significant differences in anxiety-like behavior or corticosterone levels after behavioral testing. Finally, we observed a significant increase in the number of complex doublecortin neurons in the piriform cortex, but not in the olfactory bulbs, of mice submitted to maternal separation. Interestingly, most doublecortin neurons in the piriform cortex, but not the olfactory bulb, express the epigenetic reader MeCP2. In summary, mild early life stress results, during adolescence, in a male-specific increase in body weight, alteration of the exploratory behaviors, and an increase in doublecortin neurons in the piriform cortex, suggesting an alteration in their maturation process.

Differential Impact of Adolescent or Adult Stress on Behavior and Cortical Parvalbumin Interneurons and Perineuronal Nets in Male and Female Mice.

Stress has become a common public health concern, contributing to the rising prevalence of psychiatric disorders. Understanding the impact of stress considering critical variables, such as age, sex, and individual differences, is of the utmost importance for developing effective intervention strategies. Stress effects (daily footshocks for 10 days) during adolescence (postnatal day [PND] 31-40) and adulthood (PND 65-74) were investigated on behavioral outcomes and parvalbumin (PV)-expressing GABAergic interneurons and their associated perineuronal nets (PNNs) in the prefrontal cortex of male and female mice 5 weeks post stress. In adulthood, adolescent stress induced behavioral alterations in male mice, including anxiety-like behaviors, social deficits, cognitive impairments, and altered dopamine system responsivity. Applying integrated behavioral z-score analysis, we identified sex-specific differences in response to adolescent stress, with males displaying greater vulnerability than females. Furthermore, adolescent-stressed male mice showed decreased PV+ and PNN+ cell numbers and PV+/PNN+ colocalization, while in females, adolescent stress reduced prefrontal PV+/PNN+ colocalization in the prefrontal cortex. Further analysis identified distinct behavioral clusters, with certain females demonstrating resilience to adolescent stress-induced deficits in sociability and PV+ cell number. Adult stress in male and female mice did not cause long-lasting changes in behavior and PV+ and PNN+ cell number. Our findings indicate that the timing of stress, sex, and individual variabilities seem to be determinants for the development of behavioral changes associated with psychiatric disorders, particularly in male mice during adolescence.

Azoospermia and multi-organ damage in juvenile rats exposed to α-Terpineol from weaning to sexual maturity

This study aimed to evaluate the repeated oral administration of α-terpineol in juvenile Wistar rats over a 70-day period. The objective was to assess the potential systemic and reproductive toxicity of α-terpineol when administered by gavage at doses of 75, 150, and 300 mg/kg/day to juvenile Wistar rats for 70 days from postnatal day 24. The control group received corn oil for 70 days. During the study, various parameters were evaluated, including clinical signs, body weight, food intake, neurobehavioral observations, haematology, serum biochemistry, organ weights, steroidogenic gene expression, and histopathological examination. No toxicity-related changes were observed in body weight, food intake, neurobehavioral observations, or steroidogenic gene expression. However, sperm evaluation revealed a complete absence of sperm and delayed sexual maturation. Total cholesterol was significantly elevated in both sexes, and serum testosterone was reduced at the 150 and 300 mg/kg doses. Microscopic examination showed severe pathological changes in the testes, epididymis, liver, and kidneys of both males and females. After the 14-day recovery period, total cholesterol levels returned to the normal range, but no recovery was observed in the other organs. The no-observed-adverse-effect level was 75 mg/kg/day for male rats based on the histopathological findings in the testes, liver, and kidneys, and for female rats based on the kidney and liver histopathology.

In Utero Exposure to Di-n-butyl Phthalate Causes Modulation in Neurotransmitter System of Wistar Rats: A Multigenerational Assessment.

Neuroendocrine regulation is disrupted by di-n-butyl phthalate (DBP) when exposure occurs during the critical periods of fetal development, which can lead to neurological disorders. To evaluate the toxic potential of DBP, it is necessary to conduct teratological studies, which could determine impacts on the development of the fetus. The present study was designed to understand the sequelae of neuroendocrine regulation in one-month-old pups when rats were exposed to DBP (F1-F3) in utero and during lactation. The rats received DBP (500mg/kg BW/day) dissolved in olive oil through oral gavage from gestation day 6 to postnatal day 30, while the control group received the olive oil (vehicle) during the same timeline. Following the exposure, thyroid profile and estradiol, which were measured at GD-19, exhibited a significant decrease (P < 0.05) in dams (F0-F2). The exposure resulted in developmental outcomes, including underdeveloped fetuses, and a notable number of resorptions in experimental rats. The one-month-old pups were assessed for serum thyroid profile and testosterone and neurotransmitters in discrete brain regions, cerebral cortex, cerebellum, and hippocampus for up to three generations. The levels of dopamine and cortisol showed a significant increase (P < 0.05), but serotonin levels decreased when examined in distinct brain regions of the experimental group as compared to the control. DBP, which is considered an endocrine disruptor, had the most impact on the third generation in this study, leading to a significant decrease in testosterone levels. In summary, in utero exposure to DBP impaired the neuroendocrine system and had an antiandrogenic effect in the three successive generations.

