Swine testis cells contain functional heparan sulfate but are defective in entry of herpes simplex virus.

Herpes simplex virus (HSV) enters and infects most cultured cells. We have found that swine testis cells (ST) produce yields of infectious HSV-1 up to four orders of magnitude lower than those of human embryonic lung (HEL) and HEp-2 cells because of a defect in virus entry. For ST cells, virus binding is reduced, DNA from input virus cannot be detected, and virus proteins are not synthesized. Polyethylene glycol treatment of ST cells after exposure to HSV allows viral entry, protein synthesis, and productive infection. Transfection of viral genomic DNA that bypasses the normal entry process produces similar yields of infectious virus from ST, HEL, and HEp-2 cells. Therefore, all three cell lines can support the HSV replicative cycle. Biochemical analyses and inhibition of sulfation by sodium chlorate treatment show that ST cells contain amounts and types of heparan sulfate (HS) similar to those of highly susceptible cells. HSV infection of sodium chlorate-treated HEL and ST cells indicates the presence of a second, non-HS receptor(s) on susceptible HEp-2 and HEL cells that is missing, or not functional, on poorly susceptible ST cells. We conclude that ST cells are defective in HSV entry, contain functional HS, but lack a functional non-HS receptor(s) required for efficient HSV-1 entry. Further, ST cells provide a novel resource that can be used to identify, isolate, and characterize an HSV non-HS receptor(s) and its role in the entry and tropism of this important human pathogen.     

Synthesis of herpes simplex virus DNA in isolated chromatin.

Herpes simplex virus DNA synthesis was studied in isolated chromatin (HSV chromatin) of African green monkey kidney (RC-37) cells after HSV type 1 infection. After optimizing the in vitro system, HSV chromatin was shown to synthesize both viral and cellular DNA at ratios identical with those seen in vivo. After 30 min of DNA synthesis in vitro, the DNA products were identical in size to the prelabeled parental DNA. More than 60% of the newly synthesized single-stranded DNA fragments sedimented with a sedimentation constant of greater than 10 S. HSV DNA polymerase was found to be responsible for the synthesis of 80% of all in vitro made viral and most likely also cellular DNA sequences.     

Intrinsic resistance to viral infection. Mouse macrophage restriction of herpes simplex virus replication

Macrophages isolated from mice resistant to acute (lethal) infection with a neurovirulent isolate of HSV-1 express intrinsic resistance to viral infection in vitro. Bone marrow (BM), spleen (S), peritoneal (P), and thioglycolate-stimulated peritoneal (Pthio) macrophages isolated from resistant C57BL/6 Cr (B6) mice consistently restrict HSV-1 macromolecular synthesis earlier in the viral replicative cycle than do macrophages isolated from the same tissue sources from more susceptible DBA/2Cr (D2) mice. B6-BM (BM macrophages from B6 mice) restrict HSV macromolecular synthesis at least at two points in the replicative cycle: 1) before the onset of alpha-protein synthesis and 2) between the onset of gamma 1 protein and DNA synthesis. D2-BM macrophages restrict HSV replication at about the time of DNA synthesis. B6-P macrophages restrict HSV replication shortly after gamma 1 protein synthesis, and D2-P macrophages inhibit the virus slightly later, but before DNA synthesis. B6-S macrophages restrict HSV replication at about the time of DNA synthesis, and D2-S macrophages inhibit replication after the onset of gamma 2 protein synthesis. Pthio macrophages are more permissive to HSV infection than BM, P, or S macrophages: restrictions in viral replication occur at the time of DNA synthesis in B6-Pthio macrophages, and after the onset of gamma 2 protein synthesis in D2-Pthio cells. These studies demonstrate that isolated macrophages from inbred mouse strains express intrinsic resistance to HSV infection that correlates with in vivo resistance to acute (lethal) infection. Intrinsic resistance to HSV-1 infection is due to restriction of viral macromolecular synthesis. HSV replication is inhibited in macrophages at multiple points in the viral growth cycle, depending on the tissue from which the cells are isolated.     

