Functional homologies between avian and human alphaherpesvirus VP22 proteins in cell-to-cell spreading as revealed by a new cis-complementation assay.

VP22, encoded by the UL49 gene of Marek's disease virus (MDV), is indispensable for virus cell-to-cell spreading. We show herein that MDV UL49 can be functionally replaced with avian and human viral orthologs. Replacement of MDV VP22 with that of avian gallid herpesvirus 3 or herpesvirus of turkey, whose residue identity with MDV is close to 60%, resulted in 73 and 131% changes in viral spreading, respectively. In contrast, VP22 replacement with human herpes simplex virus type 1 resulted in 14% plaque formation. Therefore, heterologous avian and human VP22 proteins share sufficient structural homology to support MDV cell-to-cell spreading, albeit with different efficiencies.

Morphogenesis of a highly replicative EGFPVP22 recombinant Marek's disease virus in cell culture.

Marek's disease virus (MDV) is an alphaherpesvirus for which infection is strictly cell associated in permissive cell culture systems. In contrast to most other alphaherpesviruses, no comprehensive ultrastructural study has been published to date describing the different stages of MDV morphogenesis. To circumvent problems linked to nonsynchronized infection and low infectivity titers, we generated a recombinant MDV expressing an enhanced green fluorescent protein fused to VP22, a major tegument protein that is not implicated in virion morphogenesis. Growth of this recombinant virus in cell culture was decreased threefold compared to that of the parental Bac20 virus, but this mutant was still highly replicative. The recombinant virus allowed us to select infected cells by cell-sorting cytometry at late stages of infection for subsequent transmission electron microscopy analysis. Under these conditions, all of the stages of assembly and virion morphogenesis could be observed except extracellular enveloped virions, even at the cell surface. We observed 10-fold fewer naked cytoplasmic capsids than nuclear capsids, and intracellular enveloped virions were very rare. The partial envelopment of capsids in the cytoplasm supports the hypothesis of the acquisition of the final envelope in this cellular compartment. We demonstrate for the first time that, compared to other alphaherpesviruses, MDV seems deficient in three crucial steps of viral morphogenesis, i.e., release from the nucleus, secondary envelopment, and the exocytosis process. The discrepancy between the efficiency with which this MDV mutant spreads in cell culture and the relatively inefficient process of its envelopment and virion release raises the question of the MDV cell-to-cell spreading mechanism.

Major rearrangements in the E element and minor variations in the U3 sequences of the avian leukosis subgroup J provirus isolated from field myelocytomatosis.

We collected paraffin-embedded myelocytomatoses induced by subgroup J avian leukosis virus (ALV-J) in French poultry from 1992 to 2000. We used nested PCR to obtain the U3 LTR and the E element sequences that encompass putative binding sites for transcription factors. We observed minor mutations in the U3 sequences that rarely affected transcription factor binding sites, thus preserving the transcriptional potential of the U3 LTR. However, we observed a large variability in the E element sequences from both field and experimental tumor samples. This variability involved genomic rearrangements and various deletions that most often occurred between two direct repeat sequences. Moreover, in seven DNA samples of the 22 field tumors analyzed, we observed two different sequences for the E element region, suggesting that proviral genomes of two different sizes may be simultaneously present in a tumor. Even though most of the E element sequences were mutated or rearranged, all myelocytomatosis samples always exhibited one E element sequence containing at least one putative C/EBP binding site that was unaffected and still potentially functional.

Immunoreactive domains and integrin-binding motifs in adenovirus penton base capsomer.

A panel of nine independent mouse monoclonal antibodies (MAbs) against penton base capsomers of subgenus C adenovirus serotypes 2 (Ad2) and 5 (Ad5) were isolated and characterized. Two of them (1D2 and 5A5), raised against Ad5 virion as the immunogen, bound to sodium dodecyl sulfate (SDS)-resistant and subgenus C-specific epitopes that were not present in subgenus B Ad3 penton base. The 1D2 and 5A5 epitopes were mapped to two distinct regions that did not belong to the main variable region carrying the integrin-binding RGD motif at position 340. For the other seven MAbs, raised against recombinant Ad2 penton base protein (9S-pentamers), the epitopes were sensitive to SDS-denaturation, but reacted with native Ad2, Ad5, and Ad3 penton base. The epitopes recognized by the nine MAbs and by polyclonal antipenton base antibodies defined three major immunoreactive regions. One (I) mapped to the N-terminal domain (residues 116-165); the other two regions were almost symmetrically disposed on both sides of the integrin-binding RGD motif at position 340, within residues 248-270 (II), and within residues 368-427 (III) in the C-terminal domain. Region II overlapped the fiber-binding site in penton base (residues 254-260). None of the MAbs showed any detectable virus neutralization effect, but they all slightly augmented the efficiency of Ad-mediated gene transfer. Although none of their epitopes included the RGD-340 tripeptide, substitutions of the arginine residue in the RGD motif abolished the reactivity of six individual and distant epitopes, suggesting a major conformational role for the RGD-containing domain.

