Age-dependent uptake and retrograde axonal transport of exogenous albumin and transferrin in rat motor neurons.

This study presents evidence for retrograde axonal transport of exogenous albumin and transferrin in adult brainstem motor neurons, whereas plasma proteins are not transported in neonatal motor neurons. The plasma protein uptake in motor neurons was dose-dependent, suggesting a nonspecific (fluid-phase) uptake mechanism. Further evidence for nonspecific uptake of exogenous transferrin in the motor neuron was found in the presence of transferrin receptor only on the soma and not on the axon terminal. The immunoreaction product of the exogenous plasma proteins was localized as perinuclear granules in association with the lysosomal system, as verified by staining for the lysosomal marker cathepsin D and by ultrastructural examinations. The results suggest that albumin and transferrin derived from hepatic synthesis gain access to motor neurons nonspecifically by retrograde axonal transport, whereas transferrin derived from intracerebral synthesis specifically gains access to motor neurons due to receptor-mediated uptake at the soma of the neuron. The lack of plasma proteins in developing motor neurons suggests that retrograde axonal transport of plasma proteins has no significance for developing axons. Plasma proteins have a potential for transporting toxic metals to motor neurons. Intraneuronal uptake of aluminum-transferrin either by nonspecific uptake in axon terminals or by receptor-mediated uptake at the soma may have a role in the pathogenesis of the motor neuron disease amyotrophic lateral sclerosis.