Proteome Atlas for Neurodegenerative Diseases

Proteome Atlas for Neurodegenerative Diseases

The proteome atlas framework represents a paradigm shift in how neurodegenerative diseases are classified and understood. Rather than relying solely on clinical phenotype and histopathological hallmarks, proteome atlases map the complete landscape of protein abundance, post-translational modifications, solubility shifts, and network co-expression patterns across disease subtypes. This molecular approach reveals hidden biological signatures that transcend traditional clinical boundaries, enabling more precise patient stratification, earlier diagnosis, and targeted therapeutic development.

Overview

Neurodegenerative diseases have historically been defined by their clinical presentation and post-mortem pathology. [Alzheimer's Disease](/diseases/alzheimers-disease) is diagnosed by amyloid plaques and tau tangles, [Parkinson's Disease](/diseases/parkinsons-disease) by alpha-synuclein Lewy bodies, and [Frontotemporal Lobar Degeneration](/diseases/frontotemporal-dementia) by TDP-43 or tau inclusions. However, this classification system fails to capture the considerable molecular heterogeneity within each disease category, the overlapping biological processes across diseases, and the preclinical stages where molecular changes precede clinical symptoms by years or decades.

Proteome Atlas for Neurodegenerative Diseases

The proteome atlas framework represents a paradigm shift in how neurodegenerative diseases are classified and understood. Rather than relying solely on clinical phenotype and histopathological hallmarks, proteome atlases map the complete landscape of protein abundance, post-translational modifications, solubility shifts, and network co-expression patterns across disease subtypes. This molecular approach reveals hidden biological signatures that transcend traditional clinical boundaries, enabling more precise patient stratification, earlier diagnosis, and targeted therapeutic development.

Overview

Neurodegenerative diseases have historically been defined by their clinical presentation and post-mortem pathology. [Alzheimer's Disease](/diseases/alzheimers-disease) is diagnosed by amyloid plaques and tau tangles, [Parkinson's Disease](/diseases/parkinsons-disease) by alpha-synuclein Lewy bodies, and [Frontotemporal Lobar Degeneration](/diseases/frontotemporal-dementia) by TDP-43 or tau inclusions. However, this classification system fails to capture the considerable molecular heterogeneity within each disease category, the overlapping biological processes across diseases, and the preclinical stages where molecular changes precede clinical symptoms by years or decades.

The emergence of large-scale proteomics technologies — including mass spectrometry-based analysis of cerebrospinal fluid (CSF) and plasma, aptamer-based proteomics platforms (SomaScan, Olink), and proximity ligation assays — has enabled comprehensive protein quantification across thousands of analytes in patient cohorts. Proteome atlases integrate these data with network-based analyses (weighted gene co-expression network analysis, WGCNA) to identify disease-specific molecular signatures that can distinguish subtypes, predict progression, and highlight therapeutic targets.

Recent landmark studies have demonstrated the power of this approach in [Frontotemporal Lobar Degeneration](/diseases/frontotemporal-dementia) (Saloner 2025, Nat Neurosci), primary tauopathies (Kavanagh 2025, Acta Neuropathol), and Alzheimer's Disease (Bai 2020, Wingo 2021, Hammerling 2025) [@saloner2025; @kavanagh2025; @bai2020; @wingo2001; @hammerling2025].

CSF Proteome Atlas of Frontotemporal Lobar Degeneration

Study Design and Methodology

The landmark 2025 Nature Neuroscience study by Saloner and colleagues analyzed cerebrospinal fluid proteomes from 116 carriers of autosomal dominant [FTLD](/diseases/frontotemporal-dementia) mutations compared with 39 non-carrier controls [@saloner2025]. The study used aptamer-based proteomics (SomaScan v4) to quantify over 4,000 proteins across the cohort. Researchers applied weighted gene co-expression network analysis (WGCNA) to identify 31 protein co-expression modules, which were then correlated with both cross-sectional clinical indicators (CDR+NACC-FTLD, CSF neurofilament light chain, bilateral frontotemporal volume) and longitudinal cognitive trajectory measures.

This approach treats the CSF proteome as an integrated network rather than a collection of individual biomarkers, capturing the coordinated biological processes that characterize disease states.

Disease-Specific Molecular Signatures

The WGCNA analysis revealed that each major genetic subtype of [FTLD](/diseases/frontotemporal-dementia) harbors a distinct proteomic signature:

• C9orf72 repeat expansion carriers: Show increased abundance of RNA splicing modules, reflecting the disruption of nucleocytoplasmic transport and RNA processing caused by GGGGCC repeat transcription and dipeptide repeat protein aggregation [@soto2023].
• GRN (progranulin) mutation carriers: Also display increased RNA splicing modules, consistent with the known role of progranulin in lysosomal function and immune regulation.
• MAPT (tau) mutation carriers: Exhibit increased extracellular matrix (ECM) modules, reflecting the distinct tau pathology and neuronal vulnerability patterns in this genetic subtype.

