Portion Of Heavy Chain Research Articles

Inactivation of myeloperoxidase by benzoic acid hydrazide

Myeloperoxidase (MPO) is expressed by myeloid cells for the purpose of catalyzing the formation of hypochlorous acid, from chloride ions and reaction with a hydrogen peroxide-charged heme covalently bound to the enzyme. Most peroxidase enzymes both plant and mammalian are inhibited by benzoic acid hydrazide (BAH)-containing compounds, but the mechanism underlying MPO inhibition by BAH compounds is largely unknown. Recently, we reported MPO inhibition by BAH and 4-(trifluoromethyl)-BAH was due to hydrolysis of the ester bond between MPO heavy chain glutamate 242 (HCGlu242) residue and the heme pyrrole A ring, freeing the heme linked light chain MPO subunit from the larger remaining heavy chain portion. Here we probed the structure and function relationship behind this ester bond cleavage using a panel of BAH analogs to gain insight into the constraints imposed by the MPO active site and channel leading to the buried protoporphyrin IX ring. In addition, we show evidence that destruction of the heme ring does not occur by tracking the heme prosthetic group and provide evidence that the mechanism of hydrolysis follows a potential attack of the HCGlu242 carbonyl leading to a rearrangement causing the release of the vinyl-sulfonium linkage between HCMet243 and the pyrrole A ring.

Antibodies 2.0

Antibodies 2.0

Structural basis for the function of anti-idiotypic antibody in immune memory

We had earlier proposed a hypothesis to explain the mechanism of perpetuation of immunological memory based on the operation of idiotypic network in the complete absence of antigen. Experimental evidences were provided for memory maintenance through anti-idiotypic antibody (Ab2) carrying the internal image of the antigen. In the present work, we describe a structural basis for such memory perpetuation by molecular modeling and structural analysis studies. A three-dimensional model of Ab2 was generated and the structure of the antigenic site on the hemagglutinin protein H of Rinderpest virus was modeled using the structural template of hemagglutinin protein of Measles virus. Our results show that a large portion of heavy chain containing the CDR regions of Ab2 resembles the domain of the hemagglutinin housing the epitope regions. The similarity demonstrates that an internal image of the H antigen is formed in Ab2, which provides a structural basis for functional mimicry demonstrated earlier. This work brings out the importance of the structural similarity between a domain of hemagglutinin protein to that of its corresponding Ab2. It provides evidence that Ab2 is indeed capable of functioning as surrogate antigen and provides support to earlier proposed relay hypothesis which has provided a mechanism for the maintenance of immunological memory.

Novel Chimeras of Botulinum Neurotoxins A and E Unveil Contributions from the Binding, Translocation, and Protease Domains to Their Functional Characteristics

Hyperexcitability disorders of cholinergically innervated muscles are treatable with botulinum neurotoxin (BoNT) A. The seven serotypes (A-G) potently block neurotransmission by binding to presynaptic receptors, undergoing endocytosis, transferring to the cytosol, and inactivating proteins essential for vesicle fusion. Although BoNT/A and BoNT/E cleave SNAP-25, albeit at distinct sites, BoNT/E blocks neurotransmission faster and more potently. To identify the domains responsible for these characteristics, the C-terminal heavy chain portions of BoNT/A and BoNT/E were exchanged to create chimeras AE and EA. After high yield expression in Escherichia coli, these single chain chimeras were purified by two-step chromatography and activated by conversion to disulfide-linked dichains. In vitro, each entered neurons, cleaved SNAP-25, and blocked neuromuscular transmission while causing flaccid paralysis in vivo. Acidification-dependent translocation of the light chain to the cytosol occurred more rapidly for BoNT/E and EA than for BoNT/A and AE because the latter pair remained susceptible for longer to inhibitors of the vesicular proton pump, and BoNT/A proved less sensitive. The receptor-binding and protease domains do not seem to be responsible for the speeds of intoxication; rather the N-terminal halves of their heavy chains are implicated, with dissimilar rates of cytosolic transfer of the light chains being due to differences in pH sensitivity. AE produced the most persistent muscle weakening and therefore has therapeutic potential. Thus, proof of principle is provided for tailoring the pharmacological properties of these toxins by protein engineering.

