Proteins encoded by open reading frames 3 and 4 of the genome of Lelystad virus (Arteriviridae) are structural proteins of the virion.

Four structural proteins of Lelystad virus (Arteriviridae) were recognized by monoclonal antibodies in a Western immunoblotting experiment with purified virus. In addition to the 18-kDa integral membrane protein M and the 15-kDa nucleocapsid protein N, two new structural proteins with molecular masses of 45 to 50 kDa and 31 to 35 kDa, respectively, were detected. Monoclonal antibodies that recognized proteins of 45 to 50 kDa and 31 to 35 kDa immunoprecipitated similar proteins expressed from open reading frames (ORFs) 3 and 4 in baculovirus recombinants, respectively. Therefore, the 45- to 50-kDa protein is encoded by ORF3 and the 31- to 35-kDa protein is encoded by ORF4. Peptide-N-glycosidase F digestion of purified virus reduced the 45- to 50-kDa and 31- to 35-kDa proteins to core proteins of 29 and 16 kDa, respectively, which indicates N glycosylation of these proteins in the virion. Monoclonal antibodies specific for the 31- to 35-kDa protein neutralized Lelystad virus, which indicates that at least part of this protein is exposed at the virion surface. We propose that the 45- to 50-kDa and 31- to 35-kDa structural proteins of Lelystad virus be named GP3 and GP4, to reflect their glycosylation and the ORFs from which they are expressed. Antibodies specific for GP3 and GP4 were detected by a Western immunoblotting assay in swine serum after an infection with Lelystad virus.     

Characterization of a 100-kilodalton binding protein for the six serotypes of coxsackie B viruses.

Viral infection of host cells primarily depends on binding of the virus to a specific cell surface protein. In order to characterize the binding protein for group B coxsackieviruses (CVB), detergent-solubilized membrane proteins of different cell lines were tested in virus overlay protein-binding assays. A prominent virus-binding protein with a molecular mass of 100 kDa was detected in various CVB-permissive human and monkey cell lines but was not detected in nonpermissive cell lines. The specificity of CVB binding to the 100-kDa protein on permissive human cells was substantiated by binding of all six serotypes of CVB and by competition experiments. In contrast, poliovirus and Sendai virus did not bind to the 100-kDa CVB-specific protein. A fraction of HeLa membrane proteins enriched in the range of 100 kDa showed functional activity by transforming infectious CVB (160S) into A-particles (135S). In order to purify this CVB-binding protein, solubilized membrane proteins from HeLa cells were separated by preparative sodium dodecyl sulfate-polyacrylamide gel electrophoresis followed by elution of the 100-kDa protein. Amino acid sequence analysis of tryptic fragments of the CVB-binding protein indicated that this 100-kDa CVB-specific protein is a cell surface protein related to nucleolin. These results were confirmed by immunoprecipitations of the CVB-binding protein with nucleolin-specific antibodies, suggesting that a nucleolin-related membrane protein acts as a specific binding protein for the six serotypes of CVB.     

Identification of two surface proteins from C6/36 cells that bind dengue type 4 virus.

Dengue viruses infect cells by attaching to a surface receptor, probably through the envelope (E) glycoprotein, located on the surface of the viral membrane. However, the identity of the dengue virus receptor in the mosquito and in mammalian host cells remains unknown. To identify and characterize the molecules responsible for binding dengue virus, overlay protein blot and binding assays were performed with labeled virus. Two glycoproteins of 40 and 45 kDa located on the surface of C6/36 cells bound dengue type 4 virus. Virus binding by total and membrane proteins obtained from trypsin-treated cells was inhibited, while neuraminidase treatment did not inhibit binding. Periodate treatment of cell proteins did not reduce virus binding, but it modified the molecular weight of the polypeptide detected by overlay assays. Preincubation of C6/36 cells with electroeluted 40- and 45-kDa proteins or with specific antibodies raised against these proteins inhibited virus binding. These results strongly suggest that the 40- and 45-kDa surface proteins are putative receptors or part of a receptor complex for dengue virus.     

