Dehydroepiandrosterone alleviates hypoxia-induced learning and memory dysfunction by maintaining synaptic homeostasis

Impact of hypoxia on the hippocampus: A review

Oxygen is the most abundant chemical substance and is a basic material for human activities. A decline in oxygen concentration affects many physiological processes in the body, leading to pathological changes and even the occurrence of diseases. Therefore, an increasing number of studies have focused on the pathological state of hypoxia. The hippocampus is the most sensitive tissue to oxygen in the brain. The reduction in oxygen concentration affects the morphology and functioning of the hippocampus, including a decline in learning and memory, immunity, and energy metabolism, causing great problems to people's physical and mental health. To keep people healthy in hypoxic environments, adapt to hypoxic environments, and avoid diseases, it is necessary to review the morphology and function of the hippocampus, as well as the effect of oxygen on the hippocampus.

Combined exposure of sleep deprivation and environmental particulate matter drives aging in multiple systems

Sleep disturbance accelerates aging, with accompanying exposure to air pollution. However, most studies ignore the combined exposure. This study aimed to investigate the combined effects of sleep deprivation and PM2.5 exposure on multi-system aging and to explore the damage mechanisms. The sleep deprivation instrument and the Shanghai Meteorological and Environmental Animal Exposure System (Shanghai-METAS) were used to construct a combined exposure model for one month. Our study used multiple behavioral, imaging, and molecular biological examinations to describe the aging characteristics in the cardiovascular system, metabolism, and central nervous system. Besides, the mechanisms in Sirt1, Wnt10β pathways were explored and correlation of damage among tissues was clarified. Based on sleep disruption, PM2.5 exposure was able to induce elevated serum T-CHO levels, impaired conditioned learning ability, abnormal brain tissue metabolic levels, and aberrant expression of multiple molecular markers related to cellular senescence, whereas PM2.5 exposure alone did not induce changes in the above indices. In addition, the Sirt1, Wnt10β pathway mediated cardiac and hepatic aging induced by combined exposure. Moreover, there was a significant correlation between heart and liver aging damage, which suggesting heart-liver axis may be involved in the aging process. Sleep deprivation and PM2.5 exposure trigger senescence in multiple tissues. In particular, on the basis of sleep deprivation, PM2.5 accelerates of the aging process in several tissues and organs. The problem of air pollution on top of sleep disturbance should be taken seriously, as it has a greater potential to accelerate aging than air pollution.

The gut microbiota mediates memory impairment under high-altitude hypoxia via the gut-brain axis in mice

Hypoxia is a predominant risk factor at high altitudes, and evidence suggests that high-altitude hypoxia alters the gut microbiota, which plays an essential regulatory role in memory function. However, the causal relationship between the gut microbiota and memory impairment under hypoxic conditions remains unclear. In this study, we employed a high-altitude hypoxia model combined with fecal microbiota transplantation (FMT) approach in mice to explore the effects of the gut microbiota on memory impairment in a hypoxic environment. We observed that high-altitude hypoxia exposure reduced short- and long-term memory and hippocampus-dependent fear memory abilities, along with decreased relative abundance of Ligilactobacillus and Muribaculum. Moreover, hypoxic conditions increased intestinal and blood-brain barrier permeability. FMT from hypoxia-exposed mice into naïve antibiotic-treated mice resulted in similar memory impairments, Ligilactobacillus and Muribaculum abundance changes, and increased intestinal/blood-brain barrier permeability. Correlation analysis showed a robust positive association between Ligilactobacillus and Muribaculum with hippocampus-dependent contextual fear memory. Likewise, Ligilactobacillus was positively correlated with short-term memory. Therefore, Ligilactobacillus and Muribaculum may be key microbes in reducing memory ability in hypoxia, with the intestinal and blood-brain barriers as primary pathways. Our findings provide further evidence for the potential regulatory mechanism by which gut microbiota dysbiosis may contribute to memory impairment in a high-altitude environment.

Copper supplementation alleviates hypoxia‑induced ferroptosis and oxidative stress in neuronal cells

Hypoxic ischemia is the primary cause of brain damage in newborns. Notably, copper supplementation has potential benefits in ischemic brain damage; however, the precise mechanisms underlying this protective effect remain unclear. In the present study, a hypoxic HT22 cell model was developed to examine the mechanism by which copper mitigates hypoxia‑induced oxidative stress. Cell viability was assessed using the Cell Counting Kit‑8 assay, mitochondrial structure was examined with a transmission electron microscope, intracellular ferrous ions and lipid reactive oxygen species levels in HT22 cells were measured using FerroOrange and BODIPY 581/591 C11 staining, copper content was determined using graphite furnace atomic absorption spectroscopy, and gene and protein expression were analyzed by reverse transcription‑quantitative PCR and western blotting. The present findings indicated that hypoxic exposure may lead to reduced cell viability, along with the upregulation of various markers associated with ferroptosis. Furthermore, hypoxia elevated the levels of reactive oxygen species, hydrogen peroxide and malondialdehyde, and decreased the activity of superoxide dismutase 1 (SOD1) in HT22 cells. In addition, the intracellular copper concentration exhibited a notable decrease, while supplementation with an appropriate dose of copper effectively shielded neurons from hypoxia‑induced oxidative stress and ferroptosis, and elevated cell viability in hypoxia‑exposed HT22 cells through the copper chaperone for superoxide dismutase/SOD1/glutathione peroxidase 4 axis. In conclusion, the present study identified a novel function of copper in protecting neurons from oxidative stress and ferroptosis under hypoxic conditions, providing fresh insights into the therapeutic potential of copper in mitigating hypoxia‑induced neuronal injury.

