Multiple forms of chicken liver and hepatoma Mc-29 microsomal and plasma-membrane sialyl and fucosyltransferases

Multiple forms of microsomal and plasma membrane sialyl and fucosyltransferases from chicken liver and transplantable hepatoma Mc-29 have been separated by means of isoelectric focusing. A net different pattern was distinguished between liver and hepatoma microsomal and plasma-membrane associated transferases. Microsomal sialyltransferase from hepatoma Mc-29 has typical forms with pI = 5.69, 7.43, 8.05 and 8.56, while in plasma membrane, enzymes with pI = 5.00 and 8.70 occur. The presence of 9 forms of fucosyltransferase within the pH range 3.46-9.57 for hepatoma microsomes and within pH 4.52-9.60 for plasma membranes was detected. Forms with pI 5.10, 5.75 and 7.87 could be considered specific for the hepatoma microsomal enzyme, and forms with pI 4.52, 4.85 and 5.20 for the plasma-membrane associated enzyme.     

Galactosyltransferase: multiple forms in serum of normal and hepatoma Mc-29 bearing chickens and from liver and hepatoma microsomal and plasma membrane preparations

The multiple forms of galactosyltransferase in chicken serum and in microsomal and plasma membrane preparations from liver and viral induced hepatoma Mc-29 have been studied by isoelectric focussing. An elevation of the hepatoma plasma membrane enzyme activity was described and in the pattern of the multiple forms of the enzyme two forms were found (pI-5.34 and 8.22) which were similar to those described in the serum of hepatoma bearing chickens (pI-5.36 and 8.24). A conclusion is drawn that these enzyme forms are apparently present to a greater extent in the hepatoma plasma membrane enriched fractions than in liver membranes and are probably shed into the serum of the tumor bearing animals.     

Partial characterization of microsomal sialyltransferase from chicken liver and hepatoma Mc-29: I. Effect of nucleotides and metal ions

CMP-N-acetylneuraminic acid: glycoprotein sialyltransferase activities were assayed in microsomal fractions from chicken liver and hepatoma, induced by the leukosis virus strain Mc-29, using asialofetuin as the substrate acceptor of N-acetylneuraminic acid. The effect of some nucleotides and metal ions on the enzyme activity was investigated. Kinetic studies revealed that the Km values toward asialofetuin at a saturation concentrations of CMP-N-acetylneuraminic acid for both liver and hepatoma enzymes are very closed, while V value was lower for the tumor enzyme. The liver and hepatoma enzymes have no exogenous Mn cations requirement and are inhibited by CTP, CMP and ATP. CMP was shown to act as a competitive inhibitor with an apparent Ki of 0.24 mM for the liver and 0.16 mM for hepatoma enzyme, respectively.     

gamma-Glutamyltranspeptidase and dipeptidyl peptidase IV activity in the serum of normal and hepatoma-bearing chickens and in the plasma membranes from liver and hepatoma Mc-29.

Investigations on the activity of gamma-glutamyltranspeptidase (GGT) and dipeptidyl peptidase IV (DPP IV) in the serum of healthy chickens and those bearing hepatoma Mc-29, and in liver and hepatoma plasma membranes were carried out. There was no difference in the serum enzyme activities of control and tumor-bearing chickens but the activity of GGT was twice higher and that of DPP IV 20 times lower in hepatoma plasma membranes than in chicken liver plasma membranes. Using thin-layer analytical isoelectric focusing in agarose gels it was established that the pI range of GGT from host serum and hepatoma plasma membranes was shifted to more acidic values. This could be interpreted as a specific feature for this enzyme considered as a tumor marker.     

Comparative study on fucosylation of chicken liver and virus-induced hepatoma Mc-29

Comparative studies on fucoprotein metabolism of chicken liver and hepatoma Mc-29 have been carried out and the following parameters were determined: the incorporation rate of [14C]fucose into hepatoma and liver total tissue homogenate, acid-soluble and acid-insoluble fractions, acid-soluble nucleotide fraction and into plasma-membrane acid-precipitable fraction; the activity of microsomal and plasma-membrane fucosyltransferase; the electrophoretic pattern of hepatoma and liver plasma-membrane proteins and the incorporation of [14C]fucose into the glycoprotein fractions in both plasma-membrane preparations. It was found that the labelling of hepatoma tissue homogenate and plasma membranes was higher than that of the same liver preparations 3 hr after the [14C]fucose injection. This finding was supported by a considerably elevated hepatoma fucosyltransferase activity. The labelling rate of numerous fucoproteins from hepatoma plasma membranes was greatly increased and some of the individual glycoprotein bands were labelled to a higher extent compared with liver. The data presented show specific alterations of fucose and fucoprotein metabolism which could be considered as a characteristic feature of chicken viral-induced hepatoma Mc-29.     

