The N-terminal domain of the murine coronavirus spike glycoprotein determines the CEACAM1 receptor specificity of the virus strain

Using isogenic recombinant murine coronaviruses expressing wild-type murine hepatitis virus strain 4 (MHV-4) or MHV-A59 spike glycoproteins or chimeric MHV-4/MHV-A59 spike glycoproteins, we have demonstrated the biological functionality of the N-terminus of the spike, encompassing the receptor binding domain (RBD). We have used two assays, one an in vitro liposome binding assay and the other a tissue culture replication assay. The liposome binding assay shows that interaction of the receptor with spikes on virions at 37 degrees C causes a conformational change that makes the virions hydrophobic so that they bind to liposomes (B. D. Zelus, J. H. Schickli, D. M. Blau, S. R. Weiss, and K. V. Holmes, J. Virol. 77: 830-840, 2003). Recombinant viruses with spikes containing the RBD of either MHV-A59 or MHV-4 readily associated with liposomes at 37 degrees C in the presence of soluble mCEACAM1(a), except for S(4)R, which expresses the entire wild-type MHV-4 spike and associated only inefficiently with liposomes following incubation with soluble mCEACAM1(a). In contrast, soluble mCEACAM1(b) allowed viruses with the MHV-A59 RBD to associate with liposomes more efficiently than did viruses with the MHV-4 RBD. In the second assay, which requires virus entry and replication, all recombinant viruses replicated efficiently in BHK cells expressing mCEACAM1(a). In BHK cells expressing mCEACAM1(b), only viruses expressing chimeric spikes with the MHV-A59 RBD could replicate, while replication of viruses expressing chimeric spikes with the MHV-4 RBD was undetectable. Despite having the MHV-4 RBD, S(4)R replicated in BHK cells expressing mCEACAM1(b); this is most probably due to spread via CEACAM1 receptor-independent cell-to-cell fusion, an activity displayed only by S(4)R among the recombinant viruses studied here. These data suggest that the RBD domain and the rest of the spike must coevolve to optimize function in viral entry and spread.     

Receptor-induced conformational changes of murine coronavirus spike protein

Although murine coronavirus mouse hepatitis virus (MHV) enters cells by virus-cell membrane fusion triggered by its spike (S) protein, it is not well known how the S protein participates in fusion events. We reported that the soluble form of MHV receptor (soMHVR) transformed a nonfusogenic S protein into a fusogenic one (F. Taguchi and S. Matsuyama, J. Virol. 76:950-958, 2002). In the present study, we demonstrate that soMHVR induces the conformational changes of the S protein, as shown by the proteinase digestion test. A cl-2 mutant, srr7, of the MHV JHM virus (JHMV) was digested with proteinase K after treatment with soMHVR, and the resultant S protein was analyzed by Western blotting using monoclonal antibody (MAb) 10G, specific for the membrane-anchored S2 subunit. A 58-kDa fragment, encompassing the two heptad repeats in S2, was detected when srr7 was digested after soMHVR treatment, while no band was seen when the virus was untreated. The appearance of the proteinase-resistant fragment was dependent on the temperature and time of srr7 incubation with soMHVR and also on the concentration of soMHVR. Coimmunoprecipitation indicated that the direct binding of soMHVR to srr7 S protein induced these conformational changes; this was also suggested by the inhibition of the changes following pretreatment of soMHVR with anti-MHVR MAb CC1. soMHVR induced conformational changes of the S proteins of wild-type (wt) JHMV cl-2, as well as revertants from srr7, srr7A and srr7B; however, a major proportion of these S proteins were resistant to proteinase K even without soMHVR treatment. The implications of this proteinase-resistant fraction are discussed. This is the first report on receptor-induced conformational changes of the membrane-anchored fragment of the coronavirus S protein.     

