DLK2 — Delta-Like Non-Canonical Notch Ligand 2

DLK2 — Delta-Like Non-Canonical Notch Ligand 2

Pathway Diagram

```mermaid
flowchart TD
DLK2["DLK2"]
style DLK2 fill:#006494,stroke:#4fc3f7,stroke-width:3px,color:#e0e0e0
Notch_Signaling["Notch Signaling"]
DLK2 -->|"involved in"| Notch_Signaling
Notch_Signaling_Pathway["Notch Signaling Pathway"]
DLK2 -->|"component of"| Notch_Signaling_Pathway
Als["Als"]
DLK2 -->|"expressed in"| Als
DLK2 -.->|"inhibits"| Als
ALS["ALS"]
DLK2 -->|"expressed in"| ALS
Neurogenesis["Neurogenesis"]
DLK2 -->|"expressed in"| Neurogenesis
Notch["Notch"]
DLK2 -.->|"inhibits"| Notch
ALDH1L1["ALDH1L1"]
DLK2 -->|"expressed in"| ALDH1L1
SOX2["SOX2"]
SOX2 -.->|"inhibits"| DLK2
EGF["EGF"]
EGF -->|"expressed in"| DLK2
GFAP["GFAP"]
GFAP -.->|"inhibits"| DLK2
NESTIN["NESTIN"]
NESTIN -->|"expressed in"| DLK2
ALDH1L1 -->|"expressed in"| DLK2
NOTCH1["NOTCH1"]
NOTCH1 -.->|"inhibits"| DLK2
ALDH1L1 -.->|"inhibits"| DLK2
VIMENTIN["VIMENTIN"]
VIMENTIN -.->|"inhibits"| DLK2
style Notch_Signaling fill:#5d4400,stroke:#4fc3f7,color:#e0e0e0
style Notch_Signaling_Pathway fill:#5d4400,stroke:#4fc3f7,color:#e0e0e0
style Als fill:#ef5350,stroke:#4fc3f7,color:#e0e0e0
style ALS fill:#ef5350,stroke:#4fc3f7,color:#e0e0e0
style Neurogenesis fill:#5d4400,stroke:#4fc3f7,color:#e0e0e0
style Notch fill:#5d4400,stroke:#4fc3f7,color:#e0e0e0
style ALDH1L1 fill:#1b5e20,stroke:#4fc3f7,color:#e0e0e0
style SOX2 fill:#1b5e20,stroke:#4fc3f7,color:#e0e0e0
style EGF fill:#1b5e20,str

DLK2 — Delta-Like Non-Canonical Notch Ligand 2

Pathway Diagram

Overview

DLK2 (Delta-Like Non-Canonical Notch Ligand 2), also known as Delta-like 2 or Poglut1, is a single-pass transmembrane protein that functions as a non-canonical Notch ligand. Unlike canonical Delta-like ligands (DLL1, DLL3, DLL4), DLK2 lacks the DSL domain required for canonical Notch receptor activation and instead modulates Notch signaling through distinct mechanisms.[@ai2022] DLK2 plays critical roles in embryonic development, tissue homeostasis, stem cell maintenance, and has emerging roles in neurodevelopment and neurodegenerative diseases [1].

<div class="infobox infobox-gene">

| | |
|---|---|
| Gene Symbol | DLK2 |
| Full Name | Delta-Like Non-Canonical Notch Ligand 2 |
| Chromosome | 6p25.1 |
| NCBI Gene ID | [203522](https://www.ncbi.nlm.nih.gov/gene/203522) |
| OMIM | [612651](https://www.omim.org/entry/612651) |
| Ensembl ID | ENSG00000154640 |
| UniProt ID | [Q9Y5F7](https://www.uniprot.org/uniprot/Q9Y5F7) |
| Associated Diseases | Alzheimer's Disease, Parkinson's Disease, Neuroinflammation, Cancer |

</div>

Gene Structure and Protein Architecture

The DLK2 gene spans approximately 9.5 kb and consists of 8 exons encoding a 387-amino acid transmembrane protein. The protein structure includes:

• N-terminal extracellular domain: Contains multiple epidermal growth factor-like (EGF) repeats (typically 6-8) that mediate protein-protein interactions
• Single transmembrane helix: Spanning the plasma membrane
• C-terminal intracellular domain: Short cytoplasmic tail lacking canonical signaling motifs

Expression Pattern

Tissue Distribution

DLK2 exhibits broad but regulated expression across multiple tissue types:

• Brain: Highest expression in the cerebral cortex, hippocampus, and cerebellum
• Developing nervous system: Prominent expression during embryonic neurogenesis
• Hematopoietic system: Expressed in hematopoietic stem and progenitor cells
• Adipose tissue: Regulated during adipogenesis
• Liver and kidney: Moderate expression in parenchymal cells

Cellular Localization

In neural cells, DLK2 localizes to:

• Neuronal soma and dendrites: Particularly in pyramidal neurons of the hippocampus and cortex
• Synaptic compartments: Present in both pre- and post-synaptic terminals
• Glial cells: Expressed in astrocytes, particularly during reactive gliosis

Molecular Functions and Signaling Pathways

Notch Signaling Modulation

DLK2 modulates Notch signaling through multiple mechanisms:

Research by Zhang et al. (2019) demonstrated that DLK2 acts as a negative regulator of Notch signaling in various contexts, with important implications for neural stem cell differentiation and maintenance [4].