Targeting Cell Senescence and Senolytics: Novel Interventions for Age-Related Endocrine Dysfunction

Multiple changes occur in hormonal regulation with aging and across various endocrine organs. These changes are associated with multiple age-related disorders and diseases. A better understanding of responsible underling biological mechanisms could help in the management of multiple endocrine disorders over and above hormone replacement therapy (HRT). Cellular senescence is involved in multiple biological aging processes and pathologies common in elderly individuals. Cellular senescence, which occurs in many older individuals but also across the lifespan in association with tissue damage, acute and chronic diseases, certain drugs, and genetic syndromes, may contribute to such endocrine disorders as osteoporosis, metabolic syndrome, and type 2 diabetes mellitus. Drugs that selectively induce senescent cell removal, "senolytics,", and drugs that attenuate the tissue-destructive secretory state of certain senescent cells, "senomorphics," appear to delay the onset of or alleviate multiple diseases, including but not limited to endocrine disorders such as diabetes, complications of obesity, age-related osteoporosis, and cancers as well as atherosclerosis, chronic kidney disease, neurodegenerative disorders, and many others. More than 30 clinical trials of senolytic and senomorphic agents have already been completed, are underway, or are planned for a variety of indications. Targeting senescent cells is a novel strategy that is distinct from conventional therapies such as HRT, and thus might address unmet medical needs and can potentially amplify effects of established endocrine drug regimens, perhaps allowing for dose decreases and reducing side effects.

A longitudinal study on the impact of high-altitude hypoxia on perceptual processes

This study aimed to explore the neural mechanisms underlying high-altitude (HA) adaptation and deadaptation in perceptual processes in lowlanders. Eighteen healthy lowlanders were administered a facial S1-S2 matching task that included incomplete face (S1) and complete face (S2) photographs combined with ERP technology. Participants were tested at four time points: shortly before they departed the HA (Test 1), twenty-five days after entering the HA (Test 2), and one week (Test 3) and one month (Test 4) after returning to the lowlands. Compared with those at sea level (SL), shorter reaction times (RTs), shorter latencies of P1 and N170, and larger amplitudes of complete face N170 were found in HAs. After returning to SL, compared with that of HA, the amplitude of the incomplete face P1 was smaller after one week, and the complete face was smaller after one month. The right hemisphere N170 amplitude was greater after entering HA and one week after returning to SL than at baseline, but it returned to baseline after one month. Taken together, the current findings suggest that HA adaptation increases visual cortex excitation to accelerate perceptual processing. More mental resources are recruited during the configural encoding stage of complete faces after HA exposure. The perceptual processes affected by HA exposure are reversible after returning to SL, but the low-level processing stage differs between incomplete and complete faces due to neural compensation mechanisms. The configural encoding stage in the right hemisphere is affected by HA exposure and requires more than one week but less than one month to recover to baseline.

TREM2 expression on the microglia resolved lead exposure-induced neuroinflammation by promoting anti-inflammatory activities

Neurotoxicity caused by environmental lead (Pb) pollution is a worldwide public health concern, and developing a therapeutic strategy against Pb-induced neurotoxicity is an important area in the current research. Our prior research has demonstrated the significant involvement of microglia-mediated inflammatory responses in the manifestation of Pb-induced neurotoxicity. Additionally, the suppression of proinflammatory mediator activity significantly mitigated the toxic effects associated with Pb exposure. Recent studies have highlighted the critical role of the triggering receptor expressed on myeloid cells 2 (TREM2) in the pathogenesis of neurodegenerative disorders. TREM2 exerted protective effects on inflammation, but whether TREM2 is involved in Pb-induced neuroinflammation is poorly understood. In the present study, cell culture experiments and animal models were designed to investigate the role of TREM2 in Pb's neuroinflammation. We examined the impact of pro- and anti-inflammatory cytokines involved in Pb-induced neuroinflammation. Flow cytometry and microscopy techniques were applied to detect microglia phagocytosis and migration ability. Our results showed that Pb treatment significantly downregulated TREM2 expression and altered the localization of TREM2 expression in microglia. The protein expression of TREM2 was restored, and the inflammatory responses provoked by Pb exposure were ameliorated upon the overexpression of TREM2. Furthermore, the phagocytosis and migratory capabilities of microglia, which were impaired due to Pb exposure, were alleviated by TREM2 overexpression. Our in vitro findings were corroborated in vivo, demonstrating that TREM2 regulates the anti-inflammatory functions of microglia, thereby mitigating Pb-induced neuroinflammation. Our results provide insights into the detailed mechanism by which TREM2 alleviates Pb-induced neuroinflammation and suggest that activating the anti-inflammatory functions of TREM2 may represent a potential therapeutic strategy against environmental Pb-induced neurotoxicity.