Appearance of the bona fide spiral tubule of ORF virus is dependent on an intact 10-kilodalton viral protein.

Parapoxviruses can be morphologically distinguished from other poxviruses in conventional negative staining electron microscopy (EM) by their ovoid appearance and the spiral tubule surrounding the virion's surface. However, this technique may introduce artifacts. We have examined Orf virus (ORFV; the prototype species of the Parapoxvirus genus) by cryoelectron microscopy (cryo-EM) and cryo-negative staining EM. From these studies we suggest that the shape and unique spiral tubule are authentic features of the parapoxviruses. We also constructed an ORFV mutant deleted of a gene encoding a 10-kDa protein, which is an orthologue of the vaccinia virus (VACV) 14-kDa fusion protein, and investigated its ultrastructure. This mutant virus multiplied slowly in permissive cells and produced infectious but morphologically aberrant particles. Mutant virions lacked the spiral tubule but displayed short disorganized tubules similar to those observed on the surface of VACV. In addition, thin extensions or loop-like structures were appended to the ORFV mutant particles. We suggest that these appended structures arise from a failure of the mutant virus particles to properly seal and that the sealing activity is dependent on the 10-kDa protein.

Embedding in Spurr's resin is a good choice for immunolabelling after freeze drying as shown with chemically unfixed dendritic cells.

Immunocytochemical reactions on biological specimens depend on many factors, the most crucial one being the maintenance of antigenicity. Antigens are vulnerable at each stage during preparation for electron microscopy. One of the least traumatic methods of preparing biological tissues for post-embedding immunolabelling includes the following steps: (1) physical stabilization of the native biological material by rapid freezing (cryofixation) and keeping the immobilized biological sample at low temperature, thereby avoiding any movements of water, ions and macromolecules; (2) dehydrating the frozen biological material by freeze-drying at low temperature; (3) embedding of the dehydrated specimen. Here we show that embedding of chemically unfixed dendritic cells in Spurr's resin after cryofixation and freeze-drying enables the conservation of fine ultrastructure without cell distortion or shrinkage. Furthermore, we demonstrate the feasibility of protein localization in ultrathin sections by immunolabelling of the major histocompatibility class II molecules.

Characterization and quality control of recombinant adenovirus vectors for gene therapy.

Highly purified recombinant adenovirus undergoes routine quality controls for identity, potency and purity prior to its use as a gene therapy vector. Quantitative characterization of infectivity is measurable by the expression of the DNA binding protein, an early adenoviral protein, in an immunofluorescence bioassay on permissive cells as a potency determinant. The specific particle count, a key quality indicator, is the total number of intact particles present compared to the number of infectious units. Electron microscopic analysis using negative staining gives a qualitative biophysical analysis of the particles eluted from anion-exchange HPLC. One purity assessment is accomplished via the documented presence and relative ratios of component adenoviral proteins as well as potential contaminants by reversed-phase HPLC of the intact virus followed by protein peak identification using MALDI-TOF mass spectrometry and subsequent data mining. Verification of the viral genome is performed and expression of the transgene is evaluated in in vitro systems for identity. Production lots are also evaluated for replication-competent adenovirus prior to human use. For adenovirus carrying the human IL-2 transgene, quantitative IL-2 expression is demonstrated by ELISA and cytokine potency by cytotoxic T lymphocyte assay following infection of permissive cells. Both quantitative and qualitative analyses show good batch to batch reproducibility under routine test conditions using validated methods.

Enveloped virus is the major virus form produced during productive infection with the modified vaccinia virus Ankara strain.

Modified vaccinia virus Ankara (MVA) is a highly attenuated virus strain that may be useful as a vaccine vector. Ultrastructural examination of purified MVA showed that most of the viral particles are enveloped in contrast to the Copenhagen strain (COP). In CsCl gradients, the majority of the MVA particles displayed a light buoyant density characteristic of the enveloped form. Consistent with these results, MVA particles were poorly labeled with antibodies against the surface of intracellular mature virus but strongly labeled with antibodies against an envelope antigen. Furthermore, MVA was more resistant than the COP strain to neutralization by mouse anti-COP antibodies. These results suggest that the MVA strain may be particularly suitable for the engineering of envelope proteins and that MVA may be able to resist the humoral immunity displayed by previously vaccinated individuals.

Schnitzler syndrome: heterogeneous immunopathological findings involving IgM-skin interactions.

