Detection of time-dependent and oxidatively induced antigens of bovine liver rhodanese with monoclonal antibodies

Rhodanese has been extensively utilized as a model protein for the study of enzyme structure-function relationships. An immunological study of conformational changes occurring in rhodanese as a result of oxidation or thermal inactivation was conducted. Three monoclonal antibodies (MABs) to rhodanese were produced. Each MAB recognized a unique epitope as demonstrated by binding of the MABs to different proteolytic fragments of rhodanese. While none of the MABs significantly bound native, soluble, sulfur-substituted bovine rhodanese, as indicated in indirect enzyme-linked immunosorbent assay experiments, each MAB was immunoadsorbed from solution by soluble rhodanese as a function of the time rhodanese was incubated at 37 degrees C. Thus, as rhodanese was thermally inactivated, conformational changes resulted in the expression of three new epitopes. Catalytic conformers demonstrated different rates of thermally induced antigen expression. Each MAB also recognized epitopes expressed when rhodanese was immobilized on microtiter plates at 37 degrees C. Two conformers resulting from oxidation of rhodanese by hydrogen peroxide were identified immunologically. All MABs recognized rhodanese that was oxidized with peroxide and allowed to undergo a secondary cyanide-dependent reaction which also resulted in a fluorescence shift and increased proteolytic susceptibility. Only one MAB was capable of recognizing an epitope expressed when rhodanese was oxidized with peroxide and then separated from the reactants to prevent induction of the secondary conformational changes.     

Identification of Genogroup I and Genogroup II broadly reactive epitopes on the norovirus capsid

Norwalk virus, a member of the family Caliciviridae, is an important cause of acute epidemic nonbacterial gastroenteritis. Norwalk and related viruses are classified in a separate genus of Caliciviridae called Norovirus, which is comprised of at least three genogroups based on sequence differences. Many of the currently available immunologic reagents used to study these viruses are type specific, which limits the identification of antigenically distinct viruses in detection assays. Identification of type-specific and cross-reactive epitopes is essential for designing broadly cross-reactive diagnostic assays and dissecting the immune response to calicivirus infection. To address this, we have mapped the epitopes on the norovirus capsid protein for both a genogroup I-cross-reactive monoclonal antibody and a genogroup II-cross-reactive monoclonal antibody by use of norovirus deletion and point mutants. The epitopes for both monoclonal antibodies mapped to the C-terminal P1 subdomain of the capsid protein. Although the genogroup I-cross-reactive monoclonal antibody was previously believed to recognize a linear epitope, our results indicate that a conformational component of the epitope explains the monoclonal antibody's genogroup specificity. Identification of the epitopes for these monoclonal antibodies is of significance, as they are components in a commercially available norovirus-diagnostic enzyme-linked immunosorbent assay.     

Expression of cloned bovine adrenal rhodanese

A cDNA for the enzyme rhodanese (thiosulfate:cyanide sulfurtransferase, EC 2.8.1.1) has been cloned from a bovine adrenal library. An initiator methionine codon precedes the amino-terminal amino acid found in the isolated protein. Rhodanese is synthesized in the cytoplasm and transferred to the mitochondrial matrix. Thus, any amino-terminal sequence required for organelle import is retained in the mature protein. Furthermore, the DNA sequence shows that there are three additional amino acids, Gly-Lys-Ala, at the carboxyl terminus that are not found by protein sequencing. Additionally, comparison of the published amino acid sequence with that encoded by the open reading frame revealed three differences in the amino acid sequence. Comparison of the bovine and chicken liver sequences shows an overall level of 70% sequence homology, but there is complete identity of all residues that have been implicated in the function of the enzyme. When two mammalian cells, cos-7 and 293 cells, were transiently transfected with a plasmid containing the rhodanese coding region, rhodanese activity in lysates increased approximately 20-fold. Fluorograms of denaturing polyacrylamide gels detected a large increase in a polypeptide that co-migrated with the native protein and reacted with anti-rhodanese antibodies. Nondenaturing gels showed two active species that co-migrated with the two major electrophoretic forms purified by current procedures. Escherichia coli, transformed with a plasmid containing the rhodanese coding region, showed a 15-fold increase in rhodanese activity over baseline values. When the E. coli recombinant protein was analyzed on a nondenaturing gel, only one species was observed that co-electrophoresed with the more electropositive variant seen in purified bovine liver rhodanese. This single variant could be converted by carboxypeptidase B digestion to a form of the enzyme that co-migrated with the more electronegative species isolated from bovine liver. Thus, two major, enzymatically active electrophoretic variants, commonly observed in mammalian cells, can be accounted for by carboxyl-terminal processing without recourse to other post-translational modifications.     

