Inverse Relationship of Polyoma Tumour Specific Cell Surface Antigen to H-2 Histocompatibility Antigens

NEOPLASTIC transformation is known to be associated with changes in the strength of normal cellular antigens, but the effect can be either an increase or a decrease. In the former category are Forssman antigens in guinea-pig hepatoma¹ and SV40 transformed cells²; HL-A antigens in leukaemic cells³; and “G” antigen in human tumour cells⁴. On the other hand, the intensity of the expression of mouse H-2 histocompatibility antigens is decreased in TL(+) leukaemia⁵ and methylcholanthrene (MCA)-induced tumours⁶. We set out to tell whether the expression of histocompatibility antigens was also affected by transformation with an oncogenic virus and have found that in tumours induced by polyoma virus, the quantity of H-2 antigens varied inversely with the amount of tumour-specific cell surface antigen.     

Synthesis of Cell Coat in Normal and Transformed Cells

THE surface of transformed cells has been a focus of considerable attention recently because some of the properties which distinguish these cells from their precursors, such as decreased cell adhesiveness, altered cell orientation and loss of contact and density dependent inhibition^1–3, may relate to changes on their surface. A common feature of vertebrate cells is the cell coat, a glycoprotein structure surrounding the plasma membrane⁴. Electron microscopy has revealed that transformed cells have a thicker coat than normal cells⁵ and we have now found that coat synthesis in cells transformed by an oncogenic DNA virus and in cells transformed by a chemical carcinogen occurs faster than in normal controls whereas only in the virus-transformed cells is the coat significantly thicker.     

Formation of heterophile antibodies by human tonsilar lymphocytes: II. In vitro stimulation with allogeneic cells

Short-term cultures of human tonsilar lymphocytes (HTL), 5 × 10⁶ cells/culture, in medium RPMI 1640 supplemented with human group AB serum were studied for the production of plaque-forming cells (PFC) against sheep (SRBC) and bovine (BRBC) red blood cells following in vitro stimulation by various allogeneic lymphoid cells. Of 55 HTL specimens examined, 48 produced a significant number (50–300/culture) of PFC against SRBC and/or BRBC following the in vitro stimulation. The optimal doses of the stimulator HTL and peripheral blood lymphocytes (PBL) were 10⁷ and 5 × 10⁶/culture, respectively. After the stimulation, PFC appeared in significant numbers on the third day, reached the peak number on the sixth day, and decreased sharply in number thereafter. Removal of E-rosetting cells from both stimulator and responder populations abolished the PFC formation. PFC formation against SRBC was inhibited by solubilized Forssman antigen, while PFC formation against BRBC was inhibited strongly by Hanganutziu-Deicher antigen, hardly by Paul-Bunnell antigen and not at all by Forssman antigen. Supernatants of mixed lymphocyte culture of PBL were shown to enhance PFC formation of HTL cultures stimulated by allogeneic lymphocytes. The results of this study indicated that in vivo primed B cells of the HTL were triggered in vitro by allogeneic stimulation for the heterophile antibody formation. Since these antibodies are apparently directed against Forssman and Hanganutziu-Deicher antigens, the “allo” nature of these antigens as well as their relationship to the previously described heterophile transplantation antigens have to be clarified.     

Apical and basal Forssman antigen in MDCK II cells: a morphological and quantitative study.

We have studied the surface distribution of a glycosphingolipid (the Forssman antigen) in MDCK II and CCL39 cells. The Forssman antigen is mobile on the surface of both these cell lines. Its surface distribution is homogenous on non-polarized cells. Under conditions where MDCK II cells are well polarized, the Forssman antigen is present in equal amounts on the apical membrane and on the basal membrane and its processes. Very little Forssman antigen can be detected on the lateral membrane. The nature of the mechanism excluding the Forssman antigen from the lateral domain remains to be determined. This surface distribution is established within hours after plating and was observed with cells grown on different types of filters. The surface density of the Forssman antigen on the apical and on the basal domain has been estimated. No involvement of the basal Forssman antigen in cell attachment could be demonstrated. However, the apical Forssman antigen appears to be essential to the establishment of the cells in culture.     

