¶ DLK2 — Delta-Like Non-Canonical Notch Ligand 2
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. DLK2 plays critical roles in embryonic development, tissue homeostasis, stem cell maintenance, and has emerging roles in neurodevelopment and neurodegenerative diseases [1].
|
|
| Gene Symbol |
DLK2 |
| Full Name |
Delta-Like Non-Canonical Notch Ligand 2 |
| Chromosome |
6p25.1 |
| NCBI Gene ID |
203522 |
| OMIM |
612651 |
| Ensembl ID |
ENSG00000154640 |
| UniProt ID |
Q9Y5F7 |
| Associated Diseases |
Alzheimer's Disease, Parkinson's Disease, Neuroinflammation, Cancer |
¶ 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
Unlike canonical Notch ligands, DLK2's extracellular domain lacks the characteristic DSL (Delta-Serrate-Lag-2) domain required for high-affinity Notch receptor binding. This structural difference underlies DLK2's non-canonical signaling properties, enabling it to function as both a Notch modulator and a receptor-independent signaling molecule [2].
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
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
Expression analysis from the Allen Brain Atlas and Human Protein Atlas confirms widespread neural expression, with altered patterns observed in neurodegenerative disease states [3].
¶ Molecular Functions and Signaling Pathways
DLK2 modulates Notch signaling through multiple mechanisms:
- Ligand-independent inhibition: The intracellular domain can bind and sequester Notch intracellular domain (NICD), preventing its nuclear translocation and transcriptional activity
- Receptor degradation: DLK2 promotes ubiquitination and degradation of Notch receptors through recruitment of E3 ubiquitin ligases
- Competitive inhibition: By occupying Notch receptors without activating them, DLK2 prevents binding of canonical ligands
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].
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
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
¶ 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
Studies by Liu et al. (2020) demonstrated that DLK2 knockdown in NSCs leads to accelerated neuronal differentiation and depleted stem cell pools, highlighting its essential role in maintaining the neurogenic niche [5].
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
Research by Zhao et al. (2021) demonstrated that DLK2 deficiency in hippocampal neurons leads to impaired memory formation and reduced synaptic plasticity, providing direct evidence for DLK2's role in cognitive function [6].
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
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
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
Research by Wang et al. (2021) demonstrated that DLK2 expression is significantly altered in AD brains and that modulating DLK2 can affect neuroinflammatory marker expression in cellular models [7].
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
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
Kim et al. (2023) performed comprehensive analysis of DLK2 in human AD brains, confirming dysregulation and identifying potential diagnostic relevance [8].
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
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
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
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
Several strategies are being explored:
- Small molecule modulators: Compounds that enhance or inhibit DLK2 function
- Antibody-based therapy: Monoclonal antibodies targeting DLK2 extracellular domain
- Gene therapy: Viral vector delivery of DLK2 or DLK2 modulators
- Cell therapy: Stem cell-based approaches with DLK2 modulation
¶ 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
- Knockout mice: Complete and conditional DLK2 deletion models
- Transgenic models: Overexpression and mutant DLK2 lines
- Conditional knockouts: Cell-type specific ablation
- Co-immunoprecipitation: Protein interaction studies
- Luciferase assays: Reporter gene analysis for Notch activity
- Proteomics: Global interaction mapping
- Confocal microscopy: Subcellular localization studies
- Electron microscopy: Ultrastructural analysis of synapses
- Live cell imaging: Dynamic trafficking studies
¶ Animal Models and Phenotypes
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
Neuron-specific deletion reveals:
- Memory deficits: Impaired hippocampal-dependent learning
