Subunit structure of the dihydrolipoyl transacylase component of branched-chain alpha-keto acid dehydrogenase complex from bovine liver. Mapping of the lipoyl-bearing domain by limited proteolysis

To characterize the lipoyl-bearing domain of the dihydrolipoyl transacylase (E2) component, purified branched-chain alpha-keto acid dehydrogenase complex from bovine liver was reductively acylated with [U-14C] alpha-ketoisovalerate in the presence of thiamin pyrophosphate and N-ethylmaleimide. Digestion of the modified complex with increasing concentrations of trypsin sequentially cleaved the E2 polypeptide chain (Mr = 52,000) into five radiolabeled lipoyl-containing fragments in the order of L1 (Mr = 28,000), L2 (Mr = 24,500), L3 (Mr = 21,000), L4 (Mr = 15,000) to L5 (Mr = 14,000) as determined by the autoradiography of sodium dodecyl sulfate-polyacrylamide gel. In addition, a lipoate-free inner E2 core consisting of fragment A (Mr = 26,000) and fragment B (Mr = 22,000) was produced. Fragment A contains the active site for transacylation reaction and fragment B is the subunit-binding domain. Fragment L5 and fragment B were stable and resistant to further tryptic digestion. Mouse antiserum against E2 reacted only with fragments L1, L2, and L3, and did not bind fragments L4, L5, A, and B as judged by immunoblotting analysis. The anti-E2 serum strongly inhibited the overall reaction catalyzed by the complex, but was without effect on the transacylation activity of E2. Measurement of incorporation of [1-14C]isobutyryl groups into the E2 subunit indicated the presence of 1 lipoyl residue/E2 chain. Based on the above data, a model is proposed in which the lipoyl-bearing domain is connected to the inner E2 core via a trypsin-sensitive hinge. The lipoyl-bearing domain contains five consecutive tryptic sites (L1 to L5), with the L1 site in the hinge region, and the L5 site next to the terminal lipoyl-binding sequence. An exposed and antigenic region is located between L1 and L4 tryptic sites of the lipoyl-bearing domain. The region accounts for about 24% of the E2 chain length. Binding of antibodies to this region probably impairs the mobility of the lipoyl-containing polypeptide, resulting in an interruption of the active-site interactions that are necessary for the overall reaction. The lack of antigenicity and resistance to tryptic digestion indicate a highly folded conformation for fragment L5, the limit polypeptide carrying the single lipoyl residue.     

Characterization and conservation of the inner E2 core domain structure of branched-chain alpha-keto acid dehydrogenase complex from bovine liver. Construction of a cDNA encoding the entire transacylase (E2b) precursor

A cDNA clone encoding the entire transacylase (E2b) precursor of the bovine branched-chain alpha-keto acid dehydrogenase complex has been constructed from two overlapping incomplete cDNA clones which were isolated from a lambda ZAP library prepared from bovine liver poly(A)+ RNA. Nucleotide sequencing indicates that this bovine E2b cDNA insert (bE2-11) is 2701 base pairs in length with an open reading frame of 1446 base pairs. The bE2-11 cDNA insert encodes a leader peptide of 61 residues and a mature E2b polypeptide of 421 amino acid residues with a calculated monomeric molecular mass of 46,518 daltons. The molecular mass of the native E2b component isolated from bovine liver is 1,110,000 daltons as determined by sedimentation equilibrium. This value establishes the 24-subunit octahedral model for the quaternary structure of bovine E2b. The amino-terminal sequences of two tryptic fragments (A and B) of the E2b protein have been determined. Fragment A comprises residues 175 to 421 of the E2b protein and is the inner E2 core domain which contains the transacylase active site. Fragment B, produced by further tryptic cleavage of fragment, comprises residues 205 to 421, but does not have transacylase activity. Both fragments A and B confer the highly assembled 24-mer structure. The primary structure of the inner E2 core domain of bovine E2b (fragment A) is very similar to those of three other E2 proteins (human E2p, Escherichia coli E2p, and E. coli E2k). These similarities suggest that these E2 proteins are structurally and evolutionarily related.     

