Glucocorticoid-dependent complementation of a hepatoma cell variant defective in viral glycoprotein sorting.

We have utilized the rat hepatoma (HTC) cell sorting variant CR4 to examine the glucocorticoid-regulated pathways that localize mouse mammary tumor virus glycoproteins to the cell surface. The defective sorting of cell surface mouse mammary tumor virus glycoproteins in CR4 cells was complemented after fusion with either normal rat hepatocytes or uninfected HTC cells. Indirect immunofluorescence of transient heterokaryons revealed that the regulated localization of mouse mammary tumor virus glycoproteins was dependent upon glucocorticoid treatment and required de novo RNA and protein synthesis. Thus, a glucocorticoid-regulated trafficking activity, unrelated to mouse mammary tumor virus sequences, which is induced in both adult rat liver and cultured hepatoma cells, can act in trans to mediate an intracellular sorting pathway for membrane glycoproteins.     

Interaction of calmodulin with the cytoplasmic domain of platelet glycoprotein VI

The platelet collagen receptor, glycoprotein VI (GPVI), and GPIb-IX-V, which binds von Willebrand factor, initiate platelet aggregation at low or high shear stress, respectively. We recently reported that positively charged, membrane-proximal sequences within cytoplasmic domains of GPIbbeta and GPV of GPIb-IX-V bind calmodulin. We now show that GPVI also binds calmodulin as follows-(1) calmodulin coimmunoprecipitated with GPVI from resting platelet lysates using an anti-GPVI IgG, but partially dissociated in platelets activated by collagen or collagen-related peptide; (2) calmodulin coprecipitated from platelet lysates with maltose-binding protein (MBP)-GPVI cytoplasmic domain fusion protein, but not MBP alone; (3) GPVI-related synthetic peptide based on the membrane-proximal sequence, His269-Pro287, induced a shift in calmodulin migration on nondenaturing gels, an assay that identifies calmodulin-binding peptides. His269-Pro287 is analogous to the calmodulin-binding sequence in GPIbbeta. The novel interaction of GPVI and calmodulin may regulate aspects of GPVI function.     

Interaction of calmodulin with the cytoplasmic domain of the platelet membrane glycoprotein Ib-IX-V complex

Engagement of platelet membrane glycoprotein (GP) Ib-IX-V by von Willebrand factor triggers Ca(++)-dependent activation of alphaIIbbeta3, resulting in (patho)physiological thrombus formation. It is demonstrated here that the cytoplasmic domain of GPIb-IX-V associates with cytosolic calmodulin. First, an anti-GPIbalpha antibody coimmunoprecipitated GPIb-IX and calmodulin from platelet lysates. Following platelet stimulation, calmodulin dissociated from GPIb-IX and, like the GPIb-IX-associated proteins 14-3-3zeta and p85, redistributed to the activated cytoskeleton. Second, a synthetic peptide based on the cytoplasmic sequence of GPIbbeta, R149-L167 (single-letter amino acid codes), affinity-isolated calmodulin from platelet cytosol in the presence of Ca(++) as confirmed by comigration with bovine calmodulin on sodium dodecyl sulfate-polyacrylamide gels, by sequence analysis, and by immunoreactivity with the use of an anticalmodulin antibody. The membrane-proximal GPIbbeta sequence was analogous to a previously reported calmodulin-binding sequence in the leukocyte adhesion receptor, L-selectin. In addition, the cytoplasmic sequence of GPV, K529-G544, was analogous to a calmodulin-binding IQ motif within the alpha1c subunit of L-type Ca(++) channels. Calmodulin coimmunoprecipitated with GPV from resting platelet lysates, but was dissociated in stimulated platelets. A GPV-related synthetic peptide also bound calmodulin and induced a Ca(++)-dependent shift on nondenaturing gels. Together, these results suggest separate regions of GPIb-IX-V can directly bind calmodulin, and this novel interaction potentially regulates aspects of GPIb-IX-V-dependent platelet activation. (Blood. 2001;98:681-687)     

Autoantibodies to the presumptive cytoplasmic domain of platelet glycoprotein IIIa in patients with chronic immune thrombocytopenic purpura.