Identification of a putative coreceptor on Vero cells that participates in dengue 4 virus infection

Dengue virus infects target cells by attaching to a cell surface receptor through the envelope (E) glycoprotein, located on the surface of the viral membrane. On Vero and BHK cells, heparan sulfate (HS) moieties of proteoglycans are the receptors for dengue virus; however, additional proteins have also been described as putative dengue virus receptors on C6/36, HL60, and BM cells. HS can also act as a receptor for other types of viruses or as an attachment molecule for viruses that require additional host cell molecules to allow viral penetration. In this study we searched for molecules other than HS that could participate in dengue virus infection of Vero cells. Labeled dengue 4 virus bound with high affinity to two molecules of 74 and 44 kDa. Binding of dengue virus to the 74-kDa molecule was susceptible to protease and sodium periodate treatment and resistant to heparinase treatments. Lectins such as concanavalin A and wheat germ agglutinin prevented dengue virus binding to both the 74- and the 44-kDa protein in overlay assays, while phytohemagglutinin P did not affect binding, suggesting that carbohydrate residues (alpha-mannose or N-acetylglucosamine) are important in virus binding to host cells. Protease susceptibility, biotin labeling, and immunofluorescence with a polyclonal antibody raised against the 74-kDa protein consistently identified the protein on the surfaces of Vero cells. Moreover, the antibody against the 74-kDa protein was able to inhibit dengue virus infection. These data suggest that HS might serve as a primary receptor, probably concentrating virus particles on the surfaces of Vero cells, and then other molecules, such as the 74-kDa protein, might participate as coreceptors in viral penetration. The 74-kDa protein possibly constitutes part of a putative receptor complex for dengue virus infection of Vero cells.     

Serotype-specific entry of dengue virus into liver cells: identification of the 37-kilodalton/67-kilodalton high-affinity laminin receptor as a dengue virus serotype 1 receptor

Dengue virus, the causative agent of dengue fever, dengue shock syndrome, and dengue hemorrhagic fever, infects susceptible cells by initially binding to a receptor(s) located on the host cell surface. Evidence to date suggests that receptor usage may be cell and serotype specific, and this study sought to identify dengue virus serotype 1 binding proteins on the surface of liver cells, a known target organ. By using a virus overlay protein binding assay (VOPBA), in both nondenaturing and denaturing gel systems, a putative dengue virus serotype 1 binding protein of approximately 37 kDa expressed on the surface of liver (HepG2) cells was identified. Mass spectrometry analysis identified a candidate protein, the 37/67-kDa high-affinity laminin receptor. Entry of the dengue virus serotype 1 was significantly inhibited in a dose-dependent manner by both antibodies directed against the 37/67-kDa high-affinity laminin receptor and soluble laminin. No inhibition of virus entry was seen with dengue virus serotypes 2, 3, or 4, demonstrating that the 37/67-kDa high-affinity laminin receptor is a serotype-specific receptor for dengue virus entry into liver cells.     

Multimeric structure of the membrane erythropoietin receptor of murine erythroleukemia cells (Friend cells). Cross-linking of erythropoietin with the spleen focus-forming virus envelope protein.

In erythroleukemia cells infected with the polycythemia strain of the Friend virus complex, erythropoietin could be cross-linked mainly to a protein of 63 kDa when using disuccinimidyl suberate. In contrast, erythropoietin in other erythroleukemia cells cross-linked to two proteins of 85 and 100 kDa. When native erythropoietin receptor complexes were immunoprecipitated, the 63-kDa erythropoietin-cross-linked protein could be precipitated both by antibodies directed against the intracellular part of the cloned chain of the erythropoietin receptor and by antibodies directed against the envelope proteins of the Friend virus. However, after denaturation of the complexes, the 63-kDa protein was only precipitated by antibodies directed against the envelope proteins of the Friend virus. Enzymatic deglycosylation confirmed that erythropoietin was cross-linked with the envelope protein of the defective virus and bidimensional diagonal gel electrophoresis analyses showed that some of the erythropoietin cross-linked envelope proteins were dimerized by disulfide bonds. Thus, the main erythropoietin-receptor complex in the plasma membrane of these cells consisted of a molecule of the cloned chain of the erythropoietin receptor noncovalently associated with one or two disulfide-bonded molecule(s) of the envelope protein of the defective virus. Moreover, our results also showed that the viral envelope protein associated with the cloned chain of the erythropoietin receptor at a site distinct from the erythropoietin binding site.     

