RT Journal Article
SR Electronic
T1 Neural pathway constraints in the motor innervation of the chick hindlimb following dorsoventral rotations of distal limb segments
JF The Journal of Neuroscience
JO J. Neurosci.
FD Society for Neuroscience
SP 1226
OP 1233
DO 10.1523/JNEUROSCI.03-06-01226.1983
VO 3
IS 6
A1 V Whitelaw
A1 M Hollyday
YR 1983
UL http://www.jneurosci.org/content/3/6/1226.abstract
AB Several studies have demonstrated that motor axons can discriminate between dorsally and ventrally derived muscles. In this paper we present evidence that (1) the pathway axons take in the limb constrain their access to either dorsally or ventrally derived muscles, and therefore (2) the axon's ability to discriminate between dorsal and ventral is expressed already at the level of pathway selection into the limb. Surgically manipulated hindlimbs were produced consisting of a normal host thigh connected to a dorsoventrally rotated calf or to rotated and duplicated donor limb segments. The limb rotations were done distal to the level at which axons select a dorsally or ventrally destined pathway through the limb, such that at the level of the rotation, axons in each nerve were confronted with the opposite-from- normal set of muscles. In this situation, the relative influence of pathway availability versus dorsal/ventral muscle recognition could be assessed. The innervation of rotated limb segments was, in all cases, opposite from normal. Motoneurons which normally innervate dorsal muscles innervated ventrally derived muscles that had been rotated into a dorsal position. Likewise, normally ventrally destined axons served dorsal muscles in the rotated segments. Thus, motor axons did not alter their distal path to reach their normal set of muscles. While these results do not rule out intrinsic dorsal/ventral differences between muscles, they do demonstrate that muscle surface recognition is not necessary to account for dorsal/ventral discrimination in the innervation of normal, supernumerary, or duplicated limbs, nor is it sufficient to account for the innervation of rotated limb segments. These results also indicate that pathway guidance cues are an important influence on innervation patterns.