Alpha IIb beta 3 integrin dissociation induced by EDTA results in morphological changes of the platelet surface-connected canalicular system with differential location of the two separate subunits.

Treatment of human platelets by EDTA (5 mM at 37 degrees C and pH 7.4 for 30 min) induces ultrastructural morphological changes of the surface-connected canalicular system (SCCS). The first consists in dilations of some portions of the channels, whereas the second is represented by collapse of parts of the canaliculi. The collapsed elements of the EDTA treated SCCS are made up of two parallel limiting membranes and a central striated zone. Some of the EDTA treated platelets form microaggregates, the cohesion of which is apparently due to the appearance of pentalaminar interplatelet structures. EDTA treatment is known to induce an irreversible loss of platelet aggregability which is due to irreversible dissociation of the membrane GPIIb-IIIa complexes. In the present study, we looked for involvement of GPIIb-IIIa in the formation of these pentalaminar structures, and were able to demonstrate that the morphological changes described are in fact directly dependent on the EDTA induced dissociation of GPIIb-IIIa complexes. Indeed, we observed that these changes (a) cannot be induced in type I Glanzmann's thrombasthenia, where GPIIb-IIIa complexes are absent, (b) do not appear when human platelets are preincubated with monoclonal anti-GPIIb-IIIa complex-dependent (CD41a) antibodies, which protect the complex from EDTA induced dissociation, (c) appear only at alkaline pH and at 37 degrees C, which corresponds to the range of pH and temperature where EDTA can dissociate GPIIb-IIIa complexes, (d) are accompanied by the disappearance in fluorescence flow cytometry of the heterodimer complex-dependent epitopes, when using anti-CD41a antibodies and (e) do not appear in rat platelets, where GPIIb-IIIa does not dissociate after EDTA treatment. Furthermore, using gold-labeled mAbs concomitantly with the addition of EDTA, we observed that almost only GPIIb was present in the collapsed regions of the canaliculi. Using double labeling studies with polyclonal anti-GPIIb antibodies coupled to 10 nm gold particles and polyclonal anti-GPIIIa antibodies coupled to 20 nm gold particles, we observed that while both 10 and 20 nm particles were present in the dilated portions of the canaliculi almost only the small particles, coupled to the anti-GPIIb antibodies, labeled the collapsed portions of the SCCS. On Lowicryl thin sections, polyclonal antibodies against GPIIb labeled the central striated zone while both GPIIb and GPIIIa were found in the dilated portions of the SCCS. All these observations lead us to suggest that homopolymers of GPIIb could be responsible for "zipping" of the SCCS.

Alpha IIB beta 3 integrin dissociation induced by EDTA results in formation of Birbeck granule-like structures in human blood platelets.

EDTA (5 mM at 37 degrees C and pH 7.4 for 30 min) induces morphologic changes in the platelet surface-connected canalicular system (SCCS), in particular the collapse of some portions of the canaliculi. These collapsed elements are made up of two parallel limiting membranes and a central irregular striated zone, a pentalaminar organization that clearly resembles that of Langerhans cell Birbeck granules (BG). Such BG-like structures are also seen between adjacent platelets in EDTA-treated platelet microaggregates. EDTA is known to induce an irreversible dissociation of the platelet membrane glycoprotein(GP)IIb-IIIa, the alpha IIb beta 3 platelet-specific intergrin, a calcium-dependent heterodimer that serves as an inducible receptor for fibrinogen and is essential for platelet aggregation. Hence, we looked for involvement of the GPIIb-IIIa in the formation of these BG-like modifications. We observed that these changes i) cannot be induced in type I Glanzmann's thrombasthenia, where the GPIIb-IIIa complexes are absent; ii) did not appear when human platelets were pre-incubated with MoAb anti-GPIIb-IIIa complex, which protected GPIIb-IIIa from EDTA-induced dissociation; iii) appeared only at alkaline pH and 37 degrees C, which corresponds to the range of pH and temperature where EDTA can dissociate the GPIIb-IIIa complexes; iv) are accompanied by the dissappearance on fluorescence flow cytometry analysis of the heterodimer specific epitopes; and v) do not appear in rat platelets at pH 7.4 where GPIIb-IIIa does not dissociate after EDTA treatment. Thus, the appearance of BG-like structures in the platelet SCCS is directly dependent on the EDTA-induced dissociation of the GPIIb-IIIa complexes. Furthermore, using gold-labeled MoAb concomitantly with the addition of EDTA, we observed that only GPIIb is present in the collapsed portions of the canaliculi. On Lowicryl thin sections essentially polyclonal antibodies to GPIIb labeled the central striated zone. All these observations lead us to suggest that homopolymers of GPIIb could be responsible for "zipping" of the SCCS and raise the question of the participation of a Langerhans cell integrin in the formation of Langerhans cell BG.