DNA polymerase in nuclei isolated from herpes simplex virus type-2-infected cells. Characterization of the reaction product and inhibition by substrate analogs

Nuclei isolated from herpes simplex virus (HSV) type 2-infected KB cells were examined for their capacity to serve as an in situ source of herpes DNA polymerase. In contrast to purified enzymes with added template, approx. 80% of the DNA synthesized in isolated nuclei was viral. The average size of DNA fragments labeled in vitro was 3.2 X 10(6) Da. Based on an increase in DNA density when nuclei were incubated in the presence of BrdUTP rather than dTTP, 16% of the nucleotides were added during the in vitro reaction. Sucrose gradient analysis of DNA polymerase activity in extracts of isolated nuclei demonstrated the nearly exclusive presence of herpes DNA polymerase. Km concentrations for the four dNTPs were from 0.14 to 0.55 microM. DNA synthesis was inhibited competitively by the 5'-triphosphates of ara-A and ara-C (Ki = 0.03 and 0.22 microM, respectively) but not by the 5'-triphosphate of dideoxythymidine. aATP also served as a substrate (Km = 0.014 microM) for the reaction. We conclude that nuclei from HSV-infected cells have significant advantages for the detailed study of inhibitors of herpesvirus replication.     

Herpes simplex virus-specified DNA polymerase is the target for the antiviral action of 9-(2-phosphonylmethoxyethyl)adenine.

9-(2-Phosphonylmethoxyethyl)adenine (PMEA) is a new antiviral compound with activity against herpes simplex virus (HSV) and retroviruses including human immunodeficiency virus. Although it has been suggested that the anti-HSV action of PMEA is through inhibition of the viral DNA polymerase via the diphosphorylated metabolite of PMEA (PMEApp), no conclusive evidence for this has been presented. We report that in cross-resistance studies, a PMEA-resistant HSV variant (PMEAr-1) was resistant to phosphonoformic acid, a compound which directly inhibits the HSV DNA polymerase. In addition, phosphonoformic acid-resistant HSV variants with defined drug resistance mutations within the HSV DNA polymerase gene were resistant to PMEA. Furthermore, the HSV DNA polymerase purified from PMEAr-1 was resistant to PMEApp in comparison with the enzyme from the parental virus. Moreover, PMEA inhibited HSV DNA synthesis in cell culture. These results provide strong evidence that HSV DNA polymerase is the major target for the anti-viral action of PMEA. Further studies showed that HSV DNA polymerase incorporated PMEApp into DNA in vitro, while the HSV polymerase-associated 3'-5' exonuclease was able to remove the incorporated PMEA. Thus, the inhibition of HSV DNA polymerase by PMEApp appears to involve chain termination after its incorporation into DNA.     

Herpes simplex virus DNA synthesis at a preformed replication fork in vitro.

Proteins from herpes simplex virus (HSV)-infected cells were used to reconstitute DNA synthesis in vitro on a preformed replication fork. The preformed replication fork consisted of a nicked, double-stranded, circular DNA molecule with a 5' single-strand tail that was noncomplementary to the template. The products of DNA synthesis on this substrate were rolling-circle molecules, as demonstrated by electron microscopy and alkaline agarose gel electrophoresis. The tails contained double-stranded regions, indicating that both leading- and lagging-strand DNA syntheses occurred. Rolling-circle DNA replication was dependent upon HSV DNA polymerase and ATP and was stimulated by a crude fraction containing ICP8 (HSV DNA-binding protein). Similar protein fractions from mock-infected cells were unable to support rolling-circle DNA replication. This in vitro DNA replication system should prove useful in the identification and characterization of the enzymatic activities required at the HSV replication fork.     

A new class of receptor for herpes simplex virus has heptad repeat motifs that are common to membrane fusion proteins

We isolated a human cDNA by expression cloning and characterized its gene product as a new human protein that enables entry and infection of herpes simplex virus (HSV). The gene, designated hfl-B5, encodes a type II cell surface membrane protein, B5, that is broadly expressed in human primary tissue and cell lines. It contains a high-scoring heptad repeat at the extracellular C terminus that is predicted to form an alpha-helix for coiled coils like those in cellular SNAREs or in some viral fusion proteins. A synthetic 30-mer peptide that has the same sequence as the heptad repeat alpha-helix blocks HSV infection of B5-expressing porcine cells and human HEp-2 cells. Transient expression of human B5 in HEp-2 cells results in increased polykarocyte formation even in the absence of viral proteins. The B5 protein fulfills all criteria as a receptor or coreceptor for HSV entry. Use by HSV of a human cellular receptor, such as B5, that contains putative membrane fusion domains provides an example where a pathogenic virus with broad tropism has usurped a widely expressed cellular protein to function in infection at events that lead to membrane fusion.     

