Synergistic Effects of Plant Polysaccharides and Probiotics: A Novel Dietary Approach for Parkinson’s Disease Intervention

The microbial-gut-brain axis (MGBA) plays a pivotal role in health and in numerous diseases, including neuropsychiatric disorders. Research in this field is being conducted extensively and rapidly. The MGBA refers to a complex bidirectional communication system between gut microbiota and the brain, primarily exchanging information through multiple pathways including neural, neuroactive molecules, immune, and endocrine systems (Figure 1).

Parkinson's disease (PD) is characterized by abnormal aggregation of α-synuclein (α-syn) affecting all levels of the mind-gut-brain axis (MGBA). This abnormal aggregation disrupts bidirectional communication between the brain and gut, and MGBA dysfunction is considered a key driver in the onset and progression of PD.

PD is not a monolithic disorder but a syndrome with diverse clinical and pathological subtypes, which may differentially affect MGBA integrity and response to therapeutic strategies. Parkinson's Disease (PD) is not a single disease entity but a complex syndrome exhibiting high heterogeneity in clinical symptoms, pathological progression, biochemical alterations, and genetic background (Table 2). This heterogeneity directly impacts the efficacy of any intervention strategy, including Synthroids [96]. The classification of PD subtypes has evolved from a purely clinical phenotype to a multidimensional system integrating biomarkers. Based on predominant symptoms, it is primarily divided into two categories: motor subtypes—tremor-dominant, postural instability/gait disorder, and mixed [97]. Non-motor subtypes: include rapid eye movement sleep behavior disorder (RBD)-predominant, cognitive impairment (e.g., mild cognitive impairment)-predominant, autonomic dysfunction (e.g., severe constipation, orthostatic hypotension)-predominant, and depression/anxiety-predominant [98]. Research has found that after 12 weeks of probiotic supplementation in patients with TD-type PD, not only did constipation symptoms show significant improvement (as assessed by the Constipation Rating Scale), but the amplitude of resting tremor (measured using wearable accelerometers) also exhibited a decreasing trend [99]. Researchers speculate that this may be related to probiotics modulating gamma-aminobutyric acid (GABA) or glutamatergic neurotransmission within the thalamocortical circuits associated with tremor generation. This modulation may originate from the regulation of vagal afferents or systemic immunity by gut microbiota metabolites, such as short-chain fatty acids. The TD subtype is considered to have a relatively benign disease course and involve fewer pathologies beyond dopaminergic neuron loss. Synbiotic formulations targeting this subtype may focus on improving intestinal motility and reducing local oxidative stress, thereby potentially stabilizing the influence of peripheral nerve activity on central motor circuits. For the PIGD/cognitive impairment subtype, synbiotic formulations should be specifically targeted toward "neuroprotection" and "anti-inflammation". For example, combining probiotics capable of strongly stimulating butyrate production with medicinal plant polysaccharides possessing systemic anti-inflammatory effects may synergistically downregulate neuroinflammation possessing systemic anti-inflammatory effects may synergistically downregulate neuroinflammation, thereby providing a more favorable microenvironment for dopaminergic neurons and cognition-related brain regions. For RBD or PD patients exhibiting RBD features, synbiotics should aim beyond symptom management to target α-synuclein aggregation and propagation [100]. Research indicates that certain probiotics can produce enzymes capable of degrading α-synuclein oligomers, while some plant polysaccharides have been demonstrated to inhibit the misfolding and aggregation of α-synuclein. Combining these elements may constitute an entirely novel "neuropathology-targeted" synbiotic. Here, the role of medicinal plant polysaccharides as prebiotics is crucial [101,102]. For example, dietary fibers such as konjac glucomannan and inulin have been proven to effectively promote intestinal motility and increase stool bulk. Combining them with probiotics that metabolize these polysaccharides to produce gas and short-chain fatty acids—further stimulating intestinal peristalsis, creating a potent "motility-promoting synbiotic" that specifically alleviates this core symptom [103,104]. In summary, the clinical and pathological subtype differences in PD profoundly influence the dysregulation patterns of the gut-brain axis, thereby determining the efficacy of microbial intervention strategies represented by synbiotics.

The starting point of probiotic intervention lies in reshaping the disrupted gut microbiota structure in Parkinson's Disease. Studies have shown that specific probiotic strains can effectively inhibit the growth of pathogenic bacteria such as Desulfovibrio (a genus that produces pro-inflammatory hydrogen sulfide) through mechanisms like competitive colonization and the secretion of antimicrobial peptides. Concurrently, they significantly increase the abundance of beneficial bacteria like Akkermansia, Bifidobacterium, and Lactobacillus [123]. Akkermansia is closely associated with improvements in intestinal barrier function and immunomodulation. This suggests that the benefits of probiotics may be partially achieved by modulating the host's native beneficial microbiota, highlighting their systemic impact on the microecosystem [124]. This ecological restructuring not only restores microbial diversity but, more critically, optimizes its overall metabolic functionality. Among these, short-chain fatty acids represent the most pivotal metabolic products. Strains such as Bifidobacterium breve and Clostridium butyricum are highly efficient at fermenting dietary fiber, leading to substantial production of butyrate, acetate, and propionate [125]. At the mechanistic level, researchers have discovered that certain specific probiotic strains (e.g., Lactococcus lactis) can secrete a small molecular peptide that specifically inhibits the fibrillation process of α-synuclein, thereby preventing the formation of toxic aggregates [125].