Cross-Platform Validation

The researchers validated their findings across independent cohorts, including the 4RTNI cohort (sporadic progressive supranuclear palsy-Richardson syndrome) and the BioFINDER 2 cohort (frontotemporal dementia spectrum clinical syndromes), using both SomaScan and Olink platforms [@saloner2025]. This cross-platform replication confirms that the molecular signatures are robust and not artifacts of a single measurement technology.

The ability to validate findings in sporadic disease cohorts — not just genetic carriers — establishes the generalizability of proteome-based disease classification beyond the monogenic forms of [FTLD](/diseases/frontotemporal-dementia).

Therapeutic Implications

The study identified "hub" proteins — highly connected nodes within the affected co-expression modules — as particularly promising for biomarker and therapeutic development [@saloner2025]. These hub proteins represent the master regulators of disease-related biological processes. Network-based proteomics demonstrated potential for identifying replicable molecular pathways that could guide drug development for adults living with [FTLD](/diseases/frontotemporal-dementia).

Tauopathy Proteome Atlas: Molecular Classification of Primary Tauopathies

Comparative Proteomics of CBD, Pick's Disease, and PSP

A parallel breakthrough came from the 2025 Acta Neuropathologica study by Kavanagh and colleagues, which applied sarkosyl fractionation and mass spectrometry to post-mortem brain tissue from three primary tauopathies: corticobasal degeneration ([CBD](/diseases/corticobasal-degeneration)), Pick's disease (PiD), and progressive supranuclear palsy ([PSP](/diseases/progressive-supranuclear-palsy)) [@kavanagh2025].

The study examined not just protein abundance, but also protein solubility — a critical distinction because disease-associated proteins often shift from soluble to insoluble compartments. The findings revealed that [CBD](/diseases/corticobasal-degeneration) and Pick's disease showed the greatest proteomic similarity in both the soluble and insoluble fractions, while [PSP](/diseases/progressive-supranuclear-palsy) exhibited the most divergent profile [@kavanagh2025]. This finding challenges the traditional grouping of these "4R tauopathies" and suggests that [CBD](/diseases/corticobasal-degeneration) and Pick's disease share more biological overlap than [CBD](/diseases/corticobasal-degeneration) and [PSP](/diseases/progressive-supranuclear-palsy).

Critical Solubility Shifts

The study identified consistent solubility changes across the tauopathies affecting four major biological categories:

Biomarker Candidates from Tauopathy Proteomics

The Kavanagh study identified several proteins as promising biomarker candidates [@kavanagh2025]:

• SORT1 (Sortilin): Verified by immunofluorescence to aggregate in [CBD](/diseases/corticobasal-degeneration) tissue. SORT1 is involved in trafficking of proteins to lysosomes and the cell surface, and its aggregation in [CBD](/diseases/corticobasal-degeneration) specifically suggests a disease-specific pathological process.
• ROCK1 and JAK2: Show solubility shifts that affect key signaling pathways — ROCK1 in cytoskeletal regulation and JAK2 in cytokine signaling.
• MAPT (tau): Peptide-level solubility analysis revealed a bias to 4R tau in the [CBD](/diseases/corticobasal-degeneration) insoluble fraction, providing molecular confirmation of the isoform composition of pathological tau in each disease.

ProPPr Analysis of Phospho-Tau-Associated Proteomes

Complementing the Kavanagh study, Morderer and colleagues (2025, Brain) used probe-dependent proximity profiling (ProPPr) to map the protein interaction landscape of phospho-tau across tauopathies [@morderer2025]. ProPPr uses engineered peroxidase enzymes to label proteins in proximity to a bait protein (phospho-tau) in fixed tissue. This approach uncovered both similarities and differences in the phospho-tau-associated proteome between [CBD](/diseases/corticobasal-degeneration), [PSP](/diseases/progressive-supranuclear-palsy), and [Alzheimer's Disease](/diseases/alzheimers-disease).

The spatial resolution of ProPPr revealed that some tau-associated proteins cluster in specific subcellular compartments in disease-specific patterns, while others show more widespread changes. This spatial dimension of proteomic analysis adds a new layer of information beyond simple abundance or solubility measurements.