Accumulation of herpes simplex virus type 1 early and leaky-late proteins correlates with apoptosis prevention in infected human HEp-2 cells

We previously reported that a recombinant ICP27-null virus stimulated, but did not prevent, apoptosis in human HEp-2 cells during infection (M. Aubert and J. A. Blaho, J. Virol. 73:2803-2813, 1999). In the present study, we used a panel of 15 recombinant ICP27 mutant viruses to determine which features of herpes simplex virus type 1 (HSV-1) replication are required for the apoptosis-inhibitory activity. Each virus was defined experimentally as either apoptotic, partially apoptotic, or nonapoptotic based on infected HEp-2 cell morphologies, percentages of infected cells with condensed chromatin, and patterns of specific cellular death factor processing. Viruses d27-1, d1-5, d1-2, M11, M15, M16, n504R, n406R, n263R, and n59R are apoptotic or partially apoptotic in HEp-2 cells and severely defective for growth in Vero cells. Viruses d2-3, d3-4, d4-5, d5-6, and d6-7 are nonapoptotic, demonstrating that ICP27 contains a large amino-terminal region, including its RGG box RNA binding domain, which is not essential for apoptosis prevention. Accumulations of viral TK, VP16, and gD but not gC, ICP22, or ICP4 proteins correlated with prevention of apoptosis during the replication of these viruses. Of the nonapoptotic viruses, d4-5 did not produce gC, indicating that accumulation of true late gene products is not necessary for the prevention process. Analyses of viral DNA synthesis in HEp-2 cells indicated that apoptosis prevention by HSV-1 requires that the infection proceeds to the stage in which viral DNA replication takes place. Infections performed in the presence of the drug phosphonoacetic acid confirmed that the process of viral DNA synthesis and the accumulation of true late (gamma(2)) proteins are not required for apoptosis prevention. Based on our results, we conclude that the accumulation of HSV-1 early (beta) and leaky-late (gamma(1)) proteins correlates with the prevention of apoptosis in infected HEp-2 cells.     

Adenovirus DNA synthesized in the presence of aphidicolin

Adenovirus types 2 and 5 DNA synthesized in vivo and in vitro in the presence of aphidicolin were studied. Inhibition of adenoviral DNA synthesis by aphidicolin was only 70% even at a concentration of 30 micrograms/ml of aphidicolin, at which the cellular DNA synthesis was completely inhibited. When initiation of the viral DNA synthesis was synchronized with hydroxyurea and labeled with [3H]thymidine for 60 min, the viral DNA synthesized in the presence of 30 micrograms/ml of aphidicolin was not of full length (35 kb) but small (approximately 12 kb) by analysis of alkaline sucrose density gradient centrifugation. When initiation of the viral DNA synthesis was not synchronized, the viral DNAs ranging from full size to 12 kb were synthesized in the presence of aphidicolin, indicating that the nascent DNAs longer than about 12 kb can continue to elongate in the presence of aphidicolin. This 12 kb DNA was not derived from the degradation products of newly synthesized full size adenoviral DNA. The viral DNA synthesis was restored and the full size of adenoviral DNA was attained within 15 min following removal of aphidicolin. About 20% of the entire viral genome length from the 5'-end was not inhibited by aphidicolin, while the synthesis of interior fragments of the adenoviral DNA was markedly inhibited by aphidicolin, judging from the electrophoretic pattern on neutral agarose gel after digestion of DNA with Hind III. These results indicate that aphidicolin inhibits adenoviral DNA replication at the internal region located approximately 20-30% from both terminals.     

Synthesis of herpes simplex virus, vaccinia virus, and adenovirus DNA in isolated HeLa cell nuclei. I. Effect of viral-specific antisera and phosphonoacetic acid.