- Synaptic abnormalities: Reduced spine density and function
- Altered neurogenesis: Changes in adult hippocampal neurogenesis
Neuronal overexpression produces:
- Enhanced Notch signaling: Increased NICD nuclear localization
- Neurogenesis effects: Altered stem cell dynamics
- Behavioral changes: Multiple cognitive modifications
DLK2 as a biomarker:
- CSF detection: Measurable in cerebrospinal fluid
- Peripheral markers: Potential blood-based indicators
- Imaging correlates: PET ligand development opportunities
DLK2 levels may serve to:
- Track progression: Correlation with disease stage
- Therapeutic monitoring: Response to disease-modifying treatments
- Prognostic value: Predictive potential for outcomes
- NOTCH1 — Canonical Notch receptor
- NOTCH3 — Alzheimer's-associated Notch isoform
- DLL1 — Canonical Notch ligand
- PSEN1 — γ-Secretase component
- APP — Amyloid precursor protein
¶ DLK2 in Autophagy and Protein Clearance
DLK2 plays important roles in autophagy:
- mTORC1 interaction: DLK2 modulates mTORC1 activity
- ULK1 complex regulation: Affects initiation of autophagy
- VPS34 complex: Modulates class III PI3K activity
- Aggregate clearance: DLK2 affects removal of toxic proteins
- Synaptic homeostasis: Autophagy maintains synaptic proteostasis
- Disease relevance: Impaired autophagy in AD and PD
- Cathepsin activity: DLK2 influences lysosomal protease function
- Autolysosome formation: Fusion process modulation
- Neuronal vulnerability: Effects on long-lived neurons
DLK2 modulates microglial phenotype:
- M1 polarization: DLK2 affects classical activation
- Cytokine production: Modulates TNF-α, IL-1β, IL-6
- Nitric oxide generation: Impacts oxidative stress
- M2 polarization: DLK2 influences anti-inflammatory state
- Neurotrophic support: BDNF and other factor production
- Tissue repair: Promotes healing responses
- Chemokine regulation: Controls inflammatory cell recruitment
- NF-κB signaling: Affects master inflammatory pathway
- Therapeutic implications: Targeting DLK2 for anti-inflammatory effects
¶ 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
- Phosphorylation: Kinase-mediated regulation (PKC, CK2)
- Ubiquitination: Degradation control and turnover
- Glycosylation: Secretory pathway processing and function
- Synaptic function: DLK2 implicated in ASD pathogenesis
- Social behavior: Mouse model studies show alterations
- Comorbid conditions: Epilepsy and intellectual disability overlap
- Notch pathway links: Schizophrenia genetics implicate Notch
- Synaptic pruning: Developmental mechanisms affected
- Therapeutic implications: Potential intervention points
¶ DLK2 in Aging and Cellular Senescence
- Senescence-associated secretory phenotype: DLK2 modulation effects
- Inflammaging: Chronic inflammation in aging brain
- Cell cycle regulation: Interactions with senescence pathways
- Expression decline: DLK2 levels decrease with aging
- Notch dysregulation: Age-related pathway changes
- Neurodegeneration risk: Cumulative effects over time
- Neuronal cultures: Primary neuron studies reveal functions
- Stem cell differentiation: Neural lineage commitment roles
- Organoid systems: Brain organoid modeling of disease
- Knockout mice: Phenotype characterization available
- Transgenic models: Disease-relevant mutations being developed
- Pharmacological studies: Drug testing platforms in use
- 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
- DLK2 overexpression: Neuroprotective approaches under study
- RNAi knockdown: Reduce DLK2 when detrimental
- CRISPR editing: Precise genetic manipulation possible
- Multi-target approaches: Address multiple pathways simultaneously
- Synergistic effects: Enhanced therapeutic benefit possible
- Reduced toxicity: Lower doses of each component feasible
- CSF DLK2 levels: May correlate with disease stage
- Blood-based markers: Peripheral measurement possible
- Imaging correlates: PET ligand development opportunities
- Progression tracking: Longitudinal measurements useful
- Therapeutic response: Can monitor treatment efficacy
- Prognostic value: May predict outcomes
¶ Outstanding Questions
- What are the precise molecular mechanisms of DLK2's neuroprotective effects?
- How does DLK2 specifically modulate amyloid and tau pathology?
- Can DLK2 be targeted therapeutically without disrupting normal Notch function?
- What are the optimal strategies for CNS delivery of DLK2 modulators?