The CEACAM1 N-terminal Ig domain mediates cis- and trans-binding and is essential for allosteric rearrangements of CEACAM1 microclusters

Cell adhesion molecules (CAMs) sense the extracellular microenvironment and transmit signals to the intracellular compartment. In this investigation, we addressed the mechanism of signal generation by ectodomains of single-pass transmembrane homophilic CAMs. We analyzed the structure and homophilic interactions of carcinoembryonic antigen (CEA)–related CAM 1 (CEACAM1), which regulates cell proliferation, apoptosis, motility, morphogenesis, and microbial responses. Soluble and membrane-attached CEACAM1 ectodomains were investigated by surface plasmon resonance–based biosensor analysis, molecular electron tomography, and chemical cross-linking. The CEACAM1 ectodomain, which is composed of four glycosylated immunoglobulin-like (Ig) domains, is highly flexible and participates in both antiparallel (trans) and parallel (cis) homophilic binding. Membrane-attached CEACAM1 ectodomains form microclusters in which all four Ig domains participate. Trans-binding between the N-terminal Ig domains increases formation of CEACAM1 cis-dimers and changes CEACAM1 interactions within the microclusters. These data suggest that CEACAM1 transmembrane signaling is initiated by adhesion-regulated changes of cis-interactions that are transmitted to the inner phase of the plasma membrane.     

结构域B在鼠冠状病毒S蛋白的抗原性及膜融合中的作用

棘突(spike, S)蛋白是冠状病毒表面必不可少的跨膜糖蛋白,在病毒进入宿主细胞时具有结合受体和诱导膜融合的双重作用。大部分冠状病毒S蛋白的受体结合域位于S1-CTD(即相对应的结构域B),而经典的乙型冠状病毒模型鼠肝炎病毒(mouse hepatitis virus, MHV)的受体mCEACAM1a与S1-NTD(即相对应的结构域A)结合,其结构域B的作用仍未完全清楚。本研究通过构建结构域B和S2膜融合元件的缺失突变体,并使其在鼠神经母细胞瘤细胞系Neuro-2a内成功表达,证实了结构域B对病毒S蛋白导致的细胞-细胞间膜融合是必需的。用不同方法处理的病毒颗粒作为抗原免疫小鼠,所获得的多克隆抗体进一步显示,结构域B不但是S蛋白的主要抗原决定簇,而且能诱导中和抗体明显抑制病毒感染和S蛋白介导的膜融合作用。此结果为阐述不同冠状病毒的致病性与感染性差异提供了新思路。     

The S2 subunit of the murine coronavirus spike protein is not involved in receptor binding.

The receptor-binding capacity of the S2 subunit of the murine coronavirus S protein was examined by testing the inhibition of virus-receptor binding. Sp-4 virus and S1N(330), which consists of the N-terminal 330 amino acids of the S1 protein, both of which exhibited receptor-binding capacity, were able to prevent the binding of cl-2 virus to the receptor, while the mutant protein S1N(330)-159, which failed to bind to the receptor protein, and S2TM-, which lacks the transmembrane and cytoplasmic domains normally existing in the S2, were unable to prevent the binding of cl-2. By using cultured DBT cells, it was revealed that the infection of cells by cl-2 virus was significantly inhibited by S1N(330) but not by S2TM-. These results indicate that the S2 protein is not involved in the receptor binding of murine coronaviruses.     

Conformational changes in the spike glycoprotein of murine coronavirus are induced at 37 degrees C either by soluble murine CEACAM1 receptors or by pH 8