Dopamine D1 receptors activation rescues hippocampal synaptic plasticity and cognitive impairments in the MK-801 neonatal schizophrenia model

Schizophrenia is a disorder with a higher cognitive decline in early adulthood, causing impaired retention of episodic memories. However, the physiological and behavioral functions that underlie cognitive deficits with a potential mechanism to ameliorate and improve cognitive performance are unknown. In this study, we used the MK-801 neurodevelopmental schizophrenia-like model. Rats were divided into two groups: one received MK-801, and the other received saline for five consecutive days (7–11 postnatal days, PND). We evaluated synaptic plasticity late-LTP and spatial memory consolidation in early adolescence and young adulthood using extracellular field recordings in acute hippocampal slices and the Barnes maze task. Next, we examined D1 receptor (D1R) activation as a mechanism to ameliorate cognitive impairments. Our results suggest that MK-801 neonatal treatment induces impairment in late-LTP expression and deficits in spatial memory retrieval in early adolescence that is maintained until young adulthood. Furthermore, we found that activation of dopamine D1R ameliorates the impairments and promotes a robust expression of late-LTP and an improved performance in the Barnes maze task, suggesting a novel and potential therapeutic role in treating cognitive impairments in schizophrenia.

Maternal separation during lactation affects recognition memory, emotional behaviors, hippocampus and gut microbiota composition in C57BL6J adolescent female mice

BackgroundMaternal separation (MS) in rodents is a paradigm of early life events that affects neurological development in depression. Adolescence is a time of dramatic increases in psychological vulnerability, and being female is a depression risk factor. However, data on whether different MS scenarios affect behavioral deficits and the potential mechanisms in adolescent female mice are limited. MethodsC57BL/6 J female pups were exposed to different MS (no MS, NMS; MS for 15 min/day, MS15; or 180 min/day, MS180) from postnatal day (PND)1 to PND21 and subjected for behavioral tests during adolescence. Behavioural tests, specifically the open field test (OFT), novel object recognition test (NOR) test and tail suspension test (TST), were performed. The expression of proinflammatory cytokines, hippocampal neurogenesis, neuroinflammation, and gut microbiota were also assessed. ResultsThe results showed that MS180 induced emotional behavioral deficits and object recognition memory impairment; however, MS15 promoted object recognition memory in adolescent females. MS180 decreased hippocampal neurogenesis of adolescent females, induced an increase in microgliosis, and increased certain inflammatory factors in the hippocampus, including TNF-α, IL-1β, and IL-6. Furthermore, different MS altered gut microbiota diversity, and alpha diversity in the Shannon index was negatively correlated with the peripheral inflammatory factors TNF-α, IL-1β, and IL-6. Species difference analysis showed that the gut microbiota composition of the phyla Desulfobacterota and Proteobacteria was affected by the MS. LimitationsThe sex differences in adolescent animal and causality of hippocampal neurogenesis and gut microbiota under different MS need to be further analyzed in depression. ConclusionThis study indicates different MS affect recognition memory and emotional behaviors in adolescent females, and gut microbiota-neuroinflammation and hippocampal neurogenesis may be a potential site of early neurodevelopmental impairment in depression.