- 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
- Nuutila K, et al. DLK2 in development and disease. Dev Biol (2012)
- Schmidt M, et al. DLK2 regulates hematopoietic stem cell differentiation. Nat Immunol (2013)
- Chen L, et al. DLK2 in Notch signaling and neurogenesis. J Neurosci (2017)
- Zhang H, et al. DLK2 suppresses Notch signaling through degradation of Notch intracellular domain. Cell Death Differ (2019)
- Liu J, et al. DLK2 in neural stem cell fate determination. Stem Cell Reports (2020)
- Zhao Y, et al. DLK2 regulates synaptic plasticity and memory formation. Nat Neurosci (2021)
- Wang X, et al. DLK2 modulates neuroinflammation in Alzheimer's disease. Front Aging Neurosci (2021)
- Park S, et al. DLK2 and Notch pathway crosstalk in tauopathies. Acta Neuropathol Commun (2023)
- Kim J, et al. DLK2 expression in human brain and its alteration in AD. J Neuropathol Exp Neurol (2023)
- Kumar V, et al. DLK2 in neurodegeneration: molecular mechanisms. Prog Neurobiol (2022)
- DLK2 in autophagy and protein clearance mechanisms (2024)
- DLK2 microglial polarization and neuroinflammation modulation (2024)
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
Dentate Gyrus:
- DLK2 in granule cells controls neurogenesis
- Modulates pattern separation capacity
- Affects adult hippocampal plasticity
- Contributes to cognitive flexibility
Research by Zhao et al. (2021) demonstrated that DLK2 knockout specifically in hippocampal neurons leads to impaired long-term potentiation and deficits in spatial memory tasks, demonstrating the critical role of DLK2 in hippocampal-dependent learning[^zhao2021].
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
Cortico-Hippocampal Interactions:
- Regulates entorhinal cortex inputs
- Modulates hippocampal-cortical feedback
- Controls memory consolidation processes
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
Cerebellar Nuclei:
- Output integration to thalamus
- Motor command refinement
¶ DLK2 and Glial Cell Function
DLK2 critically regulates astrocyte biology:
Reactive Astrocytosis:
- DLK2 limits excessive astrocyte activation
- Controls scar formation after neural injury
- Modulates inflammatory mediator release from astrocytes
Astrocytic Support Functions:
- Regulates glutamate transporter expression
- Controls potassium buffering capacity
- Supports neuronal metabolic functions
Research by Wang et al. (2021) demonstrated that astrocytic DLK2 modulates neuroinflammatory responses in Alzheimer's disease models, with altered DLK2 expression correlating with disease progression[^wang2021].
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
DLK2 affects myelinating cells:
- Regulates oligodendrocyte precursor differentiation
- Controls myelination timing during development
- Modulates remyelination capacity in injury contexts
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:
1. Intracellular domain binding and sequestration
2. Receptor ubiquitination and degradation
3. Competitive inhibition of canonical ligands
4. γ-secretase activity modulation
Cell-Type Specific Effects:
- Neural stem cells: Maintenance vs. differentiation balance
- Neurons: Synaptic plasticity modulation
- Glia: Activation state regulation
DLK2 interacts with non-Notch signaling:
ERK/MAPK Pathway:
- DLK2 can activate downstream MAPK signaling
- Cross-talk modulates cellular proliferation
- Context-dependent outcomes
PI3K/Akt Pathway:
- DLK2 affects cell survival signals
- Neuroprotection in certain contexts
- Metabolic regulation
Wnt/β-catenin Crosstalk:
- Modulates Wnt target gene expression
- Developmental pathway interactions
- Disease relevance in neurodegeneration
In AD experimental models:
Cellular Models:
- Aβ treatment alters DLK2 expression
- DLK2 modulates inflammatory responses to Aβ
- Synaptic function affected by DLK2 levels
Animal Models:
- DLK2 expression altered in APP transgenic mice
- Notch signaling dysregulation in AD models
- DLK2 modulation affects memory performance
Mechanistic Studies:
- DLK2-APP processing interactions
- Tau pathology modulation by DLK2
- Neuroinflammation regulation
In PD models:
Neurotoxin Models:
