Cell Adhesion Molecule L1 in Folded (Horseshoe) and Extended Conformations

We have investigated the structure of the cell adhesion molecule L1 by electron microscopy. We were particularly interested in the conformation of the four N-terminal immunoglobulin domains, because x-ray diffraction showed that these domains are bent into a horseshoe shape in the related molecules hemolin and axonin-1. Surprisingly, rotary-shadowed specimens showed the molecules to be elongated, with no indication of the horseshoe shape. However, sedimentation data suggested that these domains of L1 were folded into a compact shape in solution; therefore, this prompted us to look at the molecules by an alternative technique, negative stain. The negative stain images showed a compact shape consistent with the expected horseshoe conformation. We speculate that in rotary shadowing the contact with the mica caused a distortion of the protein, weakening the bonds forming the horseshoe and permitting the molecule to extend. We have thus confirmed that the L1 molecule is primarily in the horseshoe conformation in solution, and we have visualized for the first time its opening into an extended conformation. Our study resolves conflicting interpretations from previous electron microscopy studies of L1.     

Structure and hydrodynamic properties of plectin molecules

Plectin is a cytoskeletal, high molecular weight protein of widespread and abundant occurrence in cultured cells and tissues. To study its molecular structure, the protein was purified from rat glioma C6 cells and subjected to chemical and biophysical analyses. Plectin's polypeptide chains have an apparent molecular weight of 300,000, as shown by one-dimensional sodium dodecyl sulfate/polyacrylamide electrophoresis. Cross-linking of non-denatured plectin in solution with dimethyl suberimidate and electrophoretic analyses on sodium dodecyl sulfate/agarose gels revealed that the predominant soluble plectin species was a molecule of 1200 X 10(3) Mr consisting of four 300 X 10(3) Mr polypeptide chains. Hydrodynamic properties of plectin in solution were obtained by sedimentation velocity centrifugation and high-pressure liquid chromatography analysis yielding a sedimentation coefficient of 10 S and a Stokes radius of 27 nm. The high f/fmin ratio of 4.0 indicated a very elongated shape of plectin molecules and an axial ratio of about 50. Shadowing and negative staining electron microscopy of plectin molecules revealed multiple domains: a rigid rod of 184 nm in length and 2 nm in diameter, and two globular heads of 9 nm diameter at each end of the rod. Circular dichroism spectra suggested a composition of 30% alpha-helix, 9% beta-structure and 61% random coil or aperiodic structure. The rod-like shape, the alpha-helix content as well as the thermal transition within a midpoint of 45 degrees C and the transition enthalpy (168 kJ/mol) of secondary structure suggested a double-stranded, alpha-helical coiled coil rod domain. Based on the available data, we favor a model of native plectin as a dumb-bell-like association of four 300 X 10(3) Mr polypeptide chains. Electron microscopy and turbidity measurements showed that plectin molecules self-associate into various oligomeric states in solutions of nearly physiological ionic strength. These interactions apparently involved the globular end domains of the molecule. Given its rigidity and elongated shape, and its tendency towards self-association, plectin may well be an interlinking element of the cytoskeleton that may also form a network of its own.     

Electron microscopy and hydrodynamic properties of factor XIII subunits

Factor XIII is a transglutaminase important in blood coagulation and fibrinolysis. Its function is to catalyze peptide bond formation between the gamma-carboxamide group of glutamines in one protein and the epsilon-amino group of lysine in another. There are two zymogenic forms of factor XIII: one is a noncovalent, intracellular dimer (A2); the other is a noncovalent, extracellular tetramer (A2B2). The catalytic function resides in the activated A chain (A2.). Purified forms of factor XIII (A2B2, A2, A2.B2, B) were prepared and analyzed by electron microscopy, gel filtration, and gradient centrifugation. Hydrodynamic constants were derived. Electron microscopy of rotary-shadowed molecules showed A2 to consist of two globular particles each about 6 x 9 nm in size. The A2 dimer is significantly elongated, 18 nm long and 6 nm in diameter. Sedimentation and gel filtration of the A2 dimer are consistent with this asymmetric structure. B protein is a filamentous, flexible strand with kinks, with a contour length of 30 nm and a diameter of approximately 2-3 nm. The sedimentation and gel filtration behavior of the B subunit are characteristic of a highly asymmetric molecule. The observed structure of the B subunit, combined with data for its amino acid sequence, suggests a modular structure. The B subunit is a member of a family of proteins composed of tandem, repeating structures (referred to as GP-I domains); the structure seen by electron microscopy for B subunit is probably applicable to all proteins in this family. Plasma and platelet factor XIII zymogens are tetrameric and dimeric, but B protein, in the absence of A protein, appears to be monomeric. Our model for the A2B2 zymogen has the elongated A2 dimer forming the core and the two B strands wrapping around the outside.     

