Correlation between loss of the temperature-sensitive phenotype and pathogenicity of fowl plague virus mutants in the chicken.

The reversion of temperature-sensitive (ts) mutants of fowl plague virus to the ts+ phenotype was correlated with pathogenicity for chicken. Two types of ts mutants were investigated: those obtained by mutagenesis with 5-fluorouracil and those obtained by undiluted passages at 33 degrees C. The reversion frequency of the former mutants depended on the RNA segment in which the ts defect was located, mutations in RNA segments 1 and 2 having the highest reversion frequency, those in the RNA segments coding for the glycoproteins the lowest. ts mutants obtained by undiluted passages behaved differently in this respect. There was an approximate correlation between frequency of reversion and pathogenicity for chicken. Double mutants induced by 5-fluorouracil, having one tight and one leaky mutation, reverted easily without loss of the leaky mutation. These double mutants were still to a limited extent pathogenic for the chicken. Only one double mutant with two tight mutations (ts 293) was completely nonpathogenic after intramuscular inoculation. Two ts mutants with multiple tight defects (ts 1/1 and ts 3/18) obtained by undiluted passage did not revert to wild-type after injection into embryonated eggs and incubation at 33 degrees C, but they were still slightly pathogenic for the chicken. There was no obvious correlation between the shut-off temperature and pathogenicity of mutants carrying a single ts defect. However, for mutants with multiple tight mutations a high shut-off temperature seemed to be essential for reversion during serial passages as well as for pathogenicity in the chicken, when different routes of inoculation were examined. ts mutants seem to be safe as live vaccines only, (1) if they carry at least two tight ts defects, (2) if they have a relatively low shut-off temperature, and (3) if they could be administered other than via the respiratory tract.

Localisation of the temperature-sensitive defect in the nucleoprotein of an influenza A/FPV/Rostock/34 virus.

The nucleotide sequences of the nucleoprotein (NP) genes of fowl plague virus (FPV) and of a temperature-sensitive (ts) mutant (ts81) derived therefrom have been determined. The ts81-NP nucleotide sequence possesses a single nucleotide substitution in comparison to the wild type. This causes an amino acid exchange at position 332 of the NP. An alanine in the wild type-NP is substituted by a threonine in ts81-NP. This substitution leads to a significant difference in the secondary structure prediction. Although this mutation is located within the karyophilic region of the NP, the accumulation of the NP in ts81-infected cells is not significantly affected at 40 degrees C. Therefore, we assume that the cooperation with one of the polymerase proteins (P) is interfered with at 40 degrees C, leading to the loss of viral vRNA or replicative cRNA synthesis. The comparison of the FPV-NP nucleotide sequence to a previously published sequence of the same strain (Tomley and Roditi, 1984) highlights ten nucleotide differences, four of them leading to amino acid substitutions.

Influence of insulin and 12-O-tetradecanoylphorbol-13-acetate (TPA) on influenza virus multiplication.

Insulin and 12-O-tetradecanoylphorbol-13-acetate (TPA) interfere with the multiplication of fowl plague virus, an influenza A virus, in primary chick embryo cells. Specifically the production of the viral glycoproteins hemagglutinin and neuraminidase are affected by the drugs. A decrease or omission of glucose from the culture medium enhances this effect, which is in agreement with the idea that these drugs act on virus replication via a shortage of glucose in the host cell. Virus replication in cells of different organs is affected to different extents by insulin and TPA.

The methyltransferase inhibitor Neplanocin A interferes with influenza virus replication by a mechanism different from that of 3-deazaadenosine.

Neplanocin A (NeplA) and 3-deazaadenosine (3DA-Ado) are both inhibitors of methyltransferases, and both interfere with influenza virus replication. Their modes of action, however, are different. In chicken embryo cells NeplA inhibits only in media depleted of or low in methionine, while 3DA-Ado acts independently of the concentration of methionine. While homocysteine partially reverses the effect of NeplA, it strongly potentiates the effect of 3DA-Ado. While NeplA inhibits the synthesis of all viral proteins to nearly the same extent, 3DA-Ado interferes only with the production of late proteins (Fischer et al. (1990) Virology 177, 523-531). In NeplA-pretreated cells there is an extreme accumulation of S-adenosylhomocysteine, independent of the concentration of methionine in the medium, although NeplA inhibits influenza virus replication only in methionine-depleted medium. Therefore an accumulation of this intermediate by NeplA cannot account for the inhibitory effect, as has been implicated in the inhibition of the replication of other viruses. Our results indicate that at least two different methyltransferases are involved in influenza virus replication.

