Overview
<table class="infobox infobox-gene">
<tr>
<th class="infobox-header" colspan="2">LRP1B — Low Density Lipoprotein Receptor-Related Protein 1B</th>
</tr>
<tr>
<td class="label">Feature</td>
<td>LRP1B</td>
</tr>
<tr>
<td class="label">Amino acids</td>
<td>4,595</td>
</tr>
<tr>
<td class="label">Ligand-binding clusters</td>
<td>5 (31 repeats)</td>
</tr>
<tr>
<td class="label">Brain expression</td>
<td>Higher in cortex/hippocampus</td>
</tr>
<tr>
<td class="label">Tissue distribution</td>
<td>Primarily brain, some lung/kidney</td>
</tr>
<tr>
<td class="label">Cancer frequency</td>
<td>Frequently deleted</td>
</tr>
<tr>
<td class="label">Variant Type</td>
<td>Phenotype</td>
</tr>
<tr>
<td class="label">Rare missense</td>
<td>Possible AD risk</td>
</tr>
<tr>
<td class="label">Common SNPs</td>
<td>Modest AD association</td>
</tr>
<tr>
<td class="label">Copy number loss</td>
<td>Cancer risk</td>
</tr>
<tr>
<td class="label">Associated Diseases</td>
<td><a href="/wiki/als" style="color:#ef9a9a">ALS</a>, <a href="/wiki/aging" style="color:#ef9a9a">Aging</a>, <a href="/wiki/als" style="color:#ef9a9a">Als</a>, <a href="/wiki/atherosclerosis" style="color:#ef9a9a">Atherosclerosis</a>, <a href="/wiki/cancer" style="color:#ef9a9a">Cancer</a></td>
</tr>
<tr>
<td class="label">KG Connections</td>
<td><a href="/atlas" style="color:#4fc3f7">59 edges</a></td>
</tr>
</table>
LRP1B (Low Density Lipoprotein Receptor-Related Protein 1B) is a member of the LDLR family that functions as a cell surface scavenger receptor involved in lipoprotein metabolism, protein homeostasis, and cellular signaling. Initially identified as a candidate tumor suppressor due to its frequent deletion in various cancers, LRP1B has garnered significant attention in neuroscience for its potential role in Alzheimer's disease and other neurodegenerative conditions[@liu2001].
LRP1B is highly expressed in the brain, particularly in the cerebral cortex, hippocampus, and cerebellum, where it participates in the clearance of amyloid-beta (Aβ), the trafficking of lipids and apolipoproteins, and the regulation of synaptic function. The protein shares structural similarity with LRP1 but exhibits distinct expression patterns and ligand-binding properties that may confer unique functions in neuronal homeostasis[@may2003].
Gene and Protein Structure
Gene Organization
The LRP1B gene is located on chromosome 2q22.1 and consists of 92 exons spanning approximately 190 kb of genomic DNA. The gene encodes a large transmembrane protein of 4,595 amino acids with a molecular weight of approximately 500 kDa, making it one of the largest cell surface receptors.
Protein Architecture
LRP1B contains several distinct structural domains:
- Ligand-binding repeats (amino acids 1-1,500): 31 complement-type repeat sequences arranged in five ligand-binding clusters (Ligand-binding clusters I-V), each capable of binding distinct ligands. These repeats are separated by spacer regions containing epidermal growth factor (EGF)-like repeats.
- EGF precursor homology domain (amino acids 1,500-2,000): Contains EGF-like repeats and β-propeller domains that mediate ligand release at low pH, a critical step in receptor recycling.
- Transmembrane domain (amino acids 2,100-2,150): Single-pass transmembrane helix that anchors the receptor in the plasma membrane.
- Cytoplasmic tail (amino acids 2,150-4,595): Contains multiple NPXY motifs that mediate clathrin-mediated endocytosis through interaction with adaptor proteins like disabled-2 (DAB2) and ARH (autosomal recessive hypercholesterolemia protein).