Evidence That the COOH-Terminal Region of Factor Va Heavy Chain Is Involved in the Regulation of Prothrombinase Activity.

The proteolytic conversion of prothrombin to thrombin is catalyzed by the prothrombinase complex composed of the enzyme, factor Xa (fXa), the cofactor, factor Va (fVa), assembled on a membrane surface in the presence of divalent metal ions. Incorporation of fVa into the prothrombinase complex results in a 300,000-fold increase in the catalytic efficiency of fXa for thrombin generation. A first cleavage of prothrombin by prothrombinase at Arg320 produces the active intermediate meizothrombin, while the second cleavage at Arg271 produces thrombin. It has been demonstrated that elimination of the carboxyl terminal portion of the heavy chain of fVa by proteolytic enzymes results in a cofactor molecule with decreased clotting activity and slightly increased to normal chromogenic activity. In addition, we have previously shown that the carboxyl terminal portion of the heavy chain of fVa is involved in the interaction of the cofactor with prothrombin. To further ascertain the importance of this region of the molecule for cofactor activity we used PCR based methods to produce recombinant fVa molecules with several portions of the COOH-terminus deleted. Recombinant fV653 has amino acids 653–709 deleted, recombinant fV696 has amino acid residues 680–696 deleted, recombinant fV680 has amino acid residues 653–680 deleted, while recombinant fV709 has amino acid residues 680–709 missing. These recombinant molecules along with wild type fV (fVWT) were transiently expressed in COS7L cells and assessed for their capability to promote prothrombin activation following activation by Russell's Viper Venom factor V activator (RVV-V activator). Thrombin generation was evaluated by SDS-PAGE and the kinetic parameters of the reactions were determined. While fVa653 and fVa680 were devoid of clotting activity, fVa696 and fVa709 had reduced clotting activities compared to fVaWT and plasma-derived fVa. This level of clotting activity was similar to the clotting activity of a fV molecule that was treated with thrombin and human neutrophil elastase (HNE) resulting in fVaHNE. fVaHNE is cleaved at Ala677/Thr678 resulting in a cofactor with a shorter heavy chain. Further analyses revealed that all mutant recombinant molecules as well as fVaHNE have similar KD values for fXa when compared to plasma fVa and fVaWT. SDS-PAGE analyses of prothrombin activation time courses revealed that the overall cleavage of prothrombin by prothrombinase assembled with fVa696, fVa709, or fVaHNE was slower resulting in accumulation of meizothrombin. This data confirm our previous findings and suggest that this region on the heavy chain of fVa contribute to cofactor function. A logical explanation for these findings is that the COOH-terminus of the heavy chain of fVa participates in the regulation of the rates of appearance/disappearance of meizothrombin. Increased persistence of meizothrombin in the reaction mixture can explain the slower clotting times since it is well known that meizothrombin has poor clotting activity. Thus at a given time point there will be more meizothrombin present in a sample where prothrombinase was assembled with fVa709, or fVa696, or fVaHNE than in a sample where prothrombinase was formed with fVaWT. Overall the data suggests that the COOH-terminal portion of the factor Va heavy chain contributes to the appropriate orientation of prothrombin with respect to the catalytic site of fXa resulting in efficient cleavages at Arg320 /Arg271 and competent thrombin formation.

HC fragment (C-terminal portion of the heavy chain) of tetanus toxin activates protein kinase C isoforms and phosphoproteins involved in signal transduction

