Inhibition of measles virus replication by cyclic AMP

Repurposing Papaverine as an Antiviral Agent against Influenza Viruses and Paramyxoviruses

Influenza viruses are highly infectious and are the leading cause of human respiratory diseases and may trigger severe epidemics and occasional pandemics. Although antiviral drugs against influenza viruses have been developed, there is an urgent need to design new strategies to develop influenza virus inhibitors due to the increasing resistance of viruses toward currently available drugs. In this study, we examined the antiviral activity of natural compounds against the following influenza virus strains: A/WSN/33 (H1N1), A/Udorn/72 (H3N2), and B/Lee/40. Papaverine (a nonnarcotic alkaloid that has been used for the treatment of heart disease, impotency, and psychosis) was found to be an effective inhibitor of multiple strains of influenza virus. Kinetic studies demonstrated that papaverine inhibited influenza virus infection at a late stage in the virus life cycle. An alteration in influenza virus morphology and viral ribonucleoprotein (vRNP) localization was observed as an effect of papaverine treatment. Papaverine is a well-known phosphodiesterase inhibitor and also modifies the mitogen-activated protein kinase (MAPK) pathway by downregulating the phosphorylation of MEK and extracellular signal-regulated kinase (ERK). Thus, the modulation of host cell signaling pathways by papaverine may be associated with the nuclear retention of vRNPs and the reduction of influenza virus titers. Interestingly, papaverine also inhibited paramyxoviruses parainfluenza virus 5 (PIV5), human parainfluenza virus 3 (HPIV3), and respiratory syncytial virus (RSV) infections. We propose that papaverine can be a potential candidate to be used as an antiviral agent against a broad range of influenza viruses and paramyxoviruses.IMPORTANCE Influenza viruses are important human pathogens that are the causative agents of epidemics and pandemics. Despite the availability of an annual vaccine, a large number of cases occur every year globally. Here, we report that papaverine, a vasodilator, shows inhibitory action against various strains of influenza virus as well as the paramyxoviruses PIV5, HPIV3, and RSV. A significant effect of papaverine on the influenza virus morphology was observed. Papaverine treatment of influenza-virus-infected cells resulted in the inhibition of virus at a later time in the virus life cycle through the suppression of nuclear export of vRNP and also interfered with the host cellular cAMP and MEK/ERK cascade pathways. This study explores the use of papaverine as an effective inhibitor of both influenza viruses as well as paramyxoviruses.

Down regulation of melanin concentrating hormone in virally induced obesity

Obesity is a complex disease involving genetic components and environmental factors and probably associated with the dysregulation of central homeostasis normally maintained by the hypothalamic neuroendocrine/neurotransmitter network. We previously reported that canine distemper virus (CDV), which is closely related to human measles virus, can target hypothalamic nuclei, and lead to obesity syndrome in the late stages of infection. Here, using differential display PCR, we demonstrate specific down-regulation of melanin-concentrating hormone precursor mRNA (ppMCH) in infected-obese mice. Although ppMCH was down-regulated in all infected mice during the acute stage of infection, this was only seen during the late stage of infection in infected-obese mice. In addition, ppMCH mRNA and protein expression in the lateral hypothalamus was decreased in the absence of neuronal death. These results show the importance of ppMCH in the establishment and maintenance of obesity and the involvement of a virus as an environmental factor.

Measles virus modulates human T-cell somatostatin receptors and their coupling to adenylyl cyclase

