Human immunodeficiency virus type 1 envelope glycoprotein oligomerization requires the gp41 amphipathic alpha-helical/leucine zipper-like sequence.

Human immunodeficiency virus type 1 (HIV-1) envelope glycoprotein (Env) oligomerization was investigated by coexpressing wild-type and truncated envelope glycoproteins to determine the minimum sequence required for mutant-wild-type hetero-oligomerization. The gp41 putative amphipathic alpha-helix, Leu-550 to Leu-582, was essential for hetero-oligomer formation. Alanine substitution of 9 of the 10 residues composing the gp41 amphipathic alpha-helix 4-3 hydrophobic repeat sequence was required to inhibit mutant-wild-type hetero-oligomerization and to render the envelope glycoprotein precursor, gp160, monomeric. This indicates that multiple hydrophobic contacts contribute to the stable envelope glycoprotein oligomeric structure. Single alanine substitutions within the hydrophobic repeat sequence did not affect gp160 oligomeric structure but abolished syncytium-forming function. Some mutations also diminished gp160 processing efficiency and the association between gp120 and gp41 in a position-dependent manner. These results indicate that the gp41 amphipathic alpha-helix 4-3 hydrophobic repeat sequence plays a central role in HIV-1 envelope glycoprotein oligomerization and fusion function.     

Determinants of human immunodeficiency virus type 1 envelope glycoprotein oligomeric structure.

Oligomerization of the human immunodeficiency virus type 1 envelope (env) glycoproteins is mediated by the ectodomain of the transmembrane glycoprotein gp41. We report that deletion of gp41 residues 550 to 561 resulted in gp41 sedimenting as a monomer in sucrose gradients, while the gp160 precursor sedimented as a mixture of monomers and oligomers. Deletion of the nearby residues 571 to 582 did not affect the oligomeric structure of gp41 or gp160, but deletion of both sequences resulted in monomeric gp41 and predominantly monomeric gp160. Deletion of residues 655 to 665, adjacent to the membrane-spanning sequence, partially dissociated the gp41 oligomer while not affecting the gp160 oligomeric structure. In contrast, deletion of residues 510 to 518 from the fusogenic hydrophobic N terminus of gp41 did not affect the env glycoprotein oligomeric structure. Even though the mutant gp160 and gp120 molecules were competent to bind CD4, the mutations impaired fusion function, gp41-gp120 association, and gp160 processing. Furthermore, deletion of residues 550 to 561 or 550 to 561 plus 571 to 582 modified the antigenic properties of the proximal residues 586 to 588 and the distal residues 634 to 664. Our results indicate that residues 550 to 561 are essential for maintaining the gp41 oligomeric structure but that this sequence and additional sequences contribute to the maintenance of gp160 oligomers. Residues 550 to 561 map to the N terminus of a putative amphipathic alpha-helix (residues 550 to 582), whereas residues 571 to 582 map to the C terminus of this sequence.     

Kinetic pathway of dTTP hydrolysis by hexameric T7 helicase-primase in the absence of DNA

Bacteriophage T7 gp4A' protein is a hexameric helicase-primase protein that separates the strands of a duplex DNA in a reaction coupled to dTTP hydrolysis. Here we reexamine in more detail the kinetic mechanism of dTTP hydrolysis by a preassembled T7 helicase hexamer in the absence of DNA. Pre-steady state dTTP hydrolysis kinetics showed a distinct burst whose amplitude indicated that a preformed hexamer of T7 helicase hydrolyzes on an average one dTTP per hexamer. The pre-steady state chase-time experiments provided evidence for sequential hydrolysis of two dTTPs. The medium [(18)O]P(i) exchange experiments failed to detect dTTP synthesis, indicating that the less than six-site hydrolysis observed is not due to reversible dTTP hydrolysis on the helicase active site. The P(i)-release rate was measured directly using a stopped-flow fluorescence assay, and it was found that the rate of dTTP hydrolysis on the helicase active site is eight times faster than the P(i)-release rate, which in turn is three times faster than the dTDP release rate. Thus, the rate-limiting step in the pathway of helicase-catalyzed deoxythymidine triphosphatase (dTTPase) reaction is the release of dTDP. Chase-time dTTPase kinetics in the steady state phase provided evidence for two to three slowly hydrolyzing dTTPase sites on the hexamer. The results of this study are therefore consistent with those reported earlier (Hingorani, M. M., Washington, M. T., Moore, K. C., and Patel, S. S. (1997) Proc. Natl. Acad. Sci. U.S.A. 94, 5012-5017), and they support a model of dTTP hydrolysis by T7 helicase hexamer that is similar to the binding change mechanism of F(1)-ATPase with dTTP hydrolysis occurring sequentially at the catalytic sites.     

