Renal fibrosis is a hallmark of progressive chronic kidney disease (CKD), with emerging evidence linking gut microbiota dysbiosis to disease progression. Myeloid-derived suppressor cells (MDSCs) have demonstrated renoprotective effects, yet the impact of fecal microbiota transplantation (FMT) on MDSC-mediated modulation of renal fibrosis remains unclear.

C57BL/6J mice underwent unilateral ureteral obstruction (UUO) to induce renal fibrosis, followed by FMT administration via gavage. Flow cytometry was used to quantify granulocytic (G-MDSCs) and monocytic (M-MDSCs) MDSC populations in peripheral blood, kidney, and spleen. To elucidate the role of MDSCs in FMT-mediated effects, MDSCs were depleted or adoptively transferred in vivo. Renal fibrosis severity and inflammatory cytokine expression were subsequently analyzed.

FMT altered MDSC distribution, increasing M-MDSC accumulation in the blood and kidney. This was associated with downregulation of proinflammatory cytokines and attenuation of renal fibrosis. Adoptive MDSC transfer similarly produced anti-inflammatory and antifibrotic effects, reinforcing their therapeutic role in FMT-mediated renal protection.

FMT enhances M-MDSC-mediated immunomodulation, reducing inflammation and renal fibrosis in UUO-induced CKD. These findings suggest a potential therapeutic strategy targeting the gut-kidney axis in CKD management.

JOURNAL/nrgr/04.03/01300535-202510000-00028/figure1/v/2024-11-26T163120Z/r/image-tiff Alzheimer's disease not only affects the brain, but also induces metabolic dysfunction in peripheral organs and alters the gut microbiota. The aim of this study was to investigate systemic changes that occur in Alzheimer's disease, in particular the association between changes in peripheral organ metabolism, changes in gut microbial composition, and Alzheimer's disease development. To do this, we analyzed peripheral organ metabolism and the gut microbiota in amyloid precursor protein-presenilin 1 (APP/PS1) transgenic and control mice at 3, 6, 9, and 12 months of age. Twelve-month-old APP/PS1 mice exhibited cognitive impairment, Alzheimer's disease-related brain changes, distinctive metabolic disturbances in peripheral organs and fecal samples (as detected by untargeted metabolomics sequencing), and substantial changes in gut microbial composition compared with younger APP/PS1 mice. Notably, a strong correlation emerged between the gut microbiota and kidney metabolism in APP/PS1 mice. These findings suggest that alterations in peripheral organ metabolism and the gut microbiota are closely related to Alzheimer's disease development, indicating potential new directions for therapeutic strategies.

The leaves of Shiliangcha (an alternative tea, Chimonanthus salicifolius), a perennial bush cultivated in Lishui, Zhejiang, have been used for thousands of years by the She ethnic group as an herb and tea. Chimonanthus salicifolius flavonoids (CsFE) have exhibited remarkable antiaging properties. Therefore, we established a d-galactose (d_Gal)-induced aging mouse model to investigate the effect of CsFE on the central nervous system (CNS) of aging hosts. Supplementation with CsFE effectively alleviated symptoms of aging in mice, including weight loss, declining learning and memory capacity, blood-brain barrier (BBB) integrity, release of pro-inflammatory cytokines, oxidative stress, neuroinflammation, and microglia activation. Additionally, CsFE alleviated cognitive deficits by interfering with synaptic plasticity-associated protein levels, altering neuronal excitability, and affecting intracellular neurotransmitters glutamate (Glu) and γ-aminobutyric acid (GABA) release. Furthermore, CsFE supplementation modulated gut microbiota composition by enriching probiotics Akkermansia, Muribaculaceae, Lactobacillus, and Lachnospiraceae, promoting the production of short-chain fatty acids (SCFAs). Therefore, this study suggested that CsFE has the potential to resist brain aging through intervention of the microbiota-gut-brain axis (GBA), which provides a theoretical basis for the development of natural drugs and dietary supplements for antiaging.

The gut-brain axis has emerged as a key player in the regulation of brain function and cognitive health. Gut microbiota dysbiosis has been observed in preclinical models of Alzheimer's disease and patients. Manipulating the composition of the gut microbiota enhances or delays neuropathology and cognitive deficits in mouse models. Accordingly, the health status of the animal facility may strongly influence these outcomes. In the present study, we longitudinally analyzed the fecal microbiota composition and amyloid pathology of 5XFAD mice housed in a specific opportunistic pathogen-free (SOPF) and a conventional facility. The composition of the microbiota of 5XFAD mice after aging in conventional facility showed marked differences compared to WT littermates that were not observed when the mice were bred in SOPF facility. The development of amyloid pathology was also enhanced by conventional housing. We then transplanted fecal microbiota (FMT) from both sources into wild-type (WT) mice and measured memory performance, assessed in the novel object recognition test, in transplanted animals. Mice transplanted with microbiota from conventionally bred 5XFAD mice showed impaired memory performance, whereas FMT from mice housed in SOPF facility did not induce memory deficits in transplanted mice. Finally, 18 weeks of housing SOPF-born animals in a conventional facility resulted in the reappearance of specific microbiota compositions in 5XFAD vs WT mice. In conclusion, these results show a strong impact of housing conditions on microbiota-associated phenotypes and question the relevance of breeding preclinical models in specific pathogen-free (SPF) facilities.

Housing conditions affect the composition of the gut microbiota. Gut microbiota of 6-month-old conventionally bred Alzheimer's mice is dysbiotic. Gut dysbiosis is absent in Alzheimer's mice housed in highly sanitized facilities. Transfer of fecal microbiota from conventionally bred mice affects cognition. Microbiota of mice housed in highly sanitized facilities has no effect on cognition.

Accumulating evidence implicates both the brain-spleen axis and the gut microbiota-brain axis in Alzheimer's disease (AD) pathogenesis. While our previous work demonstrated heterophyllin B (HB) rectifies splenic Th1/Th2 imbalance and ameliorates cognitive deficits in Aβ1-42-induced AD mice, its potential modulation of the vagus nerve-spleen circuit remains unexplored.