The isolation and characterization of plasma membrane from cultured cells V. The chemical composition of plasma membranes isolated from chicken tumors initiated with virus-transformed cells

Sarcomas were initiated in chicken muscle and wing web by Bratislava 77 and morph^r Fujinami virus. Plasma membrane was isolated from the virus-induced tumor cells by differential centrifugation and flotation equilibrium centrifugation. The levels of neutral sugar and sialic acid in these isolated plasma membranes were very similar to the levels found in cultured chick embryo fibroblasts transformed in vitro with the same oncogenic viruses and differed markedly from the levels found in uninfected and leukosis virus-infected fibroblasts.The phospholipid content of the isolated cell membranes from tumors was less than the quantity of lipid found in the plasma membrane of cultured cells and differed with the site of the tumor. Breast muscle tumors contained less plasma membrane phospholipid than did wing tumors.The similarities in the neutral sugar and the sialic acid content of these two different sources of plasma membrane indicate that oncogenic transformation in cell culture reproduces in situ neoplastic change to a large extent, for at least this one parameter of cell surface change.     

Lectin and cholera toxin binding to guinea pig tumor (104C1) cell surfaces before and after glycosphingolipid incorporation

¹²⁵I-Labeled $\text{Dolichos biflorus}$ lectin and cholera toxin were used as probes for identification of Forssman- and GM1-type receptor sites on guinea pig tumor (104C1) cell surfaces. Increased binding of ¹²⁵I-labeled lectin and toxin to 104C1 cell surfaces was observed after the cells were treated with exogenous Forssman glycosphingolipid and GM1 ganglioside, respectively. Biosynthesis $\text{in vitro}$ of these two glycosphingolipids from their precursor molecules was established using a membrane preparation isolated from confluent cultures of guinea pig tumor 104C1 cells.     

Surface Alterations of Cells Carrying RNA Tumour Virus Genetic Information

CELLS transformed by the DNA tumour viruses, polyoma virus and SV40, are agglutinated by lectins such as wheat germ agglutinin¹, concanavalin A (Con A)² and soybean agglutinin³. Agglutination in these cases presumably reflects changes in the cell surface related to the transformed properties of the cell; studies with a temperature-dependent mutant of polyoma virus has shown that cell surface changes are controlled by viral genes⁴. Here we describe experiments in which we investigated the agglutinability of cells transformed by RNA tumour viruses. One recent report had suggested that cells transformed by RNA tumour viruses were not specifically agglutinated⁵, whereas a second more recent report claimed the specific agglutination of cells transformed by RSV⁶. We find that transformed rat, mouse and cat cells that replicate the sarcoma-leukaemia virus complex of murine (MSV) and feline (FeSV) origin are strongly agglutinated by Con A, but mouse and human cells that replicate the murine and feline leukaemia virus components alone are not agglutinated. The ability to agglutinate is rapidly acquired by normal mouse cells on infection with the murine sarcoma virus at a rate that parallels virus replication. In contrast to the results obtained with cells producing virus, non-virus-producing transformed hamster and mouse cells that synthesize virus-specific RNA are either not agglutinated or are agglutinated to a lesser degree. These results suggest that the cell surface alterations responsible for agglutination are not necessarily associated with the transformed state of the cell, but rather with the possession of sarcoma virus-specific information.     

Ca2+ and the interaction of pore-formers with membranes

The interaction of pore-forming agents, such as Sendai virus, influenza virus (at pH 5 3), activated complement,Staphylococcus aureus α-toxin, melittin and polylysine, with the surface membrane of cells has been studied. In each case the following changes are initiated: collapse of membrane potential, leakage of ions, and leakage of phosphorylated metabolites. The changes can be inihibited by extracellular Ca²⁺ at physiological concentration; Mg²⁺ is less effective, and Zn²⁺ is more effective, than Ca²⁺ Ca²⁺ appears to act at a stage subsequent to the binding of pore-forming agent to cells. It is concluded that divalent cations are able to protect cells against the damaging effects of certain viruses, toxins or the components of activated complement in a manner that is worthy of further investigation.     

Subcellular localization of Forssman glycolipid in epithelial MDCK cells by immuno-electronmicroscopy after freeze-substitution