A recent report [Gil, Chaib-Oukadour, Pelliccioni and Aguilera (2000) FEBS Lett. 481, 177–182] describes activation of signal transduction pathways by tetanus toxin (TeTx), a Zn2+-dependent endopeptidase synthesized by the Clostridium tetani bacillus, which is responsible for tetanus disease. In the present work, specific activation of protein kinase C (PKC) isoforms and of intracellular signal-transduction pathways, which include nerve-growth-factor (NGF) receptor trkA, phospholipase C(PLC)γ-1 and extracellular regulated kinases (ERKs) 1 and 2, by the recombinant C-terminal portion of the TeTx heavy chain (HC-TeTx) is reported. The activation of PKC isoforms was assessed through their translocation from the soluble (cytosolic) compartment to the membranous compartment, showing that clear translocation of PKC-α, −β, −γ and −δ isoforms exists, whereas PKC-∊ showed a slight decrease in its soluble fraction immunoreactivity. The PKC-∊ isoform showed no consistent response. Using immunoprecipitation assays against phosphotyrosine residues, time- and dose-dependent increases in tyrosine phosphorylation were observed in the trkA receptor, PLCγ-1 and ERK-1/2. The effects shown by the HC-TeTx fragment on tyrosine phosphorylation were compared with the effects produced by NGF. The trkA and ERK-1/2 activation were corroborated using phospho-specific antibodies against trkA phosphorylated on Tyr490, and antibodies against Thr/Tyr phosphorylated ERK-1/2. Moreover, PLCγ-1 phosphorylation was supported by its HC-TeTx-induced translocation to the membranous compartment, an event related to PLCγ-1 activation. Since HC-TeTx is the domain responsible for membrane binding and lacks catalytic activity, the activations described here must be exclusively triggered by the interaction of TeTx with a membrane component.

HC fragment (C-terminal portion of the heavy chain) of tetanus toxin activates protein kinase C isoforms and phosphoproteins involved in signal transduction.

A recent report [Gil, Chaib-Oukadour, Pelliccioni and Aguilera (2000) FEBS Lett. 481, 177-182] describes activation of signal transduction pathways by tetanus toxin (TeTx), a Zn(2+)-dependent endopeptidase synthesized by the Clostridium tetani bacillus, which is responsible for tetanus disease. In the present work, specific activation of protein kinase C (PKC) isoforms and of intracellular signal-transduction pathways, which include nerve-growth-factor (NGF) receptor trkA, phospholipase C(PLC)gamma-1 and extracellular regulated kinases (ERKs) 1 and 2, by the recombinant C-terminal portion of the TeTx heavy chain (H(C)-TeTx) is reported. The activation of PKC isoforms was assessed through their translocation from the soluble (cytosolic) compartment to the membranous compartment, showing that clear translocation of PKC-alpha, -beta, -gamma and -delta isoforms exists, whereas PKC-epsilon showed a slight decrease in its soluble fraction immunoreactivity. The PKC-zeta isoform showed no consistent response. Using immunoprecipitation assays against phosphotyrosine residues, time- and dose-dependent increases in tyrosine phosphorylation were observed in the trkA receptor, PLCgamma-1 and ERK-1/2. The effects shown by the H(C)-TeTx fragment on tyrosine phosphorylation were compared with the effects produced by NGF. The trkA and ERK-1/2 activation were corroborated using phospho-specific antibodies against trkA phosphorylated on Tyr(490), and antibodies against Thr/Tyr phosphorylated ERK-1/2. Moreover, PLCgamma-1 phosphorylation was supported by its H(C)-TeTx-induced translocation to the membranous compartment, an event related to PLCgamma-1 activation. Since H(C)-TeTx is the domain responsible for membrane binding and lacks catalytic activity, the activations described here must be exclusively triggered by the interaction of TeTx with a membrane component.

Inhibition by tetanus toxin of sodium-dependent, high-affinity [ 3H]5-hydroxytryptamine uptake in rat synaptosomes

