PEX10 Gene

PEX10 — Peroxisome Biogenesis Factor 10

<div class="infobox infobox-gene">

| Property | Value |
|----------|-------|
| Gene Symbol | PEX10 |
| Full Name | Peroxisome Biogenesis Factor 10 |
| Chromosomal Location | 1p36.32 |
| NCBI Gene ID | 5199 |
| OMIM ID | 614863 |
| Ensembl ID | ENSG00000103356 |
| UniProt ID | O00391 |
| Encoded Protein | Peroxin-10 |
| Associated Diseases | Zellweger Spectrum Disorders, Peroxisome Biogenesis Disorder, Autism Spectrum Disorder, Alzheimer's Disease, Parkinson's Disease |

</div>

Overview

PEX10 (Peroxisome Biogenesis Factor 10) encodes a critical peroxin essential for peroxisome biogenesis and peroxisomal matrix protein import. Peroxisomes are membrane-bound organelles that play vital roles in fatty acid oxidation, plasmalogen synthesis, hydrogen peroxide metabolism, and bile acid synthesis[@watkins2015]. PEX10 functions as a RING finger ubiquitin ligase that recognizes peroxisomal matrix proteins with defects in peroxisomal targeting signals and facilitates their retrotranslocation to the cytosol for quality control degradation.

PEX10 — Peroxisome Biogenesis Factor 10

<div class="infobox infobox-gene">

| Property | Value |
|----------|-------|
| Gene Symbol | PEX10 |
| Full Name | Peroxisome Biogenesis Factor 10 |
| Chromosomal Location | 1p36.32 |
| NCBI Gene ID | 5199 |
| OMIM ID | 614863 |
| Ensembl ID | ENSG00000103356 |
| UniProt ID | O00391 |
| Encoded Protein | Peroxin-10 |
| Associated Diseases | Zellweger Spectrum Disorders, Peroxisome Biogenesis Disorder, Autism Spectrum Disorder, Alzheimer's Disease, Parkinson's Disease |

</div>

Overview

PEX10 (Peroxisome Biogenesis Factor 10) encodes a critical peroxin essential for peroxisome biogenesis and peroxisomal matrix protein import. Peroxisomes are membrane-bound organelles that play vital roles in fatty acid oxidation, plasmalogen synthesis, hydrogen peroxide metabolism, and bile acid synthesis[@watkins2015]. PEX10 functions as a RING finger ubiquitin ligase that recognizes peroxisomal matrix proteins with defects in peroxisomal targeting signals and facilitates their retrotranslocation to the cytosol for quality control degradation.

Mutations in PEX10 cause Zellweger spectrum disorders (ZSD), a group of severe peroxisome biogenesis disorders characterized by profound developmental delay, craniofacial abnormalities, hepatomegaly, and progressive neurodegeneration[@steinberg2004][@ebberink2012]. Beyond these rare genetic disorders, PEX10 and peroxisomal function have been increasingly implicated in more common neurodegenerative conditions, including Alzheimer's disease (AD) and Parkinson's disease (PD)[@van2021][@ibanez2022].

Gene Structure and Evolution

Genomic Organization

| Feature | Details |
|---------|---------|
| Chromosome | 1p36.32 |
| Strand | Plus strand |
| Exons | 4 |
| Transcript length | 1,536 bp coding region |
| Protein length | 335 amino acids |
| RefSeq | NM_001374497 |

Evolutionary Conservation

PEX10 is highly conserved across eukaryotes:

| Species | Identity | Notes |
|---------|----------|-------|
| Human | Reference | Full length |
| Mouse | 92% | Functional conservation |
| Zebrafish | 78% | Peroxisome biogenesis |
| Drosophila | 65% | Basic function preserved |
| S. cerevisiae | 48% | Pex10p ortholog |
| A. thaliana | 54% | Plant peroxin |

