bfe67bb53c3c532ef4237fa3323691ae27404769
bfe67bb53c3c532ef4237fa3323691ae27404769
The microglial response in AGD shows a predilection for limbic structures, with prominent activation in the hippocampal formation, entorhinal cortex, and amygdala[1]. GGT demonstrates distinctive white matter microglial activation, particularly affecting periventricular regions and deep white matter tracts, corresponding to the prominent oligodendroglial pathology that characterizes this entity[2]. FTDP-17 exhibits variable microglial activation patterns that correlate with the specific MAPT mutation, with some mutations (such as P301L) showing particularly robust microglial responses[3].
The morphological transformation of microglia from a ramified surveillance phenotype to an amoeboid activated phenotype represents a common endpoint across all 4R-tauopathies, though the kinetics and extent of this transformation vary by disease[4]. Activated microglia in these conditions demonstrate enlarged cell bodies with shortened processes, increased expression of CD68 (a lysosomal marker indicating phagocytic activity), and upregulated major histocompatibility complex class II (MHC-II) molecules suggesting antigen presentation capability[5].
bfe67bb53c3c532ef4237fa3323691ae27404769
Microglial TREM2 expression correlates with tau pathology burden in PSP and CBD, with immunohistochemistry demonstrating increased TREM2 immunoreactivity in regions of dense tau deposition[6]. This correlation suggests either that tau pathology drives TREM2 upregulation as a compensatory response, or alternatively, that TREM2-expressing microglia contribute to tau propagation through mechanisms including extracellular vesicle release and direct neuron-to-neuron transmission[7]. Soluble TREM2 (sTREM2), generated through proteolytic cleavage of the extracellular domain, has been detected at elevated levels in cerebrospinal fluid from PSP patients, potentially reflecting increased microglial activation in vivo[8].
The functional consequences of TREM2 activation in 4R-tauopathies include enhanced microglial phagocytosis of tau aggregates, altered cytokine production, and modulation of microglial survival pathways[9]. However, the net effect of TREM2 activation appears context-dependent, with both protective and pathogenic roles described in different experimental models. This complexity underscores the need for careful consideration of timing and patient selection in therapeutic targeting of the TREM2 pathway[10].
The inflammatory milieu in 4R-tauopathies demonstrates both shared and disease-specific cytokine profiles that reflect distinct immune responses to tau pathology[11]. Interleukin-1β (IL-1β) represents the most consistently elevated pro-inflammatory cytokine across all 4R-tauopathies, with increased expression detected in post-mortem brain tissue and cerebrospinal fluid[12]. The NLRP3 inflammasome, which catalyzes IL-1β maturation, has been implicated in tau pathology propagation, establishing a potential feed-forward loop between tau aggregation and neuroinflammation[13].
Tumor necrosis factor-alpha (TNF-α) shows particularly robust elevation in PSP and CBD, consistent with the prominent subcortical pathology in these conditions[1:1]. Interleukin-6 (IL-6) demonstrates variable elevation across diseases, with some studies reporting increased cerebrospinal fluid IL-6 in PSP while others show no significant difference from controls[14]. This variability may reflect disease stage-dependent changes or methodological differences in sample collection and analysis.
| Cytokine/Chemokine | PSP | CBD | AGD | GGT | FTDP-17 |
|---|---|---|---|---|---|
| IL-1β | +++ | +++ | ++ | ++ | ++ |
| TNF-α | +++ | +++ | + | ++ | ++ |
| IL-6 | ++ | ++ | + | + | ++ |
| CXCL8 | +++ | ++ | + | + | + |
| CCL2 | +++ | +++ | ++ | + | + |
Chemokine profiles similarly demonstrate disease-specific patterns. C-X-C motif chemokine ligand 8 (CXCL8, also known as IL-8) shows pronounced elevation in PSP, potentially reflecting the brainstem predilection of this disorder and the rich expression of CXCL8 receptors in this region[15]. C-C motif chemokine ligand 2 (CCL2, also known as MCP-1) demonstrates increased levels in both CBD and PSP, consistent with its role in recruiting monocytes and microglia to sites of pathology[16]. These chemokine signatures may have diagnostic utility and could inform targeted therapeutic approaches.
