Design and characterization of viral polypeptide inhibitors targeting Newcastle disease virus fusion

Paramyxovirus infections can be detected worldwide with some emerging zoonotic viruses and currently there are no specific therapeutic treatments or vaccines available for many of these diseases. Recent studies have demonstrated that peptides derived from the two heptad repeat regions (HR1 and HR2) of paramyxovirus fusion proteins could be used as inhibitors of virus fusion. The mechanism underlying this activity is in accordance with that of class I virus fusion proteins, of which human immunodeficiency virus (HIV) and influenza virus fusion proteins are members. For class I virus fusion proteins, the HR1 fragment binds to HR2 to form a six-helix bundle with three HR1 fragments forming the central coiled bundle surrounded by three coiled HR2 fragments in the post fusion conformational state (fusion core). It is hypothesized that the introduced exogenous HR1 or HR2 can compete against their endogenous counterparts, which results in fusion inhibition. Using Newcastle disease virus (NDV) as a model, we designed several protein inhibitors, denoted HR212 as well asHR121 and 5-Helix, which could bind the HR1 or HR2 region of fusion protein, respectively. All the proteins were expressed and purified using a GST-fusion expression system in Escherichia coli. The HR212 or GST-HR212 protein, which binds the HR1 peptide in vitro, displayed inhibitory activity against NDV-mediated cell fusion, while the HR121 and 5-Helix proteins, which bind the HR2 peptide in vitro, inhibited virus fusion from the avirulent NDV strain when added before the cleavage of the fusion protein. These results showed that the designed HR212, HR121 or 5-Helix protein could serve as specific antiviral agents. These data provide additional insight into the difference between the virulent and avirulent strains of NDV.     

Detection of an interaction between the HN and F proteins in Newcastle disease virus-infected cells.

For many paramyxoviruses, including Newcastle disease virus (NDV), syncytium formation requires the expression of both surface glycoproteins (HN and F) in the same cell, and evidence suggests that fusion involves a specific interaction between the HN and F proteins. Because a potential interaction in paramyxovirus-infected cells has never been demonstrated, such as interaction was explored by using coimmunoprecipitation and cross-linking. Both HN and F proteins could be precipitated with heterologous antisera after a 5-min radioactive pulse as well as after a 2-h chase in nonradioactive medium, but at low levels. Chemical cross-linking increased detection of complexes containing HN and F proteins at the cell surface. After cross-linking, intermediate- as well as high-molecular-weight species containing both proteins were precipitated with monospecific antisera. Precipitation of proteins with anti-HN after cross-linking resulted in the detection of complexes which electrophresed in the stacker region of the gel, from 160 to 300 kDa, at 150 kDa, and at 74 kDa. Precipitates obtained with anti-F after cross-linking contained species which migrated in the stacker region of the gel, between 160 and 300 kDa, at 120 kDa, and at 66 kDa. The three to four discrete complexes ranging in size from 160 to 300 kDa contained both HN and F proteins when precipitated with either HN or F antisera. That cross-linking of complexes containing both HN and F proteins was not simply a function of overexpression of viral glycoproteins at the cell surface was addressed by demonstrating cross-linking at early time points postinfection, when levels of viral surface glycoproteins are low. Use of cells infected with an avirulent strain of NDV showed that chemically cross-linked HN and F proteins were precipitated independent of cleavage of F0. Furthermore, under conditions that maximized HN protein binding to its receptor, there was no change in the percentages of HN and F0 proteins precipitated with heterologous antisera, but a decrease in F1 protein precipitated was observed upon attachment. These data argue that the HN and F proteins interact in the rough endoplasmic reticulum. Upon attachment of the HN protein to its receptor, the HN protein undergoes a conformational change which causes a conformational change in the associated F protein, releasing the hydrophobic fusion peptide into the target membrane and initiating fusion.     

Restricted replication of human hepatitis A virus in cell culture: intracellular biochemical studies.

