Abstract. The calcium release channel (CRC) from skeletal muscle is an unusually large tetrameric ion channel of the sarcoplasmic reticulum, and it is a major component of the triad junction, the site of excitation contraction coupling. The three-dimensional architecture of the CRC was determined from a random conical tilt series of images extracted from electron micrographs of isolated detergent-solubilized channels prepared in a frozen-hydrated state. Three major classes of fourfold symmetric images were identified, and three-dimensional reconstructions were determined for two of these. The two independent reconstructions were almost identical, being related to each other by a 180 ° rotation about an axis in the plane of the specimen grid.The CRC consists of a large cytoplasmic assembly (29 x 29 x 12 nm) and a smaller transmembrane assembly that protrudes 7 nm from one of its faces. A cylindrical low-density region, 2-3 nm in apparent diameter, extends down the center of the transmembrane assembly, and possibly corresponds to the transmembrane Ca2+-conducting pathway. At its cytoplasmic end this channel-like feature appears to be plugged by a globular mass of density. The cytoplasmic assembly is apparently constructed from 10 or more domains that are loosely packed together such that greater than 50% of the volume enveloped by the assembly is occupied by solvent. The cytoplasmic assembly is suggestive of a scaffolding and seems well adapted to maintain the structural integrity of the triad junction while allowing ions to freely diffuse to and away from the transmembrane assembly.I N striated muscle the calcium release channel (CRC) ~, also known as the ryanodine receptor, plays a key role in excitation-contraction coupling, the process by which neuronal-induced depolarization of the sarcolemma leads to release of calcium from the lumen of the sarcoplasmic reticulum (SR). The CRC is an intracellular integral membrane protein of the SR (for reviews see Fleischer and Inui, 1989;McPherson and Campbell, 1993). Depolarization of the sarcolemma causes the CRC to open by mechanisms (apparently different in cardiac and skeletal muscle) whose elucidation represents the central remaining problem in understanding excitation-contraction coupling.Several groups succeeded in purifying the CRC from skeletal muscle, and in reconstituting Ca 2+ channel activity in lipid bilayers (Inui et al
The activation mechanism of glycosylasparaginase of Flavobacterium meningosepticum has been analyzed by site-directed mutagenesis and activation of purified precursors in vitro. Mutation of Thr-152 to Ser or Cys leads to gene products that are not activated in vivo but are activated in vitro because processing of the mutant precursors is inhibited by certain amino acids in the cell. Kinetic studies reveal that activation is an intramolecular autoproteolytic process. The involvement of His-150 and Thr/Ser/Cys-152 in activation suggests that autoproteolysis resembles proteolysis by serine/cysteine proteases. Multiple functions of the highly conserved active threonine residue are implicated.
The structure of Endo H is very similar to that of Endo F1, a closely related endoglycosidase secreted by Flavobacterium meningosepticum. Detailed comparison of the structures of Endo H and Endo F1 supports the model previously proposed for substate binding and recognition, in which the area of loop 2 determines the substrate specificity and the alpha-helices of units 5 and 6 are missing to accommodate the protein moiety of the substrate.
Endo-beta-N-acetylglucosaminidase F1 (Endo F1) is an endoglycosidase, secreted by Flavobacterium meningosepticum, that cleaves asparagine-linked oligosaccharides after the first N-acetylglucosamine residue. The enzyme is selective for high-mannose oligosaccharide chains. The crystal structure of Endo F1 has been determined at 2.0-A resolution. The molecular fold consists of a highly irregular alpha/beta-barrel, a commonly observed motif consisting of a cyclic 8-fold repeat of beta-strand/loop/alpha-helix units with an eight-stranded parallel beta-barrel at the center. Endo F1 lacks two of the alpha-helices, those of units 5 and 6. Instead, the links after beta-strands 5 and 6 consist of a short turn followed by a section in an extended conformation that replaces the helix and a long loop at the bottom of the molecule. The absence of any excursion on top of the molecule following beta-strands 5 and 6 results in a pronounced depression in the rim of the barrel. This depression forms one end of a shallow cleft that runs across the surface of the molecule, over the core of the beta-barrel to the area between the loops of units 1 and 2. The active site residues, Asp130 and Glu132, are located at the carboxyl end of beta-strand 4 and extend into this cleft. These residues are surrounded by several tyrosine residues. The cleft area formed by loops 1 and 2 is lined with polar residues, mainly asparagines. The latter area is thought to be responsible for oligosaccharide binding and recognition while the protein moiety of the substrate would be located outside the molecule but adjacent to the area of loops 5 and 6.(ABSTRACT TRUNCATED AT 250 WORDS)