Astrocytes participate actively in the neuroimmune response across 4R-tauopathies, though their contribution has received less attention than microglial activation[17]. Reactive astrocytosis, visualized as increased glial fibrillary acidic protein (GFAP) immunoreactivity, is a consistent feature of all 4R-tauopathies, with disease-specific patterns of distribution[18]. In PSP, astrocytic pathology includes tau-positive astrocytic tangles and thorn-shaped astrocytes, while CBD demonstrates distinctive astrocytic plaques representing a unique pattern of tau accumulation in glial cells[19].
The functional consequences of astroglial activation in 4R-tauopathies include both protective and harmful effects. Astrocytes contribute to metabolic support of neurons, glutamate uptake, and maintenance of the blood-brain barrier, functions that may be compromised in the reactive state[20]. Additionally, astrocyte-derived cytokines including IL-6 and chemokine ligand 2 (CCL2) modulate microglial activity, establishing bidirectional communication between these glial populations[21]. The astrocytic response may therefore represent a modifiable therapeutic target with potential for disease modification.
Progressive supranuclear palsy demonstrates the most distinctive neuroimmune signature among 4R-tauopathies, with brainstem structures showing particular vulnerability to both tau pathology and inflammatory responses[22]. The pedunculopontine nucleus, a critical node in the cholinergic system governing gait and eye movements, exhibits intense microglial activation that correlates with the characteristic vertical gaze palsy and early gait impairment in PSP[23]. Similarly, the dorsal raphe nucleus, source of serotonergic projections throughout the forebrain, demonstrates prominent microgliosis that may contribute to the mood disturbances frequently observed in PSP patients[24].
Toll-like receptor 4 (TLR4) upregulation represents a distinctive feature of PSP neuroinflammation, with increased TLR4 expression detected in both microglia and astrocytes surrounding tau-positive lesions[25]. The ligand for TLR4, which recognizes pathogen-associated molecular patterns, remains incompletely characterized in PSP, though potential sources include extracellular tau aggregates, damage-associated molecular patterns released from dying neurons, and possibly gut-derived endotoxin translocating across a compromised blood-brain barrier[26]. Downstream signaling through MyD88 and NF-κB leads to production of pro-inflammatory cytokines including IL-1β and TNF-α, establishing an innate immune activation cascade[27].
The complement system demonstrates particularly robust activation in PSP, with C1q deposition demonstrated in tau-positive neurons and surrounding neuropil[28]. This observation suggests that complement may contribute to synaptic elimination and neuronal loss in PSP, paralleling findings in Alzheimer's disease where complement activation has been extensively characterized[29]. The membrane attack complex (C5b-9) has also been detected in PSP brain tissue, indicating terminal complement pathway activation, though at lower levels than early components[30]. Additionally, the opsonization of tau aggregates by complement components may enhance microglial phagocytosis through complement receptor-mediated pathways[31].
Corticobasal degeneration exhibits neuroimmune features that reflect its characteristic asymmetric cortical and subcortical pathology, with microglial activation patterns that nicely parallel the clinical presentation of unilateral ideomotor apraxia and alien limb phenomena[32]. The motor cortex, premotor cortex, and posterior parietal cortex demonstrate intense microgliosis, with Immunohistochemistry for Iba1 and CD68 revealing activated microglia throughout the affected cortical ribbon[33]. Notably, this cortical activation extends to the underlying white matter, suggesting that pro-inflammatory mediators may contribute to the corticobasal degeneration of both gray and white matter structures[34].
The presence of type 42-kDa TAR DNA-binding protein (TDP-43) pathology in approximately 20-30% of CBD cases adds an additional dimension to the neuroimmune response in this disorder[35]. TDP-43 pathology, characterized by cytoplasmic inclusions in neurons and glia, is more classically associated with amyotrophic lateral sclerosis and frontotemporal dementia, and its co-occurrence with tau pathology suggests overlapping pathogenic mechanisms[36]. The inflammatory burden in CBD may be enhanced by the presence of dual proteinopathies, with studies demonstrating synergism between tau and TDP-43 in driving microglial activation in experimental models[37].
Astrocytic tau pathology represents a distinctive feature of CBD, with astrocytic plaques comprising tau-positive processes forming ring-like structures surrounding astrocyte cell bodies[38]. This unique pattern of glial tau accumulation is rarely seen in other 4R-tauopathies, suggesting disease-specific mechanisms of tau propagation or clearance in astrocytes[39]. The presence of astrocytic tau may induce unique inflammatory responses, as astrocytes in CBD demonstrate increased expression of GFAP, S100B, and various pro-inflammatory mediators[40].