Thermal dissociation and unfolding of insulin

The thermal stability of human insulin was studied by differential scanning microcalorimetry and near-UV circular dichroism as a function of zinc/protein ratio, to elucidate the dissociation and unfolding processes of insulin in different association states. Zinc-free insulin, which is primarily dimeric at room temperature, unfolded at approximately 70 degrees C. The two monomeric insulin mutants Asp(B28) and Asp(B9),Glu(B27) unfolded at higher temperatures, but with enthalpies of unfolding that were approximately 30% smaller. Small amounts of zinc caused a biphasic thermal denaturation pattern of insulin. The biphasic denaturation is caused by a redistribution of zinc ions during the heating process and results in two distinct transitions with T(m)'s of approximately 70 and approximately 87 degrees C corresponding to monomer/dimer and hexamer, respectively. At high zinc concentrations (>or=5 Zn(2+) ions/hexamer), only the hexamer transition is observed. The results of this study show that the thermal stability of insulin is closely linked to the association state and that the zinc hexamer remains stable at much higher temperatures than the monomer. This is in contrast to studies with chemical denaturants where it has been shown that monomer unfolding takes place at much higher denaturant concentrations than the dissociation of higher oligomers [Ahmad, A., et al. (2004) J. Biol. Chem. 279, 14999-15013].     

Isolation and characterization of a molecular chaperone, gp57A, of bacteriophage T4.

A molecular chaperone of bacteriophage T4, gp57A, which facilitates the formation of the long and short tail fibers, was isolated and characterized by peptide analysis, sedimentation equilibrium, and circular dichroism (CD). Sequence analysis confirmed the predicted sequence of 79 amino acids from the nucleotide sequence of the gene with the N-terminal methionine removed. The result led to the conclusion that the apparent smaller molecular weight of 6,000 from Tricine-sodium dodecyl sulfate-polyacrylamide gel electrophoresis than the expected molecular weight of 8,710 was due to its abnormal electrophoretic behavior instead of cleavage or processing of the gene product. Estimation of the secondary structure from far-UV CD indicated a 94% alpha-helix content, which was in accord with the prediction from the primary structure. A sedimentation equilibrium study, on the other hand, revealed that gp57A assumes a tetrameric subunit structure.     

Expression and characterization of a baseplate protein for bacteriophage Mu, gp44

The gene product of gene 44 of Mu phage (gp44) is an essential protein for baseplate assembly and has been designated as gpP, a traditional genetic assignment. The function of gp44 during the assembly or infection process is not known. In the present study, we purified the recombinant gp44 and characterized it by analytical ultracentrifugation and differential scanning microcalorimetry. The results indicate that gp44 forms a trimer comprising a complex consisting of the 42 kDa and 40 kDa subunits that had been cleaved in the C-terminal region. Thermodynamic analysis also suggested that the C-terminal region forms a flexible domain.     

Folding, assembly, and intracellular trafficking of the human immunodeficiency virus type 1 envelope glycoprotein analyzed with monoclonal antibodies recognizing maturational intermediates.

Monoclonal antibodies (MAbs) that bind linear or conformational epitopes on monomeric or oligomeric human immunodeficiency virus type 1 (HIV-1) envelope glycoproteins were screened for their recognition of maturational intermediates. On the basis of reactivities with gp160 at different times after pulse-labeling, the MAbs were sorted into groups that exhibited binding which was immediate and constant, immediate but transient, delayed, late, or very late. This grouping was consistent with the selectivity of the MAbs for structural features of gp160. Thus, a MAb to the V3 loop reacted with envelope proteins at all times, in accord with the relative conformational independence and accessibility of the epitope. Several MAbs that preferentially react with monomeric gp160 exhibited diminished binding after the pulse. A 10-min tag occurred before gp160 reacted with conformational MAbs that inhibited CD4 binding. The availability of epitopes for other conformational MAbs, including some that react equally with monomeric and oligomeric gp160 and some that react better with oligomeric forms, was half-maximal in 30 min and closely followed the kinetics of gp160 oligomerization. Remarkably, there was a 1- to 2-h delay before gp160 reacted with stringent oligomer-specific MAbs. After 4 h, approximately 20% of the gp160 was recognized by these MAbs. Epitopes recognized by monomerspecific or CD4-blocking MAbs but not by oligomer-dependent MAbs were present on gp160 molecules associated with the molecular chaperone BiP/GRP78. MAbs with a preference for monomers reacted with recombinant or HIV-1 envelope proteins in the endoplasmic reticulum, whereas the oligomer-specific MAbs recognized them in the Golgi complex. Additional information regarding gp160 maturation and intracellular trafficking was obtained by using brefeldin A, dithiothreitol, and a low temperature.     