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.

The vaccinia virus J5L open reading frame encodes a polypeptide expressed late during infection and required for viral multiplication.

A number of open reading frames (ORFs) are found in the vaccinia virus (VV) genome whose activities in the viral life cycle have not yet been determined. This report examines one such ORF, designated J5L, which was demonstrated to be essential for viral multiplication. Stable inactivation of the J5L ORF by insertion of a lacZ ORF was impossible unless another copy of the J5L ORF was present in the VV genome. Fusion genes between the J5L ORF and either the lacZ gene or the VV K1L gene were employed to study its temporal expression as well as its protein product. These experiments showed that J5L is transcribed late in infection and gives rise to a protein product which migrates by SDS-PAGE with the expected molecular weight (16 kDa). Numerous unsuccessful attempts to establish a stable cell line expressing J5L suggest that the J5L gene product could be cytotoxic.

Respiratory syncytial virus nucleocapsid protein (N) expressed in insect cells forms nucleocapsid-like structures.

The gene coding for the N protein of RSV strain Long has been cloned and sequenced. It was introduced behind the polyhedrin promoter of the shuttle vector pVL941 and baculoviruses containing the N gene were constructed by homologous recombination. Infection of Spodoptera frugiperda 9 cells resulted in the production of large amounts of a protein similar in size and antigenicity to the authentic N protein. The baculovirus expressed N protein was concentrated in the cytoplasm of the insect cells and could be extracted at low salt concentration. Nucleocapsid structures similar to those purified from RSV-infected cells could be observed by electron microscopy after negative staining of cellular extracts.

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.

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.

Physical mapping of vaccinia virus temperature-sensitive mutations.

DNA restriction fragments from the Copenhagen strain of vaccinia virus have been molecularly cloned into the plasmid pAT 153. Eleven fragments obtained with SalI and nine fragments with HindIII together overlap about 90% of the 190 kb genome. The positioning of SalI and XhoI restriction sites demonstrated that vaccinia Copenhagen DNA differs in a number of sites from other vaccinia strains. Vaccinia temperature-sensitive mutants in 17 different complementation groups have been mapped to specific regions on the viral genome by marker rescue with cloned restriction fragments of the wild type strain. As a rule, the physical order of the mutations corresponded to the genetic order previously established from recombination data. The results have thus enabled the proper alignment of the genetic and physical maps and provided a means of comparing intervals expressed on these two scales. All ts mutations that have been mapped so far lie within a central region that spans approximately 60% of the genome. This clustering of mutations confirms and extends previous observations suggesting that the majority of the genes required for viral multiplication under in vitro conditions are located in the highly conserved central region of the orthopoxvirus genome.

Detection of a protein encoded by the vaccinia virus C7L open reading frame and study of its effect on virus multiplication in different cell lines.