Using 8-month-old male APP/PS1 mice with/without splenic denervation (SD), we systematically investigated HB's therapeutic mechanisms via the spleen-gut microbiota-brain axis. Cognitive function was assessed through novel object recognition (ORT) and object location memory (OLT) tests. Immunofluorescence (IF) and enzyme-linked immunosorbent assay (ELISA) were employed to analyze Aβ plaques, phosphorylated tau (p-Tau) levels, and associated neuroinflammatory responses. Flow cytometry was utilized to examine the subtypes of splenic lymphocytes. Hematoxylin and eosin (H&E) staining, along with immunohistochemical (IHC) experiments, was conducted to evaluate the protective effects of HB on the intestinal barrier. Gut microbiota composition was analyzed using 16S rRNA sequencing.

HB administration significantly improved cognitive performance (ORT discrimination index: +28.7 %; OLT discrimination index: +26.6 %), reduced brain and serum Aβ1-42 and p-Tau levels, downregulated the Th1/Th2 ratio in the spleen, and alleviated intestinal permeability and neuroinflammation, which were abolished in SD APP/PS1 mice. Gut microbiota shifts showed HB-induced enrichment of cognition-associated Dubosiella and Muribaculaceae, with concurrent suppression of pathogenic Lachnospiraceae_NK4A136 and ASF356.

This study provides first evidence that HB ameliorates AD pathology through vagus nerve-dependent regulation of the spleen-gut microbiota-brain axis, establishing its multimodal therapeutic potential for neural-immune-gut circuit modulation in neurodegenerative diseases.

Some Alzheimer's disease (AD) patients report gastro-intestinal symptoms and present alterations in the gut microbiota (GM) composition. Elevated colonic amyloid immunoreactivity has been shown in patients and animal models. We evaluated the colonic uptake of the amyloid positron emission tomography (PET) imaging agent [18F]flutemetamol (FMM) in a memory clinic population and investigated its association with brain amyloidosis and GM composition.

Forty-five participants underwent (i) abdominal and cerebral FMM PET, acquired at 40 (early phase) and 120 min (late phase) after tracer injection, (ii) abdominal computed tomography, and (iii) cerebral T1-weighted MRI. Colonic standardized uptake value ratio (SUVr) was determined through manual tracing and automatic segmentation (TotalSegmentator), using the aortic blood signal as a reference region. Fecal GM composition was assessed using 16 S rRNA sequencing. Amyloid positive (A+) and negative (A-) participants, based on cortical FMM quantification (PetSurfer), were compared in terms of SUVr and GM features.

Increased colonic early SUVr was reported in A+ than A- (manual, p =.008; automated, p =.035). Altered GM composition was found in A + as shown by lower Pielou's evenness (p =.023), lower abundance of Eubacterium hallii group, and higher abundance of several genera. High UC5-1-2E3 abundance positively correlated with high colonic early SUVr (whole group: manual, p =.012, automated, p =.082; A+: manual, p =.074; automated, p =.016).

This exploratory study showed that subjects with cerebral amyloidosis have greater colonic FMM uptake than subjects with normal cerebral amyloid load, correlating with altered GM composition. Further analysis is needed to determine if these changes denote amyloid-related changes or other phenomena.

Type 2 diabetes mellitus (T2DM) is associated with an increased risk of cognitive decline, which can result in diabetic cognitive impairment (DCI). Recent studies have indicated that gut microbiota plays a significant role in the development of DCI. Tangliping Decoction (TLP), a traditional Chinese medicine compound, contains various active ingredients that have been shown to regulate the microecology of gut microbiota and potentially improve DCI. However, it remains unclear whether TLP can improve DCI by modulating gut microbiota, as well as which specific component is primarily responsible for these effects.

Assess the impact of TLP on alleviating DCI and investigate the contribution of quercetin (QR), the core blood-absorbed component of TLP, in this process. and investigate the underlying mechanisms through which TLP and QR enhance DCI by modulating gut microbiota composition.

Initially, experiments such as morris water maze (MWM), morphological analysis, and 16S ribosomal RNA (16S rRNA) gene amplicon sequencing from DCI mice, were performed to validate the pharmacological efficacy of TLP in mitigating DCI. The results indicated that TLP possesses the capacity to modulate the composition and quantity of gut microbiota and safeguard the integrity of the gut barrier and brain barrier. Secondly, high performance liquid chromatography coupled with high-performance liquid chromatography-quadrupole time-of-flight mass spectrometry (HPLC-Q-TOF-MS/MS) combined with network pharmacology methods were used to screen for blood-absorbed components, suggesting that QR may be a potential core blood-absorbed component of TLP in the treatment of DCI. Subsequently, the pharmacological efficacy of QR in ameliorating DCI was confirmed, and the characteristics of gut microbiota as well as the permeability of the gut and brain barrier, were assessed. Finally, fecal microbiota transplantation (FMT) experiments were conducted, wherein fecal matter from TLP and QR-treated mice (donor mice) was transplanted into pseudo-sterile DCI mice with antibiotic-induced depletion of gut microbiota. This approach aimed to elucidate the specific mechanisms by which TLP and QR improve DCI through the modulation of the structure, composition, and abundance of gut microbiota.

TLP and QR have the potential to enhance learning and memory capabilities in DCI mice, as well as reduce homeostasis model assessment insulin resistance (HOMA-IR) and restore homeostasis model assessment-β function (HOMA- β), leading to increased fasting insulin (FIN) levels and decreased fasting blood glucose (FBG) levels. Simultaneously, the administration of FMT from donor mice to pseudo-sterile DCI mice has been shown to alter the composition and abundance of gut microbiota, leading to amelioration of pathological damage in the colon and hippocampal tissues. Ultimately, FMT utilizing fecal suspensions from donor mice treated with TLP and QR improved cognitive function in pseudo-sterile DCI mice, restore gut microbiota dysbiosis, and maintained the integrity of the gut and brain barriers.

The results of this study indicate that TLP and its core component, QR, which is absorbed into the bloodstream, improve DCI through a gut microbiota-dependent mechanism, providing further evidence for gut microbiota as a therapeutic target for DCI treatment.

