Characterization of polypeptides immunoprecipitable from Pichinde virus-infected BHK-21 cells

Using hamster anti-Pichinde virus serum, we immunoprecipitated polypeptides from BHK-21 cells infected with Pichinde virus. Seven immunoprecipitable polypeptides exhibited a time- and multiplicity of infection-dependent appearance when the cultures were pulse-labeled with L-[35S]methionine for 1 h. The predominant polypeptide was a nucleoprotein (NP) of 64,000 daltons. Components of 48,000, 38,000, and 28,000 daltons, when analyzed by two-dimensional tryptic peptide mapping, were found to be derived from NP. After a 3-h chase period, polypeptides of 17,000, 16,500, and 14,000 daltons were evident, and peptide mapping revealed that these three polypeptides were also related to NP. During a series of pulse-chase experiments, a 79,000-dalton glycoprotein (GPC) was cleaved to glycoproteins of 52,000 and 36,000 daltons. Radiolabel in a polypeptide of approximately 200,000 daltons (L) did not chase into smaller cleavage products. L, GPC, and NP were found to be unique by two-dimensional tryptic peptide mapping. Comparison of polypeptides immunoprecipitated from infected cells with structural components of purified virus revealed that L protein was evident in both. This is the first report of a high-molecular-weight polypeptide in Pichinde virus particles and infected cells.     

Analysis of intracellular feline leukemia virus proteins II. Generation of feline leukemia virus structural proteins from precursor polypeptides.

The synthesis and processing of feline leukemia virus (FeLV) polypeptides were studied in a chronically infected feline thymus tumor cell line, F-422, which produces the Rickard strain of FeLV. Immune precipitation with antiserum to FeLV p30 and subsequent sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) were used to isolate intracellular FeLV p30 and possible precursor polypeptides. SDS-PAGE of immune precipitates from cells pulse-labeled for 2.5 min with [35S]methionin revealed the presence of a 60,000-dalton precursor polypeptide (Pp60) as well as a 30,000-dalton polypeptide. When cells were grown in the presence of the proline analogue L-azetidine-2-carboxylic acid, a 70,000-dalton precursor polypeptide (Pp70) was found in addition to Pp60 after a 2.5-min pulse. The cleavage of Pp60 could be partially inhibited by the general protease inhibitor phenyl methyl sulfonyl fluoride (PMSF). This partial inhibition was found to occur only if PMSF was present during pulse-labeling. Intracellular Pp70 and Pp60 and FeLV virion p70, p30, p15, p11, and p10 were subjected to tryptic peptide analysis. The results of this tryptic peptide analysis demonstrated that intracellular Pp70 and virion p70 were identical and that both contained the tryptic peptides of FeLV p30, p15, p11, and p10. Pp60 contained the tryptic peptides of FeLV P30, P15, and P10, but lacked the tryptic peptides of P11. The results of pactamycin gene ordering experiments indicated that the small structural proteins of FeLV are ordered p11-p15-p10-p30. The data indicate that the small structural proteins of FeLV are synthesized as part of a 70,000-dalton precursor. A cleavage scheme for the generation of FeLV p70, p30, p15, p11, and p10 from precursor polypeptides is proposed.     

Two small virus-specific polypeptides are produced during infection with Sindbis virus.

We have identified and characterized two small virus-specific polypeptides which are produced during infection of cells with Sindbis virus, but which are not incorporated into the mature virion. The larger of these is a glycoprotein with an approximate molecular weight of 9,800 and is found predominantly in the medium of infected cells. Three independent lines of evidence demonstrate conclusively that this 9,800-dalton glycoprotein is produced during the proteolytic conversion of the precursor polypeptide, PE2, to the virion glycoprotein E2. This small glycoprotein is therefore analogous to the virion glycoprotein E3 of the very closely related alphavirus, Semliki Forest virus. The 9,800-dalton glycoprotein of Sindbis virus, unlike the E3 glycoprotein of Semliki Forest virus, is not, however, present in the viral particle. The other virus-specific polypeptide is 4,200 daltons in size, does not appear to be a glycoprotein, and is neither incorporated into the mature virus nor released into the culture medium. The gene for this small polypeptide is present in the viral 26S mRNA (the mRNA which encodes all the viral structural polypeptides) and appears to be located in the portion of the mRNA which encodes the two viral glycoproteins. The possibility that this 4,200-dalton polypeptide functions as a signal peptide during the synthesis of the viral membrane glycoproteins is discussed.     

