C3b2-IgG complexes retain dimeric C3 fragments at all levels of inactivation

C3b2-IgG complexes are formed during complement activation in serum by attachment of two C3b molecules (the proteolytically activated form of C3) to one IgG heavy chain (IgG HC) via ester bonds. Because of the presence of two C3b molecules, these complexes are very efficient activators of the alternative complement pathway. Likewise, dimeric C3b is known to enhance complement receptor 1-dependent phagocytosis, and dimeric C3d (the smallest thioester-containing fragment of C3) linked to a protein antigen facilitates CR2-dependent B-cell proliferation. Because the efficiency of all these interactions depends on the number of C3 fragments, we investigated whether C3b2-IgG complexes retained dimeric structure upon physiological inactivation. We used two-dimensional SDS-PAGE and Western blot to study the arrangement of the C3b molecules by analyzing the fragmentation pattern after cleavage of the ester bonds. Upon inactivation with factors H and I, a 185-kDa band was generated under reducing conditions. It released IgG HC and the 65-kDa fragment of C3b alpha' chain after hydrolysis of the ester bonds with hydroxylamine. The two C3b molecules were not 65-kDa-to-40-kDa linked, because neither ester-bonded 65 kDa HC nor 65 kDa-40 kDa fragments were observed, nor was a 40-kDa peptide released after hydroxylamine cleavage. Factor I and CR1 cleaved the C3b2-IgG molecule to its final physiological product, C3dg2-IgG, which migrated as a 133-kDa fragment in reduced form. This fragment released exclusively C3dg (the final physiological product of C3b inactivation by factor I) and IgG HC. C3dg2-HC appeared as a double band on SDS-PAGE only at low gel porosity, suggesting the presence of two conformers of the same composition. Our results suggest that, upon physiological inactivation, C3b2-IgG complexes retain dimeric inactivated C3b and C3dg, which allows bivalent binding to the corresponding complement receptors.     

Phylogeny of regulatory proteins of the complement system. Isolation and characterization of a C4b/C3b inhibitor and a cofactor from sand bass plasma

We have previously demonstrated that the alpha'-chain of human activated form of the fourth (C4b) and third (C3b) component of C are cleaved by plasma or serum from vertebrate species spanning through 300,000,000 yr of evolution yielding fragments identical with those obtained with human plasma. In this study, we investigated the molecular basis of this reaction. We chose barred sand bass plasma because this is the most primitive species analyzed possessing these activities. Barred sand bass plasma proteins were separated on a Sephadex G-200 column and the eluted samples analyzed for C4b and C3b cleavage. Individual fractions were inactive, but degradation was obtained when proteins of 380 and 155 kDa were combined. In contrast to the human regulatory proteins, the sand bass proteins require Ca2+ ions. K76COOH, an inhibitor of human factor I, inhibited the function of the 155-kDa but not of the 380 kDa-fraction. Thus it appears that the 155-kDa fraction functions as the C4b/C3b cleaving enzyme (I) and the 380-kDa material as its cofactor. Further purification of the 380-kDa fraction yielded a protein that by SDS-PAGE consisted of two noncovalently linked subunits of 110 and 42 kDa at a molecular ratio of 2:1. These two chains were antigenically distinct, and constitute domains of the same protein. The 110-kDa peptide binds C4b and not C3b but it fully expresses the cofactor function for the 155-kDa fraction on the cleavage of both C4b and C3b. Limited tryptic digestion of the 110-kDa domain demonstrated C4b binding activity in fragments of 34, 25, and 23 kDa. The activity of the 34-kDa fragment was the same as that of the undigested protein. Comparison of the amino acid composition of the barred sand bass cofactor and of human C4bp shows similar high content of cysteine and proline but not of tryptophan. It differs from human factor H in cysteine, serine, proline, and tryptophan. These studies indicate that regulatory proteins for the C4b and C3b C fragments may have appeared very early phylogenetically.     