Comparison with LRP1
While LRP1B shares significant homology with LRP1, key differences include:
Cellular Functions
Lipoprotein and Ligand Endocytosis
LRP1B functions as a scavenger receptor that mediates the endocytosis of numerous ligands:
Apolipoprotein E (apoE): LRP1B binds apoE-containing lipoproteins, particularly those synthesized in the brain by astrocytes and microglia. This interaction is critical for lipid delivery to neurons and for Aβ clearance.
Alpha-2-macroglobulin (α2M): A broad-spectrum proteinase inhibitor that also binds various growth factors and cytokines. LRP1B-mediated α2M uptake contributes to extracellular matrix remodeling.
Matrix metalloproteinases (MMPs) and TIMPs: LRP1B regulates the extracellular balance of MMPs and their inhibitors, affecting tissue remodeling and neuroinflammation.
Lactadherin/MFG-E8: Involved in the clearance of apoptotic cells and cellular debris.Amyloid-Beta Clearance
One of the most significant functions of LRP1B in the brain is its role in Aβ clearance:
- Receptor-mediated clearance: LRP1B directly binds Aβ and mediates its internalization and degradation
- Synergy with LRP1: LRP1B may compensate for or cooperate with LRP1 in Aβ clearance
- ApoE-Aβ complex clearance: LRP1B efficiently clears Aβ bound to apoE lipoproteins
- Blood-brain barrier transport: May contribute to Aβ efflux from the brain
The efficiency of LRP1B-mediated Aβ clearance may influence amyloid plaque burden and disease progression in Alzheimer's disease[@vangool2019].
Synaptic Function and Plasticity
LRP1B is enriched at synapses and participates in:
- Synaptic vesicle organization: Regulates the distribution of synaptic vesicle proteins
- Long-term potentiation (LTP): Required for activity-dependent synaptic strengthening
- Memory consolidation: LRP1B deficiency impairs memory formation in mouse models
- Dendritic spine morphology: Controls spine density and shape
These functions suggest that LRP1B may be important for cognitive function beyond its role in Aβ clearance[@chen2020].
Role in Alzheimer's Disease
Genetic Evidence
Genetic studies have implicated LRP1B in Alzheimer's disease risk:
- Rare variants: Missense variants in LRP1B have been identified in AD patients, though their pathogenicity remains uncertain
- Expression quantitative trait loci (eQTLs): LRP1B expression quantitative trait loci may influence AD risk
- Copy number variants: Deletions spanning LRP1B have been reported in some AD cases
- Genome-wide studies: LRP1B shows suggestive associations in large AD GWAS datasets
The evidence for LRP1B as a strong AD risk gene is less robust than for APOE or LRP1, but functional studies support a role in disease pathogenesis[@ji2019].
Pathogenic Mechanisms
LRP1B may contribute to AD through several mechanisms:
Reduced Aβ clearance: Impaired LRP1B function leads to decreased Aβ clearance and increased amyloid burden
Altered lipid metabolism: Dysregulated lipid homeostasis affects neuronal health and membrane function
Synaptic dysfunction: LRP1B deficiency contributes to synaptic loss and cognitive decline
Neuroinflammation: Altered signaling may affect microglial activation and inflammatory responsesInteraction with Other AD Genes
LRP1B intersects with multiple Alzheimer's disease pathways:
- APOE: LRP1B binds apoE lipoproteins and may interact differently with apoE isoforms (ε2, ε3, ε4)
- LRP1: May have overlapping and distinct functions in Aβ clearance
- TREM2: Microglial expression of LRP1B may affect Aβ uptake by microglia
- CLU/Clusterin: Works with clusterin in Aβ clearance pathway
Role in Parkinson's Disease
While primarily studied in AD, LRP1B has some relevance to Parkinson's disease:
- α-Synuclein clearance: May contribute to the clearance of α-synuclein aggregates
- Lipid homeostasis: Altered lipid metabolism may affect membrane integrity in dopaminergic neurons
- Neuroinflammation: May modulate microglial responses to neurodegeneration
The role of LRP1B in PD is less well-characterized than in AD and warrants further investigation.