Mycobacterium tuberculosis Rv2536 protein implicated in specific binding to human cell lines

The gene encoding the Mycobacterium tuberculosis Rv2536 protein is present in the Mycobacterium tuberculosis complex (as assayed by PCR) and transcribed (as determined by RT-PCR) in M. tuberculosis H37Rv, M. tuberculosis H37Ra, M. bovis BCG, and M. africanum strains. Rabbits immunized with synthetic polymer peptides from this protein produced antibodies specifically recognizing a 25-kDa band in mycobacterial sonicate. U937 and A549 cells were used in binding assays involving 20-amino-acid-long synthetic peptides covering the whole Rv2536 protein sequence. Peptide 11207 (161DVFSAVRADDSPTGEMQVAQY180) presented high specific binding to both types of cells; the binding was saturable and presented nanomolar affinity constants. Cross-linking assays revealed that this peptide specifically binds to 50 kDa U937 cell membrane and 45 kDa A549 cell membrane proteins.     

Ovine cells: their long-term cultivation and susceptibility to visna virus.

Sheep choroid plexus (SCP) cells have been subcultured more than 120 times and have undergone over 300 cell generations. These fibroblastic-appearing SCP II-B cells contain ovine-specific antigens, have an absolute plating efficiency of 23 to 28% and are as susceptible to visna virus infection and virus-induced cytopathology as their low passage level counterparts. Cultures of low, relatively high and high passage level SCP cells produced equivalent amounts of visna virus at similar rates when infected with equal amounts of visna virus. The passage level of the SCP II-B cells, their elapsed number of cell generations, their possession of ovine-specific antigens and their full susceptibility to visna virus allow these cells to be considered an established line of sheep cells.     

The human cytomegalovirus receptor on fibroblasts is a 30-kilodalton membrane protein.

Previous studies have demonstrated that human cytomegalovirus (HCMV) binding to human foreskin fibroblasts (HFF) is mediated by a single type of molecule, likely a glycoprotein, which serves as a specific receptor for the virus. In the present experiments, HCMV was found to bind to an HFF membrane protein with an approximate molecular mass of 30 kilodaltons (kDa); weak binding to 28- and 92-kDa membrane components was also observed. Binding was specific, as it was inhibited by excess unlabeled HCMV. Radiolabeled HCMV also bound selectively to Raji and Daudi lymphoblastoid cell membrane proteins of the same molecular masses. The 30-kDa radiolabeled HFF membrane protein bound to HCMV in solution; this binding was also specific, as it was blocked by an excess of HCMV. These data suggest that a membrane protein with a molecular mass of approximately 30 kDa mediates HCMV binding to several cell types.     

Ovine cells: Their long-term cultivation and susceptibility to visna virus

Summary Sheep choroid plexus (SCP) cells have been subcultured more than 120 times and have undergone over 300 cell generations. These fibroblastic-appearing SCP II-B cells contain ovine-specific antigens, have an absolute plating efficiency of 23 to 28% and are as susceptible to visna virus infection and virus-induced cytopathology as their low passage level counterparts. Cultures of low, relatively high and high passage level SCP cells produced equivalent amounts of visna virus at similar rates when infected with equal amounts of visna virus. The passage level of the SCP II-B cells, their elapsed number of cell generations, their possession of ovine-specific antigens and their full susceptibility to visna virus allow these cells to be considered an established line of sheep cells. This work was partially supported by grants from the National Cancer Institute (CA12678) and the National Institute of Allergy and Infectious Diseases (AI12465).     

Visna virus synthesized in absence of host-cell division and DNA synthesis

Visna virus is similar to the avian and the murine oncornaviruses. Oncornavirus replication is dependent upon the provirus being integrated into the host cell's DNA but integration and subsequent oncornavirus synthesis is blocked when the host cells are prevented from synthesizing cellular DNA or dividing. The synthesis of visna virus is restricted in vivo and may be dependent upon the host cell's ability to synthesize cellular DNA or divide. Treatment of sheep choroid plexus (SCP) cells with ultraviolet light or with mitomycin C prior to infection irreversibly inhibited plexus (ScP) cells with ultraviolet light or with mitomycin C prior to infection irreversibly inhibited both cell division and cellular nucleic acid synthesis but did not inhibit visna virus synthesis. Similarly, the synthesis of visna virus in cultures of SCP cells which had been prevented from dividing by being deprived of serum and in cultures of SCP cells which were incapable of synthesizing host cell nucleic acids by being treated with miracil D or sodium hexachloroiridate was equivalent to the synthesis of visna virus in cultures of SCP cells which were allowed to both synthesize cellular nucleic acids and divide. The synthesis of visna virus in the presence of ethidium bromide further demonstrated that integration of the visna provirus into the host cell's DNA is not required for visna virus synthesis to occur.     

