Preclinical Evidence of Withania somnifera and Cordyceps spp.: Neuroprotective Properties for the Management of Alzheimer’s Disease

W. somnifera, commonly known as Indian ginseng or Ashwagandha, is a geographically widespread herb. It grows spontaneously in arid and semi-arid zones ranging from the European basin to southern Africa and the Middle East, and spreading through Central and South Asia across India, Pakistan, and Bangladesh. The botanical component of interest with pharmacological applications is the raw root, whose integration has been associated with cardioprotective, anti-cancer, sedative, antimicrobial, and neuroprotective benefits [8]. W. somnifera, belonging to the Ayurveda tradition, has attracted growing attention due to the health benefits derived from its consumption [9]. Preparations in the form of root powder have been traditionally used as a tonic and adaptogen to enhance vitality and counteract fatigue, anxiety, and insomnia while promoting longevity and memory functions. Nonetheless, W. somnifera has also been used in pastes and decoctions, and to produce topical oils which have been employed for the management of respiratory, dermatological, and inflammatory conditions [8]. In detail, the roots and leaves of W. somnifera contain a diverse array of phytochemicals with multi-target activity, including over 300 identified C-28 steroidal lactones known as withanolides, as well as other non-withanolide constituents such as flavonoids, tannins, and steroidal saponins. Key bioactive compounds found in the root extract include withaferin A, withanolides A, D, and E, withanone, sitoindosides (VII–X), withanosides I–VII, and various alkaloids such as somniferine and pseudotropine. These highly pleiotropic compounds exert potent activities across a wide range of disease models, including anti-cancer, antiproliferative, radiosensitizer, anti-inflammatory, anti-adipogenesis, antimicrobial, and many more (Figure 1) [10,11,12,13].

A noteworthy herbal remedy in traditional Chinese and Tibetan medicine is the entomopathogenic fungal genus Cordyceps, which includes over 750 recognized species. Members of this fungi genus manage to infect hosts from multiple insects, arthropods, or even other fungi. They are predominantly found in humid temperate and tropical forests across the Northern Hemisphere, but are especially abundant in South, East, and Southeast Asia. Among these, 35 species have gained significant attention due to their notable pharmacological properties, including anti-cancer, antioxidant, anti-aging, and immunostimulatory effects. Cordyceps sinensis (C. sinensis), for example, is praised as a kidney-nourishing, lung-invigorating tonic, and together with Cordyceps militaris (C. militaris), their consumption is associated with vitality and energy-enhancing outcomes [37].

Over 200 secondary metabolites have been isolated from C. spp., showcasing remarkable phytochemical diversity. Key bioactive classes are represented by nucleosides and analogs, polysaccharides, sterols, terpenoids, alkaloids, peptides, and flavonoids. Glucan and acid polysaccharides exert strong free-radical scavenging actions as well as a protective role towards mitochondrial function (Figure 2). Furthermore, numerous compounds belonging to the sterols, triterpenoids, and peptides group (e.g., cordymin) have been studied for their anti-inflammatory activity via the inhibition of the NF-κB pathway and the suppression of pro-inflammatory cytokines such as tumor necrosis factor alpha (TNF-α) and IL-1β [38].

Several in vitro studies have highlighted the immunostimulatory and immunomodulatory effects of C. spp. In murine macrophage line cell RAW 264.7, derived from mice infected with Abelson murine leukemia virus, a high-molecular-weight polysaccharide isolated from C. militaris demonstrated anti-inflammatory, cytokine induction and macrophage activation properties [39].

Another pivotal bioactive compound found in C. spp., cordycepin, displays broad anti-inflammatory, antioxidant, anti-apoptotic, chemopreventive, and immunomodulatory properties [38]. For example, in human colon cancer cells HT-29, cordycepin features apoptosis activation properties through the Death receptor 3 (DR3) pathway [40].

Furthermore, both cordycepin and C. militaris extracts have been associated with cancer-sensitizing and immunomodulatory actions in cancer cell models, altering the expression of markers involved in immune-mediated killing of cancer cells, death receptors such as Fas receptor (FasR) and Death receptor 4 (DR4), and apoptosis pathways [41].

In the context of cardiometabolic disease, the in vivo administration of a polysaccharide component isolated from Cordyceps cicadae (C. cicadae) was linked to improvements in mucosal barrier indicators, lower levels of serum lipopolysaccharide (LPS), and microbiota restoration properties in diabetic mice [42].