Neuroanatomical Expression
Brain Expression Pattern
LRP1B shows characteristic expression in key brain regions:
- Cerebral cortex: Highest expression in layer 5 pyramidal neurons
- Hippocampus: Strong expression in CA1 and CA3 pyramidal neurons, dentate gyrus granule cells
- Cerebellum: Purkinje cells show robust expression
- Basal ganglia: Moderate expression in striatal medium spiny neurons
- Substantia nigra: Lower expression in dopaminergic neurons compared to cortex
The cortical and hippocampal expression patterns correlate with regions vulnerable in AD.
Cell-Type Expression
Within the brain, LRP1B is expressed in:
- Neurons: Both excitatory and inhibitory neurons express LRP1B
- Astrocytes: Some astrocyte populations express LRP1B
- Microglia: Low-level expression in microglia
- Endothelial cells: LRP1B expressed at the blood-brain barrier
Cancer Biology
Tumor Suppressor Function
LRP1B is frequently deleted or downregulated in cancers:
- Lung cancer: Homozygous deletions and loss of expression in 30-40% of cases
- Breast cancer: Deletions in 20-30% of tumors
- Colorectal cancer: Frequent deletions and mutations
- Endometrial cancer: High frequency of LRP1B alterations
The tumor suppressor function involves:
- Reduced proliferation when LRP1B is re-expressed
- Inhibition of anchorage-independent growth
- Reduced invasion and metastasis
- Cell cycle arrest
Mechanism in Cancer
LRP1B acts as a tumor suppressor through:
Cell surface receptor signaling: Alters growth factor signaling
Endocytosis of oncoproteins: May increase clearance of growth-promoting ligands
Transcriptional regulation: Cytoplasmic domain may have signaling functionsResearch Models
Cellular Models
- Neuronal cell lines: SH-SY5Y, PC12 cells for overexpression/knockdown
- Primary neurons: Mouse cortical neurons for functional studies
- iPSC-derived neurons: Human neurons for disease modeling
- Astrocytes: Primary astrocyte cultures for glia-neuron interactions
Animal Models
- Lrp1b knockout mice: Show embryonic lethality or severe phenotypes
- Conditional knockouts: Brain-specific deletion for neuroscience studies
- Transgenic mice: Express mutant LRP1B variants
- AAV-mediated knockdown: Acute loss-of-function in adult brain
Findings from models:
- Complete LRP1B loss is not viable
- Conditional deletion causes synaptic deficits
- Aβ accumulation in some models
- Memory impairment
Therapeutic Implications
Therapeutic Targets
LRP1B represents a potential therapeutic target for:
Alzheimer's disease: Enhance Aβ clearance through LRP1B activation
Cognitive decline: Modulate synaptic plasticity
Cancer: Reactivate LRP1B expression in tumorsTherapeutic Strategies
- Agonist antibodies: Develop antibodies that enhance LRP1B function
- Small molecule activators: Identify brain-penetrant compounds that increase LRP1B activity
- Gene therapy: AAV-mediated LRP1B delivery to brain
- Protein replacement: Deliver soluble LRP1B extracellular domain
Challenges
- Blood-brain barrier: Therapeutic agents must cross to reach neurons
- Specificity: Avoiding off-target effects on related receptors
- Complex regulation: LRP1B function is context-dependent
Signal Transduction Pathways
Intracellular Signaling
LRP1B activates multiple intracellular signaling cascades:
MAPK/ERK pathway: LRP1B activation can trigger Ras-Raf-MEK-ERK signaling, affecting cell proliferation and differentiation
PI3K/Akt pathway: Phosphoinositide 3-kinase signaling promotes cell survival
p38 MAPK pathway: Stress-activated signaling that can lead to inflammatory responses
Wnt/β-catenin pathway: Some evidence suggests LRP1B may modulate Wnt signalingAdaptor Protein Interactions
The cytoplasmic tail of LRP1B recruits multiple adaptor proteins:
- DAB2: Links LRP1B to endocytosis machinery
- ARH: Another clathrin adaptor that recognizes NPXY motifs
- FE65: Binds to the cytoplasmic domain and may link to transcriptional regulation
- JIP proteins: Scaffold proteins for MAPK pathways
- PSD-95: At synapses, links LRP1B to postsynaptic density
Cross-talk with Other Receptors
LRP1B does not function in isolation but interacts with:
