The Role of the VPS35 Gene in Parkinson’s Disease

hotsiagoodman
October 28, 2024

The Parkinson’s Protocol™ By Jodi Knapp Parkinson’s disease cannot be eliminated completely but its symptoms can be reduced, damages can be repaired and its progression can be delayed considerably by using various simple and natural things. In this eBook, a natural program to treat Parkinson’s disease is provided online. it includes 12 easy steps to repair your body and reduce the symptoms of this disease. 

The Role of the VPS35 Gene in Parkinson’s Disease

The VPS35 (Vacuolar Protein Sorting 35) gene plays a significant role in the pathogenesis of Parkinson’s disease (PD), particularly in late-onset and familial cases. VPS35 is part of the retromer complex, which is involved in protein sorting and trafficking within cells, particularly in recycling proteins from endosomes back to the trans-Golgi network or the cell surface. Here’s an overview of the role of the VPS35 gene in Parkinson’s disease:

1. Genetic Overview

  • Location: The VPS35 gene is located on chromosome 16q11.2.
  • Mutations: Mutations in VPS35 have been linked to late-onset familial Parkinson’s disease. The most notable mutation associated with PD is the D620N mutation, which impairs the function of the VPS35 protein.

2. Function of VPS35

  • Protein Recycling: VPS35 is a critical component of the retromer complex, which facilitates the recycling of proteins from endosomes back to the plasma membrane or the trans-Golgi network. This process is essential for maintaining cellular homeostasis and function.
  • Neurotransmitter Transport: VPS35 is involved in the sorting and trafficking of key proteins, including those associated with neurotransmitter signaling, which are vital for proper neuronal communication and function.
  • Cellular Homeostasis: By ensuring that proteins are correctly trafficked and recycled, VPS35 helps maintain cellular homeostasis and prevent the accumulation of misfolded or damaged proteins.

3. Mechanisms of Dysfunction in VPS35

  • Impaired Protein Trafficking: Mutations in VPS35, such as D620N, lead to dysfunctional protein sorting and trafficking, resulting in the accumulation of misfolded proteins and impaired synaptic function. This dysfunction can contribute to neuronal death and the progression of Parkinson’s disease.
  • Impact on Alpha-Synuclein: VPS35 dysfunction has been implicated in the accumulation of alpha-synuclein, a key pathological hallmark of Parkinson’s disease. Mismanagement of protein recycling pathways may exacerbate the aggregation of alpha-synuclein, leading to neurotoxicity.

4. Clinical Implications

  • Phenotype of VPS35-Related PD: Individuals with VPS35 mutations typically present with late-onset Parkinson’s disease, often after the age of 50. Symptoms include bradykinesia, rigidity, and postural instability, similar to those seen in other forms of PD.
  • Disease Progression: The clinical features and progression of VPS35-related PD can be variable, but it generally follows a similar trajectory to sporadic cases of Parkinson’s disease.

5. Diagnosis and Genetic Testing

  • Genetic Testing: Identifying mutations in the VPS35 gene is important for diagnosing familial forms of Parkinson’s disease, particularly in late-onset cases. Genetic counseling is critical to help affected individuals and their families understand the implications of test results.
  • Screening Recommendations: Genetic testing for VPS35 mutations may be recommended for individuals with a family history of Parkinson’s disease, especially when combined with early-onset or atypical presentations.

6. Therapeutic Implications

  • Targeting Protein Trafficking: Research into the role of VPS35 in protein trafficking opens avenues for therapeutic interventions aimed at restoring normal protein sorting and recycling. Enhancing the function of the retromer complex could help alleviate the effects of VPS35 mutations.
  • Potential Drug Development: There is ongoing research to identify compounds that may enhance VPS35 activity or improve retromer function, offering potential therapeutic strategies for individuals with VPS35-related Parkinson’s disease.

7. Research and Future Directions

  • Ongoing Research: Continued studies aim to elucidate the precise mechanisms by which VPS35 mutations lead to neurodegeneration in Parkinson’s disease. Understanding these pathways can inform potential therapeutic interventions.
  • Animal Models: Animal models with VPS35 mutations are being utilized to study disease mechanisms and test new therapies, contributing to our understanding of the role of VPS35 in PD.

8. Conclusion

The VPS35 gene plays a crucial role in the pathogenesis of Parkinson’s disease, particularly through its involvement in protein sorting and trafficking within cells. Mutations in VPS35 are associated with late-onset familial PD, highlighting the importance of genetic factors in the disease. Understanding the molecular mechanisms associated with VPS35 can guide the development of targeted therapies and improve outcomes for individuals affected by Parkinson’s disease. As research progresses, the focus on VPS35 continues to be a promising area for discovering new treatments and insights into the complex nature of PD.


The Parkinson’s Protocol™ By Jodi Knapp Parkinson’s disease cannot be eliminated completely but its symptoms can be reduced, damages can be repaired and its progression can be delayed considerably by using various simple and natural things. In this eBook, a natural program to treat Parkinson’s disease is provided online. it includes 12 easy steps to repair your body and reduce the symptoms of this disease.