The possible role of immunomodulatory peptide somatostatin (SRIF) in measles virus (MV)-induced immunopathology was addressed by analysis of SRIF receptors and their coupling to adenylyl cyclase in mitogen-stimulated Jurkat T cells and human peripheral blood mononuclear cells (PBMC). SRIF-specific receptors were assayed in semipurified membrane preparations by using SRIF14 containing iodinated tyrosine at the first position in the amino acid chain ([125I]Tyr1) as a radioligand. A determination of receptor number by saturation of radioligand binding at equilibrium showed that in Jurkat cells, MV infection led to a dramatic decrease in the total receptor number. The virus-associated disappearance of one (Ki2 = 12 +/- 4 nM [mean +/- standard error of the mean [SEM]]; n = 4) of two somatostatin binding sites identified in control Jurkat cells (Ki1 = 78 +/- 3 pM and Ki2 = 12 +/- 4 nM [mean +/- SEM]; n = 4) was also observed. Almost identical results were obtained for phytohemagglutinin-activated human PBMC. In the absence of MV infection, two somatostatin binding sites were present (Ki1 = 111 +/- 31 pM and Ki2 = 17 +/- 2 nM [mean +/- SEM]; n = 2), whereas in MV-infected cells, only the high-affinity (Ki1 = 48 +/- 15 pM [mean +/- SEM]; n = 2) binding site remained. In addition, MV infection reinforced the inhibitory effects of SRIF on adenylyl cyclase activity, since maximal inhibition at 1 microM peptide was 11% +/- 4% in control cells versus 25% +/- 3% (P < 0.05) in infected Jurkat cells. Moreover, MV infection severely impaired the capacity of adenylyl cyclase to be activated directly (by forskolin) or indirectly (via Gs protein-coupled vasoactive intestinal peptide receptor). An assessment of [methyl-3H]thymidine incorporation showed that SRIF increased proliferative responses to mitogens only in control cells, not in MV-infected cells. Altogether, our data emphasize that MV-associated alteration of SRIF transduction appears to be related to the loss of SRIF-dependent increase of mitogen-induced proliferation.

Spontaneous and differentiation-dependent regulation of measles virus gene expression in human glial cells

The expression of measles virus (MV) in six different permanent human glioma cell lines (D-54, U-251, U-138, U-105, U-373, and D-32) was analyzed. Although all cell lines were permissive for productive replication of all MV strains tested, U-251, D-54, and D-32 cells spontaneously revealed restrictions of MV transcription similar to those observed for primary rat astroglial cells and brain tissue. In vitro differentiation of D-54 and U-251 cells by substances affecting the intracellular cyclic AMP level caused a significant reduction of the expression of the viral proteins after 18, 72, and 144 h of infection. This pronounced restriction was not paralleled to a comparable level by an inhibition of the synthesis and biological activity in vitro of virus-specific mRNAs as shown by quantitative Northern (RNA) blot analyses and in vitro translation. The block in viral protein synthesis could not be attributed to the induction of type I interferon by any of the substances tested. Our findings indicate that down-regulation of MV gene expression in human brain cells can occur by a cell type-dependent regulation of the viral mRNA transcription and a differentiation-dependent regulation of translation, both of which may be crucial for the establishment of persistent MV infections in the central nervous system.

Antibody-dependent transcriptional regulation of measles virus in persistently infected neural cells

Application of neutralizing anti-hemagglutinin antibodies to mouse neuroblastoma cells (NS20Y/MS) persistently infected with measles virus (MV) leads to a significant reduction of viral structural proteins within 6 days. While the transcriptional gradient for MV-specific mRNAs remained unaffected upon antibody treatment, the total amount of MV-specific transcripts dropped by 80% after 24 h. The expression of genomic RNA was affected similarly, with slightly slower time kinetics. Both transcription and expression of the viral structural proteins could be completely reactivated when viral antibodies were removed from the tissue culture. The same findings could be obtained in rat glioma cells persistently infected with subacute sclerosing panencephalitis virus (C6/SSPE) but not in cells of nonneural origin. The data indicate that antibody-induced antigenic modulation affects the early stages of viral transcription within a few hours after the addition of antibodies and leads to an almost complete repression of viral gene expression in cells of neural origin.

Restriction of measles virus gene expression in acute and subacute encephalitis of Lewis rats

Measles virus (MV) replication in brain tissue of Lewis rats with acute (AE) and subacute (SAME) encephalitis was characterized by biochemical techniques. Messenger RNAs specific for measles virus nucleocapsid (N), phospho (P)-, matrix (M), fusion (F), and haemagglutinin (H) protein were detected in all brain extracts examined. The quantity of the individual MV mRNA species was quite different in comparison to lytically infected Vero cells. A steep gradient of MV transcripts was found in brain tissue which is most likely due to strongly attenuated transcription of mRNAs along the viral genome, representing particularly low transcription of the glycoprotein genes. In addition, in vitro translation assays only revealed synthesis of N and P protein in consistent fashion. The mRNAs for the glycoproteins did not direct the synthesis of detectable viral proteins whereas the M mRNA revealed some activity in animals with AE. The data indicate a strong restriction of the MV envelope gene expression in infected brain tissue, which is independent of the incubation time and type of the central nervous system (CNS) disease. This phenomenon which is similar to the findings observed in measles inclusion body encephalitis and subacute sclerosing panencephalitis suggest that host factors may initially be responsible for the initiation of transcriptional and translational alterations.