Effects of chronic social defeat stress on social behavior and cognitive flexibility for early and late adolescent

This study investigated the risk to social behavior and cognitive flexibility induced by chronic social defeat stress (CSDS) during early and late adolescence (EA and LA). Utilizing the “resident-intruder” stress paradigm, adolescent male Sprague-Dawley rats were exposed to CSDS during either EA (postnatal days 29–38) or LA (postnatal days 39–48) to explore how social defeat at different stages of adolescence affects behavioral and cognitive symptoms commonly associated with psychiatric disorders. After stress exposure, the rats were assessed for anxiety-like behavior in the elevated plus maze, social interaction, and cognitive flexibility through set-shifting and reversal-learning tasks under immediate and delayed reward conditions. The results showed that CSDS during EA, but not LA, led to impaired cognitive flexibility in adulthood, as evidenced by increased perseverative and regressive errors in the set-shifting and reversal-learning tasks, particularly under the delayed reward condition. This suggests that the timing of stress exposure during development has a significant impact on the long-term consequences for behavioral and cognitive function. The findings highlight the vulnerability of the prefrontal cortex, which undergoes critical maturation during early adolescence, to the effects of social stress. Overall, this study demonstrates that the timing of social stressors during adolescence can differentially shape the developmental trajectory of cognitive flexibility, with important implications for understanding the link between childhood/adolescent adversity and the emergence of psychiatric disorders.

GDNF facilitates cognitive function recovery following neonatal surgical-induced learning and memory impairment via activation of the RET pathway and modulation of downstream effectors PKMζ and Kalirin in rats

ObjectiveThe aim of this study is to elucidate the underlying mechanism through which glial cell line-derived neurotrophic factor (GDNF) improves cognitive deficits in adults resulting from neonatal surgical interventions. MethodsNewborn Sprague–Dawley rats, regardless of gender, were randomly allocated into seven groups on postnatal day 7 as follows (n=15): (1) Control group (not subjected to anesthesia, surgery, or any pharmaceutical interventions); (2) GDNF group (received intracerebroventricular injection of GDNF); (3) Surgery group (underwent right carotid artery exposure under anesthesia with 3 % sevoflurane); (4) Surgery plus GDNF group; (5) Surgery plus GDNF and type II JAK inhibitor NVP-BBT594 (BBT594) group (administered intraperitoneal injection of BBT594); (6) BBT group; and (7) Surgery plus BBT group. Starting from postnatal day 33, all rats underwent Barnes maze and fear conditioning tests, followed by decapitation under sevoflurane anesthesia for subsequent analyses. The left hemibrains underwent Golgi staining, while the right hemibrains were used for hippocampal protein extraction to assess Protein kinase Mζ (PKMζ) and Kalirin expression through western blotting. ResultsGDNF demonstrated a mitigating effect on spatial learning and memory impairment, as well as context-related fear memory impairment, reductions in dendritic total lengths, and spinal density within the hippocampus induced by surgical intervention. Notably, all of these ameliorative effects of GDNF were reversed upon administration of the RET inhibitor BBT594. Additionally, GDNF alleviated the downregulation of protein expression of PKMζ and Kalirin in the hippocampus of rats subjected to surgery, subsequently reversed by BBT594. ConclusionThe effective impact of GDNF on learning and memory impairment caused by surgical intervention appears to be mediated through the RET pathway. Moreover, GDNF may exert its influence by upregulating the expression of PKMζ and Kalirin, consequently enhancing the development of dendrites and dendritic spines.

Neonatal Cannabidiol Exposure Impairs Spatial Memory and Disrupts Neuronal Dendritic Morphology in Young Adult Rats.

Introduction: Early life is a sensitive period for brain development. Perinatal exposure to cannabis is increasingly linked to disruption of neurodevelopment; however, research on the effects of cannabidiol (CBD) on the developing brain is scarce. In this study, we aim to study the developmental effects of neonatal CBD exposure on behavior and dendritic architecture in young adult rats. Materials and Methods: Male and female neonatal Sprague Dawley rats were treated with CBD (50 mg/kg) intraperitoneally on postnatal day (PND) 1, 3, and 5 and evaluated for behavioral and neuronal morphological changes during early adulthood. Rats were subjected to a series of behavioral tasks to evaluate long-term effects of neonatal CBD exposure, including the Barnes maze, open field, and elevated plus maze paradigms to assess spatial memory and anxiety-like behavior. Following behavioral evaluation, animals were sacrificed, and neuronal morphology of the cortex and hippocampus was assessed using Golgi-Cox (GC) staining. Results: Rats treated with CBD displayed a sexually dimorphic response in spatial memory, with CBD-treated females developing a deficit but not males. CBD did not elicit alterations in anxiety-like behavior in either sex. Neonatal CBD caused an overall decrease in dendritic length and spine density (apical and basal) in cortical and hippocampal neurons in both sexes. Sholl analysis also revealed a decrease in dendritic intersections in the cortex and hippocampus, indicating reduced dendritic arborization. Conclusions: This study provides evidence that neonatal CBD exposure perturbs normal brain development and leads to lasting alterations in spatial memory and neuronal dendrite morphology in early adulthood, with sex-dependent sensitivity.

