Functional differentiation of cyclooxygenase and peroxidase activities of prostaglandin synthase by trypsin treatment. Possible location of a prosthetic heme binding site

Treatment of prostaglandin (PG)H synthase purified from ram seminal vesicle microsomes with trypsin cleaves the 70-kDa subunits into 33- and 38-kDa fragments (Chen, Y.-N. P., Bienkowski, M. J., and Marnett, L. J. (1987) J. Biol. Chem. 262, 16892-16899). In contrast to a minimal decrease in cyclooxygenase activity, peroxidase activity declines rapidly following trypsin treatment. The time course for loss of guaiacol peroxidase activity corresponds closely to the time course for protein cleavage. The ability of trypsin-treated enzyme to support catalytic reduction of 5-phenyl-4-pentenyl-1-hydroperoxide in the presence of reducing substrates is significantly reduced. The products of metabolism of 10-hydroperoxy-8,12-octadecadienoic acid indicate that trypsin-treated enzyme catalyzes homolytic scission of the hydroperoxide bond in contrast to the heterolytic scission catalyzed by intact enzyme. Spectrophotometric titrations of hematin addition to trypsin-treated PGH synthase indicate approximately a 50% reduction in heme binding. These observations suggest that trypsin treatment of PGH synthase decreases the ability of the protein to bind prosthetic heme at a site that controls peroxidase activity. Comparison of the N-terminal sequence of the 38-kDa fragment of trypsin-treated PGH synthase to the amino acid sequence of the intact protein indicates that cleavage occurs between Arg253 and Gly254. Based on literature precedents and the results of the present investigations, we propose that the heme prosthetic group that controls the peroxidase activity of PGH synthase binds to the His residue of the sequence His250-Tyr251-Pro252-Arg253 located immediately adjacent to the trypsin cleavage site.     

Acetylation of prostaglandin endoperoxide synthase by N-acetylimidazole: comparison to acetylation by aspirin.

Treatment of prostaglandin endoperoxide (PGH) synthase apoprotein with a 100- or 1000-fold excess of N-acetylimidazole (NAI) led to time-dependent inactivation of both cyclooxygenase and peroxide activities. Reconstitution of apoprotein with heme prior to incubation with NAI substantially protected the enzyme from inactivation. Pretreatment of the protein with either acetylsalicylic acid (aspirin) or (+/-)-2-fluoro-alpha-methyl-4-biphenylacetic acid (flurbiprofen), which inhibit cyclooxygenase activity, did not alter the time course of peroxidase inactivation by NAI. Treatment of NAI-inactivated apoPGH synthase with hydroxylamine led to substantial regeneration of both cyclooxygenase and peroxidase activities. Quantitation of radioactivity following incubation of PGH synthase with [3H-acetyl]NAI indicated incorporation of 1.7 +/- 0.9 acetyl groups/70-kDa subunit. Cleavage of acetylated protein with trypsin under nondenaturing conditions followed by high-performance liquid chromatography analysis demonstrated that most of the radioactivity was incorporated into the 33-kDa fragment although significant radioactivity was also detectable in the 38-kDa fragment. Chymotryptic peptide mapping of acetylated protein revealed numerous potential sites of acetylation distributed in widely divergent regions of the protein. No apparent differences were observed between the chymotryptic maps of apo- and holoenzyme, suggesting that the adduct responsible for loss of catalytic activity is unstable to the chromatographic conditions. The different biochemical properties of PGH synthase acetylated by NAI or aspirin suggest that a major determinant of the specificity of aspirin for Ser530 is binding of the salicylate moiety to this region of the PGH synthase protein.     

Differential modification of cyclo-oxygenase and peroxidase activities of prostaglandin endoperoxidase synthase by proteolytic digestion and hydroperoxides.

Prostaglandin endoperoxide synthase (PES, EC 1.14.99.1) catalyse the conversion of arachidonic acid into prostaglandin H2. The enzyme is a 140 kDa homodimer which contains both a cyclo-oxygenase activity (converting arachidonate into prostaglandin G2) and peroxidase activity (reducing prostaglandin G2 to H2). PES undergoes rapid self-inactivation during oxygenation of arachidonate to prostaglandin H2 in vitro. The previously reported cDNA-derived amino acid sequence indicates numerous sites for trypsin or thrombin cleavage. Most of these sites must be inaccessible, since these enzymes cleave only at Arg253. The enzyme appears to be a self-adherent and highly folded molecule, since after cleavage it retains its functional assembly and its homodimer size of 140 kDa, as well as its overall enzymic activity. Only under denaturing conditions (e.g. SDS/PAGE) can the proteolytic peptides be demonstrated: a 38 kDa C-terminal fragment containing the aspirin-derived-acetyl-binding ability, and a 33 kDa N-terminal fragment. In the present studies we investigated whether the two enzymic activities of PES can be differentially manipulated by proteolytic cleavage or by substrate (arachidonate) self-inactivation. The results indicated that, during arachidonate oxygenation by PES, the cyclooxygenase activity is selectively inactivated, whereas the peroxidase activity is essentially retained. By contrast, thrombin or trypsin cleavage of pure PES or microsomal PES (to yield the 38 and 33 kDa peptide fragments) inactivated the peroxidase, but not the cyclo-oxygenase. Taken together, these results suggest the presence of separate cyclo-oxygenase and peroxidase structural domains on the enzyme.     

