Characterization of proteolytic fragments of the laminin-nidogen complex and their activity in ligand-binding assays

Some 12 new nidogen and laminin fragments were purified from elastase, thrombin and trypsin digests and characterized by their sizes (22 kDa to greater than 300 kDa), subunit patterns on electrophoresis, partial amino acid sequences, content of specific epitopes and their binding to laminin or nidogen structures in radioligand assays. This permitted the various fragments to be ordered along the dumbbell-shaped structure of nidogen and to compare them with previously described nidogen fragments arising by endogenous proteolysis. Two nidogen fragments (E-50, E-90; 50 kDa and 90 kDa) remain associated with a large laminin fragment in elastase digests of the complex and could be dissociated with 2 M guanidine.HCl. Recombination studies demonstrated Kd = 10-20 nM for this interaction. Nidogen fragments devoid of binding activity included the tryptic peptide T-40 (40 kDa) corresponding to the rod-like domain and several larger fragments extending more to the N-terminus of nidogen. An N-terminal thrombin fragment of about 50 kDa was also inactive. Together the data show a lack of laminin binding to the N-terminal globule and rod of nidogen and provide indirect evidence that this activity is located within or close to its C-terminal globular domain. Nidogen-binding structures of laminin were obtained as two large fragments (greater than 300 kDa), P1X and E1X. They correspond to the short arm structure of laminin with one (E1X) or two (P1X) arms decreased in size to the inner rod-like segment. Shortening in E1X is mainly due to the B1 chain segment including the central globular domain which was identified as a new laminin fragment E10. Binding of E1X and P1X to nidogen was comparable to that of laminin while much lower activity was found for other laminin fragments. A 10-fold lower binding potential was also observed for the laminin-nidogen complex whose structure can now be defined in more precise molecular terms.     

Nidogen: a new, self-aggregating basement membrane protein

Nidogen was purified from a mouse tumor basement membrane where it accounted for 2-3% of the total proteins. It was isolated as two forms (A and B) of a monomer (Mr = 80000) each consisting of a single polypeptide chain folded into a globular head connected to a small tail. The B form of the monomer was shown to be capable of aggregating into a nest-like structure (Mr greater than 250000). A smaller form (Mr = 45000) was observed in some of the extracts. The amino acid composition of nidogen was different to that of other basement membrane proteins. It contained about 10% carbohydrate, with N-linked and O-linked oligosaccharide chains in similar proportions. Isoelectrofocussing demonstrated a limited heterogeneity of nidogen with pI in the range 6.5 - 7. Monomeric nidogen failed to interact with other basement membrane components and heparin. Aggregation could be induced by limited proteolysis and was reversed by detergents or high salt concentrations. Together with the observation that most of the nidogen could be solubilized only after destroying the collagenous matrix, the data indicate that aggregation of nidogen reflects an activity involved in matrix assembly. Specific antibodies raised against nidogen did not distinguish between the monomeric and aggregated form of the protein but showed that the fragment was antigenically deficient. These antibodies did not cross-react with collagen type IV, laminin, entactin and heparansulfate proteoglycan. Immunofluorescence staining and absorption studies demonstrated that nidogen is a common component of authentic basement membranes. Larger forms of nidogen (Mr about 100000 and 150000) were found in organ cultures of Reichert's membrane suggesting that it is synthesized in precursor forms.     

Isolation and characterization of tryptic fragments of the adenosine triphosphatase of sarcoplasmic reticulum.