Inability of translation of mRNA for HVJ (Sendai virus) M protein in a rat glioma cell line at nonpermissive temperatures

The synthesis of M protein of HVJ (Sendai virus) in rat glioma (C6) cells, as has previously been reported, is selectively reduced at a nonpermissive temperature of 39 degrees C. In this phenomenon no difference was found in the viral RNA synthesis and the stability of the viral RNAs between the permissive and nonpermissive temperatures. Oligo dT-selected RNA from the infected cells at either temperature similarly directed M protein synthesis in cell-free translation reactions even if the reaction was performed at 39 degrees C. These results suggest that the restriction of M protein synthesis in C6 cells at the nonpermissive temperature might be due to the inability of translation apparatus to interact with the mRNA coding for M protein.

In vivo and in vitro models of demyelinating disease: activation of the adenylate cyclase system influences JHM virus expression in explanted rat oligodendrocytes

The specificity of JHM virus (JHMV) tropism for rat oligodendrocytes, as one of the primary host cells in the central nervous system, is maintained after explanation (S. Beushausen and S. Dales, Virology 141:89-101, 1985). The temporal correlation between onset of resistance to JHMV infection in vivo, completion of myelination, and maturation of the central nervous system can be simulated in vitro by inducers of oligodendrocyte differentiation (Beushausen and Dales, Virology, 1985). Stimulation of differentiation through the elevation of intracellular cyclic AMP (cAMP) levels suggests a possible connection between activation of the adenylate cyclase system and coronavirus expression. Chromatographic analysis of cAMP-dependent protein kinase activity in cytosol extracts prepared from astrocytes or oligodendrocytes revealed that both glial cell types were deficient in protein kinase I, indicating that expression of coronavirus in differentiated cells was not contingent upon the presence of protein kinase I. However, treatment with N6,2'-O-dibutyryladenosine-3',5'-cyclic monophosphate (dbcAMP) resulted in a severalfold enhancement of the free regulatory subunit (RI) in oligodendrocytes but not in astrocytes. The RII subunit in both neural cell types was relatively unaffected. Rapid increase in RI due to dbcAMP treatment was correlated with inhibition of JHMV expression. Other differentiation inducers, including 8-Br cAMP and forskolin which, by contrast, caused a decrease in detectable RI, also blocked JHMV expression. This apparent anomaly can be attributed to an increased turnover of RI due to destabilization of the molecule which occurs upon site-specific binding of the cyclic nucleotides. On the basis of these observations, we conclude that the state of oligodendrocyte differentiation manifested with the modulation of RI regulates JHMV expression. The differentiation process did not affect either virus adsorption or sequestration but appeared to inhibit the expression of viral RNA and proteins, implying that replication was inhibited at some step between penetration and initiation of genomic functions, perhaps at the stage of uncoating. We therefore examined the possibility that protein kinases and phosphatases, which influence cellular regulation during cAMP-induced differentiation, may be responsible for the phenomenon of coronavirus suppression in oligodendrocytes. Evidence was obtained indicating that normal processing of the phosphorylated nucleocapsid protein is inhibited in differentiated oligodendrocytes, consistent with the notion that JHMV replication might be arrested during uncoating.

Identification of a nonproductive, cell-associated form of measles virus by its resistance to inhibition by recombinant human interferon

Subacute sclerosing panencephalitis (SSPE) is a fatal disease in children and young adults that is caused by persistent infection of the central nervous system (CNS) by a nonproductive, cell-associated form of measles virus. Using an experimental model for SSPE (LEC viral strain in newborn hamsters), we have shown previously that establishment of such CNS infections involves selective elimination from the CNS of productively infected cells by host defensive mechanisms, coupled with the selective sparing of cells carrying nonproductive viral forms. That interferon (IFN) may play a role in this process was suggested by the disappearance of productively infected cells from the CNS tissues prior to the appearance of antiviral antibodies and by the demonstration of cell-associated, IFN-resistant viral variants in the virus stocks that were used. Results of this study support these conclusions by showing that similar IFN-resistant viral variants are present in the HBS strain of SSPE-derived measles virus and that these variants, in the presence of IFN, have properties that are similar to those of naturally occurring cell-associated strains of SSPE viruses, e.g., DR, IP3, and Biken. These IFN-resistant forms of HBS virus were isolated and were shown to maintain their resistance to inhibition by IFN after cloning. However, on removal of IFN, they reverted to productive forms similar to the parental HBS virus. The potential role of such viral forms in the pathogenesis of SSPE is discussed.

