Neurodegenerative Diseases: Unraveling the Heterogeneity of Astrocytes

Astrocytes respond differentially to CNS stimuli that activate different receptors and the respective signaling intracellular pathways, whose outcome can be a harmful or protective effect.

TLR activation is known to lead to the conversion of active astrocytes into reactive astrocytes in neurodegenerative diseases. Thus, TLR4 stimulation in astrocytes favors the appearance of the A1 phenotype [8,15]. This receptor is also expressed in the cell membranes of microglia in the CNS, whose activation causes microglial activation and the consequent secretion of IL-1α, TNFα, and C1q, which are required for A1 astrocyte differentiation (Figure 1) [8].

Several studies have analyzed the role of TLRs in modulating astrocyte function in vitro using pathogen-derived components, endogenous TLR activators, synthetic agonists, and antagonists as ligands. The common outcome is that the expression or release profile of cytokines and chemokines depends on the engaged TLR and the ligand type for the TLR [16,17,18].

The transcription factor NF-κB pathway, where several intracellular signaling pathways converge, including TLR activation, has been extensively studied to discriminate the role of astrocytes in neuroinflammation and immune response. Inactive NF-κB is found in the cytoplasm, bound to the protein inhibitor NF-κB alpha (IκBα). Once activated, NF-κB translocates into the cell nucleus to activate the expression of genes coding for pro-inflammatory cytokines, thus intensifying and amplifying the inflammatory response [19]. Some studies propose that the NF-κB signaling pathway preferentially mediates the modulation of astrocyte population in neurological diseases. Such a proposal emerges from findings in astrocytes that neurons and reactive microglia release factors that activate the IκB kinase complex (IKK), resulting in IκBα phosphorylation and degradation. Subsequently, p50 and p65, two NF-κB subunits, translocate to the nucleus and activate the transcription of genes related to neuroinflammation in astrocytes (Figure 1) [20,21]. In a mouse model of depression induced by mild chronic stress, it was found that the NF-κB pathway in microglia activates the Nod-like receptor protein 3 (NLRP3) inflammasome, which finally leads to caspase-1 activation. Then, active caspase-1 triggers the release of TNFα, IL-1α, and C1q, eliciting the reactivity of neurotoxic A1 astrocytes [22]. Likewise, the activation of NLRP3 and induction of A1 astrocytes was also demonstrated in primary cultures of murine astrocytes stimulated with lipopolysaccharide (LPS) [23]. NLRP3 can also be activated by P2X purinoceptor 7 (P2X7R) stimulation, which is expressed in microglia and astrocytes [24]. P2X7R stimulation is known to induce the release of bioactive molecules, including pro-inflammatory cytokines, chemokines, proteases, reactive oxygen species (ROS), nitrogen molecules, and excitotoxic glutamate, all capable of causing neurodegeneration [24]. P2X7R is also involved in the ATP-induced membrane pores that allow an excessive influx of Ca²⁺ and depletion of intracellular ions and metabolites, ultimately leading to the lysis of antigen-presenting cells as microglia (Figure 1). This mechanism has given rise to the hypothesis that P2X7R is a “death/suicide” receptor [25,26].

Another signaling pathway whose activation has been implicated in the pathological role of astrocytes is the RhoA/ROCK pathway (Figure 1) [27,28,29]. RhoA and its downstream effector ROCK are ubiquitously expressed in the CNS, including astrocytes and neurons [27]. The RhoA/ROCK signaling pathway may induce microglia and astrocyte activation and increase the expression of nitric oxide synthase and TNFα, which cause neurodegeneration. In addition, recovery from neurodegeneration is blocked because ROCK inhibits cell survival and axon growth [29].

Astrocytes, like other neuronal cells, also express the interleukin-17A receptor (IL-17AR), which is a heterodimeric complex (Figure 1) [30,31]. It has been suggested that IL-17AR can enhance glutamate excitotoxicity by reducing the ability of astrocytes to absorb and metabolize glutamate [32]. Moreover, IL-17AR expression is increased in astrocytes in the CNS of mice with experimental autoimmune encephalomyelitis, thus reinforcing the role of this receptor in neurodegeneration [30].

In summary, some essential signaling pathways activated by different insults have been identified that can mediate the astrocyte compromise for a harmful reactive state during brain injuries. However, a more profound understanding of the mechanisms determining the phenotype of reactive astrocytes in neuroinflammation, and neurodegeneration is needed to develop effective treatments against these pathologies.