When hepatitis A virus was inoculated into Vero cells, virus-specified protein and RNA synthesis was detected. Production of viral protein was detected by electrophoretic analysis in polyacrylamide gels by using a double-label coelectrophoresis and subtraction method which eliminated the contribution of host protein components from the profiles of virus-infected cytoplasm. Eleven virus-specified proteins were detected in the net electrophoretic profiles of hepatitis A virus-infected cells. The molecular weights of these proteins were very similar to those detected in cells infected with poliovirus type 1. Virus-specified protein synthesis could be detected at 3 to 6 h and continued for at least 48 h postinfection, but no significant effect on host-cell macromolecular synthesis was observed. Limited viral RNA replication occurred between 2 and 6 h postinfection. The genomic RNA of hepatitis A virus was extracted and shown to be capable of infecting cells and inducing the same set of proteins as intact virus, indicating that the RNA genome is positive stranded. Progeny virus was never detected in the supernatant fluids of infected cell cultures, and the cells showed no observable cytopathology, even though hepatitis A virus-specific proteins and antigens were being produced. The nature of the defect in the replicative cycle of hepatitis A virus in this system remains unknown.     

Identification of immunologically cross-reactive proteins of Sindbis virus: evidence for unique conformation of E1 glycoprotein from infected cells

Hyperimmune antisera to purified Sindbis (SIN) or Semliki Forest (SF) virus were used to identify alphavirus-specific and cross-reactive proteins in virions and infected cells. The hyperimmune sera participated in homologous and cross-cytolysis of alphavirus-infected cells, and the use of monospecific antisera to SIN structural proteins suggested that E1 and E2 could serve as target proteins in cytolysis. Proteins from purified virions or infected cells were extracted with Nonidet P-40, denatured by procedures for sodium dodecyl sulfate-polyacrylamide gel electrophoresis, transferred to nitrocellulose solid supports, and reacted with hyperimmune sera and 125I-labeled protein A (immunoblotting on denatured proteins). Alternatively, native proteins extracted by mild Nonidet P-40 treatment were precipitated with hyperimmune sera before denaturation by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. After immunoblotting, homologous antiserum reacted with the virus structural proteins E1, E2, capsid extracted from purified virions, and the counterparts of these proteins extracted from infected cells. In addition, PE2 and a 92,000-molecular-weight protein from infected cells reacted with homologous antiserum. These proteins were also immunoprecipitated with homologous antiserum. After immunoblotting, the Sindbis capsid protein was shown to be cross-reactive whether derived from purified virions or from infected cells; no cross-reactivity was observed with PE2 or E2 from either source, and the E1 glycoprotein was shown to be cross-reactive only when obtained from virions. However, the E1 glycoprotein could be cross-immunoprecipitated from infected cells (as well as from disrupted virions), and, in addition, capsid and a 92,000-molecular-weight protein were cross-immunoprecipitated from infected cells. These results suggest that a native conformation of the cell-associated E1 glycoproteins may be required for immunological cross-reactivity (immune precipitation), whereas virion but not cell-associated E1 retains immunological cross-reactivity after denaturation (immunoblot technique). The findings extend our previously published evidence which suggested that alphavirus maturation is accompanied by a change in immunological cross-reactivity with respect to E1.     

Inhibition of Host-Cell Protein and Ribonucleic Acid Synthesis by Newcastle Disease Virus

The mechanisms of Newcastle disease virus-(NDV) induced inhibition of cell protein and ribonucleic acid (RNA) synthesis were investigated. It was observed that the ability of NDV to inhibit cell RNA synthesis is dependent on the virus strain. The inhibitors, azauridine and cycloheximide, were added to cell cultures at different times after infection to study the roles of protein and RNA synthesis in the viral inhibition process. Viral inhibition of cell RNA synthesis and viral inhibition of cell protein synthesis become resistant to cycloheximide at a different time after infection than that in which they become resistant to azauridine. The results indicate that the inhibition of cell RNA synthesis by the Texas strain involves the synthesis of inhibitory proteins which are coded by the viral genome. The Texas and Beaudette strains of NDV appear to employ different mechanisms for the inhibition of host-cell protein synthesis. Viral inhibition of cell protein synthesis does not appear to cause, or be the result of, viral inhibition of cell RNA synthesis.     