Size and Shape of Protein Molecules at the Nanometer Level Determined by Sedimentation, Gel Filtration, and Electron Microscopy

An important part of characterizing any protein molecule is to determine its size and shape. Sedimentation and gel filtration are hydrodynamic techniques that can be used for this medium resolution structural analysis. This review collects a number of simple calculations that are useful for thinking about protein structure at the nanometer level. Readers are reminded that the Perrin equation is generally not a valid approach to determine the shape of proteins. Instead, a simple guideline is presented, based on the measured sedimentation coefficient and a calculated maximum S, to estimate if a protein is globular or elongated. It is recalled that a gel filtration column fractionates proteins on the basis of their Stokes radius, not molecular weight. The molecular weight can be determined by combining gradient sedimentation and gel filtration, techniques available in most biochemistry laboratories, as originally proposed by Siegel and Monte. Finally, rotary shadowing and negative stain electron microscopy are powerful techniques for resolving the size and shape of single protein molecules and complexes at the nanometer level. A combination of hydrodynamics and electron microscopy is especially powerful.     

Solution and surface effects on plasma fibronectin structure

As assessed by electron microscopy, the reported shape of the plasma fibronectin molecule ranges from that of a compact particle to an elongated, rod-like structure. In this study, we evaluated the effects of solution and surface conditions on fibronectin shape. Freeze-dried, unstained human plasma fibronectin molecules deposited at pH 7.0-7.4 onto carbon films and examined by scanning transmission electron microscopy appeared relatively compact and pleiomorphic, with approximate average dimensions of 24 nm X 16 nm. Negatively stained molecules also had a similar shape but revealed greater detail in that we observed irregular, yarn-like structures. Glutaraldehyde-induced intramolecular cross-linking did not alter the appearance of plasma fibronectin. Molecules deposited at pH 2.8, pH 9.3, or after succinylation were less compact than those deposited at neutral pH. In contrast, fibronectin molecules sprayed onto mica surfaces at pH 7, rotary shadowed, and examined by transmission electron microscopy were elongated and nodular with a contour length of 120-130 nm. Sedimentation velocity experiments and electron microscopic observations indicate that fibronectin unfolds when it is succinylated, when the ionic strength is raised at pH 7, or when the pH is adjusted to 9.3 or 2.8. Greater unfolding is observed at pH 2.8 at low ionic strength (less than 0.01) compared with material at that pH in 0.15 M NaCl solution. We conclude that (a) the shape assumed by the fibronectin molecule can be strongly affected by solution conditions and by deposition onto certain surfaces; and that (b) the images of fibronectin seen by scanning transmission electron microscopy at neutral pH on carbon film are representative of molecules in physiologic solution.     

Structural characteristics of the desmin protofilament

Biochemical investigations of intermediate filaments in soluble or partially assembled forms are often difficult to perform due to the unusual insolubility of most types of intermediate filaments. However, desmin is soluble in 10 mM Tris. The structure of partially soluble native desmin was studied by gel-filtration chromatography and electron microscopy. The lowest molecular weight species of soluble desmin is a flexible rod averaging 53 nm in length. Calculations of f/fmin values from a previously published sedimentation value allowed comparisons with other elongated proteins. These values and the dimensions obtained from electron microscopy suggest that the desmin protofilament contains three or four protein subunits.     