The spike glycoprotein (S) of the murine coronavirus mouse hepatitis virus (MHV) binds to viral murine CEACAM receptor glycoproteins and causes membrane fusion. On virions, the 180-kDa S glycoprotein of the MHV-A59 strain can be cleaved by trypsin to form the 90-kDa N-terminal receptor-binding subunit (S1) and the 90-kDa membrane-anchored fusion subunit (S2). Incubation of virions with purified, soluble CEACAM1a receptor proteins at 37 degrees C and pH 6.5 neutralizes virus infectivity (B. D. Zelus, D. R. Wessner, R. K. Williams, M. N. Pensiero, F. T. Phibbs, M. deSouza, G. S. Dveksler, and K. V. Holmes, J. Virol. 72:7237-7244, 1998). We used liposome flotation and protease sensitivity assays to investigate the mechanism of receptor-induced, temperature-dependent virus neutralization. After incubation with soluble receptor at 37 degrees C and pH 6.5, virions became hydrophobic and bound to liposomes. Receptor binding induced a profound, apparently irreversible conformational change in S on the viral envelope that allowed S2, but not S1, to be degraded by trypsin at 4 degrees C. Various murine CEACAM proteins triggered conformational changes in S on recombinant MHV strains expressing S glycoproteins of MHV-A59 or MHV-4 (MHV-JHM) with the same specificities as seen for virus neutralization and virus-receptor activities. Increased hydrophobicity of virions and conformational change in S2 of MHV-A59 could also be induced by incubating virions at pH 8 and 37 degrees C, without soluble receptor. Surprisingly, the S protein of recombinant MHV-A59 virions with a mutation, H716D, that precluded cleavage between S1 and S2 could also be triggered to undergo a conformational change at 37 degrees C by soluble receptor at neutral pH or by pH 8 alone. A novel 120-kDa subunit was formed following incubation of the receptor-triggered S(A59)H716D virions with trypsin at 4 degrees C. The data show that unlike class 1 fusion glycoproteins of other enveloped viruses, the murine coronavirus S protein can be triggered to a membrane-binding conformation at 37 degrees C either by soluble receptor at neutral pH or by alkaline pH alone, without requiring previous activation by cleavage between S1 and S2.     

Identification of spike protein residues of murine coronavirus responsible for receptor-binding activity by use of soluble receptor-resistant mutants.

We previously demonstrated by site-directed mutagenesis analysis that the amino acid residues at positions 62 and 214 to 216 in the N-terminal region of mouse hepatitis virus (MHV) spike (S) protein are important for receptor-binding activity (H. Suzuki and F. Taguchi, J. Virol. 70:2632-2636, 1996). To further identify the residues responsible for the activity, we isolated the mutant viruses that were not neutralized with the soluble form of MHV receptor proteins, since such mutants were expected to have mutations in amino acids responsible for receptor-binding activity. Five soluble-receptor-resistant (srr) mutants isolated had mutations in a single amino acid at three different positions: one was at position 65 (Leu to His) (srr11) in the S1 subunit and three were at position 1114 (Leu to Phe) (srr3, srr4, and srr7) and one was at position 1163 (Cys to Phe) (srr18) in the S2 subunit. The receptor-binding activity examined by a virus overlay protein blot assay and by a coimmunoprecipitation assay showed that srr11 S protein had extremely reduced binding activity, while the srr7 and srr18 proteins had binding activity similar to that of wild-type cl-2 protein. However, when cell surface receptors were used for the binding assay, all srr mutants showed activity similar to that of the wild type or only slightly reduced activity. These results, together with our previous observations, suggest that amino acids located at positions 62 to 65 of S1, a region conserved among the MHV strains examined, are important for receptor-binding activity. We also discuss the mechanism by which srr mutants with a mutation in S2 showed high resistance to neutralization by a soluble receptor, despite their sufficient level of binding to soluble receptors.     

Analysis of the receptor-binding site of murine coronavirus spike protein.

It has been found that a domain composed of 330 amino acids of the N terminus of murine coronavirus spike protein [S1N(330)] is involved in receptor-binding activity (H. Kubo, Y.K. Yamada, and F. Taguchi, J. Virol. 68:5403-5410, 1994). To delineate the amino acid sequences involved in receptor-binding activity, we have compared the S1N(330) proteins of seven different mouse hepatitis virus MHV strains that are able to utilize the MHV receptor protein. Three conserved regions (sites I, II, and III) were found to consist of more than 10 identical amino acids, and they were analyzed for receptor-binding activity by site-directed mutagenesis. S1N(330) with a substitution at position 62 from the N terminus of S1 in region I and that with substitutions at positions 212, 214, and 216 in region II showed no receptor-binding activity. The S1N(330) mutants without receptor-binding activity were not able to prevent virus binding to the receptor. These results suggest that the receptor-binding site on S1N(330) is composed of regions located apart from each other in the protein's primary structure, in which Thr at position 62 as well as amino acids located at positions 212, 214, and 216 are particularly important.     