Essential histidines of prostaglandin endoperoxide synthase. His-309 is involved in heme binding

Prostaglandin endoperoxide (PGH) synthase has a single iron protoporphyrin IX which is required for both the cyclooxygenase and peroxidase activities of the enzyme. At room temperature, the heme iron is coordinated at the axial position by an imidazole, and about 20% of the heme iron is coordinated at the distal position by an imidazole. We have used site-directed mutagenesis to investigate which histidine residues are involved in PGH synthase catalysis and heme binding. Individual mutant cDNAs for ovine PGH synthases were prepared with amino acid substitutions at each of 13 conserved histidines. cos-1 cells were transfected with each of these cDNAs, and the cyclooxygenase and peroxidase activities of the resulting microsomal PGH synthases were measured. Mutant PGH synthases in which His-207, His-309, or His-388 was replaced with either glutamine or alanine lacked both activities. Gln-386 and Ala-386 PGH synthase mutants exhibited cyclooxygenase but not peroxidase activities. Other mutants exhibited both activities at varying levels. Because binding of heme renders native PGh synthase resistant to cleavage by trypsin, we examined the effects of heme on the relative sensitivities of native, Ala-204, Ala-207, Ala-309, Ala-386, and Ala-388 mutant PGH synthases to trypsin as a measure of the heme-protein interaction. The Ala-309 PGh synthase mutant was notably hypersensitive to tryptic cleavage, even in the presence of exogenous heme; in contrast, the native enzyme and the other alanine mutants exhibited similar, lower sensitivities toward trypsin and, except for the Ala-386 mutant, were partially protected from trypsin cleavage by heme. Preincubation of the native and each of the alanine mutant PGH synthases, including the Ala-309 mutant, with indomethacin protected the proteins from trypsin cleavage. Thus, all the mutant proteins retain sufficient three-dimensional structure to bind cyclooxygenase inhibitors. Our results suggest that His-309 is one of the heme ligands, probably the axial ligand, of PGH synthase. Two other histidines, His-207 and His-388, are essential for both PGH synthase activities suggesting that either His-207 or His-388 can serve as the distal heme ligand; however, the trypsin cleavage measurements imply that neither His-207 nor His-388 is required for heme binding. This is consistent with the fact that only 20% of the distal coordination position of the heme iron of PGH synthase is occupied by an imidazole side chain.     

Topographic studies of microsomal and pure prostaglandin H synthase

Prostaglandin H synthase catalyzes the first step in the conversion of polyunsaturated fatty acids to prostaglandins, thromboxanes, and prostacyclins. The enzyme is normally bound to the endoplasmic reticulum membrane, but can be purified to homogeneity after solubilization with detergent. The topologies of the microsomal and the pure detergent-solubilized forms of the synthase were compared by an examination of their sensitivity to degradation by proteases, of the effect of heme on this protease sensitivity, and of the sizes of proteolytic fragments produced. For the microsomal synthase, the localization of proteolytic fragments was also determined. Analysis of the microsomal proteins after proteolytic digests involved separation by polyacrylamide gel electrophoresis and selective detection of the synthase-derived polypeptides with a polyclonal antibody against the pure synthase. With both the microsomal and the pure synthase, incubation with trypsin led to a progressive loss of cyclooxygenase activity and cleavage of the synthase subunit (70K Da) into two fragments of 38K and 33K Da. Incubation of the detergent-solubilized form of the synthase with proteinase K and chymotrypsin also produced a very similar pair of fragments (38K and 33K Da). After incubation of the microsomes with trypsin both the 38K and 33K Da fragments from the synthase remained bound to the membrane; no cyclooxygenase activity was released in soluble form from the microsomes by trypsin. Further, neither trypsin nor proteinase K released soluble radiolabeled peptides from microsomes whose synthase had been labeled with [acetyl-14C]-aspirin. With the microsomal synthase the sensitivity to protease (66% of the cyclooxygenase activity was lost after 90 min incubation with proteinase K) was enhanced by depletion of heme (84% of activity lost) and was decreased by addition of heme (only 20% of activity lost), just as had been previously demonstrated for the detergent-solubilized synthase. At each of several intervals during an incubation of the pure synthase with trypsin the extent of cleavage of the synthase polypeptide correlated reasonably well with the extent of loss of cyclooxygenase activity; a similar relation between proteolytic cleavage and loss of activity was observed in digests of the pure synthase supplemented with differing amounts of heme.(ABSTRACT TRUNCATED AT 400 WORDS)     