Among the primary biological effects associated with C. sinensis extract are its neuroprotective and cognitive-enhancing properties, mediated through the activation of antioxidant signaling pathways. A polysaccharide isolated from C. sinensis has demonstrated protective effects against hydrogen peroxide-induced damage in PC12 neural cell models, evidenced by reduced malondialdehyde (MDA) levels and increased activities of antioxidant enzymes such as glutathione peroxidase (GPx) and superoxide dismutase (SOD) in pretreated samples [43]. Using the same in vitro model (PC12 cells), Shen et al. confirmed the role of an acid polysaccharide derived from C. mycelia in increasing cellular survival and antioxidant enzyme levels post oxidative damage exposure. The study also pointed out that lactate dehydrogenase and MDA levels decrease [44].

Regenerative properties have been found in HT-29 cells and indomethacin-injured rats. In fact, hot water extract of C. sinensis stimulated cell proliferation and accelerated gastric mucosal healing [45].

Among the 33 studies that emerged from electronic databases (18—Google Scholar; 15—PubMed), only 11 were considered eligible for inclusion in the present review, as we excluded duplicates and review articles, focusing our attention solely on studies that reported experimental data on the effects of W. somnifera on AD (for further details, please refer to Supplementary Figure S1, which outlines the screening process and the exclusion criteria applied). As shown in Table 1, both methanolic and aqueous extracts of W. somnifera effectively promoted neuronal health via the upregulation of antioxidant enzymes and the stimulation of Aβ clearance in preclinical rodent models of AD. High-dose treatments were found not only to be safe and well tolerated but also to exert dose-dependent protective effects. Interestingly, cognitive and behavioral improvements, preservation of brain structure, and inhibition of Aβ deposition were also reported for the bioactive constituents withanone and withanoside IV when administered individually.

W. somnifera and its bioactive components, withanone and withanoside IV, have been studied for their neuroprotective and neuroenhancing properties in vitro and in preclinical models. The antioxidant activity is achieved via Nrf2 pathway activation and ROS scavenging [53].

As reported by Gladen-Skolarsky et al., administration of an aqueous extract of W. somnifera in transgenic mice mimicking AD determined the upregulation of the genes Nrf2 and NAD(P)H quinone oxidoreductase 1 (NQO1) in the cortex of mouse brain, along with the concomitant reduction in Aβ plaque deposition in the hippocampus and improvements in cognitive, behavioral, and psychological symptoms [46].

Likewise, mice treated with a methanolic extract of W. somnifera demonstrated positive modulation of oxidative stress and antioxidant activity through the reduction in MDA levels and the upregulation of GSH and SOD levels analyzed in the brain [47].

Interestingly, Afewerky et al. reported a significant role of this phytotherapeutic in promoting mitochondrial health and function. Specifically, upregulation of the neuronal sodium–calcium exchanger isoform 3 (NCX3) in the cortex and hippocampus with the use of the herb’s methanolic extract is suggested to exert a protective effect against Ca²⁺ dyshomeostasis [48].

A pivotal anti-Alzheimer mechanism reported for W. somnifera extract is Aβ formation inhibition in the brains of treated animal models. This remarkable result may be attributed to the combined effects exerted by this plant, primarily its antioxidant and anti-inflammatory activity, as well as the documented suppressing activity of withanone towards β- and γ-secretase levels in the brains of mice. Β-secretase is the aspartic enzyme responsible for the cleavage of APP and the generation of the C99 peptide fragment that is subsequently processed by γ-secretase, leading to the formation of Aβ40 and Aβ42. By inhibiting the enzymatic processing cascade, withanone-rich W. somnifera extracts might be a promising formulation for managing AD clinical features [53].

Sehgal et al. identified a novel mechanism by which W. somnifera promotes Aβ clearance. They showed that high-dose extract administration markedly increases hepatocyte expression of the low-density lipoprotein receptor-related protein (LRP), the primary receptor mediating Aβ endocytosis. Moreover, these hepatocytes shed LRP’s large extracellular domain into the bloodstream as soluble LRP (sLRP), which binds circulating Aβ and traps it in the periphery, thereby preventing its re-entry into the brain [49].

Furthermore, as described by Abdullah et al., the pharmacological potential of W. somnifera also includes support for cholinergic function through the downregulation of brain levels of AChE and BACE, both of which are involved in acetylcholine degradation [51].

Another interesting target reported for this medical plant is glutamate dehydrogenase. Methanolic and aqueous extracts of W. somnifera decreased glutamate expression in the cortex and hippocampus of treated rodents to levels comparable to the control group in scopolamine-induced Wistar albino male rats. Visweswari et al. were able to link the upregulation of glutamate dehydrogenase activity in the brain to the attenuation of neural cell loss in the cortex and hippocampus via histopathological observations [50]. This further testifies to the positive impact of W. somnifera extract and its bioactive compounds on neurotoxicity and the recovery of cognitive function, learning, memory, and behavioral deficits, all recognized as hallmarks of AD clinical features [54,55].