Tumor antigens of human ad5 in transformed cells and in cells infected with transformation-defective host-range mutants

We have studied the polypeptides associated with the expression of the transforming region of the Ad5 genome by immunoprecipitating antigens (using the double antibody and protein A-Sepharose techniques) from cells infected with wild-type (wt) Ad5 or transformation-defective host range (hr) mutants and from cells transformed by Ad5. Three different antisera were used: P antiserum specific for early viral products (Russell et al., 1967) and two different hamster tumor antisera. Immunoprecipitation of antigens from wt-infected KB cells followed by SDS-polyacrylamide gel electrophoresis of precipitated proteins revealed that a major polypeptide having a molecular weight of approximately 58,000 was detected with all three antisera and with both the double antibody and the protein A-Sepharose techniques, while P antiserum also precipitated polypeptides of molecular weights 72,000, 67,000 and 44,000, which probably represent the DNA binding protein and related polypeptides, respectively. With the double antibody technique, in addition to the proteins mentioned above, P antiserum and the hamster tumor antisera precipitated a 10,500 dalton polypeptide which was not detected when the protein A-Sepharose procedure was used. Using either the double antibody or the protein A-Sepharose technique, we found that hr mutants from complementation group II failed to induce the synthesis of the 58,000 dalton protein, whereas mutants from complementation group I produced normal or near normal amounts. Using the double antibody technique, we found that the 10,500 dalton protein was absent or made in reduced amounts by group I mutants. A 58,000 dalton protein was detected in a number of different Ad5-transformed cell lines, including the 293 human line, the 14b hamster line and several transformed rat cell lines. This observation and the fact that transformation negative group II mutants fail to induce the synthesis of a 58,000 dalton polypeptide suggest that this protein is one of the Ad5-specific products necessary for cell transformation.     

Measles Virus-Specified Polypeptide Synthesis in Two Persistently Infected HeLa Cell Lines

Measles virus-directed protein synthesis was examined in two HeLa cell lines (K11 and K11A) that are persistently infected with wild-type measles virus. Four viral proteins (H, hemagglutination protein; P, nucleocapsid-associated protein; NP, the major nucleocapsid protein; and M, the matrix protein) were readily detected in both cell lines by immune precipitation of [(35)S]methionine-labeled cell extracts followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. When analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, three (H, NP, and M) of the four viral proteins in both K11 and K11A cells differed from the corresponding viral proteins synthesized in HeLa cells acutely infected with the parental wild-type virus. In addition, the M protein from K11A cells migrated significantly more slowly on sodium dodecyl sulfate-polyacrylamide gel electrophoresis than the M protein from K11 cells, and there appeared to be slight differences in the H and NP proteins between these two persistently infected cell lines. The altered viral proteins detected in K11 and K11A cells appeared to be the result of viral mutations rather than changes in the host cell, since virus recovered from these cells directed the synthesis of similar aberrant viral proteins in HeLa cells. Virus recovered from K11 cells and virus recovered from K11A cells were both temperature sensitive and grew more slowly than wild-type virus. HeLa cells infected with virus recovered from K11 cells readily became persistently infected, resembling the original persistently infected K11 cells. Thus, viral mutations are associated with persistent measles virus infections in cell cultures.     

