Scientists pinpoint molecular signal that drives and enables spinal cord repair

The findings, published today in Brain, could one day lead to new treatments which enhance this spontaneous repair mechanism by manipulating the neuregulin-1 signal.

Every year more than 130,000 people suffer traumatic spinal cord injury (usually from a road traffic accident, fall or sporting injury) and related healthcare costs are among the highest of any medical condition -- yet there is still no cure or adequate treatment.

Spinal cord injury has devastating consequences for muscle and limb function, but the central nervous system does possess some limited capacity to repair itself naturally.

Understanding what drives this repair mechanism could aid the development of new treatment strategies aimed at boosting the self-healing capacity of the injured spinal cord by taking advantage of 'tools' that the spinal cord already possesses.

For the first time researchers from King's and Oxford have identified one of these tools, neuregulin-1, which signals from the surface of damaged nerve fibres during a process called 'spontaneous remyelination.'

Spontaneous remyelination is a period of natural regeneration that happens in the weeks following a spinal cord injury. The process takes place as a result of damage to spinal nerve fibres which have lost their insulating 'myelin sheath'. This myelin sheath is crucial for efficient communication between the brain and the body.

However, this natural capacity for repair is not sufficient for full recovery and may account for the compromised function of surviving nerve fibres, which can affect balance, coordination and movement.

The researchers found that, in mice lacking the neuregulin-1 gene, spontaneous myelin repair was completely prevented and spinal nerve fibres remained demyelinated (i.e. unable to send nerve signals along the spinal cord).

They also discovered that mice without neuregulin-1 showed worse outcomes after spinal cord injury compared to mice with the gene intact, particularly in walking, balance and coordinated movements.

Not only did neuregulin-1 drive spontaneous remyelination, but it also served as a molecular switch for cells within the spinal cord to transform themselves into cells with remyelinating capacity. This is unusual, according to the researchers, because the 'Schwann' cells with new remyelinating capacity normally only myelinate nerve fibres in the peripheral nervous system -- not the central nervous system, as observed here.

Elizabeth Bradbury, Professor of Regenerative Medicine & Neuroplasticity at the Institute of Psychiatry, Psychology & Neuroscience (IoPPN), King's College London, and Medical Research Council Senior Fellow, said: 'Spinal cord injury could happen to anyone, at any time. In an instant your life could change and you could lose all feeling and function below the level of the injury.

'Existing treatments are largely ineffective, so there is a pressing need for new regenerative therapies to repair tissue damage and restore function after spinal cord injury.

'These new findings advance our understanding of the molecular mechanisms which may orchestrate the body's remarkable capacity for natural repair.'

Professor Bradbury added: 'By enhancing this spontaneous response, we may be able to significantly improve spinal cord function after injury. Our research also has wider implications for other disorders of the central nervous system which share this demyelinating pathology, such as multiple sclerosis.'

Dr Katalin Bartus, also from the IoPPN at King's College London, said: 'We hope this work will provide a platform for future research, in which it will be important to test how enhancing levels of neuregulin-1 will improve functional outcome after spinal cord injury.'