Exposure of sarcoplasmic reticulum to trypsin in the presence of 1 M sucrose results in degradation of the Mr = 102,000 ATPase enzyme to two fragments of Mr = 55,000 and 45,000 with subsequent appearance of fragments of Mr = 30,000 and 20,000. These fragments were purified by column chromatography in sodium dodecyl sulfate. Antibodies were raised against the ATPase and the Mr = 55,000, 45,000, and 20,000 fragments. There was no antigenic cross-reactivity between the Mr = 55,000 and 45,000 fragments, indicating that they were derived from a single linear cleavage of the larger enzyme. There was antigenic cross-reactivity between the Mr = 20,000 and 55,000 fragments, indicating an origin of the Mr = 20,000 fragment in the Mr = 55,000 fragment. None of the antibodies inhibited (Ca2+ + Mg2+)-dependent ATPase or Ca2+ transport. The Mr = 20,000 fragment and the Mr = 55,000 fragment were active in Ca2+ ionophore assays. The active site of ATP hydrolysis was labeled with [gamma-32P]ATP and the site of ATP binding was labeled with tritiated N-ethylmaleimide. In both cases radioactivity was found in the intact ATPase and in the Mr = 55,000 and 30,000 fragments, indicating that the Mr = 30,000 fragment was also derived from the Mr = 55,000 fragment. Amino acid composition data showed that the Mr = 45,000 fragment contained about 60% nonpolar and 40% polar amino acids, while the Mr = 55,000 fragment and the Mr = 20,0000 fragment contained about equal amounts of polar and nonpolar amino acids. Studies of the reaction of various antibodies at the external surface of sarcoplasmic reticulum vesicles showed that the ATPase was exposed, whereas calsequestrin and the high affinity Ca2+-binding protein were not. The use of antibodies against the various fragments indicated that the Mr = 55,000 fragment was in large part exposed, whereas the Mr = 20,000 and the 45,000 fragments were only poorly exposed. It is probable that the site of ATP hydrolysis in the Mr = 55,000 fragment is external, whereas the ionophore site is only partially exposed and the Mr = 45,000 fragment is largely buried within the membrane.     

Structural inferences for the native skeletal muscle sodium channel as derived from patterns of endogenous proteolysis

The alpha subunit (Mr approximately 260,000) of the rat skeletal muscle sodium channel is sensitive to cleavage by endogenous proteases during the isolation of muscle surface membrane. Antisera against synthetic oligopeptides were used to map the resultant fragments in order to identify protease-sensitive regions of the channel's structure in its native membrane environment. Antibodies to the amino terminus labeled major fragments of Mr approximately 130,000 and 90,000 and lesser amounts of other peptides as small as Mr approximately 12,000. Antisera to epitopes within the carboxyl-terminal half of the primary sequence recognized two fragments of Mr approximately 110,000 and 78,000. Individual antisera also selectively labeled smaller polypeptides in the most extensively cleaved preparations. The immunoreactivity patterns of monoclonal antibodies previously raised against the purified channel were then surveyed. The binding sites for one group of monoclonals, including several that recognize subtype-specific epitopes in the channel structure, were localized within a 12-kDa fragment near the amino terminus. The distribution of carbohydrate along the primary structure of the channel was also assessed by quantitating 125I-wheat germ agglutinin and 125I-concanavalin A binding to the proteolytic peptides. Most of the carbohydrate detected by these lectins was located between 22 and 90 kDa from the amino terminus of the protein. No lectin binding was detected to fragments arising from carboxyl-terminal half of the protein. These results were analyzed in terms of current models of sodium channel tertiary structure. In its normal membrane environment, the skeletal muscle sodium channel appears sensitive to cleavage by endogenous proteases in regions predicted to link the four repeat domains on the cytoplasmic side of the membrane while the repeat domains themselves are resistant to proteolysis.     