Vaccinia virus encodes several proteins, the activity of which is essential for multiplication in different cell types. Both the C7L and K1L open reading frames (ORFs) have been characterized as viral determinants for multiplication in human cells. To confirm and extend these findings we inserted the C7L ORF into the genome of a mutant virus unable to multiply in human cells and showed that this virus recovered its ability to replicate. Deletion of C7L from a wild-type viral genome did not adversely affect virus multiplication in human cells but it did reduce replication in hamster Dede cells. When both C7L and K1L were deleted from the vaccinia virus genome only poor or no viral yields were obtained from various human cell lines. Recombinant viruses were also constructed to facilitate the study of C7L protein synthesis during infection. One virus in which the lacZ ORF was fused downstream and in-frame with the C7L ORF enabled us to characterize the C7L protein as an early gene product. Another recombinant virus was constructed so that the carboxy terminus of the C7L ORF product contained an additional 28 amino acids from the carboxy terminus of K1L. Tagging of C7L in this way allowed us to detect the fusion protein by immunoprecipitation with antibodies against the K1L protein. Furthermore, the hybrid protein retained its biological properties. The recombinant viruses constructed in this work should be useful for studies of the molecular basis of the activity of viral host range proteins.

Assembly of nucleocapsidlike structures in animal cells infected with a vaccinia virus recombinant encoding the measles virus nucleoprotein.

A vaccinia virus recombinant containing the measles virus nucleoprotein gene was shown to induce the synthesis of a 60 kDa phosphorylated nucleoprotein similar to authentic measles virus nucleoprotein. Mammalian or avian cells infected with the recombinant virus displayed tubular structures reminiscent of viral nucleocapsids both in the cytoplasm and in the nucleus. Such structures could be labelled in situ by using an immunogold detection method specific for measles virus proteins. Electron microscopic examination of tubular structures purified from cells infected with the vaccinia virus recombinant indicated that they displayed most of the features of measles virus nucleocapsids, although their length was on the average shorter. These results demonstrate the spontaneous assembly of measles virus nucleocapsids in the absence of viral leader RNA and provide a means for a detailed molecular analysis of the requirements for nucleocapsid assembly. Furthermore, these findings raise the possibility of achieving complete assembly of measles virus particles, devoid of infectious RNA, by using a vaccinia virus vector.

Host range restriction of vaccinia virus in Chinese hamster ovary cells: relationship to shutoff of protein synthesis.

Chinese hamster ovary cells were found to be nonpermissive for vaccinia virus. Although early virus-induced events occurred in these cells (RNA and polypeptide synthesis), subsequent events appeared to be prevented by a very rapid and nonselective shutoff of protein synthesis. Within less than 2 h after infection, both host and viral protein syntheses were arrested. At low multiplicities of infection, inhibition of RNA synthesis with cordycepin resulted in failure of the virus to block protein synthesis. Moreover, infection of the cells in the presence of cycloheximide prevented the immediate onset of shutoff after reversal of cycloheximide. Inactivation of virus particles by UV irradiation also impaired the capacity of the virus to inhibit protein synthesis. These results suggested that an early vaccinia virus-coded product was implicated in the shutoff of protein synthesis. Either the nonpermissive Chinese hamster ovary cells were more sensitive to this inhibition than permissive cells, or a regulatory control of the vaccinia shutoff function was defective.

Mapping of a vaccinia host range sequence by insertion into the viral thymidine kinase gene.

A vaccinia virus mutant deleted of ca. 18 kilobase pairs at the left-hand end of the genome is unable to multiply on many human cell lines. To determine whether all or some of the deleted sequences were responsible for the host range property, the corresponding region from wild-type DNA was cloned in three pieces into a vaccinia transplacement vector containing the thymidine kinase gene on the HindIII J fragment. The next step was to transfer these pieces to the genome of the host range deletion mutant by in vivo homologous recombination around the thymidine kinase locus. Transfer of one 5.2-kilobase-pair EcoRI fragment was found to restore a wild-type phenotype on the host range mutant, thus demonstrating that only a small portion of the 18-kilobase-pair deletion contains the host range function(s). This result also illustrates that the method initially devised for inserting foreign genes into vaccinia virus DNA is useful for studies of the vaccinia genome.

Construction of fowlpox virus vectors with intergenic insertions: expression of the beta-galactosidase gene and the measles virus fusion gene.