Tetanus toxin (TeTx) is a powerful clostridial neurotoxin that inhibits Ca 2+-dependent neurotransmitter secretion as do the botulinum neurotoxins (BoNTs). We found that TeTx (but not BoNT/A) produced a specific time- and dose-dependent inhibition of Na +-dependent [ 3H]5-hydroxytryptamine (serotonin, 5-HT) uptake in rat CNS synaptosomes. This effect was found in all CNS tryptaminergic areas, being maximal in the hippocampus and occipital cortex. TeTx produced the maximum reduction in [ 3H]5-HT uptake after 30 min of preincubation, being significant also at lower doses (10 −12 M) or shorter incubation times (10 min). Serotonin transport inhibitors such as fenfluramine ( ic 50, 11.0 ± 0.9 μM), paroxetine ( ic 50, 33.5 ± 0.1 μM), and imipramine ( ic 50, 89.9 ± 5.7 μM) were 3 or 4 orders of magnitude less potent than TeTx ( ic 50, 8.7 ± 1.0 nM). Of the two fragments of TeTx, (the C-terminal portion of the neurotoxin heavy chain, which is responsible for the binding to the nerve tissue) was consistently more effective than the L-H N fragment (the light neurotoxin chain disulfide linked to the N-terminal portion of the heavy chain, which is responsible for the toxic metalloprotease action) as inhibitor of [ 3H]5-HT uptake in synaptosomal preparations (56 ± 5% and 95 ± 3% with respect to control, respectively). Antagonism of the toxin-induced [ 3H]5-HT uptake blockade could not be reversed by zinc chelators but did have the ability to antagonize the TeTx inhibition of basal and K +-evoked [ 3H]5-HT release in rat synaptosomes. The reduction in serotonin accumulation induced by TeTx could be responsible for some tetanic symptoms that have been related to the serotonergic system.

V(H) gene replacement occurs in the spleen and bone marrow of non-autoimmune quasi-monoclonal mice.

Genes encoding the heavy chain portion of immunoglobulin molecules arise from the combinatorial association of V, D and J gene segments, which occurs during discrete stages of B lineage development in the bone marrow. Recently, V(H) replacement, a form of receptor editing, has been described, in which the variable region of an existing VDJ(H) rearrangement is replaced by another V(H) gene segment in a recombination event believed to involve an embedded heptamer within the coding region of the V(H). Studies of transgenic mice with "knocked-in" VDJ(H) genes encoding anti-DNA specificity have demonstrated that receptor editing of the heavy chain is one mechanism by which autoreactive B cell receptors can be modified. Another mouse, the "quasi-monoclonal", which encodes a "knocked-in" VDJ(H) for the hapten NP also contains B lineage cells that undergo V(H) replacement. This suggests that V(H) replacement may play a role in the normal diversification of the antibody repertoire. Using a ligation-mediated PCR assay, we have identified V(QM) double-stranded DNA breaks indicative of V(H) replacement intermediates from bone marrow and splenic B lineage cells of quasi-monoclonal mice in the absence of immunization. V(QM) to J558 recombination deletion products consistent with V(H) replacement were also detected in both the bone marrow and spleen of non-immunized quasi-monoclonal mice. Moreover, RAG-1 transcripts were detected in the spleen. These data suggest that V(H) replacement can be part of the mechanism(s) used by B lineage cells to generate diversity throughout B lineage development, including later stages occurring in secondary lymphoid tissues.

Proteolytic Events That Regulate Factor V Activity in Whole Plasma From Normal and Activated Protein C (APC)-Resistant Individuals During Clotting: An Insight Into the APC-Resistance Assay

Human factor V is activated to factor Va by alpha-thrombin after cleavages at Arg709, Arg1018, and Arg1545. Factor Va is inactivated by activated protein C (APC) in the presence of a membrane surface after three sequential cleavages of the heavy chain. Cleavage at Arg506 provides for efficient exposure of the inactivating cleavages at Arg306 and Arg679. Membrane-bound factor V is also inactivated by APC after cleavage at Arg306. Resistance to APC is associated with a single nucleotide change in the factor V gene (G1691-->A) corresponding to a single amino acid substitution in the factor V molecule: Arg506-->Gln (factor V Leiden). The consequence of this mutation is a delay in factor Va inactivation. Thus, the success of the APC-resistance assay is based on the fortuitous activation of factor V during the assay. Plasmas from normal individuals (1691 GG) and individuals homozygous for the factor V mutation (1691 AA) were diluted in a buffer containing 5 mmol/L CaCl2, phospholipid vesicles (10 micromol/L), and APC. APC, at concentrations < or = 5.5 nmol/L, prevented clot formation in normal plasma, whereas under similar conditions, a clot was observed in plasma from APC-resistant individuals. Gel electrophoresis analyses of factor V fragments showed that membrane-bound factor V is primarily cleaved at Arg306 in both plasmas. However, whereas in normal plasma production of factor Va heavy chain is counterbalanced by fast degradation after cleavage at Arg506/Arg306, in the APC-resistant individuals' plasma, early generation and accumulation of the heavy chain portion of factor Va occurs as a consequence of delayed cleavage at Arg306. At elevated APC concentrations (>5.5 nmol/L), no clot formation was observed in either plasma from normal or APC-resistant individuals. Our data show that resistance to APC in patients with the Arg506-->Gln mutation is due to the inefficient degradation (inactivation) of factor Va heavy chain by APC.