Immune reactive measles virus polypeptides on the cell's surface: turnover and relationship of the glycoproteins to each other and to HLA determinants

To better understand the mechanism(s) whereby antibody and complement and cytotoxic lymphocytes lyse infected cells, we studied the structure, interrelationship and turnover of measles virus polypeptides expressed on the cell's surface. Of the 6 major viral structural polypeptides, L, HA, P, NC, F, and M, found in purified virions or infected cells, only 2, the HA and F, resided on the surface of infected cells. The HA was present primarily in the form of a 160k dimer, and F was identified as a 64k polypeptide migrating distinct from other viral polypeptides. With reduction, the HA migrated as a 80k monomer, and F0, after cleavage, was found to be composed of a 42k nonglycosylated polypeptide, F1, and a 24k glycosylated protein, F2. The relationship between F0 and F1 and between the HA dimer and monomer was verified by tryptic peptide mapping. The turnover of HA and F from the cell's surface was 10 and 9 hr, respectively. However, in the presence of specific antibody after a marked loss of viral antigen from the surface, the turnover for HA and F was 15 and 12 hr, respectively. Despite being independent molecules, HA and F were closely linked, as they moved together (co-capped) over the plasma membrane when incubated with monospecific or monoclonal antibody. In contrast, neither HA nor F co-capped with the major histocompatibility antigens or with other host cell proteins, which indicates a separation between these host cell proteins and measles viral glycoproteins on the cell's surface.     

Cell-free synthesis of mouse mammary tumor virus Pr77 from virion and intracellular mRNA.

Mouse mammary tumor virus (MuMTV) was purified from two cell lines (GR and Mm5MT/c1), and the genomic RNA was isolated and translated in vitro in cell-free systems derived from mouse L cells and rabbit reticulocytes. The major translation product in both systems was a protein with the molecular weight 77,000. Several other products were also detected, among them a 110,000-dalton and in minor amounts a 160,000-dalton protein. All three polypeptides were specifically immunoprecipitated by antiserum raised against the major core protein of MuMTV (p27), but they were not precipitated by antiserum against the virion glycoprotein gp52. Analysis of the in vitro products by tryptic peptide mapping established their relationship to the virion non-glycosylated structural proteins. The 77,000-dalton polypeptide was found to be similar, if not identical, to an analogous precursor isolated from MuMTV-producing cells. Peptide mapping of the 110,000-dalton protein shows that it contains all of the methionine-labeled peptides found in the 77,000-dalton protein plus some additional peptides. We conclude that the products synthesized in vitro from the genomic MuMTV RNA are related to the non-glycosylated virion structural proteins. Polyadenylic acid-containing RNA from MuMTV-producing cells also directed the synthesis of the 77,000-dalton polypeptide in the L-cell system. If this RNA preparation was first fractionated by sucrose gradient centrifugation the 77,000-dalton protein appeared to be synthesized from mRNA with a sedimentation coefficient between 25 and 35S.     

Polypeptide Synthesis in Simian Virus 5-Infected Cells

Polypeptide synthesis in three different cell types infected with simian virus 5 has been examined using high-resolution polyacrylamide slab gel electrophoresis, and all of the known viral polypeptides have been identified above the host cell background. The polypeptides were synthesized in infected cells in unequal proportions, which are approximately the same as they are found in virions, suggesting that their relative rates of synthesis are controlled. The nucleocapsid polypeptide (NP) was the first to be detected in infected cells, and by 12 to 14 h the other virion structural polypeptides were identified, except for the polypeptides comprising the smaller glycoprotein (F). However, a glycosylated precursor (F(0)) with a molecular weight of 66,000 was found in each cell type, and pulse-chase experiments suggested that this precursor was cleaved to yield polypeptides F(1) and F(2). No other proteolytic processing was found. In addition to the structural polypeptides, the synthesis of five other polypeptides, designated I through V, has been observed in simian virus 5-infected cells. One of these (V), with a molecular weight of 24,000, was found in all cells examined and may be a nonstructural viral polypeptide. In contrast, there are polypeptides present in uninfected cells that correspond in size to polypeptides I through IV, and similar polypeptides have also been detected in increased amounts in cells infected with Sendai virus. These findings, and the fact that the synthesis of all four of these polypeptides is not increased in every cell type, suggest that they represent host polypeptides whose synthesis may be enhanced upon infection. When a high salt concentration was used to decrease host cell protein synthesis in infected cells, polypeptides IV and (to a lesser extent) I were synthesized in relatively greater amounts than other cellular polypeptides, as were the viral polypeptides. The possibility that these polypeptides may play some role in virus replication is discussed.     