Heme prosthetic group required for acetylation of prostaglandin H synthase by aspirin

The ability of aspirin to acetylate PGH synthase was determined by reacting [3H-acetyl]-aspirin with purified enzyme followed by high pressure liquid chromatography analysis of the protein components of the reaction mixture. Heme-reconstituted enzyme incorporated approximately one acetyl group per 70-kDa subunit, whereas apoprotein incorporated 0.1 acetyl group per subunit. The ability of the heme prosthetic group to enhance acetylation of the protein was correlated with its ability to protect the Arg253-Gly254 peptide bond from cleavage by trypsin. Thus, heme-induced alteration of protein conformation may contribute to the enhanced labeling of Ser506 by aspirin. The present results indicate that irreversible inactivation of prostaglandin H synthase by aspirin occurs only when the heme prosthetic group is bound to the protein. Considering its short in vivo half-life, it is likely that aspirin inactivates only the steady-state fraction of PGH synthase in a cell that is active but not newly synthesized apoprotein. This may contribute to the differential kinetics of inactivation and recovery of PGH synthase activity in platelets and vascular endothelial cells after administration of low dose aspirin as a prophylactic agent against cardiovascular disease.     

Topography of prostaglandin H synthase. Antiinflammatory agents and the protease-sensitive arginine 253 region

Prostaglandin H synthase catalyzes two reactions: the bis-dioxygenation of arachidonic acid to form prostaglandin G2 (cyclooxygenase activity), and the reduction of hydroperoxides to the corresponding alcohols (peroxidase activity). The cyclooxygenase activity can be selectively inhibited by many nonsteroidal antiinflammatory agents including indomethacin. In the native synthase, there is a single prominent protease-sensitive region, located near Arg253; binding of the heme prosthetic group makes the synthase resistant to proteases. To investigate the spatial relationship between the area of the synthase which interacts with indomethacin and the protease-sensitive region, the effects of indomethacin and similar agents on the protease sensitivity of the two enzymatic activities and of the synthase polypeptide were examined. Incubation of the synthase apoenzyme with trypsin (3.6% w/w) resulted in the time-dependent coordinate loss (75% at 1 h) of both enzymatic activities and the cleavage (85% at 1 h) of the 70-kDa subunit into 38- and 33-kDa fragments, indicating that proteolytic cleavage of the polypeptide at Arg253, destroyed both activities of the synthase simultaneously. Indomethacin, (S)-flurbiprofen, or meclofenamate (each at 20 microM) rendered both activities and the synthase polypeptide (at 5 microM subunit) resistant to attack by trypsin or proteinase K; these agents also inhibited the cyclooxygenase activity of the intact synthase. Two reversible cyclooxygenase inhibitors, ibuprofen and flufenamate, also made both of the activities and the synthase polypeptide more resistant to trypsin. Titration of the apoenzyme with indomethacin (0-3 mol/mol of synthase dimer) resulted in proportional increases in the inhibition of the cyclooxygenase and in the resistance to attack by trypsin. (R)-Flurbiprofen did not increase the resistance to protease or appreciably inhibit the cyclooxygenase. These results suggest that the same stereospecific interaction of these agents with the synthase that produced inhibition of the cyclooxygenase led to a decreased accessibility of the Arg253 region to proteases. Aspirin treatment made the synthase less resistant to trypsin; aspirin-treated synthase became more resistant to trypsin when it was incubated with indomethacin before addition of the protease. The presence of 50 microM arachidonate during digestion of apoenzyme or aspirin-treated apoenzyme with trypsin did not decrease the cleavage of the synthase subunit.(ABSTRACT TRUNCATED AT 400 WORDS)     