Activation of a calmodulin-dependent phosphatase by a Ca2+-dependent protease

A calmodulin-dependent protein phosphatase (calcineurin) was converted to an active, calmodulin-independent form by a Ca2+-dependent protease (calpain I). Proteolysis could be blocked by ethylene glycol bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid, leupeptin, or N-ethylmaleimide, but other protease inhibitors such as phenylmethanesulfonyl fluoride, aprotinin, benzamidine, diisopropyl fluorophosphate, and trypsin inhibitor were ineffective. Phosphatase proteolyzed in the absence of calmodulin was insensitive to Ca2+ or Ca2+/calmodulin; the activity of the proteolyzed enzyme was greater than the Ca2+/calmodulin-stimulated activity of the unproteolyzed enzyme. Proteolysis of the phosphatase in the presence of calmodulin proceeded at a more rapid rate than in its absence, and the proteolyzed enzyme retained a small degree of sensitivity to Ca2+/calmodulin, being further stimulated some 15-20%. Proteolytic stimulation of phosphatase activity was accompanied by degradation of the 60-kilodalton (kDa) subunit; the 19-kDa subunit was not degraded. In the absence of calmodulin, the 60-kDa subunit was sequentially degraded to 58- and 45-kDa fragments; the 45-kDa fragment was incapable of binding 125I-calmodulin. In the presence of calmodulin, the 60-kDa subunit was proteolyzed to fragments of 58, 55 (2), and 48 kDa, all of which retained some ability to bind calmodulin. These data, coupled with our previous report that the human platelet calmodulin-binding proteins undergo Ca2+-dependent proteolysis upon platelet activation [Wallace, R. W., Tallant, E. A., & McManus, M. C. (1987) Biochemistry 26, 2766-2773], suggest that the Ca2+-dependent protease may have a role in the platelet as an irreversible activator of certain Ca2+/calmodulin-dependent reactions.     

Factors affecting the cold inactivation of an acetyl-coenzyme-A hydrolase purified from the supernatant fraction of rat liver

An extramitochondrial acetyl-coenzyme-A hydrolase from rat liver is shown to be a cold-labile oligomeric enzyme that undergoes a reversible conformational transition between a dimeric and a tetrameric form in the presence of adenosine 5'-triphosphate or adenosine 5'-diphosphate at 25-37 degrees C, and between a dimeric and a monomeric form at low temperature. The enzymatically active dimer is fairly stable at 25-37 degrees C, but much less stable at low temperature, dissociating into monomer with no activity. At 37 degrees C and low concentrations of enzyme protein (less than or equal to 14 micrograms/ml), the activity decreased rapidly and only 10% of the initial activity remaining after 60 min. Addition of bovine serum albumin or immunoglobulin G to the medium completely prevented inactivation of the dimeric enzyme at low concentration at 37 degrees C, but had little effect on cold inactivation of the enzyme. Cold inactivation of the dimeric enzyme was partially prevented by the presence of various CoA derivatives. The order of potency was acetyl-CoA (substrate) greater than or equal to butyryl-CoA greater than octanoyl-CoA greater than CoA (product) greater than acetoacetyl-CoA. Another enzyme product, acetate, had little effect on cold inactivation. Polyols, such as sucrose, glycerol, and ethylene glycol, and high concentrations of NaCl, KCl, pyrophosphate and phosphate also greatly prevented cold inactivation. Cold inactivation was scarcely affected by pH within the pH range at which the enzyme was stable at 37 degrees C.     

Overexpression of plant histidinol dehydrogenase using a baculovirus expression vector system.

A cDNA encoding cabbage histidinol dehydrogenase, including the chloroplast transit peptide sequence, was overexpressed using a baculovirus expression vector system. The maximum level of the expression of histidinol dehydrogenase was reached 5 days after infection of the insect cells. Two forms of recombinant histidinol dehydrogenase with molecular masses of 53 and 52 kDa, respectively, were obtained by a one-step purification from the cell homogenate. Compared with the 52-kDa form, the 53-kDa form contained 10 additional amino acids at the N-terminus derived from the transit peptide. By incubating the cell homogenate for 2 h at 30 degrees C, the 53-kDa form could be completely converted to the 52-kDa form. This conversion was blocked by leupeptin. Eighty percent of the converted 52-kDa form had Cys at position 31 at the N-terminal amino acid and the rest had Met 33. Kinetic properties of the recombinant enzyme were virtually identical to those of histidinol dehydrogenase isolated from cabbage plants. The overexpression of recombinant cabbage histidinol dehydrogenase in insect cells, the proteolytic processing of the preprotein next to the N-terminus (compared to the mature cabbage enzyme), and its easy purification allow the preparation of large amounts of the active enzyme for structural and functional studies.     