Tryptic peptide analysis of outer capsid polypeptides of mammalian reovirus serotypes 1, 2, and 3.

We studied the structural relationships among the outer capsid polypeptides of prototype strains of mammalian reovirus serotypes 1, 2, and 3 by tryptic peptide mapping. The micron1C polypeptide showed an extraordinary degree of conservation of its methionine-containing tryptic peptides. In contrast, the most abundant viral polypeptide, sigma 3, contained both conserved and unique methionine-containing tryptic peptides. The viral type-specific antigen, the sigma 1 polypeptide, contained both conserved and unique methionine- and tyrosine-containing tryptic peptides. These results suggested that the mammalian reovirus genome segments encoding each of the viral outer capsid polypeptides were derived from common ancestral segments which have diverged to different degrees.     

Measles virus polypeptides in infected cells studied by immune precipitation and one-dimensional peptide mapping.

Measles virus does not turn off host cell polypeptide synthesis, making it difficult to precisely identify the polypeptides specified by the virus during the infectious cycle. By using the technique of immune precipitation with measles-specific antisera, the host cell background has been eliminated, and new observations have been made concerning measles virus polypeptides H, P, NP, F, and M. The H polypeptide is first synthesized as a monomer which is processed by further glycosylation and by the formation of disulfide-bonded dimers. Polypeptide P (70,000 daltons) has been found to occur also as a 65,000-dalton molecule, P2, and both forms of the molecule are equally phosphorylated. Polypeptide NP is processed from a cleavage-sensitive form (which undergoes cleavage during the process of isolation to form polypeptide 6 [41,000 daltons]) to a form which is resistant to this cleavage. The fusion and hemolysin polypeptide is first found in the cells as a 55,000-dalton precursor, F0, which is clearly resolved from the NP polypeptide on gel electrophoresis. The measles virus F0 protein identified in previous reports had not been resolved from the 60,000-dalton NP polypeptide. The M protein occurs in the infected cells as two distinct bands, and, as in the case of Sendai virus, one of these two M protein bands represents a phosphorylated form of the other.     

Comparison of the expression of the src gene of Rous sarcoma virus in vitro and in vivo.

We have compared the polypeptide products of the src gene of several strains of Rous sarcoma virus produced by in vitro translation of heat-denatured 70S virion RNA in the nuclease-treated reticulocyte lysate with those present in chick cells transformed by these viruses. We have done this by immunoprecipitation, using sera from rabbits injected at birth with Schmidt-Ruppin Rous sarcoma virus. In vitro translation results in the synthesis of at least nine polypeptides which appear to be encoded by the src gene. These range in size from 17,000 to 60,000 daltons. The sera from tumor-bearing rabbits precipitated these polypeptides arising from the in vitro translation of RNA from Schmidt-Ruppin Rous sarcoma virus of both subgroup A and subgroup D and from one stock of Prague Rous sarcoma virus of subgroup C. In each case, all of this family of related polypeptides could be precipitated except the smallest, the 17,000-dalton polypeptide. No precipitation of analogous polypeptides resulting from the translation of RNA from other strains of Rous sarcoma virus was observed. Cells transformed by these three strains of Rous sarcoma virus contain easily detectable amounts of a polypeptide, p60src, essentially identical to the 60,000-dalton in vitro product. With one exception, they do not contain significant amounts of polypeptides analogous to the smaller in vitro products which can be precipitated by these sera. Cells transformed by one stock of Schmidt-Ruppin Rous sarcoma virus of subgroup A did contain a 39,000-dalton polypeptide, which was related, by peptide mapping, to the 60,000-dalton polypeptide and was similar in size to a precipitable in vitro product. The 60,000-dalton polypeptide present in transformed cells appeared to be phosphorylated 10 to 25 min after its synthesis, metabolically very stable, and not derived from a precursor polypeptide. All immunoprecipitates from transformed cells which contained p60src also contained an 80,000-dalton phosphoprotein. This polypeptide is unrelated to p60src, as determined by peptide mapping, and may well be a host cell polypeptide which is specifically associated with p60src.     

