SH3 in muscles: solution structure of the SH3 domain from nebulin

Characterization of a fold in TANGO1 evolved from SH3 domains for the export of bulky cargos

Bulky cargos like procollagens, apolipoproteins, and mucins exceed the size of conventional COPII vesicles. During evolution a process emerged in metazoans, predominantly governed by the TANGO1 protein family, that organizes cargo at the exit sites of the endoplasmic reticulum and facilitates export by the formation of tunnel-like connections between the ER and Golgi. Hitherto, cargo-recognition appeared to be mediated by an SH3-like domain. Based on structural and dynamic data as well as interaction studies from NMR spectroscopy and microscale thermophoresis presented here, we show that the luminal cargo-recognition domain of TANGO1 adopts a new functional fold for which we suggest the term MOTH (MIA, Otoraplin, TALI/TANGO1 homology) domain. These MOTH domains, as well as an evolutionary intermediate found in invertebrates, constitute a distinct domain family that emerged from SH3 domains and acquired the ability to bind collagen.

Deficiency in nebulin repeats of sarcomeric nebulette is detrimental for cardiomyocyte tolerance to exercise and biomechanical stress

The actin-binding sarcomeric nebulette (NEBL) protein provides efficient contractile flexibility via interaction with desmin intermediate filaments. NEBL gene mutations affecting the nebulin repeat (NR) domain are known to induce cardiomyopathy. The study aimed to explore the roles of NEBL in exercise and biomechanical stress response. We ablated exon3 encoding the first NR of Nebl and created global Nebl^ex3-/ex3- knockout mice. Cardiac function, structure, and transcriptome were assessed before and after a 4-wk treadmill regimen. A Nebl-based exercise signaling network was constructed using systems genetics methods. H9C2 and neonatal rat cardiomyocytes (NRCs) expressing wild-type or mutant NEBL underwent cyclic mechanical strain. Nebl^ex3-/ex3- mice demonstrated diastolic dysfunction with preserved systolic function at 6 mo of age. After treadmill running, 4-mo-old Nebl^ex3-/ex3- mice developed concentric cardiac hypertrophy and left ventricular dilation compared with running Nebl^+/+ and sedentary Nebl^ex3-/ex3- mice. Disturbance of sarcomeric Z-disks and thin filaments architecture and disruption of intercalated disks and mitochondria were found in exercised Nebl^ex3-/ex3- mice. A Nebl-based exercise signaling network included Csrp3, Des, Fbox32, Jup, Myh6, and Myh7. Disturbed expression of TM1, DES, JUP, β-catenin, MLP, α-actinin2, and vinculin proteins was demonstrated. In H9C2 cells, NEBL was recruited into focal adhesions at 24-h poststrain and redistributed along with F-actin at 72-h poststrain, suggesting time-dependent redistribution of NEBL in response to strain. NEBL mutations cause desmin disorganization in NRCs upon stretch. We conclude that Nebl's NR ablation causes disturbed sarcomere, Z-disks, and desmin organization, and prevents NEBL redistribution to focal adhesions in cardiomyocytes, weakening cardiac tolerance to biomechanical stress.NEW & NOTEWORTHY We demonstrate that ablation of first nebulin-repeats of sarcomeric nebulette (Nebl) causes diastolic dysfunction in Nebl^ex3-/ex3- mice. Exercise-induced development of diastolic dysfunction, cardiac hypertrophy and ventricular dilation in knockouts. This was associated with sarcomere disturbance, intercalated disks disruption, and mitochondrial distortion upon stress and altered expression of genes involved in Nebl-based stress network. We demonstrate that G202R and A592 mutations alter actin and desmin expression causing disorganization of desmin filaments upon cyclic strain.

Functionalization of the BCL6 BTB domain into a noncovalent crystallization chaperone

The production of diffraction-quality protein crystals is challenging and often requires bespoke, time-consuming and expensive strategies. A system has been developed in which the BCL6 BTB domain acts as a crystallization chaperone and promiscuous assembly block that may form the basis for affinity-capture crystallography. The protein of interest is expressed with a C-terminal tag that interacts with the BTB domain, and co-crystallization leads to its incorporation within a BTB-domain lattice. This strategy was used to solve the structure of the SH3 domain of human nebulin, a structure previously solved by NMR, at 1.56 Å resolution. This approach is simple and effective, requiring only routine protein complexation and crystallization screening, and should be applicable to a range of proteins.