Interaction Network

DLK2 interacts with multiple proteins:

• Notch receptors (NOTCH1, NOTCH2, NOTCH3): Direct interaction through extracellular domains
• Presenilin proteins: Part of the γ-secretase complex involved in Notch processing
• E3 ubiquitin ligases (CUL4, DDB1): Mediating receptor turnover
• Protein kinases: Including CK2 and PKC isoforms that regulate DLK2 activity

Non-Notch Signaling

Emerging evidence suggests DLK2 can signal independently of Notch:

• ERK/MAPK pathway: Activation of downstream MAPK signaling
• PI3K/Akt pathway: Regulation of cell survival signals
• Wnt/β-catenin crosstalk: Modulation of Wnt target gene expression

Role in Neurodevelopment

Neural Stem Cell Maintenance

DLK2 plays crucial roles in maintaining neural stem cell (NSC) pools during development and in adult neurogenesis:

• Stem cell proliferation: DLK2 expression promotes NSC proliferation while inhibiting premature differentiation
• Fate specification: Modulates the balance between neuronal and glial lineage commitment
• Spatial patterning: Contributes to region-specific neurogenesis in the developing brain

Neuronal Differentiation

During cortical development, DLK2 regulates:

• Cortical neuron layering: Controls the temporal sequence of neuronal migration and positioning
• Dendritic morphogenesis: Influences dendritic arborization and spine formation
• Axonal guidance: Participates in axon pathfinding through modulation of growth cone dynamics

Synaptogenesis and Synaptic Function

DLK2 contributes to synaptic development and function:

• Synaptic assembly: Localizes to developing synapses during formation
• Synaptic plasticity: Modulates both long-term potentiation (LTP) and long-term depression (LTD)
• Dendritic spine maintenance: Regulates spine density and morphology

Implications in Alzheimer's Disease

Amyloid Metabolism

DLK2 intersects with amyloid precursor protein (APP) processing:

• α-secretase regulation: DLK2 expression correlates with ADAM10 levels, influencing non-amyloidogenic processing
• β-secretase modulation: Altered DLK2 in AD may affect BACE1 activity and Aβ production
• γ-secretase crosstalk: Interaction with presenilin-containing complexes

Tau Pathology

Recent studies by Park et al. (2023) identified DLK2 as a modulator of tau phosphorylation and spreading:

• Tau kinase regulation: DLK2 influences activity of tau kinases including GSK-3β and CDK5
• Tau aggregation: Modulates tau oligomerization and aggregation propensity
• Tau spread: Contributes to propagation of pathological tau across brain regions

Neuroinflammation

DLK2 plays complex roles in neuroinflammatory processes:

• Microglial activation: Regulates microglial inflammatory responses
• Cytokine modulation: Alters production of IL-1β, TNF-α, and IL-6
• Astrocyte reactivity: Influences astrocyte phenotypic changes in AD

Synaptic Dysfunction

DLK2 deficiency contributes to synaptic pathology:

• Synaptic protein loss: Reduced synaptic markers (synaptophysin, PSD95)
• Electrophysiological deficits: Impaired LTP and basal transmission
• Behavioral correlates: Memory deficits in DLK2 knock-out models

Clinical Evidence

Analysis of human brain samples has revealed:

• Altered expression: DLK2 mRNA and protein levels change in AD cortex and hippocampus
• Localization shifts: Redistribution from synaptic to somatic compartments
• Correlation with disease severity: Expression changes correlate with cognitive decline measures

Role in Other Neurodegenerative Diseases

Parkinson's Disease

DLK2 involvement in PD includes:

• Dopaminergic neuron survival: Modulates vulnerability of substantia nigra neurons
• α-synuclein interaction: Potential regulation of α-synuclein aggregation
• Mitochondrial function: Influence on mitochondrial dynamics and quality control

Amyotrophic Lateral Sclerosis (ALS)

In ALS models, DLK2:

• Motor neuron survival: Affects motor neuron viability in cellular models
• Glial crosstalk: Modulates non-cell-autonomous toxicity
• Protein aggregation: Interacts with TDP-43 pathology

Multiple Sclerosis

DLK2 contributes to demyelination and repair:

