Evolution and genomics of the human brain

Atrophy and Higher Levels of Inflammatory-Related Markers in the Posterior Cerebellar Lobe Cortex in Chronic Alcohol Use Disorder: A Cross-Sectional Study

AIMS

Alcohol use disorder (AUD) involves excessive and chronic ethanol consumption, leading to various health issues, including cerebellar atrophy. The cerebellum is particularly susceptible to ethanol-induced damage through neuroinflammation, oxidative stress and excitotoxicity. This damage has been documented predominantly in the anterior lobe, primarily due to its role in motor function, which is often impaired in patients with AUD. However, less is known about the impact of AUD on the posterior cerebellar lobes. In contrast, alterations in the posterior lobe have been associated with cerebellar cognitive affective syndrome (CCAS). Moreover, the cerebellum is an asymmetric structure with spatial functions being left-lateralised. We hypothesised that the posterior cerebellar lobe in AUD cases would show increased inflammation compared with healthy controls.

METHODS

This cross-sectional study examined the structural integrity and neuroinflammatory state of the left posterior cerebellar lobe cortex in post-mortem samples from nine males with chronic AUD and 9 control cases.

RESULTS

Chronic AUD cases showed significant cerebellar damage. Immunohistochemistry revealed higher levels of reactive astrogliosis (GFAP), increased Treg cell markers (CD45 and FOXP3), increased mitochondria marker (MitoTrackerTM), elevated COX2 (indicating inflammation and Treg cell activity), increased cFos protein (cell activity marker), and higher caspase 3 (Casp3) levels, suggesting excessive cell death. These findings indicate that chronic AUD leads to atrophy in the left posterior cerebellar lobe cortex due to neuroinflammation driven by reactive astrogliosis, Treg cell infiltration, and COX2 activity.

CONCLUSIONS

The study highlights the inflammatory consequences of chronic AUD, potentially linked to cerebellar atrophy and subsequent motor and cognitive impairments. Targeting neuroinflammation could help mitigate the neurodegenerative effects of chronic AUD.

Length of the Neurogenic Period-A Key Determinant for the Generation of Upper-Layer Neurons During Neocortex Development and Evolution

The neocortex, a six-layer neuronal brain structure that arose during the evolution of, and is unique to, mammals, is the seat of higher order brain functions responsible for human cognitive abilities. Despite its recent evolutionary origin, it shows a striking variability in size and folding complexity even among closely related mammalian species. In most mammals, cortical neurogenesis occurs prenatally, and its length correlates with the length of gestation. The evolutionary expansion of the neocortex, notably in human, is associated with an increase in the number of neurons, particularly within its upper layers. Various mechanisms have been proposed and investigated to explain the evolutionary enlargement of the human neocortex, focussing in particular on changes pertaining to neural progenitor types and their division modes, driven in part by the emergence of human-specific genes with novel functions. These led to an amplification of the progenitor pool size, which affects the rate and timing of neuron production. In addition, in early theoretical studies, another mechanism of neocortex expansion was proposed—the lengthening of the neurogenic period. A critical role of neurogenic period length in determining neocortical neuron number was subsequently supported by mathematical modeling studies. Recently, we have provided experimental evidence in rodents directly supporting the mechanism of extending neurogenesis to specifically increase the number of upper-layer cortical neurons. Moreover, our study examined the relationship between cortical neurogenesis and gestation, linking the extension of the neurogenic period to the maternal environment. As the exact nature of factors promoting neurogenic period prolongation, as well as the generalization of this mechanism for evolutionary distinct lineages, remain elusive, the directions for future studies are outlined and discussed.

Effect of lncRNA WT1-AS regulating WT1 on oxidative stress injury and apoptosis of neurons in Alzheimer's disease via inhibition of the miR-375/SIX4 axis

Objective: To study the effect of lncRNA WT1-AS on oxidative stress injury (OSI) and apoptosis of neurons in Alzheimer's disease (AD) and its specific mechanisms related to the microRNA-375 (miR-375)/SIX4 axis and WT1 expression.

Results: After bioinformatic prediction, WT1-AS was found to be downregulated in Aβ_25-35treated SH-SY5Y cells, and WT1-AS overexpression inhibited WT1 expression. WT1 could target miR-375 to promote its expression. miR-375 bound to SIX4, and miR-375 overexpression inhibited SIX4 expression. WT1-AS inhibited OSI and apoptosis, while WT1 and miR-375 overexpression or SIX4 silencing reversed the WT1-AS effect on OSI and apoptosis. In vivo experiments revealed that WT1-AS improved learning/memory abilities and inhibited OSI and apoptosis in AD mice.

Conclusion: Overexpression of WT1-AS can inhibit the miR-375/SIX4 axis, OSI and neuronal apoptosis in AD by inhibiting WT1 expression.

Methods: Related lncRNAs were identified, and miR-375 downstream targets were predicted. WT1-AS, WT1, miR-375 and SIX4 expression was detected in a cell model induced by Aβ_25-35. The binding of WT1 with miR-375 and that of miR-375 with SIX4 were further confirmed. Adenosine triphosphate (ATP), reactive oxygen species (ROS), malondialdehyde (MDA), superoxide dismutase (SOD), glutathione peroxidase (GSH-Px) and lactate dehydrogenase (LDH) activities, and apoptosis levels were tested after mitochondrial membrane potential observation. Learning/memory abilities and neuronal apoptosis were tested in a mouse model.