Despite the lack of randomized clinical trials exploring the anti-Alzheimer effects of W. somnifera extracts in affected patients, Lopresti et al. showed that 240 mg of a standardized ashwagandha extract once daily for 60 days exerted anxiolytic and mood-enhancing effects in adults with self-reported high stress [56]. Likewise, the results from the 8-week randomized clinical trial carried out by Pandit et al. confirmed the previous ones. The three administered doses of standardized W. somnifera extracts produced significant, dose-dependent drops in fasting plasma cortisol and adrenocorticotropic hormone, lowering perceived stress and improving anxiety and depressive scores. Remarkably, the treatment led to a significant drop in pro-inflammatory cytokines too, suggesting protection against oxidative stress [57].

The number of studies regarding the neuroprotective mechanisms and pharmacological application of C. spp. is more limited than those explored for W. somnifera. In detail, 10 studies published in the last 20 years emerged in the electronic database (4 from Google Scholar and 6 from PubMed). Of these, only four studies (two from Google Scholar and two from PubMed) were included in this review, as they reported experimental data on the effects of C. spp. on AD (additional information regarding the screening methodology and exclusion criteria is provided in Supplementary Figure S2). C. spp. (i.e., militaris, cicadeae, ophioglossoides mycelium) and the bioactive constituent cordycepin, administered alone, were associated with improvements in cognitive and memory skills, Aβ deposition, and key enzyme activities in preclinical models of AD (Table 2).

In the context of AD, both C. spp. extracts and cordycepin alone show a promising role in the management of cognitive dysfunction, neuroinflammation, and Aβ plaque deposition in preclinical models of this neurodegenerative disease. Consistently, in a rodent model of Parkinson’s disease, cordycepin treatment preserved mitochondrial morphology and function, preventing vacuolar degeneration and rotenone-induced neurotoxicity [62].

In another study, cordycepin exerted a pivotal role in preserving the integrity of white matter in the brain of a traumatic brain injury mouse model and ameliorated neurological deficits. The adenosine analog conferred long-term neuroprotection via the microglia and macrophage inhibition, the promotion of anti-inflammatory pathways, and the suppression of matrix metalloprotease (MMP) activity, together with neutrophil infiltration [63].

Wu et al. observed that the neuroprotective properties of C. spp. can be greatly influenced by the culture conditions. In their study, co-fermentation of C. cicadea in deep ocean water boosted the fungi’s mycelial biomass and its N(6)-(2-Hydroxyethyl) adenosine (HEA) content. The novel multi-component fungal preparation effectively inhibited the amyloidogenic pathway, reducing the protein expression of β-secretase and Aβ40 in the hippocampus of rats. It also prevented tau hyperphosphorylation and suppressed microglial inflammation by upregulating the soluble receptors for the advanced glycation end products (sRAGE) and downregulating TNF-α, IL-1β, and IL-6, ultimately leading to ameliorating results in AD-like cognitive deficits. One of the mechanisms underlying these results involves the upregulation of magnesium transporter 1 (MAGT1), a protein that facilitates Mg²⁺ influx into neurons and supports endothelial barrier function. Co-fermentation with deep ocean water enables C. cicadae to absorb and biotransform Mg²⁺ into an organic form. Elevated intracellular Mg²⁺ levels suppress BACE expression and inhibit GSK-3β activity, thereby reducing tau generation and hyperphosphorylation and limiting Aβ production [59].

Interestingly, in the study carried out by Ock Kim et al., the treatment with cordycepin from C. militaris (10 mg/kg body weight/day for 4 weeks) improved markers of cellular senescence and enhanced neuronal plasticity, evaluated through the upregulation of microtubule-associated protein 2 (MAP2) and neuronal nuclei (NeuN). Furthermore, as previously pointed out, cordycepin skewed microglial polarization from the M1 pro-inflammatory pathway towards the anti-inflammatory one, promoting the release of neurotrophic factors and the creation of a neuroprotective microenvironment, dampening chronic inflammation that drives Aβ deposition and tau pathology [60].

Consistent with the evidence discussed, the involvement of these pleiotropic mechanisms is suggested to contribute to the improvement in pathological features of AD and to support the restoration of cognitive and behavioral functions, including spatial memory and learning capacity, as reported by Jin et al. and He et al. [58,61].

To the best of our knowledge, there is a lack of scientific research concerning clinical trials that explore the effects of C. spp. extracts in ameliorating cognitive and psychological symptoms in human cohorts. Nonetheless, coherently with in vitro and preclinical evidence, the administration of C. mycelium culture extract for 8 weeks to healthy adults resulted in significant enhancements in natural killer (NK) cell cytotoxic activity compared to the placebo group, suggesting possible clinical translation regarding AD [64].

Not applicable.