Synapse formation involves a large number of macromolecules found in both presynaptic nerve terminals and postsynaptic cells. Many of the molecules involved in synaptogenesis of the neuromuscular junction have been discovered through morphological localization to the synapse and functional cell culture assays, but their role in embryonic development has been more difficult to study. One of the best understood of these molecules is agrin, a synaptic extracellular matrix protein secreted by both motor neurons and muscle cells, that organizes the postsynaptic apparatus, including high-density aggregates of acetylcholine receptors (AChRs), at the neuromuscular junction. We tested the specific hypothesis that different agrin isoforms made by neurons and muscle cells contribute to agrin's synapse organizing activity in the embryo. Agrin isoforms were overexpressed by injecting synthetic RNA into Xenopus laevis embryos at the one- or two-cell stage. To mark cells containing agrin RNA, green fluorescent protein (GFP) RNA was coinjected. The relative area of muscle AChR aggregates was measured by confocal microscopy and image analysis in GFP-positive segments of injected embryos. Innervated regions of myotomal muscles were compared in animals injected with a mixture of agrin and GFP RNAs or with GFP RNA alone. Overexpression of COOH-terminal 95-kDa fragments of a rat agrin isoform made only by neurons (4,8) and the major isoform (0,0) made by muscle cells both increased AChR cluster area by 100-200%. Rat agrin protein was colocalized with AChR aggregates in innervated regions of muscles in injected embryos. These results show that agrin derived from both the nerve terminal and the muscle cell could contribute to synaptic differentiation at the embryonic neuromuscular junction. They further demonstrate the usefulness of overexpression by RNA injection as an assay for molecular function in embryonic synapse formation.
Context
Inhalation of asbestos or silica is associated with chronic and progressive diseases, including fibrosis, cancer, and increased risk of systemic autoimmunity. Because there is a need for treatment options for these diseases, a better understanding of their mechanistic etiologies is essential. While oxidative stress in macrophages is an early consequence of these exposures, it may also serve as a signaling mechanism involved in downstream immune dysregulation. The system
xc- exchange protein is induced by oxidative stress, and exchanges equimolor levels of extracellular cystine for intracellular glutamate. Cystine is subsequently reduced to cysteine, the rate-limiting precursor for glutathione synthesis.
Objective
As the primary transporter responsible for cystine/glutamate exchange on macrophages, system
xc- was hypothesized to be inducible in response to asbestos and silica, and to increase viability through protection from oxidative stress.
Results
When challenged with amphibole asbestos, but not crystalline silica, RAW 264.7 macrophages increased expression of xCT and the rate of cystine/glutamate exchange in sodium-free conditions. This upregulation was prevented with N-acetylcysteine, implicating oxidative stress. Cystine protected the macrophages from asbestos-induced oxidative stress and cell death, supporting the hypothesis that imported cystine was used for synthesis of cellular antioxidants. System
xc- inhibitors, glutamate and S-4-carboxyphenylglycine ((S)-4-CPG), significantly increased oxidative stress and cell death of asbestos-treated macrophages.
Conclusion
System
xc- plays a critical role in survival of macrophages exposed to asbestos, but not silica. These data demonstrate a very early difference in the cellular response to these silicates that may have important downstream implications in the pathologic outcome of exposure.
Agrin is an extracellular synaptic protein that organizes the postsynaptic apparatus, including acetylcholine receptors (AChRs), of the neuromuscular junction. The COOH-terminal portion of agrin has full AChR-aggregating activity in culture, and includes three globular domains, G1, G2, and G3. Portions of the agrin protein containing these domains bind to different cell surface proteins of muscle cells, including alpha-dystroglycan (G1-G2) and heparan sulfate proteoglycans (G2), whereas the G3 domain is sufficient to aggregate AChRs. We sought to determine whether the G1 and G2 domains of agrin potentiate agrin activity in vivo, as they do in culture. Fragments from the COOH-terminal of a neuronal agrin isoform (4,8) containing G3, both G2 and G3, or all three G domains were overexpressed in Xenopus embryos during neuromuscular synapse formation in myotomal muscles. RNA encoding these fragments of rat agrin was injected into one-cell embryos. All three fragments increased the ectopic aggregation of AChRs in noninnervated regions near the center of myotomes. Surprisingly, ectopic aggregation was more pronounced after overexpression of the smallest fragment, which lacks the heparin- and alpha-dystroglycan-binding domains. Synaptic AChR aggregation was decreased in embryos overexpressing the fragments, suggesting a competition between endogenous agrin secreted by nerve terminals and exogenous agrin fragments secreted by muscle cells. These results suggest that binding of the larger agrin fragments to alpha-dystroglycan and/or heparan sulfate proteoglycans may sequester the fragments and inhibit their activity in embryonic muscle. These intermolecular interactions may regulate agrin activity and differentiation of the neuromuscular junction in vivo.
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