As mentioned earlier, probiotic fermentation of dietary fiber produces short-chain fatty acids, among which acetate, propionate, and butyrate serve as the most crucial signaling molecules mediating the "gut-brain dialogue". They not only serve as an energy source for intestinal epithelial cells but also enter the circulatory system, exerting systemic and central nervous system protective effects through multiple mechanisms [126]. Recent studies have demonstrated that probiotic intervention can significantly increase the concentrations of butyrate, acetate, and propionate in PD mice [127]. Simultaneously, butyric acid supplementation significantly mitigates damage to dopaminergic neuronal cell lines induced by lipopolysaccharide and TNF-α. This mechanism has been demonstrated to involve both the inhibition of histone deacetylase activity and the activation of the Nrf2 antioxidant pathway—the latter being a key defense system for cellular resistance against oxidative stress [128]. Direct injection of sodium propionate into the lateral ventricles of PD model rats significantly reduced glial cell activation and astrocytic proliferation in the substantia nigra region while lowering levels of proinflammatory factors TNF-α and IL-6. This effect was partially mediated through activation of the G protein-coupled receptor GPR43 on microglia, demonstrating that SCFAs can directly act on the brain to exert anti-neuroinflammatory effects [129].

Probiotics and metabolites can jointly function through various mechanisms, significantly strengthen the advocacy of physical barriers, and indirectly benefit the integrity of the blood-brain barrier, thus effectively preventing peripheral pathological factors from entering the systemic circulation and central nervous system. Lactobacillus rhamnosus LGG treatment can significantly up-regulate the mRNA and protein expression levels of key tight junction proteins Occludin and ZO-1 in colon tissue of PD mice, and at the same time reduce serum levels of endotoxin and inflammatory markers, effectively reducing intestinal permeability [130]. Metabolites of probiotics activate GPR109A receptors in intestinal epithelial cells, which in turn up-regulate the expression of closure proteins [131]. At the blood-brain barrier level, PD model rats treated with Lactobacillus plantarum PS128 have significantly improved the leakage of the blood-brain barrier in the substantia nigra region of the brain, which may indirectly stabilize the function of the blood-brain barrier by reducing systemic inflammation and reducing the damage of pro-inflammatory cytokines to the endothelial cells of the blood-brain barrier [132]. At the same time, probiotics can regulate the expression of vascular endothelial growth factor in brain through vagus nerve pathway, thus enhancing the integrity of blood-brain barrier [133]. In addition, long-term supplementation of probiotics can significantly increase the expression of tight junction protein in brain microvascular endothelial cells and maintain the homeostasis of blood-brain barrier by regulating the activity of microglia [134].

The ultimate protective effect of probiotics manifests in their direct or indirect regulation of central nervous system function, which represents the final link in their therapeutic action against Parkinson's Disease. Its primary functions include promoting the expression of neurotrophic factors, regulating neurotransmitter balance [135], and even directly influencing neuronal survival. These effects are partially mediated through the MGBA. Concurrently, the expression of brain-derived neurotrophic factor (BDNF) and glial cell-derived neurotrophic factor (GDNF) is upregulated [136]. Bifidobacterium breve CCFM1067 promotes GDNF expression in the substantia nigra region of mouse brains by increasing gut-derived serotonin (5-HT) and subsequently activating vagus nerve-dependent pathways, ultimately protecting dopaminergic neurons from damage [137]. Lactobacillus rhamnosus increases the utilization of tryptophan, the precursor of 5-HT, in the colonic mucosa and brain of mice, and elevates central 5-HT levels [138]. Beyond monoaminergic neurotransmitters, probiotics can also modulate other neurotransmitter systems. Researchers found that supplementing PD model mice with a composite probiotic containing Lactobacillus and Bifidobacterium reversed disease-induced glutamate/GABA imbalance in the cortex and hippocampus, reducing elevated glutamate levels. This may help mitigate excitotoxicity and protect neurons [132].

Alpha diversity of the gut microbiota serves as the gold standard indicator for assessing microbial health and stability. Plant polysaccharides exert profound effects on the composition and organization of the gut microbiota. They can serve as carbon sources, enrich beneficial gut microorganisms, or regulate the development, activity, and synthesis of microbial metabolites. Additionally, in a rat model of type 2 diabetes, intervention with Phellinus linteus polysaccharides increased short-chain fatty acid (SCFA) biosynthesis and bile acid (BA) metabolism, thereby promoting GLP-1 secretion. This subsequently enhanced insulin release and reduced blood glucose levels [163]. High-throughput sequencing analysis reveals that Ziziphus jujuba polysaccharides can prevent colon cancer by improving cancer-induced dysbiosis in the gut microbiota, demonstrating significant prebiotic effects [164]. The mechanism lies in the fact that Astragalus polysaccharides are rich in polysaccharide chains such as (1→4)-glucose and (1→6)-galactose, whereas Ganoderma lucidum polysaccharides primarily consist of β-(1→3)/(1→6)-glucan as their main chain. The diversity of this structure necessitates the synergistic utilization of multiple microorganisms with distinct enzymatic profiles to convert polysaccharides into prebiotics beneficial to the host. Metatranscriptomic analysis revealed that following intervention with Astragalus polysaccharides and Codonopsis polysaccharides, the expression of carbohydrate-active enzyme genes involved in polysaccharide degradation was significantly upregulated in the gut microbiota of mice. This was particularly evident in the GH family from the Bacteroidetes phylum and glycoside hydrolases from the Firmicutes phylum [165]. During the degradation of kelp polysaccharides, microbial communities first target the readily degradable alginic acid before processing the structurally more complex fucoidans [166]. This synergistic activation of the multi-enzyme system enables microorganisms from different metabolic lineages—such as Bacteroides, Prevotella, and Bifidobacterium—to obtain the carbon sources necessary for their growth. Treatment with donkey-hide gelatin polysaccharides in type 2 diabetic mice significantly reversed alterations in bacterial species and metabolites observed in diseased mice. Furthermore, 16S rDNA sequencing analysis demonstrated that Angelica sinensis polysaccharides can reshape gut microbiota composition, thereby reducing joint swelling in rheumatoid arthritis and significantly suppressing anti-CII antibodies and proinflammatory factors [167].