Forssman antigen, a neutral glycosphingolipid carrying five monosaccharides, was localized in epithelial MDCK cells by the immunogold technique. Labeling with a well defined mAb and protein A-gold after freeze-substitution and low temperature embedding in Lowicryl HM20 of aldehyde-fixed and cryoprotected cells, resulted in high levels of specific labeling and excellent retention of cellular ultrastructure compared to ultra-thin cryosections. No Forssman glycolipid was lost from the cells during freeze-substitution as measured by radio-immunostaining of lipid extracts. Redistribution of the glycolipid between membranes did not occur. Forssman glycolipid, abundantly expressed on the surface of MDCK II cells, did not move to neighboring cell surfaces in cocultures with Forssman negative MDCK I cells, even though they were connected by tight junctions. The labeling density on the apical plasma membrane was 1.4-1.6 times higher than basolateral. Roughly two-thirds of the gold particles were found intracellularly. The Golgi complex was labeled for Forssman as were endosomes, identified by endocytosed albumin-gold, and lysosomes, defined by double labeling for cathepsin D. In most cases, the nuclear envelope was Forssman positive, but the labeling density was 10-fold less than on the plasma membrane. Mitochondria and peroxisomes, the latter identified by catalase, remained free of label, consistent with the notion that they do not receive transport vesicles carrying glycosphingolipids. The present method of lipid immunolabeling holds great potential for the localization of other antigenic lipids.     

Nature of Ribonuclease-resistant Nucleic Acid of Chick Embryo Cells transformed by Schmidt–Ruppin Strain of Rous Sarcoma Virus

THE mode of replication of RNA or RNA-containing tumour viruses is not understood. The recent studies on Rous sarcoma and other RNA-containing oncogenic viruses suggest that the replicative cycle of the RNA of these viruses might not be associated with ribonuclease-resistant structures (double stranded RNAs), but might involve the synthesis of a DNA intermediate specific to viral RNA^1–3. Two groups of workers, however, presented evidence for the presence of a double stranded RNA in 78 Al cell line of rat embryo fibroblasts which had been transformed and chronically infected with the murine sarcoma-leukaemia virus complex (MSV-MLV)^4,5 and it was suggested that the mode of replication of oncogenic viral RNAs was the same as that of non-oncogenic viral RNAs⁴. This apparent discrepancy prompted me to look for ribonuclease-resistant RNA structures in the chick embryo cells transformed by Schmidt-Ruppin Rous sarcoma virus (SR-RSV).     

Infection of Tumour Cells by Fowl Plague Virus in the Presence of Actinomycin D

INFLUENZA virus is one of the few viruses in which replication is inhibited by the antimetabolite actinomycin D (AM-D)^1–4, which inhibits DNA-dependent RNA synthesis in mammalian cells⁵. It has been reported that the growth of fowl plague virus (FPV) in virus-transformed hamster cells is less sensitive to AM-D^6,7. We have examined the sensitivity of FPV to AM-D to see whether it is related to differences in the oncogenic properties of tumour cells. We found that in cells transformed by polyoma virus (PV) and also in cells transformed by methylcholanthrene, although no infectious virus was produced the cells synthesized viral haemagglutinin (HA). It was only the cell-associated HA, however, that was affected by AM-D and not that released by the cells.     

Agglutination of Normal and Rous Sarcoma Virus-transformed Chick Embryo Cells by Concanavalin A and Wheat Germ Agglutinin

RODENT cells in culture transformed by oncogenic DNA viruses have surface sites that on normal cells are usually present in latent form only^1,2. This difference in surface properties can be detected by plant glycoproteins such as wheat germ agglutinin (WGA) and concanavalin A (Con A), which agglutinate only transformed cells, because they have certain carbohydrate moieties on their neoplastic surfaces^1–4. According to some investigators, normal and neoplastic cells that have been freshly isolated also exhibit this marked difference^3,5; according to others^6,7, there is no such distinction. We have looked for such differences in cells transformed by RNA tumour viruses and in several types of normal and naturally occurring malignant cells and their normal counterparts.     

Polar appearance and nonligand induced spreading of measles virus hemagglutinin at the surface of chronically infected cells

Fixation with glutaraldehyde (GA) and paraformaldehyde (PFA) preserved measles virus hemagglutinin at the surface of chronically infected cells. Cells fixed with PFA but not with GA exhibited hemadsorption with green monkey cells. PFA fixation, in contrast to GA fixation, also preserved the immunogenicity of measles virus hemolysin.These fixatives and the removal of the measles virus hemagglutinin from the cell surface by trypsin enabled studies of the appearance of the hemagglutinin at the surface membrane. Results obtained by immunofluorescence technique and by hemadsorption indicated that measles virus hemagglutinin appeared polarly at the cell membrane and then spread around the surface. This was substantiated by measurements of the immunofluorescence intensity at the single cell level per membrane unit and per cell, and by measuring the binding of iodinated immunoglobulins per 10⁶ cells. The appearance was inhibited by sodium azide and cytochalasin B. The spreading was not inhibited by sodium azide, but was influenced by cytochalasin B. The spreading did not proceed at 4°C. On the basis of these findings, a hypothetical model for appearance and spreading of measles virus hemagglutinin was proposed.     