Epitope Mapping of Human Alpha-Fetoprotein

The epitope structure of human alpha-fetoprotein (AFP) was studied using more than 50 monoclonal antibodies (MAB) to human AFP. These MAB obtained from various world laboratories of the TD-2 AFP Workshops of the International Society for Oncodevelopmental Biology and Medicine (ISOBM-1996-1998-2000) were analyzed by competitive immunoaffinity electrochromatography (IAE) on nitrocellulose membranes (NCM). Five types of interaction of the AFP–MAB complex with the MAB fixed on NCM were found: 1) complete neutralization; 2) partial neutralization; 3) unidirectional neutralization; 4) enhanced binding; 5) lack of interaction. By IAE, 51 MAB were found to recognize 23 different epitopes in the AFP molecule. Based on these findings, an epitope map of AFP was designed which consists of eight epitope clusters and eight individual epitopes. The epitope location is considered with respect to the conformational state of the AFP molecule. Possible causes of the five types of interaction found on neutralization are discussed.     

Effects on ATPase activity of monoclonal antibodies raised against (Ca2+ + Mg2+)-ATPase from rabbit skeletal muscle sarcoplasmic reticulum and their correlation with epitope location.

A total of 28 monoclonal antibodies have been raised against the (Ca2+ + Mg2+)-ATPase of rabbit skeletal muscle sarcoplasmic reticulum. Epitope mapping, using protein fragments generated by proteolysis, indicates that these antibodies include examples binding to at least four distinct epitopes on the A1 and B tryptic fragments of the ATPase. Competition data also show that the 28 antibodies are directed against at least five spatially distinct regions. Altogether, nine inhibitory antibodies were produced: six of these inhibitory antibodies mapped to the same spatial region, although they appear to bind to two distinct epitopes located within the hinge region and the nucleotide-binding domains of current structural models; one antibody bound to an epitope located within the phosphorylation domain and the stalk-transmembranous region designated M4S4 by Brandl, Green, Korczak & MacLennan [(1986) Cell 44, 597-607]. Two of the inhibitory antibodies recognized assembled epitopes exclusively and could not be mapped. Binding to four of the five identified spatial regions was without effect on activity. These data show that the inhibition of catalytic activity by monoclonal antibodies is achieved only by binding to defined regions of the ATPase and they may therefore provide useful probes of structure-function relationships.     

Antigenic determinants of human placental and testicular placental-like alkaline phosphatases as mapped by monoclonal antibodies

Placental alkaline phosphatase (PLAP) in humans shows a high degree of genetic polymorphism as disclosed by electrophoretic analysis. Human testes contain trace amounts of a PLAP-like enzyme, that although immunologically cross-reactive with PLAP, shows unique catalytic properties. As an alternative approach to study enzyme polymorphism we have developed monoclonal antibodies to purified allelic variants of PLAP. Five different monoclonal antibodies are described in this report. The antibodies react with different epitopes on the PLAP molecule. Both conformational dependent and independent determinants are detected. Two epitopes are modified when comparing the S and F allelic variants of PLAP. One epitope is common to PLAP and the intestinal isoenzyme of alkaline phosphatase. The five epitopes appear to be mapped on two rather distant antigenic domains. Combinations of any two antibodies binding to different domains give immunoprecipitates with PLAP on Ouchterlony tests and give good response in sandwich enzyme-linked immunosorbent assays. A study of PLAP-like enzyme in 32 individual testis samples indicates differences in four of the epitopes when compared with PLAP. Four types of testicular enzymes can be distinguished based on their reactivities. These results indicate structural differences between the testicular PLAP-like enzyme and PLAP. These differences are compatible with an underlying genetic mechanism.     