A homologue of cathepsin L identified in conditioned medium from Sf9 insect cells

Gelatin zymography revealed the presence of proteolytic activity in conditioned medium (CM) from a serum-free, non-infected Spodoptera frugiperda, Sf9 insect cell culture. Two peptidase bands at about 49 and 39 kDa were detected and found to be proform and active form of the same enzyme. The 49-kDa form was visible on zymogram gels in samples of CM taken on days 4 and 5 of an Sf9 culture, while the 39-kDa form was seen on days 6 and 7. On basis of the inhibitor profile and substrate range, the enzyme was identified as an Sf9 homologue of cathepsin L, a papain-like cysteine peptidase. After lowering the pH of Sf9 CM to 3.5, an additional peptidase band at 22 kDa appeared. This peptidase showed the same inhibitor profile, substrate range and optimum pH (5.0) as the 39-kDa form, indicating that Sf9 cathepsin L has two active forms, at 39 and 22 kDa. Addition of the cysteine peptidase inhibitor E-64c to an Sf9 culture inhibited all proteolytic activities of Sf9 cathepsin L but did not influence the proliferation of Sf9 cells.     

Purification and characterization of aromatic amine dehydrogenase from Alcaligenes xylosoxidans

Aromatic amine dehydrogenase was purified and characterized from Alcaligenes xylosoxidans IFO13495 grown on beta-phenylethylamine. The molecular mass of the enzyme was 95.5 kDa. The enzyme consisted of heterotetrameric subunits (alpha2beta2) with two different molecular masses of 42.3 kDa and 15.2 kDa. The N-terminal amino acid sequences of the alpha-subunit (42.3-kDa subunit) and the beta-subunit (15.2-kDa subunit) were DLPIEELXGGTRLPP and APAAGNKXPQMDDTA respectively. The enzyme had a quinone cofactor in the beta-subunit and showed a typical absorption spectrum of tryptophan tryptophylquinone-containing quinoprotein showing maxima at 435 nm in the oxidized form and 330 nm in the reduced form. The pH optima of the enzyme activity for histamine, tyramine, and beta-phenylethylamine were the same at 8.0. The enzyme retained full activity after incubation at 70 degrees C for 40 min. It readily oxidized various aromatic amines as well as some aliphatic amines. The Michaelis constants for phenazine methosulfate, beta-phenylethylamine, tyramine, and histamine were 48.1, 1.8, 6.9, and 171 microM respectively. The enzyme activity was strongly inhibited by carbonyl reagents. The enzyme could be stored without appreciable loss of enzyme activity at 4 degrees C for one month at least in phosphate buffer (pH 7.0).     

Analysis of the effects of snake venom proteinases on the activity of human plasma C1 esterase inhibitor, alpha 1-antichymotrypsin and alpha 2-antiplasmin

Incubation of C1 esterase inhibitor with Crotalid, Viperid and Colubrid snake venoms resulted in enzymatic inactivation of the inhibitor. Intact inhibitor (104 kDa) was converted into an active intermediate species of 89 kDa and then a further cleavage resulted in formation of an 86-kDa inactive inhibitor. In contrast, C1 esterase inhibitor did not lose activity during incubation with Elapid venoms; however, the intact inhibitor was gradually converted to an active species of 89 kDa during the incubation. Human alpha 1-antichymotrypsin was inactivated by all venoms tested, including those from the Elapid family. The 67-kDa intact inhibitor was converted by the venom proteinases to an inactive 63-kDa form. The results suggest that this acute-phase plasma protein is readily susceptible to inactivation by venom proteinases. Human alpha 2-antiplasmin (68 kDa) was cleaved to form a 61-kDa active intermediate, which then underwent a second cleavage to produce an inactive 53-kDa product. Elapid venoms had no effect on alpha 2-antiplasmin activity and did not cleave this inhibitor. All inhibitors were inactivated with catalytic amounts of venom proteinases. No stable proteinase-proteinase inhibitor complexes were detected, and no random proteolysis of the inhibitors occurred.     