A DNA fragment from fowlpox virus cloned on a plasmid vector was modified to contain foreign DNA inserts within an intergenic region. In a first step, a 32-base-pair intergenic region from the fowlpox virus genome corresponding to the position of the thymidine kinase locus in the vaccinia virus genome was enlarged to 55 base pairs by site-directed mutagenesis. A unique restriction endonuclease site introduced upstream of the intergenic region was then used to insert various foreign DNA fragments. The lacZ gene encoding beta-galactosidase and the measles virus gene encoding the fusion protein were positioned downstream of two vaccinia virus p7.5 promoter elements in either a direct repeat or inverted repeat orientation. Foreign DNA inserts contained within the fowlpox virus sequence were transferred to the viral genome by homologous recombination occurring in cells infected with a fowlpox virus temperature-sensitive mutant and transfected with both wild-type viral DNA and plasmid DNA. Recombinant viruses were selected for the expression of beta-galactosidase activity by screening for blue plaques in the presence of a chromogenic substrate. Stable recombinants expressing both the lacZ gene and the unselected measles gene were obtained when the p7.5 promoter was present as an inverted repeat. However, when the p7.5 promoter was in the direct repeat orientation, viral recombinants which initially expressed both gene inserts readily deleted the lacZ gene flanked by the promoter repeat. The methods described enable precise insertion and deletion of foreign genes in the fowlpox virus genome and could be applied to other intergenic regions of the same virus as well as other poxviruses.

A cowpox virus gene required for multiplication in Chinese hamster ovary cells.

Cowpox virus, in contrast to vaccinia virus, can multiply in Chinese hamster ovary cells. To study the genetic basis for this difference in host range, recombinants between vaccinia and cowpox viruses were isolated and their DNA restriction patterns were examined. The ability to multiply in Chinese hamster ovary cells could be correlated with the conservation of cowpox virus sequences mapping at the left end of the genome. This was further demonstrated by marker rescue of the host range phenotype with restricted cowpox virus DNA. Marker rescue with cloned restriction fragments of decreasing size enabled the fine localization of the host range function to a 2.3-kilobase-pair fragment. Nucleotide sequencing revealed that the fragment encoded a single major polypeptide of approximately 77,000 daltons. It is suggested that the role of the host range gene from cowpox virus is to prevent the early and extensive shutoff of protein synthesis that normally occurs in Chinese hamster ovary cells infected by vaccinia virus.

In vitro and in vivo study of the ectromelia virus homolog of the vaccinia virus K1L host range gene.

Ectromelia virus encodes a protein which is homologous to the product of the vaccinia virus host range gene, K1L, except for eight conservative and two non-conservative substitutions and an additional threonine residue at the carboxyl terminus. Unlike the vaccinia virus gene, the ectromelia virus homolog failed to support optimal virus replication in RK-13 cells and appeared to be expressed 20-fold less efficiently. This lower level of expression was not due to the genetic background of the virus, K1L RNA transcription, sequence of the K1L RNA leader, or stability of K1L RNA or protein. Infections of RK-13 cells with ectromelia or vaccinia virus mutants lacking an intact K1L gene resulted in transient expression of early genes followed by a rapid and irreversible cessation of both virus and host protein synthesis. Infections of the disease-susceptible ANCR or -resistant C57BL/6 mice with the K1L-lacking ectromelia virus yielded a pathogenesis pattern indistinguishable from wild-type, suggesting that the ectromelia virus homolog of vaccinia virus K1L is not important for ectromelia virus in vivo replication and spread.

Antibodies directed against a synthetic peptide enable detection of a protein encoded by a vaccinia virus host range gene that is conserved within the Orthopoxvirus genus.

A vaccinia virus gene required for multiplication in some cell lines but not in others has been previously isolated and sequenced. A synthetic peptide predicted from the nucleotide sequence and corresponding to the carboxy-terminal 18 amino acids was used to raise antibodies in rabbits. The immune serum enabled detection of a 29-kilodalton (kDa) polypeptide by either immunoprecipitation or Western immunoblot assays. Synthesis of the 29-kDa polypeptide occurred immediately after infection and lasted for about 3 h. Shutoff of its synthesis was concomitant with the appearance of a delayed early polypeptide that may be antigenically related to the 29-kDa polypeptide. Analysis of cloned segments of the genomes of other orthopoxviruses by hybridization with the vaccinia virus host range gene demonstrates that it is well conserved within this genus.

