The membrane attack complex of the complement system is essential for rapid Wallerian degeneration.

The complement (C) system plays an important role in myelin breakdown during Wallerian degeneration (WD). The pathway and mechanism involved are, however, not clear. In a crush injury model of the sciatic nerve, we show that C6, necessary for the assembly of the membrane attack complex (MAC), is essential for rapid WD. At 3 d after injury, pronounced WD occurred in wild-type animals, whereas the axons and myelin of C6-deficient animals appeared intact. Macrophage recruitment and activation was inhibited in C6-deficient rats. However, 7 d after injury, the distal part of the C6-deficient nerves appeared degraded. As a consequence of a delayed WD, more myelin breakdown products were present than in wild-type nerves. Reconstitution of the C6-deficient animals with C6 restored the wild-type phenotype. Treatment with rhC1INH (recombinant human complement 1 inhibitor) blocked deposition of activated C-cleaved products after injury. These experiments demonstrate that the classical pathway of the complement system is activated after acute nerve trauma and that the entire complement cascade, including MAC deposition, is essential for rapid WD and efficient clearance of myelin after acute peripheral nerve trauma.

Deficiency of the complement regulator CD59a exacerbates Wallerian degeneration.

The complement system is implicated in Wallerian degeneration (WD). We have previously shown that the membrane attack complex (MAC), the terminal activation product of the complement cascade, mediates rapid axonal degradation and myelin clearance during WD after peripheral nerve injury. In this study we analyzed the contribution of CD59a, a cell membrane negative regulator of the MAC, to WD. Following injury, the level of MAC deposition was higher in the CD59a deficient mice than wildtypes whereas the residual axonal content was lower in CD59a deficient mice than wildtypes, strongly implicating MAC as a determinant of axonal damage during WD. The number of endoneurial macrophages was significantly higher in CD59a deficient mice compared to wildtypes at 1 day post-injury. These findings are relevant to the understanding of the mechanisms of axon loss in injury and disease.

Complement inhibition accelerates regeneration in a model of peripheral nerve injury.

Complement (C) activation is a crucial event in peripheral nerve degeneration but its effect on the subsequent regeneration is unknown. Here we show that genetic deficiency of the sixth C component, C6, accelerates axonal regeneration and recovery in a rat model of sciatic nerve injury. Foot-flick test and Sciatic Function Index monitored up to 5 weeks post-injury showed a significant improvement of sensory and motor function in the C6 deficient animals compared to wildtypes. Retrograde tracing experiments showed a significantly higher number of regenerated neurons at 1 week post-injury in C6 deficient rats than wildtypes. Pathology showed improved nerve regeneration in tibials of C6 deficient animals compared to wildtypes. Reconstitution with purified human C6 protein re-established the wildtype phenotype whereas pharmacological inhibition of C activation with soluble C receptor 1 (sCR1) facilitated recovery and improved pathology similarly to C6 deficient animals. We suggest that a destructive C-mediated event during nerve degeneration hampers the subsequent regenerative process. These findings provide a rationale for the testing of anti-complement agents in human nerve injury.

Soluble complement receptor 1 protects the peripheral nerve from early axon loss after injury.

Complement activation is a crucial early event in Wallerian degeneration. In this study we show that treatment of rats with soluble complement receptor 1 (sCR1), an inhibitor of all complement pathways, blocked both systemic and local complement activation after crush injury of the sciatic nerve. Deposition of membrane attack complex (MAC) in the nerve was inhibited, the nerve was protected from axonal and myelin breakdown at 3 days after injury, and macrophage infiltration and activation was strongly reduced. We show that both classical and alternative complement pathways are activated after acute nerve trauma. Inhibition of the classical pathway by C1 inhibitor (Cetor) diminished, but did not completely block, MAC deposition in the injured nerve, blocked myelin breakdown, inhibited macrophage infiltration, and prevented macrophage activation at 3 days after injury. However, in contrast to sCR1 treatment, early signs of axonal degradation were visible in the nerve, linking MAC deposition to axonal damage. We conclude that sCR1 protects the nerve from early axon loss after injury and propose complement inhibition as a potential therapy for the treatment of diseases in which axon loss is the main cause of disabilities.