Argyrophilic grain disease demonstrates neuroimmune features that distinguish it from other 4R-tauopathies, with a generally more subtle inflammatory response that may reflect its typically less aggressive clinical course[41]. The limbic system predilection of AGD, with prominent involvement of the hippocampus, entorhinal cortex, and amygdala, is paralleled by corresponding inflammatory changes in these structures[42]. Importantly, AGD shows a strong age-dependent incidence, with prevalence increasing substantially after the eighth decade, suggesting that age-related changes in immune function may contribute to disease pathogenesis[43].
The relationship between AGD and Alzheimer's disease neuroinflammation is complex, with high rates of comorbidity reported in clinicopathological series[44]. This comorbidity may confound interpretation of inflammatory markers in AGD, as many studies have not adequately separated pure AGD cases from those with concurrent AD pathology[45]. Limited available data suggest that pure AGD demonstrates less robust microglial activation than seen in PSP or CBD, potentially reflecting the more restricted anatomical distribution of pathology[46].
One distinctive feature of AGD is the prominent involvement of the amygdala, a limbic structure with particularly high density of GABAergic neurons and rich innervation by monoaminergic systems[47]. The inflammatory response in this region may contribute to the emotional lability and anxiety that characterize some AGD cases, though this hypothesis remains to be systematically tested[48]. Additionally, the involvement of the transentorhinal region, a critical gateway for memory circuits, may explain the prominent episodic memory impairment in AGD despite relatively restricted pathology[49].
Globular glial tauopathy demonstrates unique neuroimmune features directly related to its distinctive pathology, which features globular tau inclusions in both astrocytes and oligodendrocytes[50]. The white matter predilection of GGT, with prominent involvement of periventricular regions and deep white matter tracts, is associated with corresponding microglial activation in these regions[51]. Oligodendroglial tau pathology, which is extensive in GGT, may trigger unique inflammatory responses related to myelin degeneration and oligodendrocyte death[52].
The astroglial pathology in GGT is distinctive, with globular inclusions appearing in astrocyte processes throughout affected brain regions[53]. This pattern differs from the astrocytic plaques seen in CBD and the thorn-shaped astrocytes observed in PSP, suggesting disease-specific mechanisms of tau aggregation in different glial cell types[54]. The inflammatory response to astrocytic tau in GGT may include both cell-autonomous effects, as affected astrocytes produce inflammatory mediators, and non-cell-autonomous effects on neighboring neurons and microglia[55].
Periventricular involvement is a hallmark of GGT, with lesions frequently extending to the walls of the lateral ventricles[56]. This anatomical distribution raises the possibility of interactions between periventricular immune populations, including circumventricular organs that lack a conventional blood-brain barrier, and CNS-resident glial cells[57]. Such interactions could potentially facilitate peripheral immune system contributions to GGT neuroinflammation, though this hypothesis remains speculative.
Frontotemporal dementia with Parkinsonism-17 encompasses a heterogeneous group of disorders caused by mutations in the MAPT gene, with neuroimmune features that vary substantially depending on the specific mutation[58]. The P301L mutation, one of the most prevalent FTDP-17-causing mutations, has been associated with particularly robust microglial activation in both human post-mortem studies and mouse models[59]. Transgenic mice expressing P301L tau demonstrate agedependent microgliosis that precedes prominent tau pathology, suggesting that inflammation may actively contribute to disease progression in this model[60].
The N279K mutation in MAPT, another common FTDP-17-causing variant, demonstrates different tau isoform expression patterns and has been associated with a corticobasal syndrome phenotype in some families[61]. The inflammatory response in N279K cases may reflect both the specific tau isoform present and the regional distribution of pathology, which can differ substantially from P301L cases[62]. This mutation-specific heterogeneity underscores the importance of considering genetic subtypes in studying neuroinflammation in FTDP-17[63].
Age of onset in FTDP-17 shows considerable variation even within mutation carriers, suggesting that modifier genes and environmental factors influence disease expression[64]. Among these modifiers, human leukocyte antigen (HLA) haplotypes have been implicated in modifying age of onset in MAPT mutation carriers, pointing to potential contributions of immune genetic variation to disease progression[65]. This observation raises the possibility that immune-directed therapies may be particularly relevant for FTDP-17, given the apparent interaction between immune genetic variation and disease phenotype.