The Schnitzler syndrome is the association of chronic urticaria, intermittent fever, osteosclerotic bone lesions and a monoclonal IgM gammopathy. It is not yet firmly established whether the monoclonal immunoglobulin component plays a part in the pathophysiology of the urticarial lesions. Immunoblotting on epidermal and dermal human skin extracts as well as immunoelectron microscopic (IEM) studies on Lowicryl K4M-embedded skin sections were performed in three patients with the Schnitzler syndrome. Western blotting on epidermal extracts showed the presence of IgM-kappa antiskin autoantibodies in two patients. These antibodies displayed the same isotype as the monoclonal components and recognized a 280-290-kDa antigen in one patient and a 200-kDa antigen in the other patient. IEM studies showed sparse IgM deposits in the epidermis, around the keratinocytes, near the desmosomes in one patient and dense deposits below the lamina densa, in the region of the anchoring fibrils, in another patient. Antiskin IgM autoantibodies of the same isotype as their monoclonal gammopathies can be present in the serum of some patients with the Schnitzler syndrome. These IgM antibodies seem to deposit in vivo in the epidermis and at the dermal-epidermal junction, in the region of the anchoring fibrils. These findings suggest that the monoclonal gammopathy plays a part in the pathophysiology of the skin rash. They also suggest patient heterogeneity both in the skin antigens that are recognized as well as in their localization.

Vaccinia virus-related events and phenotypic changes after infection of dendritic cells derived from human monocytes.

The in vitro interactions between vaccinia virus (VV) and monocyte-derived human dendritic cells (DC) have been studied to gain a better understanding of the mechanisms involved in the induction of an immune response by VV. This work showed that VV binds to DC less efficiently than to HeLa cells (HeLa). Capping of viral antigens on the DC surface and electron microscopic examinations suggested that VV enters into DC mainly by endocytosis instead of fusion as for HeLa. Early viral-encoded proteins were expressed in DC but late viral proteins and viral DNA synthesis did not occur. Nevertheless, when successfully infected, DC expressed a similar amount of a foreign, viral-encoded protein, as HeLa, if the early component of the p7.5 promoter was used. VV infection did not lead to DC maturation as determined by following the level of several cell surface markers associated with maturation, but an inhibition of the expression of the costimulatory molecule CD80 was noticed. The proliferation of allogeneic peripheral blood lymphocytes (PBL) was stimulated by VV-infected DC or inhibited depending on the particular donor lymphocytes employed. PBL from VV-vaccinated individuals with good memory responses to VV antigens proliferated in the presence of infected autologous DC. PBL from individuals with poor memory responses to VV and one unvaccinated individual also proliferated, albeit to a lower level, in the presence of infected autologous DC. These results suggest that VV-infected DC could both stimulate memory cells and prime naive cells in vitro.

Inefficient measles virus budding in murine L.CD46 fibroblasts.

Infection of mouse L.CD46 fibroblasts with measles virus resulted in a poor virus yield, although no defects in the steps of virus binding, entry or fusion, were detected. Two days post-infection, the level of expression of the viral F protein was found to be similar on the surface of infected L.CD46 and HeLa cells using a virus multiplicity enabling an equal number of cells to be infected. After immunofluorescence labelling and confocal microscopy, L.CD46 cells also displayed a significant increase in the co-localisation of the N protein with the cell surface H and F proteins. Immunogold labelling and transmission electron microscopy demonstrated the accumulation of numerous nucleocapsids near the plasma membrane of L. CD46 cells with little virus budding, in contrast to infected HeLa cells which displayed fewer cortical nucleocapsids and more enveloped viral particles. Purified virus particles from infected L. CD46 contained a reduced amount of H, F and M protein. Altogether, these data indicate that, in L.CD46 cells, the late stage of measles virus assembly is defective. This cellular model will be helpful for the identification of cellular factors controlling measles virus maturation.

A functional measles virus replication and transcription machinery encoded by the vaccinia virus genome.

Measles virus encodes three proteins required for the encapsidation, transcription and replication of viral genomes. The genes for these proteins have been inserted into the vaccinia virus genome together with the gene for the bacteriophage T7 RNA polymerase. Cells infected with this recombinant virus were able to encapsidate, transcribe and replicate a CAT gene positioned in the negative polarity behind a T7 promoter and flanked by measles virus genomic termini. Inhibition of the accumulation of the nucleocapsid proteins by actinomycin D led to an increase in CAT expression. Thus the measles virus polymerase activity, encoded by the vaccinia genome, was regulated by the level of measles proteins just as the authentic polymerase. The recombinant vaccinia described in this study could be useful for the production of measles virus-like particles encoding foreign genes and employed in vaccination or gene therapy strategies.

