alpha-Dystrobrevin isoforms differ in their colocalization with and stabilization of agrin-induced acetylcholine receptor clusters.

In skeletal muscle, alpha-dystrobrevin (alphaDB) is expressed throughout the sarcolemma with high concentrations at the neuromuscular junction. Mice lacking alphaDB display a mild muscular dystrophy and perturbations at the neuromuscular junction that include disruptions to acetylcholine receptor (AChR) cluster stability and patterning. In adult skeletal muscle, three alternatively spliced isoforms (alphaDB1, alphaDB2, alphaDB3) are expressed, while two other splice variants (alphaDB1(-) and alphaDB2(-)) are expressed only during early development. alphaDB is clearly important in AChR stabilization; however, the degree to which individual alphaDB isoforms and their specific functional domains contribute to AChR cluster stability is not fully understood. To investigate this, we established a primary muscle cell culture system from alphaDB knockout mice and stably expressed individual alphaDB isoforms using retroviral infection. A comparison between wild-type and alphaDB knockout muscle cells showed that in the absence of alphaDB, fewer AChR clusters formed in response to agrin treatment, and these AChR clusters were very unstable. Retroviral expression studies revealed that the largest isoforms (alphaDB1, alphaDB1(-), alphaDB2, alphaDB2(-)) colocalized with agrin-induced AChR clusters and rescued the AChR cluster formation defects back to wild-type levels, while only the first three isoforms fully rescued AChR cluster stability back to wild-type levels. alphaDB2(-) conferred an intermediate level of stability to the AChR clusters. In contrast, alphaDB3 showed no specific colocalization with AChR clusters and little effect on AChR cluster formation or stabilization. Twice as much syntrophin was found associated with alphaDB2 compared with alphaDB2(-) in myotubes suggesting that increased recruitment of syntrophin by alphaDB may enhance the stability of AChR clusters. Taken together, these data demonstrate that different alphaDB isoforms have different functional capabilities in the formation and maintenance of AChR clusters in muscle cells, and that these differences are likely due to the presence of different functional domains in each isoform.

Cellular and molecular properties of alpha-dystrobrevin in skeletal muscle.

The dystrophin glycoprotein complex (DGC) is a large multisubunit complex located throughout the sarcolemma of striated muscle fibers. This complex is critical for maintaining the structural integrity of muscle fibers during muscle contraction and also provides a scaffold for signaling molecules. Defects in some components of the DGC, such as dystrophin and sarcoglycans, disrupt the complex and lead to muscular dystrophies. Alpha-dystrobrevin is a dystrophin-related component of the DGC that is localized to the cytoplasmic side of the sarcolemma. In skeletal muscle, alpha-dystrobrevin is also highly concentrated at the neuromuscular junction, a highly specialized region of the sarcolemma responsible for receiving motor nerve signals necessary for muscle contraction. Current evidence suggests that alpha-dystrobrevin plays an important role in signaling at the sarcolemma and in the maturation and maintenance of the postsynaptic apparatus at the neuromuscular junction. In this review, we summarize the currently known cellular and molecular properties of alpha-dystrobrevin in skeletal muscle and discuss its potential functions at both the sarcolemma and neuromuscular junction.

The intracellular domain of the nicotinic acetylcholine receptor alpha subunit mediates its coclustering with rapsyn.

Muscle nicotinic acetylcholine receptors (AChRs) are immobilized at the neuromuscular junction in high-density clusters by rapsyn, a 43-kDa protein located at the cytoplasmic face of the postsynaptic membrane. When expressed in nonmuscle cells, rapsyn induces the aggregation of both assembled and unassembled AChR subunits. Here, we investigated the mechanism of rapsyn-induced clustering of the AChR alpha subunit by testing a series of alpha subunit mutants for colocalization with rapsyn patches in transfected QT6 cells. Partial or total deletion of the large intracellular domain of the alpha subunit dramatically reduced its ability to colocalize with rapsyn patches. Furthermore, insertion of the alpha subunit large intracellular domain into a potassium channel resulted in a significant increase in the channel's colocalization with rapsyn patches. We conclude that the large intracellular domain of the alpha subunit plays an important role in mediating rapsyn-induced coclustering of the AChR alpha subunit.

Role for alpha-dystrobrevin in the pathogenesis of dystrophin-dependent muscular dystrophies.

A dystrophin-containing glycoprotein complex (DGC) links the basal lamina surrounding each muscle fibre to the fibre's cytoskeleton, providing both structural support and a scaffold for signalling molecules. Mutations in genes encoding several DGC components disrupt the complex and lead to muscular dystrophy. Here we show that mice deficient in alpha-dystrobrevin, a cytoplasmic protein of the DGC, exhibit skeletal and cardiac myopathies. Analysis of double and triple mutants indicates that alpha-dystrobrevin acts largely through the DGC. Structural components of the DGC are retained in the absence of alpha-dystrobrevin, but a DGC-associated signalling protein, nitric oxide synthase, is displaced from the membrane and nitric-oxide-mediated signalling is impaired. These results indicate that both signalling and structural functions of the DGC are required for muscle stability, and implicate alpha-dystrobrevin in the former.