Microglia, the major population of brain resident macrophages, differentiate from yolk sac progenitors in the embryo and play multiple nonimmune roles in brain organization throughout development and life. Various microglia subtypes have been described by transcriptomic and proteomic signatures, involved metabolic pathways, morphology, intracellular complexity, time of residency, and ontogeny, both in development and in disease settings. Such macrophage heterogeneity increases with aging or neurodegeneration. Monocytes' infiltration and differentiation into monocyte-derived macrophages (MDMs) in the brain contribute to this diversity. Microbiota's role in brain diseases has been recently highlighted, revealing how microbial signals, such as metabolites, influence microglia and MDMs. In this brief review, we describe how these signals can influence microglia through their sensome and shape MDMs from their development in the bone marrow to their differentiation in the brain. Monocytes could then be a crucial player in the constitution of a dysbiotic gut-brain axis in neurodegenerative diseases and aging.

Alzheimer's disease (AD), a prevalent neurodegenerative disorder, represents a significant global health challenge, characterized by cognitive decline and neuroinflammation. Recent investigations have highlighted the critical role of the gut-brain axis in the pathogenesis of AD, particularly focusing on the influence of short-chain fatty acids (SCFAs), metabolites produced by the gut microbiota through the fermentation of dietary fiber. Among SCFAs, butyrate has emerged as a crucial mediator, positively impacting various pathological processes associated with AD, including epigenetic regulation, neuroinflammation modulation, maintenance of the blood-brain barrier (BBB), enhanced intestinal integrity, regulation of brain metabolism, and interference with amyloid protein formation as well as tau protein hyperphosphorylation. Furthermore, distinctions in butyrate profile and microbial communities have been observed between AD patients and healthy individuals, underscoring the importance of gut microbiota in AD progression. This review summarizes the current understanding of the many functions of butyrate in reducing the consequences of AD and emphasizes the possibility of addressing the gut microbiota as a therapeutic approach to managing AD.

Observational research suggests that mental diseases may increase the risk of gastrointestinal diseases. However, the causal link between these conditions remains unclear. In this study, we conducted a two-sample Mendelian randomization (MR) analysis to investigate the causal associations between common mental diseases and the risk of gastrointestinal diseases.

First, a series of parameters were set to select single-nucleotide polymorphisms (SNPs) from genome-wide association studies (GWAS). Second, A two-sample Mendelian randomization analysis was conducted to investigate the causal link between mental diseases (Alzheimer's disease, depression, major depressive disorder, Parkinson's disease, schizophrenia) and gastrointestinal diseases (gastritis and duodenitis, gastric cancer) while removing outliers using MR-PRESSO. Finally, eight methods of MR analysis were used to generate forest plots, including inverse variance weighted (IVW), inverse variance weighted (fixed effects) (IVW fixed effects), maximum likelihood (ML), MR-Egger, weighted median, penalized weighted median, simple mode, and weighted mode, with IVW considered the primary method.

The result demonstrated that most MDs have no evidence of a causal link between gastrointestinal diseases except Parkinson's disease and gastric cancer based on the IVW method (OR = 0.929 [95% CI = 0.869-0.992], p = 0.029). Subsequently, we performed a robustness analysis to ensure consistency.

Our method provided evidence supporting a causal link between Parkinson's disease and the risk of gastric cancer. However, no evidence was found for other mental diseases influencing the risk of gastrointestinal diseases. Further research is warranted to explore how mental diseases affect the development of gastrointestinal diseases.

The disorder of the intestinal fungal community is closely associated with Alzheimer's disease (AD). Gut fungal dysbiosis exacerbates β-amyloid (Aβ) plaque burden through the brain-gut axis, thereby promoting the progression of AD. Previous research has demonstrated that acupuncture can ameliorate AD symptoms by modulating the gut bacterial community. However, the potential regulatory effects of acupuncture on the fungal microbiota have been largely overlooked.

APP/PS1 mice were used as AD animal model and randomly divided into the AD model (AD) group, the acupuncture (Ac) group, and the probiotics (Pr) group. Mice in the Ac group received acupuncture treatment. In the Pr group, mice were treated with probiotics. Morris water maze, ITS sequencing, immunofluorescence (IF) staining, enzyme-linked immunosorbent assay (ELISA), Hematoxylin and eosin analysis, and Nissl staining were employed to validate our hypothesis.

Acupuncture and probiotics significantly improved the behavioral performance of APP/PS1 mice, reduced the level of Aβ in the brain, and alleviated neuronal damage. Moreover, acupuncture improved the Sobs, Chao and Ace indices, decreased the abundance of Ascomycota, Aspergilaceae, Trichocomaceae, Candida, and unclassified-penicillium, while simultaneously increasing the abundance of Basidiomycota, which differed from the fungal regulation observed with probiotics.

Acupuncture may improve the cognitive impairment of APP/PS1 mice, reduce Aβ plaque burden in the brain, protect neurons, and mitigate intestinal fungi dysbiosis. The beneficial effects of acupuncture on Aβ deposition and cognitive function in APP/PS1 mice may be achieved by regulating the intestinal fungal community.

Amyloid beta (Aβ) is the primary early biomarker of Alzheimer's disease (AD), and since an acidic environment promotes Aβ aggregation, acidification plays a crucial role in AD progression. In this study, a novel acid-responsive near-infrared (NIR) fluorescent probe alongside multiple molecular biology techniques to investigate the temporal relationship between acidification and Aβ deposition, as well as the underlying mechanisms of acidification is employed. By monitoring 2- to 11-month-old APP/PS1 mice and wild-type (WT) mice, it is detected significant fluorescence signal in APP/PS1 mice beginning at 3 months preceding Aβ deposition at 5 months, and peaking at 5 months, followed by cognitive deficits at 8 months. Additionally, elevated monocarboxylate transporter 4 (MCT4) protein expression in 3-month-old APP/PS1 mice indicated disruption of astrocyte-neuron lactate shuttle (ANLS) homeostasis. Overall, this findings first demonstrate that acidification precedes Aβ deposition, peaks at the onset of Aβ deposition, and diminishes thereafter, with early acidification likely driven by the disruption of ANLS.