Cutting edge: receptor-mediated endocytosis of heat shock proteins by professional antigen-presenting cells.

Immunization with heat shock proteins (HSPs) induces Ag-specific CTL responses. The specificity of the immune response is based on peptides associated with HSPs. To investigate how exogenous HSP/peptide complexes gain access to the MHC class I-restricted Ag presentation pathway, we incubated the monocytic cell line P388D1 and the dendritic cell line D2SC/1 with gold-labeled HSPs gp96 and HSC70. We show that HSPs bind specifically to the surface of these APCs and are internalized spontaneously by receptor-mediated endocytosis, demonstrating the existence of specific receptors for HSPs on these cells. In addition, we observe colocalization of internalized HSPs and surface MHC class I molecules in early and late endosomal structures. These findings provide possible explanations for the immunogenicity of HSP/peptide complexes and for the transfer of HSP-associated peptides onto MHC class I molecules.

Fiberless recombinant adenoviruses: virus maturation and infectivity in the absence of fiber.

In vivo targeting of therapeutic genes to specific tissues has become a major issue in gene therapy, in particular when recombinant adenovirus vectors are used. Restriction of the viral tropism to selected cell types requires the abrogation of the interaction between the viral fiber and its natural cellular receptors and the introduction of a new binding specificity into the virion. In this context, fiberless adenoviruses are attractive vectors, since they may be used as substrates for the insertion of a new ligand in other capsid proteins. In this study, we confirm by using cloned full-length adenovirus genomes with the fiber gene deleted that efficient virus particle formation can occur in the absence of fiber. As expected, the infectivity of such fiberless viruses was severely reduced, but it could be only partially restored when the viruses were produced in cells stably providing the fiber in trans. Although incorporation of penton base into the fiberless particles was normal and binding of the particles to the cellular integrins was functional, several pieces of experimental evidence suggest that later steps in the cell entry process are impaired in correlation with an incorrect maturation of several structural proteins of the fiberless particles. These observations support the hypothesis that the fiber protein may have additional biological functions besides its role in cell binding. Together with the fiber complementation cells, such fiberless vectors constitute unique tools to investigate the role of the fiber in virus assembly, maturation, and cell entry and to explore the possibility of deriving gene transfer vectors with novel target specificities.

A matrix-less measles virus is infectious and elicits extensive cell fusion: consequences for propagation in the brain.

Measles viruses (MV) can be isolated from the brains of deceased subacute sclerosing panencephalitis patients only in a cell-associated form. These viruses are often defective in the matrix (M) protein and always seem to have an altered fusion protein cytoplasmic tail. We reconstituted a cell-free, infectious M-less MV (MV-DeltaM) from cDNA. In comparison with standard MV, MV-DeltaM was considerably more efficient at inducing cell-to-cell fusion but virus titres were reduced approximately 250-fold. In MV-DeltaM-induced syncytia the ribonucleocapsids and glycoproteins largely lost co-localization, confirming the role of M protein as the virus assembly organizer. Genetically modified mice were inoculated with MV-DeltaM or with another highly fusogenic virus bearing glycoproteins with shortened cytoplasmic tails (MV-Delta(tails)). MV-DeltaM and MV-Delta(tails) lost acute pathogenicity but penetrated more deeply into the brain parenchyma than standard MV. We suggest that enhanced cell fusion may also favour the propagation of mutated, assembly-defective MV in human brains.

Intracellular pathway for the generation of functional MHC class II peptide complexes in immature human dendritic cells.

Binding of antigenic peptides to MHC class II (MHC-II) molecules occurs in the endocytic pathway. From previous studies in B lymphocytes, it is believed that most but not all of the newly synthesized MHC-II molecules are directly targeted from the trans-Golgi network to endosomal compartments. By using pulse-chase metabolic labeling followed by cell surface biotinylation, we show here that in contrast to an EBV-transformed B cell line and human monocytes, the majority of newly synthesized MHC-II molecules (at least 55 +/- 13%) are first routed to the plasma membrane of dendritic cells derived from human monocytes. They reach the cell surface in association with the invariant chain (Ii), a polypeptide known to target MHC-II to the endosomal/lysosomal system. Following rapid internalization and degradation of Ii, these alphabeta Ii complexes are converted into alphabeta-peptide complexes as shown by their SDS stability. These SDS-stable dimers appear as soon as 15 to 30 min after internalization of the alphabeta Ii complexes. More than 80% of alphabeta dimers originating from internalized alphabeta Ii complexes are progressively delivered to the cell surface within the next 2 h. Depolymerization of microtubules, which delays the transport to late endosomal compartments, did not affect the kinetics of conversion of surface alphbeta Ii into SDS-stable and -unstable alphabeta dimers. Altogether, these data suggest that newly liberated class II alphabeta heterodimers may bind peptides in different compartments along the endocytic pathway in dendritic cells derived from human monocytes.

