Epidermal powder immunization with a recombinant HIV gp120 targets Langerhans cells and induces enhanced immune responses.

The recombinant envelope gp120 (rgp120) of human immunodeficiency virus (HIV) is a weak immunogen when administered by intramuscular (IM) injection. In the present study, we report that epidermal powder immunization (EPI) elicits robust antibody responses to the rgp120. EPI of mice with a dose 0.2-5 microg of rgp120 protein elicited geometric mean antibody titers that were 18- to 240-fold higher than that elicited by IM injection using a 5.0 microg dose. Targeting antigen to and mobilization of Langerhans cells (LCs) by EPI may explain the enhanced immunogenicity of the rgp120. EPI with rgp120 using sugar and gold particles as carrier resulted in differential antigen entry into the LCs and differential IgG subclass antibody and cellular immune responses. EPI may serve as a useful tool to evaluate vaccine potential of the rgp120 protein.

Epidermal powder immunization induces both cytotoxic T-lymphocyte and antibody responses to protein antigens of influenza and hepatitis B viruses.

Cytotoxic T lymphocytes (CTL) play a vital role in host defense against viral and intracellular bacterial infections. However, nonreplicating vaccines administered by intramuscular injection using a syringe and needle elicit predominantly humoral responses and not CTL responses. Here we report that epidermal powder immunization (EPI), a technology that delivers antigens on 1.5- to 2.5-microm gold particles to the epidermis using a needle-free powder delivery system, elicits CTL responses to nonreplicating antigens. Following EPI, a majority of the antigen-coated gold particles were found in the viable epidermis in the histological sections of the target skin. Further studies using transmission electron microscopy revealed the intracellular localization of the gold particles. Many Langerhans cells (LCs) at the vaccination site contained antigen-coated particles, as revealed by two-color immunofluorescence microscopy, and these cells were found in the draining lymph nodes 20 h later. Immune responses to several viral protein antigens after EPI were studied in mice. EPI with hepatitis B surface antigen (HBsAg) and a synthetic peptide of influenza virus nucleoprotein (NP peptide) elicited antigen-specific CTL responses as well as antibody responses. In an in vitro cell depletion experiment, we demonstrated that the CTL activity against HBsAg elicited by EPI was attributed to CD8(+), not CD4(+), T cells. As controls, needle injections of HBsAg or the NP peptide into deeper tissues elicited solely antibody, not CTL, responses. We further demonstrated that EPI with inactivated A/Aichi/68 (H3N2) or A/Sydney/97 (H3N2) influenza virus elicited complete protection against a mouse-adapted A/Aichi/68 virus. In summary, EPI directly delivers protein antigens to the cytosol of the LCs in the skin and elicits both cellular and antibody responses.

Serum and mucosal immune responses to an inactivated influenza virus vaccine induced by epidermal powder immunization.

Both circulating and mucosal antibodies are considered important for protection against infection by influenza virus in humans and animals. However, current inactivated vaccines administered by intramuscular injection using a syringe and needle elicit primarily circulating antibodies. In this study, we report that epidermal powder immunization (EPI) via a unique powder delivery system elicits both serum and mucosal antibodies to an inactivated influenza virus vaccine. Serum antibody responses to influenza vaccine following EPI were enhanced by codelivery of cholera toxin (CT), a synthetic oligodeoxynucleotide containing immunostimulatory CpG motifs (CpG DNA), or the combination of these two adjuvants. In addition, secretory immunoglobulin A (sIgA) antibodies were detected in the saliva and mucosal lavages of the small intestine, trachea, and vaginal tract, although the titers were much lower than the IgG titers. The local origin of the sIgA antibodies was further shown by measuring antibodies released from cultured tracheal and small intestinal fragments and by detecting antigen-specific IgA-secreting cells in the lamina propria using ELISPOT assays. EPI with a single dose of influenza vaccine containing CT or CT and CpG DNA conferred complete protection against lethal challenges with an influenza virus isolated 30 years ago, whereas a prime and boost immunizations were required for protection in the absence of an adjuvant. The ability to elicit augmented circulating antibody and mucosal antibody responses makes EPI a promising alternative to needle injection for administering vaccines against influenza and other diseases.

Adjuvantation of epidermal powder immunization.