The measles virus matrix gene and gene product defined by in vitro and in vivo expression

Sequence analysis of full-length cDNA clones of the measles virus matrix gene revealed three possible open reading frames: M, X1, and X2. The M reading frame differed from the reported sequence by a single nucleotide corresponding to a conservative lysine to arginine amino acid substitution near the carboxy-terminus conserved among the M proteins of paramyxoviruses. The putative X reading frames contained no translational termination codon due to a frame-shift mutation. The protein-coding potential of these reading frames was examined by in vitro translation and DNA-mediated gene transfer into primate cells. The M reading frame produced a 38,000 Mr protein indistinguishable from the M protein in measles virus-infected cells. This protein was not phosphorylated nor processed post-translationally in vivo. The putative X1 and X2 reading frames could be translated into proteins when placed near the 5' terminus of the RNA. The resulting proteins were heterogeneous due to the lack of a termination codon. Translation from the putative X reading frames was adversely affected by an upstream AUG codon and these reading frames were unable to synthesize proteins in their normal 3' locations. At least 146 nucleotides of these 3'-untranslated sequences could be deleted without affecting the expression of M protein in vitro or in vivo. Thus despite the multiple open reading frames, the measles virus M gene is functionally monocistronic.

Host-dependent temperature-sensitive growth of HVJ (Sendai virus) wild-type in rat glioma C 6 cells

At non-permissive temperature viral specific RNA synthesis was not restricted in rat glioma (C 6) cells infected with HVJ (Sendai virus) wild-type. However, as has previously been shown (J Gen Virol [1984] 65: 639-643), the synthesis of M protein was reduced at non-permissive temperature, in contrast to the L, P, HN, Fo and NP proteins which were synthesized in comparable amounts at permissive and non-permissive temperatures. In this report we show additionally that viral nucleocapsids (NC), which consist of L, P and NP proteins, were formed within the infected cells at both temperatures. Hemagglutinin and neuraminidase activities were also detected in samples incubated at non-permissive temperature. By membrane immunofluorescence and cell-surface immunoprecipitation it was shown that migration of HN and Fo proteins to the cell surface occurred normally at non-permissive temperature. Additionally, the L, P and NP proteins, which were associated with the plasma membrane isolated from the infected cells maintained at permissive temperature, were absent from the membrane of cells incubated at non-permissive temperature. These results suggest that NC and glycoproteins synthesized at non-permissive temperature could not assemble effectively at the plasma membrane because of a lack of M protein. Thus, the host-dependent ts lesion of HVJ in C 6 cells was considered to be mainly in M protein synthesis.

Selective inhibition of translation of the mRNA coding for measles virus membrane protein at elevated temperatures

The elevation of culture temperatures of C6 cells that were persistently infected with the Lec strain of the subacute sclerosing panencephalitis (SSPE) virus (C6/SSPE) resulted in immediate selective inhibition of membrane (M) protein synthesis. This phenomenon was confirmed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis of total cytoplasmic lysates and immunoprecipitation with monoclonal antibody against the M protein in short-time labeling experiments. The synthesis of various viral mRNAs in the presence of actinomycin D decreased gradually at similar rates after a shift to 39 degrees C. No specific disappearance of the mRNA coding for the M protein was observed when viral RNAs isolated from the infected cells were compared before and after a shift up by Northern blot analysis. Results of pulse-chase experiments did not show any significant difference in M protein stability between 35 and 39 degrees C. This rapid block of M protein synthesis was observed not only in Vero cells that were lytically infected with plaque-purified clones from the Lec strain, clones isolated from C6/SSPE cells and the standard Edmonston strain of measles virus but also in CV1, MA160, and HeLa cells that were lytically infected with the Edmonston strain. Poly(A)+ RNAs that were extracted from C6/SSPE cells before and after a shift to 39 degrees C produced detectable phospho, nucleocapsid, and M proteins in cell-free translation systems at 32 degrees C. Even higher incubation temperatures did not demonstrate the selective depression of M protein synthesis described above in vitro. All these data indicate that M protein synthesis of measles virus is selectively suppressed at elevated temperatures because of an inability of the translation apparatus to interact with the M protein-encoded mRNA.