Characterization of porcine plasma fibronectin and its fragmentation by porcine liver cathepsin B

Fibronectin was isolated from porcine plasma by affinity chromatography with gelatin-linked Sepharose 4B. Porcine fibronectin had a chemical composition similar to those of human and other fibronectins and reacted with antiserum raised against human fibronectin. It showed hemagglutination activity with trypsin-treated rabbit erythrocytes, though the activity was far less than that of human fibronectin. Porcine plasma fibronectin consisted of two subunit chains of about 230,000-daltons linked by disulfide bonds(s). Limited proteolysis of this protein with porcine liver cathepsin B yielded five major fragments which were investigated by affinity chromatography with gelatin- and heparin-linked Sepharose 4B. One fragment (Mr = 50,000) was bound to gelatin but not to heparin, while the remaining four were bound to heparin but not to gelatin, suggesting that plasma fibronectin takes a discrete domain structure with respect to interaction with these two macromolecules. The three larger heparin-binding fragments, Mr = 175,000, 150,000, and 130,000 were eluted with different concentrations of a mixture of NaCl and urea from the heparin-column, suggesting that they have different interactions with heparin, the 130,000-dalton fragment being the one with the strongest interaction. After reduction with 2-mercaptoethanol, the 175,000-dalton fragment was converted to the 150,000-dalton region fragment, which, together with the unchanged 150,000-dalton fragment, appeared to be equivalent in amount to the 130,000-dalton fragment. This finding suggests that the 150,000- and 130,000-dalton fragments may have originated from different subunit chains. Since the 175,000-dalton fragment was not produced by cathepsin B digestion of fibronectin which had been treated with plasmin, it was concluded that the 175,000-dalton fragment contained interchain disulfide bond(s) which had linked the native subunit chains. These results suggest that porcine plasma fibronectin has non-identical subunit chains composed of domains which differ in interaction with heparin and in susceptibility to cathepsin B.     

Identification and extraction of proteins that compose the triad junction of skeletal muscle

Treatment of both transverse tubules and terminal cisternae with a combination of Triton X-100 and hypertonic K cacodylate causes dissolution of nonjunctional proteins and selective retention of membrane fragments which are capable of junction formation. Treatment of vesicles with Triton X-100 and either KCl or K gluconate causes complete dissolution of all components. Therefore K cacodylate exerts a specific preservative action on the junctional material. The membrane fragment from treatment of transverse tubules with Triton X-100 + cacodylate contains a protein of Mr = 80,000 in SDS gel electrophoresis as the predominant protein while lipid composition is enriched in cholesterol. The membrane fragment retains in electron microscopy the trilaminar appearance of the intact vesicles. Freeze fracture of transverse tubule fragments reveals a high density of low-profile, intercalated particles, which frequently form strings or occasional small arrays. The fragments from Triton X-100 plus cacodylate treatment of terminal cisternae include the protein of Mr = 80,000 as well as the spanning protein of the triad, calsequestrin, and some minor proteins. The fragments are almost devoid of lipid and display an amorphous morphology suggesting membrane disruption. The ability of the transverse tubular fragment, which contains predominantly the Mr = 80,000 protein, to form junctions with terminal cisternae fragments suggests that it plays a role in anchoring the membrane to the junctional processes of the triad. The junctional proteins may be solubilized in a combination of nonionic detergent and hypertonic NaCl. Subsequent molecular sieve chromatography gives an enriched preparation of the spanning protein. This protein has subunits of Mr = 300,000, 270,000 and 140,000 and migrates in the gel as a protein of Mr = 1.2 X 10(6) indicating a polymeric structure.     

Alignment of biologically active domains in the fibronectin molecule

Gelatin-binding material was isolated from a human plasma cryoprecipitate by affinity chromatography on gelatin-Sepharose. Individual fragments of fibronectin with Mr = 170,000, 100,000, and 80,000 and a mixture of fragments with Mr = 205,000 and 190,000 (200K fraction) were isolated from this material. These fragments reacted with antifibronectin and with antibodies to a gelatin-binding Mr = 70,000 tryptic fragment of fibronectin. They all shared the same NH2-terminal amino acid sequence. The 205K and 190K fragments bound also to heparin-Sepharose, whereas the smaller fragments did not. The 200K fraction and the 170K fragment mediated cell attachment when used to coat plastic, whereas the 100K and 80K fragments were inactive in this assay. Further digestion of the 205K and 190K fragments with chymotrypsin yielded separate sets of smaller fragments that bound to either gelatin-Sepharose or heparin-Sepharose, as well as fragments that did not show either of these binding activities but mediated cell attachment. Since the NH2-terminal ends of the 205K, 190K, 100K, and 80K fragments are the same, the results define the order of the active sites in the fibronectin molecule as gelatin-binding site, cell attachment site, and heparin-binding site.     

