The evolutionary demand for rapid nerve impulse conduction led to the process of myelinationdependent organization of axons into distinct molecular domains. These domains include the node of Ranvier flanked by highly specialized paranodal domains where myelin loops and axolemma orchestrate the axoglial septate junctions. These junctions are formed by interactions between a glial isoform of neurofascin (Nfasc NF155 ) and axonal Caspr and Cont. Here we report the generation of myelinating glia-specific Nfasc NF155 null mouse mutants. These mice exhibit severe ataxia, motor paresis, and death before the third postnatal week. In the absence of glial Nfasc NF155 , paranodal axoglial junctions fail to form, axonal domains fail to segregate, and myelinated axons undergo degeneration. Electrophysiological measurements of peripheral nerves from Nfasc NF155 mutants revealed dramatic reductions in nerve conduction velocities. By using inducible PLP-CreER recombinase to ablate Nfasc NF155 in adult myelinating glia, we demonstrate that paranodal axoglial junctions disorganize gradually as the levels of Nfasc NF155 protein at the paranodes begin to drop. This coincides with the loss of the paranodal region and concomitant disorganization of the axonal domains. Our results provide the first direct evidence that the maintenance of axonal domains requires the fence function of the paranodal axoglial junctions. Together, our studies establish a central role for paranodal axoglial junctions in both the organization and the maintenance of axonal domains in myelinated axons. The anatomical organization of myelinated axons into distinct molecular domains is the basis for rapid propagation of action potentials in a saltatory manner (Hartline and Colman, 2007). Although the signal transduction mechanisms that underlie the axonal organization into specific domains (i.e., the node, the paranode, the juxtaparanode, and the internode) are poorly understood, considerable progress has been made in identifying key molecular components within these axonal domains. The paranodal region is unique in its organization and ultrastructural characteristics and contains specialized axoglial junctions referred to as the paranodal axoglial septate junctions, which resemble the ladder-like invertebrate septate junctions (Einheber et al., 1997;Pedraza et al., 2001; Banerjee et al., 2006a, b). Three major paranodal proteins have been identified: Caspr or paranodin (Einheber et al., 1997;Menegoz et al., 1997;Peles et al., 1997;Bhat et al., 2001), and a GPI-anchored neural cell adhesion molecule Contactin (Cont;Berglund et al., 1999;Boyle et al., 2001) on the axonal side, and the 155-kDa neurofascin isoform (Nfasc NF155 ) on the glial side (Tait et al., 2000;Charles et al., 2002). Although Nfasc NF155 is the only known glial paranodal protein, many proteins expressed in myelinating glia are required at some level in the formation and/or stability of the paranodal junctions (Coetzee et al., 1996;Griffiths et al., 1998;Ishibashi et al., 2002; LappeSie...