Purification of measles virus and characterization of subviral components.

Purified measles virus was obtained from [35S]methionine-labeled cells infected at 33 degrees C and maintained in the absence of fetal calf serum. The pellet that was produced by a single high-speed ultracentrifuge spin of culture medium contained virus of purity sufficient for structural analysis. Purified virions contain seven polypeptides with estimated molecular weights of: L, 200,000; G, 80,000; P2, 70,000; NP, 60,000; A, 43,000; F1, 41,000; and M, 37,000, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing conditions. Treatment of virions with 0.25% trypsin resulted in a less dense particle which lacked polypeptides G and F1. Solubilization of the viral membrane with the detergent Triton X-100 in low-salt buffer resulted in the loss of the G polypeptide, whereas in the presence of 1 M KCl, Triton X-100 also removed most of the M polypeptide. The nucleocapsids (p = 1.3) obtained from virions treated with Triton X-100 and 1 M KCl contained the L, P2, NP, and M polypeptides. Nucleocapsids isolated from the cytoplasm of infected cells were predominantly composed of the NP polypeptide with smaller amounts of either polypeptide P2 or novel polypeptides, related to NP, with estimated molecular weights of 56,000 to 58,000 and 45,000 to 46,000. A significant amount of polypeptide L was always found in association with nucleocapsids isolated either from virions or from the cytoplasm of infected cells. A membrane component containing the viral membrane polypeptides G, F1, and M was also isolated from infected cells. The data presented here thus suggest that L is an integral part of the nucleocapsid complex. In addition, 37,000-molecular-weight polypeptide (M) appears to have the function described for the matrix proteins of other paramyxoviruses.     

Evidence for an Adenovirus Type 2-Coded Early Glycoprotein

We have identified an adenovirus type 2 (Ad2)-induced early glycopolypeptide with an apparent molecular weight of 20,000 to 21,000 (20/21K), as estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The 20/21K polypeptide could be labeled in vivo with [(3)H]glucosamine. [(35)S]methionine- and [(3)H]-glucosamine-labeled 20/21K polypeptides bound to concanavalin A-Sepharose columns and were eluted with 0.2 M methyl-alpha-d-mannoside. The pulse-labeled polypeptide appeared as a sharp band with an apparent molecular weight of 21K, but after a chase it converted to multiple bands with an average molecular weight of 20K. This variability in electrophoretic mobility is consistent with glycosylation or deglycosylation of the 20/21K polypeptide. Analysis of the pulse and pulse-chase-labeled forms by using partial proteolysis indicated that the polypeptides were highly related chemically, but not identical. Most of the 20/21K polypeptide is localized in the cytoplasm fraction of infected cells lysed by Nonidet P-40. The 20/21K polypeptide and a 44K polypeptide, labeled with [(35)S]methionine or [(3)H]glucosamine in Ad2-infected human cells, were precipitated by a rat antiserum against an Ad2-transformed rat cell line (T2C4), but not by antisera against three other Ad2-transformed rat cell lines, or by serum from nonimmune rats. The partial proteolysis patterns of the 20/21K and the 44K polypeptides were indistinguishable, indicating that the two polypeptides are highly related, and suggesting that the 44K polypeptide might be a dimer of the 20/21K polypeptide. The 20/21K polypeptide was also induced in Ad2-early infected monkey and hamster cells. These results imply that the 20/21K polypeptide is synthesized in Ad2-infected human, monkey, and hamster cells, and in one but not all Ad2-transformed rat cells. Thus, the 20/21K polypeptide is probably viral coded rather than cell coded and viral induced.     

Genetic diversity in natural populations of mammalian reoviruses: tryptic peptide analysis of outer capsid polypeptides of murine, bovine, and human type 1 and 3 reovirus strains.