Chronic immune thrombocytopenic purpura (ITP) is an autoimmune disorder due to autoantibodies against platelets that result in their destruction. In some patients, these autoantibodies bind to platelet glycoprotein (GP) IIIa. With the aim of better defining the antigenic epitopes, plasma from 13 selected patients with chronic ITP known to have anti-GPIIb/IIIa autoantibodies was tested for reactivity with nine synthetic peptides corresponding to different regions of the GP IIIa molecule. Of these plasmas, five bound significantly (P less than .001) with either peptide 8 (amino acids 721-744) or peptide 9 (amino acids 742-762), which together form most of the carboxyterminal region presumed to be the cytoplasmic domain. Three of these positive plasmas, were tested further. In two of these positive plasmas, the anti-peptide antibodies represented greater than 80% of the detectable circulating autoantibody. To further evaluate the importance of the carboxyterminal region as an antigenic site, the chronic ITP plasmas were tested against Chinese hamster ovary cells transfected with GPIIb and either whole GPIIIa or GPIIIa lacking amino acids 728 to 762. Ten of the 13 plasmas required the presence of this region for significant autoantibody binding. We conclude that the carboxyterminal region is an important area for stimulating antiplatelet autoantibody formation in some patients with chronic ITP. It is not known whether these autoantibodies to the presumed cytoplasmic domain play an important role in the pathogenesis of the disease or occur as a secondary phenomenon during the course of platelet destruction.     

The presence of cysteine in the cytoplasmic domain of the vesicular stomatitis virus glycoprotein is required for palmitate addition.

The transmembrane glycoprotein (G protein) of vesicular stomatitis virus (VSV) is known to contain 1-2 mol of covalently linked fatty acid (palmitate) per mol of protein. G protein is oriented in cellular membranes such that the carboxyl-terminal 29 amino acids protrude into the cytoplasm. We have obtained expression in eukaryotic cells of mutagenized cDNA clones that encode VSV G proteins lacking portions of this cytoplasmic domain. Labeling of these truncated proteins with [3H]palmitate indicated that the palmitate might be linked to an amino acid residue within the first 14 residues on the carboxyl-terminal side of the transmembrane domain. Using oligonucleotide directed mutagenesis, we changed the single codon specifying cysteine in this domain to a codon specifying serine. Expression of this mutant gene results in synthesis of a G protein lacking palmitate. We suggest that linkage of palmitate to G protein is through the cysteine in the cytoplasmic domain and that such a linkage may occur in many viral and cellular glycoproteins. The G protein lacking palmitate is glycosylated and is transported normally to the cell surface.     

Vesicular stomatitis virus glycoprotein is anchored in the viral membrane by a hydrophobic domain near the COOH terminus

We have determined the COOH-terminal and NH(2)-terminal amino acid sequences of the vesicular stomatitis virus (VSV) glycoprotein (G). A sequence of 122 COOH-terminal amino acids was deduced from the complete sequence of a cloned DNA insert carrying 470 nucleotides derived from the 3' end of the G mRNA. Evidence presented indicates that this portion of the polypeptide includes the domains of G that reside inside the virion and span the lipid bilayer of the virion. This seems clear because a partial amino acid sequence of a fragment of G that remains associated with the membrane of the virion after exhaustive proteolytic digestions can be located unambiguously in the predicted sequence. This predicted sequence contains an uninterrupted hydrophobic domain beginning 49 amino acids and ending 30 amino acids from the COOH terminus. This region presumably spans the lipid bilayer. The COOH-terminal portion of 29 amino acids contains a high proportion of basic residues and resides inside the virion. The COOH-terminal portion of the VSV G protein therefore resembles in structure that of glycophorin, an erythrocyte membrane protein well characterized previously. The configuration of G in the viral membrane demonstrated here is probably similar for other viral glycoproteins, although this has not been tested as directly in any other case. From the sequence of a DNA primer extended on the RNA genome from the adjacent M protein gene into the G protein gene, we have deduced an NH(2)-terminal G protein sequence of 53 amino acids, including the leader sequence of 16 amino acids. Our sequence confirms, extends, and corrects two partial amino acid sequences reported for this region previously.     