Amino acid sequence of mouse nidogen, a multidomain basement membrane protein with binding activity for laminin, collagen IV and cells.

The whole amino acid sequence of nidogen was deduced from cDNA clones isolated from expression libraries and confirmed to approximately 50% by Edman degradation of peptides. The protein consists of some 1217 amino acid residues and a 28-residue signal peptide. The data support a previously proposed dumb-bell model of nidogen by demonstrating a large N-terminal globular domain (641 residues), five EGF-like repeats constituting the rod-like domain (248 residues) and a smaller C-terminal globule (328 residues). Two more EGF-like repeats interrupt the N-terminal and terminate the C-terminal sequences. Weak sequence homologies (25%) were detected between some regions of nidogen, the LDL receptor, thyroglobulin and the EGF precursor. Nidogen contains two consensus sequences for tyrosine sulfation and for asparagine beta-hydroxylation, two N-linked carbohydrate acceptor sites and, within one of the EGF-like repeats an Arg-Gly-Asp sequence. The latter was shown to be functional in cell attachment to nidogen. Binding sites for laminin and collagen IV are present on the C-terminal globule but not yet precisely localized.     

Bovine coagulation factor V visualized with electron microscopy. Ultrastructure of the isolated activated forms and of the activation fragments

Single chain bovine factor V (Mr = 330,000) was isolated and visualized by means of high resolution transmission electron microscopy of negatively stained samples. Both factor Va, activated by thrombin or by the factor V activator from Russell's viper venom, and the isolated fragments, D (Mr = 105,000), C1 (Mr = 150,000), and F1F2 (Mr = 72,000), were studied. Single chain factor V appeared as a multidomain structure with three globular domains of similar size (diameter approximately 80 A), and oriented around a somewhat larger central domain (diameter approximately 140 A). The distance between the center of the molecule and the center of each of the peripheral domains was 120 A and the maximum length of factor V was 300 A. The structure was essentially identical with that recently shown for human single chain factor V (Dahlb?ck, B. (1985) J. Biol. Chem. 260, 1347-1349). Isolated thrombin-activated factor Va (containing fragments D and F1F2) was composed of two domains of similar size, each of which was approximately 80 A in diameter and corresponded in size and shape to the peripheral domains seen in intact factor V. The isolated activation fragment C1 appeared as an irregular structure with an approximate diameter of 140 A and corresponded in size and shape to the larger central domain in intact factor V. The activator from Russell's viper venom only cleaves the bond(s) between C1 and F1F2, which results in two fragments, a larger fragment (Mr = 220,000) bearing the D, E, and C1 region and a smaller one corresponding to the F1F2 fragment. The venom-activated factor Va in the electron microscope demonstrated a multidomain structure similar in size and shape to that obtained with intact factor V. A model for factor V and the molecular events involved in activation is proposed.     

Recombinant nidogen consists of three globular domains and mediates binding of laminin to collagen type IV.

Recombinant mouse nidogen and two fragments were produced in mammalian cells and purified from culture medium without resorting to denaturing conditions. The truncated products were fragments Nd-I (positions 1-905) comprising the N-terminal globule and rod-like domain and Nd-II corresponding mainly to the C-terminal globule (position 906-1217). Recombinant nidogen was indistinguishable from authentic nidogen obtained by guanidine dissociation from tumor tissue with respect to size, N-terminal sequence, CD spectra and immunochemical properties. They differed in protease stability and shape indicating that the N-terminal domain of the more native, recombinant protein consists of two globules connected by a flexible segment. This established a new model for the shape of nidogen consisting of three globes of variable mass (31-56 kDa) connected by either a rod-like or a thin segment. Recombinant nidogen formed stable complexes (Kd less than or equal to 1 nM) with laminin and collagen IV in binding assays with soluble and immobilized ligands and as shown by electron microscopy. Inhibition assays demonstrated different binding sites on nidogen for both ligands with different specificities. This was confirmed in studies with fragment Nd-I binding to collagen IV and fragment Nd-II binding to laminin fragment P1. In addition, recombinant nidogen but not Nd-I was able to bridge between laminin or P1 and collagen IV. Formation of such ternary complexes implicates a similar role for nidogen in the supramolecular organization of basement membranes.     