Characterization of sialyltransferases from serum of normal and hepatoma Mc-29 bearing chickens

Sialyltransferase was measured in serum of normal and hepatoma Mc-29 bearing chickens. By preparative isoelectric focusing the multiple forms of sialyltransferase from both kind of serums was studied as well. By using influenza virus neuraminidase an attempt was made for partial structural characterization of the sialylation sites in asialofetuin applied as exogenous acceptor for sialyltransferase determination. It was established an elevated serum sialyltransferase activity in tumor bearing chickens with tumor an enzyme form was detected with pI-4.99 identical with an enzyme form described previously in solubilized plasma membrane preparations from hepatoma Mc-29. Monitoring of multiple forms of serum glycosyltransferases may be of value in answering the problem concerning the tissue origin of serum enzymes.     

Partial characterization of microsomal sialyltransferase from chicken liver and hepatoma Mc-29: II. Measurement of enzyme activities utilizing microsomal glycoproteins as exogenous acceptors

Microsomal sialyltransferase was assayed in chicken liver and hepatoma Mc-29 utilizing liver and hepatoma microsomal glycoprotein fractions, treated with Triton X-100, as exogenous acceptors. In a homologous assay system containing enzyme and acceptor from one and the same tissue no quantitative dependence of enzyme activity was revealed with increasing amount of the acceptor. In mixed experiments in which liver enzyme activity was tested towards hepatoma acceptor glycoproteins, a gradual drop in sialyltransferase activity occurred with increasing quantities of the acceptor. This effect seems to be a consequence of the presence of some inhibitor in the microsomal fractions from the hepatoma cells.     

Pattern of sialoglycoproteins obtained by chromatofocusing of chicken liver and hepatoma Mc-29 microsomal preparations labelled in vivo with 3H-leucine and N-acetyl-14C-mannosamine.

Chromatofocusing has been used for separation of chicken liver and virus-induced hepatoma Mc-29 microsomal glycoproteins double labelled in vivo with 3H-leucine and N-acetyl-14C-mannosamine. The sialoglycoprotein profile was obtained by plotting the pH-values, as well as the values of the calculated specific activity (SA-cpm/mg protein) in each fraction, in the graphs. Different patterns for liver and hepatoma sialoglycoproteins were detected. Unlike liver microsomes in which the highest labelled compounds were registered in the alkaline zone of the pH-gradient, special feature for the hepatoma sialoglycoprotein pattern was the presence of highly labelled fraction eluted in the acidic zone of the pH-gradient. A term named "sialylation rate" of a separated sialoglycoproteins was involved. It has been found that liver sialoglycoproteins are more or less uniformly sialylated, independently of the pI-values, while those from hepatoma with acidic pI were sialylated at a higher extent in comparison to the fractions with alkaline pI.     

The activity of polynucleotide phosphorylase in polyribosomes of regenerating liver of adult rats, liver of newborn rats and in some reinoculated tumours]

Specific activity and level of polynucleotide phosphorylase (PNPase) in polyribosomes of regenerating liver of adult rats, liver of newborn rats and in malignant tumours of rat (sarcoma M-1 and hepatoma 27) were studied. 24 hours after partial hepatectomy the specific activity and level of PNPase in regenerating liver decreased 3--4 times in the fraction of polyribosomes, bound to the endoplasmic reticulum membranes, and remained at a constantly low level in the fraction of free polyribosomes. The PNPase activity also showed a sharp decrease in the fraction of membrane-bound polyribosomes from newborn rats liver and could not be detected either in free or in bound polyribosomes from sarcoma M-1 or hepatoma 27. The PNPase activity in the fraction of bound polyribosomes increased with a decrease in the rate of liver growth (regenerating liver and newborn rats liver), and reached the level normal for adult animals. Possible mechanisms of regulation of the PNPase activity in animal tissue were studied. It was found that a 2-fold administration of cyclic 3,5'-AMP to intact animals (5 mg per 100 g of body weight) with an interval of 8 hours, corresponding to the interval between two peaks of the increase in cyclic 3,5'-AMP concentration following partial hepatectomy, diminished the PNPase specific activity in polyribosomes by 30%. A factor, presumably of protein origin, which induced a release of PNPase from polyribosomes of normal rat liver but did not affect the activity of the liberated enzyme, was detected in the cell sap of sarcoma M-1 and hepatoma 27.     