Localization and sequence of a vaccinia virus gene required for multiplication in human cells.

A vaccinia virus host range mutant (hr mutant) deleted of 18 kilobase pairs at the left end of the genome has been employed to precisely map a viral gene required for multiplication in human cells. DNA fragments from the wild-type virus were inserted into the thymidine kinase gene of mutant virus by means of in vivo homologous recombination, and the recombinants obtained were screened for their ability to multiply in human cells. A short sequence, 855 base pairs long, overlapping the HindIII M and K fragments was able to restore a normal host range on the mutant virus. A single long open reading frame that could encode a polypeptide of 32.5 kDa was found in the nucleotide sequence of the host range gene. The direction of transcription and the length of the open reading frame are in excellent agreement with previous mapping of mRNAs within this region of the genome. In vitro translation of infected cell early mRNA, selected by hybridization to the host range gene, yielded a prominent polypeptide product whose size (29 kDa) was close to that expected from the predicted amino acid sequence. The phenotype of the hr mutant suggests that the host range gene plays a role in maintaining a high level of protein synthesis in human cells. It may behave positively by complementing the lack of an analogous cellular activity or negatively by antagonizing a cell function that inhibits viral multiplication.

Restricted replication of ectromelia virus in cell culture correlates with mutations in virus-encoded host range gene.

Ectromelia virus (strain Moscow) was shown to replicate poorly or not at all in cell lines derived from the rabbit or hamster. The failure of ectromelia virus to replicate in cell lines derived from the hamster suggested that the virus lacked a functional CHO host range (hr) gene required for multiplication in these cells. A DNA fragment which hybridized to the CHO hr gene was cloned from the ectromelia virus genome and shown by sequence analysis to be deleted of 506 bp within the ectromelia virus CHO hr homologue. Two additional ectromelia viruses (Hampstead and Mill Hill strains) were also shown to lack an intact CHO hr gene. Insertion of the CHO gene from cowpox virus into the ectromelia virus genome extended the host range of ectromelia virus in tissue culture. These results demonstrate that an intact CHO hr gene is not required for maintenance of ectromelia virus in nature and provide a partial explanation for ectromelia virus' narrow host range, as opposed to the broad host range of cowpox virus, which has a functional CHO hr gene.

Construction of vaccinia virus recombinants expressing several measles virus proteins and analysis of their efficacy in vaccination of mice.

Measles virus genes encoding the haemagglutinin (HA), fusion protein (F) or nucleoprotein (NP) have been inserted into the vaccinia virus genome either alone or in various combinations. In each case the measles virus genes were expressed from the 7.5K promoter and were incorporated into the thymidine kinase (tk) or K1L loci of the Copenhagen strain of vaccinia virus. Cells infected by the recombinants synthesized measles virus proteins indistinguishable from those induced in measles virus-infected cells. However, in some instances the level of expression in cells infected by recombinants expressing more than one measles virus gene was reduced when compared to those encoding a single gene. The sera from mice immunized with recombinants containing either HA, HA.F, HA.NP or HA.F.NP had similar levels of measles virus neutralizing antibodies which remained constant throughout a 7 month period. Analysis of these sera by immunoprecipitation of radiolabelled measles virus confirmed the presence of specific antibody to each of the antigens where appropriate. The introduction of the measles virus genes into the K1L and the tk sites despite attenuating the virus for mice by 10-fold and 1000-fold respectively did not affect the vaccination efficiency, i.e. ability to induce measles virus antibody and protect mice. Vaccination of BALB/c (H2d) mice with HA and F, but not NP, recombinants completely protected the animals against a lethal measles virus challenge. In contrast, although the HA recombinant protected CBA (H2k) mice, the F recombinant did so poorly. However, by immunizing CBA mice with a recombinant expressing both F and NP, protection was increased to more than 75%. Our findings demonstrate the ability of three measles virus antigens expressed from the vaccinia virus genome alone or in combination to contribute to protective immunity against measles virus infection of mice. They also suggest that the association of measles virus antigens in a single recombinant DNA vaccine could be beneficial to overcome host-related restriction of the immune response to particular antigens.