Sequence of the nucleoprotein gene of influenza A/parrot/Ulster/73.

The nucleotide sequence of the nucleoprotein (NP) gene of the avian influenza A virus strain A/parrot/Ulster/73 (H7N1) has been determined. The gene (RNA segment 5) consists of 1565 bases. The only large open reading frame of the complementary RNA codes for a protein of 498 amino acids. A comparison of its sequence with that of three other influenza virus NPs shows that the NP of the parrot Ulster strain, although closely related to the NP of the other avian strain (A/FPV/Rostock/34), is definitely more closely related genetically to the NPs of the two human influenza strains, A/PR/8/34 and A/NT/60/68 than that of FPV. This raises the question how far the NP gene can cross the species barrier by reassortment and become adapted by mutation to the new host.

Temperature-sensitive mutants of fowl plague virus defective in the intracellular transport of the hemagglutinin.

Nine mutants of fowl plague virus with temperature-sensitive defects in the biosynthesis of the hemagglutinin have been characterized by analyzing the processing and the intracellular location of this glycoprotein in MDCK and chick embryo cells. It was found that with all of these mutants the transport of the hemagglutinin to the cell surface was impeded at the non-permissive temperature. There were differences, however, in the site of the block. With mutants tsl, ts227, ts478 and ts658 the precursor HA was not cleaved and the oligosaccharide side chains remained sensitive to endoglucosaminidase H. When the hemagglutinin was analyzed in permeabilized cells by immunofluorescence, usually only cytoplasmic labeling was seen. Immunofluorescence of non-permeabilized cells and hemadsorption revealed that the hemagglutinin did not reach the cell surface. In contrast, the hemagglutinin of mutants ts79, ts482, ts532, ts546 and ts651 was cleaved and oligosaccharides were processed to the endoglucosaminidase H-resistant form at non-permissive temperature. In permeabilized cells, the cytoplasm and juxtanuclear regions typical for the Golgi apparatus were labeled by immunofluorescence. Except for ts482, ts532 and ts546 which were leaky, hemagglutinin could not be detected at the cell surface. These observations indicate that, with the first group of mutants, hemagglutinin transport is usually arrested already in the rough endoplasmic reticulum, whereas with the second group it is inhibited at a late stage between the Golgi apparatus and the plasma membrane.

Studies on the temperature sensitivity of influenza A virus reassortants nonpathogenic for chicken.

Influenza A virus reassortants which are nonpathogenic for chickens are like mammalian influenza A viruses in that they are temperature sensitive for growth at 41 degrees C. We have investigated the mechanism of this temperature sensitivity using reassortants between the two highly pathogenic strains A/FPV/Rostock/34 (FPV, H7N1) and A/turkey/England/63 (TE, H7N3). These reassortants show a strict correlation between the pathogenicity for chickens and the constellation of the genes coding for the ribonucleoprotein complex, RNP. Evidence is presented which shows that all viral components are synthesized in sufficient amounts and that the block in the viral replication cycle at the nonpermissive temperature is a late one affecting virus maturation. It is suggested that the RNP, although still enzymatically functional, may lose its ability to interact normally with viral surface components, thus interfering with the process of virus maturation. Some of the nonpathogenic reassortants which possessed the neuraminidase of TE showed an interesting temperature-dependent phenomenon: the haemagglutinin synthesized at the elevated temperature could only agglutinate erythrocytes at 20 degrees C, when the neuraminidase was inhibited or the infected cells vigorously disrupted by ultrasonication. This phenomenon is possibly not directly related to the temperature-sensitive block.

Genetic relatedness of the nucleoprotein (NP) of recent swine, turkey, and human influenza A virus (H1N1) isolates.