Conserved patterns and interactions in the unfolding transition state across SH3 domain structural homologues

Proteins with similar structures are generally assumed to arise from similar sequences. However, there are more cases than not where this is not true. The dogma is that sequence determines structure; how, then, can very different sequences fold to the same structure? Here, we employ high temperature unfolding simulations to probe the pathways and specific interactions that direct the folding and unfolding of the SH3 domain. The SH3 metafold in the Dynameomics Database consists of 753 proteins with the same structure, but varied sequences and functions. To investigate the relationship between sequence and structure, we selected 17 targets from the SH3 metafold with high sequence variability. Six unfolding simulations were performed for each target, transition states were identified, revealing two general folding/unfolding pathways at the transition state. Transition states were also expressed as mathematical graphs of connected chemical nodes, and it was found that three positions within the structure, independent of sequence, were consistently more connected within the graph than any other nearby positions in the sequence. These positions represent a hub connecting different portions of the structure. Multiple sequence alignment and covariation analyses also revealed certain positions that were more conserved due to packing constraints and stabilizing long-range contacts. This study demonstrates that members of the SH3 domain with different sequences can unfold through two main pathways, but certain characteristics are conserved regardless of the sequence or unfolding pathway. While sequence determines structure, we show that disparate sequences can provide similar interactions that influence folding and lead to similar structures.

Nebulin: big protein with big responsibilities

Nebulin, encoded by NEB, is a giant skeletal muscle protein of about 6669 amino acids which forms an integral part of the sarcomeric thin filament. In recent years, the nebula around this protein has been largely lifted resulting in the discovery that nebulin is critical for a number of tasks in skeletal muscle. In this review, we firstly discussed nebulin’s role as a structural component of the thin filament and the Z-disk, regulating the length and the mechanical properties of the thin filament as well as providing stability to myofibrils by interacting with structural proteins within the Z-disk. Secondly, we reviewed nebulin’s involvement in the regulation of muscle contraction, cross-bridge cycling kinetics, Ca²⁺-homeostasis and excitation contraction (EC) coupling. While its role in Ca²⁺-homeostasis and EC coupling is still poorly understood, a large number of studies have helped to improve our knowledge on how nebulin affects skeletal muscle contractile mechanics. These studies suggest that nebulin affects the number of force generating actin-myosin cross-bridges and may also affect the force that each cross-bridge produces. It may exert this effect by interacting directly with actin and myosin and/or indirectly by potentially changing the localisation and function of the regulatory complex (troponin and tropomyosin). Besides unravelling the biology of nebulin, these studies are particularly helpful in understanding the patho-mechanism of myopathies caused by NEB mutations, providing knowledge which constitutes the critical first step towards the development of therapeutic interventions. Currently, effective treatments are not available, although a number of therapeutic strategies are being investigated.

Elastic domains of giant proteins in striated muscle: Modeling compliance with rulers

Chase examines a study using the MUSICO model of striated muscle to evaluate the function of giant elastic proteins titin and nebulin.

Structure of giant muscle proteins

Giant muscle proteins (e.g., titin, nebulin, and obscurin) play a seminal role in muscle elasticity, stretch response, and sarcomeric organization. Each giant protein consists of multiple tandem structural domains, usually arranged in a modular fashion spanning 500 kDa to 4 MDa. Although many of the domains are similar in structure, subtle differences create a unique function of each domain. Recent high and low resolution structural and dynamic studies now suggest more nuanced overall protein structures than previously realized. These findings show that atomic structure, interactions between tandem domains, and intrasarcomeric environment all influence the shape, motion, and therefore function of giant proteins. In this article we will review the current understanding of titin, obscurin, and nebulin structure, from the atomic level through the molecular level.

The nebulin SH3 domain is dispensable for normal skeletal muscle structure but is required for effective active load bearing in mouse