• Oligodendrocyte function: Regulates oligodendrocyte precursor differentiation
• Myelin maintenance: Essential for proper myelination
• Remyelination: Modulates repair processes in lesion areas

Therapeutic Implications

Target Validation

DLK2 represents a potential therapeutic target for neurodegenerative diseases:

• Notch modulation: DLK2-based strategies to normalize Notch signaling
• Neuroinflammation: Targeting DLK2-mediated inflammatory pathways
• Synaptic protection: Developing compounds that enhance DLK2's synaptic benefits

Drug Development Approaches

Several strategies are being explored:

Challenges and Considerations

Developing DLK2-targeted therapies faces challenges:

• Complexity of Notch crosstalk: Multiple pathways affected by modulation
• Tissue-specific effects: Different effects in various brain regions
• BBB penetration: Therapeutic delivery to CNS remains challenging

Research Methods and Tools

Genetic Models

• Knockout mice: Complete and conditional DLK2 deletion models
• Transgenic models: Overexpression and mutant DLK2 lines
• Conditional knockouts: Cell-type specific ablation

Biochemical Approaches

• Co-immunoprecipitation: Protein interaction studies
• Luciferase assays: Reporter gene analysis for Notch activity
• Proteomics: Global interaction mapping

Imaging Techniques

• Confocal microscopy: Subcellular localization studies
• Electron microscopy: Ultrastructural analysis of synapses
• Live cell imaging: Dynamic trafficking studies

Animal Models and Phenotypes

DLK2 Knockout Mice

Complete DLK2 knockout mice show:

• Perinatal lethality: Some models show embryonic or early postnatal death
• Growth retardation: Reduced body weight
• Neurological phenotypes: Behavioral abnormalities and learning deficits
• Hematopoietic defects: Altered hematopoiesis

Conditional Knockouts

Neuron-specific deletion reveals:

• Memory deficits: Impaired hippocampal-dependent learning
• Synaptic abnormalities: Reduced spine density and function
• Altered neurogenesis: Changes in adult hippocampal neurogenesis

Transgenic Overexpression

Neuronal overexpression produces:

• Enhanced Notch signaling: Increased NICD nuclear localization
• Neurogenesis effects: Altered stem cell dynamics
• Behavioral changes: Multiple cognitive modifications

Biomarker Potential

Diagnostic Applications

DLK2 as a biomarker:

• CSF detection: Measurable in cerebrospinal fluid
• Peripheral markers: Potential blood-based indicators
• Imaging correlates: PET ligand development opportunities

Disease Monitoring

DLK2 levels may serve to:

• Track progression: Correlation with disease stage
• Therapeutic monitoring: Response to disease-modifying treatments
• Prognostic value: Predictive potential for outcomes

Cross-Linking to Related Pages

Related Mechanisms

• [Notch Signaling Pathway](/mechanisms/notch-signaling-pathway) — Canonical and non-canonical Notch modulation
• [Neuroinflammation](/mechanisms/neuroinflammation) — Inflammatory processes in neurodegeneration
• [Synaptic Plasticity](/mechanisms/synaptic-plasticity) — Synaptic function and dysfunction
• [Tau Pathology](/mechanisms/tau-pathology) — Tau phosphorylation and spread
• [Amyloid Cascade](/mechanisms/amyloid-cascade) — Amyloid metabolism in AD

Related Genes and Proteins

• [NOTCH1](/genes/notch1) — Canonical Notch receptor
• [NOTCH3](/genes/notch3) — Alzheimer's-associated Notch isoform
• [DLL1](/genes/dll1) — Canonical Notch ligand
• [PSEN1](/genes/psen1) — γ-Secretase component
• [APP](/genes/app) — Amyloid precursor protein

Related Diseases

• [Alzheimer's Disease](/diseases/alzheimers-disease)
• [Parkinson's Disease](/diseases/parkinsons-disease)
• [Frontotemporal Dementia](/diseases/frontotemporal-dementia)

DLK2 in Autophagy and Protein Clearance

Regulation of Autophagic Flux

DLK2 plays important roles in autophagy:

Molecular Mechanisms

• mTORC1 interaction: DLK2 modulates mTORC1 activity
• ULK1 complex regulation: Affects initiation of autophagy
• VPS34 complex: Modulates class III PI3K activity

Implications for Neurodegeneration

