Long live the RNAs: The guardians of neuronal longevity?

In a recent publication in Science, Zocher et al.1 identify and characterize long-lived nuclear RNA in the mouse brain, suggesting their potential roles as guardians of neuronal longevity.

Nuclear SphK2/S1P signaling is a key regulator of ApoE production and Aß uptake in astrocytes.

The link between changes in astrocyte function and the pathological progression of Alzheimer's disease (AD) has attracted considerable attention. Interestingly, activated astrocytes in AD show abnormalities in their lipid content and metabolism. In particular, the expression of apolipoprotein E (ApoE), a lipid transporter, is decreased. Because ApoE has anti-inflammatory and amyloid ß (Aß)-metabolizing effects, the nuclear receptors, retinoid X receptor (RXR) and LXR, which are involved in ApoE expression, are considered promising therapeutic targets for AD. However, the therapeutic effects of agents targeting these receptors are limited or vary considerably among groups, indicating the involvement of an unknown pathological factor that modifies astrocyte and ApoE function. Here, we focused on the signaling lipid, sphingosine-1-phosphate (S1P), which is mainly produced by sphingosine kinase 2 (SphK2) in the brain. Using astrocyte models, we found that upregulation of SphK2/S1P signaling suppressed ApoE induction by both RXR and LXR agonists. We also found that SphK2 activation reduced RXR binding to the APOE promoter region in the nucleus, suggesting the nuclear function of SphK2/S1P. Intriguingly, suppression of SphK2 activity by RNA knockdown or specific inhibitors upregulated lipidated ApoE induction. Furthermore, the induced ApoE facilitates Aß uptake in astrocytes. Together with our previous findings that SphK2 activity is upregulated in AD brain and promotes Aß production in neurons, these results indicate that SphK2/S1P signaling is a promising multifunctional therapeutic target for AD that can modulate astrocyte function by stabilizing the effects of RXR and LXR agonists, and simultaneously regulate neuronal pathogenesis.

The Pursuit of the "Inside" of the Amyloid Hypothesis-Is C99 a Promising Therapeutic Target for Alzheimer's Disease?

Aducanumab, co-developed by Eisai (Japan) and Biogen (U.S.), has received Food and Drug Administration approval for treating Alzheimer's disease (AD). In addition, its successor antibody, lecanemab, has been approved. These antibodies target the aggregated form of the small peptide, amyloid-ß (Aß), which accumulates in the patient brain. The "amyloid hypothesis" based therapy that places the aggregation and toxicity of Aß at the center of the etiology is about to be realized. However, the effects of immunotherapy are still limited, suggesting the need to reconsider this hypothesis. Aß is produced from a type-I transmembrane protein, Aß precursor protein (APP). One of the APP metabolites, the 99-amino acids C-terminal fragment (C99, also called ßCTF), is a direct precursor of Aß and accumulates in the AD patient's brain to demonstrate toxicity independent of Aß. Conventional drug discovery strategies have focused on Aß toxicity on the "outside" of the neuron, but C99 accumulation might explain the toxicity on the "inside" of the neuron, which was overlooked in the hypothesis. Furthermore, the common region of C99 and Aß is a promising target for multifunctional AD drugs. This review aimed to outline the nature, metabolism, and impact of C99 on AD pathogenesis and discuss whether it could be a therapeutic target complementing the amyloid hypothesis.

Lipid flippase dysfunction as a therapeutic target for endosomal anomalies in Alzheimer's disease.

Endosomal anomalies because of vesicular traffic impairment have been indicated as an early pathology of Alzheimer'| disease (AD). However, the mechanisms and therapeutic targets remain unclear. We previously reported that ßCTF, one of the pathogenic metabolites of APP, interacts with TMEM30A. TMEM30A constitutes a lipid flippase with P4-ATPase and regulates vesicular trafficking through the asymmetric distribution of phospholipids. Therefore, the alteration of lipid flippase activity in AD pathology has got attention. Herein, we showed that the interaction between ßCTF and TMEM30A suppresses the physiological formation and activity of lipid flippase in AD model cells, A7, and AppNL-G-F/NL-G-F model mice. Furthermore, the T-RAP peptide derived from the ßCTF binding site of TMEM30A improved endosomal anomalies, which could be a result of the restored lipid flippase activity. Our results provide insights into the mechanisms of vesicular traffic impairment and suggest a therapeutic target for AD.

TMEM30A is a candidate interacting partner for the ß-carboxyl-terminal fragment of amyloid-ß precursor protein in endosomes.

Although the aggregation of amyloid-ß peptide (Aß) clearly plays a central role in the pathogenesis of Alzheimer's disease (AD), endosomal traffic dysfunction is considered to precede Aß aggregation and trigger AD pathogenesis. A body of evidence suggests that the ß-carboxyl-terminal fragment (ßCTF) of amyloid-ß precursor protein (APP), which is the direct precursor of Aß, accumulates in endosomes and causes vesicular traffic impairment. However, the mechanism underlying this impairment remains unclear. Here we identified TMEM30A as a candidate partner for ßCTF. TMEM30A is a subcomponent of lipid flippase that translocates phospholipids from the outer to the inner leaflet of the lipid bilayer. TMEM30A physically interacts with ßCTF in endosomes and may impair vesicular traffic, leading to abnormally enlarged endosomes. APP traffic is also concomitantly impaired, resulting in the accumulation of APP-CTFs, including ßCTF. In addition, we found that expressed BACE1 accumulated in enlarged endosomes and increased Aß production. Our data suggested that TMEM30A is involved in ßCTF-dependent endosome abnormalities that are related to Aß overproduction.

Functional analysis of juxta- and intra-membrane domains of murine APP by genome editing in Neuro2a cells.

Amyloid-ß precursor protein (APP) correlates with the pathogenesis of certain brain diseases, such as Alzheimer disease (AD). APP is cleaved by several enzymes to produce APP metabolites, including the amyloid beta peptide (Aß), which accumulates in the brain of AD patients. However, the exact functions of APP metabolites remain elusive. In this study, using genome editing technology, we mutated juxta- and intra-membrane domains of murine APP in the mouse neuroblastoma cell line, Neuro2a. We identified several clones that expressed characteristic patterns of APP metabolites. Mutations in juxta- (deletion 673A), and intra-membrane (deletion 705-6LM) domains of APP, decreased overall levels of APP metabolites or decreased the level of α-secretase-cleaved carboxy-terminal fragment (αCTF), respectively. APP is known to influence neuronal differentiation; therefore, we used theses clones to dissect the function of APP metabolites during neuronal differentiation. One clone (CA), which expressed reduced levels of both FL-APP and αCTF, showed increased expression of the neuronal marker, ß3-tubulin, and enhanced retinoic acid (RA)-induced neurite outgrowth. In contrast, a clone that expressed FL-APP, but was devoid of αCTF (CE), showed comparable expression of ß3-tubulin and neurite outgrowth compared with normal Neuro2a cells. These data indicate that FL-APP is a suppressor of neurite outgrowth. Our data suggest a novel regulatory function of juxta- and intra-membrane domains on the metabolism and function of APP.