Evidence for mixed membrane topology of the newcastle disease virus fusion protein

The synthesis of the Newcastle disease virus (NDV) fusion (F) protein in a cell-free protein-synthesizing system containing membranes was characterized. The membrane-associated products were in at least two different topological forms with respect to the membranes. The properties of one form were consistent with the expected membrane insertion as a classical type 1 glycoprotein. This form of the protein was fully glycosylated, and sequences amino terminal to the transmembrane domain were protected from protease digestion by the membranes. The second form of membrane-associated F protein was partially glycosylated and partially protected from protease digestion by the membranes. Protease digestion resulted in a 23-kDa protease-protected polypeptide derived from F2 sequences and sequences from the amino-terminal end of the F1 domain. Furthermore, a 10-kDa polypeptide derived from the cytoplasmic domain (CT) was also protected from protease digestion by the membranes. Protease resistance of the 23- and 10-kDa polypeptides suggested that this second form of F protein inserted in membranes in a polytopic conformation with both the amino-terminal end and the carboxyl-terminal end translocated across membranes. To determine if this second form of the fusion protein could be found in cells expressing the F protein, two different approaches were taken. A polypeptide with the size of the partially translocated F protein was detected by Western analysis of proteins in total-cell extracts of NDV strain B1 (avirulent)-infected Cos-7 cells. Using antibodies raised against a peptide with sequences from the cytoplasmic domain, CT sequences were detected on surfaces of F protein-expressing Cos-7 cells by immunofluorescence and by flow cytometry. This antibody also inhibited the fusion of red blood cells to cells expressing F and HN proteins. These results suggest that NDV F protein made both in a cell-free system and in Cos-7 cells may exist in two topological forms with respect to membranes and that the second form of the protein may be involved in cell-cell fusion.     

Mutated form of the Newcastle disease virus hemagglutinin-neuraminidase interacts with the homologous fusion protein despite deficiencies in both receptor recognition and fusion promotion

The Newcastle disease virus (NDV) hemagglutinin-neuraminidase (HN) protein mediates attachment to cellular receptors. The fusion (F) protein promotes viral entry and spread. However, fusion is dependent on a virus-specific interaction between the two proteins that can be detected at the cell surface by a coimmunoprecipitation assay. A point mutation of I175E in the neuraminidase (NA) active site converts the HN of the Australia-Victoria isolate of the virus to a form that can interact with the F protein despite negligible receptor recognition and fusion-promoting activities. Thus, I175E-HN could represent a fusion intermediate in which HN and F are associated and primed for the promotion of fusion. Both the attachment and fusion-promoting activities of this mutant HN protein can be rescued either by NA activity contributed by another HN protein or by a set of four substitutions at the dimer interface. These substitutions were identified by the evaluation of chimeras composed of segments from HN proteins derived from two different NDV strains. These findings suggest that the I175E substitution converts HN to an F-interactive form, but it is one for which receptor binding is still required for fusion promotion. The data also indicate that the integrity of the HN dimer interface is critical to its receptor recognition activity.     

Radioimmunossay for detection of antigen and antibodies to Newcastle disease virus.

When Newcastle disease virus (NDV) is treated with NP-40 and ether a membrane fraction of 150,000 m.w. is obtained. This fraction which is composed of two polypeptides with m.w. of 56,000 and 76,000 was used in a radioimmunoassay (RIA). The assay was developed for both antigen and antibody and was found to be reproducible, specific, and highly sensitive. Titers of 1:51,200 were determined by RIA as compared to 1:4 by agar gel diffusion and 1:200 by hemaglutination inhibition (HI). As little as 5 ng of viral protein were detected by RIA inhibition technique. Labeled antigen could be stored in the presence of serum, KCI and Triton X-100 at -20 degrees C for as long as 6 weeks and retained similar reactivity as fresh reagent.     