Immunochemical characterization of rat brain protein kinase C

Polyclonal antibodies against rat brain protein kinase C (the Ca2+/phospholipid-dependent enzyme) were raised in goat. These antibodies can neutralize completely the kinase activity in purified enzyme preparation as well as that in the crude homogenate. Immunoblot analysis of the purified and the crude protein kinase C preparations revealed a major immunoreactive band of 80 kDa. The antibodies also recognize the same enzyme from other rat tissues. Neuronal tissues (cerebral cortex, cerebellum, hypothalamus, and retina) and lymphoid organs (thymus and spleen) were found to be enriched in protein kinase C, whereas lung, kidney, liver, heart, and skeletal muscle contained relatively low amounts of this kinase. Limited proteolysis of the purified rat brain protein kinase C with trypsin results in an initial degradation of the kinase into two major fragments of 48 and 38 kDa. Both fragments are recognized by the antibodies. However, further digestion of the 48-kDa fragment to 45 kDa and the 38-kDa fragment to 33 kDa causes a loss of the immunoreactivity. Upon incubation of the cerebellar extract with Ca2+, the 48-kDa fragment was also identified as a major proteolytic product of protein kinase C. Proteolytic degradation of protein kinase C converts the Ca2+/phospholipid-dependent kinase to an independent form without causing a large impairment of the binding of [3H]phorbol 12,13-dibutyrate. The two major proteolytic fragments were separated by ion exchange chromatography and one of them (45-48 kDa) was identified as a protein kinase and the other (33-38 kDa) as a phorbol ester-binding protein. This degraded form of the phorbol ester-binding protein still requires phospholipid for activity but, unlike the native enzyme, becomes less dependent on Ca2+. These results demonstrate that rat brain protein kinase C is composed of two functionally distinct units, namely, a protein kinase and a Ca2+-independent/phospholipid-dependent phorbol ester-binding protein.     

Quantitative studies of hydroperoxide reduction by prostaglandin H synthase. Reducing substrate specificity and the relationship of peroxidase to cyclooxygenase activities

The peroxidase activity of prostaglandin H (PGH) synthase catalyzes reduction of 5-phenyl-4-pentenyl hydroperoxide to 5-phenyl-4-pentenyl alcohol with a turnover number of approximately 8000 mol of 5-phenyl-4-pentenyl hydroperoxide/mol of enzyme/min. The kinetics and products of reaction establish PGH synthase as a classical heme peroxidase with catalytic efficiency similar to horseradish peroxidase. This suggests that the protein of PGH synthase evolved to facilitate peroxide heterolysis by the heme prosthetic group. Comparison of an extensive series of phenols, aromatic amines, beta-dicarbonyls, naturally occurring compounds, and nonsteroidal anti-inflammatory drugs indicates that considerable differences exist in their ability to act as reducing substrates. No correlation is observed between the ability of compounds to support peroxidatic hydroperoxide reduction and to inhibit cyclooxygenase. In addition, the resolved enantiomers of MK-410 and etodolac exhibit dramatic enantiospecific differences in their ability to inhibit cyclooxygenase but are equally potent as peroxidase-reducing substrates. This suggests that there are significant differences in the orientation of compounds at cyclooxygenase inhibitory sites and the peroxidase oxidation site(s). Comparison of 5-phenyl-4-pentenyl hydroperoxide reduction by PGH synthase and horseradish peroxidase reveals considerable differences in reducing substrate specificity. Both the cyclooxygenase and peroxidase activities of PGH synthase inactivate in the presence of low micromolar amounts of hydroperoxides and arachidonic acid. PGH synthase was most sensitive to arachidonic acid, which exhibited an I50 of 0.6 microM in the absence of all protective agents. Inactivation by hydroperoxides requires peroxidase turnover and can be prevented by reducing substrates. The I50 values for inactivation by 15-hydroperoxy-5,8,11,13-eicosatetraenoic acid are 4.0 and 92 microM, respectively, in the absence and presence of 500 microM phenol, a moderately good reducing substrate. The ability of compounds to protect against hydroperoxide-induced inactivation correlates directly with their ability to act as reducing substrates. Hydroquinone, an excellent reducing substrate, protected against hydroperoxide-induced inactivation when present in less than 3-fold molar excess over hydroperoxide. The presence of a highly efficient hydroperoxide-reducing activity appears absolutely essential for protection of the cyclooxygenase capacity of PGH synthase. The peroxidase activity is, therefore, a twin-edged sword, responsible for and protective against hydroperoxide-dependent inactivation of PGH synthase.(ABSTRACT TRUNCATED AT 400 WORDS)     

Steroid binding activity is retained in a 16-kDa fragment of the steroid binding domain of rat glucocorticoid receptors

The steroid binding domain of the rat glucocorticoid receptor is considered as extending from amino acids 550 to 795. However, such a synthetic protein (i.e. amino acids 547-795; Mr approximately 31,000) has been reported to show very little affinity for the potent synthetic glucocorticoid dexamethasone. We now disclose that digestion of steroid-free rat glucocorticoid receptors with low concentrations of trypsin yields a single species, of Mr = 16,000, that is specifically labeled by dexamethasone 21-mesylate. This 16-kDa fragment retains high affinity binding for [3H]dexamethasone that is only approximately 23-fold lower than that seen with the intact 98-kDa receptor. Analysis of the protease digestion patterns obtained both with trypsin and with lysylendopeptidase C allowed us to deduce the proteolytic cleavage maps of the receptor with these enzymes. From these protease maps, the sequence of the 16-kDa fragment was identified as being threonine 537 to arginine 673. These results show that glucocorticoid receptor fragments smaller than 34 kDa do bind steroids and that the amino acids Thr537-Arg673 constitute a core sequence for ligand binding within the larger steroid binding domain. The much slower kinetics in generating the 16-kDa fragment from affinity-labeled receptors suggests that steroid binding causes a conformation change in the receptor near the cleavage sites.     