We have studied the structural relationships between the outer capsid polypeptides of eight murine, bovine, and human isolates of type 1 and 3 mammalian reoviruses. Our results show that the outer capsid polypeptides of reoviruses isolated from different mammalian species, in different years and different geographical areas, have both conserved and unique methionine-containing tryptic peptides. We found that tryptic peptides from mu 1C polypeptides of two human, one murine, and two bovine type 3 isolates and one human and two bovine type 1 reoviruses are highly conserved. Our data show that only one tryptic peptide pattern of the mu 1C polypeptide (encoded by the M2 gene) was present in reoviruses isolated from the three different mammalian species. The mu 1C polypeptide of the type 3 Dearing strain contained one tryptic peptide not found in any other reovirus isolate examined. In marked contrast to the mu 1C polypeptides, the sigma 3 polypeptides (encoded by the S4 gene) of three type 1 and three type 3 isolates were divided into two patterns based on significant differences in their tryptic peptides. In addition, at least seven tryptic peptides were conserved among the sigma 3 polypeptides of all virus strains examined. The sigma 3 polypeptide of the type 3 Dearing strain was distinguishable from the sigma 3 polypeptides of all other strains examined. The one mu 1C and two sigma 3 tryptic peptide patterns were found to occur interchangeably in isolates of type 1 or type 3. About 1/3 of the tyrosine-containing tryptic peptides of sigma 1 polypeptides of four type 3 isolates examined were conserved. Comparison of peptide differences in sigma 1 polypeptides of these isolates showed that each had one or more unique tryptic peptides, suggesting that the S1 genes coding for these polypeptides had undergone genetic drift or, alternatively, that there are at least two tryptic peptide patterns present among the sigma 1 polypeptides of these isolates. Our results suggest that genetic drift and reassortment are the most likely explanation for the extensive genetic diversity found in natural populations of mammalian reoviruses.     

Immunological and Chemical Identification of Intracellular Forms of Adenovirus Type 2 Terminal Protein

Highly purified adenovirus type 2 terminal protein (TP) with an apparent M_r of 55,000 (55K) was prepared in quantities of 10 to 30 μg from guanidine hydrochloride- or sodium dodecyl sulfate-disrupted virions (60 to 120 mg). Guinea pigs were immunized with 14 to 20 injections of TP in amounts of 1 to 2 μg. Antiserum to TP was used to study the intracellular polypeptides related to adenovirus type 2 TP. By immunoprecipitation with anti-TP serum, we identified 80K and 76K polypeptides in the nucleoplasmic and cytoplasmic S100 fractions of [³⁵S]methionine-labeled cells early and late after infection with Ad2. By immunoautoradiographic analysis which eliminates coprecipitation of unrelated proteins, we identified an 80K polypeptide (probably an 80K-76K doublet) in unlabeled, late infected cells, using anti-TP serum and ¹²⁵I-labeled staphylococcal protein A. About two- to threefold-higher levels of the 80K and 76K polypeptides were present in the nucleoplasm than in the S100 fraction, and two- to threefold-higher levels were found in late infected cells than in early infected cells (cycloheximide enhanced, arabinofuranosylcytosine treated). We did not detect the 80K or 76K polypeptide in uninfected cells, indicating that these polypeptides are virus coded. Tryptic peptide map analysis showed that the 80K and 76K polypeptides are very closely related and that they share peptides with the DNA-bound 55K TP. Our data provide the first direct demonstration of intracellular 80K and 76K forms of TP. The intracellular 80K and 76K polypeptides are closely related or identical to the 80K polypeptide that Challberg and co-workers (Proc. Natl. Acad. Sci. U.S.A. 77:5105-5109, 1980) detected at the termini of adenovirus DNA synthesized in vitro and to the 87K polypeptide that Stillman and co-workers (Cell 23:497-508, 1981) translated in vitro. We did not detect the 55K TP in early or late infected cells, consistent with the proposal by Challberg and co-workers that the 80K polypeptide is a precursor to the virion-bound TP and that the conversion of the 80K polypeptide to the 55K TP occurs during virus maturation. The 80K and 76K polypeptides have many more methionine-containing tryptic peptides than does the 55K TP, and most of the tryptic peptides unique to the 80K and 76K polypeptides are very hydrophobic. Thus, the conversion of the 80K and 76K polypeptides to the 55K TP may involve the removal of a specific hydrophobic protein region.     

