Slow axoplasmic transport under scrutiny

The origin of axoplasmic proteins is central for the biology of axons. For over fifty years axons have been considered unable to synthesize proteins and that cell bodies supply them with proteins by a slow transport mechanism. To allow for prolonged transport times, proteins were assumed to be stable, i.e., not degraded in axons. These are now textbook notions that configure the slow transport model (STM). The aim of this article is to cast doubts on the validity of STM, as a step toward gaining more understanding about the supply of axoplasmic proteins. First, the stability of axonal proteins claimed by STM has been disproved by experimental evidence. Moreover, the evidence for protein synthesis in axons indicates that the repertoire is extensive and the amount sizeable, which disproves the notion that axons are unable to synthesize proteins and that cell bodies supply most axonal proteins. In turn, axoplasmic protein synthesis gives rise to the metabolic model (MM). We point out a few inconsistencies in STM that MM redresses. Although both models address the supply of proteins to axons, so far they have had no crosstalk. Since proteins underlie every conceivable cellular function, it is necessary to re-evaluate in-depth the origin of axonal proteins. We hope this will shape a novel understanding of the biology of axons, with impact on development and maintenance of axons, nerve repair, axonopathies and plasticity, to mention a few fields.

Inmunohistoquímica de los cambios degenerativos del sistema nervioso central en paraparesias esp sticas asociadas al virus linfotrópico humanoTtipol(HTLV-l) / Immunohistochemistry of degenerative changes in the central nervous system in spastic paraparesis associated to human T lymphotropic virus type I (HTLV-I)

Background: Human T lymphotropic virus type I is associated with tropical spastic paraparesis, that is a chronic and progressive disease which damages specially the cortiespinal tracts. The pathogenesis of this degenerative process remains unknown. Aim: To identify histopathological aspects that could suggest a pathogenic hypothesis we studied immunohistochemical features in spinal cords obtained from patients that died due to progressive spastic paraparesis. Patients and Methods: Five males and five females, who died between 1990 and 2000, with a mean age of 52 years and mean disease duration of 8.6, were studied. All had a complete clinical and virological diagnosis. Samples were obtained from the frontal motor cortex and spinal cord (cervical, dorsal and lumbar segments), were fixed in formol (10 percent), included in paraffin, and stained with Haematoxylin and Luxol-fast-blue. Immunohistochemical study was made with anti-neurofilament antibodies 1:100 (M0762, DAKO), anti-APP 1:20 (Rabbit Pre Amyloid protein 51-2700 ZYMED), anti-tau 1:100 (A0024DAKO) and anti-ubiquitine 1:50 (NCL UBIQm Novocastra). Results: All cases had demyelinization and axonal loss in the cortico-spinal tracts; distal and segmental demyelinization of Goll tract; axonal thickening, amyloid precursor protein deposits in the white matter; tau protein aggregation in the spinal cord oligodendrocytes; axonal ubiquitination of sensitive and motor tracts, and subcortical white matter. Neurona! injury was absent. Conclusions: The systematic damage of motor and sensitive tracts of the spinal-cord and the absence of neurona! damage, defines a degenerative process limited to axons. This central axonopathie could be caused by a disturbance of axoplasmic transport.

Developmental strategies underlyng the elaboration of cortical circuits

The mammalian cerebral cortex is organized in layers and columns, which are reflected in the local intrinsic connections and in the projections to and from the cortex. It is well established that the development of the columnar architecture is under the influence of neuronal activity, but little is known about the mechanisms that control the laminar specificity of cortical circuits. Here we review some recent studies which show that diffusible and membrane-associated molecules provide sufficient information to reconstruct layer-specific intrinsic and extrinsic cortical circuits under in vitro conditions.

Fine structure of sensore nerve endings and SEM study of the palatine mucosa of rats

Se estudió la estructura fina de las terminaciones sensoriales nerviosas, a través de microscopÍa electrónica de barrido de la superficie celular y del tejido conectivo epitelial. La superficie epitelial de la mucosa palatina de la rata mostró una superficie de células planas y algunas elevaciones de la mucosa. La superficie de la célula está caracterizada por la presencia de numerosos micropliegues. Especímenes tratados con HCL-colagenasa revelaron que la interfase del tejido conectivo-epitelial presentaba varios surcos, circulares y alargados. Las pequeñas proyecciones citoplasmáticas son claramente visibles. Las terminaciones nerviosas libres bajo el epitelio se encuentran en el pequeño tejido conectivo papilar y están circundados por una delgada lámina de células de Schwann. El axoplasma mostró numerosas mitocondrias, neurofilamentos cuerpos multicorpustulares y pequeñas protusiones citoplasmáticas