Recently, research has focused on discovering strategies that activate signaling pathways to induce homeostatic astrocytes and neurotoxic astrocytes toward neuroprotective astrocytes, aiming to implement new treatments against neurodegeneration. However, the mechanism by which they are generated needs to be better understood. Despite this limitation, signaling pathways that could promote the transition to neuroprotective astrocytes have been proposed.

The JAK/STAT3 signaling pathway activated by receptors to cytokine, growth factors, or hormones is thought to be linked to the induction of neuroprotective reactive astrocytes (Figure 1) [33]. Upon activation of the JAK/STAT3 pathway, JAK phosphorylates tyrosine residue (Tyr705) in the C-terminal domain of STAT3, thus causing STAT3 dimerization and translocation to the nucleus to initiate the transcription of target genes [33,34]. In astrocytes, STAT3 activation can be triggered by IL-6 receptor activation, often induced by the release of IL-6 mediated by NF-κB [35]. Consequently, IL-6, via STAT3 phosphorylation, modulates the production of IL-10 [36], an anti-inflammatory cytokine known to promote neuronal survival [37]. This pathway has also been associated with the infiltration of leukocytes, maintenance of myelin, generation of anti-inflammatory cytokines, and other physiological processes such as cell growth, survival, or differentiation [34]. Moreover, it has been proposed that the JAK/STAT3 pathway promotes neurogenesis and neuronal protection in the CNS [38,39]. In a murine model of ischemic brain injury with genetic estradiol depletion, researchers observed that the JAK/STAT3 signaling pathway is downregulated. This downregulation was associated with attenuated reactive astrogliosis, lower transcription of the “A2” panel of reactive astrocyte genes in the hippocampus, microglial activation, enhanced neuronal damage, and cognitive deficits. These effects were reversed after the signaling pathway was recovered through exogenous estradiol administration [40].

The PI3K/AKT pathway (Figure 1) has also been related to the neuroprotective role of astrocytes [41]. This pathway is activated when a ligand, which may be a growth factor or hormone, binds to a tyrosine kinase receptor located on the plasma membrane. Upon ligand–receptor binding, phosphorylation is produced on tyrosine residues in the intracellular domain of the receptor, causing its dimerization. Subsequently, the regulatory subunit p85 of PI3K binds to the phosphorylated tyrosine residues of the receptor to recruit the catalytic subunit p100, forming the active PI3K enzyme. PI3K phosphorylates phosphoinositides, producing three lipid products bound to the cell membrane: PIP, PIP2, and PIP3. Among these lipid products, PIP3 binds to the Pleckstrin homology domain of the serine/threonine protein kinase AKT, leading to its translocation to the membrane and complete activation. Through activating mTORC1, active AKT triggers downstream responses in the cell, such as cell growth, proliferation, and survival [42].

Some studies suggest that the activation of the PI3K/AKT pathway promotes astrocytic reactivity towards a neuroprotective phenotype while excluding the neurotoxic phenotype [41,43]. This pathway can be activated by transforming growth factor beta (TGF-β) [44] released by M2 macrophages [41,45] and neuroprotective astrocytes. It is even thought that TGF-β secreted by A2 astrocytes is essential in neuroprotection since it could act on other immune cells as macrophages or infiltrating T lymphocytes (Figure 1) [46,47]. In 2023, in co-cultures of M2 macrophages with spinal cord astrocytes, Pang et al. demonstrated that M2 macrophages stimulate astrocytes to secrete IL-10, IL-13, and TGF-β, as well as facilitate S100A10 marker expression in astrocytes. The authors also showed that antagonists of the TGF-β receptor and inhibitors of PI3K reverse the secretion of anti-inflammatory cytokines and TGF-β [41]. In a murine brain injury model, Divolis et al. (2019) showed that TGF-β administration increased glial fibrillary acidic protein (GFAP) and S100A10 mRNA levels in astrocytes and decreased C3 mRNA [48]. These results suggest that TGF-β may activate signaling pathways, such as PI3K/AKT, which would trigger reactive astrocytes to transform into neuroprotective astrocytes.