Identification of virus-coded nonstructural polypeptides in bunyavirus-infected cells.

Analyses of bunyavirus-infected cell extracts identified at least two virus-induced nonstructural polypeptides. With snowshoe hare (SSH), La Crosse (LAC), and six SSH-LAC reassortant viruses, it was shown that one of these nonstructural polypeptides (NSs, approximate molecular weight, 7.4 X 10(3)) is coded by the SSH small (S)-size viral RNA species. This nonstructural polypeptide was not detected (at least in the same relative abundancies) in LAC virus-infected cells or in cells infected with reassortants having LAC S RNA. For SSH virus, tryptic peptide analyses of either [3H]leucine- or [3H]arginine-labeled NSs indicated that it contains unique sequences not present in the SSH nucleocapsid (N) polypeptide (also coded by the S RNA; J. R. Gentsch and D. H. L. Bishop, J. Virol. 28:417-419, 1978). Analyses of SSH virus-infected cell extracts and extracts of cells infected with SSH-LAC reassortants having SSH medium (M)-size RNA species indicated that a nonstructural polypeptide (NSM; approximate molecular weight, 12 X 10(3)) is coded by the SSH M RNA species. In extracts of LAC virus-infected cells (or cells infected with SSH-LAC reassortants having LAC M RNA), a polypeptide with an electrophoretic mobility slightly faster than that of the SSH NSM polypeptide was observed (approximate molecular weight, 11 X 10(3)); it has been designated LAC NSM. The relationships of the NSM polypeptides to the other M RNA-coded polypeptides (G1 and G2; J. R. Gentsch and D. H. L. Bishop, J. Virol. 30;767-770, 1979) have not been determined. Two additional polypeptides present in both LAC- and SSH-infected cell extracts also appear to be virus induced (one with an approximate molecular weight of 10 X 10(3), p10; the other with an approximate molecular weight of 18 X 10(3), p18). Whether these polypeptides are virus coded has not been determined.     

Major polypeptide of duck hepatitis B surface antigen particles

The 40- to 50-nm pleomorphic particles found in the sera of domestic Pekin ducks infected with duck hepatitis B virus were purified by rate zonal and isopycnic centrifugation. Sodium dodecyl sulfate-polyacrylamide gel electrophoretic polypeptide analysis of these particles, called duck hepatitis B surface antigen particles, revealed the major component to be a single 17,500-dalton polypeptide. This result is in contrast to polypeptide analyses of the surface antigens of related mammalian viruses, including hepatitis B, in which a major doublet of polypeptides is seen with molecular weights ranging from 23,000 to 29,000. Tryptic maps of 17,500-dalton polypeptide resembled that of the major non-glycosylated polypeptide of the adw subtype of hepatitis B surface antigen. A serological assay for antibody to the purified duck virus particles is also described.     

Heterogeneity of Rat Neurofilament Polypeptides Revealed by a Monoclonal Antibody

A monoclonal antibody obtained from mice immunized with a crude neurofilament preparation from newborn rat brain revealed the existence of heterogeneity of the 200,000- and 150,000-dalton neurofilament polypeptides. On immunoblot the monoclonal antibody iC8 reacted with both the 200,000- and 150,000-dalton components in the CNS, but only with the 150,000-dalton polypeptide in sciatic nerve preparations. In addition, the 150,000-dalton polypeptide appeared as a single band in the sciatic nerve, whereas in the CNS a doublet was labeled by iC8. In contrast a second monoclonal antibody (3H5) reacted with the 200,000-dalton peptide and a single 150,000-dalton component in both the central and peripheral nervous system preparations. The differences revealed by iC8 were probably not due to phosphorylation, as the pattern of antibody binding in immunoblots was not changed by pretreatment with alkaline phosphatase. The findings suggest that different isoforms of neurofilament polypeptides are present in the nervous system.     