- NMDA receptors: May influence glutamatergic signaling
- TGF-β receptors: Coordinate extracellular matrix remodeling
- Insulin receptor: Cross-talk in lipid metabolism
- Notch receptors: Potential interaction in development
Lipid Biology
LRP1B plays a role in brain cholesterol homeostasis:
- Lipoprotein uptake: Clears cholesterol-containing lipoproteins from brain interstitial fluid
- Astrocyte-neuron lipid transfer: Facilitates lipid delivery from astrocytes to neurons
- Myelin maintenance: Lipid supply for myelin sheath integrity
- Synaptic membrane turnover: Provides lipids for synaptic vesicle and membrane recycling
Apolipoprotein E Interaction
The interaction with apoE is particularly important:
- ApoE isoform-dependent binding: LRP1B may show differential binding to apoE isoforms (ε2, ε3, ε4)
- Aβ-ApoE complex clearance: Efficiently clears Aβ bound to apoE lipoproteins
- Lipid delivery: Supplies cholesterol and phospholipids via apoE-containing particles
- Neuroprotection: ApoE-LRP1B signaling may have neuroprotective effects
Genetic Epidemiology
Population Genetics
- Common variants: Single nucleotide polymorphisms (SNPs) in LRP1B show modest associations with AD risk
- Rare variants: Exome sequencing has identified rare missense variants with uncertain pathogenicity
- Copy number variants: Deletions involving LRP1B are more common in cancer than in neurodegeneration
Genotype-Phenotype Correlations
Comparative Biology
Evolutionary Conservation
LRP1B is conserved across vertebrates:
- Mammals: Highly conserved sequence and expression pattern
- Birds: Orthologous gene with similar domain structure
- Fish: Zebrafish ortholog expressed in brain
- Invertebrates: No clear ortholog in Drosophila or C. elegans
The ligand-binding repeat architecture is conserved, suggesting conserved ligand interactions.
Clinical Relevance
Biomarkers
LRP1B as a potential biomarker:
- CSF LRP1B: Levels may change in AD
- Blood LRP1B: Peripheral monocyte expression may correlate with brain pathology
- Imaging: PET ligands for LRP1B expression under development
Diagnostic Applications
- Genetic testing: LRP1B sequencing included in some AD gene panels
- Protein measurement: ELISA assays for LRP1B in tissue and fluids
- Functional assays: Ligand-binding capacity as functional readout
Future Directions
Unresolved Questions
Key questions remain about LRP1B:
Precise physiological ligands: Complete ligand repertoire in brain
Aβ clearance mechanism: Relative contribution compared to LRP1
Synaptic function: Molecular mechanisms in LTP and memory
Therapeutic targeting: Optimal approach for enhancementResearch Priorities
- Structural studies: Cryo-EM of LRP1B-ligand complexes
- Single-cell analysis: Neuron-type specific functions
- Model development: Better animal models
- Therapeutic screening: High-throughput screening for activators
Neuroinflammation and LRP1B
Microglial LRP1B
Microglial cells express LRP1B and participate in brain immune responses:
- Aβ phagocytosis: Microglial LRP1B contributes to Aβ clearance
- Cytokine signaling: LRP1B modulates inflammatory cytokine production
- T cell interaction: May present antigens and regulate adaptive immunity
- Neuroprotection: Can promote anti-inflammatory phenotypes
Inflammatory Modulation
LRP1B influences neuroinflammation through:
TNF-α signaling: Modulates tumor necrosis factor signaling
IL-1β regulation: Affects interleukin-1 beta production
TGF-β activity: Coordinates with transforming growth factor signaling
Complement activation: May influence complement systemMembrane Biology
Synaptic Membrane Dynamics
LRP1B plays a crucial role in synaptic membrane homeostasis:
- Endocytic recycling: Maintains synaptic vesicle membrane pool
- Receptor trafficking: Regulates neurotransmitter receptor density
- Lipid rafts: Influences membrane microdomain organization
- Membrane protein quality control: Clears damaged membrane proteins
Membrane Trafficking
LRP1B coordinates several trafficking pathways:
Mermaid diagram (expand to render)
The trafficking pathway determines whether ligands are recycled or degraded.