Bovine kidney pyruvate dehydrogenase complex. Limited proteolysis and molecular structure of the lipoate acetyltransferase component

1. Bovine kidney pyruvate dehydrogenase multienzyme complex is inactivated by elastase in a similar manner as described earlier for papain. The core component, lipoate acetyltransferase, is cleaved by elastase into an active fragment (Mr 26000) and a fragment with apparent Mr of 45000 as analyzed by dodecylsulfate gel electrophoresis. Due to the fragmentation of the core, the enzyme complex is disassembled into its component enzymes which retain their complete enzymatic activities as assayed separately. 2. A different mechanism was found for the inactivation of pyruvate dehydrogenase complex with trypsin and some other proteases (chymotrypsin, clostripain). In these cases, the pyruvate dehydrogenase component is inactivated rapidly by limited proteolysis. More slowly, the enzyme complex is disassembled simultaneously with fragmentation of the lipoate acetyltransferase which again results in an active fragment of Mr 26000 and another fragment of apparent Mr 45000. Upon prolonged proteolysis, the latter fragment is cleaved further to give products of Mr 36000 or lower. 3. The enzyme-bound lipoyl residues of the pyruvate dehydrogenase complex have been labelled covalently by incubation with [2-14C]pyruvate. After treatment of this [14C]acetyl-enzyme with papain, elastase, or trypsin, radioactivity was associated exclusively with the 45000-Mr and 36000-Mr fragments but not with the active 26000-Mr fragment. 4. It is concluded that the bovine kidney lipoate acetyltransferase core is composed of 60 subunits each consisting of two dissimilar folding domains. One of these contains the intersubunit binding sites as well as the active center for transacylation whereas the other possesses the enzyme-bound lipoyl residues.     

Domain structures of the dihydrolipoyl transacetylase and the protein X components of mammalian pyruvate dehydrogenase complex. Selective cleavage by protease Arg C

Treatment of the dihydrolipoyl transacetylase-protein X-kinase subcomplex (E2-X-KcKb) with protease Arg C selectively converted protein X into an inner domain fragment (Mr approximately equal to 35,000) and an outer (lipoyl-bearing) domain fragment (Mr approximately equal to 15,500). These fragments were larger and much smaller, respectively, than the inner domain and outer domain fragments derived from the E2 component, supporting the conclusion that protein X is distinct from the E2 component. Protease Arg C cleaved the Kb subunit more slowly than protein X. An increase in kinase activity correlated with this cleavage of the Kb subunits. An even slower cleavage of E2 subunits generated an inner domain fragment (Mr approximately equal to 31,500) and a lipoyl-bearing domain fragment (Mr approximately equal to 49,000) which had Mr values at least 3,000 and 10,000 larger, respectively, than the corresponding E2 fragments generated by trypsin treatment of the subcomplex. Following various extents of cleavage with protease Arg C or trypsin, residual oligomeric subcomplexes were isolated and characterized. We found that selective removal of the lipoyl-bearing domain of protein X did not alter lipoyl-mediated regulation of the kinase indicating that the lipoyl residues bound to E2 subunits are effective, that the inner domain of protein X remained associated with the inner domain of E2 subunits following the complete removal of the outer domains of both E2 and protein X, that, with only 10% of the E2 subunits intact, nearly half of the catalytic (Kc) subunits of the kinase were bound by the residual subcomplex, and that removal of the remaining outer domains from E2 subunits released the Kc subunits. Thus, protein X is unique among the subunits of the complex in binding tightly to the oligomeric inner domain of the transacetylase, and the outer domain of the transacetylase serves to bind to and facilitate the regulation of the catalytic subunit of the kinase.     

Studies of functional domains of the regulatory subunit from cAMP-dependent protein kinase isozyme I

Homogenous regulatory subunit from rabbit skeletal muscle cAMP-dependent protein kinase (isozyme I) was partially hydrolyzed with low (1 g/1300 g) or high (1 g/6 g) concentrations of trypsin. After treatment with low trypsin two main peptides (Mr = 35,000 and 12,000) were produced. The cAMP-binding activity (2 mol cAMP/mol of subunit monomer) was recovered in the monomeric Mr = 35,000 peptide. The ability of either fragment to inhibit catalytic subunit activity was lost. Treatment of the regulatory subunit with a high concentration of trypsin yielded three main fragments (Mr = 32,000, 16,000, and 6,000) which could be resolved by Sephadex G-75 and purified further on DEAE-cellulose columns. One of the peptides (Mr = 32,000) bound 2 mol cAMP/mol fragment. The Mr = 16,000 fragment was very labile and bound cAMP with an undetermined stoichiometry. Cyclic AMP dissociation curves for the native regulatory subunit and its Mr = 32,000 component were similar and suggested the presence of two nonidentical binding sites in each monomer. Using the same procedure, the Mr = 16,000 fragment or homogenous cGMP-dependent protein kinase appeared to contain a single type of binding site. Purified Mr = 32,000 fragment was readily converted to the Mr = 16,000 fragment using high trypsin as assessed by protein bands on SDS-disc gels or by following transfer of radioactivity from Mr = 32,000 peptide covalently labeled with 8-N3-[32P] cAMP to radiolabeled Mr = 16,000 fragment. The smallest regulatory subunit fragment (Mr = 6,000) did not bind cAMP, but was dimeric and could be part of the dimerization domain in the native protein. A model is presented to explain the possible structural-functional relationships of the regulatory subunit.     