Indirect detection of an epitope-specific response to HIV-1 gp120 immunization in human subjects

A specific response of human serum neutralizing antibodies (nAb) to a conformational epitope as a result of vaccination of human subjects with the surface envelope glycoprotein (gp120) of HIV-1 has not previously been documented. Here, we used computational analysis to assess the epitope-specific responses of human subjects, which were immunized with recombinant gp120 immunogens in the VAX003 and VAX004 clinical trials. Our computational methodology--a variation of sieve analysis--compares the occurrence of specific nAb targeted conformational 3D epitopes on viruses from infected individuals who received vaccination to the occurrence of matched epitopes in the viruses infecting placebo subjects. We specifically studied seven crystallographically defined nAb targeted conformational epitopes in the V3 loop, an immunogenic region of gp120. Of the six epitopes present in the immunogens and targeted by known monoclonal neutralizing antibodies, only the one targeted by the anti-V3 nAb 2219 exhibited a significant reduction in occurrence in vaccinated subjects compared to the placebo group. This difference occurred only in the VAX003 Thailand cohort. No difference was seen between vaccinated and placebo groups for the occurrence of an epitope that was not present in the immunogen. Thus, it can be theorized that a specific 2219-like human neutralizing antibody immune response to AIDSVAX immunization occurred in the VAX003 cohort, and that this response protected subjects from a narrow subset of HIV-1 viruses circulating in Thailand in the 1990s and bearing the conformational epitope targeted by the neutralizing antibody 2219.     

Alteration in expression of the rat mitochondrial ATPase 6 gene during Pneumocystis carinii infection

Background

Norwalk virus causes outbreaks of acute non-bacterial gastroenteritis in humans. The virus capsid is composed of a single 60 kDa protein. In a previous study, the capsid protein of recombinant Norwalk virus genogroup II was expressed in an E. coli system and monoclonal antibodies were generated against it. The analysis of the reactivity of those monoclonal antibodies suggested that the N-terminal domain might contain more antigenic epitopes than the C-terminal domain. In the same study, two broadly reactive monoclonal antibodies were observed to react with genogroup I recombinant protein.

Results

In the present study, we used the recombinant capsid protein of genogroup I and characterized the obtained 17 monoclonal antibodies by using 19 overlapping fragments. Sixteen monoclonal antibodies recognized sequential epitopes on three antigenic regions, and the only exceptional monoclonal antibody recognized a conformational epitope. As for the two broadly reactive monoclonal antibodies generated against genogroup II, we indicated that they recognized fragment 2 of genogroup I. Furthermore, genogroup I antigen from a patient's stool was detected by sandwich enzyme-linked immunosorbent assay using genogroup I specific monoclonal antibody and biotinated broadly reactive monoclonal antibody.

Conclusion

The reactivity analysis of above monoclonal antibodies suggests that the N-terminal domain may contain more antigenic epitopes than the C-terminal domain as suggested in our previous study. The detection of genogroup I antigen from a patient's stool by our system suggested that the monoclonal antibodies generated against E. coli expressed capsid protein can be used to detect genogroup I antigens in clinical material.     

Acid pH-induced conformational changes in bovine liver rhodanese.