Purified nuclei, isolated from appropriately infected HeLa cells, are shown to synthesize large amounts of either herpes simplex virus (HSV) or vaccinia virus DNA in vitro. The rate of synthesis of DNA by nuclei from infected cells is up to 30 times higher than the synthesis of host DNA in vitro by nuclei isolated from uninfected HeLa cells. Thus HSV nuclei obtained from HSV-infected cells make DNA in vitro at a rate comparable to that seen in the intact, infected cell. Molecular hybridization studies showed that 80% of the DNA sequences synthesized in vitro by nuclei from herpesvirus-infected cells are herpesvirus specific. Vaccinia virus nuclei from vaccinia virus-infected cells, also produce comparable percentages of vaccinia virus-specific DNA sequences. Adenovirus nuclei from adenovirus 2-infected HeLa cells, which also synthesize viral DNA in vitro, have been included in this study. Synthesis of DNA by HSV or vaccinia virus nuclei is markedly inhibited by the corresponding viral-specific antisera. These antisera inhibit in a similar fashion the purified herpesvirus-induced or vaccinia virus-induced DNA polymerase isolated from infected cells. Phosphonoacetic acid, reported to be a specific inhibitor of herpesvirus formation and the herpesvirus-induced DNA polymerase, is equally effective as an inhibitor of HSV DNA synthesis in isolated nuclei in vitro. However, we also find phosphonoacetic acid to be an effective inhibitor of vaccinia virus nuclear DNA synthesis and the purified vaccinia virus-induced DNA polymerase. In addition, this compound shows significant inhibition of DNA synthesis in isolated nuclei obtained from adenovirus-infected or uninfected cells and is a potent inhibitor of HeLa cell DNA polymerase alpha.     

Potential role for herpes simplex virus ICP8 DNA replication protein in stimulation of late gene expression.

We have identified a trans-dominant mutant form of the herpes simplex virus (HSV) DNA-binding protein ICP8 which inhibits viral replication. When expressed by the V2.6 cell line, the mutant gene product inhibited wild-type HSV production by 50- to 150-fold when the multiplicity of infection was less than 5. Production of HSV types 1 and 2 but not production of pseudorabies virus was inhibited in V2.6 cells. The inhibitory effect was not due solely to the high levels of expression, because the levels of expression were comparable to those in the permissive wild-type ICP8-expressing S-2 cell line. Experiments designed to define the block in viral production in V2.6 cells demonstrated (i) that viral alpha and beta gene expression was comparable in the different cell lines, (ii) that viral DNA replication proceeded but was reduced to approximately 20% of the control cell level, and (iii) that late gene expression was similar to that in cells in which viral DNA replication was completely blocked. Genetic experiments indicated that the mutant gene product inhibits normal functions of ICP8. Thus, ICP8 may play distinct roles in replication of viral DNA and in stimulation of late gene expression. The dual roles of ICP8 in these two processes could provide a mechanism for controlling the transition from viral DNA synthesis to late gene expression during the viral growth cycle.     

Synthesis of viral and host DNA in isolated chromatin from herpes simplex virus-infected HeLa cells.

DNA synthesis in chromatin isolated from herpes simplex virus type 1-infected HeLa cells (HSV chromatin) was examined in vitro. The HSV chromatin was found to carry out an initial limited synthesis of DNA in vitro, 50 to 64 pmol of dTMP incorporated in 10(6) nuclei per 10 min, which is comparable to that found in nuclei isolated from HSV-infected cells. DNA synthesis in vitro proceeded for only 30 min, and both HSV DNA and host DNA were synthesized in significant amounts. The HSV and host DNA synthesis in isolated chromatin were inhibited to the same extent by anti-HSV antiserum or by phosphonoacetic acid. The results indicate that the HSV-induced DNA polymerase is most likely involved in the synthesis of host and HSV DNA in isolated chromatin, even though this chromatin contains small amounts of the host gamma-polymerase in addition to the HSV-induced DNA polymerase. The HSV chromatin contains no detectable levels of DNA polymerases alpha and beta, even though infected cells have normal, or increased, levels of these enzymes.     

Electron microscopic mapping of proteins bound to herpes simplex virus DNA.