Isolation and characterization of two binding proteins for advanced glycosylation end products from bovine lung which are present on the endothelial cell surface.

Nonenzymatic glycosylation of proteins, as occurs at an accelerated rate in diabetes, can lead to the formation of advanced glycosylation end products of proteins (AGEs), which can bind to endothelial cells, thereby altering cellular function in a manner which could contribute to the pathogenesis of diabetic angiopathy. In this report, we describe the isolation of two endothelial cell surface-associated proteins which mediate, at least in part, the interaction of AGEs with endothelium. Based on pilot studies demonstrating AGE binding activity with comparable characteristics in bovine endothelial cell and lung extracts, the material from lung was sequentially subjected to chromatography on hydroxylapatite, fast protein liquid chromatography Mono S, and gel filtration. Two distinct polypeptides, approximately 35 and approximately 80 kDa, were purified to homogeneity, each of which bound AGEs as demonstrated by competitive binding assays using cellular binding proteins immobilized on a plastic surface. NH2-terminal sequence analysis indicated that the approximately 35-kDa protein was novel, whereas the NH2-terminal sequence of the approximately 80-kDa protein was identical to that of lactoferrin. Immunocytologic studies using polyclonal antibody prepared to each of the purified polypeptides demonstrated the presence of immunoreactive material on the surface of bovine endothelial cells maintained under serum-free conditions. Furthermore, immunoelectron microscopic studies with antibodies to the approximately 35- and approximately 80-kDa AGE-binding proteins conjugated to different size colloidal gold particles confirmed the presence of the target antigens on the cell surface and suggested that they were closely associated. IgG purified from polyclonal antisera to either the 35- or 80-kDa AGE-binding proteins blocked the binding of 125I-AGE-albumin to the cell surface. These results indicate that endothelial cells express specific cell surface molecules which mediate AGE-endothelial interaction. These polypeptides represent a novel class of cell surface acceptor molecules for glucose-modified proteins which may promote degradation and/or transcytosis of the ligand, and modulation of cellular function.     

Identification of a putative receptor for subgroup A feline leukemia virus on feline T cells.

Retrovirus infection is initiated by the binding of virus envelope glycoprotein to a receptor molecule present on cell membranes. To characterize a receptor for feline leukemia virus (FeLV), we extensively purified the viral envelope glycoprotein, gp70, from culture supernatants of FeLV-61E (subgroup A)-infected cells by immunoaffinity chromatography. Binding of purified 125I-labeled gp70 to the feline T-cell line 3201 was specific and saturable, and Scatchard analysis revealed a single class of receptor binding sites with an average number of 1.6 x 10(5) receptors per cell and an apparent affinity constant (Ka) of 1.15 x 10(9) M-1. Cross-linking experiments identified a putative gp70-receptor complex of 135 to 140 kDa. Similarly, coprecipitation of 125I-labeled cell surface proteins with purified gp70 and a neutralizing but noninterfering anti-gp70 monoclonal antibody revealed a single cell surface protein of approximately 70 kDa. These results indicate that FeLV-A binds to feline T cells via a 70-kDa cell surface protein, its presumptive receptor.     

Identification and characterization of the cell surface 70-kilodalton sialoglycoprotein(s) as a candidate receptor for encephalomyocarditis virus on human nucleated cells.

The attachment of encephalomyocarditis (EMC) virus to human nucleated cells susceptible to virus infection was examined with HeLa and K562 cell lines. Both cell types showed specific virus binding competitively blocked by unlabeled virions. The number of binding sites for EMC virus on HeLa and K562 cells were approximately 1.6 x 10(5) and 3.5 x 10(5) per cell, respectively, and dissociation binding constants were 1.1 and 2.7 nM, respectively. Treatment of cells with cycloheximide after pretreatment with trypsin eliminated EMC virus attachment, suggesting that the virus-binding moiety is proteinaceous in nature. Digestion of cells, cell membranes, and sodium deoxycholate-solubilized cell membranes with proteases or neuraminidases or treatment of cells with lectins demonstrated that the EMC virus-cell interaction is mediated by a sialoglycoprotein. Proteins with a molecular mass of 70 kDa were isolated from detergent-solubilized cell membranes of both HeLa and K562 cells by EMC virus affinity chromatography. The purified proteins, as well as their 70-kDa-molecular-mass equivalents detected in intact surface membranes of HeLa and K562 cells, specifically bound EMC virus in a virus overlay protein blot assay, whereas membranes from nonpermissive K562 D clone cells did not. Western immunoblot analysis with glycophorin A-specific antibody confirmed that the identified 70-kDa binding site on K562 cells is not glycophorin A, which is the EMC virus receptor molecule on virus-nonpermissive human erythrocytes (HeLa cells do not express glycophorin A). These results indicate that EMC virus attachment to permissive human cells is mediated by a cell surface sialoglycoprotein(s) with a molecular mass of 70 kDa.     