Mapping of the high molecular weight kininogen binding site of prekallikrein. Evidence for a discontinuous epitope formed by distinct segments of the prekallikrein heavy chain

Prekallikrein, a glycoprotein involved in contact phase activation, circulates in plasma in the form of a binary complex with high molecular weight kininogen (H-kininogen). The binding to H-kininogen is mediated by the prekallikrein heavy chain consisting of four repetitive domains, A1-A4. To define more precisely the region(s) involved in kininogen binding, we have employed an affinity cross-linking strategy with a synthetic peptide of 31 residues which mimics the prekallikrein binding site of H-kininogen. Cross-linking of the radiolabeled peptide to (pre)kallikrein revealed a binding segment in the NH2-terminal portion of the prekallikrein heavy chain; another binding segment was located in the COOH-terminal part of the heavy chain. The latter binding segment is harbored by a previously identified fragment of the kallikrein heavy chain involved in H-kininogen binding (Page, J.D., and Colman, R.W. (1991) J. Biol. Chem. 266, 8143-8148). Chemical cleavage of the heavy chain cross-linked with the radiolabeled peptide mapped the NH2-terminal binding segment to 60 residues (positions 53-112) of A1. Synthesis of a peptide (positions 56-86) and development of specific antibodies to this peptide narrowed down the kininogen binding segment to 31 residues of the center portion of A1. This NH2-terminal segment is equivalent to a kininogen binding site previously identified in factor XI (Baglia, F.A., Jameson, B.A., and Walsh, P.N. (1992) J. Biol. Chem. 267, 4247-4252). We conclude that prekallikrein exposes at least two segments on its heavy chain portion which form a continuous surface thereby facilitating the intimate binding of the zymogen to its nonenzymatic cofactor, H-kininogen.

Characterization of Rat Factors X and Xa: Demonstration of Factor Xa in Rat Plasma1

We have found that rat plasma corrected the non-activated PT of human normal or factor-X deficient plasma, and the factor Xa-like activity being constantly detected in every 1 ml of blood collected via the cannulated carotid artery of rats. The present study was undertaken to characterize the factor Xa-like activity in rat plasma by preparing rat factor X and a monoclonal antibody against it. Factor X was purified from a BaCl2 eluate of rat plasma by chromatographies on columns of DEAE-Sepharose CL-6B and Sulfate Cellulofine or on a column of Affi-Gel 10 conjugated with a monoclonal antibody against rat factor X. Factor Xa-like activity in rat plasma was eliminated by the treatment of rat plasma with a monoclonal antibody which recognized the heavy chain portions of rat factors X and Xa. A kinetical study demonstrated that rat factor Xa was strongly inhibited by rat antithrombin III, with a Ki of 2.2 x 10(-11) M, in the presence of heparin. However, in the absence of heparin, the second order rate constant for the inhibition of rat factor Xa by rat antithrombin III was 2.6 x 10(4) M-1.min-1, which was one forty-third that for the inhibition of human factor Xa by human antithrombin III. Furthermore, rat factor Xa was resistant to the inhibition by rat alpha-1-antitrypsin and alpha-2-macroglobulin.(ABSTRACT TRUNCATED AT 250 WORDS)

Isolation of the regulatory domain of scallop myosin: role of the essential light chain in calcium binding.