The sequences of nucleoprotein (NP) genes of recent human and turkey isolates of influenza A viruses, which serologically could be correlated to contemporary swine viruses, were determined. These sequences were closely related to the NPs of these swine viruses and they formed a separate branch on the phylogenetic tree. While the early swine virus from 1931 resembled the avian strains in consensus amino acids of the NP and in its ability to rescue NP ts mutants of fowl plague virus in chicken embryo cells, the later strains on that branch were different: at 15 positions they have their own amino acids and they rescued the NP ts mutants only poorly. Of the NPs of the human New Jersey/76 isolates analysed, one clustered with the recent H1N1 swine viruses of the U.S.A., the other one with contemporary human strains. Since the NP is one of the main determinants of species specificity it is concluded that, although the H1N1 swine isolates from the U.S.A. form their own branch in the phylogenetic tree, they can be transmitted to humans and turkeys, but they do not spread further in these populations and so far have not contributed to human pandemics. It is not very likely that they will do so in future, since its branch in the phylogenetic tree develops further away from the human and avian branch.

Long-term stability of the anti-influenza A compounds--amantadine and rimantadine.

Amantadine and rimantadine hydrochloride were tested for stability after storage at different temperatures and under different conditions for extended periods of time. Both compounds were quite stable after storage for at least 25 years at ambient temperature; they both retained full antiviral activity after long-term storage or after boiling and holding at 65-85 degrees C for several days. Thus, amantadine and rimantadine could be synthesized in large quantities and stored for at least one generation without loss of activity in preparation for the next influenza A pandemic in humans.

How to overcome resistance of influenza A viruses against adamantane derivatives.

We tested two approaches to overcoming resistance of influenza A viruses against adamantane derivatives. First, adamantane derivatives that interfere with the ion channel function of the variant M2 protein of amantadine-resistant viruses may prevent drug resistance, if they are used in mixture with amantadine. Second, amantadine acts on the M2 protein (at low concentrations) and indirectly on the hemagglutinin (at concentrations at least 100 times higher). Identifying and using a drug that reacted with both targets at the same concentration might reduce development of resistance, since, in this case, two mutations, one in each target protein would be necessary at once. Such a double mutation is assumed to be a rare event. We evaluated forty adamantane derivatives and two related compounds to determine whether they interfered with plaque formation by influenza A strains, including A/Singapore/1/57 (H2N2). Variants resistant to drugs that interfered at low concentrations (approximately 1 microg/ml; e.g. amantadine) were cross-resistant with each other, but were sensitive to those agents effective at high concentrations (8 microg/ml; e.g. memantine). The former group of compounds act on the ion channel; the corresponding escape mutants tested had amino acid replacements at positions 27, 30 or 31 of the M2 protein. Hemagglutinin was the indirect target of the latter group of compounds. Variants resistant to these agents lacked amino acid replacements within the ion channel of the M2 protein and the mutants tested had amino acid replacements in the hemagglutinin. Although we failed to identify compounds that interacted with the ion channel of amantadine-resistant variants and inhibited their replication, we were able to construct at least two compounds that interfered with both the ion channel and the hemagglutinin at about the same concentration. After passage in the presence of these compounds, we either failed to obtain any drug-resistant mutants or those obtained had amino acid replacements in the ion channel of the M2 protein and the hemagglutinin.

Molecular epidemiology of influenza.

The genome of the influenza A viruses comprises eight single-stranded RNA segments, and this property makes genetic reassortment after double infection of a host with two different influenza A strains possible. Nature takes advantage of genetic reassortment during antigenic shift creating new pandemic strains. After concurrent infection of a host with both avian and human strains, the hemagglutinin gene of the human virus may be replaced by the allelic gene of the avian virus. This reassortment leads to a human virus strain that has avian hemagglutinin molecules on its surface, significant because the human population lacks neutralizing antibodies to this new glycoprotein. The Hong Kong pandemic of 1968 resulted from just such an event.

[Neurotropic influenza type A viruses]. / Neirotropnye virusy grippa tipa A.

Influenza A/turkey/England/63 is neurotropic for mice. Substitution of the hemagglutinin gene of this virus by the corresponding gene of A/FPV/ Rostok /34 virus results in the loss of the neurotropic properties of the original virus. Examination of recombinants produced by hybridization of parental strains nonpathogenic (or weakly pathogenic) for newborn mice revealed recombinants highly virulent for this host. A correlation between constellation of genes and neurovirulence for mice was established. After intranasal administration neurovirulent viruses were shown to be able to penetrate into the brain of the infected animal along the trigeminal nerve escaping the blood stream.