Nemaline myopathy (NM) is a congenital myopathy with an estimated incidence of 150,000 live births. It is caused by mutations in thin filament components, including nebulin, which accounts for about 50% of the cases. The identification of NM cases with nonsense mutations resulting in loss of the extreme C-terminal SH3 domain of nebulin suggests an important role of the nebulin SH3 domain, which is further supported by the recent demonstration of its role in IGF-1-induced sarcomeric actin filament formation through targeting of N-WASP to the Z-line. To provide further insights into the functional significance of the nebulin SH3 domain in the Z-disk and to understand the mechanisms by which truncations of nebulin lead to NM, we took two approaches: (1) an affinity-based proteomic screening to identify novel interaction partners of the nebulin SH3 domain; and (2) generation and characterization of a novel knockin mouse model with a premature stop codon in the nebulin gene, eliminating its C-terminal SH3 domain (NebΔSH3 mouse). Surprisingly, detailed analyses of NebΔSH3 mice revealed no structural or histological skeletal muscle abnormalities and no changes in gene expression or localization of interaction partners of the nebulin SH3 domain, including myopalladin, palladin, zyxin and N-WASP. Also, no significant effect on peak isometric stress production, passive tensile stress or Young's modulus was found. However, NebΔSH3 muscle displayed a slightly altered force-frequency relationship and was significantly more susceptible to eccentric contraction-induced injury, suggesting that the nebulin SH3 domain protects against eccentric contraction-induced injury and possibly plays a role in fine-tuning the excitation-contraction coupling mechanism.

Identification of Xin-repeat proteins as novel ligands of the SH3 domains of nebulin and nebulette and analysis of their interaction during myofibril formation and remodeling

The striated muscle–specific actin-binding proteins Xin and Xirp2 are identified as novel ligands of the SH3 domains of the thin filament ruler nebulin and nebulette. The interaction is spatially restricted to structures associated with myofibril development or remodeling, indicating a role for these proteins in myofibril assembly and repair.

The Xin actin-binding repeat–containing proteins Xin and XIRP2 are exclusively expressed in striated muscle cells, where they are believed to play an important role in development. In adult muscle, both proteins are concentrated at attachment sites of myofibrils to the membrane. In contrast, during development they are localized to immature myofibrils together with their binding partner, filamin C, indicating an involvement of both proteins in myofibril assembly. We identify the SH3 domains of nebulin and nebulette as novel ligands of proline-rich regions of Xin and XIRP2. Precise binding motifs are mapped and shown to bind both SH3 domains with micromolar affinity. Cocrystallization of the nebulette SH3 domain with the interacting XIRP2 peptide PPPTLPKPKLPKH reveals selective interactions that conform to class II SH3 domain–binding peptides. Bimolecular fluorescence complementation experiments in cultured muscle cells indicate a temporally restricted interaction of Xin-repeat proteins with nebulin/nebulette during early stages of myofibril development that is lost upon further maturation. In mature myofibrils, this interaction is limited to longitudinally oriented structures associated with myofibril development and remodeling. These data provide new insights into the role of Xin actin-binding repeat–containing proteins (together with their interaction partners) in myofibril assembly and after muscle damage.

Muscle giants: molecular scaffolds in sarcomerogenesis

Myofibrillogenesis in striated muscles is a highly complex process that depends on the coordinated assembly and integration of a large number of contractile, cytoskeletal, and signaling proteins into regular arrays, the sarcomeres. It is also associated with the stereotypical assembly of the sarcoplasmic reticulum and the transverse tubules around each sarcomere. Three giant, muscle-specific proteins, titin (3-4 MDa), nebulin (600-800 kDa), and obscurin (approximately 720-900 kDa), have been proposed to play important roles in the assembly and stabilization of sarcomeres. There is a large amount of data showing that each of these molecules interacts with several to many different protein ligands, regulating their activity and localizing them to particular sites within or surrounding sarcomeres. Consistent with this, mutations in each of these proteins have been linked to skeletal and cardiac myopathies or to muscular dystrophies. The evidence that any of them plays a role as a "molecular template," "molecular blueprint," or "molecular ruler" is less definitive, however. Here we review the structure and function of titin, nebulin, and obscurin, with the literature supporting a role for them as scaffolding molecules and the contradictory evidence regarding their roles as molecular guides in sarcomerogenesis.

Bin1 SRC homology 3 domain acts as a scaffold for myofiber sarcomere assembly

In skeletal muscle development, the genes and regulatory factors that govern the specification of myocytes are well described. Despite this knowledge, the mechanisms that regulate the coordinated assembly of myofiber proteins into the functional contractile unit or sarcomere remain undefined. Here we explored the hypothesis that modular domain proteins such as Bin1 coordinate protein interactions to promote sarcomere formation. We demonstrate that Bin1 facilitates sarcomere organization through protein-protein interactions as mediated by the Src homology 3 (SH3) domain. We observed a profound disorder in myofiber size and structural organization in a murine model expressing the Bin1 SH3 region. In addition, satellite cell-derived myogenesis was limited despite the accumulation of skeletal muscle-specific proteins. Our experiments revealed that the Bin1 SH3 domain formed transient protein complexes with both actin and myosin filaments and the pro-myogenic kinase Cdk5. Bin1 also associated with a Cdk5 phosphorylation domain of titin. Collectively, these observations suggest that Bin1 displays protein scaffold-like properties and binds with sarcomeric factors important in directing sarcomere protein assembly and myofiber maturation.