Detection and Assay of Avian Tumor Virus Group-Specific Antigen and Antibody by the Paired Radioiodine-Labeled Antibody Technique

The paired radioiodine-labeled antibody technique (PRILAT) was applied to the detection and quantitation of avian tumor virus group-specific (gs) antigens and antibody. The technique proved to be specific, repeatable, and appreciably more sensitive than the microcomplement-fixation test for avian leukosis (COFAL). The PRILAT facilitated direct measurement of comparative antigen content of several types of transformed, neoplastic, or virus-infected cells and the magnitude of nonspecific antibody binding by appropriate control cells. The versatility of the technique was illustrated by application to the detection and quantitation of gs antibody content of chicken, turkey, pigeon, and hamster sera. Antibodies were detected in COFAL-negative sera from hamsters bearing tumors induced by the Schmidt-Ruppin strain of Rous sarcoma virus. Sera from chickens bearing similar tumors were not positive for gs antibodies, although sera from turkeys and chickens immunized with avian leukosis virus did contain gs antibodies.     

Chromatographic Analyses of Isoaccepting tRNAs from Avian Tumor Viruses

Low-molecular-weight RNA from transforming viruses (Rous sarcoma virus-Rous-associated virus 1, Schmidt-Ruppin strain of Rous sarcoma virus, and sarcoma-B(77)), from nontransforming viruses (Rous-associated virus 1 and sarcoma-NTB(77)), and from chicken liver, chicken embryo fibroblast, and Rous sarcoma virus-Rous-associated virus 1-transformed chicken embryo fibroblast was isolated and purified. To determine if there are modified, qualitatively or quantitatively different isoaccepting species of tRNA in these avian sarcoma viruses as compared with the cell of virus origin, chicken embryo fibroblast or normal chicken liver, methionyl-, arginyl-, and lysyl-tRNA (with high amino acid acceptance activity), and aspartyl- and glutamyl-tRNA from viral-trans-formed cells (with low viral amino acid acceptance activity) were co-chromatographed on reversed phase-5 chromatography columns, and elution profiles were compared. Although in each case the elution profile between a particular viral and host cell tRNA differed quantitatively, there was no qualitative difference in the profiles of corresponding tRNAs from either transforming or nontransforming viruses examined. Minor quantitative differences in the elution profiles might be a reflection of the metabolic state of the cells, since all evidence points to acceptor activity being of host rather than viral origin. Since, with the exception of selective packaging of methionyl-tRNA (IV) species by both transforming and nontransforming viruses, no selectivity was found for isoacceptor species of other tRNAs, it seems that such preferential packaging of methionyl-tRNA (IV) species has no bearing on the event of viral transformation.     

Electron Microscopy of Chick Fibroblasts Infected by Defective Rous Sarcoma Virus and Its Helper

Nonproducing Rous sarcoma cells of the chicken and their virus-producing as well as uninfected counterparts were studied with an electron microscope. The structural peculiarities of transformed cells included cytoplasmic annulate lamellae, aggregates of membrane-bound, glycogen-like granules, and empty, virus-like shells. Of 69 individual lines of nonproducing Rous sarcoma cells, 64 contained small numbers of viral particles. These particles were morphologically indistinguishable from mature avian tumor virus but lacked demonstrable infectivity. In sessile normal and leukosis virus-infected fibroblasts, microtubules and fibrils occurred in parallel arrays at the periphery of the cytoplasm. This cortical organization was absent from rounded Rous sarcoma cells. The characteristics of microtubular arrangement seemed to reflect differences in the locomotory activity of normal and transformed cells.     