Furthermore, the PI3K/AKT pathway can also be activated by milk fat globule epidermal growth factor 8 (MFG-E8) (Figure 1). Xu et al. (2018) induced the activation of A1 astrocytes in vitro by adding a conditioned medium of microglia activated by β-amyloid (Aβ42). They found that MFG-E8 inhibited the expression of the A1 astrocyte marker C3 in response to the conditioned medium while increasing the expression of TGF-β, a marker of neuroprotective astrocytes. In contrast, TGF-β expression in A2 astrocytes decreased in the presence of a PI3K inhibitor. Therefore, the authors concluded that MFG-E8 plays a regulatory role in A1 and A2 astrocytic states through the positive regulation of the PI3K-AKT pathway [46]. It has also been reported that fibroblast growth factor 2 (FGF2) can activate the PI3K/AKT pathway (Figure 1). Feng et al. (2023) evaluated the effect of administering 2,3,5,6-tetramethylpyrazine (TMP), an active component of Ligusticum chuanxiong Hort, on astrocytic reactivity through a model of permanent occlusion of the middle cerebral artery. The aim was to improve neurovascular restoration in subacute ischemic stroke. The authors determined that TMP decreased the number of C3-positive A1 astrocytes and, conversely, increased the number of S100A10-positive A2 astrocytes and FGF2-positive astrocytes. TMP also enhanced the levels of PI3K p85/p55 and AKT and upregulated the expression of FGF2. Therefore, it was concluded that TMP caused the release of FGF2, which activated the PI3K/AKT pathway, thereby converting A1 astrocytes into A2 astrocytes in ischemic rats [49].

Finally, Li et al. (2020) developed a model of chronic post-surgical pain causing the activation of microglia at an early stage and, 14 days later, activating astrocytes, mainly A1 astrocytes [43]. The authors observed that intrathecal injection of minocycline (a non-specific microglial inhibitor) alleviated mechanical allodynia and reverted the A1/A2 astrocyte ratio. It also increased the expression of chemokine receptor 7 (CXCR7) and the activation of the PI3K/AKT pathway (Figure 1). Similar results were obtained after intrathecal injection with AMD3100 (a CXCR7 agonist). However, administering LY294002 (a specific PI3K inhibitor) inhibited the transformation of A1 astrocytes into A2 astrocytes induced by minocycline and AMD3100. Therefore, Li et al. concluded that microglia negatively regulate the CXCR7/PI3K/AKT pathway and cause A1 astrocyte reactivity. They also determined that positive regulation of this pathway promotes A2 astrocytes [43].

These findings have important implications for understanding astroglial responses in neurodegenerative conditions and developing therapeutic strategies to modulate astrocyte reactivity and promote neuroprotective responses. However, further research is needed to fully elucidate the mechanisms that regulate astroglial responses and how these may influence the progression of neurodegenerative diseases. A complete understanding of signaling pathways will provide tools for developing efficient astrocyte-targeting therapies to improve the quality of life of patients suffering from neurodegenerative diseases.

AD is the most common neurodegenerative disorder, affecting approximately 50 million patients worldwide [118]. Histopathologically, AD is characterized by amyloid plaques formed by the extracellular deposition of amyloid-beta peptide (Aβ) and neurofibrillary tangles produced by hyperphosphorylation of the microtubule-associated Tau protein [119]. Aβ oligomers activate microglia, releasing pro-inflammatory cytokines that ultimately lead to Tau protein hyperphosphorylation and aggregation. Tau release upon neuronal death also causes microglial activation, thus generating a vicious cycle that ends in neurodegeneration [119,120]. Astrocytes are largely involved in amyloid pathology since they are abundant in the CNS, but their role in AD has been less associated with neurodegeneration than that of microglia [121]. However, along with the connection between astrocytes and AD, their roles in AD development and progression are currently gaining more attention.

Studies on AD brains have shown that reactive astrocytes accumulate around Aβ deposits [122]. It has also been demonstrated that after exposure to Aβ, astrocytes polarize to the A1 state and release a series of cytokines, such as IL-1β or IL-6, NO, ROS, and glutamate [8,123,124]. Growing evidence suggests that reactive astrocytes are primarily located in the microenvironment of amyloid plaques [125,126,127]. Interestingly, Olabarria et al. (2010) observed astroglial hypertrophy around the plaques and astroglial atrophy far from the plaques as a generalized process [126]. Moreover, Habib et al. have identified a unique reactive specific astrocyte subtype of AD, named disease-associated astrocyte (DAA). DAAs appear in the early stages of the disease, mainly localized around Aβ plaques in both the hippocampus and subiculum. These regions are adversely affected by AD [128]. To date, the involvement of A2 astrocytes in AD has not been reported. Future research should focus on analyzing the different astrocytic phenotypes in affected areas from the early to late stages of the disease.