The complement system demonstrates comprehensive activation across 4R-tauopathies, with both the classical pathway (initiated by C1q binding to target structures) and alternative pathway contributing to neuroinflammation in these disorders[66]. The pattern of complement activation differs by disease, with early components (C1q, C3) showing more prominent increases than terminal components (C5b-9), suggesting that complement activation may be contained at the level of C3 conversion in some cases[67].
C1q, the initiating component of the classical complement pathway, demonstrates particularly robust deposition in PSP, with immunohistochemistry revealing C1q绑定 to neurons containing tau pathology and surrounding neuropil[68]. This deposition may result from recognition of tau fibrils by C1q directly, as established in vitro, or alternatively from C1q binding to damaged neuronal membranes or synaptic components[69]. The functional consequences of C1q binding in 4R-tauopathies include opsonization for microglial phagocytosis, induction of microglial cytokine production through signaling receptors, and potentially direct complement-mediated killing through formation of the membrane attack complex[70].
C3 activation products, including C3b and iC3b, are detected throughout affected brain regions in 4R-tauopathies, serving as opsonins that enhance microglial phagocytosis through complement receptors[71]. The ratio of C3 activation to downstream complement components differs between diseases, with PSP showing the most robust C3 activation among 4R-tauopathies[72]. These differences may reflect distinct triggering events, varying complement regulatory protein expression, or disease-specific modulation of complement pathway activation[73].
The soluble complement regulator factor H shows altered expression in PSP and CBD, potentially contributing to inappropriate complement activation in these conditions[74]. Genetic variants in complement regulatory proteins have been associated with PSP risk in genome-wide association studies, suggesting that complement dysregulation may be a pathogenic mechanism rather than simply a downstream consequence of tau pathology[75]. These findings support therapeutic targeting of complement components in 4R-tauopathies, with clinical trials of complement inhibitors currently underway or planned[^92].
The neuroimmune mechanisms in 4R-tauopathies offer multiple therapeutic targets, though translation from preclinical findings to clinical efficacy remains challenging. Current approaches can be categorized into disease-modifying strategies targeting the underlying tau pathology and symptomatic treatments addressing specific clinical manifestations.
Tau-Directed Therapies
Anti-tau immunotherapy represents the most advanced disease-modifying approach, with several monoclonal antibodies in clinical development for PSP and CBD. The antibodies target extracellular tau aggregates with the goal of preventing neuronal uptake and cell-to-cell propagation. Initial clinical trials have demonstrated acceptable safety profiles, though efficacy signals have been modest[31:1]. Key considerations for antibody selection include epitope specificity (N-terminal versus mid-domain versus C-terminal binding), affinity for aggregated versus monomeric tau, and ability to engage pathological tau in the brain parenchyma versus cerebrospinal fluid compartments.
Small molecule tau aggregation inhibitors aim to prevent the conformational transition of tau from soluble monomers to insoluble fibrils. Several compounds have advanced to clinical testing, including methylene blue derivatives and flavonoid-based compounds. The challenge of achieving sufficient brain penetration while maintaining target engagement at the synapse has limited progress. Dose-limiting side effects, particularly gastrointestinal toxicity, have constrained the therapeutic window for some compounds.
Gene therapy approaches targeting MAPT expression directly offer potential for durable treatment effects. Antisense oligonucleotides (ASOs) designed to reduce tau expression through RNAse H-mediated degradation of MAPT mRNA have shown efficacy in preclinical models and entered clinical trials for Alzheimer's disease with potential extension to 4R-tauopathies. Viral vector-mediated delivery of shRNA or miRNA constructs targeting tau could provide longer-duration effects, though delivery to appropriate brain regions remains technically challenging.
Immunomodulatory Strategies
Given the robust neuroinflammatory component in 4R-tauopathies, immunomodulatory approaches have generated substantial interest. However, the dual nature of neuroinflammation—potentially both pathogenic and protective—creates therapeutic complexity. Early-phase interventions aiming to reduce harmful inflammation while preserving beneficial immune surveillance represent a nuanced approach.
Colony-stimulating factor 1 receptor (CSF1R) antagonists reduce microglial proliferation and can deplete disease-associated microglial populations. The small molecule PLX5622 has demonstrated efficacy in tauopathy mouse models, reducing microglial activation and improving behavioral outcomes. Early-phase clinical trials in neurodegenerative conditions are underway, though concerns about complete microglial depletion and potential adverse effects on brain homeostasis require careful monitoring.