Complex formation of platelet membrane glycoproteins IIb and IIIa with the fibrinogen D domain

Glycoprotein IIb (GPIIb) and glycoprotein IIIa (GPIIIa) form a macromolecular complex on the activated platelet surface which contains the fibrinogen-binding site necessary for normal platelet aggregation. To identify the specific region of the fibrinogen molecule responsible for its interaction with the GPIIb-GPIIIa complex, purified fragment D1 (Mr = 100,000) and fragment E (Mr = 50,000) were prepared from plasmin digests of purified human fibrinogen. In addition, the polypeptide chain subunits A alpha, B beta, and gamma of fibrinogen were prepared. Using an enzyme-linked immunosorbent assay we have demonstrated that isolated fragment D1 in a solid phase system forms a complex with a mixture of GPIIb and GPIIIa. The binding of the GPIIb-GPIIIa mixture to fragment D1-coated plates reached saturation at 8 nM and to fibrinogen-coated plates at 24 nM. Isolated A alpha, B beta, and gamma chains were not reactive with added glycoproteins. Fragment E coated directly on plastic plates or immobilized on antibody-coated plastic plates did not form a complex with GPIIb-GPIIIa. Only fluid phase fibrinogen and fragment D1 but not fragment E were inhibitory toward formation of a complex between solid phase fibrinogen and GPIIb-GPIIIa. Isolated A alpha, B beta, and gamma chains at concentrations equivalent to fluid phase fibrinogen were inactive. Binding of fragment D1 but not fragment E to the GPIIb-GPIIIa complex was also demonstrated by rocket immunoelectrophoresis of the membrane glycoprotein mixture through a gel containing the individual fragments and subsequent autoradiography of the complex following exposure to 125I-anti-fibrinogen. These observations with isolated platelet membrane glycoproteins provide strong evidence that each of the D domains of the fibrinogen molecule interacts directly with the GPIIb-GPIIIa complex on the activated platelet surface, thus allowing formation of a tertiary molecular "bridge" across the surface of two adjacent activated platelets.     

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.     

Elongation factor Tu of the extreme thermophilic hydrogen oxidizing bacterium Calderobacterium hydrogenophilum

Protein synthesis elongation factor Tu has been purified from an extreme thermophilic hydrogen oxidizing bacterium Calderobacterium hydrogenophilum. The molecular mass of EF-Tu. GDP is 51,000. The factor is heat stable and loses only 50% of its activity after heating for 5 min at 80 degrees C. Under mild conditions trypsin cleaved EF-Tu. GDP to four main fragments. Only one fragment of Mr = 20,000 had a mobility similar to the trypsin fragment "B" of Escherichia coli EF-Tu. Other peptide fragments of E. coli and C. hydrogenophilum EF-Tu differed in size, but native preparations of both factors are immunologically similar.     

Tryptic digestion of dynein 1 in low salt medium. Origin and properties of fragment A

Dynein 1 was extracted from sperm flagella of the sea urchin Tripneustes gratilla with 0.6 M NaCl and dialyzed against 0.5 mM EDTA, 14 mM 2-mercaptoethanol, 5 mM imidazole/HCl buffer, pH 7.0, for 24-48 h. In some cases, fractions containing the alpha heavy chain and the beta/intermediate chain 1 complex (beta/IC1) were separated by density gradient centrifugation in the same solution. Treatment of the samples at a trypsin:protein ratio of 1:10 w/w for 32 min at room temperature yields a crude digest from which Fragment A is purified by density gradient centrifugation. The purified Fragment A consists of two principal peptides (Mr = 195,000 and 130,000) that cosediment with the peak of ATPase activity at 12.5 S, which is slightly faster than the 11 S of the original beta/IC1 complex. When digests of the separated alpha chain and of the beta/IC1 complex are followed as a function of time, the early cleavages of the two heavy chains (Mr = 428,000) resemble each other in that both lead to similarly sized peptides of Mr 316,000 and 296,000, but only in the beta/IC1 fraction does the digestion proceed to form Fragment A. The remainder of the beta chain, termed Fragment B, occurs as an Mr 110,000 peptide sedimenting at 5.7 S with no associated ATPase activity. Fragment A has a specific ATPase activity of 4.3 mumol Pi X min-1 X mg-1, with a Km of 29 microM in 0.1 M NaCl medium, and an apparent Ki for inhibition by vanadate of 1.2 microM in the absence of salt, and 22 microM in 0.6 M NaCl. Photoaffinity labeling with [alpha-32P]8-azidoadenosine 5'-triphosphate indicates that the ATP binding site on the beta chain of dynein 1 is located on the Mr 195,000 peptide of Fragment A. The possibility that Fragments A and B of the beta/IC1 complex may correspond to the head and tail regions of the tadpole-shaped particle seen by electron microscopy is discussed.     