A cold-labile acetyl-coenzyme-A hydrolase from the supernatant fraction of rat liver. Reactivation and reconstitution of the active species from the inactive monomer

An acetyl-coenzyme-A hydrolase from the supernatant fraction of rat liver is known to be rapidly inactivated at low temperature. Loss of catalytic activity is accompanied by apparent dissociation of tetrameric and dimeric forms of the enzyme into monomers. It was found that rewarming under appropriate conditions almost completely reversed the cold-induced inactivation and dissociation of the enzyme: At a protein concentration of 14 micrograms/ml, simple rewarming only partially restored the enzyme activity (less than 3% of the original activity), but at a higher concentration of the enzyme or in the presence of 1 mg/ml bovine serum albumin, the reactivation by warming was greater. Warming at 37 degrees C appeared to be optimal for reactivation; warming at 25 degrees C or at 43 degrees C was less effective. Longer exposure to cold did not affect reactivation on rewarming, but on repeated inactivation and reactivation the reactivation decreased to some extent, especially at lower concentrations of enzyme protein. Among various nucleotides tested, ATP greatly enhanced the restoration of the activity, while ITP, UTP and ADP were less effective and AMP, GTP, TTP and CTP had little effect. At an enzyme-protein concentration of 14 micrograms/ml, 2 mM ATP restored the enzyme activity to about 70% of that before cold treatment, while acetyl-CoA (0.5 mM) restored the activity about 50%. High concentrations of phosphate (0.92 M) and pyrophosphate (0.45 M) restored about 80% and 95%, respectively, of the original activity. Sucrose density gradient centrifugation of the active dimer at high enzyme concentration at 4 degrees C for 20 h produced a monomeric form without catalytic activity. Gel filtration showed that simple rewarming mostly converted the monomeric enzyme obtained in this way to the dimeric form, whereas on rewarming with ATP the monomer was mostly converted to a tetrameric form. The dimeric and tetrameric forms both had catalytic activity.     

Structure of the cel-3 gene from Fibrobacter succinogenes S85 and characteristics of the encoded gene product, endoglucanase 3.

The cel-3 gene cloned from Fibrobacter succinogenes into Escherichia coli coded for the enzyme EG3, which exhibited both endoglucanase and cellobiosidase activities. The gene had an open reading frame of 1,974 base pairs, coding for a protein of 73.4 kilodaltons (kDa). However, the enzyme purified from the osmotic shock fluid of E. coli was 43 kDa. The amino terminus of the 43-kDa protein matched amino acid residue 266 of the protein coded for by the open reading frame, indicating proteolysis in E. coli. In addition to the 43-kDa protein, Western immunoblotting revealed a 94-kDa membranous form of the enzyme in E. coli and a single protein of 118 kDa in F. succinogenes. Thus, the purified protein appears to be a proteolytic degradation product of a native protein which was 94 kDa in E. coli and 118 kDa in F. succinogenes. The discrepancy between the molecular weight expected on the basis of the DNA sequence and the in vivo form may be due to anomalous migration during electrophoresis, to glycosylation of the native enzyme, or to fatty acyl substitution at the N terminus. One of two putative signal peptide cleavage sites bore a strong resemblance to known lipoprotein leader sequences. The purified 43-kDa peptide exhibited a high Km (53 mg/ml) for carboxymethyl cellulose but a low Km (3 to 4 mg/ml) for lichenan and barley beta-glucan. The enzyme hydrolyzed amorphous cellulose, and cellobiose and cellotriose were the major products of hydrolysis. Cellotriose, but not cellobiose, was cleaved by the enzyme. EG3 exhibited significant amino acid sequence homology with endoglucanase CelC from Clostridium thermocellum, and as with both CelA and CelC of C. thermocellum, it had a putative active site which could be aligned with the active site of hen egg white lysozyme at the highly conserved amino acid residues Asn-44 and Asp-52.     

