| cftr | |
|---|---|
| **Official Symbol** | CFTR |
| **Official Full Name** | Cystic Fibrosis Transmembrane Conductance Regulator |
| **Chromosomal Location** | 7q31.2 |
| **NCBI Gene ID** | 1080 |
| **Ensembl ID** | ENSG00000001626 |
| **OMIM** | 602421 |
| **UniProt** | P13569 |
| **Protein Length** | 1,480 amino acids |
| **Protein** | CFTR (cAMP-activated chloride channel) |
| Region | Expression |
| **Hippocampus** | Moderate |
| **Cortex** | Moderate |
| **Cerebellum** | Low-Moderate |
| **Substantia nigra** | Low-Moderate |
| **Striatum** | Moderate |
| Drug | Mechanism |
| **Ivacaftor** | Potentiator (increases channel open time) |
| **Lumacaftor** | Corrector (improves folding) |
| **Tezacaftor** | Corrector |
| **Elexacaftor** | Corrector |
| **Trikafta** | Combination therapy |
| Partner | Interaction Type |
| **NHERF/EBP50** | PDZ binding |
| **RhoA** | Regulation |
| **PKA** | Phosphorylation |
| **Annexin V** | Binding |
| **Syntaxin 1A** | Direct interaction |
| **CFTR-associated ligand (CAL)** | Degradation regulation |
| Associated Diseases | ALS, Als, Asthma, Cancer, Carcinoma |
| KG Connections | 352 edges |
Pathway Diagram
flowchart TD
CFTR["CFTR<br/>Chloride Channel"]
%% Regulatory inputs
AKT1["AKT1<br/>Survival Signaling"]
CASP3["CASP3<br/>Apoptosis Executor"]
CGAS["cGAS<br/>DNA Sensor"]
%% Autophagy pathway
SQSTM1["SQSTM1/p62<br/>Autophagy Adapter"]
ATG16L1["ATG16L1<br/>Autophagosome<br/>Formation"]
RB1CC1["RB1CC1/FIP200<br/>Autophagy<br/>Initiation"]
GABARAP["GABARAP<br/>LC3 Family<br/>Protein"]
%% Neurodegeneration-related proteins
LRRK2["LRRK2<br/>Parkinson's<br/>Kinase"]
OPTN["OPTN<br/>Autophagy<br/>Receptor"]
%% Stress response
ERN1["ERN1/IRE1alpha<br/>ER Stress<br/>Sensor"]
STING1["STING1<br/>Innate Immunity"]
%% Disease outcomes
ALS["ALS<br/>Motor Neuron<br/>Disease"]
MS["Multiple<br/>Sclerosis"]
Fibrosis["Tissue<br/>Fibrosis"]
%% Connections
AKT1 -->|"regulates"| CFTR
CASP3 -->|"regulates"| CFTR
CGAS -->|"regulates"| CFTR
CFTR -->|"regulates"| ATG16L1
CFTR -->|"interacts_with"| SQSTM1
CFTR -->|"interacts_with"| RB1CC1
CFTR -->|"interacts_with"| GABARAP
CFTR -->|"interacts_with"| LRRK2
CFTR -->|"interacts_with"| ERN1
CFTR -->|"interacts_with"| STING1
OPTN -->|"interacts_with"| CFTR
SQSTM1 -->|"links_to"| OPTN
CFTR -->|"regulates"| ALS
CFTR -->|"interacts_with"| MS
CFTR -->|"regulates"| Fibrosis
%% Styling
style CFTR fill:#006494
style AKT1 fill:#1b5e20
style ATG16L1 fill:#1b5e20
style SQSTM1 fill:#1b5e20
style RB1CC1 fill:#1b5e20
style GABARAP fill:#1b5e20
style OPTN fill:#1b5e20
style CASP3 fill:#ef5350
style ERN1 fill:#ef5350
style CGAS fill:#4a1a6b
style STING1 fill:#4a1a6b
style LRRK2 fill:#4a1a6b
style ALS fill:#5d4400
style MS fill:#5d4400
style Fibrosis fill:#5d4400Introduction
The CFTR gene (Cystic Fibrosis Transmembrane Conductance Regulator) encodes a member of the ATP-binding cassette (ABC) transporter superfamily that functions as a cAMP-activated chloride channel. While classically associated with cystic fibrosis (CF), CFTR is also expressed in the central nervous system where it plays important roles in neuronal function, astrocytic homeostasis, and neuroinflammation1CFTR in the brainOpen reference. Emerging research suggests that CFTR dysfunction may contribute to the pathogenesis of neurodegenerative diseases including Alzheimer’s disease and Parkinson’s disease.