Properties of talin from chicken gizzard smooth muscle

This paper describes the structural and biochemical characterization of talin, a protein localized to various cellular sites where bundles of actin filaments attach to the plasma membrane. By sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the protein has a molecular mass of 225,000 +/- 5,000 daltons. Hydrodynamic measurements at protein concentrations less than 0.72 mg/ml indicate a monomeric protein with a native molecular mass of 213,000 +/- 15,000 daltons. Sedimentation equilibrium experiments indicate self-association at protein concentrations of 0.72 mg/ml and higher. The data suggest that this self-association is a simple monomer:dimer equilibrium over the range of concentrations observed. At low protein concentrations where talin is a monomer, the Stokes radius and sedimentation coefficient vary with ionic strength. Under low ionic strength conditions (5-20 mM NaCl), talin has a Stokes radius of 6.5 nm and a sedimentation value of 9.4, suggesting an asymmetric globular molecule; whereas under high ionic strength conditions (200 mM NaCl), the Stokes radius increases to 7.7 nm and the sedimentation coefficient decreases to 8.8, suggesting a more elongated protein. This conformation change is confirmed by electron microscopy which reveals a more globular protein at low ionic strength which unfolds to become an elongated flexible molecule as the ionic strength is increased to physiological and higher levels. The amino acid composition of talin indicates a low level of aromatic residues, consistent with its relatively low extinction coefficient, talin has an isoelectric point between pH 6.7 and 6.8 based on isoelectric focusing. The detailed purification of talin is described.     

First images of a glutamate receptor ion channel: oligomeric state and molecular dimensions of GluRB homomers.

We have expressed, purified, and characterized glutamate receptor ion channels (GluR) assembled as homomers of the subunit GluRB. For the first time, single-milligram quantities of biochemically homogeneous GluR have been obtained. The protein exhibits the expected pharmacological profile and a high specific activity for ligand binding. Density-gradient centrifugation reveals a uniform oligomeric assembly and a molecular mass suggesting that the channel is a tetramer. On the basis of electron microscopic images, the receptor appears to form an elongated structure that is visualized in several orientations. The molecular dimensions of the molecule are approximately 11 x 14 x 17 nm, and solvent-accessible features can be seen; these may contribute to formation of the ion-conducting pathway of the channel. The channel dimensions are consistent with an overall 2-fold symmetric assembly, suggesting that the tetrameric receptor may be a dimer of dimers.     

Molecular properties of bovine interphotoreceptor retinol-binding protein

Interphotoreceptor retinol-binding protein (IRBP) is a large retinol-carrying glycoprotein, located only in the interphotoreceptor (or subretinal) space of vertebrate eyes. It has recently been purified to apparent homogeneity. The present report presents its sedimentation, spectroscopic, and binding properties. The molecular weight of bovine IRBP, determined by sedimentation equilibrium, is 133,000. The sedimentation coefficient is 5.8S. The Stokes radius, 56 A, obtained from gel-filtration chromatography, is much larger than that expected for a globular protein of the same molecular weight. These results indicate that IRBP is asymmetric (it can modeled as a prolate ellipsoid of revolution with axial ratio of about 8:1) and explain the overestimates of molecular weight obtained in previous studies based on size-exclusion methods. The molar absorption coefficients for IRBP (at 280 nm) and for bound retinol are both unaffected by ligand dissociation. Fluorescence of the holoprotein displays neither fine structure nor energy transfer from tryptophan to bound retinol. Circular dichroism suggests a secondary structure containing approximately 15% alpha-helix and approximately 20% beta-structure, unchanged by the presence of ligand. The binding of retinol creates a positive, extrinsic Cotton effect at 330 nm, proportional to the amount of retinol bound. The apparent dissociation constant for all-trans-retinol is 1.3 X 10(-6) M. This relatively loose binding implies that, if required during the visual cycle, IRBP should be able to transfer its ligand to other binding proteins in the neural retina and retinal pigment epithelium.     