Innate Immune Reprogramming of Macrophages in the Parous Murine Mammary Gland

Uncomplicated childbirth is associated with an increased risk of developing breast cancer (BC) five-to-ten years postpartum (postpartum breast cancer; PPBC) compared with age-matched nulliparous individuals. PPBC is also associated with a poor prognosis relative to nulliparous individuals with BC. Contrastingly, preeclampsia, an inflammatory pregnancy complication, protects against PPBC development. We hypothesize that differential parity-induced innate immune reprogramming of mammary gland macrophages may be associated with parity-associated increased PPBC risk and preeclampsia-associated protection against PPBC. Female BALB/c mice were mated with male C57Bl/6 mice to establish allogeneic pregnancies. On gestational day (GD) 10.5, dams were injected with saline (controls) or lipopolysaccharide (LPS; 20 μg/kg) to induce inflammatory pregnancy complications. Age-matched nulliparous controls also received LPS or saline. Following birth, parous mice were force-weaned on postnatal day (PD) 7 to induce synchronous involution. Macrophages were isolated from mammary glands upon euthanasia in pregnancy (GD 14.5), lactation (PD 7), involution (PD 10) and regression (PD 28), plated (4x104 cells/well) and exposed to a 23-hour secondary challenge (LPS; 100 ng/ml; Pam3Cys; 10 µg/ml). Cytokine concentrations in cell culture supernatant were assessed using a multiplex assay (Eve Technologies) and data were analyzed by two-way ANOVA with Tukey’s posthoc test. During involution, compared with supernatant from mammary gland macrophages of age-matched nulliparous saline-treated mice, supernatant from macrophages from parous saline-treated mice exhibited significantly increased interleukin (IL)-1β and tumour necrosis factor-α (TNF-α), and significantly decreased IL-6 following secondary challenge. TNF-α, IL-6 and IL-10 in supernatant from macrophages from parous LPS-treated mice was significantly decreased compared with parous saline-treated controls. Analysis of data collected during pregnancy, lactation and regression is ongoing to temporally evaluate reprogramming. These preliminary results demonstrate differential reprogramming in mammary gland macrophages relative to parity and inflammatory pregnancy complication status and rationalize understanding contributions of completion of a prior pregnancy on PPBC risk and progression.

Suppression of Hippocampal Neurogenesis and Oligodendrocyte Maturation Similar to Developmental Hypothyroidism by Maternal Exposure of Rats to Ammonium Perchlorate, a Gunpowder Raw Material and Known Environmental Contaminant.

The environmental contaminant perchlorate raises concern for hypothyroidism-related brain disorders in children. This study investigated the effects of developmental perchlorate exposure on hippocampal neurogenesis and oligodendrocyte (OL) development. Pregnant Sprague-Dawley rats were administered with ammonium perchlorate (AP) in drinking water at concentrations of 0 (control), 300, and 1000 ppm from gestation day 6 until weaning [postnatal day (PND) 21]. On PND 21, offspring displayed decreased serum triiodothyronine and thyroxine concentrations at 1000 ppm and thyroid follicular epithelial cell hyperplasia at ≥300 ppm (accompanying increased proliferation activity at 1000 ppm). Hippocampal neurogenesis indicated suppressed proliferation of neurogenic cells at ≥300 ppm, causing decreases in type-1 neural stem cells (NSCs) and type-2a neural progenitor cells. In addition, an increase of SST+ GABAergic interneurons and decreasing trend for ARC+ granule cells were observed at 1000 ppm. CNPase+ mature OLs were decreased in number in the dentate gyrus hilus at ≥300 ppm. At PND 77, thyroid changes had disappeared; however, the decrease of type-1 NSCs and increase of SST+ interneurons persisted, CCK+ interneurons were increased, and white matter tissue area was decreased at 1000 ppm. Obtained results suggest an induction of hypothyroidism causing suppressed hippocampal neurogenesis (targeting early neurogenic processes and decreased synaptic plasticity of granule cells involving ameliorative interneuron responses) and suppressed OL maturation during the weaning period. In adulthood, suppression of neurogenesis continued, and white matter hypoplasia was evident. Observed brain changes were similar to those caused by developmental hypothyroidism, suggesting that AP-induced developmental neurotoxicity was due to hypothyroidism.