Alzheimer's Disease Proteome Atlases

Deep Brain Proteomics

Large-scale proteomics has also transformed understanding of [Alzheimer's Disease](/diseases/alzheimers-disease). The landmark study by Bai and colleagues (2020) performed deep proteomic profiling of human [Alzheimer's Disease](/diseases/alzheimers-disease) brain tissue, identifying over 10,000 proteins and revealing coordinated changes in specific biological pathways [@bai2020]. The study found that synaptic proteins, mitochondrial proteins, and proteins involved in proteostasis showed the most pronounced changes in [Alzheimer's Disease](/diseases/alzheimers-disease), providing a molecular readout of the processes that underlie cognitive decline.

Wingo and colleagues (2021, Nat Neurosci) applied WGCNA to large-scale CSF proteomics in [Alzheimer's Disease](/diseases/alzheimers-disease), identifying proteomic signatures of neuronal dysfunction that correlated with established biomarkers ([amyloid-beta 42](/biomarkers/amyloid-beta-42-40-ratio), [phospho-tau](/biomarkers/tau-pathology-biomarkers), [neurofilament light](/biomarkers/neurofilament-light-chain)) and clinical outcomes [@wingo2001].

AD Subtype Classification via CSF Proteomics

Hammerling and colleagues (2025) analyzed CSF proteome network topology to identify [Alzheimer's Disease](/diseases/alzheimers-disease) subtypes with distinct biological signatures [@hammerling2025]. The study found that network-based analysis outperformed traditional biomarker-based classification in predicting clinical progression, suggesting that the coordinated biological processes captured by proteomic networks carry more prognostic information than individual biomarkers.

Plasma Proteome Atlas for Neurodegeneration

Large-scale plasma proteomics has emerged as a complementary approach to CSF analysis, offering the advantage of accessible sampling. Whelan and colleagues (2024, Nat Med) created an atlas of the plasma proteome for brain diseases, demonstrating that plasma protein signatures can classify neurodegenerative disease subtypes with high accuracy [@whelan2024]. Hanssen and colleagues (2024, Nat Rev Neurol) further established the utility of plasma proteomics for neurodegenerative disease classification and progression monitoring [@hanssen2024].

Molecular Classification Framework

The convergence of findings across diseases reveals a molecular classification framework that transcends traditional clinical boundaries. The following diagram illustrates how proteome atlases classify neurodegenerative diseases by their molecular signatures:

Disease Subtype Molecular Signatures

Alzheimer's Disease Subtypes

The molecular signatures of [Alzheimer's Disease](/diseases/alzheimers-disease) subtypes include:

• Amyloid-predominant type: Characterized by elevated [amyloid-beta](/biomarkers/amyloid-beta-42-40-ratio) aggregations, early amyloid PET positivity, and relatively slower progression. The proteomic signature reflects amyloid-driven pathophysiology with downstream tau pathology.
• Tau-predominant type: Shows elevated phospho-tau species (p-tau 181, p-tau 217) with more aggressive progression. The proteomic signature reveals greater synaptic loss and mitochondrial dysfunction.
• TAR DNA-binding protein 43 (TDP-43) predominant type: AD with limbic-predominant age-related TDP-43 encephalopathy (LATE) shows a distinct molecular signature with emphasis on hippocampal vulnerability and memory impairment out of proportion to amyloid/tau burden.
• Cerebral amyloid angiopathy (CAA) type: Shows vascular amyloid deposition with distinct proteomic signatures involving blood-brain barrier proteins and vascular matrix remodeling.

FTLD Subtypes

The proteomic signatures for [Frontotemporal Lobar Degeneration](/diseases/frontotemporal-dementia) subtypes are now well-characterized:

• C9orf72 subtype: RNA splicing modules elevated, dipeptide repeat proteins detected in proteome, nucleocytoplasmic transport proteins altered.
• GRN subtype: RNA splicing and lysosomal modules both elevated, reflecting the dual roles of progranulin in RNA metabolism and lysosomal function.
• MAPT subtype: Extracellular matrix and cytoskeletal modules elevated, consistent with the microtubule-stabilizing function of tau protein.
• TAU subtype: 4R tau-specific proteomic signatures with distinct solubility patterns between [CBD](/diseases/corticobasal-degeneration), Pick's disease, and [PSP](/diseases/progressive-supranuclear-palsy).