Assembly of spikes into coronavirus particles is mediated by the carboxy-terminal domain of the spike protein

The type I glycoprotein S of coronavirus, trimers of which constitute the typical viral spikes, is assembled into virions through noncovalent interactions with the M protein. Here we demonstrate that incorporation is mediated by the short carboxy-terminal segment comprising the transmembrane and endodomain. To this aim, we used the virus-like particle (VLP) system that we developed earlier for the mouse hepatitis virus strain A59 (MHV-A59) and which we describe now also for the unrelated coronavirus feline infectious peritonitis virus (FIPV; strain 79-1146). Two chimeric MHV-FIPV S proteins were constructed, consisting of the ectodomain of the one virus and the transmembrane and endodomain of the other. These proteins were tested for their incorporation into VLPs of either species. They were found to assemble only into viral particles of the species from which their carboxy-terminal domain originated. Thus, the 64-terminal-residue sequence suffices to draw the 1308 (MHV)- or 1433 (FIPV)-amino-acid-long mature S protein into VLPs. Both chimeric S proteins appeared to cause cell fusion when expressed individually, suggesting that they were biologically fully active. This was indeed confirmed by incorporating one of the proteins into virions which thereby acquired a new host cell tropism, as will be reported elsewhere.     

The N-terminal region of the murine coronavirus spike glycoprotein is associated with the extended host range of viruses from persistently infected murine cells

Although murine coronaviruses naturally infect only mice, several virus variants derived from persistently infected murine cell cultures have an extended host range. The mouse hepatitis virus (MHV) variant MHV/BHK can infect hamster, rat, cat, dog, monkey, and human cell lines but not the swine testis (ST) porcine cell line (J. H. Schickli, B. D. Zelus, D. E. Wentworth, S. G. Sawicki, and K. V. Holmes, J. Virol. 71:9499-9507, 1997). The spike (S) gene of MHV/BHK had 63 point mutations and a 21-bp insert that encoded 56 amino acid substitutions and a 7-amino-acid insert compared to the parental MHV strain A59. Recombinant viruses between MHV-A59 and MHV/BHK were selected in hamster cells. All of the recombinants retained 21 amino acid substitutions and a 7-amino-acid insert found in the N-terminal region of S of MHV/BHK, suggesting that these residues were responsible for the extended host range of MHV/BHK. Flow cytometry showed that MHV-A59 bound only to cells that expressed the murine glycoprotein receptor CEACAM1a. In contrast, MHV/BHK and a recombinant virus, k6c, with the 21 amino acid substitutions and 7-amino-acid insert in S bound to hamster (BHK) and ST cells as well as murine cells. Thus, 21 amino acid substitutions and a 7-amino-acid insert in the N-terminal region of the S glycoprotein of MHV/BHK confer the ability to bind and in some cases infect cells of nonmurine species.     

The ABCA1 domain responsible for interaction with HIV-1 Nef is conformational and not linear