Purification and characterization of a large, tryptic fragment of human thyroid peroxidase with high catalytic activity

Thyroid peroxidase (TPO) was purified from human thyroid tissue, obtained at surgery from patients with Graves' disease, by a procedure similar to one that we had previously used for the purification of porcine TPO. The membrane-bound enzyme was solubilized by treatment of the thyroid particulate fraction with trypsin plus detergent. After precipitation with ammonium sulfate, the enzyme was purified by a series of column treatments, including ion-exchange chromatography on DEAE-cellulose, gel filtration through Bio-Gel P-100, and hydroxylapatite chromatography. Although a high degree of purification was achieved, the finally isolated product was considerably more heterogeneous than the TPO obtained from porcine thyroids. Several pools of active enzyme differing in values for A412/A280 and in specific activity were collected. Gel electrophoresis was performed under native, denaturing [sodium dodecyl sulfate (SDS)] and denaturing plus reducing conditions. Native gel electrophoresis indicated that the active enzyme (93 kDa) was heavily contaminated with an inactive 60-kDa fragment, which we were unable to remove by HPLC. The inactive fragment was highly antigenic when tested on immunoblots with an antibody to TPO. The presence of the inactive fragment greatly reduced values for A412/A280 in the finally purified human TPO. Two of the pools, with A412/A280 values of 0.159 and 0.273, were used for further testing. Catalytic activity was very similar in these two pools when measured on the basis of heme content by several different assays. Moreover, the specific activities of both, based on heme content, were very similar to those observed with a porcine TPO preparation with A412/A280 = 0.48. These findings indicate that the inactive 60-kDa fragment most likely did not contain heme. On SDS-polyacrylamide gel electrophoresis under reducing conditions, the 60-kDa fragment completely disappeared and was replaced by a 36- and a 24-kDa component. Amino terminal sequence information obtained on these components indicated that the 24-kDa component represents the amino terminal portion of the active 93-kDa fragment, whereas the 36-kDa fragment represents the carboxyl terminal portion. A model is proposed suggesting that the 60-kDa fragment was generated by trypsin cleavage of native TPO at two internal sites within a disulfide loop (res approximately 300 and res 564) and at one further internal site (res 280). In addition, trypsin cleavage is proposed at sites near the amino and carboxyl ends common to both the active 93-kDa and the inactive 60-kDa fragments.(ABSTRACT TRUNCATED AT 400 WORDS)     

Organization of the functional domains of anthranilate synthase from Neurospora crassa. Limited proteolysis studies

Treatment of the multifunctional alpha 2 beta 2 anthranilate synthase complex of Neurospora crassa with elastase produced two fragments of the complex, one possessing anthranilate synthase activity and the other having both indole-3-glycerol phosphate (InGP) synthase and N-(5'-phosphoribosyl)anthranilate (PRA) isomerase activities. Sequencing the NH2 terminus of the InGP synthase-PRA isomerase fragment revealed that cleavage was between positions 237 and 238 of the beta-subunit within a segment of the polypeptide chain which links the glutamine-binding (G) domain with the InGP synthase-PRA isomerase domains. The fragment containing anthranilate synthase activity has a molecular weight of 98,000, as estimated by gel filtration, and is composed of an apparently intact alpha-subunit (70 kDa) associated with the G-domain fragment (29 kDa) derived from the beta-subunit. The alpha X G-domain complex was resistant to further degradation by elastase. When either the alpha 2 beta 2 complex or the alpha X G-domain complex was incubated with trypsin, the alpha-subunit was degraded to a 66-kDa alpha-fragment with reduced enzymatic activity, which was resistant to further cleavage. In contrast, incubation of alpha-subunit alone with either elastase or trypsin resulted in its complete degradation, indicating that association of the alpha-subunit with either G-domain or beta-subunit protected the alpha-subunit from this extensive degradation. A model for the anthranilate synthase complex is proposed in which the trifunctional beta-subunit forms a dimer by the self-association of the InGP synthase-PRA isomerase domains; the G-domain is connected to the InGP synthase-PRA isomerase domain by a relatively disordered region of the peptide chain which, in the alpha 2 beta 2 complex, remains susceptible to proteases; and neither alpha-subunit nor G-domain significantly self-associates.     

