Progesterone Effects on Neuronal Ultrastructure and Expression of Microtubule-associated Protein 2 (MAP2) in Rats with Acute Spinal Cord Injury

(1) Following acute spinal cord injury, progesterone modulates several molecules essential for motoneuron function, although the morphological substrates for these effects are unknown. (2) The present study analyzed morphological changes in motoneurons distal to the lesion site from rats with or without progesterone treatment. We employed electron microscopy to study changes in nucleus and cytoplasm and immunohistochemistry for the microtubule-associated protein 2 (MAP2) for changes in cytoskeleton. (3) After spinal cord injury, the nucleoplasm appeared more finely dispersed resulting in reduced electron opacity and the nucleus adopted an eccentric position. Changes of perikarya included dissolution of Nissl bodies and dissociation of polyribosomes (chromatolysis). After progesterone treatment for 3 days, the deafferented motoneurons now presented a clumped nucleoplasm, a better-preserved rough endoplasmic reticulum and absence of chromatolysis. Progesterone partially prevented development of nuclear eccentricity. Whereas 50% of injured motoneurons showed nuclear eccentricity, only 16% presented this phenotype after receiving progesterone. Additionally, injured rats showed reduced immunostaining for MAP2 in dendrites, pointing to cytoskeleton abnormalities, whereas progesterone treatment attenuated the injury-induced loss of MAP2. (4) Our data indicated that progesterone maintained in part neuronal ultrastructure, attenuated chromatolysis, and preclude the loss of MAP2, suggesting a protective effect during the early phases of spinal cord injury.     

Outer segment growth and periciliary vesicle turnover in developing photoreceptors of Xenopus laevis

Summary Cytoskeletal alterations in the cytoplasm of chromatolytic neurons of the dorsal root ganglia were studied in chickens after transection of the sciatic nerves. These studies were carried out using cryofixation with a nitrogencooled propane jet. By this method, the morphological complexity of the cytoskeleton in normal perikarya and cell processes can be visualized. The cytoskeleton of the dorsal root ganglion cells (DRG) is composed of an intricate network of microtubules, neurofilaments and microfilaments. The membrane-bounded cell organelles, as well as the cell nucleus and the plasmalemma, are linked to the microtubules and neurofilaments by microfilaments (or crosslinkers). As a result of the transection of the axon, chromatolysis takes place, characterized by dislocation of cell organelles, eccentric position of the nucleus and dispersion of the parallel cisternae of the rough endoplasmic reticulum throughout the cytoplasm. This characteristic phenomenon coincides with a regression of the neurocytoskeletal network. The neurofilaments and microtubules become shorter, and the microfilaments are replaced by strands of globular or granular material. The temporary regression of the microfilaments leads to a dispersion of the cell organelles. During the remodelling of the cytoskeletal structures, proliferation of the neurofilaments in the regenerating neurons may occasionally be observed. These results show that the cytoskeletal structures are responsible not only for the preservation of cell shape, but also for the maintenance of the normal distributional pattern (location and mobility) of the intracellular components.     

Orthograde, Retrograde, and Turnaround Axonal Transport of Dopamine-β-Hydroxylase: Response to Axonal Injury

Reversal of the direction (turnaround) of orthograde axonal transport of dopamine-beta-hydroxylase (DBH) activity was studied at a ligature placed on rat sciatic nerve. DBH was allowed to accumulate at a ligature in vivo for selected intervals, at which time a second ligature was placed proximal to the first and turnaround transport measured just distal to the second tie after incubation in vivo or in vitro. Orthograde accumulation of DBH activity proximal to a ligature peaked at 2 days, and then rapidly decreased as a result of turnaround transport and injury-induced reduction of orthograde transport. Destruction of postganglionic sympathetic axon terminals in vivo with 6 hydroxydopamine resulted in a decrease in orthograde transport similar to that seen after axotomy and turnaround at or proximal to the site of chemical injury. Turnaround transport of DBH in vitro was blocked by incubation in the cold and in the presence of NaCN and vinblastine. Orthograde transport of DBH appeared to reverse direction within a few millimeters of a ligature.     

Retrograde axon reaction following section of asynaptic nerve fibers

Summary The asynaptic spinal neurons of the gymnotid teleost Sternarchus albifrons show several distinct characteristics of the retrograde reaction of the perikaryon (which corresponds to chromatolysis in mammals) following axotomy. Nuclei of affected cells are characteristically eccentric. Large bundles of neurofilaments, never seen in normal perikarya of these cells, become prominent following axotomy. There is a marked increase in the number and size of dense bodies in the affected perikarya. Large arrays of parallel rough endoplasmic reticulum, never seen in normal cells, are frequent in the axotomized neurons. These results demonstrate that disconnection from synaptic terminals is not a necessary condition for the retrograde reaction of the perikaryon following axotomy.