Identification of Virus-Induced Proteins in Cells Productively Infected with Simian Virus 40

The number and molecular weight of the structural polypeptides of highly purified simian virus 40 (SV40) were determined by polyacrylamide gel electrophoresis. Six different polypeptides were found, two of which (VP1 and VP2) comprise the bulk of the viral capsid proteins. The pattern of protein synthesis in productively infected CV-1 cells was studied by sodium dodecyl sulfate polyacrylamide gel electrophoresis. Identification of virus-induced proteins in the infected CV-1 cells was achieved in double-labeling experiments by electrophoresis with purified labeled SV40 capsid proteins. Four of these proteins (VP1 and VP4) could be classified as components of the virion because their synthesis occurred after the onset of viral deoxyribonucleic acid (DNA) replication and because they were inhibited by arabinofuranosylcytosine (ara-C). Appearance of two other virus-induced proteins was not prevented by ara-C; one of them did not comigrate in the electrophoresis with purified virion polypeptides, and both could be detected before the onset of viral DNA synthesis. These latter two proteins were classified on the basis of these criteria as nonvirion capsid proteins (NCVP1 and NCVP2).     

Newcastle disease virus (NDV)-based assay demonstrates interferon-antagonist activity for the NDV V protein and the Nipah virus V,W, and C proteins

We have generated a recombinant Newcastle disease virus (NDV) that expresses the green fluorescence protein (GFP) in infected chicken embryo fibroblasts (CEFs). This virus is interferon (IFN) sensitive, and pretreatment of cells with chicken alpha/beta IFN (IFN-alpha/beta) completely blocks viral GFP expression. Prior transfection of plasmid DNA induces an IFN response in CEFs and blocks NDV-GFP replication. However, transfection of known inhibitors of the IFN-alpha/beta system, including the influenza A virus NS1 protein and the Ebola virus VP35 protein, restores NDV-GFP replication. We therefore conclude that the NDV-GFP virus could be used to screen proteins expressed from plasmids for the ability to counteract the host cell IFN response. Using this system, we show that expression of the NDV V protein or the Nipah virus V, W, or C proteins rescues NDV-GFP replication in the face of the transfection-induced IFN response. The V and W proteins of Nipah virus, a highly lethal pathogen in humans, also block activation of an IFN-inducible promoter in primate cells. Interestingly, the amino-terminal region of the Nipah virus V protein, which is identical to the amino terminus of Nipah virus W, is sufficient to exert the IFN-antagonist activity. In contrast, the anti-IFN activity of the NDV V protein appears to be located in the carboxy-terminal region of the protein, a region implicated in the IFN-antagonist activity exhibited by the V proteins of mumps virus and human parainfluenza virus type 2.     

Identification of simian virus 40 protein A.

A large simian virus 40 (SV40)-specific protein can be efficiently immunoprecipitated from infected cell extracts with antisera obtained from hamsters bearing SV40-induced tumors. The protein has an apparent molecular weight of 88,000 to 100,000 with respect to markers with known molecular weights, but behaves anomalously on sodium dodecyl sulfate (SDS)-polyacrylamide gels. Cell lines infected by two different strains of SV40 synthesize immunoreactive proteins that differ slightly in mobility during SDS-polyacrylamide gel electrophoresis, evidence that the protein is coded for by the virus. These differences in protein size correlate with differences in the electrophoretic mobility of viral DNA fragments obtained by digestion with HindII and III restriction enzymes. The size of the viral capsid proteins VP2 and VP3 also varies with the strain of virus. dl-1001, a constructed deletion mutant that lacks part of the SV40A gene, directs the synthesis of a 33,000-dalton polypeptide that is not detected in cells infected with wild-type virus. The deletion fragment, like the larger protein, is phosphorylated. Maps of tryptic peptides from the 88,000- to 100,000-dalton protein and the 33,000-dalton fragment show common peptides and provide strong direct evidence that the proteins are products of the SV40 A gene. The deletion fragment reacts with antitumor sera and binds to double-stranded DNA in the presence of the complete A protein.     