Cellular Stress Responses
Oxidative Stress
LRP1B function is affected by oxidative stress:
- Receptor downregulation: Oxidative stress reduces LRP1B surface expression
- Ligand binding changes: Oxidative modification of ligands affects clearance
- Signal modulation: Oxidative stress shifts downstream signaling
- Protective function: LRP1B may help clear oxidized proteins
Endoplasmic Reticulum Stress
LRP1B interacts with the unfolded protein response:
- Quality control: Helps clear misfolded proteins from membrane
- ERAD pathway: Participates in ER-associated degradation
- Stress signaling: Activates stress-responsive pathways
- Cell survival: May promote survival under stress
Therapeutic Development Pipeline
Preclinical Stage
Current preclinical efforts include:
Antibody development: Anti-LRP1B agonist antibodies in early testing
Small molecule screening: Cell-based screens for LRP1B activators
Gene therapy vectors: AAV constructs with LRP1B transgene
Peptide agonists: Short peptides that activate LRP1BChallenges to Clinical Translation
Major hurdles remain:
- Blood-brain barrier penetration: Essential for brain delivery
- Optimal modulation level: Both insufficient and excessive activation may be harmful
- Long-term effects: Unknown consequences of chronic LRP1B modulation
- Biomarker development: Need to verify target engagement
Conclusion
LRP1B represents an important link between lipid metabolism, amyloid clearance, and synaptic function in the brain. While not as well-characterized as its paralog LRP1, growing evidence supports a role in Alzheimer's disease pathogenesis and potentially in other neurodegenerative conditions.
Key points:
LRP1B is a large scavenger receptor with multiple ligand-binding domains
Brain expression is highest in cortex and hippocampus
Contributes to Aβ clearance and synaptic plasticity
Genetic variants may modify AD risk
Therapeutic targeting is challenging but promisingFuture research should focus on understanding LRP1B's precise functions in different neuronal cell types and developing effective therapeutic approaches.
Emerging Research Directions
LRP1B in Blood-Brain Barrier Function
Recent studies have revealed that LRP1B plays a critical role in maintaining blood-brain barrier (BBB) integrity. The receptor is expressed on brain endothelial cells where it participates in bidirectional transport between the circulating blood and the brain parenchyma[@yamazaki2019]. This function is particularly important for:
- Aβ efflux: LRP1B-mediated transport facilitates the clearance of Aβ from the brain into the bloodstream, complementing other clearance pathways
- Lipoprotein transport: The receptor regulates the passage of apolipoprotein-containing lipoproteins across the BBB
- Immune cell trafficking: LRP1B modulates the movement of immune cells across the barrier during neuroinflammation
Dysfunction of endothelial LRP1B may contribute to BBB breakdown in Alzheimer's disease, allowing harmful substances to enter the brain while impairing the removal of toxic metabolites[@ortiz2023].
LRP1B and Neurovascular Unit
The neurovascular unit (NVU) comprises endothelial cells, pericytes, astrocytes, and neurons that work together to maintain cerebral blood flow and BBB function. LRP1B interacts with multiple components of the NVU:
- Pericyte function: LRP1B on pericytes regulates their recruitment and maintenance
- Astrocyte end-feet: The receptor is expressed at astrocytic end-feet surrounding blood vessels
- Neuronal-vascular coupling: LRP1B-mediated signaling may influence neurovascular coupling mechanisms
These interactions suggest that LRP1B dysfunction could contribute to the neurovascular impairment observed in AD patients[@schmidt2020].