The preparation and partial characterization of N-terminal and C-terminal iron-binding fragments from rabbit serum transferrin.

Two iron-binding fragments of Mr 36 000 and 33 000 corresponding to the N-terminal domain of rabbit serum transferrin were prepared. One iron-binding fragment of Mr 39 000 corresponding to the C-terminal domain was prepared. The N-terminal amino acid sequence of rabbit serum transferrin is: Val-Thr-Glu-Lys-Thr-Val-Asn-Trp-?-Ala-Val-Ser. One glycan unit is presented in rabbit serum transferrin and it is located in the C-terminal domain.     

An amphiphilic structure of the ninth component of human complement. Evidence from analysis of fragments produced by alpha-thrombin

Purified human C9 was treated separately with three proteolytic enzymes: trypsin, plasmin, and alpha-thrombin, and the digestion products were analyzed by sodium dodecyl sulfate polyacrylamide gel electrophoresis. Trypsin initially cleaved the Mr = 71,000 C9 to produce a Mr = 47,000 fragment plus numerous smaller fragments and prolonged digestion reduced the molecule to small polypeptides. Plasmin produced a Mr = 37,000 fragment which was stable to further digestion, plus fragments smaller than Mr = 10,000. Human alpha-thrombin cleaved C9 (7.8% carbohydrate) at a single internal site to produce a Mr = 37,000 fragment (11.3% carbohydrate) and a Mr = 34,000 fragment (3.9% carbohydrate). Statistical analysis of the amino acid compositions of the fragments and alkaline polyacrylamide gel electrophoresis showed that C9 is highly amphiphilic; the Mr = 34,000 fragment contains a majority of the acidic amino acids and migrates rapidly on alkaline gels; the Mr = 37,000 fragment is hydrophobic with a slow electrophoretic mobility. The two fragments remain noncovalently associated, but were separated by sodium dodecyl sulfate-hydroxylapatite chromatography. The NH2-terminal sequence analysis of native C9, of alpha-thrombin-cleaved C9, and for the isolated fragments showed that the acidic Mr = 34,000 fragment is the NH2-terminal C9a domain and the more hydrophobic Mr = 37,000 fragment is the carboxyl-terminal C9b domain. Hemolytic activity of C9 was unaffected by alpha-thrombin cleavage.     

Separation and characterisation of tryptic fragments from the adenosine triphosphatase of sarcoplasmic reticulum.

The two halves of the ATPase, M, 115,000, from sarcoplasmic reticulum produ-ed by limited trypsin treatment have been purified in sodium dodecylsulphate. The fragment of Mr60,000 has been purified by electrophoresis on cellulose acetate slabs and that of Mr 55,000 by gel filtration. The two halves of the 60,000 Mr fragment (Mr33,000 and 24,000) produced by more extensive trypsin treatment have also been purified by gel filtration in sodium dodecylsulphate. The sum of the amino acid analyses of the constituent tryptic fragments is in good agreement with that for the whole ATPase. The amino acid compositions of the two halves of the ATPase were strikingly similar. N-terminal analysis shows that the ATPase and its constituent tryptic polypeptides all possess a single N-terminal alanine implying no further cleavage of the polypeptide by trypsin. Attempts to solubilize selectively the tryptic fragments from the membrane by a variety of denaturing and solubilising agents under a variety of conditions have proved unsuccessful, suggesting that the interaction between the tryptic polypeptides is stronger than between the lipid and the protein. The possibility that the interaction between the tryptic polypeptides includes disulphide bonding has been eliminated.     