The enzyme rhodanese is greatly stabilized in the range pH 4-6, and samples at pH 5 are fully active after several days at 23 degrees C. This is very different from results at pH greater than 7, where there is significant loss of activity within 1 h. A pH-dependent conformational change occurs below pH 4 in a transition centered around pH 3.25 that leads slowly to inactive rhodanese at pH 3 (t 1/2 = 22 min at pH3). The inactive rhodanese can be reactivated by incubation under conditions required for detergent-assisted refolding of denatured rhodanese. The inactive enzyme at pH 3 has the maximum of its intrinsic fluorescence spectrum shifted to 345 nm from 335 nm, which is characteristic of native rhodanese at pH greater than 4. At pH 3, rhodanese shows increased exposure of organized hydrophobic surfaces as measured by 1,1'-bis(4-anilino)naphthalene-5,5'-disulfonic acid binding. The secondary structure is maintained over the entire pH range studied (pH 2-7). Fluorescence anisotropy measurements of the intrinsic fluorescence provide evidence suggesting that the pH transition produces a state that does not display greatly increased average flexibility at tryptophan residues. Pepsin digestibility of rhodanese follows the pH dependence of conformational changes reported by activity and physical methods. Rhodanese is resistant to proteolysis above pH 4 but becomes increasingly susceptible as the pH is lowered. The form of the enzyme at pH 3 is cleaved at discrete sites to produce a few large fragments. It appears that pepsin initially cleaves close to one end of the protein and then clips at additional sites to produce species of a size expected for the individual domains into which rhodanese is folded. Overall, it appears that in the pH range between pH 3 and 4, titration of groups on rhodanese leads to opening of the structure to produce a conformation resembling, but more rigid than, the molten globule state that is observed as an intermediate during reversible unfolding of rhodanese.     

Two-dimensional structure of the Opc invasin from Neisseria meningitidis

A two-dimensional structural model was devised for the Opc outer membrane protein invasin which contains 10 transmembrane strands and five surface-exposed loops. One continuous epitope recognized by three monoclonal antibodies was localized to the tip of loop 2 by synthetic peptides and site-directed mutagenesis while a second, discontinuous epitope recognized by a fourth antibody was localized to loops 4 and 5 by insertion mutagenesis. These monoclonal antibodies are bactericidal and inhibit adhesion and invasion. Most of the T-cell epitopes defined by Wiertz et al. (1996) were localized to the transmembrane strands. Oligonucleotides encoding a foreign epitope (∇) from Semliki Forest virus were inserted into Bgl II restriction sites created by site-directed mutagenesis. The ∇ epitopes inserted in all five predicted loops were recognized on the cell surface of live Escherichia coli bacteria by a monoclonal antibody and are exposed while ∇ epitopes in the N-terminus or three predicted turns were not. The results thus confirm important predictions of the model and define five permissive sites within surface-exposed loops which can be used to insert foreign epitopes.     

Molecular Analysis of the Gal/GalNAc Adhesin of Entamoeba histolytica1

Attachment of Entamoeba histolytica to colonic epithelium and a variety of other target cells is mediated by a galactosc/N-acetyl D-galactosamine (Gal/GalNAc) inhibitable adhesin. Seven monoclonal antibodies specific for nonoverlapping epitopes of the 170 kDa subunit have been shown to have distinct effects on adherence. Four of these monoclonal antibodies inhibit or have no effect on amebic adherence while two others enhance amebic adherence. The epitopes recognized by these seven monoclonal antibodies have been mapped to the extracellular cysteine rich region of the 170 kDa subunit. The conformational nature of the epitopes was examined by testing monoclonal antibody reactivity with isolated regions of the 170 kDa subunit expressed as fusion proteins in E. coli and also with denatured native adhesin. These analyses suggested that three of monoclonal antibodies recognized conformational epitopes while the remaining four recognized linear epitopes. The mapping of these monoclonal antibodies have identified functionally important regions of the Gal/GalNAc adhesin and have also shown that recombinant Gal/GalNAc adhesin, when expressed in E. coli, retained at least some of its native conformation.     