The regulatory domain of scallop myosin, consisting of a regulatory light chain (R-LC), an essential light chain (E-LC), and a portion of heavy chain, occupies the neck region of myosin. This domain is directly involved in the regulation of molluscan muscle contraction, which is triggered by direct Ca2+ binding to myosin. We have isolated a soluble functional complex (regulatory complex) comprised of R-LC, E-LC, and a 10-kDa heavy chain fragment in a 1:1:1 stoichiometry by clostripain digestion of the myosin head (papain subfragment 1). N termini of the heavy chain fragments were either leucine-812 or valine-817. The isolated complex retained the specific Ca2(+)-binding site and bound Ca2+ with a similar affinity and selectivity as myosin. The individual components of the regulatory complex were isolated after complete denaturation with guanidine hydrochloride. The regulatory complex was reconstituted from isolated light chains and the heavy chain fragment. The renatured complex regained Ca2+ binding quantitatively. To elucidate the function of the E-LC in Ca2+ binding, we constructed hybrid regulatory complexes. The hybrid complexes reconstituted with molluscan E-LC and R-LC regained the specific Ca2(+)-binding site, whereas the hybrid complex formed with rabbit skeletal E-LC [alkali LC 2 (A2-LC)] and scallop R-LC did not. The results demonstrate that E-LCs from myosins regulated by direct Ca2+ binding are required for the specific Ca2+ binding in the molluscan muscle.

Structural model of porcine factor VIII and factor VIIIa molecules based on scanning transmission electron microscope (STEM) images and STEM mass analysis.

Porcine plasma factor VIII (fVIII) molecules are heterodimers composed of a 76,000-mol wt light chain (-A3-C1-C2) and a heavy chain ranging in molecular weight from 82,000 (A1-A2) to 166,000 (A1-A2-B). Proteolytic activation of fVIII by thrombin results in fVIIIa heterotrimers lacking B domains (A1, A2, A3-C1-C2). In this study, immunoaffinity purified fVIII was further fractionated by mono S or mono Q chromatography to prepare heterodimers containing a light chain and an A1-A2-B heavy chain (fVIII 166/76) or an A1-A2 heavy chain (fVIII 82/76). Mass analysis of scanning transmission electron microscopic (STEM) images of fVIII 166/76 indicated that heterodimers (mass 237 +/- 20 kD) had irregularly globular core structures 10-12 nm across, and frequently displayed a diffuse, occasionally globular to ovoid satellite structure extending 5-14 nm from the core, and attached to it by a thin stalk. Factor VIII 82/76 molecules (mass 176 +/- 20 kD) had the same core structures as fVIII 166/76 molecules, but lacked the satellite structure. These findings indicate that A1-A2 domains of heavy chains and the light chains of the fVIII procofactor molecule are closely associated and constitute the globular core structure, whereas the B domainal portion of heavy chains comprises the peripheral satellite appendage. Factor VIII core structures commonly displayed a finger-like projection near the origin of the B domainal stalk that was also a consistent feature of the free heavy chains (mass 128-162 kD) found in fVIII 166/76 preparations. Factor VIII light chain monomers (mass, 76 +/- 16 kD) were globular to c-shaped particles 6-8 nm across. These chains commonly possessed a v-shaped projection originating from its middle region, that could also be observed at the periphery of fVIII core molecules. Factor VIIIa preparations contained heterotrimers (mass 162 +/- 13 kD) that had the same dimensions as fVIII core structures, lacked the B domainal appendage, and sometimes possessed the same core features as fVIII molecules. Molecular species corresponding to heterodimers (mass, 128 +/- 13 kD) and unassociated subunit chains (40-100 kD) were also observed in fVIIIa preparations, suggesting that heterotrimers have an appreciable tendency to dissociate, a phenomenon that could explain the decay of fVIIIa activity after thrombin activation of fVIII.

