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.     

Direct photolabeling of the cGMP-stimulated cyclic nucleotide phosphodiesterase

cGMP-stimulated phosphodiesterase (PDE) has been directly photolabeled with [32P]cGMP using UV light. Sequence analysis of peptide fragments obtained from partial proteolysis or cyanogen bromide cleavage indicate that two different domains are labeled. One site, on a Mr = 36,000 chymotryptic fragment located near the COOH terminus, has characteristics consistent with it being close to or part of the catalytic site of the enzyme. This peptide contains a region of sequence that is highly conserved in all mammalian cyclic nucleotide PDEs and has been postulated to contain the catalytic domain of the enzyme. The other site, on a Mr = 28,000 cyanogen bromide cleavage fragment located near the middle of the molecule, probably makes up part of the allosteric site of the molecule. Labeling of the enzyme is concentration dependent and Scatchard analysis of labeling yields a biphasic plot with apparent half labeling concentrations of about 1 and 30 microM consistent with two types of sites being labeled. Limited proteolysis of the PDE by chymotrypsin yields five prominent fragments that separate by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) at Mr = 60,000, 57,000, 36,000, 21,000, and 17,000. Both the Mr = 60,000 and 57,000 apparently have blocked NH2 termini suggesting that the Mr = 57,000 fragment is a subfragment of the Mr = 60,000 fragment. Primary sequence analysis indicates that both the Mr = 21,000 and 17,000 fragments are subfragments of the Mr = 36,000 fragment. Autoradiographs of photolabeled then partially proteolyzed enzyme show labeled bands at Mr = 60,000, 57,000, and 36,000. Addition of 5 microM cAMP prior to photolabeling eliminates photolabeling of the Mr = 36,000 fragment but not the Mr = 60,000 or 57,000 fragments. The labeled site not blocked by cAMP is also contained in a Mr = 28,000 cyanogen bromide fragment of the enzyme that does not overlap with the Mr = 36,000 proteolytic fragment. Limited chymotryptic proteolysis also increases basal activity and eliminates cGMP stimulation of cAMP hydrolysis. The chymotryptic fragments can be separated by either ion exchange high performance liquid chromatography (HPLC) or solid-phase monoclonal antibody treatment. A solid-phase monoclonal antibody against the cGMP-stimulated PDE removes the Mr = 60,000 and 57,000 labeled fragments and any intact, unproteolyzed protein but does not remove the Mr = 36,000 fragment or the majority of activity. Ion exchange HPLC separates the fragments into three peaks (I, II, and III). Peaks I and II contain activity of approximately 40 and 100 units/mg, respectively. Peak II is the undigested or slightly nicked native enzyme.(ABSTRACT TRUNCATED AT 400 WORDS)     

Differences in domain structure between human fibronectins isolated from plasma and from culture supernatants of normal and transformed fibroblasts. Studies with domain-specific antibodies