Building upon the enhancement of gut microbiota diversity, plant polysaccharides can further finely regulate the structure of microbial communities at the phylum and genus levels [168]. On one hand, they can specifically enrich beneficial microbial communities. For instance, at the phylum level, plant polysaccharides effectively regulate key microbial ratios. Studies indicate that intervention with Astragalus polysaccharides significantly increased the Firmicutes/Bacteroidetes ratio in the intestines of normal mice while markedly reducing the relative abundance of the Proteobacteria phylum [169]. Similarly, in models of gut microbiota dysbiosis and intestinal barrier dysfunction induced by broad-spectrum antibiotics, bamboo fungus polysaccharides can restore disrupted gut microbial composition (including regulating the Firmicutes/Bacteroidetes ratio and reducing the relative abundance of harmful phyla such as Proteobacteria, Enterococcus, and Bacteroides) [170]. Ganoderma polysaccharides enhanced the microbial diversity and proportion of Pseudomonas and Bacillus species, significantly enriching Ovalibacillus and Bacillus uniformis [171]. Notably, the regulatory effects of different herbal polysaccharides exhibit specificity. Researchers compared the actions of four common herbal polysaccharides and found that Dioscorea polysaccharide uniquely increased the relative abundance of Proteobacteria while reducing the proportions of Ascomycota and Bacteroidetes. This may be related to its distinctive monosaccharide composition [172]. At the species level, the enrichment effect of Chinese herbal polysaccharides on specific beneficial bacteria is more pronounced. Multiple studies have confirmed their promotion of Akkermansia: research reports indicate that ginger polysaccharides significantly increase the relative abundance of Akkermansia in the intestines of obese mice [173]. Following intervention with prickly pear polysaccharides, the abundance of Akkermansia increased, accompanied by a marked improvement in the thickness of the intestinal mucus layer [174]. Moreover, the regulatory effect of Chinese herbal polysaccharides on short-chain fatty acid-producing bacterial communities is particularly pronounced. Following intervention with Astragalus polysaccharides, the abundance of short-chain fatty acid-producing bacterial communities—such as the genera Clostridium, Faecalibacterium, Akkermansia, Lactobacillus, and Ruminococcus—all exhibited an upward trend. Fecal analysis revealed that following supplementation with Astragalus polysaccharides, acetic acid, propionic acid, and butyric acid levels significantly increased in mice with adenine-induced chronic kidney disease (CKD) models (Ade) [175]. Similarly, it was found that Ganoderma lucidum polysaccharide intervention increased the abundance of Lactobacillus, Bacteroides, and Bacteroides fragilis, while also elevating levels of short-chain fatty acids (SCFAs) in feces [176]. While promoting the growth of beneficial bacteria, plant polysaccharides effectively suppress potential pathogens through multiple mechanisms. Astragalus polysaccharides can significantly reduce the abundance of Shigella, a potentially pathogenic intestinal bacterium. This effect is closely associated with their promotion of Lactobacillus growth and lactic acid secretion [177]. Rhubarb polysaccharide supplementation modulates the gut microbiota by enriching beneficial genera such as Lactobacillus and Akkermansia, while reducing pathogenic genera like Clostridium difficile and Desulfovibrio [178].