Probing the stability and mechanism for folding of the GrpE1-112 tetrameric deletion mutant of the GrpE protein from E. coli

Insight into the stability and folding of oligomeric proteins is essential to the understanding of protein folding, especially since the majority of proteins found in nature are oligomeric. A deletion mutant of the GrpE protein from Escherichia coli, that contains the first 112 residues (GrpE1-112) of 197 total, is an oligomeric protein forming a tetrameric structure. A four-helix bundle structure is formed via the interaction of an α-helix (22 amino acids in length) from each monomer. Using both thermal and chemical (urea) denaturation studies, the GrpE1-112 protein has rather low stability with a T(m) of unfolding of 37 °C, a C(m) (urea) of 1.3M, and a ΔG(unfolding) of 8.4 kJ mol(-1). Investigation into the folding pathway using circular dichroism (CD) stopped-flow revealed a two step process with a fast first phase (k(refolding)=8.0 × 10(6)s(-1)M(-1)) forming a multimeric intermediate that possesses significant α-helical content followed by a slow, first order, step forming the folded tetramer.     

DNA binding in the central channel of bacteriophage T7 helicase-primase is a multistep process. Nucleotide hydrolysis is not required

Many helicases assemble into ring-shaped hexamers and bind DNA in their central channel. This raises the question as to how the DNA gets into the central channel to form a topologically linked complex. We have used the presteady-state stopped-flow kinetic method and protein fluorescence changes to investigate the mechanism of single-stranded DNA (ssDNA) binding to the bacteriophage T7 helicase-primase, gp4A'. We have found that the kinetics of 30-mer ssDNA binding to a preformed gp4A' hexamer in the presence of both Mg-dTMP-PCP and Mg-dTTP are similar, indicating that Mg-dTTP binding is sufficient and hydrolysis is not necessary for efficient DNA binding. Multiple transient changes in gp4A' fluorescence revealed a four-step mechanism for DNA binding with Mg-dTTP. These transient changes were analyzed by global fitting and kinetic simulation to determine the intrinsic rate constants of this four-step mechanism. The initial steps, including the bimolecular encounter of the DNA with the helicase and a subsequent conformational change, were fast. We propose that these initial steps of DNA binding occur at a readily accessible site, which is likely to be on the outside of the hexamer ring. The binding of the 30-mer ssDNA at this loading site is followed by slower conformational changes that allow the DNA to transit into the central channel of gp4A' via a ring-opening or threading pathway.     

Effect of oligomerization on the properties of essential SH-groups of mitochondrial creatine kinase