Cyanogen bromide fragments of Akazara scallop Mr 52,000 troponin-I

Akazara scallop troponin-I of Mr 52,000 (52K) was cleaved into two fragments of 17K and 35K with cyanogen bromide. The 17K fragment, along with tropomyosin, inhibited weakly the rabbit actomyosin Mg-ATPase activity, however, the 35K fragment did not affect it at all. In the presence of Akazara scallop TnT (40K component), the 17K fragment, in turn, strongly inhibited the activity, while the 35K fragment did not. The amino acid composition and partial amino acid sequence suggested that the 17K and 35K fragments were derived from C- and N-terminal regions of the TnI, respectively, and that structural similarity to TnIs from other animals is present in the 17K region.     

Proteolytic fragments identified with domains of the aspartate chemoreceptor

Two proteolytic fragments generated during the preparation of the aspartate receptor from Salmonella typhimurium have been purified. These fragments are the products of a single cleavage by an endogenous protease after amino acid 259 in the sequence of the intact receptor. Proteolytic fragment 1 (PF1) represents amino acids 1-259 (Mr = 29,000); this unit retains the aspartate-binding function of the intact receptor. The second fragment (PF2) includes residues 260-552 (Mr = 31,000) and has the normal sites of reversible methylation for the receptor. Like the purified intact receptor, this fragment can be methylated in vitro, although at a much slower rate. Circular dichroic measurements suggest that both proteolytic fragments contain substantial alpha-helical structure, approximately 95 and 53% for PF1 and PF2, respectively. No beta-structure could be detected in either fragment. Molecular sieve chromatography in the presence of detergent suggests that PF1 occurs as a stable multimer of an order equivalent to that observed for the detergent-solubilized aspartate receptor, i.e. a tetramer (+/- 1). PF2 is found to have a multimeric form which is sensitive to the removal of detergent. It is proposed that these fragments represent structural and functional domains of the aspartate receptor.     

Basement-membrane heparan sulfate proteoglycan binds to laminin by its heparan sulfate chains and to nidogen by sites in the protein core.

A large, low-density form of heparan sulfate proteoglycan was isolated from the Engelbreth-Holm-Swarm (EHS) tumor and demonstrated to bind in immobilized-ligand assays to laminin fragment E3, collagen type IV, fibronectin and nidogen. The first three ligands mainly recognize the heparan sulfate chains, as shown by inhibition with heparin and heparan sulfate and by the failure to bind to the proteoglycan protein core. Nidogen, obtained from the EHS tumor or in recombinant form, binds exclusively to the protein core in a heparin-insensitive manner. Studies with other laminin fragments indicate that the fragment E3 possesses a unique binding site of laminin for the proteoglycan. A major binding site of nidogen was localized to its central globular domain G2 by using overlapping fragments. This allows for the formation of ternary complexes between laminin, nidogen and proteoglycan, suggesting a key role for nidogen in basement-membrane assembly. Evidence is provided for a second proteoglycan-binding site in the C-terminal globule G3 of nidogen, but this interaction prevents the formation of such ternary complexes. Therefore, the G3-mediated nidogen binding to laminin and proteoglycan are mutually exclusive.     

人绒毛膜促性腺激素β亚基酶解片段免疫性研究

 以嗜热菌蛋白酶将人绒毛膜促性腺激素(HCG)β亚单位进行酶解,用HPLC分离酶解产物。酶解片段经SDS-聚丙烯酰胺凝胶电泳鉴定口壬二条带。表观分子量分别为7600及20000。对照氨基酸序列分析,前者为近C端30肽(含糖链),为主要片段;后者为近N端片段。将此酶解片段混合物免疫家兔,用完整HCG作测试抗原,抗体滴度达1:204,800(Avidin-Biotin Micro-ELISA法),与促黄体激素(LH)交叉反应甚弱。表明该片段仍保留有完整HCG的主要抗原决定簇,有较强的免疫原性,可望作为免疫避孕疫苗。     

Tryptic digestion of human GPIIIa. Isolation and biochemical characterization of the 23 kDa N-terminal glycopeptide carrying the antigenic determinant for a monoclonal antibody (P37) which inhibits platelet aggregation.