Fragmentation and reduction of bovine secretory component. Preparation of a biologically active fragment and some evidence for a multiple-domain structure.

A tryptic fragment (A) of Mr 25000 was prepared from bovine secretory component. The fragment binds polymeric immunoglobulin, although 9 times less effectively than secretory component on a molar basis. The fragment has four buried half-cystine residues and two exposed half-cystine residues. It gives rise to two fragments of Mr 11000-13000 on prolonged digestion with trypsin, and these do not bind polymeric immunoglobulin. It is proposed that fragment A consists of two immunoglobulin-like domains. Bovine secretory component was found to have 9-11 buried half-cystine residues and four exposed half-cystine residues. Reduction and alkylation of the exposed residues decreases the binding of polymeric immunoglobulin by 3-fold. Initial tryptic cleavage of bovine secretory component gives a fragment (Q) disulphide-bridged to a further fragment (T). Fragment Q is similar in size to a three-domain immunoglobulin fragment, and fragment T is similar in size to a two-domain immunoglobulin fragment. The two-domain fragment A is derived from fragment Q by further tryptic cleavage. The results are compatible with the proposal by Mostov, Friedlander & Blobel [(1984) Nature (London) 308, 37-43] that secretory component consists of multiple immunoglobulin-like domains. The results also indicate that optimal binding of polymeric immunoglobulin involves several domains stabilized by an exposed disulphide bridge.     

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.     

Identification of structurally distinct catalytic intermediates of the H+-ATPase from yeast plasma membranes

Mild trypsin proteolysis of the H+-ATPase from yeast plasma membranes has been used to identify structurally distinct catalytic intermediates. In the absence of substrate, trypsin treatment resulted in rapid inactivation of enzyme activity. By contrast, trypsin treatment of enzyme in the presence of MgATP or MgATP plus vanadate resulted in enhanced rates of ATP hydrolysis accompanied by protection from extensive inactivation. High concentrations of Pi also induced strong protection from trypsin-induced inactivation, although enhancement of enzyme activity was not observed. Western blot analysis of peptide fragment profiles following tryptic digestion indicated that at least 15 prominent fragments of identical size, ranging from Mr = 12,800 to 48,000, were generated irrespective of digestion conditions. However, fragments from protected enzyme were resistant to further proteolysis, whereas fragments from unprotected enzyme were extensively degraded. These data have been interpreted in terms of a published catalytic reaction pathway (Amory, A., Goffeau, A., McIntosh, D.B., and Boyer, P.D. (1982) J. Biol. Chem. 257, 12509-12516) and are consistent with unprotected and protected enzyme conformations representing E1 and E2 X Pi catalytic intermediates, respectively. Trypsin proteolysis proved an effective tool for evaluating preferred enzyme conformational states and with this approach, it was found that ATPase inhibitors N-ethylmaleimide and fluorescein isothiocyanate locked the enzyme in an E1 conformation. The enhanced rate of ATP hydrolysis by trypsin-treated enzyme was fully coupled to proton transport, and all fragments generated by proteolysis were firmly bound to the membrane. These results, coupled with the fact that initial peptide fragmentation profiles were independent of enzyme conformation, suggest that the different conformational states, E1, and E2 X Pi, are not related to gross changes in overall enzyme structure but likely reflect localized changes in intramolecular bonding.     