Ultrastructural characterization of embryonic chick cartilage proteoglycan core protein and the mapping of a monoclonal antibody epitope.

The ultrastructure of embryonic chick cartilage proteoglycan core protein was investigated by electron microscopy of specimens prepared by low angle shadowing. The molecular images demonstrated a morphological substructural arrangement of three globular and two linear regions within each core protein. The internal globular region (G2) was separated from two terminally located globular regions (G1 and G3) by two elongated strands with lengths of 21 +/- 3 nm (E1) and 105 +/- 22 nm (E2). The two N-terminal globular regions, separated by the 21-nm segment, were consistently visualized in well spread molecules and showed little variation in the length of the linear segment connecting them. The E2 segment, however, was quite variable in length, and the C-terminal globular region (G3) was detected in only 53% of the molecules. The G1, G2, and G3 regions in chick core protein were 10.1 +/- 1.7 nm, 9.7 +/- 1.3 nm, and 8.3 +/- 1.3 nm in diameter, respectively. These results are similar to those described previously for proteoglycan core proteins isolated from rat chondrosarcoma, bovine nasal cartilage, and pig laryngeal cartilage (Paulsson, M., Morgelin, M., Wiedemann, H., Beardmore-Gray, M., Dunham, D., Hardingham, T., Heinegard, D., Timpl, R., and Engel, J. (1987) Biochem. J. 245, 763-772). However, a significant difference was detected between the length of the elongated strand (E2) of core proteins isolated from chick cartilage, E2 length = 105 +/- 22 nm, compared to bovine nasal cartilage, E2 length = 260 +/- 39 nm. The epitope of the proteoglycan core protein-specific monoclonal antibody, S103L, was visualized by electron microscopy, and the distance from the core protein N terminus to the S103L binding site was measured. The S103L binding site was localized to the E2 region, 111 +/- 20 nm from the G1 (N terminus) domain and 34 nm from the G3 (C terminus) domain. cDNA clones selected from an expression vector library of chicken cartilage mRNA also show this epitope to be located near the C-terminal region (R. C. Krueger, T. A. Fields, J. Mensch, and B. Schwartz (1990) J. Biol. Chem. 265, 12088-12097).     

Replication of simian virus 40 DNA after UV irradiation: evidence of growing fork blockage and single-stranded gaps in daughter strands.

The molecular mechanisms of in vivo inhibition of mammalian DNA replication by exposure to UV light (at 254 nm) was studied in monkey and human cells infected with simian virus 40. Analysis of viral DNA by electron microscopy and sucrose gradients confirmed that the presence of UV-induced lesions severely blocks DNA synthesis, and thus the conversion of replicative intermediates (RIs) into fully replicated form I DNA is inhibited by UV irradiation. These blocked RI molecules present several special features when visualized by electron microscopy. (i) In excision repair-proficient monkey and human cells they are composed of a double-stranded circular DNA with a double-stranded tail whose size corresponds to the average interpyrimidine dimer distance, as determined by the dimer-specific T4 endonuclease V. (ii) In excision repair-deficient human cells from patients with xeroderma pigmentosum, UV-irradiated RIs present a Cairns-like structure similar to that observed for replicating molecules obtained from unirradiated infected cells. (iii) Single-stranded gaps are visualized in the replicated portions of UV-irradiated RI molecules; such regions are detected and clearly distinguishable from double-stranded DNA when probed by a specific single-stranded DNA-binding protein such as the bacteriophage T4 gene 32 product. Consistent with the presence of gaps in UV-irradiated RI molecules, single-strand-specific S1 nuclease digestion causes a shift in their sedimentation properties when analyzed in neutral sucrose gradients compared with undamaged molecules. These results are in agreement with and reinforce the model in which UV lesions are a barrier to the replication fork movement when present in the template for the leading strand; when lesions are in the template for the lagging strand they inhibit synthesis or completion of Okazaki fragments, leaving gaps opposite the lesion. Moreover, cellular DNA repair-linked endonucleolytic activity may induce double-stranded breaks in the blocked region of the replication forks, resulting in the tailed structures observed in viral DNA molecules obtained from excision repair-proficient cell lines.     