Purification and characterization of the sea urchin embryo hatching enzyme

The sea urchin hatching enzyme provides an interesting model for the control of gene expression during early development. In order to study its properties and developmental regulation, the hatching enzyme of the species Paracentrotus lividus has been purified. The fertilization envelopes of the embryos were digested before hatching by a crude culture supernatant previously made. The enzyme was then solubilized by 1 M NaCl and 0.5% 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate and purified by hydrophobic chromatography on Procion-agarose. A 470-fold increase in specific activity was obtained. The kinetic parameters of the proteolytic activity using dimethylcasein as substrate are: Km = 120 micrograms x ml-1, Vm = 200 mumol x min-1 x mg-1, and kcat = 180 s-1 at 500 mM NaCl, 10 mM CaCl2, pH 8.0, at 35 degrees C. The purified enzyme is highly active on fertilization envelopes: at 20 degrees C and 500 mM NaCl, 10 mM CaCl2, pH 8.0, 100 ng of enzyme completely denudes embryos in about 20 min under standard conditions. The molecular mass of the enzyme was estimated as 57 kDa by gel filtration, 51 kDa by gel electrophoresis, and 52 kDa by amino acid analysis. The hatching enzyme was shown to be a glycoprotein which autolyzes to a 30-kDa inactive form. Antibodies raised against the 51- or 30-kDa forms reacted with both these forms. Immunoblotting experiments showed that the hatching supernatants contain important amounts of the autolyzed species.     

Cloning and over-expression in Escherichia coli of the gene encoding NADPH group III alcohol dehydrogenase from Thermococcus hydrothermalis. Characterization and comparison of the native and the recombinant enzymes.

A NADP-dependent group III alcohol dehydrogenase (ADH) was purified from the hyperthermophilic strictly anaerobic archaeon Thermococcus hydrothermalis, which grows at an optimum temperature of 85 degrees C and an optimum pH of 6. The gene encoding this enzyme was cloned, sequenced, and over-expressed in Escherichia coli. The recombinant enzyme was purified, characterized and compared with the native form of the enzyme. The enzyme structure is pH-dependent, being a 197-kDa tetramer (subunit of 45 kDa) at pH 10.5, the pH optimum for alcohol oxidation, and a 80.5-kDa dimer at pH 7.5, the pH optimum for aldehyde reduction. The kinetic parameters of the enzyme show that the affinity of the enzyme is greater for the aldehyde substrate and NADPH cofactor, suggesting that the dimeric form of the enzyme is probably the active form in vivo. The ADH of T. hydrothermalis oxidizes a series of primary aliphatic and aromatic alcohols preferentially from C2 to C8 but is also active towards methanol and glycerol and stereospecific for monoterpenes. T. hydrothermalis ADH is the first Thermococcale ADH to be cloned and overproduced in a mesophilic heterologous expression system, and the recombinant and the native forms have identical main characteristics.     

Isolation of the von Willebrand factor domain interacting with platelet glycoprotein Ib, heparin, and collagen and characterization of its three distinct functional sites

We have used purified proteolytic fragments of von Willebrand factor (vWF) to characterize three related functional sites of the molecule that support interaction with platelet glycoprotein Ib, collagen, and heparin. A fragment of 116 kDa was found to be dimeric and consisted of disulfide-linked subunits which, after reduction and alkylation, corresponded to the previously described 52/48-kDa fragment extending from residue 449 to 728. Fragment III-T2, also a dimer, was composed of two pairs of disulfide-linked subunits, two 35-kDa heavy chains (residues 273-511) and two 10-kDa light chains (residues 674-728). The 116-kDa fragment, but not the constituent 52/48-kDa subunit, supported ristocetin-induced platelet aggregation and retained 20% (on a molar basis) of the ristocetin cofactor activity of native vWF; fragment III-T2 retained less than 5% activity. All three fragments, however, inhibited vWF interaction with glycoprotein Ib. Both 116-kDa and 52/48-kDa fragments inhibited vWF binding to heparin with similar potency, while fragment III-T2 had no effect in this regard. Only the 116-kDa fragment inhibited vWF binding to collagen. These results indicate that dimeric fragments containing two glycoprotein Ib-binding sites possess the minimal valency sufficient to support ristocetin-induced aggregation. The sequence comprising residues 512-673, missing in fragment III-T2, is necessary for binding to heparin and collagen and may be crucial for anchoring vWF to the subendothelium. Immunochemical and functional data suggest that the same sequence, although not essential for interaction with glycoprotein Ib, may influence the activity of the glycoprotein Ib-binding site. Only binding to collagen has absolute requirement for intact disulfide bonds. Thus, the three functional sites contained in the 116-kDa domain of vWF are structurally distinct.     

