Targeting immune response induction with cochleate and liposome-based vaccines.

The immune response generated by infection with a pathogenic organism, or by vaccination with a live attenuated or whole killed pathogen, often does not stimulate optimal protection against that organism. Lipid matrix-based subunit vaccines can be used to produce custom-designed vaccines, that elicit desired immune responses targeted to specific parts of the pathogen that are relevant to protection. Harmful or competitive responses can be minimized or avoided. Earlier work with liposomes has allowed the development of a new class of subunit vaccines called cochleate delivery vehicles, whose structure and properties are very different from liposomes. Protein and DNA cochleates are highly effective vaccines when given via mucosal or parenteral routes, including oral, intranasal, intramuscular, or subcutaneous. Strong, long-lasting, mucosal and circulating, antibody and cell-mediated responses are generated. Protection from challenge with live viruses following oral or intramuscular administration has been achieved.

Aspects of cellular physiology that influence DNA-mediate gene transfer in NIH3T3 cells.

Cellular physiology has a significant influence on the efficiency of various gene transfer procedures, as shown by the fact that transfection efficiency varies dramatically among different cell lines. However, the aspects of cellular physiology which influence the transfection process remain substantially uncharacterized. In this study, NIH3T3 cells were treated with inhibitors of protein synthesis, DNA synthesis, and RNA synthesis to determine the importance of these processes in the calcium-phosphate transfection process. The results suggest that protein synthesis during the first 4 h after DNA addition enhances transfection. In contrast, inhibition of RNA synthesis has no effect on transfection during the first 24 h post-DNA addition. The DNA synthesis inhibitor results remain inconclusive due to a secondary inhibition of an unknown cellular factor. Secondly, agents that destabilize microtubules, microfilaments, and the golgi apparatus were used to determine whether these elements play a role in the transfection process. The results suggest that microtubules are not involved in the transfection process, microfilaments are important but not necessary for the transfection process, and a functional golgi apparatus is essential early in the transfection process. These studies provide a foundation from which further investigations into the cellular processes involved in the uptake and expression of exogenous DNA can proceed.

Lipid matrix-based vaccines for mucosal and systemic immunization.

For more than a decade our laboratories have been combining concepts in biochemistry, virology, and immunology in order to develop a conceptual basis for vaccine design. Our long-term goals have been to construct simple and well-defined immunogens that would stimulate specific immune responses in vivo. Using this approach, we hypothesized that it should be possible to define the structural and biochemical parameters of an immunogen that are necessary and sufficient to stimulate designated effector arms of the immune system. Through the use of covalently coupled peptide complexes, we have been able to define minimal requirements for the induction of humoral immune responses (Mannino et al., 1992). This represents a significant advance in eliciting an immune response to peptides, because it requires only peptides and phospholipids in the absence of additional adjuvants. It is different from the previous use of peptides and liposomes since here the peptides are covalently linked to a hydrophobic anchor and integrated into the phospholipid complex, rather than passively adsorbed or encapsulated. The presentation of peptide as part of a peptide-phospholipid complex (in contrast to encapsulation or nonspecific absorption) may be more similar to the natural presentation of an epitope in the context of an in vivo antigenic challenge. This technology also allows us to incorporate B and Th epitopes in a number of forms--as a single peptide, as two peptides in the same liposome, or as a peptide with viral glycoproteins in the same liposome. These data also demonstrate that Th epitopes do not have to be covalently linked to the B-cell epitope in order to provide help for that epitope. The implications of the data reported here are significant for both basic science and applied technologies. In basic science, the peptide-phospholipid complexes are potentially useful for analyzing the cooperative effects of B- and T-cell epitopes in the in vivo immune response. Since the peptide-phospholipid complexes are totally synthetic and highly immunogenic, they may be constructed in any formulation required to answer questions on the roles of B and T cells in promoting an immune response. Furthermore, since the number of antigenic sites is limited only by the number of peptides included in the peptide-phospholipid complexes, these constructs may be useful in producing antisera or monoclonal antibodies to weakly antigenic regions of a large protein, since the lack of antigenic competition should enhance the immunogenicity of these regions. Clinically, this technology will expand the potential for subunit vaccines.(ABSTRACT TRUNCATED AT 400 WORDS)

Viral induction of low frequency interferon-alpha producing cells.

The human peripheral blood mononuclear cells responsible for IFN-alpha production in response to viral stimuli have been most often described as either monocytes (as typified by the response to Sendai virus) or as a light density, HLA-DR+ population which is negative for most cell surface markers characteristic of mature T cells, B cells, monocytes, or natural killer cells (as typified by the response to Herpes simplex virus (HSV)). The frequency of IFN-alpha-producing cells (IPC) responding to Sendai virus is typically 10-fold or more higher than those responding to HSV. In the current study, we have used ELISpot assays to determine the frequency of IPC responding to DNA and RNA viruses including HSV, Sendai, vesicular stomatitis virus, cytomegalovirus, adenovirus, SV40, influenza, measles, mumps, Newcastle disease virus (NDV) and human immunodeficiency virus (HIV). The enveloped viruses but not the nonenveloped viruses (adenovirus and SV40) elicited an IFN-alpha response. The frequency of IPC for each of the other viruses was more similar to the low frequency HSV-responding population than to the higher frequency Sendai virus response. These included several viruses in the same family as Sendai virus, namely the paramyxo viruses measles, mumps, and NDV. IPC were also tested for sensitivity to the lysosomotropic drug chloroquine, which diminishes IFN-alpha produced in response to HSV but not Sendai virus. With the exception of Sendai virus, chloroquine treatment abrogated the majority of IFN-alpha produced and IPC against each of the viruses. We conclude that low frequency, nonmonocytic NIPC account for the majority of IFN-alpha production in response to different viruses.