Definition of an amino-terminal domain of the human T-cell leukemia virus type 1 envelope surface unit that extends the fusogenic range of an ecotropic murine leukemia virus.

Murine leukemia viruses (MuLV) and human T-cell leukemia viruses (HTLV) are phylogenetically highly divergent retroviruses with distinct envelope fusion properties. The MuLV envelope glycoprotein surface unit (SU) comprises a receptor-binding domain followed by a proline-rich region which modulates envelope conformational changes and fusogenicity. In contrast, the receptor-binding domain and SU organization of HTLV are undefined. Here, we describe an HTLV/MuLV envelope chimera in which the receptor-binding domain and proline-rich region of the ecotropic MuLV were replaced with the potentially corresponding domains of the HTLV-1 SU. This chimeric HTLV/MuLV envelope was processed, specifically interfered with HTLV-1 envelope-mediated fusion, and similar to MuLV envelopes, required cleavage of its cytoplasmic tail to exert significant fusogenic properties. Furthermore, the HTLV domain defined here broadened ecotropic MuLV envelope-induced fusion to human and simian cell lines.

Features of the SIVmac transmembrane glycoprotein cytoplasmic domain that are important for Env functions.

The cytoplasmic domain (CD) of the SIVmac transmembrane protein (TM) can affect viral infectivity by modulating several Env functions, notably fusogenic capacity and incorporation into virions. In addition, envelopes with a truncated CD are counterselected in primary cells in culture and in vivo in rhesus macaques, suggesting a role for this domain in viral persistence. Here, we have used mutagenesis to examine specific features of the SIVmac TM CD, including the conserved C-terminal alpha helix and the overall length of the CD. Several mutations dramatically reduced and/or delayed virus infectivity in lymphoid cell lines. Detailed analysis of mutants revealed defects in envelope stability, fusogenic capacity, and virion incorporation. The primary defect associated with an envelope containing a 64-residue CD was rapid degradation. A mutant Env lacking the C-terminal alpha helix but encoding an exceptionally long CD (373 residues) was highly fusogenic but inefficiently incorporated into virions. A third mutant, containing amino acid substitutions designed to alter the charge density of the C-terminal helix, retained cytopathic properties and showed enhanced fusogenic capacity but replicated with delayed kinetics. Taken together, these results demonstrate that CD sequence variation entails functional "tradeoffs" that can involve optimization of certain Env functions at the expense of others.

Regulation of Golgi structure through heterotrimeric G proteins.

We have previously shown that ilimaquinone (IQ), a marine sponge metabolite, causes complete vesiculation of the Golgi stacks. By reconstituting the IQ-mediated vesiculation of the Golgi apparatus in permeabilized cells, we now demonstrate that this process does not require ARF and coatomers, which are necessary for the formation of Golgi-derived COPI vesicles. We find that IQ-mediated Golgi vesiculation is inhibited by G alpha(s)-GDP and G alpha(i3)-GDP. Interestingly, adding betagamma subunits in the absence of IQ is sufficient to vesiculate Golgi stacks. Our findings reveal that IQ-mediated Golgi vesiculation occurs through activation of heterotrimeric G proteins and that it is the free betagamma, and not the activated alpha subunit, that triggers Golgi vesiculation.

Membrane fusion in organelle biogenesis.

Intracellular membrane fusion is a fascinating reaction that is crucial for cellular function. Several components of the membrane fusion machinery have been identified, although a precise understanding of the fusion mechanism is lacking. More recent studies are revealing novel proteins that regulate membrane fusion during organelle assembly.

TM domain swapping of murine leukemia virus and human T-cell leukemia virus envelopes confers different infectious abilities despite similar incorporation into virions.

We investigated the influence of transmembrane protein (TM) domains on incorporation of retroviral envelopes into virions and on infectivity. We introduced complete, truncated, or chimeric Friend murine leukemia virus (F-MuLV) and human T-cell leukemia virus type 1 (HTLV-1) envelopes into an MuLV particle-producing complementation cell line. As shown previously for HTLV-1 envelopes containing extracellular domains of F-MuLV TM (C. Denesvre, P. Sonigo, A. Corbin, H. Ellerbrok, and M. Sitbon, J. Virol. 69:4149-4157, 1995), reverse chimeric F-MuLV envelopes containing the extracellular domain of HTLV-1 TM were not processed. In contrast, a chimeric MuLV envelope containing the entire HTLV membrane-spanning and cytoplasmic domains (FHTMi) was efficiently processed, fusogenic as tested in a cell-to-cell assay, and efficiently incorporated into MuLV particles. However, these MuLV particles bearing FHTMi envelope proteins could not infect mouse or rat cells which are susceptible to wild-type F-MuLV. Therefore, envelopes which are readily fusogenic in cell-to-cell assays and also efficiently incorporated into virions may not necessarily confer virus-to-cell fusogenicity. HTLV envelopes, whether parental, chimeric (containing the MuLV cytoplasmic tail) or with a truncated cytoplasmic domain, were incorporated into MuLV particles with equal efficiencies, indicating that the cytoplasmic tails of these envelopes did not determine their incorporation into virions. In contrast to FHTMi envelope, HTLV-1 envelopes with F-MuLV membrane-spanning and cytoplasmic domains, as well as wild-type HTLV-1 envelopes, conferred virion infectivity. These results help to define requirements for envelope incorporation into retroviral particles and their cell-free infectivity.