Proposed therapeutic approaches associated with astrocyte reactivity (Table 2) involve preventing the secretion of microglial cytokines, such as IL-1α, TNFα, or C1q, known to trigger astrocytic differentiation to the neurotoxic phenotype [129]. Some drugs that have been shown to influence this mechanism are agonists of the glucagon-like peptide-1 (GLP-1) receptor (GLP-1R) (GLP-1RA), TNFα inhibitors (i-TNFα), C1q inhibitors, and IL-1α inhibitors, among others.

GLP-1RAs, an approved treatment option for type 2 diabetes mellitus, have autonomic and neuroendocrine regulatory actions associated with neuroprotective effects [128]. GLP-1R is expressed in various areas of the CNS that are closely related to memory and learning [130]. Several studies have indicated that GLP-1RA improves cognitive dysfunction in vivo and protects astrocytes in vitro, potentially by inhibiting the NLRP3 inflammasome pathway [131,132]. Another hypothesis is that GLP-1RAs influence brain metabolism and its action on astrocytic aerobic glycolysis, during which GLP-1 increases astrocytic glycolytic capacity via phosphatidylinositol-3-kinase (PI3K/Akt). NLY01, a long-lasting GLP-1RA, is proposed to block neurotoxic astrocytes. It effectively penetrates the BBB and inhibits reactive microglia-induced astrocytes while preserving neuronal viability [130,133,134].

Dimethyl itaconate (DI), an itaconate derivative, reduces neurotoxic reactive astrocytes and inhibits inflammasome assembly, reducing caspase-1 cleavage and IL-1β levels. Furthermore, DI attenuates NF-κB phosphorylation and exerts a neuroprotective effect by reprogramming astrocytes from an A1 neurotoxic state to an A2 neuroprotective state [135]. Microglial activation of TLR4, which triggers NF-κB signaling, causing a specific A1 astrocyte response in brain tissue, was observed in APP/PS1 transgenic (Tg) mice, which is a model of AD. The impact of treatment with Fasudil, an inhibitor targeting the RhoA/ROCK signaling pathway associated with inflammation and oxidative stress, has also been investigated. Fasudil suppressed microglial activation and promoted the expression of the A2 astrocyte phenotype through TLR4 and NF-κB downregulation [136].

Moreover, there are other drugs with potential effects on the neurotoxic effects of reactive astrocytes in AD, such as etanercept (i-TNFα), anakinra (recombinant IL-1α antagonist), non-steroidal anti-inflammatory drugs (NSAIDs), and C3 or C1q inhibitors [137], among others. Cornuside, for example, is an iridoid glycoside from Cornus officinalis that modulates memory deficits in Tg mice used as AD models. This glycoside could suppress the activation of the NF-κB pathway, upregulated in the cortex and hippocampus of AD mouse models, through IκBα downregulation and p65 protein upregulation. Cornuside was proposed as a regulator of astrocyte reactivity that enhanced synaptic plasticity and alleviated cognitive decline through the NF-κB signaling pathway in an AD mouse model [138].

On the other hand, applying specific cytokines has been considered a potentially helpful approach for astrocyte reactivity to promote the synthesis of neuroprotective mediators (Table 2). These cytokines include tissue inhibitors of metalloproteinase-1 (TIMP-1), intercellular adhesion molecule-1 (ICAM-1), TGF-β, IL-1, and interferon-β (IFN-β), among others. Saha et al. (2020) demonstrated that the intracerebroventricular administration of recombinant exogenous TIMP-1 in rats infused with Aβ reduced this peptide and apoptosis in the hippocampus and other cortical regions. In addition, this drug decreased cognitive dysfunction and promoted the activation of neuroprotective astrocytes through Akt pathway activation [139].

While astrocyte-targeted therapeutic options appear promising, more research is needed to assess their efficacy and safety. Some drugs mentioned in this section can potentially regulate astrocyte reactivity, but more studies are required to fully understand the effects of astrocytes. Understanding the complex interplay between astrocytes, microglia, and other factors involved in neurodegeneration will be critical to advancing effective treatments for AD. While these drugs could alleviate AD symptoms, approaches to stop neurodegeneration and promote the correct structural and functional recovery of neural circuitry damaged by AD are needed for an efficient treatment against AD.