A basolateral sorting motif in the MICA cytoplasmic tail

The MHC class I chain-related MICA molecule is a stress-induced, highly polymorphic, epithelia-specific, membrane-bound glycoprotein interacting with the activating NK cell receptor NKG2D and/or gut-enriched Vdelta1-bearing gammadelta T cells. We have previously reported the presence of a MICA transmembrane-encoded short-tandem repeat harboring a peculiar allele, A5.1, characterized by a frame shift mutation leading to a premature intradomain stop codon, thus denying the molecule of its 42-aa cytoplasmic tail. Given that this is the most common population-wide MICA allele found, we set out to analyze the functional consequences of cytoplasmic tail deletion. Here, we show native expression of MICA at the basolateral surface of human intestinal epithelium, the site of putative interaction with intraepithelial T and NK lymphocytes. We then demonstrate, in polarized epithelial cells, that although the full-length MICA protein is sorted to the basolateral membrane, the cytoplasmic tail-deleted construct as well as the naturally occurring A5.1 allele are aberrantly transported to the apical surface. Site-directed mutagenesis identified the cytoplasmic tail-encoded leucine-valine dihydrophobic tandem as the basolateral sorting signal. Hence, the physiological location of MICA within epithelial cells is governed by its cytoplasmic tail, implying impairment in A5.1 homozygous individuals, perhaps relevant to the immunological surveillance exerted by NK and T lymphocytes on epithelial malignancies.     

Calcium levels in the Golgi complex regulate clustering and apical sorting of GPI-APs in polarized epithelial cells

Glycosylphosphatidylinositol-anchored proteins (GPI-APs) are lipid-associated luminal secretory cargoes selectively sorted to the apical surface of the epithelia where they reside and play diverse vital functions. Cholesterol-dependent clustering of GPI-APs in the Golgi is the key step driving their apical sorting and their further plasma membrane organization and activity; however, the specific machinery involved in this Golgi event is still poorly understood. In this study, we show that the formation of GPI-AP homoclusters (made of single GPI-AP species) in the Golgi relies directly on the levels of calcium within cisternae. We further demonstrate that the TGN calcium/manganese pump, SPCA1, which regulates the calcium concentration within the Golgi, and Cab45, a calcium-binding luminal Golgi resident protein, are essential for the formation of GPI-AP homoclusters in the Golgi and for their subsequent apical sorting. Down-regulation of SPCA1 or Cab45 in polarized epithelial cells impairs the oligomerization of GPI-APs in the Golgi complex and leads to their missorting to the basolateral surface. Overall, our data reveal an unexpected role for calcium in the mechanism of GPI-AP apical sorting in polarized epithelial cells and identify the molecular machinery involved in the clustering of GPI-APs in the Golgi.