Early digestion of pure human platelet glycoprotein IIIa (GPIIIa) leads to a single cleavage of the molecule at 23 kDa far from one of the terminal amino acids. Automated Edman degradation demonstrates that GPIIIa and the smaller (23 kDa) tryptic fragment share the same N-terminal amino acid sequence. A further cleavage occurs in the larger fragment (80 kDa), reducing its apparent molecular mass by 10 kDa. The 23 kDa fragment remains attached to the larger ones in unreduced samples. Stepwise reduction of early digested GPIIIa with dithioerythritol selectively reduces the single disulphide bond joining the smaller (23 kDa) to the larger (80/70 kDa) fragments. Two fractions were obtained by size-exclusion chromatography of early digested GPIIIa after partial or full reduction and alkylation. The larger-size fraction contains the 80/70 kDa fragments, while the 23 kDa fragment is isolated in the smaller. The amino acid compositions of these fractions do not differ very significantly from the composition of GPIIIa; however the 23 kDa fragment contains only 10.2% by weight of sugars and is richer in neuraminic acid. Disulphide bonds are distributed four in the 23 kDa glycopeptide and 20-21 in the 80/70 kDa glycopeptide. The epitope for P37, a monoclonal antibody which inhibits platelet aggregation [Melero & González-Rodríguez (1984) Eur. J. Biochem. 141, 421-427] is situated within the first 17 kDa of the N-terminal region of GPIIIa, which gives a special functional interest to this extracellular region of GPIIIa. On the other hand, the epitopes for GPIIIa-specific monoclonal antibodies, P6, P35, P40 and P97, which do not interfere with platelet aggregation, are located within the larger tryptic fragment (80/70 kDa). Thus, the antigenic areas available in the extracellular surface of GPIIIa for these five monoclonal antibodies are now more precisely delineated.     

Association of vesicular stomatitis virus glycoprotein with virion membrane: characterization of the lipophilic tail fragment.

The proteolytic enzyme, thermolysin, degraded the external segment of the membrane glycoprotein of intact vesicular stomatitis (VS) virions but left behind a small nonglycosylated fragment, presumably embedded in the virion membrane. Other proteases generated membrane-associated glycoprotein fragments differing somewhat in molecular weight. The thermolysin-resistant, virion-associated fragment, which can be selectively solubilized by either Triton X-100 or chloroform/methanol, has a molecular weight of 5,200. Amino acid analysis of the glycoprotein fragment reveals a preponderance of hydrophobic amino acids (64% of the residues); the amino-terminal amino acid is alanine as determined by dansylation. Cyanogen bromide digestion of the tail fragment generated two peptides, confirming the presence of one methionine residue per thermolysin-resistant glycoprotein fragment. The secondary structure of this glycoprotein tail peptide is maintained by at least one disulfide bridge. Thermolysin treatment is isolated VS viral glycoprotein in the presence of Triton X-100 also generated a hydrophobic peptide fragment which is very similar to the virion-associated glycoprotein fragment. The amino acid terminus of intact glycoprotein was also found to be alanine as was its dansylated Triton-micellar fragment that resisted thermolytic degradation; this finding suggests that the amino-terminal end of the VS viral glycoprotein is embedded in the virion membrane. These results suggest that the VS viral glycoprotein is an amphipathic molecule, the hydrophilic portion of which contains all the carbohydrate and a lipophilic tail segment which forms lipid or detergent micelles, thus rendering it resistant to proteolysis.