Marker rescue of endogenous cellular genetic information related to the avian leukosis virus gene encoding RNA-directed DNA polymerase.

Endogenous cellular genetic information related to the avian leukosis virus gene encoding RNA-directed DNA polymerase was studied, using a marker rescue assay to detect biological activity of subgenomic fragments of virus-related DNAs of uninfected avian cells. Recipient cultures of chicken embryo fibroblasts were treated with sonicated DNA fragments and were infected with a temperature-sensitive mutant of Rous sarcoma virus that encoded a thermolabile DNA polymerase. Wild-type progeny viruses were isolated by marker rescue with fragments of DNA of uninfected chicken, pheasant, quail, and turkey cells. The DNAs of these uninfected avian cells, therefore, appeared to contain endogenous genetic information related to the avian leukosis virus DNA polymerase gene.     

Assay of noninfectious fragments of DNA of avian leukosis virus-infected cells by marker rescue.

A marker rescue assay of noninfectious fragments of avian leukosis virus DNAs is describe. DNA fragments were prepared either by sonication of EcoRI-digestion of DNAs of chicken cells infected with wild-type Rous sarcoma virus, with a nontransforming avian leukosis virus, and with a mutant of Rous sarcoma virus temperature sensitive for transformation. Recipient cultures of chicken embryo fibroblasts were treated with noninfectious DNA fragments and infected with temperature-sensitive mutants of Rous sarcoma virus defective in DNA polymerase or in an internal virion structural protein. Wild-type progeny viruses which replicated at the nonpermissive temperature were isolated. Some of the wild-type progeny acquired both the wild-type DNA polymerase and the subgroup specificity of the Rous sarcona virus strain used for preparation of sonicated or EcoRI-digested DNA fragments. Therefore the genetic markers for DNA polymerase and envelope were linked and appeared to be located on the same EcoRi fragment of the DNA of Rous sarcoma virus-infected cells.     

Comparison between the viral transforming gene (src) of recovered avian sarcoma virus and its cellular homolog.

Recovered avian sarcoma viruses are recombinants between transformation-defective mutants of Rous sarcoma virus and the chicken cellular gene homologous to the src gene of Rous sarcoma virus. We have constructed and analyzed molecular clones of viral deoxyribonucleic acid from recovered avian sarcoma virus and its transformation-competent progenitor, the Schmidt-Ruppin A strain of Rous sarcoma virus. A 2.0-megadalton EcoRI fragment containing the entire src gene from each of these clones was subcloned and characterized. These fragments were also used as probes to isolate recombinant phage clones containing the cellular counterpart of the viral src gene, termed cellular src, from a lambda library of chicken deoxyribonucleic acid. The structure of cellular src was analyzed by restriction endonuclease mapping and electron microscopy. Restriction endonuclease mapping revealed extensive similarity between the src regions of Rous sarcoma virus and recovered avian sarcoma virus, but striking differences between the viral src's and cellular src. Electron microscopic analysis of heteroduplexes between recovered virus src and cellular src revealed a 1.8-kilobase region of homology. In the cellular gene, the homologous region was interrupted by seven nonhomologous regions which we interpret to be intervening sequences. We estimate the minimum length of cellular src to be about 7.2 kilobases. These findings have implications concerning the mechanism of formation of recovered virus src and possibly other cell-derived retrovirus transforming genes.     

Nucleotidase activity in regenerating liver and in clonal strains of hepatoma and pituitary cells in culture.

A nucleotidase of the combined 3'- and 5'-type (nucleotide phosphohydrolase, E.C.3.1.3.31) was present in the cytosol of regenerating rat liver cells, and of rat hepatoma and pituitary cells in culture. The enzyme activity per milligram of cell protein was very similar in regenerating liver and in three of the different cell types. The hepatoma cell strain which showed the slowest growth rate had a three-fold higher basal enzyme activity. After the first days of regenerative growth in rat liver and during early plateau phase of cell growth, there was a 50-120% increase in specific enzyme activity. In the hepatoma cells, the enzyme activities were also compared to the cellular content and synthesis of RNA and DNA. The increase in enzyme activity occurred concomitantly with a reduced incorporation of 3H-thymidine into DNA. The possible physiological role of this nucleotidase in nucleic acid and nucleotide metabolism is discussed.     