The two coiled coils in the isolated rod domain of the intermediate filament protein desmin are staggered. A hydrodynamic analysis of tetramers and dimers

Desmin protofilaments and the proteolytically derived alpha-helical rod domain have been characterized by high-resolution gel permeation chromatography (GPC) using columns calibrated for the determination of viscosity radii. Additional characterization by chemical cross-linking and the determination of sedimentation values allowed the calculation of the molecular dimensions of the molecular species isolated. In dilute buffers GPC separated desmin rod preparations into two complexes: a dimer species (single coiled coil) with a length of 50 +/- 5 nm and a tetramer species (two coiled coils) with a length of 65 +/- 5 nm. Thus the two coiled coils in the tetramer are staggered by approximately 15 nm. The hydrodynamically derived lengths of the rod dimer and tetramer are supported by electron microscopy after metal shadowing. The hydrodynamic properties of desmin protofilaments follow that of the rod tetramer. The data on the hydrodynamic analysis of the rod tetramer of desmin in solution are in full agreement with the structural information recently deduced from paracrystals of the rod of glial fibrillary acid protein [Stewart, M., Quinlan, R.A. & Moir, R.D. (1989) J. Cell Biol. 109, 225-234]. Our results explain the inhomogeneity of molecules encountered in previous electron microscopical analyses.     

Molecular shape and self-association of vinculin and metavinculin

Vinculin, a 130,000-dalton protein localized to adhesion plaques, and metavinculin, a 150,-000 dalton protein closely related to vinculin, have been studied using rotary shadowing and electron microscopy. Both proteins have globular head regions attached to rod-shaped tail domains. Vinculin and metavinculin also both form complexes consisting of four to six individual molecules. These multimers are formed by head-to-head as well as tail-to-tail interactions. Talin, another protein which has been localized to adhesion plaques and binds to both vinculin and metavinculin, has also been investigated using shadowing techniques. Talin is an elongated, flexible molecule in high ionic strength buffers, as shown here by rotary shadowing and negative stain electron microscopy.     

Isolation and characterization of monkey interphotoreceptor retinoid-binding protein, a unique extracellular matrix component of the retina

The interphotoreceptor retinoid-binding protein (IRBP) has been isolated from monkey interphotoreceptor matrix (IPM). Following gentle washing of the IPM from the retinal surface, the protein was purified to homogeneity by concanavalin A-Sepharose affinity chromatography, ion-exchange high-performance liquid chromatography (HPLC), and size-exclusion HPLC. Bovine IRBP was purified similarly and compared with the monkey protein. Sedimentation equilibrium analysis yielded a molecular weight of 106 000 +/- 2900 for the native monkey protein. Sedimentation velocity analysis gave a sedimentation coefficient of 5.4 +/- 0.3 S and a frictional ratio of 1.59, indicating an asymmetrical molecular shape. IRBP contains neutral sugar, including fucose, and sialic acid; the glycoprotein nature of the proteins probably accounts for the microheterogeneity observed in the electrofocusing pattern of both bovine and monkey IRBP. Both IRBPs have isoelectric points between 6.0 and 7.0. The fluorescence emission lambda max of the bound ligand was 470 nm with excitation at 340 nm, while the excitation lambda max was 333 nm with emission at 470 nm, for monkey IRBP incubated with exogenous all-trans-retinol. The amino acid compositions of the monkey and bovine proteins are similar; nonpolar amino acids account for over 50% of the residues, which may explain the apparent hydrophobic nature of the isolated proteins. The amino-terminal analyses indicated considerable homology between the monkey and bovine IRBPs in this region and verified the purity of the isolated proteins. IRBP thus appears to be a unique, conserved glycoprotein of the retinal extracellular matrix that could serve as a retinoid-transport vehicle.     

Purification and analysis of authentic CLIP-170 and recombinant fragments.