Dissecting Antibodies with Regards to Linear and Conformational Epitopes

An important issue for the performance and specificity of an antibody is the nature of the binding to its protein target, including if the recognition involves linear or conformational epitopes. Here, we dissect polyclonal sera by creating epitope-specific antibody fractions using a combination of epitope mapping and an affinity capture approach involving both synthesized peptides and recombinant protein fragments. This allowed us to study the relative amounts of antibodies to linear and conformational epitopes in the polyclonal sera as well as the ability of each antibody-fraction to detect its target protein in Western blot assays. The majority of the analyzed polyclonal sera were found to have most of the target-specific antibodies directed towards linear epitopes and these were in many cases giving Western blot bands of correct molecular weight. In contrast, many of the antibodies towards conformational epitopes did not bind their target proteins in the Western blot assays. The results from this work have given us insights regarding the nature of the antibody response generated by immunization with recombinant protein fragments and has demonstrated the advantage of using antibodies recognizing linear epitopes for immunoassay involving wholly or partially denatured protein targets.     

A Novel Universal Neutralizing Monoclonal Antibody against Enterovirus 71 That Targets the Highly Conserved “Knob” Region of VP3 Protein

Hand, foot and mouth disease caused by enterovirus 71(EV71) leads to the majority of neurological complications and death in young children. While putative inactivated vaccines are only now undergoing clinical trials, no specific treatment options exist yet. Ideally, EV71 specific intravenous immunoglobulins could be developed for targeted treatment of severe cases. To date, only a single universally neutralizing monoclonal antibody against a conserved linear epitope of VP1 has been identified. Other enteroviruses have been shown to possess major conformational neutralizing epitopes on both the VP2 and VP3 capsid proteins. Hence, we attempted to isolate such neutralizing antibodies against conformational epitopes for their potential in the treatment of infection as well as differential diagnosis and vaccine optimization. Here we describe a universal neutralizing monoclonal antibody that recognizes a conserved conformational epitope of EV71 which was mapped using escape mutants. Eight escape mutants from different subgenogroups (A, B2, B4, C2, C4) were rescued; they harbored three essential mutations either at amino acid positions 59, 62 or 67 of the VP3 protein which are all situated in the “knob” region. The escape mutant phenotype could be mimicked by incorporating these mutations into reverse genetically engineered viruses showing that P59L, A62D, A62P and E67D abolish both monoclonal antibody binding and neutralization activity. This is the first conformational neutralization epitope mapped on VP3 for EV71.     

Monoclonal antibodies as probes of conformational changes in protein-engineered cytochrome c

Determination of the nature of the antigen-antibody complex has always been the ultimate goal of three-dimensional epitope mapping studies. Various strategies for epitope mapping have been employed which include comparative binding studies with peptide fragments of antigens, binding studies with evolutionarily related proteins, chemical modifications of epitopes, and protection of epitopes from chemical modification or proteolysis by antibody shielding. In this study we report the use of protein engineering to modify residues in horse cytochrome c that are in or near the epitopes of four monoclonal antibodies specific for this protein. The results demonstrate not only that site-specific changes in the antigen binding site dramatically affect antibody binding, but, more importantly, that some of the site-specific changes cause local and long-range perturbations in structure that are detected by monoclonal antibody binding at other surfaces of the antigen. These findings emphasize the role of native conformation in the stabilization of the interaction between protein antigens and high affinity monoclonal antibodies. Furthermore, the results demonstrate that monoclonal antibodies are more sensitive probes of changes in conformation brought about by protein engineering than low resolution spectroscopic methods such as circular dichroism, where similar spectra are observed for all the analogues. These findings suggest a role for monoclonal antibodies in detecting conformational changes invoked by nonconservative amino acid substitutions or substitutions of evolutionarily conserved residues in protein-engineered or recombinant proteins.     