Gene Family

PEX10 belongs to the peroxin family involved in peroxisome biogenesis:

| Peroxin | Function | Disease if mutated |
|---------|----------|---------------------|
| PEX1 | AAA-ATPase, peroxisome proliferation | ZSD (most common) |
| PEX2 | Peroxisomal membrane protein | ZSD |
| PEX5 | PTS1 receptor, protein import | ZSD |
| PEX6 | AAA-ATPase, import | ZSD |
| PEX10 | RING finger E3 ligase | ZSD |
| PEX12 | RING finger E3 ligase | ZSD |
| PEX13 | Docking factor | ZSD |

Protein Structure and Biochemistry

Domain Architecture

PEX10 is a multi-domain protein with distinct functional regions:

Key Structural Features

| Domain | Amino Acids | Function |
|--------|-------------|----------|
| N-terminal | 1-30 | Cytoplasmic exposure, initial protein interactions |
| Membrane anchor | 31-60 | peroxisomal membrane insertion |
| RING finger | 61-150 | E3 ubiquitin ligase activity, substrate recognition |
| Central loop | 151-250 | Protein-protein interactions |
| C-terminal | 251-335 | Quality control function |

The RING Finger Domain

The RING finger domain (C3H2C3-type) coordinates two zinc ions and is essential for PEX10's E3 ubiquitin ligase activity:

• Cys/His residues — Coordinate zinc ions for structural stability
• Substrate binding — Recognizes misfolded PTS1 proteins
• Ubiquitin transfer — Catalyzes ubiquitin transfer to substrates
• Complex formation — Works with PEX2 and PEX12 as E3 ligase complex

Protein-Protein Interactions

| Partner | Interaction Type | Functional Consequence |
|---------|-----------------|----------------------|
| PEX2 | Complex | E3 ubiquitin ligase complex formation |
| PEX12 | Complex | RING finger complex, substrate recognition |
| PEX5 | Substrate | Import receptor for PTS1 proteins |
| PEX3 | Docking | Peroxisomal membrane anchoring |
| PEX19 | Docking | Peroxisomal targeting |

Normal Physiological Functions

Peroxisome Biogenesis

PEX10 plays a central role in peroxisome biogenesis[@stehlik2020]:

Peroxisomal Matrix Protein Import

The peroxisomal targeting signal (PTS1) pathway:

Lipid Metabolism

Peroxisomes are essential for several lipid metabolic pathways:

| Pathway | Substrate | Product | Clinical Relevance |
|---------|-----------|---------|-------------------|
| β-oxidation | Very long-chain fatty acids (VLCFAs) | Acetyl-CoA | Elevated in ZSD, AD |
| Plasmalogen synthesis | Fatty alcohols | Plasmalogens | Myelin deficiency |
| Phytanic acid oxidation | Phytanic acid | Pristanic acid | Refsum disease |
| Bile acid synthesis | C27-sterols | Primary bile acids | Liver dysfunction |

Hydrogen Peroxide Metabolism

Peroxisomes contain key antioxidant enzymes:

• Catalase — Converts H₂O₂ to H₂O and O₂
• Urate oxidase — Uric acid metabolism
• D-amino acid oxidase — D-amino acid metabolism
• Peroxisomal glutathione peroxidase — Lipid peroxidation

Plasmalogen Synthesis

Plasmalogens (ether phospholipids) are essential for:

• Myelin formation — Major component of white matter
• Membrane fluidity — Influence neuronal membrane properties
• Signal transduction — Precursors for lipid mediators
• Antioxidant properties — Protect against oxidative damage

Expression Patterns

Tissue Distribution

PEX10 shows widespread expression with highest levels in peroxisome-rich tissues:

| Tissue | Expression Level | Notes |
|--------|-----------------|-------|
| Liver | Very high | Primary peroxisome function |
| Kidney | High | Peroxisomal metabolism |
| Brain | High | Neurons and glia |
| Skeletal muscle | Moderate | Energy metabolism |
| Heart | Moderate | Lipid metabolism |
| Lung | Low-Moderate | Metabolic function |