鹅源新城疫病毒ZJ1株微型基因组的构建及其初步应用

在获得鹅源新城疫病毒ZJ1株全基因组序列的基础上,用增强型绿色荧光蛋白（eGFP）报告基因取代鹅源新城疫病毒ZJ1株整个编码区,只保留与病毒复制、转录和病毒粒子包装相关的调控序列,将其反向克隆入转录载体TVT7R(0.0)中,构建了该毒株的微型基因组。当转染用辅助病毒ZJ1株感染的Hep_2细胞时报告基因得到表达,表明此微型 基因组RNA可被辅助病毒提供的NP、P和L蛋白翻译。同时将该病毒NP、P和L蛋白基因分别克隆入真核表达载体pCI_neo中,构建了表达该病毒NP、P与L蛋白的辅助质粒,用此微型基因组对辅助质粒的表达产物进行了功能鉴定并对该病毒拯救过程中痘苗病毒的最适感染剂量进行了摸索。以上研究为该病毒的成功拯救及开展其它相关研究奠定了基础。     

Sequential Formation of Vaccinia Virus Proteins and Viral Deoxyribonucleic Acid Replication

In vaccinia virus-infected cell cultures, cellular protein synthesis was inhibited 50% at 2 hr postinfection (PI) and 80 to 90% by 4 hr PI. Input virus was responsible for this inhibition. Five early proteins, coded for by the viral genome, could be detected at 2 to 3 hr PI. Normally, their synthesis did not continue beyond 6 hr PI, at which time synthesis of a different set of proteins began. When DNA replication was blocked, synthesis of these early proteins continued until 9 to 12 hr PI. The bulk of the proteins which were incorporated into mature virus were synthesized at 8 hr PI and thereafter. The time of their formation was close to the time at which virus maturation occurred. However, 15% of the protein found in mature virus was synthesized early in the infectious cycle. The quantity of “early viral protein” which was not incorporated into mature virus was almost as large as the quantity of viral protein which did appear in mature virus. The “early” and “late” proteins could be shown to have separate and distinct immunological properties. The role of this large quantity of “early” protein is discussed.     

Inhibition of cellular protein synthesis by simultaneous pretreatment of host cells with fowl plague virus and actinomycin D: a method for studying early protein synthesis of several RNA viruses.

A method is described for analysis of viral protein synthesis early after infection when minute amounts of viral proteins are effectively concealed by large amounts of produced host-specific proteins. The method is superior to a radioimmune assay, since all virus-induced proteins can be measured independent of their immunological reactivity. Host-specific protein synthesis can be suppressed by infection with fowl plague virus. Addition of actinomycin C 1.25 h postinfection does not prevent this suppression, but it does block effectively the formation of fowl plague virus-specific proteins. Such cells synthesize only small amounts of cellular proteins, as revealed by polyacrylamide electrophoresis. They can be superinfected with several different enveloped viruses, however, without significant diminution of virus yeilds. In pretreated cells the eclipse is shortened for Semliki Forest virus, Sindbis virus, and vesicular stomatitis virus, but prolonged for Newcastle disease virus. The onset of protein synthesis, specific for the superinfecting virus, could be clearly demonstrated within 1 h after superinfection. At this time, in cells superinfected with Semliki Forest virus, great amounts of NSP 75 (nonstructural protein; molecular weight, 75 X 10(3)) and reduced amounts of the core protein C could be deomonstrated. The precursor glycoprotein NSP 68 is followed by a new polypeptide, NSP 65: three proteins with molecular weights exceeding 100 X 10(3) were observed which are missing later in the infectious cycle. Similar results were obtained after superinfection with Sindbis virus. The formation of a new polypeptide with a molecular weight of about 80 X 10(3) was detected. After superinfection with vesicular stomatis virus or Newcastle disease virus the formation of new proteins, characteristic for the early stage of infeciton, was not observed.     

新城疫病毒M蛋白在病毒毒力和复制中的作用研究进展

M蛋白是新城疫病毒(Newcastle disease virus,NDV)基因组编码的一种非糖基化膜相关蛋白,主要位于病毒囊膜内表面,构成病毒囊膜与核衣壳连接的支架.研究表明,M蛋白是一种细胞核-细胞质穿梭蛋白,在抑制细胞基因转录和蛋白质合成以及协助病毒粒子组装和出芽方面发挥了重要作用.目前,国内外对NDV毒力和复制...     