CFTR is a unique ABC transporter in that it functions as an ion channel rather than an active transporter. The protein forms a chloride-selective pore that is regulated by cAMP-dependent protein kinase (PKA) and ATP binding at the nucleotide-binding domains. Beyond its role as a chloride channel, CFTR influences other ion channels and cellular processes through protein-protein interactions and regulation of intracellular signaling pathways2CFTR and neurodegenerationOpen reference.
Gene Information
Protein Structure and Function
Structural Organization
CFTR is composed of five domains:
-
Two transmembrane domains (TMD1, TMD2): Each contains six transmembrane helices that form the channel pore
-
Two nucleotide-binding domains (NBD1, NBD2): Bind and hydrolyze ATP to drive channel gating
-
One regulatory (R) domain: Contains multiple phosphorylation sites that regulate channel activity
The channel functions as a dimer of two ABC transporter-like halves, with the two NBDs forming a “head-to-tail” dimer that hydrolyzes ATP to open and close the channel.
Chloride Channel Function
CFTR mediates chloride (Cl⁻) transport with the following properties:
-
Selectivity: Highly selective for Cl⁻ over other anions
-
Conductance: Single-channel conductance of ~10 pS under physiological conditions
-
Gating: Regulated by PKA phosphorylation and ATP hydrolysis
-
Localization: Apical membrane in epithelial cells, plasma membrane in neurons
Additional Functions
Beyond chloride transport, CFTR:
-
Regulates other ion channels: Modulates ENaC, ROMK, and other channels
-
Affects water transport: Indirectly influences aquaporin function
-
Modulates cellular signaling: Interacts with various signaling pathways
-
Supports epithelial function: Maintains salt and water homeostasis
Expression in the Brain
Neuronal Expression
CFTR is expressed in various neuronal populations3CFTR function in the central nervous systemOpen reference:
Glial Expression
CFTR is also expressed in glial cells:
-
Astrocytes: High expression in astrocytic processes
-
Microglia: Lower expression, upregulation under inflammatory conditions
-
Oligodendrocytes: Limited expression
Cellular Localization
In neurons, CFTR localizes to:
-
Soma and dendrites: Particularly in dendritic branches
-
Synapses: Synaptic plasma membrane
-
Endoplasmic reticulum: Intracellular pools
Subcellular Distribution in Neurons
The subcellular distribution of CFTR in neurons is specialized4CFTR in neurodevelopment: implications for brain functionOpen reference:
-
Synaptic compartments: CFTR is enriched at both excitatory and inhibitory synapses
-
Regulates synaptic chloride gradients
-
Modulates GABAergic inhibition
-
Affects excitatory neurotransmission
-
-
Dendritic arbor: Distribution along dendrites
-
Spatial buffering of chloride ions
-
Integration of synaptic inputs
-
-
Somatic membrane: Cell body expression
-
General neuronal homeostasis
-
CFTR in the Blood-Brain Barrier
CFTR is expressed in brain endothelial cells forming the blood-brain barrier5CFTR and blood-brain barrier dysfunction in neurodegenerationOpen reference:
-
Endothelial cells: Regulates BBB integrity
-
Tight junctions: Maintains barrier function
-
Transport: Modulates blood-to-brain transit
Dysfunction may contribute to:
-
Increased BBB permeability
-
Reduced clearance of brain metabolites
-
Enhanced infiltration of immune cells
Role in Neurodegenerative Diseases
Alzheimer’s Disease
CFTR contributes to Alzheimer’s disease pathogenesis through multiple mechanisms6CFTR and neuroinflammation in Alzheimer's diseaseOpen reference:
-
Chloride homeostasis: Altered Cl⁻ transport affects neuronal excitability and inhibitory GABAergic signaling
-
Neuroinflammation: CFTR in astrocytes modulates inflammatory responses
-
Amyloid processing: CFTR may influence amyloid precursor protein (APP) processing
-
Calcium dysregulation: CFTR dysfunction affects intracellular calcium handling
-
Blood-brain barrier: CFTR in endothelial cells may affect BBB integrity
Parkinson’s Disease
In Parkinson’s disease, CFTR plays roles in astrocytic function7CFTR and Parkinson's disease: astrocytic dysfunctionOpen reference:
-
Astrocytic support: CFTR in astrocytes supports neuronal survival
-
Dopaminergic neuron vulnerability: CFTR dysfunction may exacerbate SN neuron vulnerability
-
Neuroinflammation: Astrocytic CFTR modulates inflammatory responses
-
α-Synuclein clearance: CFTR may affect protein clearance pathways
-
Mitochondrial function: CFTR interacts with mitochondrial processes