Traumatic brain injury (TBI) is a major global disability and mortality cause, with the gut-brain axis playing a crucial role in its pathophysiology. Neuroinflammation, triggered by microglia and astrocytes, contributes to neuronal damage and cognitive impairment. This paper aims to explore the relationship between the gut-brain axis and neuroinflammation in TBI and its potential implications for therapeutic interventions. A comprehensive review of the literature was conducted using PubMed, MEDLINE, and Google Scholar databases. Studies investigating the gut-brain axis, neuroinflammation, and TBI were included. Evidence suggests that TBI disrupts the gut-brain axis, leading to alterations in gut microbiota composition, intestinal permeability, and immune responses. These gut-related changes promote the activation of microglia and astrocytes in the central nervous system, contributing to neuroinflammation and neuronal damage. Conversely, interventions that modulate gut microbiota or reduce intestinal permeability have been shown to attenuate neuroinflammation and improve cognitive outcomes in TBI models. The gut-brain axis plays a significant role in the pathogenesis of neuroinflammation following TBI. Targeting the gut-brain axis through interventions that restore gut homeostasis and reduce intestinal permeability holds promise as a novel therapeutic strategy for mitigating neuroinflammation and improving cognitive function in TBI patients. Further research is needed to elucidate the specific mechanisms involved and to develop effective therapies based on this understanding.

Gut microbiota and microRNAs (miRNAs) have been proved to be intimately involved in dementia. Our previous studies have showed that oxysterols and the subsequent neurotoxic effects contributed to the pathogenesis of cognitive decline. However, the exact mechanism linking dietary oxysterol-induced cognitive changes, gut microbiota, and miRNAs remains elusive. Here, two sets of experiments were conducted on male C57BL/6J mice treated with mixed-oxysterol diet or 27-hydroxycholesterol (27-OHC) combined with antibiotic cocktails and miRNA antagonists. Neurobehavioral tests were conducted to assess learning and memory of mice. 16S ribosomal DNA gene sequencing was performed to evaluate microbial diversity and community composition. Oxysterol levels were detected using HPLC-MS. Western blotting and RT-qPCR were used to detect the expression of the intestinal barrier-related factors. We found that a 0.05% mixed-oxysterol diet altered the gut microbiota, damaged the intestinal barrier, upregulated the expression of miR-144-3p, and resulted in learning and memory impairment, while depleting the gut microbiota with antibiotic cocktails partly alleviated these injuries. Moreover, there were enhanced Aβ deposition, as well as higher 27-OHC and its metabolite in the brain of oxysterols-treated mice, which could be reduced by sterol 27-hydroxylase inhibitor-anastrozole, indicating that 27-OHC might be the key regulator of oxysterol-induced brain pathological changes. Additionally, by antagonizing miR-144-3p, microbiota dysbiosis-related Aβ deposition, oxysterol load, and cognitive decline were significantly ameliorated. Taken together, our study demonstrates that dietary oxysterols impair cognitive function through 27-OHC causing microbiota dysbiosis and intestinal barrier dysfunction, targeting miR-144-3p might be a promising strategy against cognitive impairment.

Postoperative neurocognitive disorders (PND) represent a significant challenge affecting patients undergoing surgical procedures, particularly in the elderly population. These disorders can lead to profound impairments in cognitive function, impacting memory, attention, and overall quality of life. Despite ongoing research efforts to identify risk factors and improve management strategies, PND remains underdiagnosed and poorly understood, complicating postoperative recovery and rehabilitation. This review aims to explore the recent advancement in the literature about PND, focusing on the underlying mechanisms, risk factors, and potential therapeutic approaches. We highlight recent advancements in the understanding of neuroinflammation, and it is implications for novel therapies to prevent PND. By synthesizing the latest research, we hope to provide insights that could lead to improved outcomes for patients at risk for PND and foster a shift towards more effective preventive measures in such population.

Polystyrene micro/nanoplastics (MPs/NPs) are globally recognized environmental concerns due to their widespread pollution and detrimental effects on physiological functions. However, the neurotoxic effects and underlying mechanisms of MPs/NPs on brain function in adolescents remain incompletely understood. This study investigated the effects of polystyrene MPs/NPs on neurobehavioral function in adolescent mice, utilizing multi-omic analysis and molecular biology assays to explore potential mechanisms. Following oral exposure of MPs (5 μm) or NPs (0.5 μm) at 0.5 mg/day for 4 weeks, NPs induced more severe cognitive impairment in mice than MPs, as assessed by the Morris water maze and Y-maze tests. This impairment might be associated with the neuron loss and neurogenesis inhibition caused by NPs, while dendritic spine loss mediated by MPs in the hippocampus. Furthermore, analysis of hippocampal transcriptome and Western blotting indicated the potential involvement of the PI3K/AKT pathway in NPs-induced neurotoxicity. Meanwhile, exposure to NPs induced more pronounced disruptions in the hippocampal metabolome and gut microbiota, and strong correlations were observed between changes in hippocampal metabolites and gut bacteria. This study elucidated the toxicity mechanism of MPs and NPs in inducing cognitive impairment in adolescent mice, providing insights into their toxicological impacts and potential strategies for intervention.

The gut microbiota, the complex community of microorganisms that inhabit the gastrointestinal tract, has emerged as a key player in the pathogenesis of neurodegenerative disorders, including Alzheimer's disease (AD). AD is characterized by progressive cognitive decline and neuronal loss, associated with the accumulation of amyloid-β plaques, neurofibrillary tangles, and neuroinflammation in the brain. Increasing evidence suggests that alterations in the composition and function of the gut microbiota, known as dysbiosis, may contribute to the development and progression of AD by modulating neuroinflammation, a chronic and maladaptive immune response in the central nervous system. This review aims to comprehensively analyze the current role of the gut microbiota in regulating neuroinflammation and glial cell function in AD. Its objective is to deepen our understanding of the pathogenesis of AD and to discuss the potential advantages and challenges of using gut microbiota modulation as a novel approach for the diagnosis, treatment, and prevention of AD.