Titin as a Giant Scaffold for Integrating Stress and Src Homology Domain 3-mediated Signaling Pathways

The richness of proline sequences in titins qualifies these giant proteins as the largest source of intrinsically disordered structures in nature. An extensive search and analysis for Src homology domain 3 (SH3) ligand motifs revealed a myriad of broadly distributed SH3 ligand motifs, with the highest density in the PEVK segments of human titin. Besides the canonical class I and II motifs with opposite orientations, novel overlapping motifs consisting of one or more of each canonical motif are abundant. Experimentally, the binding affinity and critical residues of these putative titin-based SH3 ligands toward nebulin SH3 and other SH3-containing proteins in muscle and non-muscle cell extracts were validated with peptide array technology and by the sarcomere distribution of SH3-containing proteins. A 28-mer overlapping motif-containing PEVK module binds to nebulin SH3 in and around the canonical cleft, especially to the acidic residues in the loops, as revealed by NMR titration. Molecular dynamics and molecular docking studies indicated that the overlapping motif can bind in opposite orientations with comparable energy and contact areas and predicts correctly orientation-specific contacts in NMR data. We propose that the overlap ligand motifs are a new class of ligands with innate ability to dictate SH3 domain orientation and to facilitate the rate, strength, and stereospecificity of receptor interactions. Proline-rich sequences of titins are candidates as major hubs of SH3-dependent signaling pathways. The interplay of elasticity and dense clustering of mixed receptor orientations in titin PEVK segment have important implications for the mechanical sensing, force sensitivity, and inter-adapter interactions in signaling pathways.

Nebulin regulates thin filament length, contractility, and Z-disk structure in vivo

The precise assembly of the highly organized filament systems found in muscle is critically important for its function. It has been hypothesized that nebulin, a giant filamentous protein extending along the entire length of the thin filament, provides a blueprint for muscle thin filament assembly. To test this hypothesis, we generated a KO mouse model to investigate nebulin functions in vivo. Nebulin KO mice assemble thin filaments of reduced lengths and approximately 15% of their Z-disks are abnormally wide. Our data demonstrate that nebulin functions in vivo as a molecular ruler by specifying pointed- and barbed-end thin filament capping. Consistent with the shorter thin filament length of nebulin deficient mice, maximal active tension was significantly reduced in KO animals. Phenotypically, the murine model recapitulates human nemaline myopathy (NM), that is, the formation of nemaline rods combined with severe skeletal muscle weakness. The myopathic changes in the nebulin KO model include depressed contractility, loss of myopalladin from the Z-disk, and dysregulation of genes involved in calcium homeostasis and glycogen metabolism; features potentially relevant for understanding human NM.

Zyxin interacts with the SH3 domains of the cytoskeletal proteins LIM-nebulette and Lasp-1

Zyxin is a versatile component of focal adhesions in eukaryotic cells. Here we describe a novel binding partner of zyxin, which we have named LIM-nebulette. LIM-nebulette is an alternative splice variant of the sarcomeric protein nebulette, which, in contrast to nebulette, is expressed in non-muscle cells. It displays a modular structure with an N-terminal LIM domain, three nebulin-like repeats, and a C-terminal SH3 domain and shows high similarity to another cytoskeletal protein, Lasp-1 (LIM and SH3 protein-1). Co-precipitation studies and results obtained with the two-hybrid system demonstrate that LIM-nebulette and Lasp-1 interact specifically with zyxin. Moreover, the SH3 domain from LIM-nebulette is both necessary and sufficient for zyxin binding. The SH3 domains from Lasp-1 and nebulin can also interact with zyxin, but the SH3 domains from more distantly related proteins such as vinexin and sorting nexin 9 do not. On the other hand, the binding site in zyxin is situated at the extreme N terminus as shown by site-directed mutagenesis. LIM-nebulette and Lasp-1 use the same linear binding motif. This motif shows some similarity to a class II binding site but does not contain the classical PXXP sequence. LIM-nebulette reveals a subcellular distribution at focal adhesions similar to Lasp-1. Thus, LIM-nebulette, Lasp-1, and zyxin may play an important role in the organization of focal adhesions.