Integration of Rous sarcoma virus DNA into chicken embryo fibroblasts: no preferred proviral acceptor site in the DNA of clones of singly infected transformed chicken cells.

We analyzed retroviral integration into a host genome by using avian sarcoma virus infection of natural target cells under conditions where secondary integration via virus spread was inhibited. This was accomplished by using the noninfectious pol- env- alpha variant of the Bryan high-titer strain of Rous sarcoma virus. A total of 12 independent Bryan high-titer Rous sarcoma virus-transformed chicken embryo fibroblast clones were obtained and mapped by using restriction endonucleases. Provirus-cell junction fragments were identified with appropriate hybridization probes. We found that expression of the viral genes could occur after proviral integration at many sites on the chicken genome and that there was no apparent preference for specific integration sites.     

Morphological transformation, autonomous proliferation and colony formation by chicken heart mesenchymal cells infected with avian sarcoma, erythroblastosis and myelocytomatosis viruses

Normal chicken heart mesenchymal cells at low density in monolayer culture in plasma-containing medium have a polygonal shape and are proliferatively quiescent. The combination of epidermal growth factor and insulin at hyperphysiological concentration, an insulin-like growth factor surrogate, causes these cells to assume a fusiform shape and to increase 40-fold in number during four days of incubation. These mitogenic hormones do not, however, induce normal chicken heart mesenchymal cells to form colonies in agarose suspension culture. Chicken heart mesenchymal cells infected with the Schmidt-Ruppin or Prague-A strains of Rous sarcoma virus or with the Fujinami or Y73 avian sarcoma viruses assume spindle and round shapes, increase 50-100 fold in number during four days of monolayer culture in the absence of mitogenic hormones and form macroscopic colonies during 3-4 days of agarose suspension culture. The autonomous (mitogenic hormone-independent) proliferation, in monolayer culture, of cells infected with temperature-sensitive transformation mutants of Rous sarcoma virus (tsNY68, tsNY72, tsLA24, tsLA29) is temperature-sensitive. Chicken heart mesenchymal cells infected with avian erythroblastosis virus assume spindle shapes and proliferate in monolayer culture at a rate comparable to that of sarcoma virus-infected cells but do not, however, form colonies in agarose suspension culture. Cells infected with the myelocytomatosis virus MC29 assume stellate shapes and increase 18-fold in number during four days of monolayer culture. Cells infected with the myelocytomatosis virus MH2 assume fusiform shapes and increase fourfold in number during four days of monolayer culture. Neither MC29 nor MH2 renders chicken heart mesenchymal cells capable of colony formation in agarose suspension culture. Infection with avian leukosis viruses (RAV-1, RAV-2, RPL-42) or with transformation-defective mutants of Rous sarcoma virus (tdNY105, 107, 109) does not affect the morphology or proliferative behavior of chicken heart mesenchymal cells. Monolayer culture of chicken heart mesenchymal cells in plasma-containing medium appears, therefore, to define the ability of onc genes of acute transforming avian retroviruses to induce autonomous (mitogenic hormone-independent) cell proliferation, the essential characteristic of neoplasia. The differences in transformed morphology and rates of autonomous proliferation between cells infected with different acute transforming retroviruses probably reflects differences in the modes of action of the transforming proteins encoded by the onc genes of the respective viruses.(ABSTRACT TRUNCATED AT 400 WORDS)     

Rous sarcoma virus does not induce sarcoma in early chick embryos by lack of the v-src gene expression.

The Schmidt-Ruppin or the B77 strain of Rous sarcoma virus (RSV) was inoculated into limb buds of 4.5-days-old avian embryos. No sarcoma but blister formation was observed in those RSV-inoculated embryos. Protein kinase activity of pp60v-src in RSV-inoculated embryos, even in the site of virus inoculation, was the same as that in mock-infected embryos. This indicated that the expression of the v-src gene did not attain superiority over that of the c-src gene in RSV-inoculated embryos. The v-src gene was detected in every DNA from tissues of RSV-inoculated embryos but not in DNAs from tissues of RSV-inoculated chicken except for the DNA from Rous sarcoma. Those results confirmed that the lack of sarcoma induction in early avian embryos by RSV was due to the lack of the expression of the v-src gene which was present in the target cells.