Under normal physiological conditions, gut microbiota and host mutually coexist. They play key roles in maintaining intestinal barrier integrity, absorption, and metabolism, as well as promoting the development of the central nervous system (CNS) and emotional regulation. The dysregulation of gut microbiota homeostasis has attracted significant research interest, specifically in its impact on neurological and psychiatric disorders. Recent studies have highlighted the important role of the gut- brain axis in conditions including Alzheimer's Disease (AD), Parkinson's Disease (PD), and depression. This review aims to elucidate the regulatory mechanisms by which gut microbiota affect the progression of CNS disorders via the gut-brain axis. Additionally, we discuss the current research landscape, identify gaps, and propose future directions for microbial interventions against these diseases. Finally, we provide a theoretical reference for clinical treatment strategies and drug development for AD, PD, and depression.

spinal cord injury (SCI) disrupts the gut microbiota, worsening the injury's impact. Fecal microbiota transplantation (FMT) is increasingly recognized as a promising strategy to improve neural function post-SCI, yet its precise mechanisms are still far from clear. The present study aims to elucidate how FMT influences motor function recovery and its underlying mechanisms utilizing a SCI mouse model.

Mice with SCI received FMT from healthy donors. We used 16 S rRNA amplicon sequencing to analyze the alterations of gut microbes. Pathological alterations in the spinal cord tissue, including neuronal survival, axonal regeneration, cell proliferation, and neuroinflammation, were assessed among experimental groups. Additionally, RNA sequencing (RNA-seq) was used to explore alterations in relevant signaling pathways.

Significant shifts in gut microbiota composition following SCI were observed through 16 S rRNA analysis. On day 7 post-SCI, the FMT group exhibited a significantly higher diversity of gut microbiota compared to the ABX group, with the composition in the FMT group more closely resembling that of healthy mice. FMT promoted neuronal survival and axonal regeneration, leading to notable improvements in motor function compared to control mice. Immunofluorescence staining showed increased neuronal survival, alleviated extracellular matrix (ECM) deposition, diminished glial scar formation, and reduced inflammation in FMT-treated mice. RNA-seq analysis indicated that FMT induced transcriptomic changes associated with material metabolism, ECM remodeling, and anti-inflammatory responses.

FMT restored gut microbiota balance in SCI mice, mitigated inflammation, and promoted ECM remodeling, establishing an optimal environment for neural recovery. These findings demonstrated that FMT may represent a valuable approach to enhance functional recovery following SCI.

The mechanisms underlying the protective effect of the e2 variant of the APOE gene (APOEe2) against Alzheimer's disease (AD) have not been elucidated. We altered the microbiota of 3xTgAD mice by fecal microbiota transplantation from a human APOEe2 donor (e2-FMT) and tested the effect of microbiota perturbations on brain AD pathology.

FMT of bacteria isolated from stools of untreated 3xTgAD mice (M-FMT) or e2-FMT were transplanted in 15-month-old 3xTgAD mice. FMT was done alone or in combination with antibiotic and proton-pump inhibitor following the Microbiota Transfer Therapy protocol (MTT). The effect of donor (M or e2) and transplantation protocol (FMT or MTT) on hippocampal amyloid, tau pathology and neuroinflammation were assessed at the end of the treatment.

e2-FMT reduced amyloid, and tau pathology as well as increased neuroinflammation as compared with M-FMT. MTT was associated with reduced number of Aβ40+ plaques and tau pathology. Low levels of amyloid were associated with high levels of pro-inflammatory molecules in e2-FMT mice. These associations were partially attenuated by MTT.

Bacteria from a human APOEe2 donor reduced AD pathology and increased neuroinflammation in mice suggesting that the gut microbiota may be a mediator of the protective effect of APOEe2.

Hypoxia is a predominant risk factor at high altitudes, and evidence suggests that high-altitude hypoxia alters the gut microbiota, which plays an essential regulatory role in memory function. However, the causal relationship between the gut microbiota and memory impairment under hypoxic conditions remains unclear. In this study, we employed a high-altitude hypoxia model combined with fecal microbiota transplantation (FMT) approach in mice to explore the effects of the gut microbiota on memory impairment in a hypoxic environment. We observed that high-altitude hypoxia exposure reduced short- and long-term memory and hippocampus-dependent fear memory abilities, along with decreased relative abundance of Ligilactobacillus and Muribaculum. Moreover, hypoxic conditions increased intestinal and blood-brain barrier permeability. FMT from hypoxia-exposed mice into naïve antibiotic-treated mice resulted in similar memory impairments, Ligilactobacillus and Muribaculum abundance changes, and increased intestinal/blood-brain barrier permeability. Correlation analysis showed a robust positive association between Ligilactobacillus and Muribaculum with hippocampus-dependent contextual fear memory. Likewise, Ligilactobacillus was positively correlated with short-term memory. Therefore, Ligilactobacillus and Muribaculum may be key microbes in reducing memory ability in hypoxia, with the intestinal and blood-brain barriers as primary pathways. Our findings provide further evidence for the potential regulatory mechanism by which gut microbiota dysbiosis may contribute to memory impairment in a high-altitude environment.

Accumulating evidence suggests that gut microbiota (GM) plays a crucial role in Alzheimer's disease (AD) pathogenesis and progression. This narrative review explores the complex interplay between GM, the immune system, and the central nervous system in AD. We discuss mechanisms through which GM dysbiosis can compromise intestinal barrier integrity, enabling pro-inflammatory molecules and metabolites to enter systemic circulation and the brain, potentially contributing to AD hallmarks. Additionally, we examine other pathophysiological mechanisms by which GM may influence AD risk, including the production of short-chain fatty acids, secondary bile acids, and tryptophan metabolites. The role of the vagus nerve in gut-brain communication is also addressed. We highlight potential therapeutic implications of targeting GM in AD, focusing on antibiotics, probiotics, prebiotics, postbiotics, phytochemicals, and fecal microbiota transplantation. While preclinical studies showed promise, clinical evidence remains limited and inconsistent. We critically assess clinical trials, emphasizing challenges in translating GM-based therapies to AD patients. The reviewed evidence underscores the need for further research to elucidate precise molecular mechanisms linking GM to AD and determine whether GM dysbiosis is a contributing factor or consequence of AD pathology. Future studies should focus on large-scale clinical trials to validate GM-based interventions' efficacy and safety in AD.