TREM2-modulating therapies aim to enhance the beneficial functions of TREM2 signaling while inhibiting pathogenic effects. Agonistic antibodies designed to activate TREM2 signaling have entered clinical testing for Alzheimer's disease, with potential extension to 4R-tauopathies based on the strong TREM2 involvement in these conditions. The timing of intervention may be critical, as TREM2 activation may be beneficial in early disease stages when phagocytic clearance of tau aggregates is still possible.
Complement inhibitors target the robust complement activation observed in PSP and CBD. C1q inhibitors could prevent classical pathway initiation and downstream synaptic elimination. C3 convertase inhibitors would block all complement pathway amplification. The C3 inhibitor pegcetacoplan has received FDA approval for paroxysmal nocturnal hemoglobinuria and is being evaluated for other applications, providing a template for CNS-targeted complement inhibition. C5a receptor antagonists block pro-inflammatory signaling while preserving terminal pathway functions.
Minocycline and other tetracycline derivatives have broad anti-inflammatory properties and have been tested in multiple neurodegenerative conditions. While clinical trials in Parkinson's disease and ALS have yielded disappointing results, disease-specific effects in 4R-tauopathies remain to be definitively evaluated. The distinct inflammatory profiles in different tauopathies suggest that disease-specific responses might be expected.
The development of biomarkers for 4R-tauopathies is critical for patient selection, disease staging, and therapeutic monitoring. Biomarkers can be categorized into fluid-based, imaging-based, and clinical measures.
Fluid Biomarkers
Cerebrospinal fluid biomarkers have shown disease-specific patterns in 4R-tauopathies. Total tau and phosphorylated tau demonstrate intermediate elevations in PSP between Alzheimer's disease and healthy controls, potentially reflecting different tau turnover dynamics. Neurofilament light chain (NfL) correlates with disease severity and progression in PSP and CBD, serving as a marker of axonal injury. The inflammatory markers IL-1β, TNF-α, and CCL2 show disease-specific alterations that may inform patient stratification for immunomodulatory trials.
Blood-based biomarkers offer advantages of accessibility and repeatability. Plasma NfL shows strong correlation with cerebrospinal fluid NfL and clinical measures, enabling large-scale studies and clinical monitoring. Emerging technologies including single molecule array (Simoa) detection allow measurement of cytokines at previously inaccessible concentrations. Tau fragments and aggregated tau in plasma may provide diagnostic information, though standardization across platforms remains challenging.
Soluble TREM2 (sTREM2) in cerebrospinal fluid reflects microglial activation and has been detected at elevated levels in PSP patients. The ratio of sTREM2 to total TREM2 may provide insight into microglial activation states and could serve as a pharmacodynamic marker for TREM2-targeted therapies.
Imaging Biomarkers
Molecular imaging provides non-invasive characterization of neuroinflammation in living patients. TSPO PET ligands enable visualization of microglial activation, with increased binding in PSP, CBD, and FTDP-17 correlating with post-mortem microglial activation markers. Second-generation ligands including [18F]DPA-714 show improved signal-to-noise characteristics.
Tau PET imaging using ligands such as [18F]AV-1451 (flortaucipir) enables visualization of tau pathology burden in vivo. In PSP, tau PET signal in the basal ganglia and brainstem correlates with disease severity and may predict clinical progression. Correlation studies between TSPO and tau PET signals provide evidence for spatial relationships between tau pathology and microglial activation.
Diffusion tensor imaging and magnetization transfer ratio imaging provide metrics of white matter integrity that may be particularly relevant for GGT and CBD. PET ligands targeting the translocator protein allow monitoring of microglial response to therapeutic intervention.
The clinical trial landscape for 4R-tauopathies has expanded significantly in recent years, though no disease-modifying therapies have yet received regulatory approval.
Active and Recent Trials
Several anti-tau immunotherapy trials are recruiting patients with PSP and CBD. These include both active immunization approaches (vaccines designed to generate anti-tau antibodies) and passive immunization (monoclonal antibody administration). Primary endpoints typically include clinical rating scales such as the PSP Rating Scale (PSPRS) and the Corticobasal Degeneration Inventory.
Tau aggregation inhibitor trials have completed phase I and phase II studies, with mixed results. The challenge of achieving sufficient brain penetration while maintaining target engagement has limited efficacy signals. Optimizing dosing regimens and patient selection based on biomarker profiles may improve outcomes in future trials.