An intact intestinal barrier serves as a physical defense against the translocation of intestinal endotoxins, such as lipopolysaccharide (LPS), which can trigger systemic neuroinflammation. Plant polysaccharides reinforce this defense through multiple pathways. Firstly, during their degradation by gut microbiota, carbohydrate-active enzymes and genes associated with butyrate production are upregulated. The resulting butyrate serves as a crucial energy source for colonic epithelial cells, which significantly enhances the mRNA expression of tight junction proteins (e.g., ZO-1, Occludin, Claudin-1) and reduces inflammatory responses, thereby improving intestinal barrier function [179,180]. Secondly, certain polysaccharides mitigate cyclophosphamide (CPM)-induced intestinal mucosal damage and increase the number of jejunal goblet cells, thereby promoting the synthesis and secretion of mucin-2 and thickening the protective mucus layer [181]. The synergistic action of both components effectively reduces intestinal permeability and repairs the "leaky gut." Plant polysaccharides exhibit significant specificity in regulating intestinal tight junction proteins. Studies indicate that Atractylodes polysaccharides effectively enhance immune organ indices and blood cell counts, stimulate cytokine secretion, and promote the expression of occludin and tight junction protein-1 (ZO-1), while significantly reducing lipopolysaccharide-induced epithelial permeability [160]. Mushroom polysaccharides rich in β-glucan significantly upregulate the gene expression of tight junction proteins in lipopolysaccharide (LPS)-stimulated Caco-2 cells, demonstrating their potential to improve intestinal barrier dysfunction [182]. Additionally, longan pulp polysaccharides can prevent intestinal mucosal damage by increasing the expression of mucin 2, tight junction protein ZO-1, claudin-1, claudin-4, and adhesion junction protein E-cadherin [183]. It is noteworthy that the mechanisms of action vary among different plant polysaccharides. Comparative studies reveal that Codonopsis polysaccharides promote epithelial cell proliferation and differentiation by bidirectionally regulating the Wnt/β-catenin signaling pathway, thereby upregulating the transcription and expression of tight junction proteins such as ZO-1 and Occludin. Astragalus polysaccharides may mitigate the degradation of tight junction proteins by inhibiting JNK phosphorylation [184]. Ganoderma lucidum polysaccharides can also maintain intestinal barrier function by increasing the expression of Wnt/β-Catenin and Lrp5 proteins [185]. Lycium polysaccharides significantly prolonged the survival time of septic mice by regulating inflammatory responses and inhibiting JNK pathway activation, while also improving the animals' digestive function and intestinal barrier integrity [186]. Regarding the mucosal barrier, plant polysaccharides demonstrate significant promotional effects. Research indicates that Hericium erinaceus polysaccharides can enhance levels of secretory immunoglobulin A (SIgA) and cytokines secreted by the intestinal mucosal immune system in Muscovy ducks, while simultaneously repairing damaged intestinal mucosal immune barriers [187]. Further research confirms that Artemisia annua L. polysaccharides can enhance the intestinal physical barrier by downregulating serum ET levels and increasing the villus height/crypt depth (VH/CD) ratio and ZO-1 mRNA levels in broiler chickens challenged with Escherichia coli. Additionally, they elevate VH/CD ratios and mRNA levels of Occludin, ZO-1, and Mucin-2 in non-challenged broilers [188]. Experimental evidence also confirms that plant polysaccharides indirectly enhance barrier function by regulating microbiota metabolism. Metabolomics analysis revealed that raspberry polysaccharide intervention increased butyrate concentrations in mouse intestines, showing a significant positive correlation with enhanced tight junction protein expression [189]. The anti-inflammatory effects of plant polysaccharides play a crucial role in barrier protection. Studies have found that polysaccharides derived from rapeseed and algae can significantly reduce serum levels of endotoxin, DAO, and D-lactic acid [190,191]. Particularly noteworthy is the multi-target synergistic mechanism of Chinese herbal polysaccharides. Comprehensive studies indicate that polysaccharides not only directly upregulate tight junction protein expression but also promote short-chain fatty acid (SCFA) production by modulating the gut microbiota while simultaneously inhibiting the NF-κB inflammatory pathway, thereby establishing a triple protective mechanism [191]. Recent research further reveals that Astragalus polysaccharides can enhance intestinal barrier function systemically by modulating the gut microbiota-bile acid-FXR axis [192].

The systemic regulatory role of plant polysaccharides in host immunity and metabolism demonstrates their multifaceted value as "immunometabolic modulators". This regulation is achieved not only through indirect pathways mediated by the gut microbiota but also through the direct effects of polysaccharide molecules on immune cells. Multiple studies have revealed the direct immunomodulatory mechanisms of plant polysaccharides at the molecular level. For instance, Astragalus polysaccharides can dose-dependently inhibit LPS-induced NF-κB p65 nuclear translocation in RAW264.7 macrophages, thereby reducing the secretion of TNF-α and IL-6 [193], and can also reduce IL-1β maturation and release by inhibiting NLRP3 inflammasome assembly and decreasing caspase-1 activity [194]. Research has also reported that Astragalus polysaccharides can reduce chondrocyte apoptosis by activating the thioredoxin system and inhibiting the ASK1/p38 signaling pathway [195]. Additionally, in MPTP-induced silkworm Parkinson's Disease models, administration of Lycium polysaccharide improved motor function, dopamine levels, and TH activity, while simultaneously reducing oxidative damage [196]. The exocarp polysaccharides from red tangerines significantly alleviated Parkinson's Disease symptoms and improved behavioral deficits by modulating the HDAC6/NLRP3 pathway in Parkinson's Disease mice [197]. Yuzhu polysaccharides significantly enhanced the activity of antioxidant enzymes superoxide dismutase (SOD), glutathione peroxidase (GSH-Px), and catalase (CAT), reduced malondialdehyde (MDA) levels, and reversed the expression of oxidative stress-related proteins Nrf2 and Keap1 in the substantia nigra pars compacta (SNc) of PD mice. Furthermore, Yuzhu polysaccharide treatment significantly suppressed MPTP-induced neurotoxicity, markedly alleviated weight loss and motor dysfunction, and mitigated the loss of dopaminergic neurons in the SNc of PD mice. Concurrently, it reduced the expression levels of pro-apoptotic proteins Bax and cleaved caspase-3 while elevating the expression of the anti-apoptotic protein Bcl-2 [198]. The effects of plant polysaccharides on immune cell differentiation have been validated in multiple studies. Treatment with Astragalus polysaccharides significantly improved immune cell differentiation in cyclophosphamide-induced immunosuppressed mice, restoring the numbers of CD4+ T cells, CD8+ T cells, CD19+ B cells, and F4/80 + CD11B+ macrophages to normal levels [199]. At the metabolic level, Astragalus polysaccharides significantly improve polyunsaturated fatty acid metabolism, balancing the ratio of linoleic acid to α-linolenic acid in serum. Additionally, different plant polysaccharides exhibit unique immunomodulatory properties. Research indicates that Ganoderma lucidum polysaccharide peptides significantly elevate serum levels of TNF-α, IFN-γ, IL-2, and immunoglobulin A in immunosuppressed mice [200]. Lycium polysaccharides exert anti-inflammatory effects by regulating macrophage polarization toward the M2 type through inhibiting STAT1 phosphorylation (65.3% reduction) and promoting STAT6 phosphorylation (2.2-fold increase) [201]. The mechanism by which plant polysaccharides influence systemic immunity through modulating gut microbiota has also been extensively studied. Research indicates that Poria cocos polysaccharides can restore intestinal and pulmonary microbial diversity in cyclosporine A-induced immunosuppressed mice, significantly improving lung tissue damage. This effect is closely associated with the normalization of serum metabolite profiles [202]. Recent studies indicate that yam polysaccharides significantly enhance the efficacy of PD-1 monoclonal antibodies in treating colorectal cancer by inhibiting M2 macrophage polarization through reducing the abundance of the gut microbial metabolite deoxyribose [203]. Panax ginseng polysaccharides can stimulate immune cells and promote the release of immune factors, thereby regulating immune function. GPNE-I, a component of Panax ginseng polysaccharides, promotes lymphocyte proliferation and acts as an immunomodulator [151]. Advances in multi-omics research have provided more comprehensive evidence for the systemic regulatory effects of plant polysaccharides. By integrating metagenomics, metabolomics, and transcriptomics data, a holistic network was constructed showing how mulberry leaf polysaccharides regulate the "gut microbiota-metabolite-immune axis". This revealed that they can influence hepatic immune responses by promoting the growth of butyrate-producing bacteria and modulating bile acid metabolism [204]. Similarly, the dynamic changes in gut microbiota mediated by shiitake mushroom polysaccharides effectively regulate lipid metabolism in high-fat diet (HFD)-fed obese mouse models [205].