• Aggregate clearance: DLK2 affects removal of toxic proteins
• Synaptic homeostasis: Autophagy maintains synaptic proteostasis
• Disease relevance: Impaired autophagy in AD and PD

Lysosomal Function

• Cathepsin activity: DLK2 influences lysosomal protease function
• Autolysosome formation: Fusion process modulation
• Neuronal vulnerability: Effects on long-lived neurons

DLK2 in Microglial Biology

Microglial Polarization

DLK2 modulates microglial phenotype:

Pro-inflammatory State

• M1 polarization: DLK2 affects classical activation
• Cytokine production: Modulates TNF-α, IL-1β, IL-6
• Nitric oxide generation: Impacts oxidative stress

Alternative Activation

• M2 polarization: DLK2 influences anti-inflammatory state
• Neurotrophic support: BDNF and other factor production
• Tissue repair: Promotes healing responses

Neuroinflammation Modulation

• Chemokine regulation: Controls inflammatory cell recruitment
• NF-κB signaling: Affects master inflammatory pathway
• Therapeutic implications: Targeting DLK2 for anti-inflammatory effects

DLK2 Structure-Function Relationships

Domain Analysis

Extracellular Domain

• EGF repeats: Mediate protein-protein interactions (typically 6-8 repeats)
• Glycosylation sites: Post-translational modifications affect function
• Notch binding: Ligand-receptor interaction properties

Transmembrane Domain

• Helix properties: Single-pass transmembrane configuration
• Dimerization potential: Functional assembly at membrane
• Signal transduction: Structural basis for signaling

Intracellular Domain

• Phosphorylation sites: Multiple serine/threonine residues
• Protein interaction motifs: Signaling complex formation
• Trafficking signals: Subcellular localization determinants

Post-Translational Modifications

• Phosphorylation: Kinase-mediated regulation (PKC, CK2)
• Ubiquitination: Degradation control and turnover
• Glycosylation: Secretory pathway processing and function

DLK2 in Neurodevelopmental Disorders

Autism Spectrum Disorders

• Synaptic function: DLK2 implicated in ASD pathogenesis
• Social behavior: Mouse model studies show alterations
• Comorbid conditions: Epilepsy and intellectual disability overlap

Schizophrenia

• Notch pathway links: Schizophrenia genetics implicate Notch
• Synaptic pruning: Developmental mechanisms affected
• Therapeutic implications: Potential intervention points

DLK2 in Aging and Cellular Senescence

Cellular Senescence

• Senescence-associated secretory phenotype: DLK2 modulation effects
• Inflammaging: Chronic inflammation in aging brain
• Cell cycle regulation: Interactions with senescence pathways

Age-Related Changes

• Expression decline: DLK2 levels decrease with aging
• Notch dysregulation: Age-related pathway changes
• Neurodegeneration risk: Cumulative effects over time

DLK2 in Model Systems

In Vitro Models

• Neuronal cultures: Primary neuron studies reveal functions
• Stem cell differentiation: Neural lineage commitment roles
• Organoid systems: Brain organoid modeling of disease

In Vivo Models

• Knockout mice: Phenotype characterization available
• Transgenic models: Disease-relevant mutations being developed
• Pharmacological studies: Drug testing platforms in use

DLK2 Therapeutic Targeting

Small Molecule Modulators

• Notch pathway inhibitors: Downstream effects on DLK2 signaling
• Notch pathway activators: Opposite effects on pathway
• Receptor-specific targeting: Greater selectivity possible

Antibody Approaches

• Neutralizing antibodies: Can block DLK2 function
• Agonistic antibodies: Can enhance DLK2 signaling
• Therapeutic potential: CNS delivery remains challenging

Gene Therapy Strategies

• DLK2 overexpression: Neuroprotective approaches under study
• RNAi knockdown: Reduce DLK2 when detrimental
• CRISPR editing: Precise genetic manipulation possible

Combination Therapies

• Multi-target approaches: Address multiple pathways simultaneously
• Synergistic effects: Enhanced therapeutic benefit possible
• Reduced toxicity: Lower doses of each component feasible

Biomarker Potential

Diagnostic Applications

• CSF DLK2 levels: May correlate with disease stage