Sugar induced protein-protein interactions play an important role in several biological processes. The carbohydrate moieties of proteoglycans, the glycosaminoglycans, bind to growth factors with a high degree of specificity and induce interactions with growth factor receptors, thereby regulate the growth factor activity. We have used molecular modeling method to study the modes of binding of heparin or heparan sulfate proteoglycans (HSPGs) to bFGF that leads to the dimerization of FGF receptor 1 (FGFR1) and activation of receptor tyrosine kinase. Homology model of FGFR1 Ig D(II)-D(III) domains was built to investigate the interactions between heparin, bFGF and FGFR1. The structural requirements to bridge the two monomeric bFGF molecules by heparin or HSPGs and to simulate the dimerization and activation of FGFR1 have been examined. A structural model of the biologically functional dimeric bFGF-heparin complex is proposed based on: (a) the stability of dimeric complex, (b) the favorable binding energies between heparin and bFGF molecules, and (c) its accessibility to FGFR1. The modeled complex between heparin, bFGF and FGFR1 has a stoichiometry of 1 heparin: 2 bFGF: 2 FGFR1. The structural properties of the proposed model of bFGF/heparin/FGFR1 complex are consistent with the binding mechanism of FGF to its receptor, the receptor dimerization, and the reported site-specific mutagenesis and biochemical cross-linking data. In the proposed model heparin bridges the two bFGF monomers in a specific orientation and the resulting complex induces FGF receptor dimerization, suggesting that in the oligosaccharide induced recognition process sugars orient the molecules in a way that brings about specific protein-protein or protein-carbohydrate interactions.
Complexes of soybean agglutinin (SBA) with galactose (Gal) and N-acetyl galactosamine (GalNAc) have been modeled based on its homology to erythrina corallodendron (EcorL) lectin. The three dimensional structure of SBA-Gal modeled with homology techniques agrees well with SBA-(beta-LacNAc)2Gal-R complex determined by X-ray crystallographic techniques at the beta-sheet regions and the regions where Ca2+ and Mn2+ ions bind. However, significant deviations have been observed between the modeled and the X-ray structures, particularly at the loop regions where the polypeptide chain could not be unequivocally traced in the X-ray structure. The hydrogen bonding scheme, predicted from the homology model, shows that the invariant residues i.e. Asp, Gly, Asn, and aromatic residues (Phe) found in all other legume lectins, bind Gal, slightly in a different way than reported in X-ray structure of SBA-pentasaccharide complex. The higher binding affinity of GalNAc over Gal to SBA is due to additional hydrophobic interactions with Tyr107 rather than a hydrogen bond between N-acetamide group of the sugar and the side chain of Asp88 as suggested from X-ray crystal structure studies. Our modeling also suggest that the variation in the length of the loop D observed among galactose binding legume lectins may not have any effect on the binding of sugar at the monosaccharide specific site of the lectins. Soybean agglutinin (SBA) is a member of the leguminous family of lectins. They generally possess a single carbohydrate binding site, besides the tightly bound Ca2+ and Mn2+ ions which are required for their carbohydrate binding activity. They possess a high degree of sequence homology and about 50% of the amino acid residues are invariant. Some of these invariant amino acid residues are involved in the binding of sugar moieties and in metal ion coordination. X-ray crystallographic studies showed that their three-dimensional structures are very similar, though they differ in their carbohydrate binding specificity (1-6). Three of the invariant residues Asp, Gly, and Asn, besides an aromatic residue (Phe or Tyr), are involved in carbohydrate binding. Independent of their sugar specificity, these four residues in legume lectins provide the basic frame for the sugar to bind.
Endo-beta-N-acetylglucosaminidase H hydrolyzes the beta-(1-4)-glycosidic link of the N,N'-diacetylchitobiose core of high-mannose and hybrid asparagine-linked oligosaccharides. Seven mutants of the active site residues, Asp130 and Glu132, have been prepared, assayed, and crystallized. They include single site mutants of each residue to the corresponding amide, to Ala and to the alternate acidic residue, and to the double amide mutant. The mutants of Asp130 are more active than the corresponding Glu132 mutants, consistent with the assignment of the latter residue as the primary catalytic residue. The amide mutants are more active than the alternate acidic residue mutants, which in turn are more active than the Ala mutants. The structures of the Asn mutant of Asp130 and the double mutant are very similar to that of the wild-type enzyme. Several residues surrounding the mutated residues, including some that form part of the core of the beta-barrel and especially Tyr168 and Tyr244, adopt a very different conformation in the structures of the other two mutants of Asp130 and in the Asp mutant of Glu132. The results show that the residues in the upper layers of the beta-barrel can organize into two very distinct packing arrangements that depend on subtle electrostatic and steric differences and that greatly affect the geometry of the substrate-binding cleft. Consequently, the relative activities of several of the mutants are defined by structural changes, leading to impaired substrate binding, in addition to changes in functionality.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.