Limited proteolysis of the nitrate reductase from spinach leaves

The functional structure of assimilatory NADH-nitrate reductase from spinach leaves was studied by limited proteolysis experiments. After incubation of purified nitrate reductase with trypsin, two stable products of 59 and 45 kDa were observed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The fragment of 45 kDa was purified by Blue Sepharose chromatography. NADH-ferricyanide reductase and NADH-cytochrome c reductase activities were associated with this 45-kDa fragment which contains FAD, heme, and NADH binding fragment. After incubation of purified nitrate reductase with Staphylococcus aureus V8 protease, two major peaks were observed by high performance liquid chromatography size exclusion gel filtration. FMNH2-nitrate reductase and reduced methyl viologen-nitrate reductase activities were associated with the first peak of 170 kDa which consists of two noncovalently associated (75-90-kDa) fragments. NADH-ferricyanide reductase activity, however, was associated with the second peak which consisted of FAD and NADH binding sites. Incubation of the 45-kDa fragment with S. aureus V8 protease produced two major fragments of 28 and 14 kDa which contained FAD and heme, respectively. These results indicate that the molybdenum, heme, and FAD components of spinach nitrate reductase are contained in distinct domains which are covalently linked by exposed hinge regions. The molybdenum domain appears to be important in the maintenance of subunit interactions in the enzyme complex.     

Proteolysis and orientation on reconstitution of the coated vesicle proton pump

We recently proposed a structural model for the ATP-dependent proton pump from clathrin-coated vesicles (Arai, H., Terres, G., Pink, S., and Forgac, M. (1988) J. Biol. Chem. 263, 8796-8802). To test this model further, we have carried out additional structural analysis of the (H+)-ATPase in both the detergent-solubilized and reconstituted states in this and the following paper (Adachi, I., Puopolo, K., Marquez-Sterling, N., Arai, H., and Forgac, M. (1990) J. Biol. Chem. 265, 967-973). The orientation of the reconstituted proton pump was determined by analyzing the effect of detergent on ATP hydrolysis and by quantitating the extent of labeling of luminally oriented subunits using a membrane-impermeant reagent. Greater than 90% of the reconstituted (H+)-ATPase is oriented with the cytoplasmic surface facing outward. Treatment of the reconstituted (H+)-ATPase with trypsin results in rapid cleavage of the 100-, 73-, 58-, 38-, and 34-kDa subunits and slower cleavage of the 40- and 33-kDa subunits, consistent with our previous results indicating that all of these polypeptides have some portion of their mass exposed to the cytoplasmic surface. The 19- and 17-kDa subunits, by contrast, appear resistant to cleavage by trypsin in both the detergent-solubilized and reconstituted states, consistent with their being buried extensively in the hydrophobic phase of the bilayer. Treatment of the enzyme with trypsin under conditions in which the 100-, 73-, 58-, 38-, and 34-kDa subunits have been cleaved results in a species which is virtually inactive with respect to proton transport but retains 50% of the original ATPase activity, suggesting that proteolysis has resulted in uncoupling of these two activities. Cleavage of both the 73- and 58-kDa subunits by trypsin at a site 1-2 kDa from the amino terminus is inhibited in the presence of 2',3'-O-(2,4,6-trinitrophenyl)-ATP, consistent with the suggestion that both the 73- and 58-kDa subunits may be nucleotide binding proteins.     

Characterization of structural domains of the human epidermal growth factor receptor obtained by partial proteolysis

Partial cleavage with trypsin has been used to study the structure of the epidermal growth factor (EGF) receptor purified from human carcinoma cells. Following affinity labeling of the receptor with 125I-EGF or the ATP analogue 5'-p-fluorosulfonyl benzoyl[14C]adenosine, metabolic labeling with [35S]methionine, [3H]glucosamine, or [32P]orthophosphate, or in vitro autophosphorylation with [gamma-32P]ATP, tryptic cleavage defines the following three regions of the 180-kDa receptor protein: 1) a 125-kDa trypsin-resistant domain which contains sites of glycosylation, EGF binding, and an EGF-specific threonine phosphorylation site; 2) an adjacent 40-kDa fragment which contains serine and threonine phosphorylation sites and is further cleaved to a 30-kDa trypsin-resistant domain; and 3) a terminal 15-kDa portion of the receptor that contains the sites of tyrosine phosphorylation and is degraded to small fragments in the presence of trypsin. Both the 125- and 40-kDa regions of the EGF receptor appear to be required for receptor-associated protein kinase activity since separation of these regions by tryptic cleavage abolishes this activity, and both regions are specifically labeled with an ATP affinity analogue, suggesting that both are involved in ATP binding. Additional 63- and 48-kDa phosphorylated fragments are generated upon trypsin treatment of EGF receptor from EGF-treated cells. The potential usefulness of partial tryptic cleavage in studying the EGF receptor and the possible biological function of the 30-kDa trypsin-resistant fragment of the receptor are discussed.     