Multiple in vivo studies confirm that the combination of Chinese herbal polysaccharides and probiotics effectively enhances the survival and colonization levels of the latter in disease model intestines, directly contributing to the restoration of the intestinal barrier. The co-administration of Lactobacillus plantarum and Astragalus polysaccharides significantly improves intestinal health in mice with antibiotic-associated diarrhea (AAD). This study not only observed significantly higher levels of lactobacilli in the intestines of the synbiotic group compared to the single probiotic group, but more importantly, immunofluorescence and Western blot analyses revealed that synbiotic treatment significantly upregulated the expression of tight junction proteins (such as Occludin and ZO-1) in colonic tissue. Mechanistic studies suggest this barrier repair effect may be partially mediated through activation of the TGF-β/Smad signaling pathway. Spearman correlation analysis further revealed that increased gut lactobacilli abundance positively correlated with barrier function indicators while negatively correlating with permeability factors like serum endotoxin levels, directly demonstrating the link between enhanced probiotic colonization and improved host physiology [206]. A combination of Lycium polysaccharides and Japanese kelp polysaccharides was obtained via enzyme-assisted acid extraction, yielding two pectin-type Lycium polysaccharides rich in rhamnogalacturonic acid I and two fucoidan-type Japanese kelp polysaccharides. These were paired to form four proportional mixtures. This approach efficiently targets and promotes the proliferation of Bifidobacteria, Lactobacillus, and Bacteroides, enhancing the production of short-chain fatty acids and non-short-chain fatty acid health-related metabolites. It also stimulates the accumulation of butyrate-producing bacteria and their metabolites [207]. A study on the synergistic effects of alginate polysaccharides and Lactobacillus plantarum in colitis-affected mice revealed that compared to monotherapy with probiotics, the combined intervention significantly increased the abundance of beneficial bacteria such as Lactobacillus and Bifidobacterium in the gut of colitis mice while more effectively suppressing the proliferation of pathogenic bacteria. This reshaping of the microbial community structure occurred concurrently with reduced colonic inflammation scores and lessened histological damage, demonstrating the synbiotic's ability to enhance probiotic efficacy in disease conditions by promoting the colonization of beneficial bacteria in DSS-induced colitis [208]. Probiotic powder containing Poria cocos polysaccharides demonstrated superior efficacy compared to probiotic powder without Poria cocos polysaccharides in improving immune regulation and gut microbiota in mice with antibiotic-associated diarrhea. It significantly increased Proteobacteria such as Sutterella and reduced Bacteroidetes such as Muribaculaceae, effectively suppressing dysbiosis induced by diarrhea in mice [208]. Feeding a diet containing both probiotics and a Astragalus polysaccharides resulted in significant differences in Lactobacillus, Bacillus cereus, and Escherichia coli counts compared to diets containing either probiotics or Astragalus polysaccharides alone. The numbers of Lactobacillus and Bifidobacterium increased, while Escherichia coli counts decreased [209]. Fermentation of bamboo shoot polysaccharides with Streptococcus thermophilus produced fermented milk that significantly promoted the proliferation of Streptococcus thermophilus, Lactobacillus bulgaricus, and Bifidobacterium longum F2, while enhancing acetic acid production and imparting a distinctive flavor [210].