The skin is an immunologically active site and an attractive vaccination route. All current vaccines, however, are administered either orally, intramuscularly, or subcutaneously. We previously reported that epidermal powder immunization (EPI) with an extremely small dose of powdered influenza vaccine induces protective immunity in mice. In this study, we report that commonly used adjuvants can be used in EPI to further enhance the immune responses to an antigen. The IgG antibody response to diphtheria toxoid (DT) following EPI was augmented by 25- and 250-fold, when 1 microg DT was co-delivered with aluminum phosphate (alum) and a synthetic oligonucleotide containing CpG DNA motifs (CpG DNA), respectively. These antibodies had toxin-neutralization activity and were long lasting. Furthermore, EPI using an adjuvant selectively activated different subsets of T helper cells and gave either a Th1 or a Th2 type of immune response. Similar to needle injection into deeper tissues, EPI with alum adsorbed DT promoted a predominantly IgG1 subclass antibody response and elevated level of IL-4 secreting cells. These are indicative of Th2-type immunity. In contrast, co-delivery of CpG DNA adjuvant via EPI led to Th-1 type of response as characterized by the increased production of IgG2a antibodies and IFN-gamma secreting cells. This study indicated that EPI using appropriate adjuvants can produce an augmented antibody response and desirable cellular immune responses. EPI is a promising immunization method that may be used to administer a broad range of vaccines including vaccines with adjuvants.

Preparation of hydrogel microspheres by coacervation of aqueous polyphosphazene solutions.

A new method of preparing ionically cross-linked polyphosphazene hydrogel microspheres which enables effective control over microsphere size distribution has been developed. The synthesized microspheres can be used in protein delivery and, especially, as vaccine delivery vehicles. A new technique utilizes the ability of aqueous solutions of poly[di(carboxylatophenoxy)phosphazene] (PCPP) to form coacervate microdroplets upon addition of sodium chloride. These microdroplets are then stabilized via polymer cross-linking with calcium ions. It was demonstrated that the method enables efficient microencapsulation of proteins. It was also shown that microsphere size can be controlled through the manipulation of microencapsulation conditions. The process is simple, highly reproducible and generates microspheres with a narrower microsphere size distribution, compared to the previous technologies.

Poly[di(carboxylatophenoxy)phosphazene] (PCPP) is a potent immunoadjuvant for an influenza vaccine.

The adjuvant activity of poly[di(carboxylatophenoxy)phosphazene] (PCPP) on the immunogenicity of formalin-inactivated influenza virions and commercial trivalent influenza vaccine was studied. Regardless of which antigen preparation is used, the addition of 100 micrograms PCPP enhances the HAI antibody response 10-fold over the levels elicited by the vaccine alone. Similarly, PCPP enhanced the IgM, IgG, and IgG1 ELISA antibody titers to influenza antigens at least 10-fold higher than the vaccine alone. In contrast, the IgG2a isotype titers were only enhanced about 2-fold. Immunization of aged mice (22 months old) with trivalent influenza vaccine alone did not sero-convert these mice as measured by HAI or ELISA whereas significant sero-conversion was achieved when mice were immunized with PCPP-formulated trivalent vaccine. The adjuvant activity of PCPP was shown to not be due to a site of injection depot effect. PCPP adjuvanticity was positively correlated to the molecular weight of the polymer.

PCPP as a parenteral adjuvant for diverse antigens.

The adjuvanticity of the phosphazene polymer, poly[di(carboxylatophenoxy) phosphazene] (PCPP) was examined with a diverse collection of immunogens. PCPP proved to be a potent adjuvant for trivalent influenza virus vaccine, tetanus toxoid, hepatitis B surface antigen, herpes simplex virus glycoprotein gD2 and the capsular polysaccharide, polyribosylribitolphosphate, from Haemophilus influenzae type b. Taken together these results clearly demonstrate the general utility of PCPP as an adjuvant. Furthermore, PCPP was a superior adjuvant at least with TT compared to similar negatively charged polyanions, polymethylacrylic acid and polyacrylic acid.

Utility of SHIV for testing HIV-1 vaccine candidates in macaques.