Inhibition of transmitter release by botulinum neurotoxin A

1. The contribution of a proteolytic fragment (H2L) of botulinum neurotoxin type A (comprised of the aminoterminal region of the heavy-chain disulphide-linked to the light chain) to inhibition of neurotransmitter release was investigated, using central cholinergic synapses of Aplysia, rodent nerve-diaphragm preparations and cerebrocortical synaptosomes. 2. No reduction in neurotransmitter release was observed following external application to these preparations of highly purified H2L or after intracellular injection into Aplysia neurons. 3. The lack of activity was not the result of alteration in the light chain of H2L during preparation of the latter because (a) renaturation of this light chain with intact heavy chain produced a toxic di-chain form and (b) simultaneous application of heavy chain and light chain from H2L inhibited transmitter release in Aplysia. 4. Bath application of H2L and heavy chain together inhibited release of transmitter; however, at the neuromuscular junction the potency of this mixture was much lower than that of native toxin. A similar blockade resulted when heavy chain was applied intracellularly and H2L added to the bath, demonstrating that H2L is taken up into cholinergic neurons of Aplysia. This uptake is shown to be mediated by the amino-terminal moiety of heavy chain (H2), because bath application of light chain plus H2 led to a decrease in acetylcholine release from a neuron that had been injected with heavy chain. 5. A role within the neuron is implicated for a carboxy-terminal portion of heavy chain (H1) since intracellular injection of light chain and H2 did not affect transmitter release. Although the situation is unclear in mammalian nerves, these collective findings indicate that blockade of transmitter release in Aplysia neurons requires the intracellular presence of light chain and H1 (by inference), whilst H2 contributes to the internalization step.

Proteinase-sensitive regions in the heavy chain of low molecular weight kininogen map to the inter-domain junctions.

Low molecular weight kininogen from human plasma was subjected to limited proteolysis with trypsin, chymotrypsin, elastase, and bromelain, and the resulting fragments of 20,000 or 40,000 Da were isolated. Amino-terminal sequence analysis of the fragments disclosed for the various proteinases eight independent cleavage sites distinct from the typical kallikrein cleavage sites flanking the kinin region. All the identified cleavage sites cluster in two stretches of 11-12 residues of the kininogen heavy chain. These short segments represent the primary attack sites for proteinases ("proteinase-sensitive regions") in the heavy chain portion of human low molecular weight kininogen. The amino acid sequences of the two proteinase-sensitive regions are mutually homologous; they are further characterized by the presence of a single copy each of the consensus tetrapeptide Cys-X-Gly-Cys known to form a narrow disulfide loop (Kellermann, J., Thelen, C., Lottspeich, F., Henschen, A., Vogel, R., and Müller-Esterl, W. (1987) Biochem. J. 247, 15-21). The proteinase-sensitive regions are located at the junctions of the three cystatin-like domains constituting the kininogen heavy chain. Proteolytic cleavage at the sensitive regions dissects the kininogen heavy chain and releases single domains of 20,000 Da and combined domains of 40,000 Da which can function as cysteine proteinase inhibitors. The presence of kininogen heavy chain domains in plasma samples under pathologic conditions suggests that cleavage of the proteinase-sensitive regions might also occur in vivo.

Structure of Myosin Subfragment-1 from Electron Microscopy and Crystallography

The primary role of the interaction of actin and myosin is the generation of force and motion as a direct consequence of the cyclic interaction of myosin crossbridges with actin filaments. Myosin is composed of six polypeptides: two heavy chains of molecular weight 220,000 daltons and two pairs of light chains of molecular weight 17,000-23,000. The C-terminal portions of the myosin heavy chains associate to form an α-helical coiled-coil rod which is responsible for myosin filament formation. The N-terminal portion of each heavy chain associates with two different light chains to form a globular head that binds actin and hydrolyses ATP. Myosin can be fragmented by limited proteolysis into several structural and functional domains. It has recently been demonstrated using an in vitro movement assay that the globular head domain, subfragment-1, is sufficient to cause sliding movement of actin filaments.The discovery of conditions for crystallization of the myosin subfragment-1 (S1) has led to a systematic analysis of S1 structure by x-ray crystallography and electron microscopy. Image analysis of electron micrographs of thin sections of small S1 crystals has been used to determine the structure of S1 in the crystal lattice.

Bovine high molecular weight kininogen. The amino acid sequence, positions of carbohydrate chains and disulfide bridges in the heavy chain portion.