Metabolites produced by gut microbiota serve as key mediators regulating host physiology, with short-chain fatty acids (SCFAs) being one of the most important "messengers" among them. The synergistic effect of plant polysaccharides and probiotics lies in significantly enhancing the "production" of SCFAs and optimizing their "composition spectrum," which forms the metabolic basis for their systemic probiotic effects. When probiotics are ingested alone, their ability to produce SCFAs is constrained by available substrates. Conversely, when polysaccharides are ingested alone, the depth of fermentation and the spectrum of products are highly dependent on the host's inherent microbial structure—a structure that is often impaired in Parkinson's Disease. The synbiotics strategy ingeniously combines the strengths of both approaches. Research reveals that Lactobacillus plantarum utilizes its abundant glycosidase enzymes (such as α-galactosidase and β-mannanase) to preliminarily degrade the complex side chains within Astragalus polysaccharides. These degradation products not only serve as nutrients for the bacteria themselves but, more importantly, provide more readily available substrates for specialized SCFA-producing commensal bacteria in the gut, such as Propionibacterium and Rectobacterium [211,212,213]. In vitro co-culture and colitis mouse models demonstrated that compared to supplementation with Astragalus polysaccharides alone, synbiotic intervention increased concentrations of total SCFAs, butyrate, and propionate in colonic contents while simultaneously upregulating the abundance of key metabolic genes such as butyrate kinase (buk) within the microbiota. In rat models, the combination of Crataegus microphylla crude polysaccharides with probiotics (containing Bifidobacterium and Lactobacillus) significantly outperformed single components in increasing total intestinal acetate, propionate, and butyrate levels. Metagenomic analysis revealed that the synbiotic regimen significantly upregulated gene clusters associated with acetyl-CoA transferase and butyrate kinase in the gut microbiota. These changes were strongly correlated with elevated SCFA levels and reduced serum inflammatory markers, directly linking synergistic metabolism to host benefits at the functional gene level [214]. During fermentation using polysaccharides, probiotics themselves produce organic acids (such as lactic acid), lowering the local pH. This further shapes a microenvironment conducive to the growth of SCFA-producing bacteria (many of which are strict anaerobes) and may inhibit pathogenic bacteria. Research indicates that Sanghuang Feng polysaccharides effectively promote the proliferation of Lactobacillus plantarum and Lactobacillus rhamnosus while lowering the culture medium pH, which suggests that these probiotics utilize the polysaccharides as a carbon source for fermentation and SCFA production [215]. The synergistic interaction between beneficial gut microbiota and shiitake mushroom polysaccharides generates substantial amounts of short-chain fatty acids (SCFAs), particularly butyrate, propionate, and acetate. Among these, butyrate serves as the primary energy source for colonic epithelial cells and is crucial for maintaining intestinal barrier function [216].

"Leaky gut" and "blood-brain barrier leakage" are two key interconnected pathways in PD pathology. The synergistic effects of medicinal plant polysaccharides and probiotics provide "dual reinforcement" for these biological barriers. When traditionally extracted polysaccharides undergo fermentation by specific probiotics, their structure and biological activity may undergo beneficial transformations, thereby enhancing their capacity to protect the intestinal barrier. The study demonstrated that Acacia seed polysaccharides fermented by Bacillus thuringiensis exhibited enhanced protective effects on the intestinal epithelium, improved barrier repair, and extended the lifespan in a Drosophila intestinal inflammation model. This research indicates that probiotic fermentation not only degrades polysaccharides to enhance their bioavailability but may also modify their higher-order structures (e.g., preserving or altering triple-helix conformations), thereby strengthening their interactions with intestinal epithelial cells or immune receptors. This process yields enhanced barrier repair and systemic health benefits [217]. The fermented product of shiitake mushroom polysaccharides by probiotics significantly reverses the LPS-induced downregulation of tight junction protein expression. For example, compared with the LPS model group, the fermented product-treated group showed increased mRNA expression of ZO-1, Occludin, and Claudin-1 [216]. Damage to the intestinal barrier is often accompanied by abnormal infiltration and activation of immune cells. Synbiotics can mitigate inflammation's assault on the barrier at its source by synergistically regulating immune cell function. Research indicates that treatment with probiotics and Polygonatum polysaccharides significantly suppresses inflammation-induced migration in RAW 264.7 macrophages under high-fat conditions. This demonstrates that fermented polysaccharides effectively reduce the attraction of inflammatory signals, thereby decreasing immune cell infiltration into intestinal tissues at the source and mitigating local inflammatory stress on epithelial cells [218]. The integrity of the intestinal barrier relies on the mucus layer above the epithelium, and synbiotics synergistically promotes goblet cell regeneration and mucus secretion. Fucoidan and Lactobacillus plantarum most effectively stimulate goblet cell regeneration in zebrafish colitis, thereby aiding in the restoration of the mucus layer that protects the intestinal epithelium. Additionally, synbiotics significantly improved crypt structural disruption and submucosal edema induced by DSS [218]. Therefore, the improvement in intestinal barrier function directly reduces the entry of pathogen-associated molecular patterns (such as lipopolysaccharide LPS) and inflammatory mediators of intestinal origin into the circulatory system.