The properties of creatine kinase isolated from bovine heart mitochondria in dimeric (Mr = 84 +/- 6 kD) and octameric (Mr = 340 +/- 17 kD) forms were compared with those of the earlier described hexameric form of the enzyme (Mr = 240 +/- 12 kD). The kinetics of SH-group modification by DTNB, the inactivation kinetics as well as the number of modified SH-groups point to significant differences between the three oligomeric forms of the enzyme. Each subunit of creatine kinase was found to possess one "fast" essential cysteine residue whose modification by DTNB and iodoacetamide led to enzyme inactivation. The formation of an analog of the transition state complex (E--MgADP--NO3--creatine) was paralleled with partial protection of only the "fast" cysteine residue which manifested itself in the decrease of the rate of its interaction with DTNB in all the three oligomeric forms. Dimer association into a hexamer and octamer occurred in parallel with a decrease of the affinity of essential SH-groups of cysteine for DTNB in 50% of the oligomeric molecule subunits. Thus, in the dimer two essential SH-groups were rapidly modified by DTNB at the same rate: k1 = k2 = (23.9 +/- 5.6).10(4) M-1 min-1. Within the hexamer, the rate of modification of 3 out of 6 SH-groups was practically unchanged: k1 = (10.6 +/- 2.3).10(4) M-1 min-1. Another 3 SH-groups in the remaining 50% of the subunits were partly masked, which manifested itself in a 10-fold decrease of their modification rate: k2 = (1.12 +/- 0.28).10(4) M-1 min-1. Within the octamer, the SH-groups rapidly interacted with DTNB only on 4 subunits: k1 = (20.7 +/- 2.2).10(4) M-1 min-1, whereas in the remaining 4 octamer subunits a practically complete masking of essential SH-groups was observed, as a result of which these groups became inaccessible to DTNB. This manifested itself in a 1000-fold decrease of the rate of SH-group modification by DTNB which reached that of non-essential SH-group modification. In has been found that a complete loss of the octamer activity is due to the modification of only 4 SH-groups which interact with DTNB at a high rate. A model for subunit association into a dimer, hexamer and octamer has been proposed. Presumably, 50% of the active centers in the mitochondrial creatine kinase octamer are not involved in the catalytic act.     

Assembly pathway of an AAA+ protein: tracking ClpA and ClpAP complex formation in real time

The ClpAP chaperone-protease complex is active as a cylindrically shaped oligomeric complex built of the proteolytic ClpP double ring as the core of the complex and two ClpA hexamers associating with the ends of the core cylinder. The ClpA chaperone belongs to the larger family of AAA+ ATPases and is responsible for preparing protein substrates for degradation by ClpP. Here, we study in real time using fluorescence and light scattering stopped-flow methods the complete assembly pathway of this bacterial chaperone-protease complex consisting of ATP-induced ClpA hexamer formation and the subsequent association of ClpA hexamers with the ClpP core cylinder. We provide evidence that ClpA assembles into hexamers via a tetrameric intermediate and that hexamerization coincides with the appearance of ATPase activity. While ATP-induced oligomerization of ClpA is a prerequisite for binding of ClpA to ClpP, the kinetics of ClpA hexamer formation are not influenced by the presence of ClpP. Models for ClpA hexamerization and ClpA-ClpP association are presented along with rate parameters obtained from numerical fitting procedures. The hexamerization kinetics show that the tetrameric intermediate transiently accumulates, forming rapidly at early time points and then decaying at a slower rate to generate the hexamer. The association of assembled ClpA hexamers with the ClpP core cylinder displays cooperativity, supporting the coexistence of interchanging ClpP conformations with different affinities for ClpA.     

A conformational switch is associated with receptor affinity in peptides derived from the CD4-binding domain of gp120 from HIV I

A 15-residue region within the CD4-binding domain of gp120 from HIV I was identified with use of folding algorithms as conserving the potential for forming a particular secondary structure throughout 11 sequenced HIV strains. The region chosen has a potential for forming both beta-sheet and alpha-helix; the helical form would be amphipathic with the five hydrophobic residues all totally or functionally conserved. Five peptides were synthesized corresponding to this region in strain LAV and the strain most highly divergent from it in primary structure (Z3) plus three additional peptides with critical substitutions in the LAV sequence. The conformation of these five peptides was examined under various conditions with circular dichroism, and the results were compared with the ability of each peptide to bind to a CD4-expressing strain of HeLa cells (HeLa T4). In solution, the unmodified peptides exhibit a bistable structure, existing as beta-sheet in dilute buffer and converting to alpha-helix under more apolar conditions. The transition is reversible and sharp, occurring at a particular point in the polar/apolar gradient with virtually no intermediate state. The ability to undergo this bistable flip is closely associated with binding ability, amino acid substitutions that eliminate binding ability also eliminating the switch, and vice versa. The transition thus may reflect conformational changes occurring in this region of gp120 as it binds to the CD4 receptor.     