The domain structure of human fibronectins isolated from plasma and from the conditioned medium of normal and transformed fibroblasts was analyzed by limited proteolysis and S-cyanylation followed by immunostaining of released fragments with five kinds of antibodies, each specific for one functional domain. The results indicate that all three human fibronectins are composed of the same set of functional domains aligned in the same topological order. However, the following clear differences were found in specific fragments released from plasma fibronectin (pFN) and those released from fibronectin of normal (N-cFN) and transformed fibroblasts (T-cFN). Two fragments (Mr = 70,000 and 60,000) were released from the COOH-terminal region of pFN by cathepsin D. These fragments represent the COOH-terminal heparin-binding (Hep-2) and fibrin-binding (Fib-2) domains. The corresponding fragments released from both N-cFN and T-cFN by cathepsin D had much larger molecular weights (Mr = 100,000 and 83,000-74,000) than those from pFN. The fragments from the Fib-2 domain alone, however, did not show any difference among all three FNs. The internal region, from the gelatin-binding (Gel) domain through the Hep-2 domain, of N-cFN and T-cFN was released as a Mr = 210,000 fragment upon mild trypsin digestion. The corresponding fragment from pFN was released as a Mr = 185,000 fragment. The COOH-terminal half, including the Hep-2 domain, of both N-cFN and T-cFN was released by S-cyanylation as Mr = 160,000-145,000 fragments, which are 25,000-20,000 larger than the corresponding fragments of pFN. These results clearly indicate that the Hep-2 domain of N-cFN and T-cFN is 30,000-20,000 daltons larger than the same domain of pFN. Although various fragments released from N-cFN and T-cFN showed a similar pattern, there were minor differences. Thermolysin fragments derived from the Hep-2 domain of N-cFN were clearly distinguishable from those from T-cFN. Three groups of fragments with Mr = 40,000, 35,000-32,000, and 30,000 were released from N-cFN, while only the 35,000-32,000 fragment was released from T-cFN. The Mr = 44,000/60,000 thermolysin fragments representing the Gel domain and the Mr = 210,000/165,000 tryptic fragments representing the internal domains of T-cFN were slightly, but consistently, larger than those of N-cFN.(ABSTRACT TRUNCATED AT 400 WORDS)     

Isolation and characterization of the third complement component of axolotl (Ambystoma mexicanum)

1. Using a monoclonal anti-human C3 antibody and a polyclonal anti-cobra venom factor antibody as probes, a protein homologous to the mammalian third complement component (C3) was purified from axolotl plasma and found to be axolotl C3. 2. Axolotl C3 consists of two polypeptide chains (Mr = 110,000 and 73,000) linked by disulfide bonds. An internal thiolester bond in the alpha chain was identified by the incorporation of [14C]methylamine and NH2-terminal sequence from the C3d fragment of C3. 3. Digestion of C3 by trypsin resulted in the cleavage of both the alpha and beta chains, generating fragments with a cleavage pattern similar to that of human C3. 4. The amino acid composition of axolotl C3 and the amino acid sequences of the thiolester site (and the surrounding amino acids), the cleavage site for the C3-convertase, and one of the factor I cleavage sites are similar to C3 from other vertebrates. 5. In contrast to human C3, which has concanavalin A binding carbohydrates on both the alpha and beta chains, only the beta chain of axolotl C3 contains such carbohydrates.     

Heat-induced thiol-disulfide interchange reaction on the third component of human complement, C3

The third component of human complement, C3 is composed of two disulfide-bridged polypeptide chains of Mr 120,000 (alpha chain) and Mr 70,000 (beta chain). C3 has a thioester bond that serves as a binding site for targets when C3 is activated. Heat treatment of C3 induces autolytic peptide bond cleavage at the thioester site in the alpha chain as well as rupture of the thioester bond. The alpha chain fragments are linked to each other and beta chain via disulfide bonds. This study, however, documented that prolonged heating gave rise to liberation of several fragments including beta and the larger fragment of alpha chain. Using a fluorescent thiol reagent and [14C]iodoacetamide, we analyzed thiol residues present on each fragment, and elucidated that the thiol residue exposed by rupture of the thioester bond shifts in turn to another fragment resulting in the liberation of the fragments. The results were compatible with those on C4, and suggested that the generated thiol residue induces thiol-disulfide interchange reaction. On heating of plasma, fragments of C3 were not released, while the cleavage of the alpha chain occurred more effectively. The heated C3 (56 degrees C, 15 min) became insusceptible to C3b inactivator (I) and factor H, suggesting that additional conformational change is accompanied with cleavage of the thioester bond.     

