Muscle and neural isoforms of agrin increase utrophin expression in cultured myotubes via a transcriptional regulatory mechanism.

Duchenne muscular dystrophy is a prevalent X-linked neuromuscular disease for which there is currently no cure. Recently, it was demonstrated in a transgenic mouse model that utrophin could functionally compensate for the lack of dystrophin and alleviate the muscle pathology (Tinsley, J. M., Potter, A. C., Phelps, S. R., Fisher, R., Trickett, J. I., and Davies, K. E. (1996) Nature 384, 349-353). In this context, it thus becomes essential to determine the cellular and molecular mechanisms presiding over utrophin expression in attempts to overexpress the endogenous gene product throughout skeletal muscle fibers. In a recent study, we showed that the nerve exerts a profound influence on utrophin gene expression and postulated that nerve-derived trophic factors mediate the local transcriptional activation of the utrophin gene within nuclei located in the postsynaptic sarcoplasm (Gramolini, A. O., Dennis, C. L., Tinsley, J. M., Robertson, G. S., Davies, K. E, Cartaud, J., and Jasmin, B. J. (1997) J. Biol. Chem. 272, 8117-8120). In the present study, we have therefore focused on the effect of agrin on utrophin expression in cultured C2 myotubes. In response to Torpedo-, muscle-, or nerve-derived agrin, we observed a significant 2-fold increase in utrophin mRNAs. By contrast, CGRP treatment failed to affect expression of utrophin transcripts. Western blotting experiments also revealed that the increase in utrophin mRNAs was accompanied by an increase in the levels of utrophin. To determine whether these changes were caused by parallel increases in the transcriptional activity of the utrophin gene, we transfected muscle cells with a 1. 3-kilobase pair utrophin promoter-reporter (nlsLacZ) gene construct and treated them with agrin for 24-48 h. Under these conditions, both muscle- and nerve-derived agrin increased the activity of beta-galactosidase, indicating that agrin treatment led, directly or indirectly, to the transcriptional activation of the utrophin gene. Furthermore, this increase in transcriptional activity in response to agrin resulted from a greater number of myonuclei expressing the 1.3-kilobase pair utrophin promoter-nlsLacZ construct. Deletion of 800 base pairs 5' from this fragment decreased the basal levels of nlsLacZ expression and abolished the sensitivity of the utrophin promoter to exogenously applied agrin. In addition, site-directed mutagenesis of an N-box motif contained within this 800-base pair fragment demonstrated its essential contribution in this regulatory mechanism. Finally, direct gene transfer studies performed in vivo further revealed the importance of this DNA element for the synapse-specific expression of the utrophin gene along multinucleated muscle fibers. These data show that both muscle and neural isoforms of agrin can regulate expression of the utrophin gene and further indicate that agrin is not only involved in the mechanisms leading to the formation of clusters containing presynthesized synaptic molecules but that it can also participate in the local regulation of genes encoding synaptic proteins. Together, these observations are therefore relevant for our basic understanding of the events involved in the assembly and maintenance of the postsynaptic membrane domain of the neuromuscular junction and for the potential use of utrophin as a therapeutic strategy to counteract the effects of Duchenne muscular dystrophy.

Chick wing innervation. III. Formation of axon collaterals in developing peripheral nerves.

Axon navigation during vertebrate limb innervation has been shown to be associated with position-dependent changes in size and complexity of the axon growth cones, and sometimes with bifurcation of terminal growth cones and axon branching (Hollyday and Morgan-Carr, companion paper). We have further examined axon branching and asked whether it extends to the projection of collaterals to different nerves. Injections of horseradish peroxidase or Dil were made into individual peripheral nerves in the wings of chick embryos at stages 28-35, and the trajectories of solidly labeled axons were traced proximally from the injection site in tissue sections. During stages when the peripheral nerves were first forming in the shoulder region, collaterals of retrogradely labeled axons were frequently observed to project into uninjected nerves proximal to the injection site. These two-nerve collaterals were formed by a small percentage of axons in a high percentage of the embryos studied and could occur in both motor and sensory axons. Two-nerve collateral projections were observed between nerves separated along both the proximodistal and anteroposterior axes of the limb, but they were limited in spatial extent to nerves supplying adjacent limb regions and were never seen between nerves projecting to widely disparate regions of the limb. Collaterals were not seen at the plexus projecting to both dorsal and ventral pathways. The apparent frequency of two-nerve collaterals was found to decline progressively from stage 28-29 to stage 32; no two-nerve collaterals were seen in the proximal wing at stage 33 and older. The mechanism of their elimination is presently unknown.(ABSTRACT TRUNCATED AT 250 WORDS)

