Role of the RNA recognition motif of the E1B 55 kDa protein in the adenovirus type 5 infectious cycle.

Although the adenovirus type 5 (Ad5) E1B 55 kDa protein can bind to RNA in vitro, no UV-light-induced crosslinking of this E1B protein to RNA could be detected in infected cells, under conditions in which RNA binding by a known viral RNA-binding protein (the L4 100 kDa protein) was observed readily. Substitution mutations, including substitutions reported to inhibit RNA binding in vitro, did not impair synthesis of viral early or late proteins or alter significantly the efficiency of viral replication in transformed or normal human cells. However, substitutions of conserved residues in the C-terminal segment of an RNA recognition motif specifically inhibited degradation of Mre11. We conclude that, if the E1B 55 kDa protein binds to RNA in infected cells in the same manner as in in vitro assays, this activity is not required for such well established functions as induction of selective export of viral late mRNAs.

An early function of the adenoviral E1B 55 kDa protein is required for the nuclear relocalization of the cellular p53 protein in adenovirus-infected normal human cells.

It is well established that the human subgroup C adenovirus type 5 (Ad5) E1B 55 kDa protein can regulate the activity and concentration of the cellular tumor suppressor, p53. However, the contribution(s) of these functions of the E1B protein to viral reproduction remains unclear. To investigate this issue, we examined properties of p53 in normal human cells infected by E1B mutant viruses that display defective entry into the late phase or viral late mRNA export. The steady-state concentrations of p53 were significantly higher in cells infected by the E1B 55 kDa null mutant Hr6 or three mutants carrying small insertions in the E1B 55 kDa protein coding sequence than in Ad5-infected cells. Nevertheless, none of the mutants induced apoptosis in infected cells. Rather, the localization of p53 to E1B containing nuclear sites observed during infection by Ad5 was prevented by mutations that impair interaction of the E1B protein with p53 and/or with the E4 Orf6 protein. These results indicate that the E1B protein fulfills an early function that correlates efficient entry into the late phase with the localization of E1B and p53 in the nucleus of Ad5-infected normal human cells.

The vaccinia virus F11L gene product facilitates cell detachment and promotes migration.

We previously showed that infection with vaccinia virus (VV) induces cell motility, characterized by contractility and directed migration. Motility is temporally regulated because cells are motile immediately after infection, whereas late in infection motility ceases and cells resettle. Motility and its cessation are accompanied by temporal rearrangements of both the microtubule and the actin networks. Because the F11L gene has previously been implicated in VV-induced migration, we now explore the role of F11L in contractility, migration, the cessation of motility and the cytoskeletal rearrangements. By live cell imaging using a VV that lacks an intact F11L gene, we show that F11L facilitates cell detachment and is required for migration but not for contractility. By light microscopy, F11L expression induces a remodeling of the actin, but not the microtubule, network. The lack of migration correlates with smaller plaques, indicating that this process facilitates cell-to-cell spreading of VV. Late in infection, when motility ceases, cells re-establish cell-to-cell contacts in an F11L-independent manner. We finally show that VV-induced motility and its cessation correlate with a temporal regulation of the guanosine triphosphatase RhoA as well as the expression levels of F11L during the infectious cycle.

Marker rescue mapping of the combined Condit/Dales collection of temperature-sensitive vaccinia virus mutants.

Complementation analysis of the combined Condit/Dales collection of vaccinia virus temperature-sensitive mutants has been reported (Lackner, C.A., D'Costa, S.M., Buck, C., Condit, R.C., 2003. Complementation analysis of the Dales collection of vaccinia virus temperature-sensitive mutants. Virology 305, 240-259), however not all complementation groups have previously been assigned to single genes on the viral genome. We have used marker rescue to map at least one representative of each complementation group to a unique viral gene. The final combined collection contains 124 temperature-sensitive mutants affecting 38 viral genes, plus five double mutants.

Phenotypic analysis of a temperature sensitive mutant in the large subunit of the vaccinia virus mRNA capping enzyme.

The heterodimeric vaccinia virus mRNA capping enzyme is a multifunctional enzyme, encoded by genes D1R and D12L. Published biochemical experiments demonstrate that, in addition to mRNA capping, the enzyme is involved in early viral gene transcription termination and intermediate viral gene transcription initiation. This paper presents the phenotypic characterization of Dts36, a temperature sensitive mutant in the large subunit of the mRNA capping enzyme (G705D), encoded by gene D1R. At the non-permissive temperature, Dts36 displays decreased steady state levels of some early RNAs, suggesting a defect in mRNA capping. Mutant infections also show decreased steady state levels of some early proteins, while DNA replication and post-replicative gene expression are absent. Under non-permissive conditions, the mutant directs synthesis of longer-than-normal early mRNAs from some genes, demonstrating that early gene transcription termination is defective. If mutant infections are initiated at the permissive temperature and shifted to the non-permissive temperature late during infection, steady state levels of intermediate gene transcripts decrease while the levels of late gene transcripts remain constant, consistent with a defect in intermediate gene transcription initiation. In addition to its previously described role in mRNA capping, the results presented in this study provide the first in vivo evidence that the vaccinia virus mRNA capping enzyme plays a role in early gene transcription termination and intermediate gene transcription.