The Mr 46,000 nuclear scaffold ATP-binding protein: identification of the putative nucleoside triphosphatase by proteolysis and monoclonal antibodies directed against lamins A/C

Previous work suggested that the major Mr 46,000 ATP-binding protein [a putative nucleoside triphosphatase (NTPase)] found in rat liver nuclear scaffold (NS) may be proteolytically derived from lamins A/C. To definitively establish this identification, we undertook a series of photolabeling, proteolysis, and immunoprecipitation experiments. Mice were immunized with human lamin C expressed in bacteria, and monoclonal antibody-producing hybridomas were obtained. The purified monoclonal antibodies all recognized lamins A and C on immunoblots of NS, as well as Mr 46,000 or 34,000 proteolytic fragments as minor components. The Mr 46,000 photolabeled band was the only major NS component photolabeled with low concentrations of azido-ATP, and it was immunoprecipitated with anti-lamin monoclonal antibodies. To preclude the possibility that the photolabeled Mr 46,000 protein represented a minor component which comigrated with the Mr 46,000 lamin fragment and which specifically associated with lamins A/C during immunoprecipitation, a series of proteolytic digestions were undertaken. Digestion of the photolabeled Mr 46,000 peptide with chymotrypsin and staphylococcal protease V8 produced a limited number of photolabeled fragments, all of which comigrated with major stainable fragments produced from the Mr 46,000 lamin fragment. Cyanogen bromide cleavage of the photolabeled Mr 46,000 polypeptide, followed by polyacrylamide gel electrophoresis or high performance liquid chromatography/amino acid analyses, defined the COOH-terminal cleavage site as the Y residue at amino acid 376 and localized the photolabeled site to the COOH-terminal region (amino acids 372-376). In support of this proposed proteolytic cleavage site, specific assays with tyrosine-containing thiobenzyl ester substrate documented the presence of NS protease activity which cleaves at tyrosine residues; this activity shows a Km of 0.2 mM and a Kcat of approximately 250/s. Parallel experiments with mildly proteolyzed cloned lamin C preparations showed selective photolabeling of an Mr 34,000 fragment, which corresponds to a proteolytic breakdown product of the Mr 46,000 NS polypeptide; this Mr 34,000 photolabeled fragment was also immunoprecipitated with anti-lamin monoclonal antibodies and contained the same photolabeled site as the Mr 46,000 peptide. Cloned lamin C preparations were inactive in NTPase assays but did exhibit substantial ATP binding with an apparent KD = 4 x 10(-5) M ATP. These results indicate that the major Mr 46,000 photoaffinity-labeled protein in NS, which represents the putative NTPase thought to participate in nucleocytoplasmic transport, is derived from lamin A or lamin C by NS proteolytic activity which exposes a cryptic ATP-binding site near the highly conserved end of coil-2.(ABSTRACT TRUNCATED AT 400 WORDS)     

Purification and structural characterization of intact and fragmented nidogen obtained from a tumor basement membrane

Extraction of a basement-membrane-producing mouse tumor with 6 M guanidine/HCl in the presence of protease inhibitors allowed the purification of the genuine form of the matrix protein nidogen (Mr = 150,000) and, in addition, two defined fragments (Mr = 130,000 and 100,000). Smaller fragments (Mr = 80,000 and 40,000) were obtained under conditions with less stringent control of endogenous proteolysis. Intact nidogen and the larger fragments were similar in amino acid and carbohydrate (about 5%) composition, the presence of a single polypeptide chain, conformational features as revealed by CD spectroscopy and all shared major epitopes located on the Mr = 80,000 fragment. Additional epitopes were found on intact nidogen and the Mr = 130,000 fragment. Nidogen and the various fragments possess different N-terminal amino acid sequences indicating a stepwise degradation from the N-terminal end of the molecule. Electron microscopical and hydrodynamic studies of the Mr = 80,000 fragment demonstrated a structure consisting of a globular head connected to a thin tail. Intact nidogen appears to contain a somewhat larger globule but the same tail, which is terminated at its opposite end by a second, smaller globular structure. The data suggest a multidomain structure for nidogen containing sites highly susceptible to proteolytic cleavage.     

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.     