Alternative splicing generates multiple LRP1B isoforms with distinct properties:
- Soluble LRP1B (sLRP1B): A truncated isoform lacking the transmembrane domain, detectable in cerebrospinal fluid
- Tissue-specific isoforms: Different brain regions show varying isoform expression patterns
- Disease-associated variants: Certain splice variants have been associated with AD risk
Measuring sLRP1B in CSF may serve as a biomarker for neurodegenerative diseases, as levels correlate with disease progression[@yamazaki2019].
Epigenetic Regulation of LRP1B
LRP1B expression is subject to epigenetic control:
- DNA methylation: Promoter methylation can silence LRP1B expression in certain contexts
- Histone modifications: Chromatin state influences LRP1B transcription
- Non-coding RNAs: MicroRNAs can target LRP1B mRNA for degradation
Understanding epigenetic regulation may reveal new therapeutic approaches for modulating LRP1B expression[@liu2022].
LRP1B in Glial Cells
Beyond neurons, LRP1B is expressed in glial cells where it serves important functions:
- Astrocytes: LRP1B mediates astrocytic uptake of Aβ and lipoproteins
- Microglia: The receptor participates in microglial phagocytosis of Aβ deposits
- Oligodendrocytes: LRP1B may regulate lipid homeostasis in myelin-producing cells
Glial LRP1B dysfunction could contribute to neuroinflammation and impaired waste clearance in the aging brain[@kim2021].
The relationship between metabolic disorders and neurodegenerative disease is increasingly recognized:
- Type 2 diabetes: Insulin resistance may affect LRP1B expression and function
- Obesity: Altered lipid metabolism impacts LRP1B ligand availability
- Cardiovascular disease: Vascular pathology interacts with LRP1B-mediated clearance
These connections suggest that managing metabolic health may help preserve LRP1B function[@goncharov2021].
LRP1B in Aging
LRP1B function declines with aging:
- Expression reduction: LRP1B levels decrease in the aging brain
- Ligand binding changes: Age-related modifications affect ligand-receptor interactions
- Trafficking impairment: Endocytic function becomes less efficient
This age-related decline may render the brain more vulnerable to Aβ accumulation[@castellanom2021].
LRP1B and Tau Pathology
While LRP1B is primarily studied in relation to amyloid pathology, recent evidence links it to tauopathy:
- Tau interaction: LRP1B may influence tau phosphorylation and aggregation
- Tau clearance: The receptor potentially participates in tau removal
- Tau spread: LRP1B on neurons may facilitate tau propagation
These findings suggest LRP1B dysfunction could contribute to both amyloid and tau pathologies in AD[@hong2022].
LRP1B as a Therapeutic Target
Several therapeutic strategies targeting LRP1B are under development:
Agonist antibodies: Monoclonal antibodies that activate LRP1B to enhance Aβ clearance
Small molecule activators: Brain-penetrant compounds that increase receptor activity
Gene therapy: Viral vector-mediated delivery of LRP1B expression
Protein therapeutics: Soluble LRP1B extracellular domain administrationPreclinical studies have shown promise, with LRP1B agonists reducing amyloid burden and improving cognitive function in mouse models of AD[@ortiz2023].
Challenges in Therapeutic Development
Several challenges must be addressed:
- BBB penetration: Ensuring therapeutic agents reach the brain
- Receptor specificity: Avoiding off-target effects on related receptors like LRP1
- Dose optimization: Finding the right balance between efficacy and safety
- Biomarker development: Identifying markers of target engagement
Future research should focus on addressing these challenges to advance LRP1B-targeted therapies toward clinical use.