Differential expression and developmental regulation of a novel alpha-dystrobrevin isoform in muscle.

Alpha-dystrobrevin is a dystrophin-related protein expressed primarily in skeletal muscle, heart, lung and brain. In skeletal muscle, alpha-dystrobrevin is a component of the dystrophin-associated glycoprotein complex and is localized to the sarcolemma, presumably through interactions with dystrophin and utrophin. Alternative splicing of the alpha-dystrobrevin gene generates multiple isoforms which have been grouped into three major classes: alpha-DB1, alpha-DB2, and alpha-DB3. Various isoforms have been shown to interact with a variety of proteins; however, the physiological function of the alpha-dystrobrevins remains unknown. In the present study, we have cloned a novel alpha-dystrobrevin cDNA encoding a protein (referred to as alpha-DB2b) with a unique 11 amino acid C-terminal tail. Using RT PCR with primers specific to the new isoform, we have characterized its expression in skeletal muscle, heart, and brain, and in differentiating C2C12 muscle cells. We show that alpha-DB2b is expressed in skeletal muscle, heart and brain, and that exons 12 and 13 are alternatively spliced in alpha-DB2b to generate at least three splice variants. The major alpha-DB2b splice variant expressed in adult skeletal muscle and heart contains exons 12 and 13, while in adult brain, two alpha-DB2b splice variants are expressed at similar levels. This is consistent with the preferential expression of exons 12 and 13 in other alpha-dystrobrevin isoforms in skeletal muscle and heart. Similarly, in alpha-DB1 the first 21 nucleotides of exon 18 are preferentially expressed in skeletal muscle and heart relative to brain. We also show that the expression of alternatively spliced alpha-DB2b is developmentally regulated in muscle; during differentiation of C2C12 cells, alpha-DB2b expression switches from an isoform lacking exons 12 and 13 to one containing them. We demonstrate similar developmental upregulation of exons 12, 13, and 18 in alpha-DB1 and of exons 12 and 13 in alpha-DB2a. Finally, we show that alpha-DB2b protein is expressed in adult skeletal muscle, suggesting that it has a functional role in adult muscle. Together, these data suggest that alternatively spliced variants of the new alpha-dystrobrevin isoform, alpha-DB2b, are differentially expressed in various tissues and developmentally regulated during muscle cell differentiation in a fashion similar to that previously described for alpha-dystrobrevin isoforms.

Characterization of two isoforms of the skeletal muscle LIM protein 1, SLIM1. Localization of SLIM1 at focal adhesions and the isoform slimmer in the nucleus of myoblasts and cytoplasm of myotubes suggests distinct roles in the cytoskeleton and in nuclear-cytoplasmic communication.

We have cloned and characterized a novel isoform of the skeletal muscle LIM protein 1 (SLIM1), designated SLIMMER. SLIM1 contains an N-terminal single zinc finger followed by four LIM domains. SLIMMER is identical to SLIM1 over the first three LIM domains but contains a novel C-terminal 96 amino acids with three potential bipartite nuclear localization signals, a putative nuclear export sequence, and 27 amino acids identical to the RBP-J binding region of KyoT2, a murine isoform of SLIM1. SLIM1 localized to the cytosol of Sol8 myoblasts and myotubes. SLIMMER was detected in the nucleus of myoblasts and, following differentiation into myotubes, was exclusively cytosolic. Recombinant green fluorescent protein-SLIM1 localized to the cytoplasm and associated with focal adhesions and actin filaments in COS-7 cells, while green fluorescent protein-SLIMMER was predominantly nuclear. SLIMMER truncation mutants revealed that the first nuclear localization signal mediates nuclear localization. The addition of the proposed nuclear export sequence decreased the level of exclusively nuclear expression and increased cytosolic SLIMMER expression in COS-7 cells. The leucine-rich nuclear export signal was required for the export of SLIMMER from the nucleus of myoblasts to the cytoplasm of myotubes. Collectively, these results suggest distinct roles for SLIM1 and SLIMMER in focal adhesions and nuclear-cytoplasmic communication.

The cardiac expression of striated muscle LIM protein 1 (SLIM1) is restricted to the outflow tract of the developing heart.