Physiologic inactivation of fluid phase C3b: isolation and structural analysis of C3c, C3d,g (alpha 2D), and C3g

The fragments that result from the inactivation of C3b have not been completely characterized. Initial inactivation is catalyzed by the protease factor I, which, in the presence of its cofactor (factor H), cleaves two peptide bonds in the alpha'-chain of C3b. This results in the release of a small peptide (C3f, Mr 3000) from iC3b, which consists of the C3 beta chain covalently bonded to two alpha'-chain-derived peptides (Mr 68,000 and Mr 43,000). Surface-bound iC3b is cleaved at a third site by factor I to produce C3c and C3d,g (or alpha 2D). The factor I cofactor for this cleavage is the C3b receptor that is present on erythrocyte and leukocyte membranes. This report describes the isolation and initial structural characterization of C3c and C3d,g generated in whole blood after complement activation with cobra venom factor. These fragments were compared with the C3 fragments isolated from the serum and plasma of a patient with complement activation in vivo. The fragments were isolated with two solid phase monoclonal antibodies, one of which recognizes a determinant on C3g (clone 9) and one of which recognizes a determinant on C3c (clone 4). C3c isolated from normal blood showed three polypeptides that had apparent m.w. of 75,000, 43,000, and 27,000. The C3d,g consisted of a single polypeptide chain with a m.w. of 40,000. Amino terminal sequence analysis showed that the Mr 27,000 peptide from C3c is derived from the amino terminal portion of the alpha'-chain of C3b, whereas the Mr 43,000 peptide is derived from the carboxy terminus of the same chain. Amino terminal sequence analysis showed also that C3g is derived from the amino terminus of C3d,g. The C3 fragments isolated from a patient with partial lipodystrophy, nephritic factor activity, low serum C3 levels, and circulating C3 cleavage products showed a more complicated pattern on SDS-PAGE. The fragment isolated with clone 9 had an apparent m.w. of 40,000, identical to C3d,g generated in vitro, and it had the same amino terminal sequence as C3d,g generated in vitro. The eluate from insolubilized clone 4, however, showed prominent bands with Mr of 75,000, 56,000, 43,000, and 27,000, together with a triple-banded pattern at 68,000 and a minor band at 80,000. This eluate thus appears to contain C3c, and iC3b or an iC3b-like product. The origin of the Mr 56,000 and Mr 80,000 peptides have not yet been determined. These studies, with previous data, definitively order the C3c and C3d,g peptides in the alpha-chain of C3.(ABSTRACT TRUNCATED AT 400 WORDS)     

Characterization of antisera to a synthetic carboxyl-terminal peptide of the glucose transporter protein

Peptides corresponding to amino acid residues 1-12 of the amino terminal and 480-492 of the carboxyl terminal of the deduced sequence of the glucose transporter were synthesized and used to produce site-specific polyclonal antipeptide sera. In a solid-phase radioimmunoassay, antiserum to the carboxyl terminal recognizes peptide 480-492 and purified human erythrocyte glucose transporter, but not peptide 1-12. Antiserum to the amino terminal recognizes peptide 1-12 but neither peptide 480-492 nor the erythrocyte transporter. The antiserum to the carboxyl terminal specifically immunoblots the Mr 55,000 glucose transporter in erythrocyte membranes and the purified erythrocyte transporter. It also recognizes a Mr 40,000-60,000 polypeptide in membranes of cells derived from different mammalian species and tissues including insulin-sensitive rat adipocytes as well as a Mr 20,000 tryptic fragment of the transporter which contains the site for photolabeling by cytochalasin B. Antiserum to the carboxyl terminal of the transporter binds specifically to leaky erythrocyte membranes but not to intact erythrocytes. This binding is saturable and competitively inhibited by peptide 480-492. Using immunofluorescence microscopy, this antiserum detects glucose transporter protein in permeabilized erythrocytes, but not in intact erythrocytes. These studies provide immunochemical evidence in support of the predicted cytoplasmic orientation of the carboxyl terminus of the glucose transporter, allow us to suggest a spatial relationship of the cytochalasin B binding site to the carboxyl terminal of the glucose transporter and suggest that antisera directed to the carboxyl terminal domain of the protein may be useful for the immunocytochemical localization of the glucose transporter.     