Accuracy and repeatability of a micro plaque reduction neutralization test for vaccinia antibodies.

The detection of neutralizing antibodies against vaccinia virus is a valuable tool for the investigation of previous smallpox vaccination. Compulsory smallpox vaccination ended in Brazil during the early 1970s, although the vaccine was available until the late 1970s. The threat of smallpox as a biological weapon has called the attention of public health authorities to the need for an evaluation of the immune status of the population. Based on our previous experience with a micro plaque reduction neutralization test (PRNT) for the evaluation of yellow fever immunity, a similar test was developed for the detection and quantification of vaccinia neutralizing antibodies. A cross-sectional study to test the repeatability and validity of plaque reduction neutralization test (PRNT) for vaccinia antibodies was performed in 182 subjects divided into two categories: subjects above 31 years old and the other > or = 35 years old. Cases were subjects considered to have been vaccinated with vaccinia virus if they declared vaccination history or evidenced vaccination marks. The assay is carried out in 96-well plates, provides results within 30 h, is easily performed, has good sensitivity (92.7%) and specificity (90.8), excellent repeatability (ICC 0.89 (0.88; 0.92)) and is thus suitable for use in mass screening of a population's antibody levels.

The vaccinia virus E8R gene product is required for formation of transcriptionally active virions.

Two vaccinia virus temperature-sensitive mutants were mapped to the E8R gene and subjected to phenotypic characterization. Dts23 contains a missense mutation in the coding region of E8R (L81F), and in Cts19 the initiating methionine codon is changed from ATG to ATA (M1I). The two ts mutants display normal patterns of gene expression and DNA replication during infection. The E8 protein is synthesized exclusively late during infection and packaged into virion cores Western blot analysis revealed that E8 synthesis is reduced in Dts23 infected cells at permissive (31 degrees C) and non-permissive temperature (39.7 degrees C) and absent in Cts19 infection under both conditions. Dts23 virions produced at 39.7 degrees C were indistinguishable in appearance from wt virions. Cts19 fails to produce identifiable viral structures when incubated at 39.7 degrees C. Purified Dts23 virions produced at 39.7 degrees C contain reduced amounts of E8 and have a high particle to infectivity ratio; purified Cts19 virions grown at 31 degrees C also show reduced infectivity and do not contain detectable E8. Dts23 grown at 39.7 degrees C could enter cells but failed to synthesize early mRNA or produce CPE. Soluble extracts from mutant virions were active in a promoter dependent in vitro transcription assay, however intact mutant cores were defective in transcription. We suggest that E8 plays a subtle role in virion core structure that impacts directly or indirectly on core transcription.

Temperature-sensitive mutants in the vaccinia virus 4b virion structural protein assemble malformed, transcriptionally inactive intracellular mature virions.

Two noncomplementing vaccinia virus temperature-sensitive mutants, Cts8 and Cts26, were mapped to the A3L gene, which encodes the major virion structural protein, 4b. The two ts mutants display normal patterns of gene expression, DNA replication, telomere resolution, and protein processing during infection. Morphogenesis during mutant infections is normal through formation of immature virions with nucleoids (IVN) but appears to be defective in the transition from IVN to intracellular mature virus (IMV). In mutant infections, aberrant particles that have the appearance of malformed IMV accumulate. The mutant particles are wrapped in Golgi-derived membranes and exported from cells. Purified mutant particles are indistinguishable from wt particles in protein and DNA composition; however, they are defective in a permeabilized-virion-directed transcription reaction despite containing significant (Cts8) or even normal (Cts26) levels of specific transcription enzymes. These results indicate that the 4b protein is required for proper metamorphosis of IMV from IVN and that proper organization of the IMV structure is required to produce a transcriptionally active virion particle.

An alternative genetic method to test essential vaccinia virus early genes.

The vaccinia virus F11L gene product was identified during search for additional factors involved in the control of post-replicative viral gene transcription elongation. F11L is a 1065 base pairs (354 aminoacids) gene expressed early during infection with no attributed function. The F11L gene is conserved in many but not all poxviruses. The essential presence of the F11L gene was tested using two different genetic methods. F11L gene disruption by insertion of a selectable cassette containing the Escherichia coli guanine phosphoribosyl transferase gene driven by the viral early-late 7.5K transcriptional promoter resulted exclusively in recombinant viruses containing both the wild type and disrupted alleles, indicating that the F11L gene was essential. However, an alternative test, using transient dominant selection to insert nonsense mutations into the F11L gene, proved that the F11L gene was non-essential for growth in culture. These experiments suggest that misleading results can be obtained using gene insertional mutagenesis as a test of essential presence of the gene. The experiments also provide genetic data on the probability of co-insertion of linked mutations in vaccinia virus genome using transient dominant selection.

Accidental infection of laboratory worker with vaccinia virus.

We report the accidental needlestick inoculation of a laboratory worker with vaccinia virus. Although the patient had previously been vaccinated against smallpox, severe lesions appeared on the fingers. Western blot and polymerase chain reaction-restriction fragment length polymorphism were used to analyze the virus recovered from the lesions. The vaccinia virus-specific immunoglobulin G levels were measured by enzyme-linked immunosorbent assay. Our study supports the need for vaccination for laboratory workers that routinely handle orthopoxvirus.