HIV-1 Nef is an accessory protein responsible for inactivation of a number of host cell proteins essential for anti-viral immune responses. In most cases, Nef binds to the target protein and directs it to a degradation pathway. Our previous studies demonstrated that Nef impairs activity of the cellular cholesterol transporter, ABCA1, and that Nef interacts with ABCA1. Mutation of the ²²²⁶DDDHLK motif in the C-terminal cytoplasmic tail of ABCA1 disrupted interaction with Nef. Here, we tested Nef interaction with the ABCA1 C-terminal cytoplasmic fragment using yeast 2-hybrid system assay and co-immunoprecipitation analysis in human cells. Surprisingly, analysis in a yeast 2-hybrid system did not reveal any interaction between Nef and the C-terminal cytoplasmic fragment of ABCA1. Using co-immunoprecipitation from HEK 293T cells expressing these polypeptides, only a very weak interaction could be detected. The ²²²⁶DDDHLK motif in the C-terminal cytoplasmic tail of ABCA1 found previously to be essential for interaction between ABCA1 and Nef is insufficient to bestow strong binding to Nef. Molecular modeling suggested that interaction with Nef may be mediated by a conformational epitope composed of the sequences within the cytoplasmic loop of ABCA1 and the C-terminal cytoplasmic domain. Studies are now underway to characterize this epitope.     

N-terminal domain of eotaxin-3 is important for activation of CC chemokine receptor 3

Eotaxin-3 belongs to the CC chemokine family, and specifically recognizes CC chemokine receptor (CCR) 3 that is expressed on eosinophils, basophils and helper T type 2 cells. The three-dimensional structure of eotaxin-3 determined by nuclear magnetic resonance has revealed that the N-terminal nine residues preceding the first cysteine comprise an unstructured domain, which is also observed in other chemokine molecules. In order to determine the function of the N-terminal domain of eotaxin-3, we constructed various N-terminal-deletion mutants, and then examined their binding and chemotactic activities toward eosinophils in vitro. Competitive binding studies showed that the binding affinity of truncated mutant toward CCR3 was almost the same as that of wild-type eotaxin-3 even though the N-terminal truncation involved the first through to the ninth residues. In contrast, the chemotactic activity gradually decreased with extension of the N-terminal deletion, and when the deletion extended to the eighth residue, the activity was not detected at all. Thus, the N-terminal nine residues are not critical for binding but the N-terminal eight residues are essential for activation of CCR3. The truncated eotaxin-3 proteins lacking the N-terminal eight or nine residues inhibited the chemotactic activity of chemokines that recognize CCR3. The truncated mutants can possibly be used for anti-allergic and anti-HIV-1 therapy.     

Cooperative involvement of the S1 and S2 subunits of the murine coronavirus spike protein in receptor binding and extended host range

To study the process of spike (S)-receptor interaction during coronavirus entry, we evaluated the contributions of mutations in different regions of the murine hepatitis virus (MHV) S protein to natural receptor murine carcinoembryonic antigen-related cell adhesion molecule 1a (CEACAM1a) dependence and to the acquisition of extended host range. Extended-host-range variants of MHV strain A59 were previously obtained from persistently infected cells (J. H. Schickli, B. D. Zelus, D. E. Wentworth, S. G. Sawicki, and K. V. Holmes, J. Virol. 71:9499-9504, 1997). These variant viruses contain several mutations in the S protein that confer to the viruses the ability to enter cells in a heparan sulfate-dependent manner (C. A. de Haan, Z. Li, E. te Lintelo, B. J. Bosch, B. J. Haijema, and P. J. M. Rottier, J. Virol. 79:14451-14456, 2005). While the parental MHV-A59 is fully dependent on murine CEACAM1a for its entry, viruses carrying the variant mutations in the amino-terminal part of their S protein had become dependent on both CEACAM1a and heparan sulfate. Substitutions in a restricted, downstream part of the S protein encompassing heptad repeat region 1 (HR1) and putative fusion peptide (FP) did not alter the CEACAM1a dependence. However, when the mutations in both parts of the S protein were combined, the resulting viruses became independent of CEACAM1a and acquired the extended host range. In addition, these viruses showed a decreased binding to and inhibition by soluble CEACAM1a. The observations suggest that the amino-terminal region of the S protein, including the receptor-binding domain, and a region in the central part of the S protein containing HR1 and FP, i.e., regions far apart in the linear sequence, communicate and may even interact physically in the higher-order structure of the spike.     

A role for naturally occurring variation of the murine coronavirus spike protein in stabilizing association with the cellular receptor.