The existence of two types of circulating bovine plasma high molecular weight kininogen (HMWK) was predicted from analyses of complementary DNAs coding for this protein (Kitamura, N., Takagaki, Y., Furuto, S., Tanaka, T., Nawa, H., and Nakanishi, S. (1983) Nature 305, 545-549). The present protein-based study provided evidence in support of the proposed amino acid sequence derived from analysis of the cDNA clone, and the results confirm the existence of two types of circulating HMWK. Type I HMWK contains a heavy chain composed of 361 residues, while the heavy chain of type II HMWK contains 359 residues. The amino acid sequences of type I and type II HMWK determined in this study were identical to that inferred from the cDNA sequence with the exception of microheterogeneity observed in the cDNA at position 87 (Glu/Gln) and 168 (Lys/Arg). The heavy chain of type I HMWK contains 4 asparagine-linked carbohydrate chains at Asn-69, -150 (or -151), -179, and -186, while the heavy chain of type II HMWK contains these and an additional carbohydrate chain at Asn-264. In addition, a carbohydrate chain was found to be O-glycosidically linked to Thr-118 in both chains. Among nine disulfide linkages found in HMWK, eight intrachain disulfide pairs were established in the heavy chain. One interchain disulfide bridge occurs between the heavy chain and the light chain. This disulfide pairing, as well as repeating amino acid sequences observed in the heavy chain, provides strong evidence for the existence of three homologous domains in the heavy chain of bovine HMWK.

Protection of Mice Against Tetanus Toxin by Combination of Two Human Monoclonal Antibodies Recognizing Distinct Epitopes on the Toxin Molecule

Human B-lymphocytes were fused with the human lymphoblastoid B-cell line WI-L2-729 HF2. Hybridoma frequencies were in the range of 10(-5) when the mononuclear cells were (a) prestimulated with pokeweed mitogen (PWM), (b) fused with polyethyleneglycol (PEG), and (c) selected in a hypoxanthine-azaserine (HAza) containing medium. To generate monoclonal antibodies (MAb) specific for tetanus toxin (TToxin) human spleen cells were precultured with PWM plus tetanus toxoid (TToxoid) in two separate fusions. Two hybridomas were selected based on high binding activity using an enzyme-linked immunosorbent assay (ELISA) for TToxoid. Both hybridomas, cloned twice and designated anti-TT1 and anti-TT2, exhibited a near tetraploid karyotype and showed stable production of antibody (0.15 micrograms/ml) over several months. Using ELISA for fragments of TToxin and the immunoblotting technique, the two IgG1 monoclonal antibodies were found to bind to the heavy chain portion of the B-fragment (anti-TT1) and on the C-fragment (anti-TT2) of the toxin. When tested in an ELISA with TToxin the combination of anti-TT1 and anti-TT2 showed higher binding activity than either reagent alone. In an in vivo neutralization assay mice were completely protected against TToxin by the combination of the two antibodies while either antibody alone resulted only in a delay of death of the mice. These findings demonstrate that a cocktail of appropriate human monoclonal antibodies can be far superior to a single reagent when used in a therapeutic setting.

Transformation of trypomastigote forms of Trypanosoma cruzi into activators of alternative complement pathway by immune IgG fragments.

In this report we examined the capacity of immune IgG fragments to prepare trypomastigote bloodstream forms (TBF) of Trypanosoma cruzi for lysis. F(ab')2 fragments were capable of presensitizing TBF for complement (C) lysis, thus excluding the participation of Fc domains in the C activation process. An intact hinge region of the IgG molecule was not involved either, since the corresponding Fab' were almost as active as the original molecules in preparing TBF for lysis. Fab also retained such activity even after further reduction and alkylation. These findings indicate that neither the portions of heavy chains that make up the hinge region nor the intrachain disulphide bonds are involved in the process. The IgG fragments promoted lysis through the activation of the alternative C pathway (ACP). These results suggest that the immune IgG transforms TBF into ACP activators by blocking the capacity of some parasite cell surface components that are known inhibitors of C activation.