We have purified authentic CLIP-170 (cytoplasmic linker protein of 170 kDa) and fragments comprising functional domains of the protein to characterize the structural basis of the function of CLIP-170. Analysis of authentic CLIP-170 and the recombinant fragments by electron microscopy after glycerol spraying/low angle rotary metal shadowing reveals CLIP-170 as a thin, 135-nm-long molecule with two kinks in its central rod domain, which are approximately equally spaced from the two ends of the protein. The central domain consisting of heptad repeats, which is alpha-helical in nature and forms a 2-stranded coiled-coil, mediates dimerization of CLIP-170. The rod domain harbors two kinks, each spaced approximately 37 nm from the corresponding end of the molecule, thus providing mechanical flexibility to the highly elongated molecule. The N-terminal domain of CLIP-170 binds to microtubules in vitro with a stoichiometry of one dimeric head domain per four tubulin heterodimers. Authentic CLIP-170 binds to microtubules with lower stoichiometry, indicating that the rod and tail domains affect microtubule binding of CLIP-170. These results document that CLIP-170 is a highly elongated polar molecule with the microtubule-binding domain and the organelle-interacting domains at opposite ends of the homodimer, thus providing a structural basis for the function of CLIP-170 as a microtubule-organelle linker protein.     

Properties of chicken cardiac dystrophin.

We investigated the presence of dystrophin by immunoblot and immunofluorescence analyses, negative staining, rotatory shadowing and immunogold electron microscopy in chicken cardiac muscle. Saponin was found to be better than Triton X-100 for providing a new 'dystrophin-enriched' solution for use in biochemical studies of the molecule. By Western blot analysis, only a 400-kDa band was revealed with polyclonal antibodies directed against a central region (residues 1178-1723) of the dystrophin molecule and no cross-reactions with other proteins or degraded products were observed. Specific cleavage of the dystrophin molecule showed that the central rod-shaped domain corresponded to a resistant 'core'. This structure might rigidify the protein. By immunofluorescence, dystrophin was localized at the periphery of cardiac ventricular cells. The molecule was examined by electron microscopy and found to have variable lengths (140-160 nm for the monomeric from and about 260 +/- 10 nm or more for oligomeric forms). These oligomeric structures are considered to be associated molecules which are only partially overlapped lengthwise. The precise distribution of dystrophin within the cardiac muscle was determined by visualisation of gold particles in immuno-electron microscopy. Gold particles were found on the sarcolemma with no evidence of any association with cytoplasmic structures. The present data provide further details on the cardiac dystrophin molecule and suggest that its capacity of self-association may elasticize the dystrophin dimer.     

The tetrameric form of ribosomal protein L7/L12 from Escherichia coli

A tetrameric form of the ribosomal protein L7/L12 has been prepared and its structure studied by using hydrodynamic methods, photon correlation spectroscopy, and small angle x-ray scattering. The tetrameric nature of the protein preparation is confirmed by three independent determinations of its molecular weight, with analysis of accurate sedimentation equilibrium data giving the most reliable estimate. The species has a Stokes radius of 4.0 +/- 0.1 nm and an absolute frictional ratio of 1.7. Taken together, the hydrodynamic measurements suggest the possibility of a flat structure, and this is consistent with the x-ray scattering results. The molecule has a radius of gyration of 3.6 +/- 0.05 nm and a maximum dimension of 11-12 nm. A geometric model consisting of four elongated monomers, arranged in a plane, is proposed.     

Compaction of single molecules of supercoiled DNA immobilized on amino mica: from duplex to minitoroidal and spheroidal conformations

Supercoiled DNA pGEMEX with a length of 3993 nucleotides was immobilized on various substrates (freshly cleaved mica, standard amino mica, and modified amino mica) and visualized by atomic force microscopy. Plectonemically supercoiled DNA molecules and molecules with an extremely high level of compaction were visualized on modified amino mica, which was characterized by increased surface charge density. It was found that the length of the superhelix axis decreases two and four times to form superhelix axes of the second and third orders as the DNA compaction level increases because of the twice folding of DNA molecules. In this case, the length of the superhelix axis decreases from L approximately 470 nm to L approximately 140 nm (which corresponds to 10% contour length of a relaxed molecule on assumption of B-DNA) to form minitoroids and spheroids of approximately 50 nm diameter. Note that the previously reported experimentally measured length of the superhelix axis was equal to 35% contour length of the relaxed DNA molecule at the maximal density of the superhelix. Our data show that the significant decrease in the length of superhelix axis and the compaction of single supercoiled DNA molecules to the level of spheroids and minitoroids are caused by the screening of negatively charged DNA phosphate groups by positively charged amino groups of the modified amino mica because of its high surface charge density and increased hydrophobicity compared with standard amino mica.     