A tyrosine-based signal present in Ig alpha mediates B cell receptor constitutive internalization.

B lymphocytes express Ag receptors (BCR) that are composed of ligand binding subunits, the membrane Igs, associated with Ig alpha/Ig beta heterodimers. One main BCR function is to bind and to internalize Ags. Peptides generated from these internalized Ags may be presented to T lymphocytes. Here, we have analyzed the involvement of BCR Ig alpha/Ig beta components in BCR constitutive endocytosis. The role of Ig alpha subunit in BCR constitutive endocytosis was first determined in the context of an IgM-based BCR. In contrast with BCR that contain wild-type Ig alpha, surface BCR lacking Ig alpha cytoplasmic domain were not constitutively internalized. The respective roles of Ig alpha and Ig beta subunits were then analyzed by expressing chimeric molecules containing the cytoplasmic domains of either subunits in a B cell line. Only the Ig alpha cytoplasmic domain contained an internalization signal that allowed constitutive endocytosis of Ig alpha chimeras via coated pits and accumulation in sorting-recycling endosomes. This internalization signal is contained in its immunoreceptor tyrosine-based activation motif. These results indicate that Ig alpha, through its immunoreceptor tyrosine-based activation motif, may account for the ability of IgM/IgD BCR to constitutively internalize monovalent Ags.

The assembly of the measles virus nucleoprotein into nucleocapsid-like particles is modulated by the phosphoprotein.

Measles virus nucleoprotein encoded from the vaccinia virus genome assembles into nucleocapsids similar in many respects to those observed during a natural measles virus infection. The influence of the measles virus phosphoprotein on nucleocapsid assembly has been studied using a vaccinia virus recombinant encoding both the nucleoprotein and the phosphoprotein. Infection of cells with the virus recombinant resulted in the formation of cytoplasmic inclusions in which the nucleoprotein and the phosphoprotein colocalized. Electron microscopic examination suggested that these inclusions contained characteristic nucleocapsid filaments. The buoyant density of nucleocapsids assembled in the presence of the phosphoprotein was found to be slightly higher than that of nucleocapsids assembled in its absence. Furthermore, the phosphoprotein partially inhibited the formation of nucleocapsids, a process which was extremely efficient when the nucleoprotein was expressed alone. Analysis of the nucleic acid content of nucleocapsids showed that they packaged heterologous RNA into a micrococcal nuclease-resistant form. These experiments demonstrate that the measles virus phosphoprotein regulates the efficiency with which the nucleoprotein assembles into nucleocapsids and the structural conformation they acquire.

Soluble CD16/Fc gamma RIII induces maturation of dendritic cells and production of several cytokines including IL-12.

Fc gamma RIII (CD16), a low affinity FcR which binds IgG-containing immune-complexes, exists under membrane-associated forms and under a soluble form (sFc gamma RIII). The latter, present in biological fluids (serum, saliva), is generated by proteolytic cleavage of the two membrane-associated Fc gamma RIII isoforms, Fc gamma RIII-A (expressed by macrophages and NK cells) and Fc gamma RIII-B (expressed exclusively by neutrophils). Herein we demonstrate that dendritic cells (DCs), generated by culturing monocytes with GM-CSF and IL-4, bind biotinylated recombinant sFc gamma RIII. This binding is specific and involves the complement receptor CR3 (CD11b/CD18) and CR4 (CD11c/CD18). Indeed, preincubation of DCs with anti-CD11b and anti-CD11c mAbs decreased by 52% and 62% respectively the binding with sFc gamma RIII. Moreover, electron microscopy showed that binding of gold-labeled sFc gamma RIII to DCs maintained at 4 degrees C occurred within clathrin-coated pits. Once internalized, at 37 degrees C, sFc gamma RIII entered the endocytic pathway and reached the MHC class II compartments. Furthermore, DCs incubated for 48 h with multivalent sFc gamma RIII expressed increased levels of CD40, CD80, CD86, CD54, CD58, HLA class I and class II molecules and decreased levels of CD23 and CD32. These effects result in an increased capacity of DCs to trigger proliferative responses by CD4+ CD45RA+ allogeneic T cells. RT-PCR amplification demonstrated that incubation of DCs for 20 h in the presence of multivalent sFc gamma RIII induced the appearance of GM-CSF and IL-12 p40 mRNA. Among the cytokines constitutively expressed, IL-1 beta and IL-8 were strongly up-regulated whereas IL-6 and IL-12 p35 mRNA were increased to a lesser extent and the expression of MIP-1 alpha mRNA remained constant. Finally, ELISA tests demonstrated that DCs incubated with multivalent sFc gamma RIII secreted the cytokines IL-1 beta, IL-6, IL-8, GM-CSF and IL-12 p75. Thus, while becoming internalized sFc gamma RIII could affect the capacity of DCs to present antigens and, via the induction of accessory molecules and the release of the IL-12 p75 protein, could initiate Th1 type immune response.