- MPTP treatment changes DLK2 expression
- DLK2 levels affect dopaminergic neuron survival
α-Synuclein Models:
- DLK2 modulates aggregation pathology
- Altered Notch signaling in Lewy body disease
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 shows dynamic expression patterns:
Embryonic Development:
- Peak expression during neurogenesis
- Regional specificity in developing brain
- Temporal regulation of Notch modulation
Postnatal Development:
- Continued expression in immature neurons
- Synaptogenesis phase expression
- Maturation-associated changes
During cortical development, DLK2 regulates:
- Cortical neuron layering and migration
- Dendritic morphogenesis and arborization
- Axonal guidance through growth cone dynamics
DLK2 function varies across development:
- Embryonic: Stem cell maintenance
- Early postnatal: Circuit formation
- Adult: Synaptic plasticity and homeostasis
Gene Therapy:
- AAV-mediated DLK2 delivery
- CRISPR modulation of endogenous DLK2
- Optimized expression cassettes for CNS delivery
Antisense Strategies:
- siRNA approaches for DLK2 knockdown
- Antisense oligonucleotides
- RNA aptamers
Notch Pathway Modulators:
- γ-secretase modulators
- DLL-Notch interaction inhibitors
- Pathway-selective compounds
DLK2-Targeting Compounds:
- Small molecules affecting DLK2 expression
- Protein-protein interaction inhibitors
- Allosteric modulators
- Recombinant DLK2 protein delivery
- DLK2 extracellular domain fragments
- Dominant-negative constructs
- DLK2 + Notch pathway components
- DLK2 + neuroprotective agents
- DLK2 + anti-inflammatory strategies
DLK2 as a diagnostic marker:
CSF Biomarkers:
- DLK2 levels in cerebrospinal fluid
- Correlation with disease stage
- Distinguishing disease subtypes
Blood Biomarkers:
- Peripheral blood mononuclear cell DLK2
- Extracellular vesicle DLK2
- Disease-specific signatures
DLK2 as a prognostic indicator:
- Progression rate prediction
- Treatment response anticipation
- Outcome prediction
Monitoring DLK2-targeted therapy:
- Target engagement indicators
- Pharmacodynamic markers
- Dose-response relationships
DLK2 is evolutionarily conserved:
- Mammalian DLK2 orthologs
- Avian and reptile DLK2 homologs
- Domain structure conservation
- Expression pattern variations between species
- Functional nuances in model organisms
- Relevance to human disease
¶ Outstanding Questions
- What are the precise molecular mechanisms of DLK2's neuroprotective effects?
- How does DLK2 specifically modulate amyloid and tau pathology?
- Can DLK2 be targeted therapeutically without disrupting normal Notch function?
- What are the optimal strategies for CNS delivery of DLK2 modulators?
- How does DLK2 interact with other neurodegenerative disease mechanisms?
- 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
- Nuutila K, et al. DLK2 in development. Dev Biol (2012)
- Schmidt M, et al. DLK2 regulates hematopoietic stem cell differentiation. Nat Immunol (2013)
- Chen L, et al. DLK2 in Notch signaling and neurogenesis. J Neurosci (2017)
- Zhang H, et al. DLK2 suppresses Notch signaling. Cell Death Differ (2019)
- Liu J, et al. DLK2 in neural stem cell fate determination. Stem Cell Reports (2020)
- Zhao Y, et al. DLK2 regulates synaptic plasticity and memory. Nat Neurosci (2021)
- Wang X, et al. DLK2 modulates neuroinflammation in AD. Front Aging Neurosci (2021)
- Park S, et al. DLK2 and Notch pathway crosstalk in tauopathies. Acta Neuropathol Commun (2023)
- Kim J, et al. DLK2 expression in human brain and AD. J Neuropathol Exp Neurol (2023)
- Kumar V, et al. DLK2 in neurodegeneration. Prog Neurobiol (2022)
- Sanchez-Perez AM, et al. DLK2 and neural development. Dev Neurobiol. 2020;80(5):234-248
- Ferrer-Martin RM, et al. DLK2 in brain aging. Aging Cell. 2021;20(4):e13345
- Tanaka M, et al. Notch-DLK2 interactions in neurogenesis. Stem Cells. 2022;40(2):156-168
- Martinez-Lopez M, et al. DLK2 and cognitive function. J Neurosci. 2023;43(8):1345-1358
- Cheng H, et al. DLK2:From development to disease. Cell Mol Neurobiol. 2023;43(5):1823-1840
- DLK2 in autophagy and protein clearance mechanisms (2024)
- DLK2 microglial polarization and neuroinflammation modulation (2024)