Isolation and characterization of a 58-kDa membrane- and microfilament-associated protein from ascites tumor cell microvilli

A 58-kDa protein is found in microvilli and in actin-containing transmembrane complexes of 13762 ascites tumor cells with immobile surface receptors; it is absent from sublines with mobile receptors. 58-kDa protein has been proposed to stabilize microvilli and restrict receptor mobility by stabilizing membrane-microfilament interactions. Antibodies against 58-kDa protein were blot-purified from antisera of rabbits injected with crude transmembrane complex and were used to monitor purification of the protein. 58-kDa protein was extracted from EDTA/EGTA-stripped microvillar microfilament cores with 1 M NaCl. A single depolymerization-polymerization cycle of the microfilaments, followed by solubilization of 58-kDa protein in 1 M NaCl and chromatography on hydroxyapatite-Sephadex G-150, purified the protein to greater than 95% homogeneity. The native molecular weight and frictional coefficient indicated a monomeric, asymmetric structure. 58-kDa protein bound F-actin in pelleting assays and inhibited polymerization of pyrenyl-actin. It also bound phosphatidylserine, phosphatidylinositol, and phosphatidylcholine vesicles in pelleting studies. Immunoblot analyses of endogenously and exogenously proteolyzed microvilli and their membranes and microfilament cores showed specific membrane and microfilament binding fragments of 28-30 kDa. The microfilament- and phospholipid-binding properties of 58-kDa protein and the localization of its proteolysis products are consistent with its proposed role in stabilizing membrane-microfilament interactions in the ascites cell microvilli.     

The 1A protein of respiratory syncytial virus is an integral membrane protein present as multiple, structurally distinct species.

The respiratory syncytial virus (RSV) 1A protein was previously identified as a 7.5-kilodalton (kDa) nonglycosylated species that, on the basis of its predicted sequence determined from the sequence of its mRNA, contains a hydrophobic central domain that was suggestive of membrane interaction. Here, four major, structurally distinct intracellular species of the 1A protein were identified in cells infected by RSV or by a recombinant vaccinia virus expressing the 1A gene. The four species of 1A were: (i) the previously described, nonglycosylated 7.5-kDa species that appeared to be the full-length, unmodified 1A protein; (ii) a nonglycosylated 4.8-kDa species that was carboxy-coterminal with the 7.5-kDa species and might be generated by translational initiation at the second AUG in the sequence; (iii) a 13- to 15-kDa species that contained one or two N-linked carbohydrate side chains of the high-mannose type; and (iv) a 21- to 30-kDa glycosylated species that appeared to be generated from the 13- to 15-kDa species by further modification of the N-linked carbohydrate. All four forms of the 1A protein were synthesized and processed on intracellular membranes, and several lines of biochemical evidence showed that all four species were integral membrane proteins. Thus, the 1A protein is a third RSV integral membrane protein and is present as such in both glycosylated and nonglycosylated forms. With the use of antiserum raised against a synthetic peptide representing the C terminus of the 1A protein, indirect immunofluorescence showed that the 1A protein was expressed at the cell surface. Antibody-antigen complexes formed at the surface of intact infected cells were immunoprecipitated, showing that the 7.5-kDa, 13- to 15-kDa, and 21- to 30-kDa, but not the 4.8-kDa, species, were accessible to extracellular antibodies. Thus, the 1A protein is a candidate to be a viral surface antigen. The small size, gene map location integral membrane association, and cell surface expression of the 1A protein strongly suggested that it is a counterpart to the SH protein that has been described for simian virus type 5. We suggest that, in the future, the RSV 1A protein be given the same designation, namely, SH.     

Purification, characterization and comparison with mammalian SCP2 of a chicken SCP2-like protein.