Biosynthesis of alpha-fetoprotein in cultured hepatoma cells

Pulse and pulse-chase experiments demonstrated that a heterogeneous polypeptide with an apparent Mr = 68,000 was the first intracellular anti-alpha-fetoprotein (AFP)-precipitable polypeptide synthesized by rat Mc-A-RH-7777 hepatoma cells. The 68,000-dalton polypeptide may consist of polypeptides with apparent molecular weights ranging from 68,000 to 70,000. It was the precursor of two intracellular anti-AFP-precipitable polypeptides of 69,000 and 73,000 apparent molecular weight. The latter were secreted into the medium without further processing. The anti-AFP-precipitable polypeptides in both cells and medium incorporated [3H]glucosamine, indicating that these polypeptides are at least partially glycosylated. The 68,000-dalton polypeptide in cells was bound mostly to concanavalin A-Sepharose, whereas the 69,000-dalton polypeptide was entirely unbound. The 73,000-dalton polypeptide consisted of concanavalin A-bound and -unbound variants. Tunicamycin completely abolished the uptake of [3H]glucosamine into anti-AFT-precipitable polypeptides in both cells and medium, and the resulting polypeptide of apparent Mr = 66,000 did not bind to concanavalin A-Sepharose. Tunicamycin did not affect the synthesis or secretion of AFP by hepatoma cells.     

Identification of a second tetracycline-inducible polypeptide encoded by Tn10.

Three Tn10 polypeptides were detected by analyzing the proteins synthesized in ultraviolet light-irradiated Escherichia coli cells after infection with lambda::Tn10. One of these polypeptides was the previously identified 36,000-dalton TET polypeptide. The other two had approximate sizes of 25,000 and 13,000 daltons. The syntheses of both the TET polypeptide and the 25,000-dalton polypeptide were inducible by tetracycline in lambda-immune hosts. Similarly, the synthesis of the TET polypeptide was inducible in nonimmune hosts. However, the synthesis of the 25,000-dalton polypeptide was constitutive in nonimmune hosts. An amber mutation in a gene required for tetracycline resistance on lambda::Tn10 was isolated that eliminated the synthesis of the TET polypeptide in sup+ hosts but not the synthesis of the 25,000-dalton or the 13,000-dalton polypeptides. The expression of tetracycline resistance from wild-type Tn10 was found to be anomalous in E. coli strains carrying the amber suppressors supD, supE, and supF. In general, strains containing these nonsense suppressors were less resistant to tetracycline.     

Unique peptide maps of the three largest proteins specified by the flavivirus Kunjin.

Tryptic digests of four polypeptides found in Kunjin virus-infected Vero cells, NV5, NV4, V3, and NV3, were compared by peptide mapping. The polypeptides to be analyzed were labeled with radioactive methionine and separated by electrophoresis through polyacrylamide gels containing sodium dodecyl sulfate. Because infection of Vero cells by Kunjin virus does not inhibit host cell protein synthesis, radioactively labeled viral polypeptides prepared from infected cells migrate coincidentally during sodium dodecyl sulfate-gel electrophoresis with some of the labeled host proteins. Thus, the genuine viral methionine-containing peptides in tryptic digests of viral proteins have been identified by co-analyzing polypeptides from [3H]methionine-labeled uninfected cells and [35S]methionine-labeled infected cells and determining the 35S/3H ratio in the peptides resolved in two dimensions on thin-layer chromatography plates. The peptide map of NV3 demonstrated that it is host coded, whereas NV5, NV4, and V3 have unique peptide maps and, therefore, account for approximately one-half of the coding potential of Kunjin virus RNA.     

Rapid metabolism of moloney leukemia virus precursor polypeptides in virus infected Swiss mouse embryo cells.

Viral protein synthesis in Moloney murine leukemia virus infected high passage mouse embryo cells was studied utilizing monospecific antisera to the viral core protein p30 and envelope protein gp71. Pulse-chase analysis of [³⁵S]methionine-labeled polypeptides in combination with the demonstration of the presence of either gp71 or p30-specific antigenic determinants in them indicated a 84,000-dalton polypeptide as the precursor of viral glycoproteins and four metabolically unstable polypeptides of approximate molecular weights 88,000, 72,000, 62,000, and 39,000 as the precursors of viral core protein, p30. The p30-containing 88,000 and 72,000-dalton polypeptides were distinctly seen in this system under normal growth conditions. Further, the processing of p30 precursors was very rapid and was complete during a 40 min chase while only partial processing of glycoprotein precursor was observed during the same period.