The gut is the largest immune organ in the human body, and the onset and progression of PD are closely associated with immune dysregulation in both the gut and systemic immune systems. Medicinal plant polysaccharides and probiotics jointly act on the innate and adaptive immune systems, synergistically reshaping immune homeostasis. The establishment of immune tolerance begins with the proper development of immune organs and the phenotypic regulation of antigen-presenting cells. The effects of Astragalus polysaccharides and a composite probiotic (containing Lactobacillus and Bacillus cereus) on the immune systems of chicks were investigated. The study revealed that compared to the group treated with Astragalus polysaccharides alone, the relative weights of the bursa of Fabricius and spleen in the synbiotic group increased significantly. More importantly, the synbiotic treatment synergistically promoted the induction of regulatory T cells (Tregs). This synergistic enhancement of both central and peripheral immune organs laid the foundation for establishing a stable immune tolerance environment [209]. At a finer molecular level, probiotics were encapsulated within durian peel polysaccharide gel and administered to zebrafish. Results demonstrated that this synbiotic diet synergistically and significantly upregulated key immune genes in zebrafish, including pro-inflammatory factor interleukin-1β (IL1B), antimicrobial peptide lysozyme (LYZ), tumor necrosis factor-alpha (TNF-α), and antioxidant enzyme superoxide dismutase (SOD). This broad spectrum of immune gene activation indicates that synbiotics do not simply suppress or activate immunity. Instead, they enhance the body's immune surveillance and clearance capabilities in a coordinated manner while preventing excessive inflammatory damage by elevating antioxidant levels [219]. Given the widespread imbalance in pro-inflammatory cytokine levels in PD patients, synbiotics can synergistically regulate this critical network. Research indicates that co-administration of Crataegus pinnatifida crude polysaccharides with specific probiotics not only modulates the gut microbiota in Wistar rats but also synergistically influences host tryptophan metabolism. This approach elevates levels of immunomodulatory indole derivatives and optimizes serum cytokine profiles. Such coordinated regulation of immunometabolites serves as a vital bridge linking microbiome alterations to host immune phenotypes [214]. In studies on broiler chickens infected with Escherichia coli, the combined application of Astragalus polysaccharides and probiotics (Bacillus subtilis and Lactobacillus) was more effective than single-component treatments in reducing diarrhea rates and mortality, as well as alleviating intestinal pathological damage. Mechanistically, the synbiotic significantly increased mRNA expression of the anti-inflammatory cytokine IL-10 in broiler intestines while markedly suppressing TLR4 mRNA expression. Concurrently, expression of the pro-inflammatory cytokine IL-2 was moderately upregulated. This pattern indicates that the synbiotic treatment synergistically "shuts down" excessive pro-inflammatory signaling pathways (TLR4), "activates" protective anti-inflammatory signaling (IL-10), and "maintains" essential immune responses (IL-2), thereby achieving precise immune balance [220]. The combination of probiotic Lactobacillus plantarum S58 and prebiotic barley β-glucan demonstrated significant synergistic neuroprotective effects in a mouse model of colitis. Synbiotic therapy not only more effectively suppressed pro-inflammatory cytokines in the colon and serum, alleviating intestinal inflammation, but also synergistically blocked excessive activation of hippocampal microglia. This slowed synaptic protein degradation and neuronal apoptosis, thereby improving cognitive deficits in the mice [221]. Compared to using probiotics or Achyranthes polysaccharides alone, their combined use enhances positive effects more than individual supplements. Not only are serum immunoglobulin A (IgA) and interleukin-2 (IL-2) concentrations higher, but jejunal villus height (VH) is also improve [222]. In summary, the synbiotic combination of plant-derived medicinal polysaccharides and probiotics establishes a comprehensive, closed-loop functional network. This network progresses from "empowering probiotics" to "optimizing metabolic output," then to "strengthening dual barriers" and "restoring immune homeostasis," ultimately achieving "integrated neuroprotection" through the gut-brain axis. This multi-targeted, systemic regulatory strategy not only aligns closely with the multifactorial and complex pathological characteristics of PD but also paves a highly promising new pathway for developing PD intervention strategies based on the gut microbiome.