1. Three proteins have been isolated from chicken (Gallus domesticus) liver that bind antibodies directed against authentic rat sterol carrier protein2 (SCP2) and have similar molecular mass to the three major immunoreactive rat liver proteins (12 kDa, 30-36 kDa, 55-60 kDa). 2. Bile from both chicken and rat contains the high molecular mass immunoreactive species. 3. The chicken 12 kDa SCP2-like protein purifies similarly to rat SCP2 but the homogeneous chicken SCP2-like protein is dissimilar in amino acid composition and N-terminal amino acid sequence. 4. The activity of chicken SCP2-like protein differs from rat SCP2 in that it was consistent with fusion (transfer of both polar surface and non-polar core lipids) rather than transfer of polar lipids only.     

Characterization of envelope proteins of alcelaphine herpesvirus 1.

Alcelaphine herpesvirus 1 is a gammaherpesvirus which causes malignant catarrhal fever, an acute lymphoproliferative disorder of cattle and other susceptible Bovidae, which is almost invariably fatal. A preliminary analysis of proteins induced by the virus indicated that as many as six glycoproteins and one nonglycosylated molecule might be present in the virus envelope. Monoclonal antibodies selected for recognition of virion envelope proteins included two that recognized a complex of infected cell proteins, designated the gp115 complex, and neutralized virus infectivity in the absence of complement. The gp115 complex consisted of five glycoproteins of 115, 110, 105, 78, and 48 kilodaltons (kDa), and all except the 48-kDa species reacted with antibody in Western blots (immunoblots). Pulse-chase experiments analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing and nonreducing conditions suggested that the 110-kDa protein was the precursor molecule which was processed by addition of sugars to 115 kDa. The 115-kDa protein was cleaved to form a disulfide-linked heterodimer of 78 and 48 kDa, which was the mature form of the molecule incorporated into the virion envelope. The glycoprotein contained N-linked sugars, but little or no O-linked sugar was present. The relative abundance of the mature protein and its ability to induce neutralizing antibodies suggest that it will prove useful to studies aimed at elucidating the biology and pathogenesis of alcelaphine herpesvirus 1.     

登革2型病毒结合血管内皮细胞分子机制的初步研究

以ECV304细胞为对象分析登革病毒感染血管内皮细胞的机制。2型登革病毒(DEN2)吸附后微量蚀斑法测定ECV304细胞上清释放的病毒滴度,证实该细胞对DEN2感染有一定的敏感性。机械刮取或胰蛋白酶消化法收集ECV304细胞分离膜蛋白,SDS—PAGE见胰酶处理样品缺失一43 kDa的膜蛋白。将ECV304细胞膜蛋白与^35S—Met标记的DEN2进行病毒重叠蛋白结合试验(VOPBA),有29、34和43kDa的3种膜蛋白可与DV结合,其中29 kDa的蛋白对胰酶耐受。培养的ECV304细胞中加入重组E蛋白(rEgp)对DEN2吸附进行阻断试验,微量蚀斑法与间接免疫荧光表明rEgp抑制DEN2感染该细胞。VOPBA中rEgp可阻断病毒与细胞膜蛋白的结合。结果表明ECV304细胞表面可能存在29、34、43 kDa的3种与DEN2结合的相关蛋白,DEN2E蛋白可直接介导DV感染血管内皮细胞。     

Isoform-specific transforming growth factor-beta binding proteins with membrane attachments sensitive to phosphatidylinositol-specific phospholipase C.

We report the identification of cell surface glycoproteins that bind transforming growth factor-beta (TGF-beta) in an isoform-specific manner, and are distinct from TGF-beta receptors I and II or the TGF-beta binding proteoglycan beta-glycan. The novel TGF-beta binding proteins have been identified in various cell lines including fetal bovine heart endothelial cells and MG-63 human osteosarcoma cells. They include proteins of 90-100 and 180 kDa that preferentially bind TGF-beta 1 (KD 0.1-0.2 nM) and proteins of 60 and 140 kDa that preferentially bind TGF-beta 2 (KD 0.5-1 nM). The 180-kDa TGF-beta 1 binding protein and the 60- and 140-kDa TGF-beta 2 binding proteins can be released from the cell surface by treatment with phosphatidylinositol-specific phospholipase C, suggesting that these proteins are attached to the plasma membrane through a phosphatidylinositol anchor. The expression of these three proteins as well as their sensitivity to phosphatidylinositol-specific phospholipase C is cell line-dependent. The 90-100-kDa TGF-beta 1 binding proteins are components of a 190-kDa disulfide-linked complex. The structural properties of these proteins and their high affinity and selectivity for different TGF-beta isoforms defines them as a novel class of cell surface TGF-beta binding proteins.