LIM kinase 1 accumulates in presynaptic terminals during synapse maturation.

LIM kinase 1 (LIMK1) is a cytoplasmic protein kinase that is highly expressed in neurons. In transfected cells, LIMK1 binds to the cytoplasmic tail of neuregulins and regulates the breakdown of actin filaments. To identify potential functions of LIMK1 in vivo, we have determined the subcellular distribution of LIMK1 protein within neurons of the rat by using immunomicroscopy. At neuromuscular synapses in the adult hindlimb, LIMK1 was concentrated in the presynaptic terminal. However, little LIMK1 immunoreactivity was detected at neuromuscular synapses before the 2nd week after birth, and most motoneuron terminals were not strongly LIMK1 immunoreactive until the 3rd week after birth. Thus, LIMK1 accumulation at neuromuscular synapses coincided with their maturation. In contrast, SV2, like many other presynaptic terminal proteins, can be readily detected at neuromuscular synapses in the embryo. Similar to its late accumulation at developing synapses, LIMK1 accumulation at regenerating neuromuscular synapses occurred long after these synapses first formed. In the adult ventral spinal cord, LIMK1 was concentrated in a subset of presynaptic terminals. LIMK1 gradually accumulated at spinal cord synapses postnatally, reaching adult levels only after P14. This study is the first to implicate LIMK1 in the function of presynaptic terminals. The concentration of LIMK1 in adult, but not nascent, presynaptic terminals suggests a role for this kinase in regulating the structural or functional characteristics of mature synapses.

Neuregulin-1 proteins in rat brain and transfected cells are localized to lipid rafts.

Neuregulin-1 proteins and their receptors, which are members of the ErbB subfamily of receptor tyrosine kinases, play essential roles in the development of the nervous system and heart. Most neuregulin-1 isoforms are synthesized as transmembrane proproteins that are proteolytically processed to yield an N-terminal fragment containing the bioactive EGF-like domain. In this study we investigated whether neuregulins are found in lipid rafts, membrane microdomains hypothesized to have important roles in signal transduction, protein trafficking, and proteolytic processing. We found that 45% of a 140-kDa neuregulin protein in rat brain synaptosomal plasma membrane fractions was insoluble in 1% Triton X-100. Flotation gradient analysis demonstrated the presence of the brain 140 kDa neuregulin protein in low-density fractions enriched in PSD-95, a known lipid raft protein. In transfected cells expressing the neuregulin I-beta 1a or the III-beta 1a isoform, most of the neuregulin proprotein was insoluble in 1% Triton X-100, and neuregulin proproteins and C-terminal fragments were detected in lipid raft fractions. In contrast, the III-beta 1a N-terminal fragment was detected only in the detergent-soluble fraction. These results suggest that localization of neuregulins to lipid rafts may play a role in neuregulin signaling within the nervous system.

ARIA, a protein that stimulates acetylcholine receptor synthesis, also induces tyrosine phosphorylation of a 185-kDa muscle transmembrane protein.

Motoneurons promote the accumulation of acetylcholine receptors (AChRs) at developing neuromuscular synapses. The AChR-inducing activity protein ARIA, which is purified from chicken brain and increases the synthesis of AChRs in chicken myotubes, may play a crucial role in this process. Here we show that ARIA induces the rapid tyrosine phosphorylation of a M(r) 185,000 protein (p185) in muscle cells. Phosphorylation of p185 correlates with AChR induction at each stage of ARIA purification. Moreover, medium conditioned by spinal cord motoneurons stimulates AChR synthesis and p185 phosphorylation. Studies with membrane-impermeant reagents and 125I-labeled ARIA indicate that p185 is a transmembrane ARIA-receptor tyrosine kinase. Our data suggests that muscle AChR synthesis can be regulated through tyrosine phosphorylation.

The N-terminal region of neuregulin isoforms determines the accumulation of cell surface and released neuregulin ectodomain.

Two neuregulin-1 isoforms highly expressed in the nervous system are the type III neuregulin III-beta1a and the type I neuregulin I-beta1a. The sequence of these two isoforms differs only in the region that is N-terminal of the bioactive epidermal growth factor-like domain. While the biosynthetic processing of the I-beta1a isoform has been well characterized, the processing of III-beta1a has not been reported. In this study, we compared III-beta1a and I-beta1a processing. Both III-beta1a and I-beta1a were synthesized as transmembrane proproteins that were proteolytically cleaved to produce an N-terminal fragment containing the bioactive epidermal growth factor-like domain. For I-beta1a, this product was released into the medium. However, for III-beta1a, this product was a transmembrane protein. In cultures of cells expressing III-beta1a, the amount of neuregulin at the cell surface was much greater, and the amount in the medium was much less than in cultures expressing I-beta1a. Phorbol ester treatment and truncation of the cytoplasmic tail had markedly different effects on III-beta1a and I-beta1a processing. These results demonstrate an important role for the N-terminal region in determining neuregulin biosynthetic processing and show that a major product of III-beta1a processing is a tethered ligand that may act as a cell surface signaling molecule.