PD is the second most common neurodegenerative disorder, with an estimated worldwide prevalence of 6.2 million patients [140]. Histopathologically, it is characterized by pathological α-synuclein (α-syn) aggregates, neuroinflammation, and neurodegeneration of the dopaminergic nigrostriatal system [141,142]. It has been suggested that α-syn plays a significant role in astrocytic activation, attributed to the presence of α-syn aggregates within reactive astrocytes [143]. It should be noted that while intracellular α-syn has been detected in reactive astrocytes, the clearance of extracellular α-syn is reduced, implying that astrocytes may face challenges in effectively breaking down ingested α-syn [143]. Also, it has been suggested that A1 reactive astrocytes are induced by α-syn–activated microglia [129].

Oxidative stress, impaired lysosomal degradation mechanisms, and mitochondrial dysfunction have been associated with pathological α-syn accumulation [144,145]. Research suggests that this abnormal accumulation would result in a change from A2 astrocytes to A1 reactive astrocytes, indicating that increasing the A1/A2 ratio of reactive astrocytes drives the abnormal aggregation and spread of α-syn and, therefore, PD progression.

On the other hand, extracellular α-syn could activate microglia through TLR2 and TLR4 [146], acting as damage-associated molecular patterns and inducing the activation of NF-κB [92,147] and the production of pro-inflammatory cytokines [92]. In this way, the role of α-syn in astrocytes is highlighted since its continuous misfolding and resistance to degradation could generate a perpetual state of reactivity.

Luna-Herrera et al. (2020) reported that the A1 reactive astrocyte response was associated with the loss of dopaminergic neurons in the substantia nigra pars compacta (SNpc) in a PD animal model [148]. In postmortem studies, Liddelow et al. demonstrated the presence of A1 reactive astrocytes in the brains of PD patients [8]. Likewise, Valenzuela et al. showed that intranigral administration of LPS induced the A1 neurotoxic phenotype in a progressive and sustained manner associated with the progression of dopaminergic neurodegeneration. Moreover, in this PD animal model, the A2 astrocyte phenotype presents a defensive response to injury in the brain [92].

Concerning therapeutic approaches, identifying reactive astrocytes within the SN in both patients and preclinical models of PD is a crucial element (Table 2). The use of NLY01 in PD models has a neuroprotective effect through the direct prevention of astrocyte reactivity mediated by the blockade of microglia and inhibition of the release of IL-1α, TNFα, and C1q [129]. However, no further studies have contributed to improving the evidence of the blocking effect of NLY01 on reactive astrocytes. Interestingly, NLY01 is currently being clinically evaluated [NCT04154072↗] to assess the safety, tolerability, and efficacy of NLY01 in subjects with early untreated PD.

Statins, which are primarily used to inhibit cholesterol synthesis, are another class of drugs with the potential to influence astrocyte reactivity by inhibiting the enzyme 3-hydroxy-3-methyl-glutaryl-coenzyme A reductase (HMG-CoA reductase). Statins have shown beneficial effects for managing neuroinflammatory conditions [149,150]. It has been identified that simvastatin, a lipophilic statin capable of crossing the BBB, can modulate the activity of the nuclear receptor subfamily A group 4 member 2 (NR4A2, also known as NURR1) in reactive astrocytes. NURR1 belongs to a group of orphan nuclear receptors with broad physiological actions. For example, it antagonizes the signaling of the NF-κB pathway of macrophage and microglia pro-inflammatory genes, thereby influencing astrocyte reactivity [151,152]. Through these mechanisms in reactive astrocytes, it is proposed that simvastatin decreases the production of IL-6 and TNFα and their amount in the SNpc, which prevents the loss of dopaminergic neurons with consequent improvement in behavioral tests of preclinical models [151,153]. Simvastatin was tested in a clinical trial to evaluate its neuroprotective effect in patients with moderate severity of the condition. The trial was a double-blind, randomized, placebo-controlled futility study, and the primary outcome was a change in the Unified Parkinson’s Disease Rating Scale (MDS-UPDRS) Part III motor subscale score in the OFF-medication state (OFF state). However, study results have not been submitted to ClinicalTrials.gov [154]. Future research is required to better understand and develop astrocyte-targeted therapeutic strategies in PD, highlighting the role of α-syn in astrocyte activation.

