INTERDEPENDENT CHANGES OF THE AXON AND SCHWANN CELL IN THE PROCESS OF REACTIVE REMODELING OF A MYELINATED NERVE FIBER
T. N. Kokurina , O. S. Sotnikov , S. A. Novakovskaya , A. S. Yegorov , R. V. Kozhevetz , S. D. Solnuschkin , V. N. Chikhman
Morphology ›› 2013, Vol. 143 ›› Issue (2) : 035 -042.
INTERDEPENDENT CHANGES OF THE AXON AND SCHWANN CELL IN THE PROCESS OF REACTIVE REMODELING OF A MYELINATED NERVE FIBER
Using the inverted phase-contrast microscope, the living undamaged frog sciatic nerve fibers and the fibers mechanically injured to varying degrees, were studied. It was found that the swelling of myelin incisures (MI) (of Schmidt–Lanterman) occured according to the principles similar to those controlling the changes of the myelin gap (node of Ranvier) and depended on the swelling of a Schwann cell (SC) perikaryon. It was detected that this was a single process, which which could be united in a complex of nonspecific changes of a myelinated nerve fiber. It was also demonstrated that under the action of mechanical injury and hypotonic solution, swelling of MI, nodes of Ranvier and SC perikaryon occurred without modifications of outer fiber diameter, due to the pronounced local axon thinning. Electron microscopic study of the cytoskeletal axonal structures showed that there was not a simple local contraction of an axon, but a significant local increase in the density of cytoskeletal components of the axoplasm (by 200–275%). Reactive reversible remodeling of a myelinated fiber suggests a new type of interaction between the axon and SC, the mechanism of reversible translocation of liquid axoplasmic fraction to the glial cell cytoplasm.
myelinated fiber / myelin (Schmidt-Lanterman) incisures / node of Ranvier / Schwann cell perikaryon / water exchange in the fiber
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