Nebulin is a thin filament protein of the cardiac muscle of the agnathans

Nebulin is an integral protein of skeletal muscle thin filaments and probably acts as a ruler for the thin filament length. Cardiac muscles of higher vertebrates have been shown earlier to lack nebulin. Instead in human and chicken cardiac muscle the much smaller protein nebulette replaces nebulin. Since nebulette is confined to the Z-disc region of the sarcomere and does not span the whole thin filament length, it must have functions significantly different from those assumed for nebulin. We have investigated nebulin in skeletal and cardiac muscles of the agnathans (lamprey, hagfish), elasmobranchs (shark), chondrosts (sturgeon) and teleosts (trout, eel) by SDS-PAGE and immunodetection methods. Among these, lamprey and hagfish cardiac muscles are unique in that both contain full-length nebulin identical in molecular mass to the nebulin of the respective body muscle. Using immunofluorescence microscopy, lamprey cardiac nebulin was localised in the I-band of the sarcomere, the same as for nebulin in skeletal muscle. In contrast to this, all gnathostome species investigated lacked nebulin in cardiac muscles, while it was present in the respective skeletal muscles. This clearly shows that nebulin is not exclusively present in skeletal muscles of chordates. The findings also demonstrate a rare case of dramatic size reduction of a protein during evolution.

Functional sites in protein families uncovered via an objective and automated graph theoretic approach

We report a method for detection of recurring side-chain patterns (DRESPAT) using an unbiased and automated graph theoretic approach. We first list all structural patterns as sub-graphs where the protein is represented as a graph. The patterns from proteins are compared pair-wise to detect patterns common to a protein pair based on content and geometry criteria. The recurring pattern is then detected using an automated search algorithm from the all-against-all pair-wise comparison data of proteins. Intra-protein pattern comparison data are used to enable detection of patterns recurring within a protein. A method has been proposed for empirical calculation of statistical significance of recurring pattern. The method was tested on 17 protein sets of varying size, composed of non-redundant representatives from SCOP superfamilies. Recurring patterns in serine proteases, cysteine proteases, lipases, cupredoxin, ferredoxin, ferritin, cytochrome c, aspartoyl proteases, peroxidases, phospholipase A2, endonuclease, SH3 domain, EF-hand and lectins show additional residues conserved in the vicinity of the known functional sites. On the basis of the recurring patterns in ferritin, EF-hand and lectins, we could separate proteins or domains that are structurally similar yet different in metal ion-binding characteristics. In addition, novel recurring patterns were observed in glutathione-S-transferase, phospholipase A2 and ferredoxin with potential structural/functional roles. The results are discussed in relation to the known functional sites in each family. Between 2000 and 50,000 patterns were enumerated from each protein with between ten and 500 patterns detected as common to an evolutionarily related protein pair. Our results show that unbiased extraction of functional site pattern is not feasible from an evolutionarily related protein pair but is feasible from protein sets comprising five or more proteins. The DRESPAT method does not require a user-defined pattern, size or location of the pattern and therefore, has the potential to uncover new functional sites in protein families.

Interaction of nebulin SH3 domain with titin PEVK and myopalladin: implications for the signaling and assembly role of titin and nebulin

Skeletal muscle nebulin is thought to determine thin filament length and regulate actomyosin interaction in a calcium/calmodulin or S100 sensitive manner. We have investigated the binding of nebulin SH3 with proline-rich peptides derived from the 28-mer PEVK modules of titin and the Z-line protein myopalladin, using fluorescence, circular dichroism and nuclear magnetic resonance techniques. Of the six peptides studied, PR2 of titin (VPEKKAPVAPPK) and myopalladin MyoP2 (646VKEPPPVLAKPK657) bind to nebulin SH3 with micromolar affinity (approximately 31 and 3.4 microM, respectively), whereas the other four peptides bind weakly (>100 microM). Sequence analysis of titins reveals numerous SH3 binding motifs that are highly enriched in the PEVK segments of titin isoforms. Our findings suggest that titin PEVK and myopalladin may play signaling roles in targeting and orientating nebulin to the Z-line during sarcomere assembly.

Mutations in the nebulin gene can cause severe congenital nemaline myopathy

Previously, we reported results indicating that nebulin was the gene causing the typical form of autosomal recessive nemaline (rod) myopathy. Here we describe the identification of mutations in the nebulin gene in seven offspring of five families affected by the severe congenital form of nemaline myopathy. One pregnancy was terminated on the grounds of foetal abnormality, while six affected infants died at ages ranging from the first day of life to 19 months. Only three of the six neonates were able to establish spontaneous respiration. Three had arthrogryposis. In three of the five families, the mutations were located in exon 184. These mutations are predicted to cause absence of the C-terminal part of nebulin.