Human microbiota-associated murine models, using fecal microbiota transplantation (FMT) from human donors, help explore the microbiome's role in diseases like Alzheimer's disease (AD). This study examines how gut bacteria from donors with protective factors against AD influence behavior and brain pathology in an AD mouse model. Female 3xTgAD mice received weekly FMT for 2 months from (i) an 80-year-old AD patient (AD-FMT), (ii) a cognitively healthy 73-year-old with the protective APOEe2 allele (APOEe2-FMT), (iii) a 22-year-old healthy donor (Young-FMT), and (iv) untreated mice (Mice-FMT). Behavioral assessments included novel object recognition (NOR), Y-maze, open-field, and elevated plus maze tests; brain pathology (amyloid and tau), neuroinflammation (in situ autoradiography of the 18 kDa translocator protein in the hippocampus); and gut microbiota were analyzed. APOEe2-FMT improved short-term memory in the NOR test compared to AD-FMT, without significant changes in other behavioral tests. This was associated with increased neuroinflammation in the hippocampus, but no effect was detected on brain amyloidosis and tauopathy. Specific genera, such as Parabacteroides and Prevotellaceae_UGC001, were enriched in the APOEe2-FMT group and associated with neuroinflammation, while genera like Desulfovibrio were reduced and linked to decreased neuroinflammation. Gut microbiota from a donor with a protective factor against AD improved short-term memory and induced neuroinflammation in regions strategic to AD. The association of several genera with neuroinflammation in the APOEe2-FMT group suggests a collegial effect of the transplanted microbiome rather than a single-microbe driver effect. These data support an association between gut bacteria, glial cell activation, and cognitive function in AD.

Canine cognitive dysfunction (CCD) is the dog version of human Alzheimer's disease (AD), and it has strikingly similar pathological features to those of this neurodegenerative disorder. The gastrointestinal system is in constant communication with the brain via several conduits collectively termed the gut-brain axis. The microbial population of the gut, referred to as the microbiota, has a profound effect on the interactions that occur along this communication route. Recent evidence suggests that dysbiosis, an abnormal gastrointestinal microbial population, is linked to cognitive impairment in rodent AD models and human AD. There is also evidence from rodent AD models that correcting dysbiosis by transferring fecal material from healthy donors to the gastrointestinal tracts of cognitively impaired recipients [fecal microbiome transplantation (FMT)] reverses AD-associated brain pathology and improves cognitive function. Although limited, some clinical reports have described the improvement of cognitive function with FMT in human AD. The goals of this review article are to provide an overview of the mechanisms involved in dysbiosis- associated cognitive decline and the role of FMT in therapy for such decline. The potential role of FMT in CCD is also discussed.

Microorganisms in the gut play a pivotal role in human health, influencing various pathophysiological processes. Certain microorganisms are particularly essential for maintaining intestinal homeostasis, reducing inflammation, supporting nervous system function, and regulating metabolic processes. Short-chain fatty acids (SCFAs) are a subset of fatty acids produced by the gut microbiota (GM) during the fermentation of indigestible polysaccharides. The interaction between GM and SCFAs is inherently bidirectional: the GM not only shapes SCFAs composition and metabolism but SCFAs also modulate microbiota's diversity, stability, growth, proliferation, and metabolism. Recent research has shown that GM and SCFAs communicate through various pathways, mainly involving mechanisms related to inflammation and immune responses, intestinal barrier function, the gut-brain axis, and metabolic regulation. An imbalance in GM and SCFA homeostasis can lead to the development of several chronic diseases, including inflammatory bowel disease, colorectal cancer, systemic lupus erythematosus, Alzheimer's disease, and type 2 diabetes mellitus. This review explores the synergistic interactions between GM and SCFAs, and how these interactions directly or indirectly influence the onset and progression of various diseases through the regulation of the mechanisms mentioned above.

A growing body of evidence suggests a link between the gut microbiota and Alzheimer's disease (AD), although the underlying mechanisms remain elusive. This study aimed to investigate the impact of fecal microbiota transplantation (FMT) on cognitive function in a mouse model of AD.

Four-month-old 5 × FAD (familial Alzheimer's disease) mice underwent antibiotic treatment to deplete their native gut microbiota. Subsequently, they received FMT either weekly or every other day. After 8 weeks, cognitive function and β-amyloid (Aβ) load were assessed through behavioral testing and pathological analysis, respectively. The composition of the gut microbiota was analyzed using 16S rRNA sequencing.

Initial weekly FMT failed to alleviate memory deficits or reduce brain Aβ pathology in 5 × FAD mice. In contrast, FMT administered every other day effectively restored gut dysbiosis in 5 × FAD mice and decreased Aβ pathology and lipopolysaccharide levels in the colon and hippocampus. Mechanistically, FMT reduced the expression of amyloid β precursor protein, β-site APP cleaving enzyme 1, and presenilin-1, potentially by inhibiting the Toll-like receptor 4/inhibitor of kappa B kinase β/nuclear factor kappa-B signaling pathway. However, the cognitive benefits of FMT on 5 × FAD mice diminished over time.

These findings demonstrate the dose- and time-dependent efficacy of FMT in mitigating AD-like pathology, underscoring the potential of targeting the gut microbiota for AD treatment.

Alzheimer's disease (AD) is a neurodegenerative disorder characterized by cognitive decline and progressive neuronal damage. Recent research has highlighted the significant roles of the gut microbiota and microRNAs (miRNAs) in the pathogenesis of AD. This review explores the intricate interaction between gut microbiota and miRNAs, emphasizing their combined impact on Alzheimer's progression. First, we discuss the bidirectional communication within the gut-brain axis and how gut dysbiosis contributes to neuroinflammation and neurodegeneration in AD. Changes in gut microbiota composition in Alzheimer's patients have been linked to inflammation, which exacerbates disease progression. Next, we delve into the biology of miRNAs, focusing on their roles in gene regulation, neurodevelopment, and neurodegeneration. Dysregulated miRNAs are implicated in AD pathogenesis, influencing key processes like inflammation, tau pathology, and amyloid deposition. We then examine how the gut microbiota modulates miRNA expression, particularly in the brain, potentially altering neuroinflammatory responses and synaptic plasticity. The interplay between gut microbiota and miRNAs also affects blood-brain barrier integrity, further contributing to Alzheimer's pathology. Lastly, we explore therapeutic strategies targeting this gut microbiota-miRNA axis, including probiotics, prebiotics, and dietary interventions, aiming to modulate miRNA expression and improve AD outcomes. While promising, challenges remain in fully elucidating these interactions and translating them into effective therapies. This review highlights the importance of understanding the gut microbiota-miRNA relationship in AD, offering potential pathways for novel therapeutic approaches aimed at mitigating the disease's progression.

