Novel function of Contactin associated protein 1 (Caspr 1)/ Paranodin in embryonic cortical neurons: hypoxia modulated neurite development.

Hypoxia, a condition of inadequate oxygen supply, is a common phenomenon affecting neurons and brain tissue, leading to significant implications for neuronal health and function. The prevalence of hypoxia in the brain is associated with various neurological conditions, making it a critical area of study. Neuritogenesis, the process of neurite outgrowth, is an essential aspect of neuronal development and connectivity and is particularly sensitive to hypoxic stress. Investigating how hypoxia affects neurite outgrowth is vital for understanding neuronal response and adaptation under low oxygen conditions. This study explores how hypoxic stress affects neurite regulation mediated by Contactin Associated Protein-1 (Caspr1) in primary mouse embryonic cortical neurons. Hypoxia, induced by culturing neurons in a 2% oxygen environment, significantly reduced neurite length and induced notable changes in growth cone morphology. Concurrently, we observed an upregulation in the expression of Caspr1 and its transcriptional regulator C/EBP, suggesting a compensatory role for Caspr1 in neurite extension under low oxygen conditions. Shorter hypoxia exposure periods revealed a dynamic biphasic response in Caspr1 levels, with an initial decrease followed by a substantial increase, correlating with corresponding changes in neurite length. This pattern emphasizes the critical involvement of Caspr1 in adapting neurite growth to fluctuating hypoxia duration. Furthermore, comparative analyses using wild-type and Caspr1 knockout Neuro2a cells demonstrated that the absence of Caspr1 mitigates hypoxia-induced neurite shortening, indicating a potential protective role against hypoxic stress. Additionally, hypoxia profoundly impacted mitochondrial morphology and function. Under hypoxic conditions, mitochondria transitioned to a more spherical shape. Mitochondrial respiration analysis revealed significant reductions in oxygen consumption rates (OCR), highlighting compromised mitochondrial function during hypoxia. These findings underscore the multifaceted role of Caspr1 in neurite regulation and mitochondrial adaptation to hypoxic stress. The study provides insights into the molecular mechanisms underpinning hypoxia-induced changes in neuronal morphology and function. Understanding these processes opens avenues for therapeutic strategies targeting Caspr1 in treating neurological disorders characterized by hypoxic stress. Future research will benefit from extending these investigations to more complex models, such as brain organoids, to further elucidate the metabolic and structural changes under hypoxia and their implications for neurodegenerative diseases.