Round cell variant of measles virus: neurovirulence and pathogenesis of acute encephalitis in newborn hamsters

A subacute sclerosing panencephalitis (SSPE) strain of measles virus has been previously shown to be composed of two interrelated but separable viral variants. One of these, the syncytiagenic or S variant, resembles defective, cell-associated strains of measles virus; while the other, the round cell inducing or RC variant, induces a highly productive infection in cell culture. It is now reported that the S variant is more neurovirulent in newborn hamsters than the RC variant and that viral replication in infected CNS tissues occurs in two phases. Early in the infection cell-free virus, composed primarily of the RC variant, is produced. Later, coincident with the appearance of antiviral antibody, cell-free virus rapidly disappears, leaving behind only cell-associated virus which resembles the S variant. Quantification of viral antigen expression in the infected tissues suggests that this change in the state of infection is not associated with antigenic modulation, but rather is the result of preferential elimination of RC variant infected cells.

Quantification of measles virus antigens in infected CNS tissue: development of an enzyme linked immunoassay

An enzyme linked immunoassay procedure has been developed which allows accurate quantification of low levels of measles virus antigens in infected central nervous system (CNS) tissues. In its development a systematic study was made of the effects of a large excess of nonviral proteins on the assay results. It was found that controls using single proteins such as bovine serum albumin were inadequate. Further, results indicate that experimental samples and viral antigen standards must be closely matched for their content of CNS tissue proteins since such proteins exert distinctive quantitative effects, both dramatic and subtle.

Round cell variant of measles virus: spontaneous conversion from productive to cell-associated state of infection

A subacute sclerosing panencephalitis strain of measles virus was found to be composed of two viral variants distinguishable by their cytopathic effects in Vero cells. One of the variants was similar to defective cell-associated measles virus strains, whereas the other was highly productive of viral progeny but did not induce cell fusion. Cloning of the variants by an agarose plaque procedure revealed a consistent and rapid interconversion of the variants into one another. While the mechanism of this interconversion remains unknown, analysis of the expression of viral antigens by the variants using indirect immunofluorescence with monoclonal antibodies specific for measles structural antigens suggested that the interconversion involved modulation of the expression of the viral matrix or M antigen.

Inhibitory effect of papaverine on RNA and protein synthesis of vesicular stomatitis virus

Papaverine, an inhibitor of cAMP phosphodiesterase, reduced yields of infectious vesicular stomatitis virus in HEp-2 cells approximately 100-fold if added to cultures at a concentration of 30 microM before and after virus infection. The extent of papaverine-induced suppression of viral growth was dependent on drug dose and treatment regimen. Cells progressively recovered their viral permissive state after removal of drug. The cyclic nucleotide, cGMP, nullified the inhibitory effect of papaverine if added to cells during drug treatment. Pulse labeling experiments with [35S]methionine showed that papaverine compromises production of all virus-specific proteins in infected cells without adversely affecting host cell protein synthesis. Treatment of cells with papaverine strongly inhibited the production of viral RNA and both cellular RNA and DNA. It was found that VSV causes an immediate but transient stimulation of DNA synthesis in HEp-2 cells which is prevented by papaverine treatment. This drug also selectively blocked primary transcription of VSV in vivo and to a lesser extent in vitro RNA polymerase activity of the virion-bound transcriptase. The finding that papaverine has a strong inhibitory effect on viral biosynthesis including early transcription suggests that VSV replication may depend on host factors that regulate intracellular levels of cyclic nucleotides such as cAMP.