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.     

Conformational lock and dissociative thermal inactivation of lentil seedling amine oxidase

The kinetics of thermal inactivation of copper-containing amine oxidase from lentil seedlings were studied in a 100 mM potassium phosphate buffer, pH 7, using putrescine as the substrate. The temperature range was between 47-60 degrees C. The thermal inactivation curves were not linear at 52 and 57 degrees C; three linear phases were shown. The first phase gave some information about the number of dimeric forms of the enzyme that were induced by the higher temperatures using the "conformational lock" pertaining theory to oligomeric enzyme. The "conformational lock" caused two additional dimeric forms of the enzyme when the temperature increased to 57 degrees C. The second and third phases were interpreted according to a dissociative thermal inactivation model. These phases showed that lentil amine oxidase was reversibly-dissociated before the irreversible thermal inactivation. Although lentil amine oxidase is not a thermostable enzyme, its dimeric structure can form "conformational lock," conferring a structural tolerance to the enzyme against heat stress.     

Conformational transitions in the myosin head induced by temperature, nucleotide and actin. Studies on subfragment-1 of myosins from rabbit and frog fast skeletal muscle with a limited proteolysis method

Tryptic digestion patterns reveal a close similarity of the substructure of frog subfragment-1 (S1) to that established for rabbit S1. The 97-kDa heavy chain of chymotryptic S1 of frog myosin is preferentially cleaved into three fragments with apparent molecular masses of 29 kDa, 49 kDa and 20 kDa. These fragments correspond to the 27-kDa, 50-kDa and 20-kDa fragments of rabbit S1, respectively; this is indicated by the sequence of their appearance during digestion, by the suppression by actin of the generation of the 49-kDa and 20-kDa peptides, and by a nucleotide-promoted cleavage of the 29-kDa peptide to a 24-kDa fragment and the 49-kDa peptide to a 44-kDa fragment, analogous to the nucleotide-promoted cleavage of the 27-kDa and 50-kDa fragments of rabbit S1 to the 22-kDa and 45-kDa peptides. The same changes in the digestion patterns as those produced by the presence of nucleotide (ATP or its beta,gamma-imido analog AdoP P[NH]P) at 25 degrees C were observed when the digestion was carried out at 0 degrees C in the absence of nucleotide. The low-temperature-induced changes were particularly well seen in the preparations from frog myosin. The presence of ATP or AdoP P[NH]P at 0 degrees C enhanced, whereas the complex formation with actin prevented, the low-temperature-induced changes. The results are consistent with there being two fundamental conformational states of the myosin head in an equilibrium that is dependent on the temperature, the nucleotide bound at the active site, and the presence or absence of actin.     

Regulation of the autoactivation of human 72-kDa progelatinase by tissue inhibitor of metalloproteinases-2

To study the activation of human 72-kDa gelatinase, and its relation to tissue inhibitor of metalloproteinases 2 (TIMP-2), we purified human 72-kDa progelatinase both as a complex with TIMP-2 and as a free proteinase. Activation of progelatinase-TIMP-2 complexes with 4-aminophenylmercuric acetate yielded gelatinolytically active enzyme migrating at 62 kDa. TIMP-2 remained bound to the active enzyme. Removal of TIMP-2 from progelatinase by reverse-phase high performance liquid chromatography in the presence of trifluoroacetic acid, followed by complete dialysis in neutral pH buffer, resulted in multiple fragments. These fragments were formed as a result of the cleavage of 72-kDa progelatinase at several locations. Cleavage at the amino terminus was restricted to the removal of the propeptide, except in the case of degradation leading to inactive fragments. Two active species autocatalytically evolved upon removal of TIMP-2 from progelatinase. The 62 kDa-activated gelatinase lacked the amino-terminal propeptide, which is known to be removed upon treatment with 4-aminophenylmercuric acetate. In addition, an active 42.5-kDa fragment lacking both the propeptide and a portion of the carboxyl terminus was formed. This low-molecular-weight active form of 72-kDa progelatinase retained its ability to bind and degrade gelatin. Self-activation and degradation of 72-kDa progelatinase can be prevented by agents that inhibit metalloproteinases, including 1,10-phenanthroline. Evidence presented here suggests that TIMP-2 binds to a stabilization site that is independent of the active site. This stabilization site does not bind TIMP-1 (TIMP). Occupation of this site by TIMP-2 prevents autocatalytic activation and degradation but does not prevent gelatinolysis by the enzyme-inhibitor complex.     