Lipid matrix-based subunit vaccines: a structure-function approach to oral and parenteral immunization.

Immunization is today the most effective defense mechanism against microbial infections. Although highly effective vaccines are currently available for a number of infectious diseases, vaccine formulations can still be improved in a number of important areas. The ability to induce antigen-specific humoral and cell-mediated immunity is crucial to the development of effective prophylactic and therapeutic vaccines for HIV and other pathogens. The approach of our laboratory has been to design and test simple, highly defined antigen-lipid complexes that would stimulate antibody and cell-mediated immune responses in the absence of any nonspecific immunological activators such as Freund's adjuvant, lipopolysaccharide (LPS), or alum. These studies have provided insight into the relationships between the properties of an immunogen and the induction of the desired immune responses. We have previously utilized this approach to define the minimal structures required for the induction of antibody responses. Our more recent studies have focused on defining the parameters involved in the induction of cell-mediated and mucosal immune responses. Toward this end we have developed a new type of subunit vaccine that is effective when given orally or intramuscularly, and elucidated structure-function relationships in peptide vaccines that affect induction of CD8+ cell responses.

Differential effects of the phorbol ester TPA on DNA-mediated transfection in a variety of cell lines.

The efficiency of stable gene transfer and expression in NIH3T3 cells has been shown to be significantly enhanced by a brief treatment with the phorbol ester tetradecanoylphorbol 12,13-acetate (TPA) immediately following calcium-phosphate transfection. Several lines of evidence indicated that this effect was mediated through protein kinase C activation. These studies were expanded to determine whether this was a consistent and widespread phenomenon among other cell lines. The efficiency of transfection in two other established fibroblast lines, LMtk- and 2A3 3T3, was unaffected by TPA treatment, and primary human foreskin fibroblasts were similarly unaffected. Transfection was inhibited by TPA treatment in the transformed cell lines EJ and HeLa. Protein kinase C enzyme assays indicated that TPA causes a translocation of the enzyme from cytosol to membrane in both NIH3T3 and EJ cells, suggesting that the PKC translocation event does not account for the TPA effect on transfection. The TPA-mediated inhibition of transfection in EJ cells was not blocked by sphingosine, suggesting that this phenomenon is unrelated to PKC activation. The results suggest that TPA treatment may either enhance, inhibit, or have no effect on transfection, depending on the cell line.

Vaccination of rhesus monkeys with synthetic peptide in a fusogenic proteoliposome elicits simian immunodeficiency virus-specific CD8+ cytotoxic T lymphocytes.

An effective vaccine against the human immunodeficiency virus should be capable of eliciting both an antibody and a cytotoxic T lymphocyte (CTL) response. However, when viral proteins and peptides are formulated with traditional immunological adjuvants and inoculated via a route acceptable for use in humans, they have not been successful at eliciting virus-specific, major histocompatibility complex (MHC) class I-restricted CTL. We have designed a novel viral subunit vaccine by encapsulating a previously defined synthetic peptide CTL epitope of the simian immunodeficiency virus (SIV) gag protein within a proteoliposome capable of attaching to and fusing with plasma membranes. Upon fusing, the encapsulated contents of this proteoliposome can enter the MHC class I processing pathway through the cytoplasm. In this report, we show that after a single intramuscular vaccination, rhesus monkeys develop a CD8+ cell-mediated, MHC class I-restricted CTL response that recognizes the synthetic peptide immunogen. The induced CTL also demonstrate antiviral immunity by recognizing SIV gag protein endogenously processed by target cells infected with SIV/vaccinia recombinant virus. These results demonstrate that virus-specific, MHC class I-restricted, CD8+ CTL can be elicited by a safe, nonreplicating viral subunit vaccine in a primate model for acquired immune deficiency syndrome. Moreover, the proteoliposome vaccine formation described can include multiple synthetic peptide epitopes, and, thus, offers a simple means of generating antiviral cell-mediated immunity in a genetically heterogeneous population.

Potentiation of DNA mediated gene transfer in NIH3T3 cells by activators of protein kinase C.