Generation of specific Th1 and CD8+ T-cell responses by immunization with mouse CD8+ dendritic cells loaded with HIV-1 viral lysate or envelope glycoproteins

Immunization with antigen-pulsed dendritic cells (DCs) can be used to elicit optimal immune responses. We developed the SRDC cell line, with a morphology, phenotype and activity similar to mouse splenic CD4(-)CD8alpha(+)CD205(+)CD11b(-) dendritic cells, which induce a polarized Th1 immune response. We evaluated the ability of SRDCs pulsed with HIV-1 viral lysate, oligomeric soluble gp140 or capsid p24 to induce specific antibody and T-cell responses in CBA/J mice. Immunization with all loaded SRDCs elicited antibody responses against the antigens tested. However, only HIV-1 viral lysate and gp140-pulsed SRDCs elicited specific CD4(+) and CD8(+) T-cell responses. These findings demonstrate the value of well characterized DC lines for optimizing the antigen-loading mixture, according to the DC population targeted. Our data suggest that splenic DCs pulsed with complex antigens, such as HIV-1 viral lysate or oligomeric soluble gp140, could be used as vaccines, eliciting strong primary Th1-polarized and humoral immune responses against HIV proteins in vivo.     

Molecular architecture of E. coli purine nucleoside phosphorylase studied by analytical ultracentrifugation and CD spectroscopy

Purine nucleoside phosphorylase (PNP) is a key enzyme of the nucleoside salvage pathway and is characterized by complex kinetics. It was suggested that this is due to coexistence of various oligomeric forms that differ in specific activity. In this work, the molecular architecture of Escherichia coli PNP in solution was studied by analytical ultracentrifugation and CD spectroscopy. Sedimentation equilibrium analysis revealed a homohexameric molecule with molecular mass 150+/-10 kDa, regardless of the conditions investigated-protein concentration, 0.18-1.7 mg/mL; presence of up to 10 mM phosphate and up to 100 mM KCl; temperature, 4-20 degrees C. The parameters obtained from the self-associating model also describe the hexameric form. Sedimentation velocity experiments conducted for broad protein concentration range (1 microg/mL-1.3 mg/mL) with boundary (classical) and band (active enzyme) approaches gave s(0)20,w=7.7+/-0.3 and 8.3+/-0.4 S, respectively. The molecular mass of the sedimenting particle (146+/-30 kDa), calculated using the Svedberg equation, corresponds to the mass of the hexamer. Relative values of the CD signal at 220 nm and the catalytic activity of PNP as a function of GdnHCl concentration were found to be correlated. The transition from the native state to the random coil is a single-step process. The sedimentation coefficient determined at 1 M GdnHCl (at which the enzyme is still fully active) is 7.7 S, showing that also under these conditions the hexamer is the only catalytically active form. Hence, in solution similar to the crystal, E. coli PNP is a hexameric molecule and previous suggestions for coexistence of two oligomeric forms are incorrect.     

Oligomeric and conformational properties of a proteolytically mature,disulfide-stabilized human immunodeficiency virus type 1 gp140 envelope glycoprotein

We describe the further properties of a protein, designated SOS gp140, wherein the association of the gp120 and gp41 subunits of the human immunodeficiency virus type 1 (HIV-1) envelope glycoprotein is stabilized by an intersubunit disulfide bond. HIV-1(JR-FL) SOS gp140, proteolytically uncleaved gp140 (gp140(UNC)), and gp120 were expressed in stably transfected Chinese hamster ovary cells and analyzed for antigenic and structural properties before and after purification. Compared with gp140(UNC), SOS gp140 reacted more strongly in surface plasmon resonance and radioimmunoprecipitation assays with the neutralizing monoclonal antibodies (MAbs) 2G12 (anti-gp120), 2F5 (anti-gp41), and 17b (to a CD4-induced epitope that overlaps the CCR5-binding site). In contrast, gp140(UNC) displayed the greater reactivity with nonneutralizing anti-gp120 and anti-gp41 MAbs. Immunoelectron microscopy studies suggested a model for SOS gp140 wherein the gp41 ectodomain (gp41(ECTO)) occludes the "nonneutralizing" face of gp120, consistent with the antigenic properties of this protein. We also report the application of Blue Native polyacrylamide gel electrophoresis (BN-PAGE), a high-resolution molecular sizing method, to the study of viral envelope proteins. BN-PAGE and other biophysical studies demonstrated that SOS gp140 was monomeric, whereas gp140(UNC) comprised a mixture of noncovalently associated and disulfide-linked dimers, trimers, and tetramers. The oligomeric and conformational properties of SOS gp140 and gp140(UNC) were largely unaffected by purification. An uncleaved gp140 protein containing the SOS cysteine mutations (SOS gp140(UNC)) was also oligomeric. Surprisingly, variable-loop-deleted SOS gp140 proteins were expressed (although not yet purified) as cleaved, noncovalently associated oligomers that were significantly more stable than the full-length protein. Overall, our findings have relevance for rational vaccine design.     