Terminal regions of flagellin are disordered in solution

Limited proteolysis of flagellin from Salmonella typhimurium SJW1103 by subtilisin, trypsin and thermolysin results in homologous degradation patterns. The terminal regions of flagellin are very sensitive to proteolysis. These parts are degraded into small oligopeptides at the very early stage of a mild digestion that yields a relatively stable fragment with a molecular weight of 40,000. Further proteolytic degradation results in a stable 27,000 Mr fragment. The 40,000 Mr tryptic fragment has been identified as residues 67 to 446 of the flagellin sequence, while the 27,000 Mr fragment involves the 179 to 418 segment. The NH2-terminal sequence positions for the corresponding fragments produced by subtilisin are 60 and 174 for the 40,000 Mr and 27,000 Mr fragments, respectively. The fragments lost their polymerizing ability. Structural properties of flagellin and its 40,000 Mr tryptic fragment were compared by circular dichroism spectroscopy and differential scanning calorimetry. Analysis of the calorimetric melting profiles suggests that terminal parts of flagellin have no significant internal stability and they are in extensive contact with water. However, these regions contain some secondary structure, probably alpha-helices, as revealed by comparison of the circular dichroic spectra in the far-ultraviolet region. Our results indicate that, although the terminal regions of flagellin may contain some alpha-helical secondary structure of marginal stability, they have no compact ordered tertiary structure in solution. On the contrary, the central region of the molecule involves at least two compact structural units.     

A novel cleavage product of human complement component C3 with structural and functional properties of cobra venom factor

The generation of two cleavage products of human C3, termed C3o and C3p, by incubation with a C3-cleaving protease isolated from cobra venom (Naja naja siamensis) is described. The venom protease removes the C3p fragment (Mr approximately 33,000) from the C3dg region of the C3 alpha-chain. The major cleavage fragment C3o (Mr approximately 140,000) contains the unaltered beta-chain of C3 and two alpha-chain-derived polypeptides of Mr approximately 29,000 and Mr approximately 38,000, respectively. Amino-terminal amino acids sequence analysis of C3p and the three chains of C3o allowed the identification of the exact location of the two alpha-chain-derived fragments of C3o and the three cleavage sites of the venom protease. The chain structure of C3o resembles those of C3c and cobra venom factor. In contrast to C3c but like cobra venom factor (and C3b), C3o was found to support the activation of the serine protease Factor B by cleavage in the presence of Factor D and Mg2+ into Bb and Ba, generating an enzymatically active complex that is able to cleave a fluorogenic peptide substrate for C3 convertases. Since the only stretch of amino acid residues of C3o not present in C3c is the carboxyl terminus of the Mr approximately 29,000 chain of C3o, it is suggested that this region is important for the interaction with Factor B and convertase formation.     

Studies on the structure of the calcium-dependent adenosine triphosphatase from rabbit skeletal muscle sarcoplasmic reticulum

The linear arrangement of the three fragments of Ca²⁺-ATPase from rabbit skeletal muscle sarcoplasmic reticulum with molecular weights of 20,000, 30,000, and 45,000 obtained by limited tryptic hydrolysis was determined by locating the NH₂-terminal acetylated methionyl residue of the original peptide in the M_r = 20,000 fragment. Since both the M_r = 20,000 and 30,000 polypeptides originate from a M_r = 55,000 fragment which is distinct from the M_r = 45,000 polypeptide, the sequence of these three fragments was determined to be 20,000, 30,000, and 45,000. The M_r = 20,000 fragment was further cleaved by cyanogen bromide to yield a M_r = 7,000 COOH-terminal fragment which is relatively hydrophilic. The NH₂-terminal portion is rich in glutamyl residues. The COOH-terminus of the M_r = 30,000 fragment was determined by both digestion with carboxypeptidases and cyanogen bromide cleavage. Using the partial amino acid sequence of the Ca²⁺-ATPase, it was deduced that the active site phosphoaspartyl residue is 154 amino acids from the COOH-terminus of the M_r = 30,000 fragment and hence approximately 35,000 M_r from the NH₂-terminus of the original Ca²⁺-ATPase molecule. Furthermore, it was shown that the two tryptic cleavages of the Ca²⁺-ATPase generating these three large fragments were both single hydrolyses of arginylalanine peptide bonds.     