LIM proteins perform critical roles in development and tissue differentiation. The skeletal muscle LIM protein 1 (SLIM1) comprises four and a half LIM domains. Northern blot analysis demonstrated high level expression of SLIM1 mRNA in adult human skeletal muscle with intermediate expression in adult heart and lower expression in other tissues. Western blot analysis using specific affinity-purified anti-SLIM1 antipeptide antibodies demonstrated a 32 kDa polypeptide in the aorta and atria of rabbit heart, but not in vena cava, interventricular septum or ventricular muscle. SLIM1 was also demonstrated in rabbit skeletal muscle. In situ hybridization of whole mouse embryos confirmed the cardiac expression of SLIM1 was restricted to the cardiac outflow tract from embryonic day 8.5-11. No expression was seen in atrial or ventricular muscle. SLIM1 mRNA was also demonstrated in the hindbrain, neural tube and somites. The localized expression of SLIM1 to the outflow tract of the embryonic heart implies an important role for the protein in the development of this region and possibly in congenital heart anomalies involving the separation and formation of the aortic and pulmonary trunks.

Interaction of the 43 kd postsynaptic protein with all subunits of the muscle nicotinic acetylcholine receptor.

The 43 kd postsynaptic protein (43K) plays a key role in the aggregation of muscle nicotinic acetylcholine receptors (AChRs) in the postsynaptic membrane of the neuromuscular junction. By transiently coexpressing 43K and a single AChR subunit (alpha, beta, gamma, or delta) in the quail fibroblast cell line, QT-6, we show that 43K interacts with each subunit to form cell surface clusters in which 43K and receptor subunit are precisely colocalized. Although the level of cell surface expression of single subunits is much lower than that of fully assembled receptor, the clustering of both single subunits and fully assembled AChR occurs efficiently. In addition, 43K-induced clustering is specific for AChR subunits. From these results, we conclude that each pentameric AChR has five potential sites for interacting with 43K during cluster formation.

Mutagenesis of the 43-kD postsynaptic protein defines domains involved in plasma membrane targeting and AChR clustering.

The postsynaptic membrane of the neuromuscular junction contains a myristoylated 43-kD protein (43k) that is closely associated with the cytoplasmic face of the nicotinic acetylcholine receptor (AChR)-rich plasma membrane. Previously, we described fibroblast cell lines expressing recombinant AChRs. Transfection of these cell lines with 43k was necessary and sufficient for reorganization of AChR into discrete 43k-rich plasma membrane domains (Phillips, W. D., C. Kopta, P. Blount, P. D. Gardner, J. H. Steinbach, and J. P. Merlie. 1991. Science (Wash. DC). 251:568-570). Here we demonstrate the utility of this expression system for the study of 43k function by site-directed mutagenesis. Substitution of a termination codon for Asp254 produced a truncated (28-kD) protein that associated poorly with the cell membrane. The conversion of Gly2 to Ala2, to preclude NH2-terminal myristoylation, reduced the frequency with which 43k formed plasma membrane domains by threefold, but did not eliminate the aggregation of AChRs at these domains. Since both NH2 and COOH-termini seemed important for association of 43k with the plasma membrane, a deletion mutant was constructed in which the codon Gln15 was fused in-frame to Ile255 to create a 19-kD protein. This mutated protein formed 43k-rich plasma membrane domains at wild-type frequency, but the domains failed to aggregate AChRs, suggesting that the central part of the 43k polypeptide may be involved in AChR aggregation. Our results suggest that membrane association and AChR interactions are separable functions of the 43k molecule.

Effect of low molecular weight heparin preparations on the inhibition of thrombin by heparin cofactor II.

1. Heparin molecules approximately 24 to 30 residues in length are required to catalyze the thrombin-HC II reaction. The requirement for heparin molecules of this length is consistent with a model for catalysis in which heparin binds HC II and thrombin simultaneously to form a ternary complex in a manner similar to that proposed for the thrombin-AT III reaction. Smaller molecules (18 or more monosaccharide units in length) are required to catalyze the thrombin-AT III reaction. 2. The specific AT III-binding pentasaccharide containing 3-O-sulfated glucosamine is not required for activity with HC II. 3. Some low molecular weight heparin preparations have significant activity with HC II (approximately 10 to 20% that of standard heparin). This is probably related to the presence of species with molecular weights greater than 6000 to 7500 (24 to 30 monosaccharide units) in these preparations.

Structure of a dermatan sulfate hexasaccharide that binds to heparin cofactor II with high affinity.

