大野 伸彦

Amyotrophic lateral sclerosis (ALS) and frontotemporal lobar degeneration (FTLD) develop as spatial pathologies in which neurons and glial cells are interconnected. TAR DNA-binding protein 43 (TDP-43) is a major pathological protein that is inextricably associated with ALS and FTLD. In this study, we investigated the roles of neuronal TDP-43 in neuron-oligodendrocyte interactions using neuron-specific TDP-43 knockout (TDP-43cKO) mice. TDP-43 depletion in neurons induced hypomyelination, which was confirmed by immunohistochemistry and ultrastructural analysis. In addition, conduction disturbance was revealed by electrophysiological analysis. The hypomyelination of TDP-43cKO mouse was restored by cytoplasmic TDP-43 supplementation in neurons. Neuron-specific transcriptome analysis revealed that neurexin 1 (NRXN1) is the regulatory target of TDP-43, which promotes myelin formation. The hypomyelination of TDP-43cKO mice was also restored by NRXN1b supplementation in neurons. We further confirmed that TDP-43 stabilizes Nrxn1 mRNA by binding to the Nrxn1 3'untranslated region (3'UTR). Although TDP-43cKO exhibited impaired recognition memory, the supplementation of NRXN1 in the hippocampus recovered the memory disturbances. In conclusion, this study demonstrates the neuron-oligodendrocyte interaction mediated by neuronal TDP-43 via NRXN1 mRNA stabilization. These findings shed light on neuron-oligodendrocyte interaction in the disease mechanisms of ALS/FTLD.

Fibroblast growth factor-23 (FGF23) is a bone-derived hormone that promotes urinary phosphate excretion in response to phosphate loading. While essential for phosphate homeostasis, elevated FGF23 increases phosphate concentration in the renal tubular fluid, promoting calcium-phosphate crystal formation and tubular injury. Here we show that bone resorption mobilizes phosphate into the circulation and mimics the pathophysiology of dietary phosphate loading. Enhanced bone resorption, induced by soluble receptor activator of NF-κB ligand (sRANKL) administration or microgravity exposure on the International Space Station, increased circulating FGF23 levels and caused renal tubular injury in mice. Pre-treatment with bisphosphonate, an inducer of osteoclast apoptosis, prevented sRANKL-induced increases in FGF23 and tubular damage. These findings suggest that bone mineral loss may contribute to renal tubular injury in clinical settings, including immobilization, osteoporosis, and chronic kidney disease-mineral bone disorder.

Familial neurohypophysial diabetes insipidus (FNDI) is an autosomal dominant disorder caused by mutations in the arginine vasopressin (AVP) gene. In AVP neurons in a mouse model of FNDI, aggregates of mutant AVP precursors accumulate within a specific compartment of the endoplasmic reticulum (ER). However, as FNDI mice aged, or were exposed to repeated water deprivation, the ER lumen dilated and mutant aggregates dispersed throughout the ER. Meanwhile, autophagic isolation membranes, known as phagophores, emerged to envelop ER containing these aggregates, indicating induction of ER-phagy. Previous in vitro studies showed that phagophores originate from ER membranes, but the structural relationship between phagophores and the ER membrane in vivo remains unknown. In this study, we used serial block-face scanning electron microscopy to investigate the structural relationship between phagophores, ER membranes, and protein aggregates within dilated ER of AVP neurons from FNDI mice subjected to intermittent water deprivation for 4 weeks. Three-dimensional analysis revealed that phagophores enveloped aggregates located within the dilated ER. Serial imaging further demonstrated a physical connection between these phagophores and intact ER membranes. This study provides the first in vivo evidence of the structural continuity between phagophores and the ER membrane in AVP neurons in a mouse model of FNDI.

The activity of oligodendrocyte progenitor cells (OPCs) and oligodendrocytes (OLs) throughout life drives myelination, which is crucial for rapid neuronal communication. OLs in the aging brain demonstrate a reduced capacity for myelin formation and maintenance, but the underlying differentiation of individual OLs and morphological changes of their myelin in aging remain unclear. Here, we utilized Pdgfra-CreERT2:Tau-mGFP double transgenic mice to selectively label and visualize newly generated OLs in aged (78-week-old) mice and compared them with those in young (8-week-old) mice. We revealed a significantly lower percentage of newly generated OLs that differentiated into mature OLs and a decreased rate of myelinating OLs accumulation in aged mice compared with young mice. Additionally, newly generated myelinating mature OLs in aged mice demonstrated significantly greater height compared with those in young mice. Furthermore, myelin internodes were significantly shorter and significantly fewer in aged mice compared with young mice. Our results indicate age-related impairments in the differentiation efficiency of aged OPCs and age-related morphological changes in OLs. These alterations in newly generated OLs may contribute to impaired myelination, reduced myelin turnover, and disrupted myelin maintenance in aged mice.