Fine mapping of the interaction of neutralizing and nonneutralizing monoclonal antibodies with the CD4 binding site of human immunodeficiency virus type 1 gp120

Alanine scanning mutagenesis was performed on monomeric gp120 of human immunodeficiency virus type 1 to systematically identify residues important for gp120 recognition by neutralizing and nonneutralizing monoclonal antibodies (MAbs) to the CD4 binding site (CD4bs). Substitutions that affected the binding of broadly neutralizing antibody b12 were compared to substitutions that affected the binding of CD4 and of two nonneutralizing anti-CD4bs antibodies (b3 and b6) with affinities for monomeric gp120 comparable to that of b12. Not surprisingly, the sensitivities to a number of amino acid changes were similar for the MAbs and for CD4. However, in contrast to what was seen for the MAbs, no enhancing mutations were observed for CD4, suggesting that the virus has evolved toward an optimal gp120-CD4 interaction. Although the epitope maps of the MAbs overlapped, a number of key differences between b12 and the other two antibodies were observed. These differences may explain why b12, in contrast to nonneutralizing antibodies, is able to interact not only with monomeric gp120 but also with functional oligomeric gp120 at the virion surface. Neutralization assays performed with pseudovirions bearing envelopes from a selection of alanine mutants mostly showed a reasonable correlation between the effects of the mutations on b12 binding to monomeric gp120 and neutralization efficacy. However, some mutations produced an effect on b12 neutralization counter to that predicted from gp120 binding data. It appears that these mutations have different effects on the b12 epitope on monomeric gp120 and functional oligomeric gp120. To determine whether monomeric gp120 can be engineered to preferentially bind MAb b12, recombinant gp120s were generated containing combinations of alanine substitutions shown to uniquely enhance b12 binding. Whereas b12 binding was maintained or increased, binding by five nonneutralizing anti-CD4bs MAbs (b3, b6, F105, 15e, and F91) was reduced or completely abolished. These reengineered gp120s are prospective immunogens that may prove capable of eliciting broadly neutralizing antibodies.     

A thermally induced phase transition in a viral capsid transforms the hexamers, leaving the pentamers unchanged

Scanning calorimetry combined with cryo-electron microscopy affords a powerful approach to investigating hierarchical interactions in multi-protein complexes. Calorimetry can detect the temperatures at which certain interactions are disrupted and cryo-EM can reveal the accompanying structural changes. The procapsid of bacteriophage HK97 (Prohead I) is a 450A-diameter shell composed of 60 hexamers and 12 pentamers of gp5, organized with icosahedral symmetry. Gp5 consists of the N-terminal Delta-domain (11kDa) and gp5* (31 kDa): gp5* forms the contiguous shell from which clusters of Delta-domains extend inwards. At neutral pH, Prohead I exhibits an endothermic transition at 53 degrees C with an enthalpy change of 14 kcal/mole (of gp5 monomer). We show that this transition is reversible. To capture its structural expression, we incubated Prohead I at 60 degrees C followed by rapid freezing and, by cryo-EM, observed a capsid species 10% larger than Prohead I. At 11A resolution, visible changes are confined to the gp5 hexamers. Their Delta-domain clusters have disappeared and are presumably disordered, either by unfolding or dispersal. The gp5* hexamer rings are thinned and flattened as they assume the conformation observed in Expansion Intermediate I, a transition state of the normal, proteolysis-induced, maturation pathway. We infer that, at ambient temperatures, the hexamer Delta-domains restrain their gp5* rings from switching to a lower free energy, EI-I-like, state; above 53 degrees, this restraint is overcome. Pentamers, on the other hand, are more stably anchored and resist this thermal perturbation.     

Humoral response to oligomeric human immunodeficiency virus type 1 envelope protein.

