CCR1 (C-C Chemokine Receptor Type 1), also known as CD191, MIP-1α Receptor, and RANTES Receptor, encodes a G protein-coupled receptor that binds multiple CC chemokines including CCL3 (MIP-1α), CCL5 (RANTES), CCL7 (MCP-3), CCL14 (HCC-1), and CCL15 (HCC-2). This receptor is expressed on various immune cells including monocytes, neutrophils, lymphocytes, eosinophils, and microglia, where it plays critical roles in leukocyte trafficking, inflammatory responses, and cellular signaling. Recent research has established CCR1 as a significant player in neuroinflammation associated with Alzheimer's disease, Parkinson's disease, multiple sclerosis, and amyotrophic lateral sclerosis, making it an emerging therapeutic target for neurodegenerative conditions [1][2].
The CCL3-CCR1 signaling axis has emerged as a key mediator of neuroinflammation in the central nervous system. Upon binding of CCL3, CCL5, or other cognate chemokines, CCR1 activates multiple downstream signaling cascades that promote microglial activation, recruitment of peripheral immune cells to the brain, and propagation of inflammatory responses that contribute to neuronal dysfunction and death. This page provides comprehensive coverage of CCR1's normal function, molecular mechanisms, disease associations, expression patterns, and therapeutic targeting potential.
| Property | Value |
|---|---|
| Gene Symbol | CCR1 |
| Full Name | C-C Chemokine Receptor Type 1 |
| Aliases | CD191, MIP-1a Receptor, RANTES Receptor, CMKBR1 |
| Chromosomal Location | 3p21.31 |
| NCBI Gene ID | 1230 |
| OMIM | 601626 |
| Ensembl ID | ENSG00000163631 |
| UniProt ID | P32246 |
| Gene Type | Protein coding |
| Gene Family | Chemokine receptors (GPCR family) |
The CCR1 gene spans approximately 35 kb and consists of 5 exons encoding a 7-transmembrane domain GPCR of 355 amino acids. The gene is located on chromosome 3p21.31, a region that has been implicated in various inflammatory and autoimmune diseases. The promoter region contains binding sites for multiple transcription factors including NF-κB, AP-1, and STAT1, reflecting its regulation in inflammatory conditions [3].
CCR1 is a Class A G protein-coupled receptor consisting of:
The receptor binds multiple chemokines with varying affinities:
Upon chemokine binding, CCR1 activates multiple intracellular signaling pathways:
G protein-dependent signaling:
β-arrestin-dependent signaling:
Key downstream pathways:
The ability of CCR1 to bind multiple chemokines creates a complex signaling network that allows for nuanced regulation of immune responses depending on the local chemokine environment [4].
CCR1 plays essential roles in immune cell trafficking:
Monocyte recruitment: CCR1 mediates monocyte migration to sites of inflammation in response to CCL3 and CCL5 gradients. This is critical for tissue repair and immune surveillance.
Neutrophil trafficking: CCR1 contributes to neutrophil recruitment in inflammatory conditions, working alongside other chemokine receptors.
Lymphocyte homing: Memory T cells expressing CCR1 migrate to sites of inflammation based on CCL3/CCL5 gradients.
Eosinophil recruitment: CCR1 participates in eosinophil trafficking in allergic and parasitic conditions.
CCR1 mediates multiple inflammatory processes:
CCR1 participates in bone marrow cell mobilization and hematopoiesis:
| Cell Type | CCR1 Expression | Functional Significance |
|---|---|---|
| Monocytes | High | Inflammatory recruitment |
| Neutrophils | Moderate | Acute inflammation |
| Memory T cells | Moderate-High | Chronic inflammation |
| Eosinophils | High | Allergic inflammation |
| Dendritic cells | Moderate | Antigen presentation |
| B cells | Low | Subset-specific |
In the healthy brain, CCR1 expression is minimal. However, under pathological conditions:
Microglia: CCR1 is significantly upregulated on activated microglia in neuroinflammatory conditions. These cells respond to CCL3 and CCL5 released by neurons and other glial cells, propagating inflammatory responses [6].
Astrocytes: Some studies report low-level CCR1 expression on astrocytes, particularly in reactive astrocytes surrounding lesions.