Association of spectrin with its membrane attachment site restricts lateral mobility of human erythrocyte integral membrane proteins

Interactions between spectrin and the inner surface of the human erythrocyte membrane have been implicated in the control of lateral mobility of the integral membrane proteins. We report here that incubation of “leaky” erythrocytes with a water-soluble proteolytic fragment containing the membrane attachment site for spectrin achieves a selective and controlled dissociation of spectrin from the membrane, and increases the rate of lateral mobility of fluorescein isothiocyanate-labeled integral membrane proteins (> 70% of label in band 3 and PAS-1). Mobility of membrane proteins is measured as an increase in the percentage of uniformly fluorescent cells with time after fusion of fluorescent with nonfluorescent erythrocytes by Sendai virus. The cells are permeable to macromolecules since virus-fused erythrocytes lose most of their hemoglobin. The membrane attachment site for spectrin has been solubilized by limited proteolysis of inside-out erythrocyte vesicles and has been purified (V). Bennett, J Biol Chem 253:2292 (1978). This 72,000-dalton fragment binds to spectrin in solution, competitively inhibits association of ³²P-spectrin with inside-out vesicles with a K_i of 10^?7M, and causes rapid dissociation of ³²P-spectrin from vesicles. Both acid-treated 72,000-dalton fragment and the 45,000 dalton-cytoplasmic portion of band 3, which also was isolated from the proteolytic digest, have no effect on spectrin binding, release, or membrane protein mobility. The enhancement of membrane protein lateral mobility by the same polypeptide that inhibits binding of spectrin to inverted vesicles and displaces spectrin from these vesicles provides direct evidence that the interaction of spectrin with protein components in the membrane restricts the lateral mobility of integral membrane proteins in the erythrocyte.     

Analysis of Immunoprecipitated Surface Glycoproteins in Measles Virions and in Membranes of Infected Cells

Measles viral envelope proteins were immune precipitated from membranes of infected cells and from purified virus and analyzed by polyacrylamide gel electrophoresis. Under reducing conditions, specific precipitates contained two major polypeptide bands, designated virus glycopeptides 1 and 2 (VGP-1 and VGP-2). Both polypeptides appeared to be glycosylated, as indicated by their incorporation of [¹⁴C]glucosamine in infected cells. VGP-2 appeared as a single band in specific precipitates of infected cells and as a double band in precipitates of purified virus. Trypsin treatment of infected cells showed that reduced VGP-2 may be composed of two unrelated polypeptides. One may be F₁, which is unglycosylated, and the other may correspond to the proteolytic cleavage product of VGP-1, which is glycosylated. The relation of VGP-1 and VGP-2 to smaller surface antigens (X and Y) obtained by tryptic treatment of infected cells remains to be elucidated. In cells taken at various times postinfection and analyzed for viral membrane proteins, VGP-1 was detected at all times, indicating that the input virus VGP-1 was inserted into the cell and could not be differentiated from newly synthesized VGP-1. VGP-2 was not detectable before 24 h postinfection. In precipitates of cells 4 h postinfection and of infected cells incubated at pH 5.8, an additional polypeptide band migrated immediately ahead of VGP-1. We conclude that VGP-2 (molecular weight, 42,000) possibly consists of two components, one of which is the tryptic cleavage product of VGP-1 and the other of which is the unglycosylated polypeptide, F₁.     

Development of a novel mammalian display system for selection of antibodies against membrane proteins

Reliable, specific polyclonal and monoclonal antibodies are important tools in research and medicine. However, the discovery of antibodies against their targets in their native forms is difficult. Here, we present a novel method for discovery of antibodies against membrane proteins in their native configuration in mammalian cells. The method involves the co-expression of an antibody library in a population of mammalian cells that express the target polypeptide within a natural membrane environment on the cell surface. Cells that secrete a single-chain fragment variable (scFv) that binds to the target membrane protein thereby become self-labeled, enabling enrichment and isolation by magnetic sorting and FRET-based flow sorting. Library sizes of up to 10⁹ variants can be screened, thus allowing campaigns of naïve scFv libraries to be selected against membrane protein antigens in a Chinese hamster ovary cell system. We validate this method by screening a synthetic naïve human scFv library against Chinese hamster ovary cells expressing the oncogenic target epithelial cell adhesion molecule and identify a panel of three novel binders to this membrane protein, one with a dissociation constant (K_D) as low as 0.8 nm. We further demonstrate that the identified antibodies have utility for killing epithelial cell adhesion molecule–positive cells when used as a targeting domain on chimeric antigen receptor T cells. Thus, we provide a new tool for identifying novel antibodies that act against membrane proteins, which could catalyze the discovery of new candidates for antibody-based therapies.     