Structural and functional analysis of the complement component factor H with the use of different enzymes and monoclonal antibodies to factor H.

The action of six different enzymes on the function and structure of Factor H was investigated by use of sodium dodecyl sulphate/polyacrylamide-gel electrophoresis, haemagglutination, two enzyme-linked immunosorbent assay systems and an assay for Factor I cofactor activity. Six monoclonal antibodies directed against the 38 kDa tryptic fragment of Factor H [which contains the binding site for C3b (a 180 kDa fragment of the third component of complement) and the cofactor activity] were also used to detect cleavage products derived from the same fragment. Elastase, chymotrypsin A4 or trypsin first cleaved Factor H to 36-38 kDa fragments carrying all six monoclonal anti-(Factor H)-binding sites. In parallel, the interaction of Factor H with surface-bound C3b was lost, whereas the cofactor function was preserved. Further cleavage of the 36-38 kDa fragments into two 13-19 kDa fragments (one carrying the MAH4 and MRC OX 24 epitopes, the other the MAH1, MAH2, MAH3 and MRC OX 23 epitopes) destroyed cofactor activity. Pepsin, bromelain or papain rapidly split off a 13-15 kDa fragment of Factor H carrying the MAH1, MAH2, MAH3 and MRC OX 23 epitopes and destroyed all tested functions of Factor H. Ficin cleaved Factor H into disulphide-linked fragments smaller than 25 kDa, but did not affect the functions of the Factor H molecule. The 38 kDa tryptic fragment of Factor H is the N-terminal end of the Factor H molecule, as determined by N-terminal sequence analysis. A model is presented of the substructure of Factor H.     

Functional, chymotryptically split actin and its interaction with myosin subfragment 1

We have prepared chymotryptically split actin that retains the characteristic properties of intact actin. Chymotryptic digestion of G-actin produces an intermediate 35-kilodalton (kDa) fragment and from this a final product of 33 kDa known as the C-terminal "core". These fragments remain attached to an N-terminal 10-kDa fragment. The 35-kDa-10-kDa complex is able to polymerize upon addition of KCl and MgCl2, like intact actin, whereas the 33-kDa-10-kDa complex is not. The 35-kDa-10-kDa complex is here termed "split actin". In the rigor state, split actin binds to myosin subfragment 1 (S-1) strongly, with the same stoichiometry as intact actin. In the rigor state, split actin forms a carbodiimide-induced cross-linked product with S-1; the cross-linking sites on the split actin and on S-1 were proved to be the N-terminal 10-kDa fragment of split actin and the 20-kDa domain of S-1. There was no cross-linking between the 50-kDa domain of S-1 and the 10 kDa of actin. Therefore, the structure of the split actin-S-1 complex differs somewhat from that of the complex with intact actin. The cross-linking of split actin to S-1 causes superactivation of S-1 ATPase to approximately the same extent as does cross-linking of intact actin, whereas non-cross-linked split actin activates S-1 ATPase to a lesser extent. The N-terminus of the 35-kDa fragment was found to be residue 45 (Val-45) by amino acid sequence analysis; so there is no residue missing in split actin.     

Prostaglandin H synthase. Kinetics of tyrosyl radical formation and of cyclooxygenase catalysis.