Reversible restriction of vesicular stomatitis virus in permissive cells treated with inhibitors of prostaglandin biosynthesis

Indomethacin, a potent nonsteroidal inhibitor of prostaglandin synthetase (cyclooxygenase) reduced yields of infectious vesicular stomatitis virus in HEp-2 cells more than 99% if added to cultures at levels of 10(-3)M either before or after infection. Other permissive cell lines differed according to the treatment period and drug level required for restricting productive infections. The inhibitory effect of indomethacin was progressively reduced if infection of cells was delayed for increasing times after drug removal. Strong inhibition of viral replication also occurred in cells treated with the cyclooxygenase antagonists naproxen, phenylbutazone, and oxyphenylbutazone whereas phenacetin, which does not block cyclooxygenase function, was inactive. Enhanced viral replication occurred in indomethacin-treated HEp-2 cultures when these cells were subsequently exposed to such substances as prostaglandin E1, cyclic AMP, or insulin. Conversely, indomethacin-treated cells remained restrictive for VSV if they were subsequently exposed to metabolic inhibitors of functional DNA (actinomycin D or mitomycin C), messenger RNA synthesis (alpha-amanitin), or protein synthesis (cycloheximide) at concentrations that normally do not compromise viral replication. Pretreatment of HEp-2 cells with mitomycin C markedly shifted the dose response for indomethacin-mediated inhibition of VSV from a 90% inhibitory dose of about 10(-4)M to one of 10(-9)M or lower. These findings suggest that preexisting host factors essential for replication of VSV, although rendered nonfunctional by the drug indomethacin, can be replenished unless their synthesis is blocked by various classes of metabolic inhibitors.

Effect of papaverine treatment on replication of measles virus in human neural and nonneural cells

The replication of measles virus in human neural and nonneural cell lines in terms of growth and cytopathic effect was affected by treatment of the cells with papaverine, which increases endogenous cyclic AMP. Suppression of virus growth was most prominent in neuroblastoma cells, followed by that in epidermoid carcinoma and glioblastoma cells, whereas the suppressive effect was relatively weak in oligodendroglioma cells. The papaverine-induced suppression of virus growth in neuroblastoma cells was studied in detail. The suppression that occurred was dependent on the dose of papaverine and was reversible. By treatment with 10 microM papaverine, virus-cell interactions were modified as follows: (i) early replication steps such as adsorption, penetration, and uncoating of the virus were not affected; (ii) synthesis of viral RNAs, including genomic RNA and mRNA, was inhibited; (iii) translation of viral proteins from mRNA was not blocked; and (iv) glycosylation and transport of viral glycoproteins to the cell membrane were not inhibited, but phosphorylation was blocked. The significance of suppressed virus replication in neural cells is discussed in relation to the persistence mechanisms of measles virus in the central nervous system.

Characterization of four cell lines persistently infected with measles virus

Persistently infected cell lines were established by infecting Vero cells with four different strains of measles virus: Edmonston "wild type", Schwarz vaccine strain passaged at high multiplicity of infection, Hallé SSPE strain, and a temperature sensitive mutant of Edmonston strain, designated ts 841. The four cell lines have continued to produce virus at a constant low level over a period of more than two years, although cytopathology and hemagglutinating ability have varied with cell passage. Only virus from cells originally infected with ts 841 appears to be temperature sensitive. In each of the cell lines a sizable population of low density, interfering virus particles was generated, indicating that this is an important mechanism for these four cell lines in maintenance of the measles virus persistent infection.

Prolonged effects of cyclic AMP analogues of phosphatidylcholine biosynthesis in cultured rat hepatocytes

The short- and long-term effects of cyclic AMP analogues and phosphodiesterase inhibitors on phosphatidylcholine biosynthesis in monolayer cultures of rat hepatocytes were investigated. All the compounds tested produced an inhibition of phosphatidylcholine biosynthesis for up to 6 h after addition to the hepatocyte medium. The reduced rate of lipid synthesis was a function of the concentration of cyclic AMP analogue and was independent of the concentration of choline in the medium. The proportion of choline oxidized to betaine was relatively unaffected. Choline was incorporated into hepatocytes by saturable and non-saturable mechanisms. Although the various cAMP analogues had different effects on choline uptake, chlorophenylthio-cAMP reduced uptake of choline by 28% for cells treated for 1.5-15 h. This analogue lowered the Vmax of the saturable component of choline transport by 3.6-fold. Prolonged incubation of the hepatocytes with cAMP analogues resulted in a reversal of the inhibition of phosphatidylcholine synthesis. After 15 h all the compounds tested stimulated the relative incorporation of [methyl-3H]choline into phosphatidylcholine. For hepatocytes incubated with chlorophenylthio-cAMP for 14-16 h, there was a 2.8-fold stimulation of the rate of phosphatidylcholine synthesis. The enzymes responsible for the conversion of choline into phosphatidylcholine were examined at various times after addition of the chlorophenylthio-cAMP to the hepatocyte medium. The reduced synthesis of phosphatidylcholine strongly correlated with inhibition of CTP:phosphocholine cytidylyltransferase activity. After 12 h of treatment with the analogue, the relative inhibition of the cytidylyltransferase activity was reversed.