Identification of proteins encoded by Epstein-Barr virus trans-activator genes.

Specific antisera were generated to characterize Epstein-Barr virus proteins reported to have trans-activating properties. Open reading frame BRLF1 was found to be expressed in two modifications in vivo, with molecular sizes ranging from 94 to 98 kilodaltons (kDa) depending on the cell line, whereas only one protein (Raji cells, 96 kDa) was detected by in vitro translation. Open reading frame BZLF1 encoded polypeptides of 38 and 35 kDa and additional smaller forms. A BZLF1-encoded 30-kDa protein could be detected under conditions in which expression was restricted to immediate early genes. Nuclear localization could be detected under conditions in which expression was restricted to immediate early genes. Nuclear localization could be shown for the proteins derived from reading frames BZLF1 and BMLF1. BMLF1 expression gave a heterogeneous protein pattern, with molecular sizes between 45 and 70 kDa, including a predominant 60-kDa protein detected in different B-cell lines.     

Protein synthesis in BHK-21 cells infected with semliki forest virus.

[3H]leucine-labeled proteins synthesized in BHK-21 cells infected with Semliki Forest virus were fractionated by polyacrylamide gel electrophoresis (PAGE). Cellular and virus-specific proteins were identified by difference analysis of the PAGE profiles. The specific activity of intracellular [3H-A1leucine was determined. Two alterations of protein synthesis, which develop with different time courses, were discerned. (i) In infected cultures an inhibition of overall protein synthesis to about 25% of the protein synthesis in mock-infected cultures develops between about 1 and 4 h postinfection (p.i.). (ii) The relative amount of virus-specific polypeptides versus cellular polypeptides increases after infection. About 80% of the proteins synthesized at 4 h p.i. are cellular proteins. Since significant amounts of nontranslocating robosomes in polyribosomes were not detected up to 7 h p.i., the inhibition of protein synthesis is not caused by inactivation of about 75% of all polyribosomes but by a decreased protein synthetic activity of the majority of polyribosomes. Indirect evidence indicates that an inhibition of elongation and/or release of protein synthesis develops in infected cells, which is sufficient to account for the observed inhibition of protein synthesis. Inhibition of over-all protein synthesis developed when virus-specific RNA began to accumulate at the maximal rate. This relationship was observed during virus multiplication at 37, 30, and 25 C. A possible mechanism by which synthesis of virus-specific RNA in the cytoplasm could inhibit cellular protein synthesis is discussed. Indirect evidence and analysis of polyribosomal RNA show that the increased synthesis of virus-specific protein is brought about by a substitution of cellular by viral mRNA in the polyribosomes.     

Evaluation of immunogenic potential of 75kDa and 56kDa proteins of newcastle disease virus (NDV)

The R2B strain of virus of new castle disease virus (NDV) was propagated in 9-11 day old embryonated chicken eggs via allantoic cavity route and after seven serial passages virus was purified from allantoic fluid. Purified virus was analyzed by sodium dodecyl sulfate polyacrylamide gel electrophoresis which yielded six major polypeptides ranging from 38-200 kDa. Protein fractions, corresponding to 75 and 56kDa, resembling haemagglutinin-neuraminidase (HN) and fusion (F) proteins were used to ascertain their immunization potential. Immunization of viral proteins was compared with the whole virus vaccine. Among different group of birds, highest haemagglutination inhibition (HI) and enzyme linked immunosorbent assay (ELISA) titers were obtained in birds immunized with whole virus vaccine followed by viral proteins, 75 and 56kDa in combination which was comparable with birds immunized with 56kDa protein alone. Despite lower values of HI and ELISA titers elicited by viral subunits in immunized birds, when challenged with virulent NDV strain, protection accorded by viral proteins in combination (75 +56kDa) or 56kDa alone was comparable with whole virus vaccine.