Differential activation of myotube nuclei following exposure to an acetylcholine receptor-inducing factor.

A glycoprotein purified from chick brain, of relative molecular mass 42,000, increases the rate of appearance of acetylcholine receptors (AChRs) on the surface of chick myotubes. RNase protection assays have shown that this AChR-inducing activity (ARIA) increases the amount of mRNA encoding the alpha-subunit of the AChR, with little or no effect on the amounts of gamma- and delta-mRNAs2. Here, we report that the mRNAs encoding the alpha- and gamma-subunits of the receptor detected by in situ hybridization are concentrated around nuclei in cultured myotubes. Consistent with previous results, ARIA selectively increased the amount of alpha-subunit mRNA, but we now find that all nuclei were not activated to the same extent, with a substantial number not responding at all. Assuming that ARIA is released by motor nerve terminals, our results indicate that only a subset of muscle nuclei are capable of contributing to the accumulation of AChRs at developing neuromuscular junctions.

A prion-like protein from chicken brain copurifies with an acetylcholine receptor-inducing activity.

The mammalian prion protein (PrPC) is a cellular protein of unknown function, an altered isoform of which (PrPSc) is a component of the infectious particle (prion) thought to be responsible for spongiform encephalopathies in humans and animals. We report here the isolation of a cDNA that encodes a chicken protein that is homologous to PrPC. This chicken prion-like protein (ch-PrLP) is identical to the mouse PrP at 33% of its amino acid positions, including an uninterrupted stretch of 24 identical residues, and it displays the same structural domains. In addition, ch-PrLP, like its mammalian counterpart, is attached to the cell surface by a glycosyl-phosphatidylinositol anchor. We find that ch-PrLP is the major protein in preparations of an acetylcholine receptor-inducing activity that has been purified greater than 10(6)-fold from brain on the basis of its ability to stimulate synthesis of nicotinic receptors by cultured myotubes. The ch-PrLP gene is expressed in the spinal cord and brain as early as embryonic day 6; and in the spinal cord, the protein appears to be concentrated in motor neurons. Our results therefore raise the possibility that prion proteins serve normally to regulate the chemoreceptor number at the neuromuscular junction and perhaps in the central nervous system as well.

Acetylcholine receptor-inducing factor from chicken brain increases the level of mRNA encoding the receptor alpha subunit.

A 42-kDa glycoprotein isolated from chicken brain, referred to as acetylcholine receptor-inducing activity (ARIA), that stimulates the rate of incorporation of acetylcholine receptors into the surface of chicken myotubes may play a role in the nerve-induced accumulation of receptors at developing neuromuscular synapses. Using nuclease-protection assays, we have found that ARIA causes a 2- to 16-fold increase in the level of mRNA encoding the alpha subunit of the receptor, with little or no change in the levels of gamma- and delta-subunit messengers. ARIA also increases the amount of a putative nuclear precursor of alpha-subunit mRNA, consistent with an activation of gene transcription. These results suggest that the concentration of alpha subunit may limit the rate of biosynthesis of the acetylcholine receptors in chicken myotubes. They also indicate that neuronal factors can regulate the expression of receptor subunit genes in a selective manner. Tetrodotoxin, 8-bromo-cAMP, and forskolin also increase the amount of alpha-subunit mRNA, with little change in the amount of gamma- and delta-subunit mRNAs. Unlike, ARIA, however, these agents have little effect on the concentration of the alpha-subunit nuclear precursor.

ARIA, a protein that stimulates acetylcholine receptor synthesis, is a member of the neu ligand family.

Motor neurons stimulate their postsynaptic muscle targets to synthesize neurotransmitter receptors. Polypeptide signaling molecules may mediate this inductive interaction. Here we report the purification of ARIA, a protein that stimulates the synthesis of muscle acetylcholine receptors, and the isolation of ARIA cDNA. Recombinant ARIA increases acetylcholine receptor synthesis greater than 3-fold, and it induces tyrosine phosphorylation of a 185 kd muscle protein. The ARIA cDNA hybridizes with mRNAs that are expressed in the spinal cord from E4, a time prior to the onset of neuromuscular synapse formation, through adulthood. By E7, hybridizing mRNAs are concentrated in motor neurons. Chicken ARIA is homologous to the rat Neu differentiation factor and human here-gulin, ligands for the receptor tyrosine kinase encoded by the neu (c-erbB2, HER2) proto-oncogene. Our data suggest that members of the ARIA protein family promote the formation and maintenance of chemical synapses and, furthermore, that receptor tyrosine kinases play important roles in this process.