Murine hepatitis virus (MHV), a coronavirus, initiates infection by binding to its cellular receptor (MHVR) via spike (S) proteins projecting from the virion membrane. The structures of these S proteins vary considerably among MHV strains, and this variation is generally considered to be important in determining the strain-specific pathologies of MHV infection, perhaps by affecting the interaction between MHV and the MHVR. To address the relationships between S variation and receptor binding, assays capable of measuring interactions between MHV and MHVR were developed. The assays made use of a novel soluble form of the MHVR, sMHVR-Ig, which comprised the virus-binding immunoglobulin-like domain of MHVR fused to the Fc portion of human immunoglobulin G1. sMHVR-Ig was stably expressed as a disulfide-linked dimer in human 293 EBNA cells and was immobilized to Sepharose-protein G via the Fc domain. The resulting Sepharose beads were used to adsorb radiolabelled MHV particles. At 4 degrees C, the beads specifically adsorbed two prototype MHV strains, MHV JHM (strain 4) and a tissue culture-adapted mutant of MHV JHM, the JHMX strain. A shift to 37 degrees C resulted in elution of JHM but not JHMX. This in vitro observation of JHM (but not JHMX) elution from its receptor at 37 degrees C was paralleled by a corresponding 37 degrees C elution of receptor-associated JHM (but not JHMX) from tissue culture cells. The basis for this difference in maintenance of receptor association was correlated with a large deletion mutation present within the JHMX S protein, as sMHVR-Ig exhibited relatively thermostable binding to vaccinia virus-expressed S proteins containing the deletion. These results indicate that naturally occurring mutations in the coronavirus S protein affect the stability of the initial interaction with the host cell and thus contribute to the likelihood of successful infection by incoming virions. These changes in virus entry features may result in coronaviruses with novel pathogenic properties.     

Copper-induced conformational changes in the N-terminal domain of the Wilson disease copper-transporting ATPase

The Wilson disease copper-transporting ATPase plays a critical role in the intracellular trafficking of copper. Mutations in this protein lead to the accumulation of a toxic level of copper in the liver, kidney, and brain followed by extensive tissue damage and death. The ATPase has a novel amino-terminal domain ( approximately 70 kDa) which contains six repeats of the copper binding motif GMTCXXC. We have expressed and characterized this domain with respect to the copper binding sites and the conformational consequences of copper binding. A detailed analysis of this domain by X-ray absorption spectroscopy (XAS) has revealed that each binding site ligates copper in the +1 oxidation state using two cysteine side chains with distorted linear geometry. Analysis of copper-induced conformational changes in the amino-terminal domain indicates that both secondary and tertiary structure changes take place upon copper binding. These copper-induced conformational changes could play an important role in the function and regulation of the ATPase in vivo. In addition to providing important insights on copper binding to the protein, these results suggest a possible mechanism of copper trafficking by the Wilson disease ATPase.     

Prefusion spike protein conformational changes are slower in SARS-CoV-2 than in SARS-CoV-1

Within the last 2 decades, severe acute respiratory syndrome coronaviruses 1 and 2 (SARS-CoV-1 and SARS-CoV-2) have caused two major outbreaks; yet, for reasons not fully understood, the coronavirus disease 2019 pandemic caused by SARS-CoV-2 has been significantly more widespread than the 2003 SARS epidemic caused by SARS-CoV-1, despite striking similarities between these two viruses. The SARS-CoV-1 and SARS-CoV-2 spike proteins, both of which bind to host cell angiotensin-converting enzyme 2, have been implied to be a potential source of their differential transmissibility. However, the mechanistic details of prefusion spike protein binding to angiotensin-converting enzyme 2 remain elusive at the molecular level. Here, we performed an extensive set of equilibrium and nonequilibrium microsecond-level all-atom molecular dynamics simulations of SARS-CoV-1 and SARS-CoV-2 prefusion spike proteins to determine their differential dynamic behavior. Our results indicate that the active form of the SARS-CoV-2 spike protein is more stable than that of SARS-CoV-1 and the energy barrier associated with the activation is higher in SARS-CoV-2. These results suggest that not only the receptor-binding domain but also other domains such as the N-terminal domain could play a crucial role in the differential binding behavior of SARS-CoV-1 and SARS-CoV-2 spike proteins.     