Other Neurological Conditions
-
Epilepsy: Altered chloride homeostasis affects neuronal excitability
-
Multiple sclerosis: CFTR in glial cells may influence demyelination
-
Brain development: CFTR affects neural progenitor cell function
Epilepsy
CFTR plays important roles in neuronal excitability relevant to epilepsy8Chloride channels in epilepsy: CFTR and other targetsOpen reference:
-
Chloride gradient regulation: Controls neuronalCl⁻ levels
-
Dysregulation affects GABAergic inhibition
-
Contributes to hyperexcitability
-
-
Synaptic plasticity: Alters seizure susceptibility
-
CFTR dysfunction affects excitatory/inhibitory balance
-
-
Astrocytic CFTR: Modulates astrocyte function
-
Potassium buffering affected
-
Contributes to seizure generation
-
-
Therapeutic targeting: CFTR modulators as anti-seizure agents
CFTR Modulators and Neurodegeneration
CFTR Modulators in Clinical Use
The development of CFTR modulators has revolutionized cystic fibrosis treatment:
Potential Neuroprotective Effects
CFTR modulators may have neuroprotective potential:
-
Reduced neuroinflammation: Modulator treatment may reduce glial activation
-
Improved neuronal function: Restored chloride homeostasis
-
Antioxidant effects: Modulators may reduce oxidative stress
-
Protein clearance: May enhance autophagy and protein clearance
CFTR and Synaptic Function
CFTR plays crucial roles in synaptic transmission9CFTR in synaptic plasticity and memoryOpen reference:
-
GABAergic inhibition: Regulates chloride gradients at inhibitory synapses
-
Affects GABA_A receptor function
-
Modulates inhibitory tone
-
-
Excitatory synaptic transmission: Influences glutamate signaling
-
Postsynaptic chloride regulation
-
Calcium entry through NMDA receptors
-
-
Synaptic plasticity: Memory and learning processes
-
Long-term potentiation (LTP)
-
Long-term depression (LTD)
-
-
Network oscillations: Brain rhythms
-
Hippocampal theta oscillations
-
Cortical gamma oscillations
-
Molecular Interactions
Protein Partners
CFTR interacts with various proteins in the brain:
Signaling Pathways
CFTR engages multiple signaling pathways:
-
cAMP/PKA pathway: Primary regulatory mechanism
-
Rho GTPases: Cytoskeletal regulation
-
MAPK pathway: Cell survival signaling
-
PI3K/AKT pathway: Neuroprotection
Therapeutic Implications
Targeting CFTR in Neurodegeneration
Potential therapeutic strategies:
-
CFTR modulators: Use of existing CF drugs for neuroprotection
-
Chloride channel blockers: Selective inhibition for specific conditions
-
Gene therapy: Restoring CFTR expression in the brain
-
Small molecules: Developing CNS-penetrant CFTR modulators
Challenges
-
Blood-brain barrier penetration: Most CFTR modulators have limited CNS penetration
-
Selectivity: Avoiding off-target effects
-
Dosing: Determining effective neuroprotective doses
-
Patient selection: Identifying patients most likely to benefit
Animal Models
CFTR Knockout Mice
-
Neurological phenotypes: Altered neuronal excitability, cognitive deficits
-
Astrocyte abnormalities: Morphological and functional changes
-
Inflammatory changes: Elevated neuroinflammation markers
-
Behavioral deficits: Learning and memory impairments
Transgenic Models
-
Neuron-specific knockout: Studying neuronal CFTR function
-
Astrocyte-specific knockout: Astrocytic CFTR role
-
Human CFTR expression: Modeling mutant CFTR in brain
Related Mechanisms
CFTR intersects with multiple cellular pathways:
See Also
External Links
Brain Atlas Resources
References
- CFTR in the brain
- CFTR and neurodegeneration
- CFTR function in the central nervous system
- CFTR in neurodevelopment: implications for brain function
- CFTR and blood-brain barrier dysfunction in neurodegeneration
- CFTR and neuroinflammation in Alzheimer's disease
- CFTR and Parkinson's disease: astrocytic dysfunction
- Chloride channels in epilepsy: CFTR and other targets
- CFTR in synaptic plasticity and memory
Sister wikis (recently updated · no domain on this page)
- Agent Recipe: AI-for-Biology Closed-Loop with Reviewer Handoffs and Eval Contracts
- Agent Recipe: AI-for-Biology Closed-Loop with Reviewer Handoffs and Eval Contracts
- test
- JGBO-I27: Top 10 GBO Questions for Prioritization
- JGBO-I27: Top 10 GBO Questions for Prioritization
- Design Brief: Beta-test Evaluation Protocol for SciDEX v2 Design Trajectories
- Andy — Showcase Findings (auto-curated)
- Kris — Showcase Findings (auto-curated)
Recent activity here
No recent events touching this page.