Highly attenuated SIVmac142 is immunogenic but does not protect against SIVmac251 challenge.

We report here the use of the highly attenuated SIVmac142 clone, unable to establish permanent infection of rhesus macaques, in a vaccine trial. Four rhesus macaques were immunized over a long time period with HUT-78 cells infected with wild-type SIVmac142 or, in order to reinforce the safety use of the vaccine, a deleted mutant with similar in vitro infectivity. The first two injections were done with living cells and the remaining boosts with cells emulsified in muramyl dipeptide adjuvant. Three control macaques were injected with uninfected HUT-78 cells. Over 3 years, we have been unable except once to detect viral infections by three methods. However, antibodies directed against the viral Gag proteins and envelope glycoproteins were detected by immunoblots and/or in vitro neutralization assays. All macaques were challenged intravenously with a low dose (10 animal infectious doses) of a highly pathogenic biological clone of SIVmac251 grown on macaque PBMCs. All seven animals became persistently viremic following challenge. The cell-associated viral loads of the vaccinated monkeys were not reduced relative to those of unvaccinated controls during the first weeks postchallenge even if vaccinated monkeys did not present a transient CD4 decrease. Thus, our data reinforced the notion that the efficacy of live attenuated SIV requires the establishment of persistent infection.

Influence of transmembrane domains on the fusogenic abilities of human and murine leukemia retrovirus envelopes.

The envelopes of two highly divergent oncoviruses, human T-cell leukemia virus type 1 (HTLV-1) and Friend murine leukemia virus (F-MuLV), have distinct patterns of cellular receptor recognition, fusion, and syncytium formation. To analyze the influence of the transmembrane envelope subunit (TM) on fusogenic properties, we substituted either the entire TM or distinct domains from F-MuLV for the corresponding domains in the HTLV-1 envelope. Parental, chimeric, and truncated envelopes cloned into a eukaryotic expression vector were monitored for fusogenic potential in human, rat, and murine indicator cell lines by using a quantitative assay. This highly sensitive assay allowed us to assess the fusogenic properties and syncytium-forming abilities of the HTLV-1 envelope in murine NIH 3T3 cells. All chimeric envelopes containing extracellular sequences of the F-MuLV TM were blocked in their maturation process. Although deletions of the HTLV-1 cytoplasmic domain, alone and in combination with the membrane-spanning domain, did not prevent envelope cell surface expression, they impaired and suppressed fusogenic properties, respectively. In contrast, envelopes carrying substitutions of membrane-spanning and cytoplasmic domains were highly fusogenic. Our results indicate that these two domains in F-MuLV and HTLV-1 constitute structural entities with similar fusogenic properties. However, in the absence of a cytoplasmic domain, the F-MuLV membrane-spanning domain appeared to confer weaker fusogenic properties than the HTLV-1 membrane-spanning domain.

The envelopes of two ecotropic murine leukemia viruses display distinct efficiencies in retroviral vaccination by interference.

In cell cultures infected with a retrovirus, the expression of the viral envelope interferes with superinfection by retroviruses which recognize the same receptor. We have previously demonstrated that vaccination of susceptible strains of mice (of the Mus musculus species) with the attenuated ecotropic Friend murine leukemia virus (F-MuLV) B3 efficiently protects against the early hemolytic anemia and the erythroleukemia induced by a challenge with the virulent F-MuLV 57 through a similar in vivo mechanism of interference to superinfection (A. Corbin and M. Sitbon, J. Virol. 67, 5146-5152, 1993). Vaccination with the heterologous ecotropic Moloney-MuLV (M-MuLV) efficiently protects against the early hemolytic anemia but has a weak protective effect on the F-MuLV 57-induced erythroleukemia. Furthermore, vaccination with the attenuated F-MuLV B3 had only a transient protective effect on M-MuLV-induced thymomas. These different efficiencies of F- and M-MuLV to confer protection in this model of vaccination by interference were mostly due to envelope sequences, indicative of distinct in vivo interference properties of the two ecotropic envelopes.