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.     

Hydrogen peroxide stabilizes the steroid-binding state of rat liver glucocorticoid receptors by promoting disulfide bond formation

Hydrogen peroxide and diamide inactivate the steroid-binding capacity of unoccupied glucocorticoid receptors in rat liver cytosol at 0 degrees C, and steroid-binding capacity is reactivated with dithiothreitol. Treatment of cytosol with peroxide or sodium molybdate, but not diamide, inhibits the irreversible inactivation (i.e., inactivation not reversed by dithiothreitol) of steroid-binding capacity that occurs when cytosol is incubated at 25 degrees C. Pretreatment of cytosol with the thiol derivatizing agent methyl methanethiosulfonate at 0 degrees C prevents the ability of peroxide, but not molybdate, to stabilize binding capacity at 25 degrees C. As derivatization of thiol groups prevents peroxide stabilization of steroid-binding capacity and as treatment with dithiothreitol reverses the effect, we propose that peroxide acts by promoting the formation of new disulfide linkages. The receptor in our rat liver cytosol preparations is present as three major degradation products of Mr 40,000, 52,000, and 72,000 in addition to the Mr 94,000 intact receptor. Like the intact receptor, these three forms exist in the presence of molybdate as an 8-9S complex, they bind glucocorticoid in a specific manner, and they copurify with the intact Mr 94,000 receptor on sequential phosphocellulose and DNA-cellulose chromatography. Despite the existence of receptor cleavage products, it is clear that peroxide does not stabilize steroid-binding capacity by inhibiting receptor cleavage.     

Methylamine reaction and denaturation-dependent fragmentation of complement component 3. Comparison with alpha2-macroglobulin

Complement protein C-3 can covalently incoporate [14C]methylamine with a stoichiometry of 0.85 +/- 0.11 mol/mol of protein. The reactive site is located in the larger, Mr = 135,000 peptide subunit of C-3. The methylamine is incorporated as a derivative of glutamic acid, viz. as gamma-glutamylmethylamide, which was identified by high performance liquid chromatography and low resolution mass spectroscopy. C-3 was shown to undergo a specific, denaturation-dependent protein fragmentation in sodium dodecyl sulfate at 90 degrees C. The cleavage results in the partial conversion of the Mr = 135,000 subunit to fragments of Mr = 84,000 and 53,000. The cleavage is completely prevented by reaction of C-3 with methylamine prior to the 90 degrees C incubation. The site of methylamine incorporation (the glutamyl residue) and the peptide fragmentation reaction have been reported for alpha2-macroglobulin (Howard, J.B., Vermeulen, M., and Swenson, R. (1980) J. Biol. Chem. 255, 3820-3823). A comparison of the results for the two proteins suggests that they have a common reactive site.     

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.     

The calmodulin and F-actin binding sites of smooth muscle caldesmon lie in the carboxyl-terminal domain whereas the molecular weight heterogeneity lies in the middle of the molecule

Caldesmons are major Ca2+-calmodulin regulated F-actin binding proteins of smooth and non-muscle cells that have been implicated as components of a thin filament regulatory system. Chicken gizzard caldesmons are monomeric proteins of Mr 140,000 and 135,000. We have employed enzymatic and chemical cleavage methods in order to dissect the protein to locate the Ca2+-calmodulin and F-actin binding domain and the site of molecular weight heterogeneity. Using a novel mapping procedure that employs partial chemical cleavage at cysteine residues, we show that both caldesmon polypeptides contain 2 cysteine residues located approximately 28,000 from the protein's amino terminus and the second approximately 25,000 from the carboxyl terminus. Identification of the composition of partial cleavage products with region-specific antibodies is consistent with this derived map. The apparent molecular weight heterogeneity was found to lie in the approximately 80,000 region between the 2 cysteine residues and therefore is not due to proteolytic processing. Digestion with alpha-chymotrypsin yields a relatively stable basic Mr 40,000 Ca2+-calmodulin and F-actin binding fragment that we have purified and characterized. The chymotryptic 40,000 fragment contains the 25,000 carboxyl-terminal fragment and therefore is derived from the carboxyl-terminal region of caldesmon. The 25,000 fragment obtained after chemical cleavage at cysteine under native conditions has also been purified and shown to bind F-actin and Ca2+-calmodulin. Surprisingly, the purified carboxyl 25,000 fragment, unlike the reduced intact monomer, cross-links F-actin into tightly ordered bundles in which the filaments are in register.     