Polarity of the Forssman glycolipid in MDCK epithelial cells

To determine whether epithelial plasma membrane glycolipids are polarized in a manner analogous to membrane proteins, MDCK cells grown on permeable filters were analyzed for the expression of Forssman ceramide pentasaccharide, the major neutral glycolipid in these cells. In contrast to a recent report which described exclusive apical localization of the Forssman glycolipid (Hansson, G.C., Simons, K. and Van Meer, G. (1986) EMBO J. 5, 483-489), immunofluorescence and immunoelectron microscopic staining revealed the Forssman glycolipid on both the apical and basolateral surfaces of polarized cells. Immunoblots indicated that the Forssman antigen was detectable only on glycolipids and not on proteins. Analysis of metabolically labeled glycolipids released into the apical and basal culture medium, either as shed membrane vesicles or in budding viruses, also demonstrated the presence of the Forssman glycolipid on both apical and basolateral membranes of polarized cells. Quantitation of the released glycolipid indicated that the Forssman glycolipid was concentrated in the apical membrane. These results are consistent with previous reports which described quantitative enrichment of glycolipids in the apical domain of several epithelia.     

Forssman Reactivity and Cell Contacts in Cultured Hamster Cells

THE net synthesis of Forssman hapten glycolipid is enhanced in contact-inhibited NIL cells, particularly in the early stages of contact inhibition^1,2. We have now found that the surface reactivity of cells to anti-Forssman glycolipid antiserum is, however, significantly decreased when they are contact inhibited.     

Location of the Glycoprotein in the Membrane of Sindbis Virus

SINDBIS virus, which is transmitted by arthropods, consists of a nucleoprotein core within a lipid-containing envelope. Its components assemble at a cellular membrane and virus particles form by an outfolding of this membrane. Thus, such viruses provide useful systems for studies of the structure and synthesis of membranes. The Sindbis virus particle contains only two proteins, one associated with the viral envelope and the other with the viral RNA in the core, or nucleocapsid¹. The protein associated with the membrane is a glycoprotein, whereas the core protein contains no carbohydrate². The exact location of the glycoprotein within the viral envelope has not been determined, nor has information been obtained about the function of the carbohydrate in the virion. The results described here indicate that the spikes which cover the surface of the virion are glycoprotein in nature.     

The degradation and turnover of fucosylated glycoproteins in the plasma membrane of a neuroblastoma-cell line

When monolayer cultures of neuroblastoma N2a cells were prelabelled with [³H]fucose to steady state, and then reincubated in complete medium in the presence of unlabelled 40mm-l-fucose, there was a rapid metabolism of fucosylated cellular macromolecules and the specific radioactivity of the acid-insoluble material decreased by 22% within 2h. After this period of time the remaining radioactive glycoproteins appeared to be more stable and the rate of loss of specific radioactivity markedly decreased. Since fucose is known to be associated predominantly with plasma-membrane components, the analysis of fucosylated glycoproteins was characterized in plasma-membrane fractions by polyacrylamide-gel electrophoresis. Two experimental approaches were used to measure glycoprotein degradation and turnover in the cell-surface membranes. In one set of experiments, with a similar incubation procedure to that used with intact cells, three membrane components were rapidly degraded (150000, 130000 and 48000 daltons), but another surface glycoprotein (68000 daltons) appeared to be more slowly metabolized than the mean rate of glycoprotein degradation. The relationship of the degradation of membrane glycoproteins to their turnover was analysed by dual-label experiments that used both [¹⁴C]fucose and [³H]fucose. Glycoproteins of the surface membrane of neuroblastoma cells were found to turn over at heterogeneous rates. The components mentioned above that exhibited significantly rapid rates of degradation, were also shown to turn over more rapidly than the average surface component. In addition to the membrane components detected by the use of only [³H]fucose, dual-label experiments illustrated that numerous surface glycoproteins were metabolized more rapidly or slowly than most of the cell-surface constituents.