Brain Regional Distribution

Within the central nervous system:

| Region | Expression | Cell Type |
|--------|-----------|-----------|
| Cerebral cortex | High | Pyramidal neurons |
| Hippocampus | High | CA neurons, dentate gyrus |
| Cerebellum | High | Purkinje cells |
| Basal ganglia | Moderate | Medium spiny neurons |
| White matter | High | Oligodendrocytes |

Cellular Localization

• Neurons — Cytoplasmic, peroxisomal targeting
• Astrocytes — Peroxisomes for lipid metabolism
• Oligodendrocytes — High for myelin plasmalogens
• Microglia — Lower, inflammatory responses

Disease Associations

Zellweger Spectrum Disorders (ZSD)

PEX10 mutations cause a severe form of ZSD[@hille2023][@steinberg2004]:

Clinical Features

| System | Manifestation |
|--------|---------------|
| Neurological | Profound intellectual disability, hypotonia, seizures, developmental regression |
| Vision | Retinal degeneration, optic atrophy, cataracts |
| Hearing | Sensorineural hearing loss |
| Craniofacial | Characteristic dysmorphic features, high forehead, epicanthal folds |
| Hepatic | Hepatomegaly, cholestasis, liver dysfunction |
| Skeletal | Calcific stippling, vertebral anomalies |

Genotype-Phenotype Correlation

| Mutation Type | Severity | Phenotype |
|--------------|-----------|-----------|
| Null/nonsense | Severe | Classic Zellweger |
| Missense (RING) | Moderate | Neonatal ZSD |
| Missense (other) | Mild | Adult ZSD |
| Compound heterozygous | Variable | Spectrum |

Biochemical Abnormalities

• Elevated plasma VLCFAs (C26:0, C24:0)
• Decreased plasmalogens (PE, PC)
• Elevated phytanic acid
• Elevated pipecolic acid
• Reduced catalase activity

Alzheimer's Disease

Peroxisomal dysfunction is increasingly recognized in AD pathogenesis[@van2021][@federico2023]:

Evidence for Peroxisomal Involvement

| Finding | Evidence |
|---------|----------|
| Peroxisome number | Decreased in AD brain |
| Catalase activity | Reduced in AD cortex |
| VLCFAs | Elevated in AD plasma and brain |
| Plasmalogens | Decreased in AD white matter |
| PEX10 expression | Altered in AD |

Mechanistic Links

Potential Therapeutic Approaches

• Peroxisome proliferators — Activate peroxisome function
• VLCFA-lowering agents — Reduce toxic lipid accumulation
• Plasmalogen supplementation — Restore membrane composition
• Antioxidant therapy — Reduce oxidative damage

Parkinson's Disease

Peroxisomal dysfunction has been implicated in PD[@ibanez2022]:

Evidence

| Finding | Reference |
|---------|-----------|
| Peroxisome loss in PD substantia nigra | Ibanez et al., 2022 |
| PEX5 alterations in PD models | Published |
| VLCFAs elevated in PD CSF | Conference reports |
| Phytanic acid metabolism impaired | Case studies |

Mechanisms

• Dopaminergic neuron vulnerability — Peroxisomes critical for energy metabolism
• α-Synuclein interaction — Peroxisomal dysfunction enhances aggregation
• Mitochondrial cross-talk — Peroxisome-mitochondria coordination
• Neuroinflammation — Peroxisomal lipid mediators

Autism Spectrum Disorder

PEX10 and peroxisomal function have been linked to ASD:

| Evidence | Details |
|----------|---------|
| Genetic | Rare PEX10 variants in ASD patients |
| Biochemical | Altered VLCFAs in some ASD cases |
| Lipid metabolism | Peroxisomal function in synaptic membranes |
| Energy | Peroxisomal β-oxidation in neurons |

Aging and Age-Related Neurodegeneration

Peroxisomal function declines with age[@federico2023]:

• Reduced peroxisome number
• Decreased catalase activity
• Accumulation of very long-chain fatty acids
• Declining plasmalogen levels
• Increased oxidative stress