The ability of agrin to cluster AChRs depends on alternative splicing and on cell surface proteoglycans.

Agrin, which induces acetylcholine receptor (AChR) clustering at the developing neuromuscular synapse, occurs in multiple forms generated by alternative splicing. Some of these isoforms are specific to the nervous system; others are expressed in both neural and nonneural tissues, including muscle. We have compared the AChR clustering activity of agrin forms varying at each of the three identified splicing sites, denoted x, y, and z. Agrin isoforms were assayed by applying either transfected COS cells, with agrin bound to their surfaces, or soluble agrin to myotubes of the C2 muscle line, or of two variant lines having defective proteoglycans. Dramatic differences in activity were seen between z site isoforms and lesser differences between y site isoforms. The most active agrin forms contained splicing inserts of 4 amino acids at the y site and 8 amino acids at the z site. These forms are found exclusively in neural tissue. All forms were active on C2 myotubes in cell-attached assays, but muscle forms were less active than neural forms. AChR clustering activity of all agrin forms was decreased when assayed on the proteoglycan-deficient lines, suggesting that proteoglycans may help mediate the action of agrin. As neural agrin forms are more active than muscle forms, they are likely to play a primary role in synaptogenesis.

Motor innervation of dorsoventrally reversed wings in chick/quail chimeric embryos.

In the limb plexus, motor axons destined for limb muscles diverge along separate pathways to innervate muscles derived from either the dorsal or ventral premuscle masses. We have examined the axonal guidance cues involved in this initial, specific pathway choice at the plexus by making dorsoventral (D/V) limb bud reversals prior to innervation. Chick/quail chimeras were used to determine the proximodistal level of the reversal in tissue sections. The specificity of the projections to dorsal or ventral nerve trunks was assessed by retrograde HRP labeling at ages prior to motoneuron death. Axons corrected for the reversal when the level of the graft was proximal to the plexus, and when the reversed limb and its gross nerve pattern were normal. If all of these conditions were not satisfied, aberrant innervation patterns were observed. Axonal trajectories were analyzed within the host tissue, at the host-graft border, and within rotated tissue to determine where along the pathway guidance cues might be located. Special attention was given to cases in which axons compensated for the reversal to project in accord with the positions of their soma in the lateral motor column. In these correcting cases, after normal D/V sorting in the spinal nerves of the host, motor axons altered their trajectories upon entering rotated graft tissue as they approached and traversed the plexus. Because corrections were within rotated tissue and not proximal to it, the D/V pathway cues are unlikely to be long-range target-derived signals, but rather appear to be closely associated with positional information in the plexus region and also more proximally in the tissue surrounding the distal spinal nerves.

Peripheral competition in the control of sensory neuron numbers in Xenopus frogs reared with a single bilaterally innervated hindlimb.

Sensory neurons were counted in the hind-limb innervating spinal ganglia on both sides of juvenile Xenopus frogs which, as tadpoles, had had one hind limb bud amputated prior to innervation, and a channel made to allow innervation of the remaining limb bud from both sides. The total number of sensory neurons surviving on the two sides approximated the number on one side of normal frogs, the ipsilateral and contralateral numbers being negatively correlated. These effects differ markedly from the effects on motoneuron numbers, suggesting different control mechanisms of cell death in the two neuronal classes.