HD is the most common of the dominant hereditary neurodegenerative diseases. It is characterized by neuropsychiatric and motor symptoms such as chorea, akinesia, bradykinesia, hypokinesia, and progressive cognitive impairment [155]. HD typically begins in adulthood and follows an irreversible progression of 15 to 20 years, ultimately leading to death [156]. It is caused by an autosomal mutation of the Huntingtin gene (HTT), with full penetrance, when the CAG codon exceeds 40 repeats [157]. The amyloidogenic mutant huntingtin (mHtt) forms soluble fragments and aggregates that are toxic to neurons, particularly the medium-spiny neurons in the striatum [13]. The presence of mHtt and neurodegenerative processes in the striatum can trigger immunological responses of microglia and astrocytes [158]. In this context, it was demonstrated in various Tg mouse models that mHtt inclusions trigger microglial activation [159], which promotes the expression in astrocytes of pro-inflammatory genes through NF-κB activation [158]. Furthermore, the increased reactivity of A1 astrocytes is linked to a neurotoxic phenotype in the brains of HD patients because elevated counts of C3 immunoreactive astrocytes have been found in the caudate nucleus [8,160].

Diaz-Castro et al. (2019) suggest that A1 and A2 astrocyte activity may not be observed in all areas of the HD brain but only in areas affected by HD [157]. Using RNAseq, these authors evaluated astrocyte reactivity genes in both R6/2 and Q175 mouse models of HD. No astrocyte reactivity occurred in the early stages of HD, only in the late stages where they found increased gene activity related to A1 astrocytes [157]. However, these researchers suggest that astrocyte reactivity is unlikely to contribute to neurodegeneration in the early stages.

Likewise, in a rat model of HD induced by 3-nitro propionic acid, researchers observed motor dysfunctions, neurological disorders, and damage in the striatum [161]. The study reported a significant increase in A1 astrocytic levels in the striatum, hippocampus, and cerebellum through histological and molecular analysis for GFAP, C3, TNFα, and IL-1α [161]. Subsequently, the same working group reported the therapeutic use of kaempferol in this HD model (Table 2) since the treatment decreased the reactivity of A1 astrocytes [162]. As an attractive astrocyte-focused therapeutic strategy, kaempferol has recently gained relevance for its anti-inflammatory and anti-neuroinflammatory actions [162]. The effect is mainly attributed to its ability to inhibit phospholipase A2, lipoxygenase, cyclooxygenase, and NO synthesis by inhibiting the inducible NO synthase (iNOS) enzyme [162]. These actions are attractive pharmacological targets in astrocytes since kaempferol can cross the BBB [163]. Although the exact mechanism of its antioxidant and anti-inflammatory actions is not fully known, it is believed that the inhibition of the NF-κB pathway and decrease in pro-inflammatory cytokines IL-1α, TNFα, and C1q are responsible for kaempferol’s neuroprotective effects. These effects may inhibit astrocyte reactivity differentiation in preclinical models of HD [162]. Understanding the complex interplay between glial cells and their activation patterns holds promise for future therapeutic strategies targeting astrocytes in HD.

Multiple sclerosis (MS) is an inflammatory and neurodegenerative disease and the leading cause of non-traumatic disability worldwide [164,165]. According to the MS Atlas by the International Federation of MS, this disease affected around 2.8 million people in 2020 [166]. Neurologically, MS patients experience episodes of motor dysfunction as well as sensory symptoms and optic neuritis.

MS is characterized by neuronal demyelination, axonal degeneration, and reactive gliosis in white and gray matter in the brain and spinal cord and by the infiltration of macrophages and T and B lymphocytes [167,168]. The interaction between infiltrating T cells and astrocytes is pivotal [169]. This interaction occurs directly with T cells binding to astrocytes via major histocompatibility complex molecules, leading to immune response activation and inflammatory factor release [170,171]. Additionally, indirect mechanisms involve T cells releasing cytokines like IL-17 and IL-6, thus prompting astrocyte reactivity [170,172]. Ultimately, these interactions create an inflammatory environment that contributes to myelin and neuronal damage in MS.