Parkinson's Disease and Synucleinopathies

Emerging proteomic studies of [Parkinson's Disease](/diseases/parkinsons-disease) and related synucleinopathies have identified:

• Alpha-synuclein oligomers: The key pathogenic proteomic signature in [Parkinson's Disease](/diseases/parkinsons-disease), [Dementia with Lewy Bodies](/diseases/dementia-with-lewy-bodies), and [Multiple System Atrophy](/diseases/multiple-system-atrophy).
• Lysosomal dysfunction signature: Consistent with the genetic evidence from [GBA](/genes/gba) mutations and the role of lysosomal pathways in alpha-synuclein clearance.
• Mitochondrial dysfunction signature: Reflecting the established role of mitochondrial pathology in [Parkinson's Disease](/diseases/parkinsons-disease) through PINK1, PRKN, and other genes.

Amyotrophic Lateral Sclerosis (ALS) and FTD Overlap

The proteomic signatures at the [ALS](/diseases/als-amyotrophic-lateral-sclerosis)-[FTLD](/diseases/frontotemporal-dementia) interface reveal:

• TDP-43 pathology: Shared across the majority of ALS and many FTLD cases, with concordant proteomic signatures of RNA metabolism disruption.
• FUS pathology: In a subset of ALS and FTLD-FUS, distinct proteomic signatures involving stress granule proteins and nuclear import factors.
• C9orf72 repeat expansion: The most common genetic cause of both conditions, showing the characteristic RNA splicing module elevation in both diseases.

Biomarker Discovery from Proteome Atlases

Hub Proteins as Biomarker Candidates

The network-based approach to proteomics identifies "hub proteins" — highly connected nodes within disease-associated co-expression modules — as particularly valuable biomarkers. These hub proteins represent master regulators of disease biology, making them more likely to reflect the integrated state of the biological system than individual markers.

Key hub proteins identified across studies include:

• Neurofilament light chain (NfL): Consistently elevated across neurodegenerative diseases in both CSF and plasma, reflecting axonal degeneration. NfL is now established as a cross-disease marker of neurodegeneration severity [@zetterberg2019].
• GFAP (glial fibrillary acidic protein): Elevated in diseases with astrocyte activation, particularly [Alzheimer's Disease](/diseases/alzheimers-disease) and [FTLD](/diseases/frontotemporal-dementia).
• YKL-40 (chitinase-3-like protein 1): Marker of neuroinflammation and glial activation, elevated across multiple neurodegenerative conditions.
• TREM2 (Triggering Receptor Expressed on Myeloid Cells 2): Microglial activation marker with distinct patterns in different diseases and disease stages.

Disease-Specific Biomarker Candidates

• SORT1 (Sortilin): Highly insoluble in [CBD](/diseases/corticobasal-degeneration) specifically, making it a candidate biomarker for CBD vs. other tauopathies.
• ROCK1, JAK2: Solubility-shifted in tauopathies, potential markers of disease-specific pathway dysregulation.
• Synaptic proteins (GAP43, neurogranin, SNAP25): Decreased in synaptic/neuronal modules across diseases, reflecting synaptic loss as a common endpoint.
• Autophagy proteins (p62/SQSTM1, LC3): Decreased in autophagy modules, reflecting the proteostasis failure that characterizes neurodegeneration.

Fluid Biomarker Integration

Proteome atlases enable the integration of multiple fluid biomarkers into composite scores that capture disease biology more comprehensively than single markers. The AT(N) framework for [Alzheimer's Disease](/diseases/alzheimers-disease) — based on amyloid (A), tau (T), and neurodegeneration (N) biomarkers — represents an early implementation of this approach [@bjorkhem2009]. Proteome atlases extend this framework by identifying additional biological axes (lysosomal function, synaptic integrity, inflammatory state, vascular function) that can be captured by fluid biomarkers.

Treatment Acceleration Through Proteome Atlases

Target Identification

Proteome atlases accelerate treatment discovery through several mechanisms:

Therapeutic Strategies Implied by Proteome Atlas Findings

The molecular signatures identified by proteome atlases suggest several therapeutic strategies:

• Synaptic protection: Given the universal decrease in synaptic/neuronal modules across diseases, interventions that protect synapses or promote synaptic regeneration represent a broadly applicable approach.
• Autophagy enhancement: The consistent autophagy module decrease across [FTLD](/diseases/frontotemporal-dementia) subtypes and [Alzheimer's Disease](/diseases/alzheimers-disease) points to autophagy induction as a disease-modifying strategy.
• Lysosomal modulation: Disease-specific lysosomal signatures (SORT1 in [CBD](/diseases/corticobasal-degeneration), GBA-related pathways in [Parkinson's Disease](/diseases/parkinsons-disease)) suggest lysosomal enhancement as a targeted approach.
• RNA splicing repair: Elevated RNA splicing modules in [C9orf72](/genes/c9orf72) and [GRN](/genes/grn)-related [FTLD](/diseases/frontotemporal-disease) suggest that targeted RNA splicing modifiers could address the underlying biology in these genetic subtypes.
• Extracellular matrix modulation: Elevated ECM modules in [MAPT](/genes/mapt) mutation carriers suggest that matrix remodeling interventions could address this specific biological process.

