In situ structural basis of human axonopathies

The cryoNERVE project aims to develop cryo-electron tomography workflows to analyze native nerve tissues, enhancing understanding of axonopathies and improving diagnostic precision for diseases like HSP and CMT.

Subsidie

€ 1.986.750

2023

Projectdetails

Introduction

Myelinated axons propagate action potentials across otherwise unsurmountable distances. The overarching hypothesis of the cryoNERVE project is that membrane morphology crucially determines axonal health and function. Mutations in genes coding for membrane-shaping proteins are the major cause of familial axonopathies like hereditary spastic paraplegia (HSP) and Charcot-Marie-Tooth (CMT) disease.

Current Challenges

However, current techniques lack the resolution to ascertain the functions of these proteins and their pathological dysfunction within native nerves. At the same time, the highly specialized architecture of axons and their delicate interplay with glia can only be studied in situ.

Methodology

I have shown how cryo-electron tomography (cryo-ET) reveals the structural basis of neuronal function and disease within intact cells. However, cryo-ET imaging of tissues remains a major challenge. In cryoNERVE, we will develop cryo-ET workflows to image native nerve tissue at unprecedented resolution.

Research Focus

We will build on these advances to study the function of HSP and CMT proteins within truly physiological environments. Specifically, we will investigate:

How these proteins shape axonal organelles and their cross-talk.
The mechanisms allowing myelin sheath formation and neuron-glia communication.
The alterations introduced by axonopathy-causing mutants.

Future Directions

Lastly, we will pioneer the first cryo-ET analyses of vitrified human tissues. Frustratingly, peripheral nerve biopsies from axonopathy patients often cannot be diagnosed with existing methods.

Patient Examination

We will examine patient biopsies at molecular resolution and capitalize on our findings in flies and mice to reveal hitherto obscured pathological abnormalities.

Conclusion

Thus, cryoNERVE will provide a holistic molecular and structural basis of human axonopathies like HSP and CMT, pave the way for high-resolution analyses of native human tissues, and explore the potential of cryo-ET as a diagnostic tool with nanometric precision.

Financiële details & Tijdlijn

Financiële details

Subsidiebedrag	€ 1.986.750
Totale projectbegroting	€ 1.986.750

Tijdlijn

Startdatum	1-10-2023
Einddatum	30-9-2028
Subsidiejaar	2023

Partners & Locaties

Projectpartners

UNIVERSITAETSMEDIZIN GOETTINGEN - GEORG-AUGUST-UNIVERSITAET GOETTINGEN - STIFTUNG OEFFENTLICHEN RECHTSpenvoerder

Land(en)

Germany

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Projectdetails

Introduction

Current Challenges

Methodology

Research Focus

We will build on these advances to study the function of HSP and CMT proteins within truly physiological environments. Specifically, we will investigate:

How these proteins shape axonal organelles and their cross-talk.
The mechanisms allowing myelin sheath formation and neuron-glia communication.
The alterations introduced by axonopathy-causing mutants.

Future Directions

Lastly, we will pioneer the first cryo-ET analyses of vitrified human tissues. Frustratingly, peripheral nerve biopsies from axonopathy patients often cannot be diagnosed with existing methods.

Patient Examination

We will examine patient biopsies at molecular resolution and capitalize on our findings in flies and mice to reveal hitherto obscured pathological abnormalities.

Conclusion

Vergelijkbare projecten binnen European Research Council

Project	Regeling	Bedrag	Jaar	Actie
Axon Initial Segment plasticity: unravelling the mechanisms that control neuronal excitability This project aims to investigate the molecular mechanisms of axon initial segment plasticity in neurons and its implications for network homeostasis and diseases like Angelman Syndrome.	ERC Starting...	€ 1.494.740	2024	Details
In situ structural biology of human immune defence Developing super-resolution cryo-correlative light and electron microscopy (SRcryoCLEM) to enhance in situ structural biology for antibody-mediated immunity and therapeutic advancements.	ERC Consolid...	€ 1.976.553	2025	Details
Stress-induced structural and organizational adaptations of the cellular translation machinery This project aims to investigate how cellular strategies for maintaining protein homeostasis affect ribosome structure and organization under stress, using cryo-electron tomography for detailed insights relevant to neurodegenerative diseases.	ERC Starting...	€ 1.498.832	2023	Details
Deciphering Neurodegenerative Disease with fast 3D imaging & functional nanoscopy This project aims to investigate the biophysical mechanisms of protein aggregation in Huntington's Disease using advanced imaging techniques to enhance understanding of neurodegenerative processes.	ERC Starting...	€ 1.500.000	2024	Details
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ERC Starting...

Axon Initial Segment plasticity: unravelling the mechanisms that control neuronal excitability

This project aims to investigate the molecular mechanisms of axon initial segment plasticity in neurons and its implications for network homeostasis and diseases like Angelman Syndrome.

ERC Starting Grant

€ 1.494.740

2024

Details

ERC Consolid...

In situ structural biology of human immune defence

Developing super-resolution cryo-correlative light and electron microscopy (SRcryoCLEM) to enhance in situ structural biology for antibody-mediated immunity and therapeutic advancements.

ERC Consolidator Grant

€ 1.976.553

2025

Details

ERC Starting...

Stress-induced structural and organizational adaptations of the cellular translation machinery

ERC Starting Grant

€ 1.498.832

2023

Details

ERC Starting...

Deciphering Neurodegenerative Disease with fast 3D imaging & functional nanoscopy

This project aims to investigate the biophysical mechanisms of protein aggregation in Huntington's Disease using advanced imaging techniques to enhance understanding of neurodegenerative processes.

ERC Starting Grant

€ 1.500.000

2024

Details

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Advancing neuroscience by imaging BRAin Cortical fibErs

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ERC Starting Grant

€ 1.499.736

2025

Details

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Project	Regeling	Bedrag	Jaar	Actie
A synaptic mechanogenetic technology to repair brain connectivity Developing a mechanogenetic technology using magnetic nanoparticles to non-invasively regulate neural circuits for treating treatment-resistant brain disorders like stroke and epilepsy.	EIC Pathfinder	€ 3.543.967	2023	Details

EIC Pathfinder

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Developing a mechanogenetic technology using magnetic nanoparticles to non-invasively regulate neural circuits for treating treatment-resistant brain disorders like stroke and epilepsy.

EIC Pathfinder

€ 3.543.967

2023

Details