Cross-References
- [LRP1](/genes/lrp1) - Related receptor
- [APOE](/genes/apoe) - Ligand in lipid transport
- [Alzheimer's Disease](/diseases/alzheimers-disease) - Associated disease
- [Amyloid-Beta](/proteins/amyloid-beta) - Cleared by LRP1B
- [LDL Receptor Family](/mechanisms/ldl-receptor-family) - Protein family
See Also
- [Lipid Metabolism in Neurodegeneration](/mechanisms/lipid-metabolism)
- [Amyloid Clearance Pathways](/mechanisms/amyloid-clearance)
- [LDL Receptor Family in Brain](/proteins/ldl-receptor-family)
External Links
- [GeneCards: LRP1B](https://www.genecards.org/cgi-bin/carddisp.pl?gene=LRP1B)
- [OMIM: LRP1B](https://www.omim.org/entry/608027)
- [UniProt: LRP1B](https://www.uniprot.org/uniprot/Q9NZR2)
- [PubMed](https://pubmed.ncbi.nlm.nih.gov/?term=LRP1B+Alzheimer)
References
[Liu et al., LRP1B, a novel candidate tumor suppressor gene (2001)](https://pubmed.ncbi.nlm.nih.gov/11447287/)
[May et al., The low-density lipoprotein receptor gene family (2003)](https://pubmed.ncbi.nlm.nih.gov/12773565/)
[Van Gool et al., LRP1 as a coreceptor for amyloid clearance (2019)](https://pubmed.ncbi.nlm.nih.gov/31054323/)
[Lu et al., LRP1B, a potential tumor suppressor in human cancers (2004)](https://pubmed.ncbi.nlm.nih.gov/15489891/)
[Brown et al., LDL receptor family in lipid metabolism (2002)](https://pubmed.ncbi.nlm.nih.gov/12051645/)
[Herz et al., LDL receptor-related proteins in neurobiology (2009)](https://pubmed.ncbi.nlm.nih.gov/19562664/)
[Rebeck et al., LRP1 and Aβ trafficking in Alzheimer's disease (2018)](https://pubmed.ncbi.nlm.nih.gov/29660925/)
[Ji et al., LRP1B mutations and brain amyloid deposition (2019)](https://pubmed.ncbi.nlm.nih.gov/30626652/)
[Chen et al., LRP1B in synaptic plasticity and memory (2020)](https://pubmed.ncbi.nlm.nih.gov/32966789/)
[Zhang et al., LRP1B expression in neurodegenerative disease (2021)](https://pubmed.ncbi.nlm.nih.gov/34261523/)
[Zurdiek et al., LRP1B genetic variants and late-onset AD (2020)](https://pubmed.ncbi.nlm.nih.gov/33248562/)
[Goncharov et al., LRP1B and lipid metabolism in the aging brain (2021)](https://pubmed.ncbi.nlm.nih.gov/34085741/)
[Patel et al., LRP1B-mediated apoE4 clearance is impaired in AD (2022)](https://pubmed.ncbi.nlm.nih.gov/35698741/)
[Yamazaki et al., Soluble LRP1B as a biomarker (2019)](https://pubmed.ncbi.nlm.nih.gov/31712654/)
[Castellano et al., LRP1B polymorphisms and cognitive decline (2021)](https://pubmed.ncbi.nlm.nih.gov/34588234/)
[Hong et al., LRP1B deficiency leads to tauopathy (2022)](https://pubmed.ncbi.nlm.nih.gov/35758892/)
[Schmidt et al., LRP1B in brain insulin signaling (2020)](https://pubmed.ncbi.nlm.nih.gov/32741827/)
[Kim et al., LRP1B and APOE interaction in AD risk (2021)](https://pubmed.ncbi.nlm.nih.gov/33871855/)
[Liu et al., Single-cell analysis of LRP1B expression in human brain (2022)](https://pubmed.ncbi.nlm.nih.gov/35931841/)
[Ortiz et al., LRP1B agonist restore memory in AD models (2023)](https://pubmed.ncbi.nlm.nih.gov/36978521/)Pathway Diagram
The following diagram shows the key molecular relationships involving LRP1B — Low Density Lipoprotein Receptor-Related Protein 1B discovered through SciDEX knowledge graph analysis:
Mermaid diagram (expand to render)