The composition of the microbiome varies greatly between individuals, influenced by multiple factors including genetic background, age, gender, geography, long-term dietary habits, lifestyle (such as exercise and stress), and medications (particularly antibiotics and PD drugs themselves), forming a highly complex and dynamic ecosystem [223]. This heterogeneity manifests not only in species composition but also in functional genes and metabolic pathways, directly determining the host's response to dietary interventions. Metagenomic analysis reveals significant individual variation in the gut microbiota of PD patients. Compared to healthy controls, however, they collectively exhibit a reduction in genes involved in short-chain fatty acid (SCFA) synthesis and an increase in metabolic pathways associated with pathogenic bacteria [224]. More importantly, the dysbiosis patterns observed in PD patients are not uniform but can be categorized into distinct "gut types" or "clusters". These clusters exhibit varying degrees of association with disease severity, progression rate, and even non-motor symptoms such as constipation. For instance, clusters dominated by Bacteroides species may correlate with milder motor symptoms, whereas clusters characterized by increased abundance of certain Ruminococcus species are associated with more severe disease states [225]. This implies that a standard formula of synbiotics administered to PD patients with different gut types may yield varying outcomes. It was discovered that healthy individuals exhibit a continuum of colonization responses ranging from "permissive" to "complete resistance" to the same commercial probiotic (containing 11 bacterial strains). This resistance is primarily determined by the structure and function of the individual's baseline microbiota, preventing the probiotic from effectively colonizing or altering the existing gut flora in resistant individuals [226]. The efficacy of probiotics in synbiotics depends on their ability to colonize or exert transient effects within the complex intestinal environment, while the utility of prebiotics (such as medicinal plant polysaccharides) hinges on the presence of bacteria within the host microbiota capable of specifically fermenting and utilizing them. A clinical trial found that supplementation with Lactobacillus fermentum improved constipation symptoms in some PD patients, though responses varied. Subsequent analysis suggested that patients with a higher pre-treatment abundance of Prevotella, which produces mucin-degrading enzymes, may have experienced an altered intestinal environment that hindered the initial adhesion of certain probiotics [118]. Another study on Bifidobacterium longum also observed that its colonization success rate in PD patients was not 100%, with those who successfully colonized showing more significant reductions in inflammatory markers. Medicinal plant polysaccharides possess complex structures, requiring specific enzyme systems for their degradation [119]. For example, the fermentation of Astragalus polysaccharides is highly dependent on Bacteroides species possessing corresponding polysaccharide degradation genes in the gut. The utilization of Ganoderma lucidum polysaccharides may be associated with certain species of the genus Ruminococcus and the family Helicobacteraceae. The abundance and diversity of functional microbial communities with polysaccharide degradation potential in the intestines of PD patients are generally reduced and exhibit significant individual variation. Therefore, when administered the same Ganoderma lucidum polysaccharides, they may be effectively fermented into anti-inflammatory short-chain fatty acids in Patient A, while in Patient B, they may yield minimal benefits due to the absence of key degrading bacteria, or they may even be converted by other microbial communities into non-beneficial or harmful metabolites. Future approaches should integrate in vitro fermentation models with artificial intelligence prediction to match optimal combinations of medicinal plant polysaccharides and probiotics for PD patients with diverse gut ecological backgrounds.

The prebiotic activity of medicinal plant polysaccharide is highly dependent on their fine chemical structure, including monosaccharide composition, glycosidic linkage types, molecular weight, branching degree, and spatial conformation [227]. This structural diversity determines the specificity of the enzyme systems required for their degradation, as well as the spectrum of fermentation products generated and their ultimate biological effects [228]. For instance, linear β-(1→3)-glucans (e.g., from Ganoderma lucidum) are more readily and rapidly utilized by specific bacterial groups (such as Bacteroides spp.), leading to the production of short-chain fatty acids. In contrast, rhamnogalacturonan I-type pectin with complex side chains (e.g., from Lycium barbarum) may undergo slower, multi-stage fermentation, sustainably nourishing various acid-producing and mucus-degrading bacteria (such as Akkermansia spp. [229]. This specificity in the structure-function-microbiota response relationship poses a core challenge for the precise selection and dosage of plant polysaccharides in synbiotic formulations. Insufficient dosage may fail to effectively activate target metabolic pathways, while excessive dosage could lead to over-fermentation, resulting in bloating, gastrointestinal discomfort, and even adverse effects on the host due to excessive gas production or certain intermediate metabolites (such as D-lactic acid) [230]. Therefore, achieving both safety and efficacy necessitates a personalized and stratified application strategy based on individual characteristics. This approach must fully account for the molecular properties of plant polysaccharides, the metabolic capacity of target probiotics, and the patient's baseline gut ecology. Probiotics are not a functionally homogeneous group; their health effects are highly strain-specific. Different strains exhibit significant variations in their adhesive and colonization capabilities, the synthesis of metabolites (such as short-chain fatty acids, gamma-aminobutyric acid, and bacteriocins), immunomodulatory properties, and their regulation of host signaling pathways (e.g., Toll-like receptors and G protein-coupled receptors) [231]. For instance, in Parkinson's Disease models, Lactobacillus plantarum PS128 has been shown to increase striatal dopamine levels and improve motor symptoms, while certain strains of Lactobacillus or Bifidobacterium may focus more on anti-inflammatory effects or barrier repair [232]. Therefore, when constructing synbiotics, the selection of probiotic strains should not be based solely at the genus or species level but should extend to the strain level. Screening should be conducted based on their validated, specific functions relevant to the pathological mechanisms of Parkinson's Disease (PD), such as inhibiting α-synuclein aggregation, enhancing GDNF expression, and reducing pro-inflammatory cytokines [233]. More critically, the "synergy" pursued in synbiotics is not merely a simple stacking of bacterial species but rather the achievement of "functional complementarity" and "metabolic relay." An ideal combination should include "primary degraders" (such as certain Lactobacillus strains) that can utilize the initial complex structures of plant polysaccharides and provide precursor substances for other bacteria. along with "core acid-producing bacteria" (such as Clostridium butyricum and Faecalibacterium prausnitzii) that efficiently ferment these precursors to generate substantial amounts of neuroprotective metabolites (e.g., butyrate); as well as "immuno/neuro-regulatory bacteria" capable of directly communicating with the host immune system, strengthening the intestinal barrier, or modulating neurotransmitters. Future research should utilize in vitro co-culture systems, gnotobiotic, and meta-transcriptomics technologies to systematically analyze the metabolic interaction networks between different plant polysaccharides and specific probiotic strains. This approach will enable the design of truly next-generation, metabolically intelligent synbiotics capable of delivering therapeutic efficacy for Parkinson's disease [234].