Proteolysis of factor Va by factor Xa and activated protein C

Bovine Factor Va, produced by selective proteolytic cleavage of Factor V by thrombin, consists of a heavy chain (D chain) of Mr = 94,000 and a light chain (E chain) of Mr = 74,000. These peptides are noncovalently associated in the presence of divalent metal ion(s). Each chain is susceptible to proteolysis by activated protein C and by Factor Xa. Sodium dodecyl sulfate electrophoretic analysis indicates that cleavage of the E chain by either activated protein C or Factor Xa yields two major fragments: Mr = 30,000 and Mr = 48,000. Amino acid sequence analysis indicates that the Mr = 30,000 fragments have identical NH2-terminal sequences and that this sequence corresponds to that of intact E chain. The Mr = 48,000 fragments also have identical NH2-terminal sequences, indicating that activated protein C and Factor Xa cleave the E chain at the same position. Sodium dodecyl sulfate electrophoretic analysis indicates that activated protein C cleavage of the D chain yields two products: Mr = 70,000 and Mr = 24,000. Amino acid sequence analysis indicates that the Mr = 70,000 fragment has the same NH2-terminal sequence as intact D chain, whereas the Mr = 24,000 fragment does not. Factor Xa cleavage of the D chain also yields two products: Mr = 56,000 and Mr = 45,000. The Mr = 56,000 fragment corresponds to the NH2-terminal end of the D chain and Factor V. Functional studies have shown that both chains of Factor Va may be entirely cleaved to products by Factor Xa without loss of activity, whereas activated protein C cleavage results in loss of activity. Since activated protein C and Factor Xa cleave the E chain at the same position, the cleavage of the D chain by activated protein C is responsible for the inactivation of Factor Va.     

Structure of alpha-polymer from in vitro and in vivo highly cross-linked human fibrin.

Peptides derived from plasmic and cyanogen bromide (CNBr) cleavage of highly cross-linked fibrin were isolated and characterized by sodium dodecyl sulfate-gel electrophoresis, amino acid analyses, cyanoethylation, and NH2-terminal analyses. Extended plasmic digestions of human fibrin containing four epsilon-(gamma-glutamyl)lysine cross-links per molecule produced a peptide of alpha-chain origin (Mr congruent to 21,000) which was comprised of a small donor peptide cross-linked to the acceptor site peptide from the middle of the alpha-chain. CNBr cleavage of highly cross-linked in vitro fibrin or of fibrin from a spontaneously formed in vivo arterial embolus produced about three cross-linked species of molecular weights 30,000 to 40,000, each of which contained the largest CNBr fragment (Mr = 29,000) from the alpha-chain. The predominant cross-link-containing CNBr fragments derived their donor group from the near COOH-terminal region of the alpha-chain as judged by difference amino acid compositions and NH2-terminal analyses. Additionally, cross-linked fragments of molecular weights 68,000 to 70,000 which appeared to contain two acceptor site peptides (Mr = 29,000) were detected in minor amounts in the CNBr digests of fibrin formed from whole plasma or from purified, plasminogen-free fibrinogen. No larger polymeric cross-linked CNBr fragment was generated from any of the highly cross-linked fibrin preparations examined. A model for the predominant mode of alpha-chain polymerization is proposed.