Glycosylphosphatidylinositol (GPI)-anchored proteins (GPI-APs) are localized on the apical surface of most epithelia, where they exert their physiological functions, which are regulated by their spatiotemporal compartmentalization.In polarized epithelial cells, the organization of GPI-APs at the apical surface is driven by the mechanism of apical sorting, which relies on the formation of GPI-AP homoclusters in the Golgi apparatus (1, 2). GPI-AP homoclusters (containing a single GPI-AP species) form uniquely in the Golgi apparatus of fully polarized cells (and not in nonpolarized cells) in a cholesterol-dependent manner (1, 3, 4). Once formed, GPI-AP homoclusters become insensitive to cholesterol depletion, suggesting that protein–protein interactions stabilize them (1, 2). At the apical membrane, newly arrived homoclusters coalesce into heteroclusters (containing at least two different GPI-AP species) that are sensitive to cholesterol depletion (1). Of importance, in the absence of homoclustering in the Golgi (e.g., in nonpolarized epithelial cells), GPI-APs remain in the form of monomers and dimers and do not cluster at the cell surface (1, 5). Thus, the organization of GPI-APs at the apical plasma membrane of polarized cells strictly depends on clustering mechanisms in the Golgi apparatus allowing their apical sorting. This is different from what was shown in fibroblasts where clustering of GPI-APs occurs from monomer condensation at the plasma membrane, indicating that distinct mechanisms regulate GPI-AP clustering in polarized epithelial cells and fibroblasts (1, 6, 7). Furthermore, in polarized epithelial cells, the spatial organization of clusters also appears to regulate the biological activity of the proteins (1) so that GPI-APs are fully functional only when properly sorted to the apical surface and less active in the case of missorting to the basolateral domain (1, 8, 9). Understanding the mechanism of GPI-AP apical sorting in the Golgi apparatus is therefore crucial to decipher their organization at the plasma membrane and the regulation of their activity. The determinants for protein apical sorting have been difficult to uncover compared to the ones for basolateral sorting (10–14). Besides a role of cholesterol, the molecular factors regulating the clustering-based mechanism of GPI-AP sorting in polarized epithelial cells are unknown. Here, we analyzed the possible role of the actin cytoskeleton and of calcium levels in the Golgi. The actin cytoskeleton is not only critical for the maintenance of the Golgi structure and its mechanical properties but also provides the structural support favoring carrier biogenesis (15–18). The Golgi exit of various cargoes is altered in cells treated with drugs either depolymerizing or stabilizing actin filaments (19, 20), and the post-Golgi trafficking is affected either by the knockdown of the expression of some actin-binding proteins, which regulate actin dynamics, or by the overexpression of their mutants (12, 21–23), all together revealing the critical role of actin dynamics for protein trafficking. Only few studies have shown the involvement of actin remodeling proteins in polarized trafficking, mostly in selectively mediating the apical and basolateral trafficking of transmembrane proteins [refs. 24–26; and reviewed in ref. 27]; thus, it remains unclear whether actin filaments play a role in protein sorting in polarized cells.On the other hand, the Golgi apparatus exhibits high calcium levels that have been revealed to be essential for protein processing and the sorting of some secreted soluble proteins in nonpolarized cells (28–31). Moreover, a functional interplay between the actin cytoskeleton and Golgi calcium in modulating protein sorting in nonpolarized cells has been shown (22).In this study, we report that in epithelial cells, actin perturbation does not impair GPI-AP clustering capacity in the Golgi and therefore their apical sorting. In contrast, we found that the Golgi organization of GPI-APs is drastically perturbed upon calcium depletion and that the amount of calcium in the Golgi cisternae is critical for the formation of GPI-AP homoclusters. We further show that the TGN calcium/manganese pump, SPCA1 (secretory pathway Ca(2+)-ATPase pump type 1), which controls the Golgi calcium concentration (32), and Cab45, a calcium-binding luminal Golgi resident protein previously described to be involved in the sorting of a subset of soluble cargoes (33, 34), are essential for the formation of GPI-APs homoclusters in the Golgi and for their subsequent apical sorting. Indeed, down-regulation of SPCA1 or Cab45 expression impairs the oligomerization of GPI-APs in the Golgi complex and leads to their missorting to the basolateral surface but does not affect apical or basolateral transmembrane proteins. Overall, our data reveal an unexpected role for calcium in the mechanism of GPI-AP apical sorting in polarized epithelial cells and identify the molecular machinery involved in the clustering of GPI-APs in the Golgi.     

Development of a safe and rapid neutralization assay using murine leukemia virus pseudotyped with HIV type 1 envelope glycoprotein lacking the cytoplasmic domain.

Neutralizing antibody (NAb) is a critical component of an immune system that can potentially provide sterilizing protection against human immunodeficiency virus type 1 (HIV-1). Therefore, an in vitro assay that can rapidly, safely, and accurately evaluate the NAb response vaccine candidates elicit, especially against a large number of HIV-1 variants, would be highly valuable. It has been demonstrated that HIV-1 envelope glycoprotein lacking the cytoplasmic domain can pseudotype murine leukemia virus encoding the beta-galactosidase gene and that this pseudovirus can specifically infect CD4(+) cells (Schnierle BS, Stitz J, Bosch V, et al.: Proc Natl Acad Sci USA 1997;94:8640-8645). Because the pseudovirus is not biohazardous and because the infection can be quantitatively determined within 2 days, we examined the feasibility of using the pseudovirus for high-throughput neutralization assays for HIV-1. We have generated viruses pseudotyped with gp140 of six different HIV-1 isolates (LAI, RF, Bal, AD8, 89.6, and DH12). All six pseudoviruses were infectious and exhibited expected coreceptor usage phenotype in HOS-CD4 cells expressing either CCR5 or CXCR4. More importantly, the neutralization sensitivity profile of these pseudoviruses was virtually identical to that observed from more conventional neutralization assays using either HIV-1 or SHIV. All pseudoviruses could be neutralized by broadly reactive human monoclonal antibody IgG1 b12. Our results indicate that the pseudoviruses are ideal for high-throughput evaluation of immune sera for their capacity to broadly neutralize a large number of HIV-1 isolates.     