Nebulin mutations in autosomal recessive nemaline myopathy: an update

We report mutational analysis of the last 42 exons of the nebulin gene (NEB) in 77 patients with various forms of nemaline myopathy. In addition to the previously described six mutations in five families, we identified 12 novel recessive mutations in 13 families. Affected individuals were homozygous for the mutations in five families and compound heterozygous in two, while in the remaining cases only one heterozygous mutation was identified. The majority of the mutations were frameshifts due to small deletions or insertions; also common were point mutations causing premature stop codons or abnormal splicing, while missense mutations appeared rare. There were no obvious mutational hotspots, although four unrelated patients showed mutations in the differentially expressed exon 177d, and another three showed mutations in exon 184. Most of the mutations are predicted to result in truncated or internally deleted proteins. Mutations in the differentially expressed exons are expected to reduce the nebulin isoform diversity necessary for normal muscle development.

The SH3 domain of nebulin binds selectively to type II peptides: theoretical prediction and experimental validation

Nebulin, a giant modular protein from muscle, is thought to act as a molecular ruler in sarcomere assembly. The C terminus of nebulin, located in the sarcomere Z-disk, comprises an SH3 domain, a module well known for its role in protein/protein interactions. SH3 domains are known to recognize proline-rich ligands, which have been classified as type I or type II, depending on their relative orientation with respect to the SH3 domain in the complex formed. Type I ligands are bound with their N terminus at the RT loop of the SH3 domain, while type II ligands are bound with their C terminus at the RT loop. Many SH3 domains can bind peptides of either class. Despite the potential importance of the SH3 domain for the function of nebulin as an integral part of a complex network of interactions, no in vivo partner has been identified so far. We have adopted an integrated approach, which combines bioinformatic tools with experimental validation to identify possible partners of nebulin SH3. Using the program SPOT, we performed an exhaustive screening of the muscle sequence databases. This search identified a number of potential nebulin SH3 partners, which were then tested experimentally for their binding affinity. Synthetic peptides were studied by both fluorescence and NMR spectroscopy. Our results show that nebulin SH3 domain binds selectively to type II peptides. The affinity for a type II peptide, 12 residues long, spanning the sequence of a stretch of titin known to colocalise with nebulin in the Z-disk is in the submicromolar range (0.7 microM). This affinity is among the highest found for SH3/peptide complexes, suggesting that the identified stretch could have significance in vivo. The strategy outlined here is of more general applicability and may provide a valuable tool to identify potential partners of SH3 domains and of other peptide-binding modules.

Effect of pH and salt bridges on structural assembly: molecular structures of the monomer and intertwined dimer of the Eps8 SH3 domain

The SH3 domain of Eps8 was previously found to form an intertwined, domain-swapped dimer. We report here a monomeric structure of the EPS8 SH3 domain obtained from crystals grown at low pH, as well as an improved domain-swapped dimer structure at 1.8 A resolution. In the domain-swapped dimer the asymmetric unit contains two "hybrid-monomers." In the low pH form there are two independently folded SH3 molecules per asymmetric unit. The formation of intermolecular salt bridges is thought to be the reason for the formation of the dimer. On the basis of the monomer SH3 structure, it is argued that Eps8 SH3 should, in principle, bind to peptides containing a PxxP motif. Recently it was reported that Eps8 SH3 binds to a peptide with a PxxDY motif. Because the "SH3 fold" is conserved, alternate binding sites may be possible for the PxxDY motif to bind. The strand exchange or domain swap occurs at the n-src loops because the n-src loops are flexible. The thermal b-factors also indicate the flexible nature of n-src loops and a possible handle for domain swap initiation. Despite the loop swapping, the typical SH3 fold in both forms is conserved structurally. The interface of the acidic form of SH3 is stabilized by a tetragonal network of water molecules above hydrophobic residues. The intertwined dimer interface is stabilized by hydrophobic and aromatic stacking interactions in the core and by hydrophilic interactions on the surface.