Immunomodulatory trials targeting TREM2, complement, and other neuroinflammatory pathways are in various stages. The complexity of neuroimmune biology and the potential for both protective and pathogenic effects create challenges for trial design and interpretation.
Trial Design Considerations
Several factors complicate clinical trial execution in 4R-tauopathies. The relatively low prevalence of PSP and CBD compared to Alzheimer's disease limits enrollment rates and requires multi-site collaboration. The heterogeneity of clinical presentations, particularly in CBD, creates challenges for patient stratification and endpoint selection. The typically slow disease progression requires long trial durations or sensitive biomarkers to detect treatment effects.
The identification of biomarker endpoints that predict clinical benefit remains an important research priority. Surrogate markers of target engagement, such as reduction in cerebrospinal fluid tau or modulation of inflammatory biomarkers, could accelerate development programs.
The neuroimmune mechanisms in 4R-tauopathies have direct implications for patient care and clinical outcomes. Understanding these pathways informs both symptomatic management and disease-modifying therapeutic development.
Motor Symptom Implications
The brainstem and basal ganglia involvement in PSP and CBD correlates with the characteristic motor symptoms including vertical gaze palsy, parkinsonism, and postural instability. Neuroinflammatory contributions to neuronal dysfunction in these regions may accelerate motor progression. Anti-inflammatory interventions might protect remaining neurons and preserve motor function, though the timing of intervention may be critical given the advanced pathology at clinical presentation.
Cognitive and Behavioral Implications
The cortical involvement in CBD and limbic system predilection in AGD contribute to cognitive and behavioral symptoms. Neuroinflammation may exacerbate synaptic dysfunction and contribute to cognitive decline independent of tau pathology burden. Inflammatory markers have been associated with cognitive performance in PSP and CBD, suggesting potential for inflammatory modulation to preserve cognitive function.
Quality of Life Impact
The progressive nature of 4R-tauopathies and the limited treatment options create substantial quality of life burdens for patients and caregivers. The development of disease-modifying therapies that target neuroimmune mechanisms offers hope for preserving function and extending the period of independent living. Symptomatic treatments addressing neuroinflammation-related symptoms, such as sleep disturbance and mood changes, could improve quality of life even without disease modification.
Several challenges must be addressed to advance neuroimmune-targeted therapies for 4R-tauopathies.
Target Engagement and Biomarker Validation
The demonstration of target engagement in the brain remains a critical gap. Peripheral biomarkers may not accurately reflect central nervous system effects, and imaging endpoints require further validation. The development of PET ligands for TREM2, complement components, and other therapeutic targets would enable direct assessment of target engagement.
Therapeutic Window and Timing
The optimal timing of immunomodulatory intervention remains uncertain. Early intervention might prevent neuroinflammatory contributions to tau propagation, while later intervention might target established inflammation that contributes to symptom progression. Biomarker profiles that identify patients at different disease stages could guide treatment selection.
Combination Approaches
Given the complex pathophysiology of 4R-tauopathies, combination approaches targeting both tau pathology and neuroinflammation may be required. Clinical trial designs that evaluate combination therapies, including tau-directed and immunomodulatory approaches in sequence or simultaneously, will be important.
Precision Medicine Approaches
The heterogeneity within 4R-tauopathies, including genetic subtypes in FTDP-17 and variable clinical presentations, suggests that precision medicine approaches may improve therapeutic outcomes. Biomarker-driven patient selection and mutation-specific therapeutic strategies could enhance treatment efficacy.
The neuroimmune response in 4R-tauopathies encompasses both shared mechanisms that unify these disorders and distinctive patterns that explain their diverse clinical presentations. Microglial activation, TREM2 signaling, cytokine and chemokine production, and complement activation represent common pathological themes, while disease-specific anatomical distributions of pathology, unique glial involvement, and mutation-specific effects create distinctive inflammatory signatures. These insights provide a foundation for therapeutic targeting of neuroinflammation in 4R-tauopathies, with strategies including microglial modulation, complement inhibition, and disease-specific approaches under active development. The identification of biomarkers enabling non-invasive monitoring of neuroinflammation in vivo represents an additional priority that will facilitate clinical development of immunomodulatory therapies. As the field advances, the integration of neuroimmune mechanisms into comprehensive models of 4R-tauopathy pathogenesis promises to illuminate disease biology and accelerate the development of effective treatments for these devastating disorders.
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