SUMMARY: Intravenous injection of SHIV (simian/human immunodeficiency virus, chimeric virus) into rhesus macaques resulted in a viremia in peripheral blood lymphocytes (PBL) and the generation of anti-HIV-1 (human immunodeficiency virus type 1) envelope immune responses. A challenge stock of a SHIV containing HIV-1 HXBc2 envelope glycoproteins was prepared from infected rhesus monkey peripheral blood mononuclear cells (PBMC). The minimum animal infectious dose of the SHIV stock was determined and used in a challenge experiment to test protection. The vaccination of two rhesus monkeys with whole inactivated HIV-1 plus polydicarboxylatophenoxy phosphazene (PCPP) as the adjuvant protected the animals from becoming infected by a SHIV challenge. This experiment demonstrated for the first time that monkeys immunized with HIV-1 antigens can be protected against an HIV-1 envelope-containing virus. As the challenge virus was prepared from monkey PBMC, human antigens were unlikely to be involved in the protection. Protection of rhesus monkeys from SHIV challenge may help,define protective immune responses stimulated by HIV-1 vaccine candidates.

Extracellular vaccinia virus envelope glycoprotein encoded by the A33R gene.

With the aid of three monoclonal antibodies (MAbs), a glycoprotein specifically localized to the outer envelope of vaccinia virus was shown to be encoded by the A33R gene. These MAbs reacted with a glycosylated protein that migrated as 23- to 28-kDa and 55-kDa species under reducing and nonreducing conditions, respectively. The protein recognized by the three MAbs was synthesized by all 11 orthopoxviruses tested: eight strains of vaccinia virus (including modified vaccinia virus Ankara) and one strain each of cowpox, rabbitpox, and ectromelia viruses. The observation that the protein synthesized by ectromelia virus-infected cells reacted with only one of the three MAbs provided a means of mapping the gene encoding the glycoprotein. By transfecting vaccinia virus DNA into cells infected with ectromelia virus and assaying for MAb reactivity, we mapped the glycoprotein to the A33R open reading frame. The amino acid sequence and hydrophilicity plot predicted that the A33R gene product is a type II membrane protein with two asparagine-linked glycosylation sites. Triton X-114 partitioning experiments indicated that the A33R gene product is an integral membrane protein. The ectromelia virus homolog of the vaccinia virus A33R gene was sequenced, revealing 90% predicted amino acid identity. The vaccinia and variola virus homolog sequences predict 94% identical amino acids, the latter having one fewer internal amino acid. Electron microscopy revealed that the A33R gene product is expressed on the surface of extracellular enveloped virions but not on the intracellular mature form of virus. The conservation of this protein and its specific incorporation into viral envelopes suggest that it is important for virus dissemination.

Water-soluble phosphazene polymers for parenteral and mucosal vaccine delivery.

PCPP can be used in two different ways to potentiate an immune response. The soluble form of the polymer has been found to have immunoadjuvant activity. A single subcutaneous injection of polymer/influenza dramatically increases the ELISA, neutralizing, and HI antibodies to influenza virus compared to CFA. The polymer has also succeeded in dramatically increasing the amount of ELISA antibodies to TT. The antibody response elicited was predominantly of the IgG1 isotype. PCPP has also been used to generate micron-sized hydrogel microspheres through a process of divalent ion cross-linking of the polymer strands. These microspheres can induce significantly higher anti-TT serum IgG titers after a single intranasal immunization than TT alone.

Recombinant-expressed virus-like particle pseudotypes as an approach to vaccine development.

Coinfection of a cell with two different types of enveloped virus can result in the generation of infectious virus particle pseudotypes having the internal proteins of one virus and the envelope proteins of the other virus. Vaccinia virus recombinants expressing either non-infectious virus-like particles of simian immunodeficiency virus (SIV) or the gD2 glycoprotein of herpes simplex virus were used to coinfect cells to determine if virus-like particle pseudotypes would be formed. Sucrose gradient sedimentation analysis and immunoprecipitation with a monoclonal antibody provided independent evidence of virus-like particle pseudotype formation. Preparations of such particles were immunogenic in mice. Recombinant-expressed virus-like particles thus represent a novel vaccine approach to presenting envelope glycoprotein antigens in a non-infectious state that mimics natural infection.

Host range selection of vaccinia recombinants containing insertions of foreign genes into non-coding sequences.