Important role for the transmembrane domain of severe acute respiratory syndrome coronavirus spike protein during entry

The spike protein (S) of severe acute respiratory syndrome coronavirus (SARS-CoV) is responsible for receptor binding and membrane fusion. It contains a highly conserved transmembrane domain that consists of three parts: an N-terminal tryptophan-rich domain, a central domain, and a cysteine-rich C-terminal domain. The cytoplasmic tail of S has previously been shown to be required for assembly. Here, the roles of the transmembrane and cytoplasmic domains of S in the infectivity and membrane fusion activity of SARS-CoV have been studied. SARS-CoV S-pseudotyped retrovirus (SARSpp) was used to measure S-mediated infectivity. In addition, the cell-cell fusion activity of S was monitored by a Renilla luciferase-based cell-cell fusion assay. S(VSV-Cyt), an S chimera with a cytoplasmic tail derived from vesicular stomatitis virus G protein (VSV-G), and S(MHV-TMDCyt), an S chimera with the cytoplasmic and transmembrane domains of mouse hepatitis virus, displayed wild-type-like activity in both assays. S(VSV-TMDCyt), a chimera with the cytoplasmic and transmembrane domains of VSV-G, was impaired in the SARSpp and cell-cell fusion assays, showing 3 to 25% activity compared to the wild type, depending on the assay and the cells used. Examination of the oligomeric state of the chimeric S proteins in SARSpp revealed that S(VSV-TMDCyt) trimers were less stable than wild-type S trimers, possibly explaining the lowered fusogenicity and infectivity.     

Mimicking lipid-binding-induced conformational changes in the human apolipoprotein E N-terminal receptor binding domain effects of low pH and propanol.

We studied the effects of n-propanol and pH on the structure of the apolipoprotein E3 N-terminal receptor binding domain, apo E3(1-191), to determine whether conditions similar to those occurring near lipid surfaces (decreased dielectric constant and pH) can mimic lipid-induced conformational changes in apo E3. The addition of 30% n-propanol, at pH 7, induces a conformational change in apo E3(1-191) as shown by changes in the intrinsic tryptophan fluorescence and by an increase in the Stokes radius of the majority of the protein from 3.0 to 4.1 nm, although the protein remains monomeric as shown by chemical cross-linking. These changes are accompanied by increased resistance to limited proteolysis with trypsin, chymotrypsin, subtilisin and endoproteinase glu-C, as is the case for apo E3(1-191) reconstituted into phospholipid/cholesterol lipid bicelles. Far and near UV circular dichroism showed that n-propanol increases the amount of calculated alpha-helical structure (42-65%) and alters the tertiary structure of the protein although not as much as when apo E3(1-191) is incorporated into lipid bicelles. In the absence of n-propanol, lowering the pH to 4.5 decreases the Stokes radius of the majority of the protein somewhat, with little effect upon the secondary and the tertiary structures. The addition of 30% n-propanol at pH 4.5 increases the Stokes radius of apo E3(1-191) from 2.2 to 5.0 nm, even more than at pH 7 (3.0-4.1 nm) although the protein still remains predominantly monomeric. There is increased resistance to limited proteolysis with endoproteinase glu-C. As assessed by far and near UV circular dichroism, the addition of 30% n-propanol at pH 4.5, in contrast to pH 7, markedly increases the alpha-helical structure and changes the tertiary structure of the protein similarly to that resulting from the incorporation of apo E3(1-191) into lipid bicelles. The results suggest that a combination of n-propanol and low pH in aqueous solutions may be useful as a simple model system for studying conformational changes in apo E3 similar to those, which occur upon interaction of the protein with lipids.