Isolation and characterization of staphylocoagulase chymotryptic fragment. Localization of the procoagulant- and prothrombin-binding domain of this protein

Several strains of Staphylococcus aureus secrete a protein, staphylocoagulase, that binds stoichiometrically to human prothrombin, resulting in a coagulant complex designated staphylothrombin. In the present study, staphylocoagulase was digested with alpha-chymotrypsin and the resulting fragments were isolated by gel filtration. One fragment (Mr 43,000) exhibited a high affinity for human prothrombin (Kd = 1.7 X 10(-9) M), which is comparable to the affinity observed using intact staphylocoagulase (Kd = 4.6 X 10(-10) M). A complex of the Mr 43,000 fragment and prothrombin possessed both clotting and amidase activity essentially identical to that observed in a complex of intact staphylocoagulase and prothrombin. A second fragment (Mr 30,000) exhibited weaker affinity for prothrombin (Kd = 1.2 X 10(-7) M). While clotting activity was not observed with a complex of this fragment and prothrombin, it nonetheless possessed a weak amidase activity. A third fragment (Mr 20,000) was found to bind to prothrombin, but the resultant complex did not exhibit clotting or amidase activity. Amino-terminal sequence analyses of these staphylocoagulase fragments revealed that the Mr 43,000 fragment constitutes the amino-terminal portion of staphylocoagulase and also contains the Mr 30,000 and 20,000 fragments. Moreover, the amino-terminal sequence of the Mr 20,000 fragment was identical to that observed for the Mr 30,000 fragment. From these results, we conclude that the functional region of staphylocoagulase for binding and activation of human prothrombin is localized in the amino-terminal region of the intact bacterial protein.     

Limited proteolysis of the pyruvate dehydrogenase multienzyme complex of Bacillus subtilis.

Limited digestion of the pyruvate dehydrogenase complex of Bacillus subtilis with either trypsin or chymotrypsin at 0 degrees C inhibited its ability to decarboxylate pyruvate and 2-oxoisovalerate oxidatively, without causing disassembly of the complex. The proteinases selectively cleaved the E1 alpha subunits to form two fragments of Mr 31500 and approx. 9500, as judged by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis, both fragments remaining bound to the complex. Trypsin also caused a much slower cleavage of the E2 subunits, to form a fragment of apparent Mr 34000. The inhibition of overall dehydrogenase-complex activity was accompanied by the apparent loss of the pyruvate-driven and 2-oxoisovalerate-driven E1 activities, which was found to be due to a large increase in the Km for the 2-oxo acids: this change was correlated with the cleavage of the E1 alpha subunit.     

Characterization of the calmodulin-binding and catalytic domains in skeletal muscle myosin light chain kinase

Limited proteolysis has been utilized to study the structural organization of rabbit skeletal muscle myosin light chain kinase. The enzyme (Mr approximately 89,000 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis) consists of an amino-terminal, protease-susceptible region of unidentified function and a carboxyl-terminal, protease-resistant region of Mr approximately 40,000 containing the catalytic and calmodulin-binding domains. Partial digestion with trypsin produced an intermediate 56,000-dalton fragment and a stable 38,000-dalton fragment, both of which were catalytically active and calmodulin-dependent. Chymotryptic digestion yielded three catalytically active fragments of about 37,000, 36,000, and 35,000 daltons. The Mr = 37,000 fragment was calmodulin-dependent with an apparent affinity equivalent to that of the native enzyme (approximately 1 nM). The 36,000-dalton fragment was also calmodulin-dependent but had a approximately 200-fold lower apparent affinity. The Mr = 35,000 fragment was calmodulin-independent. These three chymotryptic fragments, had identical amino termini. Nineteen residues were missing from the carboxyl terminus of the calmodulin-independent chymotryptic fragment whereas only 8 or 9 carboxyl-terminal residues were missing from the calmodulin-dependent tryptic fragments. These results suggest that the 11-residue sequence (IAVSAANRFKK) in the carboxyl-terminal region of myosin light chain kinase contributes directly to the binding of calmodulin. This conclusion is in accord with data (Blumenthal, D. K., Takio, K., Edelman, A. M., Charbonneau, H., Titani, K., Walsh, K. A., and Krebs, E. G. (1985) Proc. Natl. Acad. Sci. U. S. A. 82, 3187-3191) that the carboxyl-terminal, 27-residue CNBr peptide of the native enzyme shows Ca2+-dependent, high affinity binding to calmodulin and that similar calmodulin-binding activity, although detectable in unfractionated CNBr digests of calmodulin-dependent enzyme forms, is much reduced in a CNBr digest of the calmodulin-independent, Mr = 35,000 chymotryptic fragment.     