A simple yet powerful selection system was developed for the insertion of foreign genes in vaccinia virus. The selection system utilizes the vaccinia virus K1L (29K) host range gene which is located in HindIII M. This gene is necessary for growth in RK-13 cells but not in BSC40 or CV-1 cells. A vaccinia mutant (vAbT33) unable to grow on RK-13 cells was constructed having sequences at the 3' end of the K1L gene and the adjacent M2L gene deleted and replaced with the beta-galactosidase gene regulated by the BamHI F (F7L) promoter. A recombination plasmid containing the hepatitis B surface (HBs) antigen gene regulated by the M2L promoter and the complete sequence of the K1L gene was used to insert the HBs gene into vAbT33. The M2L negative K1L positive recombinant was easily isolated in two rounds of plaque purification by plating the virus on RK-13 cell monolayers. The K1L gene selection system allows the isolation of recombinants arising at frequencies as low as 1/100,000. It was noted that recombinants containing vaccinia sequence duplications (promoters) resulted in intragenomic recombinations that eliminated all sequences between the duplications. A second recombination plasmid was constructed that allowed insertion into the vaccinia genome without the loss of vaccinia coding sequences. This was achieved by insertion of the pseudorabies virus GIII gene regulated by the vaccinia H5R (40K) promoter between the translation and transcription stop signals at the 3' end of the K1L gene. The K1L gene transcription stop signal thus became the stop signal for the inserted GIII gene and an upstream transcription stop signal present in the H5R promoter fragment provided the stop signal for the K1L gene. This manipulation of the vaccinia genome had no effect on the accumulation or 5' end of the M2L gene transcripts. Although the insertion lengthened the 3' end and lowered the accumulation of K1L transcripts it altered neither the virulence nor the immunogenicity of the recombinant.

Characterization of a vaccinia virus-encoded 42-kilodalton class I membrane glycoprotein component of the extracellular virus envelope.

Using a reverse genetic approach, we have demonstrated that the product of the B5R open reading frame (ORF), which has homology with members of the family of complement control proteins, is a membrane glycoprotein present in the extracellular enveloped (EEV) form of vaccinia virus but absent from the intracellular naked (INV) form. An antibody (C'-B5R) raised to a 15-amino-acid peptide from the translated B5R ORF reacted with a 42-kDa protein (gp42) found in vaccinia virus-infected cells and cesium chloride-banded EEV but not INV. Under nonreducing conditions, an 85-kDa component, possibly representing a hetero- or homodimeric form of gp42, was detected by both immunoprecipitation and Western immunoblot analysis. Metabolic labeling with [3H]glucosamine and [3H]palmitate revealed that the B5R product is glycosylated and acylated. The C-terminal transmembrane domain of the protein was identified by constructing a recombinant vaccinia virus that overexpressed a truncated, secreted form of the B5R ORF product. By N-terminal sequence analysis of this secreted protein, the site of signal peptide cleavage of gp42 was determined. A previously described monoclonal antibody (MAb 20) raised to EEV, which immunoprecipitated a protein with biochemical characteristics similar to those of wild-type gp42, reacted with the recombinant, secreted product of the B5R ORF. Immunofluorescence of wild-type vaccinia virus-infected cells by using either MAb 20 or C'-B5R revealed that the protein is expressed on the cell surface and within the cytoplasm. Immunogold labeling of EEV and INV with MAb 20 demonstrated that the protein was found exclusively on the EEV membrane.

Molecular attenuation of vaccinia virus: mutant generation and animal characterization.

These studies demonstrated that the inbred BALB/c mouse strain can be optimized for the assessment of vaccinia virus virulence, growth, and spread from the site of inoculation and immune protection from a lethal vaccinia virus challenge. The studies established that manipulation of the vaccinia virus genome generated mutants exhibiting a wide range of attenuated phenotypes. The nine NYCBH vaccinia virus mutants had intracranial 50% lethal doses that ranged from 2 to greater than 7 log10 units. The decreased neurovirulence was due to decreased replication in brain tissue. Three mutants had a decreased ability to disseminate to the lungs, brains, livers, and spleens of mice after intranasal infection. One mutant had a decreased transmission from mice infected by tail scarification to naive cage mates. Although the mutants, with one exception, grew to wild-type titers in cell culture, they showed a growth potential on the scarified skin of mice that was dramatically different from that of the wild-type virus. Consequently, all of the mutants had significantly compromised immunogenicities at low virus immunization doses compared with that of the wild-type virus. Conversely, at high immunization doses most mutants could induce an immune response similar to that of the wild-type virus. Three Wyeth vaccine strain mutants were also studied. Whereas the thymidine kinase, ribonucleotide reductase, and hemagglutinin mutants had a reduced virulence (50% lethal dose), only the thymidine kinase mutant retained its immunogenicity.