Proteolytic substructure of brain myosin

Individual bovine brain myosin molecules visualized by electron microscopy consist of two globular heads and a fibrous tail, like myosin molecules from other sources. Brain myosin, however, showed much lower solubility at moderate to high ionic strength (0.2 to 0.4 M KCl) than gizzard myosin, and the filaments formed at low ionic strength in the presence of Mg2+ were fairly resistant to low concentrations of ATP, by which gizzard myosin filaments were completely solubilized. Brain myosin was digested with low concentrations of papain, alpha-chymotrypsin, or trypsin, and the fragmentation patterns were analyzed by means of polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate, sedimentation at low ionic strength, and electron microscopy of the fragments produced. The results indicate that all of the proteases cleave the myosin molecule primarily at sites located in the neck or in the head close to the neck, suggesting that the brain myosin molecule contains a hinge region or an open peptide stretch around these sites. The differences as well as the similarities between the proteolytic fragmentation patterns of brain myosin and other myosins are discussed.     

Purification and characterization of a retinol-binding glycoprotein synthesized and secreted by bovine neural retina

A retinol-binding glycoprotein ( IRBP ) was purified in milligram quantities from the extracellular matrix ( interphotoreceptor matrix) that occupies the subretinal space in bovine eyes. IRBP binds 2.2 molecules of all-trans retinol with a KD of approximately 10(-6) M. The holoprotein has lambda max at 280 nm (E1%1 cm = 10.99) and at 330 nm (E1%1 cm = 7.88). When freshly isolated from light-exposed eyes, IRBP contains up to 0.6 molecule of all-trans retinol, together with small amounts of the 11-cis and 13-cis isomers. IRBP also binds exogenous cholesterol, alpha-tocopherol, and all-trans retinoic acid, all of which are completely displaced by all trans retinol. The affinity of alpha-tocopherol for IRBP was at least several orders of magnitude less than that of all-trans retinol. IRBP contains 8.4% by weight of carbohydrate, which consists of sialic acid, neutral hexoses, and glucosamine in the molar ratio of approximately 1:3:2. No galactosamine was detected. Observations on the binding of 125I-labeled lectins to IRBP in sodium dodecyl sulfate-polyacrylamide gels before and after desialosylation suggest that at least one oligosaccharide chain is of the sialated biantennary complex type and contains fucose. The Mr of IRBP on calibrated size-exclusion columns averaged 249,000; on sodium dodecyl sulfate-polyacrylamide gels (with or without dithiothreitol) the apparent Mr was 144,000. IRBP exists in at least four isoelectric forms that bind concanavalin A and have pI values ranging from 4.4 to 4.8. Rabbit anti-bovine IRBP antiserum gave a single precipitin line against purified bovine IRBP , which showed a line of complete identity with crude bovine interphotoreceptor matrix and a line of partial identity with human interphotoreceptor matrix. The human material contains a prominent protein with lectin-binding properties similar to bovine IRBP but with a somewhat faster electrophoretic mobility. When isolated bovine neural retinas were incubated with 3H-labeled fucose, glucosamine, or leucine, a solitary labeled protein identified as IRBP was secreted into the medium. Labeled IRBP could not be detected in the medium when retinal pigment epithelium was incubated with these precursors under the same conditions. Neural retinas incubated with 3H-labeled leucine in the presence of tunicamycin secreted a form of IRBP that did not bind concanavalin A and had an Mr reduced by approximately 5,000.