Thermal stability of molecular forms of acetylcholinesterase from muscle microsomes

To establish if the predominant form of acetylcholinesterase in muscle microsomes (4.8S) corresponded to the monomeric or dimeric form of the enzyme we studied the sensitivity to heating of Triton X-100 solubilized extract and that of 4.8S, 10-11S and 13.5S species of the enzyme. Inactivation of soluble acetylcholinesterase began at 45-47 degrees C and was almost complete at 60 degrees C. Sedimentation analysis revealed that the partial loss of activity was due to inactivation of the 4.8S form, although by heating the 13.5S was converted into the 10S enzyme. Inactivation of the 4.8S form began at 45 degrees C, whereas the larger forms required higher temperature. The 4.8S component follows a time course of inactivation which could be fitted by a double exponential equation (when heated at 52 degrees C, almost 83% of the activity showed a short half-life). The 10-11S species was also inactivated following a two step process while the 13.5S enzyme was fairly stable at 52 degrees C. The results show that the lightest component behaves as a monomeric form of acetylcholinesterase.     

Controlled tryptic digestion of prostaglandin H synthase. Characterization of protein fragments and enhanced rate of proteolysis of oxidatively inactivated enzyme

Treatment of prostaglandin H (PGH) synthase (70 kDa) with trypsin generates fragments of 33 and 38 kDa. Each of the fragments was purified by reverse-phase high performance liquid chromatography (HPLC) using acetonitrile/water/trifluoroacetic acid gradients. Amino acid sequence analysis indicates that the 33-kDa protein contains the NH2 terminus of PGH synthase. Neither the 33- nor 38-kDa fragment isolated by HPLC exhibits any PGH synthase activity; however, cleavage of intact enzyme to 33- and 38-kDa fragments to the extent of 90% only reduces cyclooxygenase activity by 40%. This implies that the cleaved proteins or a complex formed between them retains the conformation necessary for enzyme activity. Extensive attempts to resolve active fragments from each other or from intact enzyme were unsuccessful; intact enzyme and digestion fragments cochromatograph under all conditions employed. Treatment of PGH synthase with [3H]acetylsalicylic acid followed by trypsin digestion introduces [3H]acetyl moieties into the intact protein and the 38-kDa fragment (0.8-0.9 acetyl group/subunit). Nearly complete conversion of PGH synthase to 33- and 38-kDa fragments by exposure to high concentrations of trypsin prior to [3H]acetylsalicylic acid treatment results in labeling of the 38-kDa fragment, but not the 33-kDa fragment. The present findings are consistent with the presence of a membrane-binding domain (33 kDa) and an active site domain (38 kDa) in the 70-kDa subunit of PGH synthase. They also suggest that, following cleavage, the 38-kDa fragment retains the structural features responsible for the cyclooxygenase activity and selective aspirin labeling of PGH synthase. PGH synthase undergoes self-catalyzed inactivation by oxidants generated during its catalytic turnover. When PGH synthase, inactivated by treatment with arachidonic acid or hydrogen peroxide, was treated with trypsin it was cleaved two to three times faster than unoxidized enzyme. Addition of heme to oxidized PGH synthase did not reconstitute cyclooxygenase activity or resistance to trypsin cleavage. Spectrophotometric studies demonstrated that oxidatively inactivated enzyme did not bind heme. This implies that oxidation of protein residues as well as the heme prosthetic group is an important determinant of proteolytic sensitivity. Oxidative modification may mark PGH synthase for proteolytic cleavage and turnover.