Hormone binding site of the insulin receptor: analysis using photoaffinity-mediated avidin complexing

A trifunctional reagent was designed which allows derivatization of ligands, particularly peptides and proteins, for subsequent photoaffinity labelling of receptors and specific isolation of the covalent complex or its fragments. B29-(2-nitro-4-azidophenyl)-biocytinyl-insulin (NB-insulin) was synthesized, radioiodinated, and the B26-mono-iodo derivative isolated by HPLC. It was used to photoaffinity label human placental membranes and the purified insulin receptor. Extensive digestion of the covalent insulin-receptor complex with trypsin (EC 3.4.21.4) led to the generation of a fragment of Mr 14,000. Specific complexing with avidin, derivatized avidin or streptavidin could be demonstrated for the photoaffinity labelled alpha-subunit and the 14,000 core fragment. The latter was isolated (approx. 100 pmol from 3-4 placentae) by streptavidin affinity chromatography and HPLC. According to microsequencing based on the known primary structure of the insulin receptor, the N-terminus of the core peptide appears to be Leu20-His21-Glu22-Leu23. We thus conclude: a part of the insulin-binding region of the receptor is located close to the N-terminus of its alpha-subunit in a remarkably stable domain of the sequence 20--(approx.) 120.     

Binding phenomena of isolated unique plasmic degradation products of human cross-linked fibrin.

Proteolysis of human cross-linked fibrin by plasmin results in the formation of a DD . E complex, and Fragments DD and E as the major degradation products. Three species of Fragment E, which differ both in molecular weights (E1, Mr = 60,000; E2, Mr = 55,000; E3, Mr = 50,000) and in charge, have been isolated from a digest of cross-linked fibrin. Each Fragment E species reacts with monospecific anti-E antiserum. Fragments E1 and E2 bind with Fragment DD to form a DD . E complex but Fragment E3 is inactive. This binding is specific since these Fragments E do not bind to fibrinogen or to degradation products of fibrinogen or of noncross-linked fibrin. Fragments E1 and E2 incubated with plasmin are degraded to Fragment E3, suggesting that the three species represent sequential degradation products. Plasmin-treated Fragments E1 and E2 no longer bind with Fragment DD; therefore, it appears that the peptides cleaved from Fragment E2 by plasmin contain or modify the sites responsible for complex formation. On the other hand, Fragment DD binds not only to Fragments E1 and E2, but also to fibrinogen, Fragments X (Stage 1), X (Stage 2), Y, and NH2-terminal disulfide knot, but only after thrombin treatment, suggesting that Fragment DD binds to complementary sites on the NH2-terminal region of fibrinogen which are exposed after thrombin treatment.     

Domain structure of human plasma and cellular fibronectin. Use of a monoclonal antibody and heparin affinity to identify three different subunit chains

The domain structure of human plasma fibronectin was investigated by using heparin-binding and antibody reactivity of fibronectin and its proteolytically derived fragments. Digestion of human plasma fibronectin with a combination of trypsin and cathepsin D produced six major fragments. Affinity chromatography showed that one fragment (Mr 45 000) binds to gelatin and three fragments (Mr 31 000, 36 000, and 61 000) bind to heparin. The 31K fragment corresponds to NH2-terminal fragments isolated from other species. The 36K and 61K fragments are derived from a region near the C-terminus of the molecule and appear to be structurally related as demonstrated by two-dimensional peptide maps. A protease-sensitive fragment (Mr 137 000), which binds neither gelatin nor heparin but which has been shown previously to be chemotactic for cells [Postlethwaite, A. E., Keski-Oja, J., Balian, G., & Kang, A. H. (1981) J. Exp. Med. 153, 494-499], separates the NH2-terminal heparin- and gelatin-binding fragments from the C-terminal 36K and 61K heparin-binding fragments. A monoclonal antibody to fibronectin that recognized the 61K heparin-binding fragment was used to isolate a sixth fragment (Mr 34 000) that did not bind to heparin or gelatin and that represents a difference between the 61K and 36K heparin-binding fragments. Cathepsin D digestion produced an 83K heparin-binding, monoclonal antibody reactive fragment that contains the interchain disulfide bond(s) linking the two fibronectin chains at their C-termini. The data indicate that plasma fibronectin is a heterodimeric molecule consisting of two very similar but not identical chains (A and B). In contrast, enzymatic digestion of cellular fibronectin produced a 50K heparin-binding fragment lacking monoclonal antibody reactivity which suggests that the cellular fibronectin subunit is similar to the plasma A chain in enzyme susceptibility but contains a larger heparin-binding domain. A model relating the differences in the three fibronectin polypeptides to differences in published cDNA sequences is presented.     

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.