In MS, astrocytes are transformed to the A1 phenotype [8], which could secrete several neurotoxic cytokines such as TNFα, IL-1β, and IL-6, leading to the formation of a pro-inflammatory environment in the CNS, myelin damage, and deterioration of the remyelination process [173].

Several reports indicate that specific microRNAs play a vital role in the processes of demyelination and remyelination in MS [174,175]. Upregulation of miR-155 inhibited myelin repair by promoting a pro-inflammatory microenvironment in the CNS [176]. Furthermore, it was confirmed that miR-155 promotes pro-inflammatory cytokine production in astrocytes [176]. Interestingly, it has been suggested that the A1 phenotype induces oligodendrocyte death and inhibits differentiation and maturation of oligodendrocyte precursors, thus exacerbating demyelination and preventing myelin repair [8]. In MS, oligodendrocytes are the target of inflammatory and immune attacks, and their gradual death leads to demyelinated lesions and remyelination failure [177].

On the other hand, A2 astrocytes enhance the maturity of oligodendrocyte precursor cells and protect against the progression of white matter lesions [178]. MiR-155 may regulate the transition between A1 and A2 reactive astrocytes, making it a potential treatment target for myelin repair in MS [179].

The presence of reactive astrocytes has been evidenced and associated with demyelinating lesions and neurodegeneration zones [180]. These findings suggest a link between NLRP3 inflammasome activation in microglia and the conversion of astrocytes into the neurotoxic A1 phenotype [180]. Additionally, A1 astrocyte reactivity was recently evaluated through histological assays, where an increased C3 marker perpetuates neuronal damage [179]. Similarly, an alteration in the phenotype with a hypertrophic cell body and thick processes has been recorded [181]. Current research shows that several drugs used to treat demyelinating diseases, such as MS, provide therapeutic benefits by modulating astrocytic activity, either by reducing the harmful actions of reactive astrocytes or by potentiating their beneficial effects [182,183].

Dimethyl fumarate (DMF) is a drug belonging to the group of fumaric acid esters (Table 2). It has immunomodulatory and neuroprotective properties and treats MS as a disease-modifying agent for relapsing-remitting MS [184]. Both DMF and isosorbide DMF (IDMF), a new molecule synthesized through the esterification of isosorbide with DMF, decreased C3+ reactive astrocytes by activating the nuclear factor-related erythroid factor-2 (Nrf2) pathway, the master transcription regulator of oxidative stress-related genes, including those of the NF-κB pathway and hypoxia-inducible factor 1 alpha [184,185]. Another study carried out in fetal human astrocytes identified that IDMF alters the expression of genes associated with MS, including antioxidant gene heme oxygenase 1 and genes linked to the integrity of the extracellular matrix (metallopeptidase inhibitor 3 and serum matrix metalloproteinase-9). Moreover, the same study found that IDMF downregulates mitogenic genes associated with the reactive astrocytes, such as the intercellular adhesion molecule 1 gene. These findings suggest that the IDMF-mediated neuroprotection could be due to inhibiting astrocyte reactivity [186].

Siponimod and fingolimod (Table 2) are MS-modifying drugs approved for the treatment of secondary progressive and relapsing MS, respectively. They function as sphingosine-1-phosphate (S1P) receptor 1 antagonists and S1P receptor 5 agonists. S1P receptors are expressed in various organs and regulate functions such as lymphocyte trafficking, brain development, and vascular permeability. The S1P receptor 1 plays an essential role in neurogenesis, immune cell trafficking, and endothelial barrier function. Blocking these receptor-employing modulators in preclinical models reduces cytokine amplification and immune cell recruitment, which is the aim of MS treatment. However, S1P receptor 1 participates in glial activation and proliferation [187]. Siponimod, as an S1P receptor 1 antagonist, suppresses the activation of the NF-κB pathway and histone deacetylase enzyme. This inhibition reduces the production of pro-inflammatory cytokines IL-1β, IL-6, and TNFα at the astroglial level. Additionally, siponimod leads to S1P receptor 1 internalization in astrocytes and activates Nrf2, which is associated with antioxidant and neuroprotective responses by astrocytes [188,189,190]. On the other hand, the GLP-1RA NLY01 has shown therapeutic potential by blocking neurotoxic astrocyte conversion in preclinical models of MS [133].

The data that support the findings of this study are available from the corresponding author upon reasonable request.