Site-directed mutagenesis and epitope-mapped monoclonal antibodies define a catalytically important conformational difference between human placental and germ cell alkaline phosphatase.

Placental (PLAP) and germ cell (GCAP) alkaline phosphatases were probed immunologically with a library of 18 murine monoclonal antibodies reacting with different conformational epitopes on PLAP. Three main antigenic domains (I, II and III) were mapped by antibody competition experiments and the relative binding of the antibodies to site-directed PLAP mutants. Relative affinities of each of the antibodies for the wild type (wt) GCAP were 2-3-fold lower than the values found for wt PLAP. Relative affinity was determined for a series of PLAP mutants, in which one, two or three amino acids were substituted for the corresponding wt GCAP residues by site-directed mutagenesis. Substitutions at residues 15, 38, 67, 241 or 254 induced a major decrease in affinity (6-10-fold) primarily for those antibodies reacting within domain I, whereas changes at positions 84 and 297 led to a 2-3-fold enhancement of affinities as measured with antibodies reacting within the three domains. Arg209 was found to constitute the only difference between the S and F allelic phenotypes of PLAP and to structure the epitope for the F/S allotype-discriminating antibodies. Arg241 was found to constitute the epitope for the antibody 17E3 that discriminates between PLAP and GCAP. Mutagenesis at position 68 or 133 had little effect on the overall reactivity with the antibody panel. Substitution in wt PLAP of Glu429 for Gly429 or even for His429 (found at this position in tissue-nonspecific alkaline phosphatase) and Ser429 (found in the intestinal alkaline phosphatase) induced a general decrease in affinities as detected by 16 of the 18 antibodies. The conformational change accompanying mutagenesis of Glu429 in PLAP, is important in view of the recent identification of Gly429 as the major determinant of the unique GCAP inhibition by the uncompetitive inhibitor L-Leu. Relative affinity values determined for the rare L-Leu sensitive heterodimeric FD and SD PLAP phenotypes, suggested that the reactivity pattern of the D homodimer with the antibody panel, would resemble more closely that of wt GCAP than wt PLAP. Our data suggest that the uncompetitive inhibition of GCAP by L-Leu is due to an enzymatically critical conformational change in a loop region proximal to the active site of the enzyme, induced by substitution of a single amino acid residue.     

Distribution of Epitopes of Trypanosoma cruzi Amastigotes During the Intracellular Life Cycle within Mammalian Cells

ABSTRACT. In this study we have examined the distribution of epitopes defined by monoclonal antibodies raised against Trypanosoma cruzi amastigotes during the intraceullar life cycle of the parasite. We have raised monoclonal antibodies towards amastigote forms and performed preliminary immunochemical characterization of their reactivities. MAB 1D9, 3G8, 2B7, 3B9, and 4B9, and 4B9 react with carbohydrate epitopes of the parasite major surface glycoprotein—Ssp-4 defined by MAB 2C2 [5]: MAB 4B5 reacts with a noncarbohydrate epitope in all developmental stages of the parasite, and MAB 3B2 also detects a noncarbohydrate epitope preferentially in T. cruzi flagellared forms. Vero cells infected with tissue culture-derived trypomastigotes of clone D11 (G strain) were fixed at different times during the intraceullular proliferation of parasites, and processed for immjno-electron microscopy and confocal immunoflurescence with the different monoclonal antibodies. We observed that while the surface distribution of MAB 2C2 and 4B9 epitopes was uniform throughout the cycle, MAB 1D9, 3G8, and 2B7 reacted with cytoplasmic membrance-bound compartments of the amastigotes. MAB 3B9 displayed a unique surface dentate pattern in some amastigotes. MAB 4B5 recognized a curved-shaped structure at the flagellar pocket region in some intracellular amastigotes and localized to the membrane in dividing forms. In intracellular trypomastigotes, MAB 4B5 also displayed a punctate pattern near the flagellar pocket.     