Neurons: Low basal expression of CCR1 on neurons, with upregulation in disease states.
Infiltrating immune cells: Peripheral monocytes and lymphocytes expressing CCR1 infiltrate the CNS in neurodegenerative conditions.
| Condition | CCR1 Expression | Key Features |
|---|---|---|
| Alzheimer's Disease | High | Microglia surrounding plaques |
| Parkinson's Disease | High | Substantia nigra, dopaminergic regions |
| Multiple Sclerosis | Very High | Active demyelinating lesions |
| ALS | High | Spinal cord, motor neurons |
| Stroke | High | Infarct area, penumbra |
The CCL3-CCR1 axis is strongly implicated in Alzheimer's disease pathogenesis:
Aβ-induced inflammation: Amyloid-beta (Aβ) peptides stimulate astrocytes and microglia to produce CCL3, which then activates CCR1+ microglia, creating a positive feedback loop of neuroinflammation. This mechanism drives chronic microglial activation that contributes to neuronal damage [7][8].
Microglial recruitment: CCR1+ microglia accumulate around amyloid plaques in AD brain. Single-cell analyses have identified distinct CCR1+ microglial subsets with pro-inflammatory phenotypes [9].
Tau pathology: The CCL3-CCR1 axis may contribute to tau pathology propagation through microglial-mediated spread of pathological tau species [10].
Disease progression: CCR1 expression correlates with disease severity, with higher levels in more advanced disease stages.
| AD Feature | CCR1 Association | Evidence |
|---|---|---|
| Amyloid plaques | CCR1+ microglia surrounding plaques | Strong |
| Neurofibrillary tangles | Indirect association via inflammation | Moderate |
| Neuroinflammation | CCL3 elevated in brain/CSF | Strong |
| Cognitive decline | CCR1 expression correlates with decline | Moderate |
CCR1 plays a role in Parkinson's disease through multiple mechanisms:
Dopaminergic neuron degeneration: CCL3-CCR1 signaling contributes to dopaminergic neuron loss in the substantia nigra. CCR1 activation on microglia promotes release of neurotoxic factors [11].
Microglial activation: CCR1 mediates microglial activation in response to α-synuclein pathology and neuronal damage.
Neuroinflammation: The CCL3-CCR1 axis contributes to chronic neuroinflammation in PD, with CCR1 antagonists showing protective effects in models [12].
The CCL3-CCR1 axis is strongly implicated in multiple sclerosis pathogenesis:
Immune cell recruitment: CCL3 expression is elevated in MS lesions, recruiting CCR1+ immune cells to the CNS.
Demyelination: CCR1+ monocytes and T cells contribute to demyelination through release of inflammatory mediators.
Therapeutic potential: CCR1 antagonists reduce disease severity in EAE models, the mouse model of MS [13].
In ALS, CCR1 contributes to neuroinflammation:
Microglial activation: CCR1+ microglia are abundant in ALS spinal cord, contributing to motor neuron damage.
Disease progression: CCR1 expression correlates with disease progression in ALS patients and models [14].
Rheumatoid arthritis: CCR1 is a therapeutic target, with antagonists in development.
Inflammatory bowel disease: CCR1 mediates leukocyte recruitment to inflamed gut.
Transplant rejection: CCR1+ cells contribute to graft rejection.
Psoriasis: CCR1 in skin inflammation.
Several CCR1-targeting strategies are in development:
Small molecule antagonists:
Monoclonal antibodies:
Alternative approaches:
CCR1 knockout mice (Ccr1-/-) exhibit:
The CCR1 gene encodes a critical chemokine receptor that plays essential roles in immune cell trafficking, inflammatory responses, and neuroinflammation. The CCL3-CCR1 axis contributes to disease pathogenesis in Alzheimer's disease, Parkinson's disease, multiple sclerosis, and ALS through mechanisms involving microglial activation, immune cell recruitment, and propagation of inflammatory cascades. While therapeutic targeting of CCR1 faces challenges related to blood-brain barrier penetration and broad expression, ongoing research aims to develop BBB-penetrant antagonists and cell-type-specific approaches for treating neurodegenerative diseases.