Examination of cutaneous macroglobulinosis by immunoelectron microscopy.

Cutaneous macroglobulinosis is a rare cutaneous manifestation of Waldenström's disease. Lesions are though to result from accumulation of macroglobulin in the dermis and are therefore called IgM storage papules. Ultrastructural findings in the previously reported cases were contradictory and the nature of the deposits was not established by electron microscopy. The purpose of this study was to analyse such deposits by the use of immunoelectron microscopy. A 60-year-old woman had multiple erythematous papules for 1 year. The histopathological changes consisted of plasmocytic infiltration of the dermis and eosinophilic deposits. The skin changes and other investigations led to a diagnosis of Waldenström's disease. Samples from normal and diseased skin were analysed by electron microscopy and by immunogold labelling with anti-IgM antibodies, after Lowicryl K4M embedding. An extracellular electron dense granular and filamentous material was observed in the mid- and upper dermis, between and within the collagen bundles. No periodicity was noted and no deposits were seen at the dermoepidermal junction. Immunoelectron microscopy showed a positive labelling located only on these deposits, in both normal-appearing skin and in lesions. In this patient, immunoelectron microscopy clearly demonstrated the presence of large amounts of IgM in the dermis, which were found in the lesions of cutaneous macroglobulinosis and in normal skin. These results suggest that the IgM storage papules result from a greater density of deposits rather than a site-specific accumulation.

A vaccinia virus transfer vector using a GUS reporter gene inserted into the I4L locus.

A vaccinia virus (VV) transfer vector is described which enables integration of heterologous sequences into the I4L locus (ribonucleotide reductase-encoding gene) through co-insertion of a GUS selection marker. I4L- VV recombinants formed blue plaques when an agarose overlay containing XGluc (5-bromo-4-chloro-3-indolyl-beta-glucuronide) was added to the infected cell monolayer. Viruses already containing a lacZ reporter gene were also suitable recipients for the selection procedure since infection with a VV lacZ recombinant did not produce any blue plaques with XGluc. The addition of a synthetic early promoter downstream from the GUS cassette initiated the predicted-size transcript during an infection. Insertion of genes with VV p7.5-promoters into the I4L, J2R and K1L loci of the same virus produced viable virus recombinants even though recombination between these loci could be demonstrated. These techniques should be valuable for the further development of VV as a polyvalent vector.

Role of B cell receptor Ig alpha and Ig beta subunits in MHC class II-restricted antigen presentation.

The ability of the B cell antigen receptors (BCRs) to enhance MHC class II-restricted antigen presentation was ascribed to mig-associated Ig alpha/Ig beta heterodimers. The relative role of Ig alpha and Ig beta subunits in antigen presentation was investigated by fusing their cytoplasmic tails to the extracellular and transmembrane domains of Fc receptors. Ig alpha and Ig beta chimera mediate antigen internalization and increase the efficiency of antigen presentation, but they drive antigens to different endosomal compartments. Furthermore, antigens internalized by either chimera are degraded and presented with different kinetics. The cytoplasmic tail of Ig alpha targets antigen towards a major population of newly synthesized MHC class II located in class II-rich compartments. In contrast, Ig beta targets antigen towards a minor population of recycling MHC class II molecules, located in transferrin receptor-containing endosomes. Altogether, our data indicate that the composition of BCR could be therefore an important way to modulate the immune response.