High-affinity actin-binding nebulin fragments influence the actoS1 complex

Human nebulin fragments, NA3 and NA4, corresponding to individual superrepeats display high-affinity interactions with individual actin protomers in cosedimentation and solid-phase binding assays. Stoichiometric analysis of nebulin fragment-induced actin polymerization and inhibition of actin-activated S1 ATPase indicate that one superrepeat influences multiple actin molecules along the F-actin filament, consistent with a combination of strong and weak interactions of nebulin over the length of the actin filament. The mechanisms by which human nebulin fragments affect the interaction between actin and myosin S1 are studied by fluorescence quenching, polarization, and resonance energy transfer. We show that, under strong binding conditions, premixing actin with the NA3 prior to adding myosin subfragment 1 (S1) inhibits the rate of actoS1 association. The nebulin fragments, NA3 and NA4, caused little effect on the extent of actoS1 binding at equilibrium but did alter the nature of the complex as evidenced by an increase in the resonance energy transfer efficiencies between S1 and actin in the absence of ATP. The addition of low concentrations of ATP rapidly dissociates the strong-binding actoS1 irrespective of the presence or absence of nebulin fragment. Interestingly, the strongly bound state reforms rapidly after S1 hydrolyzes all available ATP. These observations are consistent with the notion that nebulin might contribute to optimizing the alignment of actomyosin interactions and inhibit suboptimal actomyosin contacts.

The design of a hyperstable mutant of the Abp1p SH3 domain by sequence alignment analysis

We have characterized the thermodynamic stability of the SH3 domain from the Saccharomyces cerevisiae Abp1p protein and found it to be relatively low compared to most other SH3 domains, with a Tm of 60 degrees C and a deltaGu of 3.08 kcal/mol. Analysis of a large alignment of SH3 domains led to the identification of atypical residues at eight positions in the wild-type Abp1p SH3 domain sequence that were subsequently replaced by the residue seen most frequently at that position in the alignment. Three of the eight mutants constructed in this way displayed increases in Tm ranging from 8 to 15 degrees C with concomitant increases in deltaGu of up to 1.4 kcal/mol. The effects of these substitutions on folding thermodynamics and kinetics were entirely additive, and a mutant containing all three was dramatically stabilized with a Tm greater than 90 degrees C and a deltaGu more than double that of the wild-type domain. The folding rate of this hyperstable mutant was 10-fold faster than wild-type, while its unfolding rate was fivefold slower. All of the stabilized mutants were still able to bind a target peptide with wild-type affinity. We have analyzed the stabilizing amino acid substitutions isolated in this study and several other similar sequence alignment based studies. In approximately 25% of cases, increased stability can be explained by enhanced propensity of the substituted residue for the local backbone conformation at the mutagenized site.

Distinct families of Z-line targeting modules in the COOH-terminal region of nebulin

To learn how nebulin functions in the assembly and maintenance of I-Z-I bands, MYC- and GFP- tagged nebulin fragments were expressed in primary cultured skeletal myotubes. Their sites of incorporation were visualized by double staining with anti-MYC, antibodies to myofibrillar proteins, and FITC- or rhodamine phalloidin. Contrary to expectations based on in vitro binding studies, none of the nebulin fragments expressed in maturing myotubes were incorporated selectively into I-band approximately 1.0-micrometer F-alpha-actin-containing thin filaments. Four of the MYC/COOH-terminal nebulin fragments were incorporated exclusively into periodic approximately 0.1-micrometer Z-bands. Whereas both anti-MYC and Rho-phalloidin stained intra-Z-band F-alpha-actin oligomers, only the latter stained the pointed ends of the polarized approximately 1.0-micrometer thin filaments. Z-band incorporation was independent of the nebulin COOH-terminal Ser or SH3 domains. In vitro cosedimentation studies also demonstrated that nebulin SH3 fragments did not bind to F-alpha-actin or alpha-actinin. The remaining six fragments were not incorporated into Z-bands, but were incorporated (a) diffusely throughout the sarcoplasm and into (b) fibrils/patches of varying lengths and widths nested among normal striated myofibrils. Over time, presumably in response to the mediation of muscle-specific homeostatic controls, many of the ectopic MYC-positive structures were resorbed. None of the tagged nebulin fragments behaved as dominant negatives; they neither blocked the assembly nor induced the disassembly of mature striated myofibrils. Moreover, they were not cytotoxic in myotubes, as they were in the fibroblasts and presumptive myoblasts in the same cultures.