The mechanisms involved in the translocation of exogenously added genetic information through the cellular cytoplasm and into the nucleus are essentially unknown. Several trans-cytoplasmic translocation systems operate within cells to transport information received by the plasma membrane into the nucleus. Protein kinase C may be functionally involved in many of these translocation mechanisms. In order to explore the involvement of protein kinase C activation in the cytoplasmic translocation of DNA, NIH3T3 fibroblasts were transfected using the calcium-phosphate co-precipitation method with a plasmid containing the lacZ gene and treated with tetradecanoylphorbol 12,13-acetate (TPA) or 1,2-dioctanoylglycerol (DiC8). Addition of TPA or DiC8 immediately after glycerol shock resulted in a 5-7-fold increase in the number of cells expressing beta-galactosidase as well as a concomitant increase in the total amount of beta-galactosidase activity in the population during periods of transient and stable expression. TPA added at later times resulted in lesser increases in the efficiency of transfection. In contrast, TPA added at the time of addition of the calcium-phosphate precipitate inhibited transfection. In support of a role for protein kinase C activation in enhancing DNA transfection, the TPA analog 4 alpha-phorbol 12,13-didecanoate, which does not activate protein kinase C, was ineffective at enhancing transfection. Furthermore, treatment of cells with the protein kinase C inhibitor sphingosine blocked the TPA-mediated increase in transient and stable expression. The results suggest that protein kinase C activation enhances transfection of exogenous DNA through an as yet unknown mechanism.

Chimerasome-mediated gene transfer in vitro and in vivo.

Proteoliposome delivery vesicles can be prepared by the protein-cochleate method [Gould-Fogerite and Mannino, Anal. Biochem. 148 (1985) 15-25; Mannino and Gould-Fogerite, Biotechniques 6 (1988) 682-690]. Proteins which mediate the entry of enveloped viruses into cells are integrated in the lipid bilayer, and materials are encapsulated at high efficiency within the aqueous interior of these vesicles. We describe proteoliposome-mediated delivery of proteins and drugs into entire populations of cells in culture. Material can be delivered gradually by Sendai-virus-glycoprotein-containing proteoliposomes. Alternatively, synchronous delivery to a population can be achieved by exposing cell-bound influenza glycoprotein vesicles briefly to low pH buffer. When DNA is encapsulated, chimeric proteoliposome gene-transfer vesicles (chimerasomes), which mediate high-efficiency gene transfer in vitro and in vivo, are produced. Stable expression of a bovine papilloma virus-based plasmid in tissue-cultured cells, at 100,000 times greater efficiency than Ca.phosphate precipitation of DNA, with respect to the quantity of DNA used, has been achieved. Stable gene transfer and expression in mice has been obtained by subcutaneous injection of chimerasomes containing a plasmid expressing the early region of polyoma virus. In one experimental group, 50% of the mice developed tumors which were shown to express polyoma virus early proteins and contain the transferred DNA. This is the first report of stable gene transfer in animals mediated by a liposome- or proteoliposome-based system.

Liposome mediated gene transfer.

Liposomes, artificial membrane vesicles, are being intensively studied for their usefulness as delivery vehicles in vitro and in vivo. Substantial progress has been made in the development of procedures for liposome preparation, targeting and delivery of contents. The broad flexibility now available in the design of the structure and composition of liposomes, coupled to recent reports of liposome mediated gene transfer in animals, suggest that liposome technology is now poised to be utilized in the creation of custom-designed cell-type-specific gene transfer vehicles.

Rotary dialysis: its application to the preparation of large liposomes and large proteoliposomes (protein-lipid vesicles) with high encapsulation efficiency and efficient reconstitution of membrane proteins.

An apparatus for rotary dialysis is introduced and described in detail. The component parts are inexpensive, widely available, and relatively easy to modify and assemble. The apparatus achieves increased mixing of the contents of dialysis bags by constant end-over-end rotation. This technique is particularly useful in systems where maximum contact is desired between substances which would tend to partition under standard dialysis conditions. We have applied rotary dialysis to two liposome production methods. These are (i) the calcium-EDTA-chelation method of Papahadjopoulos et al. (1), which produces large unilamellar liposomes from negatively charged phospholipids, and (ii) a procedure for the reconstitution of membrane proteins into liposomes with a large internal aqueous space, which we have developed using the calcium-EDTA-chelation technique as a point of departure. In both techniques, vesicle formation occurs when a calcium-phospholipid precipitate is dissolved by the addition of EDTA. Instead of adding a 150 mM EDTA solution directly, as described in the original method, we have used overnight rotary dialysis against buffer containing 10 mM EDTA at the vesicle formation stage. Materials are encapsulated within the aqueous interior of the vesicles at much higher efficiencies when rotary dialysis is used in either method, compared to efficiencies obtained with direct addition of EDTA (up to 37% of added material vs a maximum published efficiency of 10% for direct addition). Rotary dialysis also promotes the reconstitution of a higher proportion of the membrane proteins present in the dialysis mixture into the bilayer of large liposomes (79 vs 41.6%). It also affects the content of liposomes qualitatively, allowing better reconstitution of the Sendai virus F glycoprotein than does direct addition of EDTA. These effects may be due to the slow time course, the extensive mixing of components, and the low volume-to-phospholipid ratios maintained during vesicle formation.