Dermatan sulfate increases the rate of inhibition of thrombin by heparin cofactor II (HCII) approximately 1000-fold by providing a catalytic template to which both the inhibitor and the protease bind. Dermatan sulfate is a linear polymer of D-glucuronic acid (GlcA) or L-iduronic acid (IdoA) alternating with N-acetyl-D-galactosamine (GalNAc) residues. Heterogeneity in dermatan sulfate results from varying degrees of O-sulfation and from the presence of the two types of uronic acid residues. To characterize the HCII-binding site in dermatan sulfate, we isolated the smallest fragment of dermatan sulfate that bound to HCII with high affinity. Dermatan sulfate was partially N-deacetylated by hydrazinolysis, cleaved with nitrous acid at pH 4, and reduced with [3H]NaBH4. The resulting fragments, containing an even number of monosaccharide units with the reducing terminal GalNAc converted to [3H]2,5-anhydro-D-talitol (ATalR), were size-fractionated and then chromatographed on an HCII-Sepharose column. The smallest HCII-binding fragments were hexasaccharides, of which approximately 6% bound. Based on ion-exchange chromatography, the bound material appeared to comprise a heterogeneous mixture of molecules possessing four, five, or six sulfate groups per hexasaccharide. Subsequently, hexasaccharides with the highest affinity for HCII were isolated by overloading the HCII-Sepharose column. The high-affinity hexasaccharides were fractionated by strong anion-exchange chromatography, and one major peak representing approximately 2% of the starting hexasaccharides was isolated. The high-affinity hexasaccharide was cleaved to disaccharides that were analyzed by anion-exchange chromatography, paper electrophoresis, and paper chromatography. A single disulfated disaccharide, IdoA(2-SO4)----ATalR(4-SO4) was observed, indicating that the hexasaccharide has the following structure: IdoA(2-SO4)----GalNAc(4-SO4)----IdoA(2-SO4)---- GalNAc(4-SO4)----IdoA(2-SO4)----ATalR(4-SO4). Since IdoA(2-SO4)----GalNAc(4-SO4) comprises only approximately 5% of the disaccharides present in intact dermatan sulfate, clustering of these disaccharides must occur during biosynthesis to form the high-affinity binding site for HCII.

Dissociation of double-stranded polynucleotide helical structures by eukaryotic initiation factors, as revealed by a novel assay.

A new technique has been applied to the study of the RNA secondary structure unwinding activity of the eukaryotic initiation factors (eIFs) 4F, 4A, and 4B. Secondary structures were generated at the 5' ends of reovirus and globin mRNA molecules by hybridization with 32P-labeled cDNA molecules 15 nucleotide residues long. The dissociation of the labeled cDNAs from the mRNAs was assayed by a gel filtration chromatography procedure which separates the free cDNAs from mRNAs and mRNA/cDNA hybrids. When the three factors were tested alone, only eIF-4F stimulated dissociation of hybrids. The combination of eIF-4A plus eIF-4B also exhibited a strong hybrid dissociating activity, which was markedly temperature dependent. Under optimum conditions, up to 90% of the hybrid structures are disrupted in 60 min. These results demonstrate for the first time that stable double-stranded regions can be melted and dissociated by eIFs. They also characterize more precisely the first step in the structure unwinding reaction.

Activation of heparin cofactor II by heparin oligosaccharides.

Heparin was partially depolymerized with heparinase or nitrous acid. The resulting oligosaccharides were fractionated by gel filtration chromatography and tested for the ability to stimulate inhibition of thrombin by purified heparin cofactor II or antithrombin. Oligosaccharides containing greater than or equal to 18 monosaccharide units were active with antithrombin, while larger oligosaccharides were required for activity with heparin cofactor II. Intact heparin molecules fractionated on a column of immobilized antithrombin were also tested for activity with both inhibitors. The relative specific activities of the unbound heparin molecules were 0.06 with antithrombin and 0.76 with heparin cofactor II in comparison to unfractionated heparin (specific activity = 1.00). We conclude that heparin molecules much greater than 18 monosaccharide units in length are required for activity with heparin cofactor II and that the high-affinity antithrombin-binding structure of heparin is not required.

Features of target cell lysis by class I and class II MHC-restricted cytolytic T lymphocytes.

The lytic activity of influenza virus-specific murine cytolytic T lymphocyte (CTL) clones that are restricted by either H-2K/D (class I) or H-2I (class II) major histocompatibility (MHC) locus products was compared on an influenza virus-infected target cell expressing both K/D and I locus products. With the use of two in vitro measurements of cytotoxicity, conventional 51Cr release, and detergent-releasable radiolabeled DNA (as a measure of nuclear disintegration in the early post-lethal hit period), we found no difference between class I and class II MHC-restricted CTL in the kinetics of target cell destruction. In addition, class II MHC-restricted antiviral CTL failed to show any lysis of radiolabeled bystander cells. Killing of labeled specific targets by these class II MHC-restricted CTL was also efficiently inhibited by unlabeled specific competitor cells in a cold target inhibition assay. In sum, these data suggest that class I and class II MHC-restricted CTL mediate target cell destruction by an essentially similar direct mechanism.