Identification of two novel B-cell epitopes on the nucleocapsid protein of porcine deltacoronavirus

Highlights
1. Two monoclonal antibodies against newly emerged porcine deltacoronavirus nucleocapsid protein were prepared.
2. The epitopes that these two monoclonal antibodies recognized on nucleocapsid protein were identified.
3. The monoclonal antibody 6B7 recognized a linear epitope of N protein, while the 7F8 recognized a conformational epitope.
4. Conservation of the identified epitopes between different coronaviruses was analyzed.     

Neutralizing human monoclonal antibodies to conformational epitopes of human T-cell lymphotropic virus type 1 and 2 gp46.

Ten human monoclonal antibodies derived from peripheral B cells of a patient with human T-cell lymphotropic virus (HTLV)-associated myelopathy are described. One monoclonal antibody recognized a linear epitope within the carboxy-terminal 43 amino acids of HTLV gp21, and two monoclonal antibodies recognized linear epitopes within HTLV type 1 (HTLV-1) gp46. The remaining seven monoclonal antibodies recognized denaturation-sensitive epitopes within HTLV-1 gp46 that were expressed on the surfaces of infected cells. Two of these antibodies also bound to viable HTLV-2 infected cells and immunoprecipitated HTLV-2 gp46. Virus neutralization was determined by syncytium inhibition assays. Eight monoclonal antibodies, including all seven that recognized denaturation-sensitive epitopes within HTLV-1 gp46, possessed significant virus neutralization activity. By competitive inhibition analysis it was determined that these antibodies recognized at least four distinct conformational epitopes within HTLV-1 gp46. These findings indicate the importance of conformational epitopes within HTLV-1 gp46 in mediating a neutralizing antibody response to HTLV infection.     

Epitope mapping and direct visualization of the parallel, in-register arrangement of the double-stranded coiled-coil in the NuMA protein.

NuMA, a 238 kDa protein present in the nucleus during interphase, translocates to the spindle poles in mitosis. NuMA plays an essential role in mitosis, since microinjection of the NuMA SPN-3 monoclonal antibody causes mitotic arrest and micronuclei formation. We have mapped the approximate position of the epitopes of six monoclonal NuMA antibodies using recombinant NuMA fragments. The SPN-3 epitope has been located to residues 255-267 at the C-terminus of the first helical subdomain of the central rod domain and several residues crucial for antibody binding have been identified. To gain insight into the ultrastructure of NuMA, several defined fragments, as well as the full-length recombinant protein, were expressed in Escherichia coli and purified to homogeneity. They were then characterized by chemical cross-linking, circular dichroism spectra and electron microscopy. The results directly reveal the tripartate structure of NuMA. A long central rod domain is flanked by globular end domains. The rod is 207 nm long and is at least 90% alpha-helical. It reflects a double-stranded coiled-coil with the alpha-helices arranged parallel and in register. The NuMA protein thus forms the longest coiled-coil currently known. Our analyses reveal no indication that recombinant NuMA assembles into filaments or other higher order structures.     

Monoclonal antibody 5A binds apolipoprotein B-48 and inhibits the low density lipoprotein-receptor interaction

In a panel of 10 monoclonal antibodies raised against human LDL we detected three antibodies (named 5A, 6B, and 6E) which recognize both apolipoprotein B-100 and B-48. Antibody 5A inhibited, in a dose dependent manner, the interaction of 125I-LDL with their receptor on human skin fibroblasts. Using thrombolytic fragments, the epitope of antibody 5A was mapped to the carboxy terminal region of apo B-48. MAB 5A was equipotent with MAB Mb 47, an inhibitory antibody whose epitope lies near a putative receptor binding domain of apo B in thrombolytic fragment T2. These findings suggest that areas other than the carboxy terminal portion of apo B-100 may participate in the LDL-receptor interaction, either directly or by determining the exposition of high affinity sites of apo B-100.