Identification of a neutralizing domain in the external envelope glycoprotein of simian immunodeficiency virus.

Two murine monoclonal antibodies (MAbs), designated MATG2014 and MATG2033, were generated. They are reactive with the external envelope glycoprotein gp130 of the simian immunodeficiency virus of macaque monkey (SIVmac251), and display a cell-free virus neutralizing activity in vitro. In addition, MATG2014 cross-reacts with HIV-2Rod gp140. Epitope mapping of these MAbs was performed by screening and SIVmac peptide library expressed in yeast and confirmed using synthetic peptides. MATG2014 and MATG2033 recognize two overlapping epitopes localized in an 18 residue domain between amino acid 171 and 188 of the SIVmac251 gp130. Sera from experimentally SIV-infected macaques are immunoreactive with this neutralizing domain. Sequence comparison with related SIV and HIV-2 viral strains indicates a low variability of this region, consistent with the cross-reactivity of MATG2014 with HIV-2Rod gp140. This domain should then be considered in designing experimental vaccines.     

Kinetic characterization of a cytoplasmic myosin motor domain expressed in Dictyostelium discoideum.

A detailed kinetic study of the interaction of a recombinant myosin head fragment (MHF) of Dictyostelium discoideum with actin and adenine nucleotides has been made by using a combination of rapid-reaction, equilibrium, and fluorescence methods. MHF is equivalent in size to a proteolytic fragment of skeletal muscle myosin, subfragment 1 (S1), the simplest unit of myosin to retain enzymatic and functional activity. The results show that qualitatively the interactions of MHF with nucleotides and actin are the same as those of S1. Both bind to rabbit actin with the same affinity, although differences in the rate constants of their interactions with nucleotides in the presence and absence of actin occur. The rate of ATP binding to MHF and the subsequent cleavage step are significantly slower than the corresponding rates with S1. The dissociation of a fluorescent analog of ADP from MHF was 5-fold faster than from S1, while its rate of binding MHF was 3-fold slower, resulting in a weaker association equilibrium constant. The ATP-induced isomerization of the actoMHF complex was 10-fold slower than for actoS1, but the binding affinities of ADP for actoMHF and actoS1 were indistinguishable. The results suggest a different degree of coupling between the nucleotide and actin binding sites of MHF and S1 which may be a common feature of nonmuscle myosins. They also provide the basis for a study of specifically modified myosins with which one can probe the sites of interaction with nucleotides or actin, as well as functional motility.     

A cytoplasmic domain is important for the formation of a SecY-SecE translocator complex.

An approach to identifying the interaction site of multicomponent protein assembly has been applied to the membrane-bound SecY-SecE complex, which mediates protein export across the Escherichia coli cytoplasmic membrane. A dominant negative secY allele, secY-d1, inactivates SecY but preserves its ability to interact with SecE. Thus, the mutant protein sequesters SecE in an inactive complex. Second site mutations that disrupt the SecE binding site will suppress the export interference. We introduced insertion/deletion mutations that intragenically suppressed secY-d1. After eliminating knock-out mutations by virtue of the expression of a LacZ alpha sequence that had been attached to the C terminus, we obtained a striking clustering of mutations in cytoplasmic domain 4. On the basis of this result, the secY24 (Ts) substitution mutation in this domain was examined for its effects on interaction with SecE. It indeed suppressed secY-d1. Although the instability associated with excess SecY can be alleviated by overproduction of SecE, the secY24 mutant protein was not stabilized by SecE. The basal-level SecY24 protein was also destabilized at 42 degrees C. SecE was coimmunoprecipitated with SecY+ but not with the SecY24 protein. These results indicate that the secY24 mutation weakens SecY's interaction with SecE. Taken together, we propose that cytoplasmic domain 4 is important for the association between SecY and SecE.     

Transmembrane signaling by an insulin receptor lacking a cytoplasmic beta-subunit domain.