Expression of five viral antigens in cells infected with wild-type and SSPE strains of measles virus: correlation with cytopathic effects and productivity of infections

Cells infected with four strains (LEC, Biken, IP-3 and DR) of subacute sclerosing panencephalitis (SSPE) virus were compared with wild type measles virus (Edmonston) with respect to titers of extracellular virus, morphology of the cytopathic effect (CPE) and occurrence of different measles virus antigens within infected cells as determined by immune fluorescence. Murine monoclonal antibodies with specifities for the nucleocapsid (NP), polymerase (P), matrix (M), hemagglutinin (H), and fusion (F) proteins as well as specific hyperimmune sera prepared in rabbits against the NP, H and M proteins were used in immune fluorescence analyses of the various strains. All of the strains produced large amounts of NP and P. Only the NP antigen occurred in nuclei of cells. The Edmonston and LEC strains also showed bright fluorescence with the antibodies against the H, F, and M antigens. Immune fluorescent intensity was variably reduced in cells infected with the Biken, IP-3, and DR strains labelled with anti M, H, and F antibodies. The Biken strain produced moderate titers of extracellular virus and moderate amounts of M, H, and F antigens whereas the DR strain produced no extracellular virus and contained no detectable M or F and only trace amounts of H antigen. The IP-3 strain was intermediate both in antigen expression and in production of extracellular virus.

Reversible repression and activation of measles virus infection in neural cells

Conversion of acute measles virus infection to an indolent state has been achieved by treatment of infected cells of neural origin with agents that affect cyclic nucleotide metabolism. Striking results were obtained with papaverine, an inhibitor of cAMP phosphodiesterase that is capable of enhancing neural differentiation. In papaverine-treated cultures, decreased production of infectious virus was accompanied by selective disappearance of intracellular matrix proton, as detected by immunofluorescence. Viral nucleocapsid protein was enhanced in the cytoplasm while three other structural proteins--polymerase, hemagglutinin, and fusion protein--showed little change in distribution or intensity of staining. These results were specific for cells of neural origin and not observed in CV-1 or Vero cultures. cAMP, dibutyryl cAMP, 8-bromo-cAMP, and isobutylmethylxanthine all inhibited replication of virus but less so than did papaverine. Inhibition of virus replication by any of these agents was rapidly reversible, either by removal of the agent or by addition of cGMP to the culture medium and was accompanied by reappearance of the matrix protein. These results suggest that measles virus replication in neural cells depends on host factors, particularly those affecting endogenous cAMP and cGMP. Viral persistence may thus be related to the state of neural differentiation. This model system may yield information on mechanisms of recrudescence observed in some chronic diseases of the nervous system.

Differential effect of prostaglandins and other products of arachidonic acid metabolism on measles virus replication in Vero cells

The influence of cyclic adenosine 3', 5'-monophosphate (cAMP) and prostaglandin (PG), E1, E2, F2 alpha, A2 and thromboxane B2 (TxB2) and measles virus infection was investigated. Addition of PGE1, E2 and cAMP (10(-3)-10(-)8M) inhibited measles virus replication in Vero cells. TxB2 and PGA2 enhanced replication. Cytotoxic effects were not observed. Inhibition of infectious titers (98%) was most pronounced when agents were present throughout replication. Treated cells exhibited hemadsorbing antigen, but the size and number of cytoplasmic inclusions was decreased by cAMP. Pre-treatment of cells with PGE1 or presence of PGE1 during virus adsorption enhanced infectious titers (30%). Results suggest that cAMP and PGE1 inhibit measles virus production infection. That both enhancing and inhibiting effects of PGs were seen suggest that measles virus may require PG at specific times during the replicative cycle.