Acetylcholine receptor-inducing activity stimulates expression of the epsilon-subunit gene of the muscle acetylcholine receptor.

Motor neurons regulate the transcription of acetylcholine receptor subunit genes in postsynaptic muscle fibers both through muscle electrical activity produced by motor neuron acetylcholine release and by mechanisms independent of such transmitter release. Factors secreted by the motor neuron may mediate activity-independent regulation, including the postnatal switch from alpha 2 beta gamma delta (embryonic type) to alpha 2 beta epsilon delta (adult type) receptors. We have investigated the effect of putative trophic factors, agents affecting second-messenger systems, and muscle activity on the levels of acetylcholine receptor subunit mRNAs in primary mouse muscle cultures. We found that ARIA (acetylcholine receptor-inducing activity), a 42-kDa glycoprotein purified on the basis of its ability to increase the synthesis of acetylcholine receptors in chick myotubes, increases epsilon-subunit mRNA levels up to 10-fold. In addition, ARIA stimulated alpha-, gamma-, and delta-subunit mRNA levels 2-fold but had no effect on the expression of the beta-subunit gene. These effects of ARIA were independent of muscle activity, and they were not mimicked by calcitonin gene-related peptide nor by thyroxine, forskolin, phorbol 12-myristate 13-acetate, the calcium ionophore A23187, basic fibroblast growth factor, or transforming growth factor beta. Based on these data, we suggest that ARIA may act at the mammalian neuromuscular junction to induce adult-type acetylcholine receptors.

Transmembrane neuregulins interact with LIM kinase 1, a cytoplasmic protein kinase implicated in development of visuospatial cognition.

The neuregulins are receptor tyrosine kinase ligands that play a critical role in the development of the heart, nervous system, and breast. Unlike many extracellular signaling molecules, such as the neurotrophins, most neuregulins are synthesized as transmembrane proteins. To determine the functions of the highly conserved neuregulin cytoplasmic tail, a yeast two-hybrid screen was performed to identify proteins that interact with the 157-amino acid sequence common to the cytoplasmic tails of all transmembrane neuregulin isoforms. This screen revealed that the neuregulin cytoplasmic tail interacts with the LIM domain region of the nonreceptor protein kinase LIM kinase 1 (LIMK1). Interaction between the neuregulin cytoplasmic tail and full-length LIMK1 was demonstrated by in vitro binding and co-immunoprecipitation assays. Transmembrane neuregulins with each of the three known neuregulin cytoplasmic tail isoforms interacted with LIMK1. In contrast, the cytoplasmic tail of TGF-alpha did not interact with LIMK1. In vivo, neuregulin and LIMK1 are co-localized at the neuromuscular synapse, suggesting that LIMK1, like neuregulin, may play a role in synapse formation and maintenance. To our knowledge, LIMK1 is the first identified protein shown to interact with the cytoplasmic tail of a receptor tyrosine kinase ligand.

A protein kinase from neutrophils that specifically recognizes Ser-3 in cofilin.

Cofilin promotes the depolymerization of actin filaments, which is required for a variety of cellular responses such as the formation of lamellipodia and chemotaxis. Phosphorylation of cofilin on serine residue 3 is known to block these activities. We now report that neutrophils contain a protein kinase that selectively catalyzes the phosphorylation of cofilin on serine 3 (>/=70%) and a nonspecific kinase that recognizes multiple sites in this protein. The selective serine 3 cofilin kinase binds to a deoxyribonuclease I affinity column, whereas the nonspecific cofilin kinase does not. Deoxyribonuclease I forms a very tight complex with actin, and deoxyribonuclease affinity columns have been utilized to identify a variety of proteins that interact with the cytoskeleton. The serine 3 cofilin kinase did not react with antibodies to LIM kinase 1 or 2, which can catalyze the phosphorylation of cofilin in other cell types. The activity of the serine 3 cofilin kinase was insensitive to a variety of selective antagonists of protein kinases but was blocked by staurosporine. This pattern of inhibition is similar to that observed for the kinase that is active with cofilin in intact neutrophils. Thus, neutrophils contain a protein kinase distinct from LIM kinase-1/2 that selectively recognizes serine 3 in cofilin.