• Blood-based markers: Peripheral measurement possible
• Imaging correlates: PET ligand development opportunities

Disease Monitoring

• Progression tracking: Longitudinal measurements useful
• Therapeutic response: Can monitor treatment efficacy
• Prognostic value: May predict outcomes

Future Directions

Outstanding Questions

Emerging Research Areas

• Single-cell analysis: Defining DLK2's role in specific neuronal populations
• Spatial transcriptomics: Mapping DLK2 expression in disease contexts
• Systems biology: Integrating DLK2 into comprehensive neurodegeneration models

Key Publications

DLK2 in Specific Brain Regions

Hippocampal Function

DLK2 plays crucial roles in hippocampal circuitry:

CA1 Pyramidal Neurons:

• High DLK2 expression in CA1 region
• Modulates Notch signaling during memory consolidation
• Affects synaptic plasticity mechanisms
• Regulates dendritic integration

• DLK2 in granule cells controls neurogenesis
• Modulates pattern separation capacity
• Affects adult hippocampal plasticity
• Contributes to cognitive flexibility

Cortical Function

In the cerebral cortex, DLK2 contributes to:

Layer-Specific Functions:

• Layer 2/3: Cortical circuit formation and plasticity
• Layer 4: Thalamocortical input processing
• Layer 5: Corticospinal motor command integration

• Regulates entorhinal cortex inputs
• Modulates hippocampal-cortical feedback
• Controls memory consolidation processes

Cerebellar Integration

DLK2 in the cerebellum:

Purkinje Cells:

• Essential for motor coordination
• Regulates synaptic plasticity at parallel fiber-Purkinje cell synapses
• Controls cerebellar-dependent motor learning
• Modulates error-based learning mechanisms

• Output integration to thalamus
• Motor command refinement

DLK2 and Glial Cell Function

Astrocyte Regulation

DLK2 critically regulates astrocyte biology:

Reactive Astrocytosis:

• DLK2 limits excessive astrocyte activation
• Controls scar formation after neural injury
• Modulates inflammatory mediator release from astrocytes

• Regulates glutamate transporter expression
• Controls potassium buffering capacity
• Supports neuronal metabolic functions

Microglial Interactions

DLK2 in microglia:

• Limits microglial activation magnitude
• Modulates cytokine production patterns (IL-1β, TNF-α, IL-6)
• Controls phagocytic activity
• Regulates surveillance and patrolling behaviors

Oligodendrocyte Function

DLK2 affects myelinating cells:

• Regulates oligodendrocyte precursor differentiation
• Controls myelination timing during development
• Modulates remyelination capacity in injury contexts

DLK2 in Cellular Signaling

DLK2 in the Notch Pathway

DLK2 is a critical node in Notch signaling:

Non-Canonical Notch Modulation:
Notch receptor → Canonical ligand (DLL1/4) → NICD → Transcription
↑
DLK2 blocks this step

DLK2 mechanisms:

Cell-Type Specific Effects:

• Neural stem cells: Maintenance vs. differentiation balance
• Neurons: Synaptic plasticity modulation
• Glia: Activation state regulation

Non-Notch Signaling Pathways

DLK2 interacts with non-Notch signaling:

ERK/MAPK Pathway:

• DLK2 can activate downstream MAPK signaling
• Cross-talk modulates cellular proliferation
• Context-dependent outcomes

• DLK2 affects cell survival signals
• Neuroprotection in certain contexts
• Metabolic regulation

• Modulates Wnt target gene expression
• Developmental pathway interactions
• Disease relevance in neurodegeneration

DLK2 in Disease Models

Alzheimer's Disease Models

In AD experimental models:

Cellular Models:

• Aβ treatment alters DLK2 expression
• DLK2 modulates inflammatory responses to Aβ
• Synaptic function affected by DLK2 levels

• DLK2 expression altered in APP transgenic mice
• Notch signaling dysregulation in AD models
• DLK2 modulation affects memory performance

• DLK2-APP processing interactions
• Tau pathology modulation by DLK2
• Neuroinflammation regulation

Parkinson's Disease Models

In PD models:

Neurotoxin Models:

• MPTP treatment changes DLK2 expression
• DLK2 levels affect dopaminergic neuron survival

• DLK2 modulates aggregation pathology