Exonuclease digestion experiments have suggested that there is a protein(s) bound close to one or both ends of herpes simplex virus-1 (HSV) DNA. The existence of such bound proteins has been positively demonstrated and their positions on the HSV genome determined by application of a newly developed method for electron microscopic mapping of proteins bound to nucleic acids. Purified HSV DNA was treated with dinitrofluorobenzene under conditions that covalently attach the dinitrophenyl (DNP) group to the proteins in a protein-nucleic acid complex. The HSV DNA-protein-(DNP)n complex was treated with rabbit anti-DNP IgG, and, in some cases, additionally treated with monovalent Fab fragments of goat anti-rabbit IgG, and mounted for examination in the electron microscope. Electron opaque dots representing the protein-(DNP)n-(IgG)m complex were seen on the HSV DNA. Direct measurements of the positions of the protein, as well as partial denaturation mapping, indicate that there are four positions for protein bound to HSV DNA: two near but not at the two ends and two at sites corresponding to the internal inverted repeats of the ends. These results suggest that there is a specific protein binding sequence within the direct terminal repeat of HSV DNA. The previous observation that HSV DNA is more sensitive to digestion by a 3' than by a 5' exonuclease then indicates that the bound protein(s) is more intimately associated with one strand of the specific sequence than with the complementary strand.     

In vitro polyoma DNA synthesis: inhibition by 1-beta-d-arabinofuranosyl CTP.

The effects of 1-beta-D-arabinofuranosyl CTP (ara-CTP) on DNA replication were studied in an in vitro system from polyoma-infected BALB/3T3 cells. Ara-CTP concentrations of larger than or equal to 150 muM were found to block in vitro DNA synthesis completely, and concentrations of smaller than or equal to 0.3 muM had no inhibitory effect. Intermediate concentrations resulted in a concentration-dependent reduction of the in vitro synthesis rate. Long-term labeling with [alpha-32-P]ara-CTP demonstrated the incorporation of the analogue into cellular and viral DNA concomitantly with [3-H]TTP. In pulse-labeling experiments, at noninhibitory concentrations of the analogue, ara-CTP was incorporated into short DNA fragments and long growing strands to relatively the same extent as TTP. Partial venom phosphodiesterase digestion liberated the incoporated are-CTP at essentially the same rate as incorporated TTP, excluding a predominantly terminal incorporation, and after total venom phosphodiesterase digestion greater than 80% of the incorporated ara-CTP was recovered as 5'-ara-CMP. Analysis of the long-term in vitro viral DNA product made in the presence of partially inhibiting ara-CTP concentrations demonstrated that none of the steps leading to mature viral DNA were totally inhibited at the ara-CTP concentrations used. Pulse labeling of replicating viral DNA in the presence of ara-CTP revealed two consistent differences in the pattern found in control pulses: (i) predominant labeling of short chains (5S) with reduced amounts of radioactivity in the longer growing viral DNA strands (smaller than or equal to 16S), and (ii) a one-third to one-half reduction in size for short DNA chains labeled in the presence of ara-CTP. Release of the ara-CTP inhibition with excess dCTP resulted in covalent extension of these smaller short chans to approximately the size of regular short chains labeled in the absence of the inhibitor. Isolated short chains synthesized in the presence of ara-CTP exhibited a slightly lower degree of self-complementarity than regular short chains. The predominant labeling of short chains during pulses is, therefore, not a consequence of discontinuous growth on both sides of the replication fork. Similar results were obtained with ara-ATP and N-ethylmaleimide. The experiments indicate that ara-CTP acts primarily on DNA-polymerizing activities, affecting different DNA polymerases to varying degrees. The results are discussed in terms of the possible number and identity of polymerases involved in viral (and cellular) DNA replication.     

Integration pattern of hepatitis B virus DNA sequences in human hepatoma cell lines.

Four human hepatoma cell lines established from primary hepatocellular carcinomas were examined for the presence of hepatitis B virus DNA sequences. Reassociation kinetic analysis indicated that the cell lines HEp-3B 217, HEp-3B 14, HEp-3B F1, and PLC/PRF/5 contained two, one, one, and four genome equivalents per cell, respectively. Southern blot hybridization analysis demonstrated that hepatitis B virus DNA was integrated into the cellular DNAs of these cell lines. Further liquid hybridization studies with 32P-labeled HincII restriction fragments of hepatitis B virus DNA established that DNA sequences from all regions of the HBV genome were represented in the integrated viral sequences. Although the three HEp-3B cell lines were derived from the same tumor, they differed significantly in their patterns of integration of hepatitis B virus DNA, the number of copies of viral DNA per cell, and their ability to produce the virus-coded surface antigen.