To assess the function of the cytoplasmic domain of the insulin receptor (IR) beta subunit, we have studied a mutant IR truncated by 365 aa (HIR delta 978), thereby deleting > 90% of the cytoplasmic domain. HIR delta 978 receptors were processed normally to homodimers that were expressed at the cell surface where they bind insulin with normal affinity. Although these truncated IRs were inactive with respect to ligand-induced internalization and autophosphorylation, insulin stimulated endogenous substrate (pp185) phosphorylation significantly more in HIR delta 978 cells than in untransfected Rat1 cells. Importantly, despite absence of the beta-subunit cytoplasmic domain, fibroblasts expressing HIR delta 978 receptors displayed enhanced sensitivity to insulin for stimulation of glucose incorporation into glycogen, alpha-aminoisobutyric acid uptake, thymidine incorporation, and S6 kinase activity compared with parental fibroblasts. Insulin also induced the expression of the protooncogene c-fos and the early growth response gene Egr-1 in HIR delta 978 cells far greater than in parental Rat1 fibroblasts. Furthermore, an agonistic monoclonal antibody specific for the human IR stimulated insulin action in fibroblasts expressing wild-type human IR but had no effect on HIR delta 978 cells. In conclusion, the HIR delta 978 truncated IRs appear to confer enhanced insulin sensitivity by augmenting the signaling properties of the endogenous rodent IRs.     

Conformational change in a viral glycoprotein during maturation due to disulfide bond disruption.

The fusion glycoprotein of Newcastle disease virus is synthesized as an inactive precursor, F0. During intracellular transport and maturation, F0 undergoes a conformational change resulting from the loss of intramolecular disulfide bonds. F0 is also cleaved to yield F1, F2, the active, membrane-fusing form of the protein. Two monoclonal antibodies were used to explore this conformational change and its relationship to cleavage. These antibodies failed to precipitate the pulse-labeled fusion protein but did precipitate the F0 and the F1, F2 forms of the "chase" fusion protein. Use of the inhibitors carbonylcyanide m-chlorophenylhydrazone and monensin showed that the fusion protein acquired the ability to react with the monoclonal antibodies after it left the rough endoplasmic reticulum but before it left the medial Golgi membranes and before it was cleaved. The acquisition of antigenicity correlates with the disruption of intramolecular disulfide bonds during transit through the cell. This correlation was directly confirmed. The pulse-labeled fusion protein could be recognized by both monoclonal antibodies if the protein was first reduced. The formation and disruption of intramolecular disulfide bonds as a posttranslational modification of glycoproteins is discussed.     

Functional analysis of the cytoplasmic domain of the integrin {alpha}1 subunit in endothelial cells

Integrin alpha1beta1, the major collagen type IV receptor, is expressed by endothelial cells and plays a role in both physiologic and pathologic angiogenesis. Because the molecular mechanisms whereby this collagen IV receptor mediates endothelial cell functions are poorly understood, truncation and point mutants of the integrin alpha1 subunit cytoplasmic tail (amino acids 1137-1151) were generated and expressed into alpha1-null endothelial cells. We show that alpha1-null endothelial cells expressing the alpha1 subunit, which lacks the entire cytoplasmic tail (mutant alpha1-1136) or expresses all the amino acids up to the highly conserved GFFKR motif (mutant alpha1-1143), have a similar phenotype to parental alpha1-null cells. Pro(1144) and Leu(1145) were shown to be necessary for alpha1beta1-mediated endothelial cell proliferation; Lys(1146) for adhesion, migration, and tubulogenesis and Lys(1147) for tubulogenesis. Integrin alpha1beta1-dependent endothelial cell proliferation is primarily mediated by ERK activation, whereas migration and tubulogenesis require both p38 MAPK and PI3K/Akt activation. Thus, distinct amino acids distal to the GFFKR motif of the alpha1 integrin cytoplasmic tail mediate activation of selective downstream signaling pathways and specific endothelial cell functions.     