The humoral immune response to human immunodeficiency virus type 1 (HIV-1) is often studied by using monomeric or denatured envelope proteins (Env). However, native HIV-1 Env complexes that maintain quaternary structure elicit immune responses that are qualitatively distinct from those seen with monomeric or denatured Env. To more accurately assess the levels and types of antibodies elicited by HIV-1 infection, we developed an antigen capture enzyme-linked immunosorbent assay using a soluble, oligomeric form of HIV-1IIIB Env (gp140) that contains gp120 and the gp41 ectodomain. The gp140, captured by various monoclonal antibodies (MAbs), retained its native oligomeric structure: it bound CD4 and was recognized by MAbs to conformational epitopes in gp120 and gp41, including oligomer-specific epitopes in gp41. We compared the reactivities of clade B and clade E serum samples to captured Env preparations and found that while both reacted equally well with oligomeric gp140, clade B seras reacted more strongly with monomeric gp120 than did clade E samples. However, these differences were minimized when gp120 was captured by a V3 loop MAb, which may lead to increased exposure of the CD4 binding site. We also measured the ability of serum samples to block binding of MAbs to epitopes in gp120 and gp41. Clade B serum samples consistently blocked binding of oligomer-dependent MAbs to gp41 and, to a slightly lesser extent, MAbs to the CD4 binding site in gp120. Clade E serum samples showed equivalent or greater blocking of oligomer-dependent gp41 antibodies and considerably less blocking of CD4-binding-site MAbs. Finally, we found that < 5% of the antibodies in clade B sera bound to epitopes present only in monomeric gp120, 30% bound to epitopes present in both monomeric gp120 and oligomeric gp140, and 70% bound to epitopes present in oligomeric gp140, which includes gp41. Thus, captured oligomeric Env closely reflects the antigenic characteristics of Env protein on the surface of virions and infected cells, retains highly conserved epitopes that are recognized by antibodies raised against different clades, and makes it possible to detect a much greater fraction of total anti-HIV-1 Env activity in sera than does native monomeric gp120.     

Effect of subunit dissociation, denaturation, aggregation, coagulation, and decomposition on enzyme inactivation kinetics: II. Biphasic and grace period behavior

A model previously developed to characterize enzymatic in activation behavior was used to explain the non-first-order biphasic and grace period phenomena that are often observed with oligomeric enzymes. Luciferase and urease were used as model enzyme such as luciferase, the oligomer initially dissociates reversibly into two native monomer species. These native monomers can then reversibly denature and irreversibly aggregate and coagulate. With the hexamer, urease, two trimers are formed that can subsequently aggregate to form an inactive hexamer. The dissociated monomer species of luciferase do not possess catalytic activity, so the inactivation mechanism, is biphasic; the first slope of a first-order kinetic plot is influenced by the reversible oligomer/monomer/denatured-monomer transition. Whereas the second slope is associated with either irreversible aggregation or coagulation. In contrast, the trimer of urease has the same activity as the hexamer; therefore, during the intitial hexamer-trimer transition, little activity loss occurs. However, as the trimer concentration increases, activity decreases as a result of trimer aggregation. As a result, grace period inactivation behavior is observed. (c) 1992 John Wiley & Sons, Inc.     

Autoantigen glycoprotein 70 expression is regulated by a single locus, which acts as a checkpoint for pathogenic anti-glycoprotein 70 autoantibody production and hence for the corresponding development of severe nephritis, in lupus-prone PXSB mice

Retroviral envelope glycoprotein gp70 is present in the sera of immunologically normal and autoimmune-prone strains of mice. However, only lupus-prone mice spontaneously develop gp70-anti-gp70 immune complexes (gp70IC), and these have been implicated in the development of nephritis. We investigated the genetic factors that affect the production of both free serum gp70 and gp70IC in the lupus-prone BXSB mouse strain by analyzing (BXSB x (C57BL/10 x BXSB)F(1))- and (C57BL/10 x (C57BL/10 x BXSB)F(1))-backcrossed male mice. Production of gp70 mapped to a single major locus located on chromosome 13 (Bxs6) with a maximum log likelihood of the odds of 36.7 (p = 1.6 x 10(-38)). The level of gp70IC was highly dependent on Bxs6-related gp70 production, and high titer autoantibody production only occurred when serum gp70 levels were greater than a threshold value of approximately 4.0 microg/ml. The subdivision of the (BXSB x (C57BL/10 x BXSB)F(1))-backcrossed mice into those homozygous or heterozygous for Bxs6 enabled a remarkable association to be observed between high levels of gp70IC and severe nephritis in the Bxs6 homozygote population. A further mapping study in these two subgroups identified a previously unrecognized interval associated with the production of autoantibodies.