Hydroperoxides are known to induce the formation of tyrosyl free radicals in prostaglandin (PG) H synthase. To evaluate the role of these radicals in cyclooxygenase catalysis we have analyzed the temporal correlation between radical formation and substrate conversion during reaction of the synthase with arachidonic acid. PGH synthase reacted with equimolar levels of arachidonic acid generated sequentially the wide doublet (34 G peak-to-trough) and wide singlet (32 G peak-to-trough) tyrosyl radical signals previously reported for reaction with hydroperoxide. The kinetics of formation and decay of the doublet signal corresponded reasonably well with those of cyclooxygenase activity. However, the wide singlet free radical signal accumulated only after prostaglandin formation had ceased, indicating that the wide singlet is not likely to be an intermediate in cyclooxygenase catalysis. When PGH synthase was reacted with 25 equivalents of arachidonic acid, the wide doublet and wide singlet radical signals were not observed. Instead, a narrower singlet (24 G peak-to-trough) tyrosyl radical was generated, similar to that found upon reaction of indomethacin-treated synthase with hydroperoxide. Only about 11 mol of prostaglandin were formed per mol of synthase before complete self-inactivation of the cyclooxygenase, far less than the 170 mol/mol synthase produced under standard assay conditions. Phenol (0.5 mM) increased the extent of cyclooxygenase reaction by only about 50%, in contrast to the 460% stimulation seen under standard assay conditions. These results indicate that the narrow singlet tyrosyl radical observed in the reaction with high levels of arachidonate in this study and by Lassmann et al. (Lassmann, G., Odenwaller, R., Curtis, J.F., DeGray, J.A., Mason, R.P., Marnett, L.J., and Eling, T.E. (1991) J. Biol. Chem. 266, 20045-20055) is associated with abnormal cyclooxygenase activity and is probably nonphysiological. In titrations of the synthase with arachidonate or with hydroperoxide, the loss of enzyme activity and destruction of heme were linear functions of the amount of titrant added. Complete inactivation of cyclooxygenase activity was found at about 10 mol of arachidonate, ethyl hydrogen peroxide, or hydrogen peroxide per mol of synthase heme; maximal bleaching of the heme Soret absorbance peak was found with 10 mol of ethyl hydroperoxide or 20 mol of either arachidonate or hydrogen peroxide per mol of synthase heme. The peak concentration of the wide doublet tyrosyl radical did not change appreciably with increased levels of ethyl hydroperoxide. In contrast, higher levels of hydroperoxide gave higher levels of the wide singlet radical species, in parallel with enzyme inactivation.(ABSTRACT TRUNCATED AT 400 WORDS)     

Alanyl-tRNA synthetase from Escherichia coli, Bombyx mori and Ratus ratus. Existence of common structural features

Alanyl-tRNA synthetase from Escherichia coli, Bombyx mori and rat were examined with respect to the following functional and structural properties: the effect of substrates on sensitivity to proteolysis, secondary structure as determined by circular dichroism, amino acid composition and, in the case of the rat and insect enzymes, partial amino acid sequence determination on a 60-kDa C-terminal tryptic fragment. Digestion of the enzyme from all three sources with trypsin resulted in significant decline in aminoacyl-tRNA synthetase activity with little effect on pyrophosphate-exchange activity. In each case the presence of alanine and ATP together, but not separately, reduced the rate of digestion by trypsin; the largest effect was observed with the enzyme from rat liver. Trypsin digestion generated fragments of 47 kDa and 40 kDa with all three enzymes, but detection of significant quantities of the 47-kDa fragment from the rat enzyme required the presence of ATP and alanine. Trypsin digestion produced a fragment of 60 kDa with all three enzymes, but detection of significant quantities of this fragment with the bacterial enzyme required the presence of ATP and alanine. Limited sequence analysis of the 60-kDa fragment from the insect and rat enzymes indicated that trypsin cleaved both proteins at the same site to generate this species. Similar effects of substrates were observed when the enzymes were digested with chymotrypsin suggesting that the effects of substrates on protease sensitivity were not unique to trypsin. Circular dichroism spectra obtained for the three enzymes were qualitatively and quantitatively similar. There is some similarity in amino acid composition between the rat and insect enzymes.     

Structural organization of the human glucocorticoid receptor determined by one- and two-dimensional gel electrophoresis of proteolytic receptor fragments

The structural organization of the steroid-binding protein of the IM-9 cell glucocorticoid receptor was investigated by using one- and two-dimensional gel electrophoresis of proteolytic receptor fragments. One-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) of receptor fragments isolated after trypsin digestion of immunopurified [3H]dexamethasone 21-mesylate ([3H]DM-) labeled receptor revealed the presence of a stable 26.5-kilodalton (kDa) steroid-containing, non-DNA-binding fragment, derived from a larger, less stable, 29-kDa fragment. The 26.5-kDa tryptic fragment appeared to be completely contained within a 41-kDa, steroid-containing, DNA-binding species isolated after chymotrypsin digestion of the intact protein. Two-dimensional electrophoretic analysis of the [3H]DM-labeled tryptic fragments resolved two (pI congruent to 5.7 and 7.0) 26.5-kDa and two (pI congruent equal to 5.7 and 6.8) 29-kDa components. This was the same number of isoforms seen in the intact protein, indicating that the charge heterogeneity of the steroid-binding protein is the result of modification within the steroid-containing, non-DNA-binding, 26.5-kDa tryptic fragment. Two-dimensional analysis of the 41-kDa [3H]DM-labeled chymotryptic species revealed a pattern of isoforms more complex than that seen either in the intact protein or in the steroid-containing tryptic fragments. These results suggest that the 41-kDa [3H]DM-labeled species resolved by one-dimensional SDS-PAGE after chymotrypsin digestion may be composed of several distinct proteolytic fragments.