Therapeutic Implications

Small Molecule Approaches

| Strategy | Compound | Status |
|----------|----------|--------|
| PPARα agonists | Fibrates | FDA-approved, peroxisome proliferation |
| VLCFA reduction | Lorenzo's oil | Available for X-ALD |
| Plasmalogen precursors | DHA-ether phospholipids | Clinical trials |
| Antioxidants | Catalase mimetics | Preclinical |

Gene Therapy

• PEX10 gene delivery — AAV vectors for ZSD
• CRISPR-based approaches — Gene editing in development
• mRNA therapy — Direct protein replacement

Cell Therapy

• Stem cell transplantation — Hematopoietic or neural
• Organoid models — Drug testing platforms

Biomarker Potential

PEX10 and peroxisomal markers:

| Marker | Utility |
|--------|---------|
| Plasma VLCFAs | Diagnostic, monitoring |
| Red blood cell plasmalogens | Disease progression |
| Fibroblast peroxisome function | Diagnostic |
| PEX10 expression | Research |

Animal Models

Knockout Mouse Models

| Model | Phenotype | Relevance |
|-------|-----------|-----------|
| Pex10-/- | Embryonic lethal | Severe peroxisome loss |
| Pex10+/- | Partial peroxisome dysfunction | Mild ZSD model |
| Conditional KO | Brain-specific | Neurodegeneration studies |

Zebrafish Models

• Morpholino knockdowns — Developmental phenotypes
• CRISPR mutants — Peroxisome biogenesis defects

In Vitro Models

• Patient fibroblasts — Biochemical studies
• iPSC-derived neurons — Disease modeling
• Organoids — Brain development studies

Research Methods

Detection Techniques

| Method | Application |
|--------|-------------|
| Immunohistochemistry | Tissue localization |
| Western blot | Protein expression |
| Catalase activity | Functional assessment |
| EM | Peroxisome morphology |
| VLCFA quantification | Metabolic status |

Model Systems

| System | Use |
|--------|-----|
| Patient fibroblasts | Diagnostic, mechanism |
| Mouse models | In vivo studies |
| Yeast models | Basic mechanism |
| iPSC neurons | Human disease |

Interaction Network

Signaling Pathways

| Pathway | Modulation |
|---------|------------|
| PPARα signaling | Peroxisome proliferation |
| mTORC1 | Coordinate metabolism |
| Antioxidant response | Nrf2 pathway |
| Lipid synthesis | SREBP regulation |

Cross-Organelle Communication

| Organelle | Interaction |
|-----------|-------------|
| Mitochondria | β-oxidation coordination |
| ER | Lipid synthesis |
| Lysosomes | Degradation pathways |
| Nucleus | Transcriptional regulation |

Unanswered Questions

Related Pages

• [PEX1](/genes/pex1) — Most common ZSD gene
• [PEX2](/genes/pex2) — E3 ligase complex
• [PEX5](/genes/pex5) — PTS1 receptor
• [Zellweger Spectrum Disorders](/diseases/zellweger-spectrum-disorders)
• [Peroxisome Biogenesis](/mechanisms/peroxisome-biogenesis)
• [Alzheimer's Disease](/diseases/alzheimers-disease)
• [Parkinson's Disease](/diseases/parkinsons-disease)
• [Very Long-Chain Fatty Acids](/mechanisms/very-long-chain-fatty-acids-metabolism)
• [Plasmalogens and Myelin](/mechanisms/plasmalogen-synthesis-myelin)

External Links

• [NCBI Gene: PEX10](https://www.ncbi.nlm.nih.gov/gene/5199)
• [UniProt: O00391](https://www.uniprot.org/uniprot/O00391)
• [OMIM: 614863](https://omim.org/entry/614863)
• [Ensembl: ENSG00000103356](https://www.ensembl.org/Homo_sapiens/Gene/Summary?g=ENSG00000103356)

References