Alzheimer's disease (AD) is a prevalent neurodegenerative disease (ND). In recent years, multiple clinical and animal studies have shown that mitochondrial dysfunction may be involved in the pathogenesis of AD. In addition, short-chain fatty acids (SCFA) produced by intestinal microbiota metabolism have been considered to be important factors affecting central nervous system (CNS) homeostasis. Among the main mediators of host-microbe interactions, volatile fatty acids play a crucial role. Nevertheless, the influence and pathways of microorganisms and their metabolites on Alzheimer's disease (AD) remain uncertain.

In this study, we present distinctions in blood and fecal SCFA levels and microbiota composition between healthy individuals and those diagnosed with AD. We found that AD patients showed a decrease in the abundance of Akkermansia muciniphila and a decrease in propionic acid both in fecal and in blood. In order to further reveal the effects and the mechanisms of propionic acid on AD prevention, we systematically explored the effects of propionic acid administration on AD model mice and cultured hippocampal neuronal cells. Results showed that oral propionate supplementation ameliorated cognitive impairment in AD mice. Propionate downregulated mitochondrial fission protein (DRP1) via G-protein coupled receptor 41 (GPR41) and enhanced PINK1/PARKIN-mediated mitophagy via G-protein coupled receptor 43 (GPR43) in AD pathophysiology which contribute to maintaining mitochondrial homeostasis both in vivo and in vitro. Administered A. muciniphila to AD mice before disease onset showed improved cognition, mitochondrial division and mitophagy in AD mice.

Taken together, our results demonstrate that A. muciniphila and its metabolite propionate protect against AD-like pathological events in AD mouse models by targeting mitochondrial homeostasis, making them promising therapeutic candidates for the prevention and treatment of AD. Video Abstract.

Alzheimer's disease (AD), the most common form of dementia, is a progressive neurodegenerative disorder that profoundly impacts cognitive function and the nervous system. Emerging evidence highlights the pivotal roles of iron homeostasis dysregulation and microbial inflammatory factors in the oral and gut microbiome as potential contributors to the pathogenesis of AD. Iron homeostasis disruption can result in excessive intracellular iron accumulation, promoting the generation of reactive oxygen species (ROS) and oxidative damage. Additionally, inflammatory agents produced by pathogenic bacteria may enter the body via two primary pathways: directly through the gut or indirectly via the oral cavity, entering the bloodstream and reaching the brain. This infiltration disrupts cellular homeostasis, induces neuroinflammation, and exacerbates AD-related pathology. Addressing these mechanisms through personalized treatment strategies that target the underlying causes of AD could play a critical role in preventing its onset and progression.

Alzheimer's disease (AD) is a prevalent and progressive neurodegenerative disorder that is the leading cause of dementia. The underlying mechanisms of AD have not yet been completely explored. Neuroinflammation, an inflammatory response mediated by certain mediators, has been exhibited to play a crucial role in the pathogenesis of AD. Additionally, disruption of the gut microbiota has been found to be associated with AD, and fecal microbiota transplantation (FMT) has emerged as a potential therapeutic approach. However, the precise mechanism of FMT in the treatment of AD remains elusive. In this study, FMT was performed by transplanting fecal microbiota from healthy wild-type mice into APP/PS1 mice (APPswe, PSEN1dE9) to assess the effectiveness of FMT in mitigating AD-associated inflammation and to reveal its precise mechanism of action. The results demonstrated that FMT treatment improved cognitive function and reduced the expression levels of inflammatory factors by regulating the TLR4/MyD88/NF-κB signaling pathway in mice, which was accompanied by the restoration of gut microbial dysbiosis. These findings suggest that FMT has the potential to ameliorate AD symptoms and delay the disease progression in APP/PS1 mice.

For decades, Alzheimer's Disease (AD) research has focused on the amyloid cascade hypothesis, which identifies amyloid-beta (Aβ) as the primary driver of the disease. However, the consistent failure of Aβ-targeted therapies to demonstrate efficacy, coupled with significant safety concerns, underscores the need to rethink our approach to AD treatment. Emerging evidence points to microbial infections as environmental factors in AD pathoetiology. Although a definitive causal link remains unestablished, the collective evidence is compelling. This review explores unconventional perspectives and emerging paradigms regarding microbial involvement in AD pathogenesis, emphasizing the gut-brain axis, brain biofilms, the oral microbiome, and viral infections. Transgenic mouse models show that gut microbiota dysregulation precedes brain Aβ accumulation, emphasizing gut-brain signaling pathways. Viral infections like Herpes Simplex Virus Type 1 (HSV-1) and Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) may lead to AD by modulating host processes like the immune system. Aβ peptide's antimicrobial function as a response to microbial infection might inadvertently promote AD. We discuss potential microbiome-based therapies as promising strategies for managing and potentially preventing AD progression. Fecal microbiota transplantation (FMT) restores gut microbial balance, reduces Aβ accumulation, and improves cognition in preclinical models. Probiotics and prebiotics reduce neuroinflammation and Aβ plaques, while antiviral therapies targeting HSV-1 and vaccines like the shingles vaccine show potential to mitigate AD pathology. Developing effective treatments requires standardized methods to identify and measure microbial infections in AD patients, enabling personalized therapies that address individual microbial contributions to AD pathogenesis. Further research is needed to clarify the interactions between microbes and Aβ, explore bacterial and viral interplay, and understand their broader effects on host processes to translate these insights into clinical interventions.