The V domain of herpesvirus Ig-like receptor (HIgR) contains a major functional region in herpes simplex virus-1 entry into cells and interacts physically with the viral glycoprotein D

The herpesvirus entry mediator C (HveC), previously known as poliovirus receptor-related protein 1 (PRR1), and the herpesvirus Ig-like receptor (HIgR) are the bona fide receptors employed by herpes simplex virus-1 and -2 (HSV-1 and -2) for entry into the human cell lines most frequently used in HSV studies. They share an identical ectodomain made of one V and two C2 domains and differ in transmembrane and cytoplasmic regions. Expression of their mRNA in the human nervous system suggests possible usage of these receptors in humans in the path of neuron infection by HSV. Glycoprotein D (gD) is the virion component that mediates HSV-1 entry into cells by interaction with cellular receptors. We report on the identification of the V domain of HIgR/PRR1 as a major functional region in HSV-1 entry by several approaches. First, the epitope recognized by mAb R1.302 to HIgR/PRR1, capable of inhibiting infection, was mapped to the V domain. Second, a soluble form of HIgR/PRR1 consisting of the single V domain competed with cell-bound full-length receptor and blocked virion infectivity. Third, the V domain was sufficient to mediate HSV entry, as an engineered form of PRR1 in which the two C2 domains were deleted and the V domain was retained and fused to its transmembrane and cytoplasmic regions was still able to confer susceptibility, although at reduced efficiency relative to full-length receptor. Consistently, transfer of the V domain of HIgR/PRR1 to a functionally inactive structural homologue generated a chimeric receptor with virus-entry activity. Finally, the single V domain was sufficient for in vitro physical interaction with gD. The in vitro binding was specific as it was competed both by antibodies to the receptor and by a mAb to gD with potent neutralizing activity for HSV-1 infectivity.     

Cationic lipids direct a viral glycoprotein into the class I major histocompatibility complex antigen-presentation pathway.

Recombinant glycoprotein B (gB) of herpes simplex virus (HSV) was processed and presented by class I major histocompatibility complex (MHC) molecules after delivery into cells by using N-[1-(2,3-dioleoyloxy)propyl]-N,N,N-trimethylammonium methyl sulfate (DOTAP), a commercially available cationic lipid used for DNA transfection. Cells treated with DOTAP-associated gB were susceptible to lysis by class I MHC-restricted, HSV-specific cytotoxic T lymphocytes (CTL), and the treated cells restimulated memory gB-specific CTL activity in spleen cells from HSV-infected mice. gB-specific CTL responses were detected in mice immunized with recombinant gB and DOTAP but not in those receiving gB emulsified in complete Freund's adjuvant. Thus, cationic lipids may facilitate induction of CD8+ T-cell responses in vaccinations with recombinant antigens, and they may serve as readily available reagents for dissecting class I MHC immunity to viruses and other intracellular pathogens.     

Uvomorulin-catenin complex formation is regulated by a specific domain in the cytoplasmic region of the cell adhesion molecule.

We have recently found that the cytoplasmic region of the cell adhesion molecule uvomorulin associates with three proteins named catenin alpha, beta, and gamma. Here we show by analysis of various mutant uvomorulin polypeptides expressed in mouse L cells that this association is mediated by a specific domain in the cytoplasmic region. A specific recognition site for catenins is located in a 72-amino acid domain. Interestingly, 69 of the 72 amino acid residues are encoded by a single exon of the uvomorulin gene. To demonstrate the direct interaction between catenins and the 72-amino acid domain, cDNA constructs composed of H-2Kd cDNA and various 3' sequences of uvomorulin were expressed in L cells. Chimeric proteins between H-2Kd and the 72-amino acid domain of uvomorulin were shown, by immunoprecipitation with anti-H-2Kd antibodies, to complex with catenin alpha, beta, and gamma. Catenins connect uvomorulin to cytoskeletal structures. We provide biochemical evidence for an association of the uvomorulin-catenin complex with actin bundles. Our results suggest that catenin alpha plays a key role in the association with actin filaments, whereas catenin beta binds more directly to the cytoplasmic region of uvomorulin. In cell aggregation assays with transfected cells expressing normal or mutant uvomorulin, the adhesive function was expressed only when uvomorulin was associated with catenins. From these results we conclude that the cytoplasmic anchorage of uvomorulin is of major biological importance.     

Demonstration of a cytoplasmic structure in plasma cells

In normal and pathologic plasma cells of the bone marrow, a specific filamentous structure of the cytoplasm has been revealed by electron microscopy. Thesignificance of this structure is briefly discussed.

Submitted on January 26, 1953 Accepted on February 16, 1953