Architecture of the thin filament-Z-line junction: lessons from nebulette and nebulin homologies

Nebulette and nebulin are homologous proteins associated with the Z-lines of cardiac and skeletal muscle sarcomeres. Although these proteins share 70% sequence homology and an identical domain layout, nebulette is one-tenth the size of nebulin. To define structurally important features of these proteins in terms of the Z-line architecture, we have analyzed the primary structure of nebulette and nebulin from a variety of species and developmental stages. Alignment of the 35 residue nebulin-like modules from both proteins demonstrates that the individual modules share 30-90% homology across the six proteins analyzed. In addition, this analysis demonstrates a number of areas in which the identity across the six proteins is as high as 75%. These areas may be important signals for Z-line assembly and function in the striated muscles. Significantly, most of the areas of high identity also coincide with consensus phosphorylation sites. To evaluate if nebulette, like nebulin, exhibits tissue-specific and developmental specific polymorphism, a series of immunoblot assays were performed. These data demonstrate that nebulettes from different portions of the heart are the same size. Comparison of nebulette from embryonic and adult cardiac muscle also demonstrates that this protein does not appear to vary in size with developmental stage. Consistent with the large number of consensus phosphorylation sites identified in the nebulette primary structure, we find that nebulette is phosphorylated in the cardiac muscle at serine and threonine residues. These data and sequence analyses are discussed in terms of current models for Z-line architecture.

Organization and ligand binding properties of the tail of Acanthamoeba myosin-IA. Identification of an actin-binding site in the basic (tail homology-1) domain

The Acanthamoeba myosin-IA heavy chain gene encodes a 134-kDa protein with a catalytic domain, three potential light chain binding sites, and a tail with separately folded tail homology (TH) -1, -2, and -3 domains. TH-1 is highly resistant to trypsin digestion despite consisting of 15% lysine and arginine. TH-2/3 is resistant to alpha-chymotrypsin digestion. The peptide link between TH-1 and TH-2/3 is cleaved by trypsin, alpha-chymotrypsin, and endo-AspN but not V8 protease. The CD spectra of TH-2/3 indicate predominantly random structure, turns, and beta-strands but no alpha-helix. The hydrodynamic properties of TH-2/3 (Stokes' radius of 3.0 nm, sedimentation coefficient of 1.8 S, and molecular mass of 21.6 kDa) indicate that these domains are as long as the whole myosin-I tail in reconstructions of electron micrographs. Furthermore, separately expressed and purified TH-1 binds with high affinity to TH-2/3. Thus we propose that TH-1 and TH-2/3 are arranged side by side in the myosin-IA tail. Separate TH-1, TH-2, and TH-2/3 each binds muscle actin filaments with high affinity. Salt inhibits TH-2/3 binding to muscle actin but not amoeba actin filaments. TH-1 enhances binding of TH-2/3 to muscle actin filaments at physiological salt concentration, indicating that TH-1 and TH-2/3 cooperate in actin binding. An intrinsic fluorescence assay shows that TH-2/3 also binds with high affinity to the protein Acan125 similar to the SH3 domain of myosin-IC. Phylogenetic analysis of SH3 sequences suggests that myosin-I acquired SH3 domain after the divergence of the genes for myosin-I isoforms.

Characterization of nebulette and nebulin and emerging concepts of their roles for vertebrate Z-discs

Nebulin is an 800 kDa large actin-binding protein specific to skeletal muscle and thought to act as a molecular template that regulates the length of thin filaments. Recently, a 100 kDa nebulin-like protein has been described in the avian cardiac muscle and referred to as nebulette. We have determined the full-length (8 kb) cDNA sequence of the human nebulette. Its open reading frame (3044 bp) encodes a 109 kDa protein that shares extensive similarity with the C-terminal region of human nebulin. The C-terminal regions of nebulin and nebulette are identical in domain organization and share a family of highly related C-terminal repeats, a serine-rich domain with potential phosphorylation sites, and an SH3 domain. Immunoelectron-microscopy suggests that the C-terminal 30 kDa of nebulin and nebulette filaments integrate into the Z-disc lattice, whereas their N termini appear to project into the I-band. Gene mapping studies assign the human nebulette gene to chromosome 10p12, whereas the nebulin gene has been previously assigned to 2q21. Evolutionary constraints appear to have maintained identical modular arrangements in these two independent genes. Comparison of nebulin and nebulette cDNAs demonstrates that a subgroup of repeats within the C-terminal regions is regulated tissue-specifically and stage-dependently during development of both molecules. This leads to a substantial diversity of nebulin and nebulette isoforms. Their further study is likely to provide insights into how they contribute to the molecular diversity of Z-discs from different muscle tissues and fiber types.