Alzheimer's disease (AD) is marked by impaired cognitive functions, particularly in learning and memory, owing to complex and diverse mechanisms. Methionine restriction (MR) has been found to exert a mitigating effect on brain oxidative stress to improve AD. However, the bidirectional crosstalk between the gut and brain through which MR enhances learning and memory in AD, as well as the effects of fecal microbiota transplantation (FMT) from MR mice on AD mice, remains underexplored. In this study, APP/PS1 double transgenic AD mice were used and an FMT experiment was conducted. 16S rRNA gene sequencing, targeted metabolomics, and microbial metabolite short-chain fatty acids (SCFAs) of feces samples were analyzed. The results showed that MR reversed the reduction in SCFAs induced by AD, and further activated the free fatty acid receptors, FFAR2 and FFAR3, as well as the transport protein MCT1, thereby signaling to the brain to mitigate inflammation and enhance the learning and memory capabilities. Furthermore, the FMT experiment from methionine-restricted diet mouse donors showed that mice receiving FMT ameliorated Alzheimer's learning and memory ability through SCFAs. This study offers novel non-pharmaceutical intervention strategies for AD prevention.

With the continuous increase of the elderly population, there is an urgency to understand and develop relevant treatments for Alzheimer's disease and related dementias (ADRD). In tandem with this, the prevalence of health inequities continues to rise as disadvantaged communities fail to be included in mainstream research. The neural exposome poses as a relevant mechanistic approach and tool for investigating ADRD onset, progression, and pathology as it accounts for several different factors: exogenous, endogenous, and behavioral. Consequently, through the neural exposome, health inequities can be addressed in ADRD research. In this paper, we address how the neural exposome relates to ADRD by contributing to the discourse through defining how the neural exposome can be developed as a tool in accordance with machine learning. Through this, machine learning can allow for developing a greater insight into the application of transferring and making sense of experimental mouse models exposed to health inequities and potentially relate it to humans. The overall goal moving beyond this paper is to define a multitude of potential factors that can increase the risk of ADRD onset and integrate them to create an interdisciplinary approach to the study of ADRD and subsequently translate the findings to clinical research.

The complex gut microbiome influences host aging and plays an important role in the manifestation of age-related diseases. Restoring a healthy gut microbiome via Fecal Microbiota Transplantation (FMT) is receiving extensive consideration to therapeutically transfer healthy longevity. Herein, we comprehensively review the benefits of gut microbial rejuvenation - via FMT - to promote healthy aging, with few studies documenting life length properties. This review explores how preconditioning donors via standard - lifestyle and pharmacological - antiaging interventions reshape gut microbiome, with the resulting benefits being also FMT-transferable. Finally, we expose the current clinical uses of FMT in the context of aging therapy and address FMT challenges - regulatory landscape, protocol standardization, and health risks - that require refinement to effectively utilize microbiome interventions in the elderly.

Radiation therapy is widely recognized as an efficacious modality for treating neoplasms located within the craniofacial region. Nevertheless, this approach is not devoid of risks, predominantly concerning potential harm to the neural structures. Adverse effects may encompass focal cerebral necrosis, cognitive function compromise, cerebrovascular pathology, spinal cord injury, and detriment to the neural fibers constituting the brachial plexus. With increasing survival rates among oncology patients, evaluating post-treatment quality of life has become crucial in assessing the benefits of radiation therapy. Consequently, it is imperative to investigate therapeutic strategies to mitigate cerebral complications from radiation exposure. Current management of radiation-induced cerebral damage involves corticosteroids and bevacizumab, with preclinical research on antioxidants and thalidomide. Despite these efforts, an optimal treatment remains elusive. Recent studies suggest the gut microbiota's involvement in neurologic pathologies. This review aims to discuss the causes and existing treatments for radiation-induced cerebral injury and explore gut microbiota modulation as a potential therapeutic strategy.

The innate immune response aims to prevent pathogens from entering the organism and/or to facilitate pathogen clearance. Innate immune cells, such as macrophages, mast cells (MCs), natural killer cells and neutrophils, bear pattern recognition receptors and are thus able to recognize common molecular patterns, such as pathogen-associated molecular patterns (PAMPs), and damage-associated molecular patterns (DAMPs), the later occurring in the context of neuroinflammation. An inflammatory component in the pathology of otherwise "primary cerebrovascular and neurodegenerative" disease has recently been recognized and targeted as a means of therapeutic intervention. Activated MCs are multifunctional effector cells generated from hematopoietic stem cells that, together with dendritic cells, represent first-line immune defense mechanisms against pathogens and/or tissue destruction.

This review aims to summarize evidence of MC implication in the pathogenesis of neurodegenerative diseases, namely, Alzheimer's disease, Parkinson's disease, amyotrophic lateral sclerosis, Huntington's disease, and multiple sclerosis.

In view of recent evidence that the gut-brain axis may be implicated in the pathogenesis of neurodegenerative diseases and the characterization of the neuroinflammatory component in the pathology of these diseases, this review also focuses on MCs as potential mediators in the gut-brain axis bi-directional communication and the possible role of Helicobacter pylori, a gastric pathogen known to alter the gut-brain axis homeostasis towards local and systemic pro-inflammatory responses.

As MCs and Helicobacter pylori infection may offer targets of intervention with potential therapeutic implications for neurodegenerative disease, more clinical and translational evidence is needed to elucidate this field.

Alzheimer's Disease (AD) is a neurodegenerative disorder marked by cognitive decline, for which effective treatments remain elusive due to complex pathogenesis. Recent advances in neuroimaging, gene therapy, and gut microbiota research offer new insights and potential intervention strategies. Neuroimaging enables early detection and staging of AD through visualization of biomarkers, aiding diagnosis and tracking of disease progression. Gene therapy presents a promising approach for modifying AD-related genetic expressions, targeting amyloid and tau pathology, and potentially repairing neuronal damage. Furthermore, emerging evidence suggests that the gut microbiota influences AD pathology through the gut-brain axis, impacting inflammation, immune response, and amyloid metabolism. However, each of these technologies faces significant challenges, including concerns about safety, efficacy, and ethical considerations. This article reviews the applications, advantages, and limitations of neuroimaging, gene therapy, and gut microbiota research in AD, with a particular focus on their combined potential for early diagnosis, mechanistic insights, and therapeutic interventions. We propose an integrated approach that leverages these tools to provide a multi-dimensional framework for advancing AD diagnosis, treatment, and prevention.