Transcriptome analysis of the hippocampus in environmental noise-exposed SAMP8 mice reveals regulatory pathways associated with Alzheimer’s disease neuropathology

Alzheimer’s disease (AD) is the most common form of dementia, accounting for 50–56% of autopsy and clinical cases [1]. It is marked by a progressive loss of memory and cognitive function, overproduction of amyloid beta (Aβ), and increased hyperphosphorylation of tau [1, 2]. However, the pathogenesis of AD is complex, and the disease has no clear cause.

Generally, the association among environmental stress, aging process, and their causal roles plays a role in the development of AD pathogenesis [3‐5]. Aging is the major risk factor for AD [6]. The incidence of dementia increases exponentially with increasing age [7]. AD-like pathological changes, such as aggregation of Aβ and the phosphorylation of tau protein, are associated with aging [8, 9]. Noise-induced health effects were first recognized in industrial settings, such as manufacturers, where intense impulse sound or steady-state long-term exposure with sound pressure levels higher than 85 dBA were associated with auditory and non-auditory effects [10]. Chronic noise exposure in experimental animals can cause not only accelerated Aβ synthesis but also significant and persistent hyperphosphorylation of tau and the formation of prominent pathological neurofibrillary tangles (NFTs) of tau in the hippocampus, key structures in learning and memory, and initial sites of tau pathology in AD [11‐14]. On the other hand, chronic noise exposure could affect the spatial learning and memory [15, 16]. Hence, noise exposure may aggravate the development of aging-related AD-like pathological changes, and its related molecular mechanisms need to be explored further.

In the present study, we performed a comparative gene expression analysis of chronic noise-affected and non-noise-affected brain tissues by using the RNA sequencing technique, an advanced approach that determines the differential expression profiles underlying phenotypic differences [17]. We selected senescence-accelerated mouse prone 8 (SAMP8), which shares behavioral, cognitive, and neuropathological alterations observed in AD patients and is a plausible natural model for exploring the pathogenesis of AD [18]. Our data will serve as a new reference for the prevention and treatment of AD.

Multiple factors contribute to the pathogenesis of AD, and they include aging, genetic variables, and environmental factors [21]. Chronic noise exposure, the main focus of environmental factors, is related to AD [12‐14, 22]. Acute or chronic noise exposure could induce various indicators of AD-like pathological changes that increase the risk of AD development [19, 23]. Our recent research further confirmed that chronic noise exposure led to cognitive impairment and Aβ accumulation in young SAMP8 mice, similar to that observed in aging SAMP8 mice [12]. In the present study, we described a reliable transcriptome sequencing to highlight key proteins in the hippocampus that are modulated in response to AD-like neurodegenerations. We also reported genomic signatures that are associated with chronic noise exposure and with age-related changes in the tissue.

By overlaying transcriptomic and neuropathological profiles, we identified noise and age-related shifts in underappreciated pathways, such as the Toll-like receptor (TLR) signaling pathway, TNF signaling pathway, MAP kinase pathway, and Ras/ERK signaling pathway, which are involved in the pathogenesis of AD. TLRs, a family of receptor proteins, play a wide role in innate and adaptive immune responses upon the stimulations by exogenous and endogenous TLR ligands. There is an increased endocytosis of TLR4 in the AD model mice brain, which might be a key event for the neurodegeneration signaling in the brain [24]. TNF-α has been assessed in the pathophysiology of AD both in human [25] and animal studies [26], and in our previous study, chronic noise exposure increased levels of TNF-α in the rat hippocampus [20]. The mammalian MAPK family consists of p38-MAPK, ERK, and c-Jun NH2-terminal kinase (JNK), which is involved in inflammatory reactions and apoptosis processes under conditions of oxidative stress [27]. It was also reported in our previous study that noise exposure could induce neural apoptosis [28], which is influenced by multiple factors and was shown to be closely related to the MAPK pathway [29]. AD is a multifactorial disease, and many theories have been formulated concerning its causes, including neuron loss, Aβ deposition, tau neuropathology, immune system dysfunction, synapse injury, oxidative stress, and mitochondrial dysfunction [30]. In AD, the differential expression of genes can affect different signaling pathways [31]. As expected, our analysis showed that chronic noise exerted a multi-level effect on the acceleration of AD progress, which indicated that chronic noise exposure accelerated AD progress to a certain extent.

Our finding that AD-related genes [32‐36], including Egr2, Fos, Arc, Hmgcr, Nuak1, Egr1, Hap1, Per2. Egr2, Fos, Arc, and Hmgcr, show significant differential expression in noise-exposed mice lends support to the idea that environmental hazards including noise exposure may promote the occurrence and development of AD. Egr is a transcription factor and belongs to the family of immediate early genes induced by serum, which is closely related to the differentiation of some tissues and cells and is expressed in the early stage of central nervous system development, which promotes the formation of afterbrain. Upregulation of phagocytic markers Egr2 was observed in Aβ plaque-associated microglia, which reflects an attempt to enhance phagocytosis in plaque-associated microglia [37]. Egr-1 mRNA level is fourfold higher in AD brain than in non-AD brain, and the Egr-1 level is high in brain areas with high NFT density [38]. The overexpression of Egr-1 in rat brain could promote tau phosphorylation at Ser396/404 and Ser262 [39]. In the present study, we found an increase in the phosphorylation levels of tau protein at the Ser202 and Ser404 sites in the noise and aging groups. These alterations were also concomitant with the overexpression of Egr-1 after the end of the stimulus. Furthermore, lasting increase in Fos was found to occur in close correspondence with increase in tau hyperphosphorylation.

Aβ precursor protein (APP) metabolism engages neuronal endolysosomal pathways for Aβ processing and secretion. In AD, the dysregulation of APP leads to excess Aβ. Hap1 may promote the trafficking of APP into the non-amyloidogenic pathway and reduce the production of Aβ [40]. In the present study, the amount of Aβ increased when Hap1 was decreased; hence, regulating Hap1 expression may help to control Aβ production and affect the development of AD. In our previous study, following noise stress, we detected significantly higher levels not only in Aβ but also in the phosphorylation of tau [16, 17, 28, 41]. Our findings indicate that the long-lasting changes in tau phosphorylation observed after chronic noise exposure are likely to be the result of a complex regulatory network of multiple signaling pathways.

Due to the consideration of the influence of too many factors on the results of transcriptome, we did not use wild-type mice to set up the normal control group, which may affect the in-depth analysis of the research results. Additionally, the dose-response relationship of noise exposure was not considered in this study. More perfect experiments will be designed according to the important clues and limitations of the present study.

In summary, our results show the exacerbation of aging-like impairment following chronic noise exposure, as well as candidate genes mediating AD-like pathological changes in the hippocampus of noise-exposed SAMP8 mice. We also identify significant associations of genes with specific molecular pathway, which may be key candidate regulators involved in environment-gene interactions, and suggest that a more detailed look into the underlying mechanism of AD pathogenesis is warranted. Further detailed studies are required to clarify the molecular mechanisms underlying the regulation of the multifaceted signaling system in AD etiology.