Multi-Disease Proteome Atlas Integration

The next frontier in neurodegenerative disease proteomics is the integration of disease-specific atlases into a unified multi-disease framework. Such an integration would enable:

• Cross-disease molecular comparisons: Identifying shared vs. disease-specific biological processes across the full spectrum of neurodegenerative diseases.
• Patient stratification across diseases: Classifying patients not by their clinical diagnosis but by their molecular profile, potentially revealing that patients with different clinical labels share more molecular similarity than patients with the same label.
• Platform-independent classification: Developing classification systems that are robust across different proteomic measurement platforms (SomaScan, Olink, mass spectrometry).
• Longitudinal proteomic trajectories: Mapping how molecular signatures change over the disease course, from preclinical stages through mild cognitive impairment to dementia.

Cross-Linking to Related Pages

The proteome atlas framework connects to numerous related pages across the wiki:

Disease Pages

• [Alzheimer's Disease](/diseases/alzheimers-disease) — CSF proteome subtypes, AD-specific molecular signatures
• [Frontotemporal Dementia](/diseases/frontotemporal-dementia) — CSF proteome atlas, FTLD subtype classification
• [Parkinson's Disease](/diseases/parkinsons-disease) — Synuclein proteomics, lysosomal dysfunction signatures
• [Corticobasal Degeneration](/diseases/corticobasal-degeneration) — Tauopathy proteomics, SORT1 aggregation
• [Progressive Supranuclear Palsy](/diseases/progressive-supranuclear-palsy) — Tauopathy proteomics, PSP divergence
• [ALS](/diseases/als-amyotrophic-lateral-sclerosis) — ALS-FTD overlap, TDP-43 proteomics

Biomarker Pages

• [Neurofilament Light Chain](/biomarkers/neurofilament-light-chain) — Cross-disease neurodegeneration marker
• [CSF Biomarkers](/biomarkers/csf-biomarkers-overview) — CSF proteome methodology
• [Alzheimer's Biomarkers](/biomarkers/alzheimers-biomarkers) — AT(N) framework, fluid biomarker integration
• [Alpha-Synuclein Seeding Assays](/biomarkers/alpha-synuclein-seed-amplification) — Synucleinopathy proteomics

Gene/Protein Pages

• [C9orf72](/genes/c9orf72) — RNA splicing module elevation, dipeptide repeat proteins
• [GRN (Progranulin)](/genes/grn) — Lysosomal and RNA metabolism dysfunction
• [MAPT (Tau Protein)](/genes/mapt) — 4R tau proteomics, extracellular matrix remodeling
• [TREM2](/genes/trem2) — Microglial activation, disease-modifying variant
• [GBA](/genes/gba) — Lysosomal dysfunction in PD, alpha-synuclein clearance

Mechanism Pages

• [Protein Aggregation Mechanisms](/mechanisms/protein-aggregation-mechanisms) — Proteostasis failure, solubility shifts
• [ER Stress and Unfolded Protein Response](/mechanisms/er-stress-unfolded-protein-response) — Proteostasis pathways
• [Synaptic Dysfunction in Neurodegeneration](/mechanisms/synaptic-dysfunction-neurodegeneration) — Synaptic module decrease
• [Neuroinflammation Mechanisms](/mechanisms/neuroinflammation-mechanisms) — Microglial activation signatures
• [Tauopathies Comparison Matrix](/mechanisms/tauopathies-comparison-matrix) — Cross-tauopathy molecular comparison

Therapeutic Pages

• [Anti-Aggregation Therapies](/treatments/anti-aggregation-therapies) — Targeting disease-specific protein aggregation
• [Lysosomal Enhancement Therapies](/treatments/lysosomal-enhancement-therapies) — Targeting lysosomal dysfunction
• [Synaptic Protection Strategies](/treatments/synaptic-protection-strategies) — Neuroprotective approaches

Future Directions

The proteome atlas approach is rapidly evolving with several key developments on the horizon:

The proteome atlas represents a fundamental advance in the molecular understanding of neurodegenerative diseases, moving the field from clinical classification based on pathological hallmarks toward biology-driven classification based on measurable molecular signatures. This shift has profound implications for diagnosis, patient stratification, clinical trial design, and therapeutic development.