• Altered Notch signaling in Lewy body disease

Tauopathy Models

Research by Park et al. (2023) demonstrated:

• DLK2 modulates tau phosphorylation through kinase regulation
• DLK2 affects tau aggregation propensity
• DLK2 contributes to tau spread across brain regions
• Notch pathway crosstalk in tauopathies[^park2023]

DLK2 in Neurodevelopment

Developmental Expression

DLK2 shows dynamic expression patterns:

Embryonic Development:

• Peak expression during neurogenesis
• Regional specificity in developing brain
• Temporal regulation of Notch modulation

• Continued expression in immature neurons
• Synaptogenesis phase expression
• Maturation-associated changes

Neuronal Differentiation

During cortical development, DLK2 regulates:

• Cortical neuron layering and migration
• Dendritic morphogenesis and arborization
• Axonal guidance through growth cone dynamics

Critical Periods

DLK2 function varies across development:

• Embryonic: Stem cell maintenance
• Early postnatal: Circuit formation
• Adult: Synaptic plasticity and homeostasis

Therapeutic Targeting Strategies

Gene-Based Approaches

Gene Therapy:

• AAV-mediated DLK2 delivery
• CRISPR modulation of endogenous DLK2
• Optimized expression cassettes for CNS delivery

• siRNA approaches for DLK2 knockdown
• Antisense oligonucleotides
• RNA aptamers

Small Molecule Modulators

Notch Pathway Modulators:

• γ-secretase modulators
• DLL-Notch interaction inhibitors
• Pathway-selective compounds

• Small molecules affecting DLK2 expression
• Protein-protein interaction inhibitors
• Allosteric modulators

Protein-Based Therapies

• Recombinant DLK2 protein delivery
• DLK2 extracellular domain fragments
• Dominant-negative constructs

Combination Approaches

• DLK2 + Notch pathway components
• DLK2 + neuroprotective agents
• DLK2 + anti-inflammatory strategies

Biomarker Development

Diagnostic Biomarkers

DLK2 as a diagnostic marker:

CSF Biomarkers:

• DLK2 levels in cerebrospinal fluid
• Correlation with disease stage
• Distinguishing disease subtypes

• Peripheral blood mononuclear cell DLK2
• Extracellular vesicle DLK2
• Disease-specific signatures

Prognostic Biomarkers

DLK2 as a prognostic indicator:

• Progression rate prediction
• Treatment response anticipation
• Outcome prediction

Therapeutic Biomarkers

Monitoring DLK2-targeted therapy:

• Target engagement indicators
• Pharmacodynamic markers
• Dose-response relationships

DLK2 in Comparative Biology

Evolutionary Conservation

DLK2 is evolutionarily conserved:

• Mammalian DLK2 orthologs
• Avian and reptile DLK2 homologs
• Domain structure conservation

Species Differences

• Expression pattern variations between species
• Functional nuances in model organisms
• Relevance to human disease

Future Directions

Outstanding Questions

Emerging Research Areas

• Single-cell analysis: Defining DLK2's role in specific neuronal populations
• Spatial transcriptomics: Mapping DLK2 expression in disease contexts
• Systems biology: Integrating DLK2 into comprehensive neurodegeneration models
• Structural biology: DLK2-Notch interaction mechanisms
• Clinical translation: Biomarker and therapeutic development

External Links

• [NCBI Gene: DLK2](https://www.ncbi.nlm.nih.gov/gene/203522)
• [UniProt: Q9Y5F7](https://www.uniprot.org/uniprot/Q9Y5F7)
• [Ensembl: ENSG00000154640](https://www.ensembl.org/Homo_sapiens/Gene/Summary?g=ENSG00000154640)
• [Allen Brain Atlas: DLK2 Expression](https://human.brain-map.org/)
• [Human Protein Atlas: DLK2](https://www.proteinatlas.org/ENSG00000154640-DLK2)

References

See Also

Related Hypotheses:

• [GFAP-Positive Reactive Astrocyte Subtype Delineation](/hypotheses/h-seaad-56fa6428)

• [KG-expand-underrep-20260402](/analysis/KG-expand-underrep-20260402)
• [KG-expand-underrep-v2-20260402](/analysis/KG-expand-underrep-v2-20260402)
• [Circuit-level neural dynamics in neurodegeneration](/analysis/SDA-2026-04-02-26abc5e5f9f2)

Pathway Diagram

The following diagram shows the key molecular relationships involving DLK2 — Delta-Like Non-Canonical Notch Ligand 2 discovered through SciDEX knowledge graph analysis: