| fubp1 | |
|---|---|
| **Gene Symbol** | FUBP1 |
| **Alternative Names** | FBP1, FUSE binding protein 1 |
| **Full Name** | Far Upstream Element Binding Protein 1 |
| **Chromosomal Location** | 1p31.1 |
| **NCBI Gene ID** | 2260 |
| **OMIM** | 608470 |
| **Ensembl ID** | ENSG00000107223 |
| **UniProt ID** | Q96AE4 |
| Tissue | Expression Level |
| Brain | High |
| Liver | High |
| Testis | High |
| Heart | Moderate |
| Kidney | Moderate |
| Pathway | Consequence |
| c-Myc regulation | Altered proliferation/metabolism |
| DNA repair | Accumulated DNA damage |
| RNA processing | Dysregulated gene expression |
| Metabolic control | Energy impairment |
| Associated Diseases | AD, Breast Cancer, Cancer, Glioma, Ms |
| KG Connections | 41 edges |
Introduction
FUBP1 (Far Upstream Element Binding Protein 1), also known as FBP1 (FUSE Binding Protein 1), is a multifunctional DNA and RNA-binding protein that plays critical roles in transcriptional regulation, RNA processing, and the DNA damage response. Originally identified as a regulator of c-Myc expression through binding to the far upstream element (FUSE), FUBP1 has emerged as an important player in neurodegeneration, particularly in amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD). 1The FUSE binding protein FUBP1: Nuclear roles in transcriptionOpen reference
The identification of FUBP1 mutations in ALS/FTD patients has highlighted the importance of transcriptional regulation and DNA repair in maintaining neuronal health. As a master regulator of gene expression, FUBP1 sits at the intersection of multiple pathways critical for neuronal survival. 2FUBP1 mutations in ALS and FTDOpen reference
Gene Overview
Protein Structure and Domains
FUBP1 is a ~650 amino acid protein with multiple functional domains:
Functional Domains
-
N-terminal transactivation domain: Interacts with transcriptional co-activators
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Central KH domain: RNA/DNA binding domain (~100 aa)
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C-terminal domains: Additional nucleic acid binding capacity
Structure-Function
The KH domain is the critical nucleic acid-binding module:
-
Recognizes single-stranded DNA (FUSE) and RNA
-
Mediates protein-protein interactions
-
Essential for transcriptional regulation function
Normal Physiological Function
Transcriptional Regulation
FUBP1 regulates gene expression through multiple mechanisms:
c-Myc Regulation
-
Binds to FUSE upstream of c-Myc promoter
-
Modulates RNA polymerase II processivity
-
Coordinates transcriptional elongation
-
Links nutritional/growth signals to Myc expression 3FUBP1: A single-stranded DNA binding protein that regulates c-myc expressionOpen reference
Broader Transcriptional Network
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Regulates numerous target genes beyond Myc
-
Functions as both activator and repressor
-
Integrates signaling inputs
-
Controls metabolic gene expression
RNA Processing
FUBP1 participates in RNA metabolism:
-
mRNA stability: Affects transcript half-life
-
Alternative splicing: Influences splice site selection
-
Translation regulation: Modulates protein synthesis
-
RNA localization: Affects subcellular RNA distribution 4FUBP1 interacts with RNA and regulates gene expressionOpen reference
DNA Damage Response
FUBP1 is involved in DNA repair:
-
Response to damage: Rapid recruitment to DNA lesions
-
Repair pathway: Participates in repair of double-strand breaks
-
Replication stress: Response to replication fork stalling
-
Genomic stability: Maintains chromosome integrity 5FUBP1 in DNA damage response and repairOpen reference
Expression Pattern
Brain Expression
In the nervous system, FUBP1 shows:
-
Neuronal expression: High in pyramidal neurons
-
Glial expression: Detected in astrocytes and oligodendrocytes
-
Subcellular localization: Nuclear and cytoplasmic
-
Stress responsiveness: Altered by DNA damage and cellular stress
Disease Associations
Amyotrophic Lateral Sclerosis (ALS)
FUBP1 is genetically associated with ALS:
Genetic Evidence
-
FUBP1 mutations identified in ALS/FTD patients
-
Autosomal dominant inheritance pattern
-
Both missense and loss-of-function variants
-
Pathogenic mechanisms involve loss-of-function 2FUBP1 mutations in ALS and FTDOpen reference
Mechanistic Pathways
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Transcriptional dysregulation: Impaired c-Myc and target gene regulation
-
DNA repair deficiency: Reduced DNA damage response
-
Metabolic dysfunction: Altered cellular energetics
-
Stress vulnerability: Reduced ability to respond to cellular stress
Frontotemporal Dementia (FTD)
FUBP1 mutations also cause FTD:
-
Overlapping clinical spectrum with ALS
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Behavioral variant FTD presentation
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Language variant FTD (particularly)
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Often co-occurs with ALS features
Alzheimer’s Disease
Potential FUBP1 involvement in AD:
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Transcriptional dysregulation is a hallmark of AD
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DNA damage accumulates in AD neurons
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c-Myc dysregulation affects neuronal function
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May contribute to disease progression
Parkinson’s Disease
Possible FUBP1 connections:
-
Transcriptional alterations in PD models
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DNA damage in dopaminergic neurons
-
Metabolic dysfunction in vulnerable neurons
Molecular Mechanisms
FUBP1 in Neuronal Death
graph TD
A["FUBP1 Loss-of-Function"] --> B["Transcriptional<br/>Dysregulation"]
A --> C["DNA Repair<br/>Deficiency"]
A --> D["Metabolic<br/>Dysfunction"]
B --> E["c-Myc Dysregulation"]
B --> F["Target Gene<br/>Alterations"]
C --> G["DNA Damage<br/>Accumulation"]
C --> H["Genomic<br/>Instability"]
D --> I["Energy<br/>Deficiency"]
D --> J["Metabolic<br/>Stress"]
E --> K["Neuronal<br/>Dysfunction"]
F --> K
G --> L["Apoptosis"]
H --> L
I --> K
J --> K
K --> M["Neuronal<br/>Death"]
L --> M
style A fill:#3b1114
style M fill:#3b1114Cellular Pathways Affected
Therapeutic Implications
Targeting FUBP1 Pathway
Transcriptional Modulation
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Targeting downstream effectors of transcriptional dysregulation
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Modulating c-Myc activity as compensatory approach
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Enhancing expression of protective genes
DNA Repair Enhancement
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Boosting DNA repair capacity in neurons
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Reducing DNA damage burden
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Protecting against genomic instability
Challenges
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Protein function: FUBP1 has multiple functions - targeting may have off-target effects
-
Blood-brain barrier: CNS penetration requirements
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Timing: Intervention at appropriate disease stage
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Specificity: Avoiding effects on dividing cells
Research Directions
Current Areas of Investigation
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Mutation characterization: Understanding pathogenic FUBP1 variants
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Mechanistic studies: How loss-of-function causes neurodegeneration
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Therapeutic targets: Identifying downstream effectors
-
iPSC models: Patient-derived neurons with FUBP1 mutations
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Biomarkers: FUBP1-related biomarkers for disease progression
Key Unanswered Questions
-
What is the precise mechanism of FUBP1-mediated neurotoxicity?
-
Can transcriptional or DNA repair pathways be modulated therapeutically?
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What determines selective neuronal vulnerability?
-
How do FUBP1 mutations interact with other ALS/FTD genes?
See Also
References
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