Characterization of vaccinia virus glycoproteins by monoclonal antibody precipitation.

Monoclonal antibodies were used to characterize vaccinia virus glycoproteins known to be incorporated into the envelope of extracellular enveloped vaccinia (EEV) virus. The 89K hemagglutinin, 42K, and 23-28K glycoproteins were predominantly expressed as late vaccinia proteins. The 89K glycoprotein was sulfated and phosphorylated but not acylated. 89K precursor proteins of 32K, 41.5K, and 52K were detected. The former had a molecular weight expected from the deduced amino acid sequence of the hemagglutinin gene. A 76K glycoprotein that did not contain methionine and was not sulfated or phosphorylated was precipitated late in infection by the anti-hemagglutinin monoclonal antibody. The appearance of this protein was inhibited by rifampicin and it may thus result from 89K cleavage. A 220K complex contained some or all of the hemagglutinin gene products linked by disulfide bonds. The 42K glycoprotein was not sulfated or phosphorylated but was acylated. This glycoprotein was disulfide bonded with the EEV 37K nonglycosylated envelope protein. The 23-28K glycoprotein was not sulfated but was both phosphorylated and acylated. The 23-28K glycoprotein group of five proteins had a common protein backbone that was differentially glycosylated. Pulse-chase, glycosylation inhibition with tunicamycin, and glycosidase experiments established that the precursor to the 23-28K glycoproteins was a 21K protein. Members of this protein family formed dimers of approximately 55K through disulfide bonds.

A mutation in the gene encoding the vaccinia virus 37,000-M(r) protein confers resistance to an inhibitor of virus envelopment and release.

Plaque formation in vaccinia virus is inhibited by the compound N1-isonicotinoyl-N2-3-methyl-4-chlorobenzoylhydrazine (IMCBH). We have isolated a mutant virus that forms wild-type plaques in the presence of the drug. Comparison of wild-type and mutant virus showed that both viruses produced similar amounts of infectious intracellular naked virus in the presence of the drug. In contrast to the mutant, no extracellular enveloped virus was obtained from IMCBH-treated cells infected with wild-type virus. Marker rescue experiments were used to map the mutation conferring IMCBH resistance to the mutant virus. The map position coincided with that of the gene encoding the viral envelope antigen of M(r) 37,000. Sequence analysis of both wild-type and mutant genes showed a single nucleotide change (G to T) in the mutant gene. In the deduced amino acid sequence, the mutation changes the codon for an acidic Asp residue in the wild-type gene to one for a polar noncharged Tyr residue in the mutant.

The polypeptide composition of vaccinia-infected cell membranes and rifampicin bodies.

The protein and glycoprotein composition of a sucrose gradient fraction from vaccinia infected cells treated with rifampicin was studied. This particulate fraction contained cytoplasmic membranes and pleomorphic membranous structures. The glycoproteins (89, 42 and 20-23 kDa, respectively) were identified as the same glycoproteins that are found in plasma membranes of infected cells and the envelope of extracellular enveloped vaccinia (EEV). These glycoproteins could be solubilized by 0.1% NP-40. The Golgi membrane associated 41K acylated vaccinia protein was also NP-40 soluble. In contrast, most particulate fraction proteins (125, 100, 86, 65, 41, 39, 31, 27, 25, 14 and 12.5 kDa) with the exception of the 33 and 29 kDa proteins remained essentially insoluble after NP-40 treatment. The 86 and 65 kDa proteins are the rifampicin inhibited precursors to INV core proteins while the 33 and 29 kDa proteins are INV surface proteins. Twelve proteins behaved like their respective comigrating INV proteins when extracted with NP-40 and 2ME. Electron microscopy showed that a centrifuged sediment from NP-40 treated cells contained pleomorphic protein containing membranous structures that we have called rifampicin bodies. We conclude that (1) the major glycoproteins found in the particulate fraction from sucrose gradients are vaccinia glycoproteins residing in cytoplasmic membranes while (2) the major non-glycosylated proteins are components of the rifampicin bodies and that (3) the rifampicin bodies represent an intermediate in the morphogenetic process leading to mature INV.