Eli Kedar

Liposomal immunostimulatory DNA sequence (ISS-ODN): an efficient parenteral and mucosal adjuvant for influenza and hepatitis B vaccines.

Synthetic oligodeoxynucleotides (ODNs) containing immunostimulatory sequences (ISS-ODN, also known as CpG-ODNs) have been shown to display in experimental models potent Th1-biassed immunoadjuvant activity upon parenteral or mucosal co-administration with a variety of antigens. In an attempt to potentiate adjuvant activity, and to reduce dose and number of administrations, ISS-ODN was entrapped (up to 90% efficiency) in large (1.5 microm) multilamellar liposomes using a simple and fast (5 min) procedure. Mice were vaccinated once or twice intramuscularly (i.m.) or intranasally (i.n.) with subunit influenza vaccines (consisting of the viral hemagglutinin and neuraminidase, HN) or with hepatitis B surface antigen particles (HBsAg), either non-encapsulated or liposome-encapsulated, together with free or liposomal ISS-ODN (5-25 microg per dose). At 3-12 weeks post-vaccination, the humoral (systemic, mucosal) and cellular responses and protective immunity were assessed. Vaccine formulations containing liposomal ISS-ODN co-administered with either soluble antigen or liposomal antigen (in the same vesicles or in separate vesicles) were up to 30 times more effective than formulations containing un-encapsulated ISS-ODN in inducing: (a) antigen-specific serum and mucosal IgG2a and IgA antibodies; (b) splenocyte proliferative response, cytotoxic activity and IFNgamma production; (c) a DTH response; and (d) protection against virus challenge. The response was Th1-dominant in the influenza model and a mixed Th1+Th2 response in the hepatitis B model. No adverse reactions were noted. Thus, liposomal encapsulation of ISS-ODN further enhances its inherent adjuvant activity.

Cancer immunotherapy: are the results discouraging? Can they be improved?

Publisher Summary Immunization with tumor cells or tumor extracts preventing the growth of subsequently grafted cells provided the proof for immunogenicity of some animal tumors. The demonstration of antigenicity of experimental tumors and the beneficial effects of immunotherapy in animal models generated great expectations for cancer treatment. Active specific immunotherapy in patients was attempted by several investigators using various vaccines such as irradiated autologous tumor cells allogeneic or extracts of the corresponding histologic type. This chapter discussesthe potential of the combined treatment modalities including tumor debulking, followed by active immunization with tumor material, and by administration of cytokines, other biological response modifiers (BRMs), and antitumor antibodies in various combinations. The new ideas for immunotherapy propose readministration of autologous tumor–reactive T cells transfected with cytokine–encoding genes, and the use of encapsulated cytokines directed by antibodies to the tumor cells. These may home in on the tumor tissue and deliver large quantities of cytokines. The therapeutic efficacy of these two modalities is not yet known.

Delivery of cytokines by liposomes. III. Liposome-encapsulated GM-CSF and TNF-alpha show improved pharmacokinetics and biological activity and reduced toxicity in mice.

In an attempt to potentiate the therapeutic index of cytokines, recombinant mouse granulocyte/macrophage colony-stimulating factor (GM-CSF) and recombinant human tumor necrosis factor alpha (TNF-alpha) were encapsulated in large (0.3-2.2 microns) multilamellar vesicles composed of various lipids, using several encapsulation methods. Liposomal cytokine activity was tested in vitro and in vivo and was compared with that of the soluble cytokines. The main observations were as follows: (a) The mean encapsulation efficiency, as determined by bioassays, was 49-79%, depending on the formulation, for GM-CSF, and 48% for TNF-alpha; (b) some of the entrapped cytokine preparations displayed high stability at 4 degrees C, with < 30% loss of biologic activity during a 4-month period; (c) release of TNF-alpha, but not of GM-CSF, from the liposomes was required for their biological activity in vitro; (d) plasma half-lives (t1/2 alpha, t1/2 beta) and the area under the curve (AUC) of the entrapped cytokines were 10-20 times greater than those of the soluble cytokines; (e) the toxicity of liposomal TNF-alpha was one-third and one-seventh that of soluble TNF-alpha in normal and tumor-bearing mice, respectively; (f) administration of liposomal GM-CSF (5 x 10(4)-2 x 10(5) U, one to five times) to normal and 5-fluorouracil-treated mice led to a two- to fourfold increase in the absolute number of peritoneal and spleen leukocytes and of GM colony-forming cells in the spleen, as compared with the levels obtained using soluble GM-CSF; and (g) under the experimental conditions used, neither free nor liposomal GM-CSF significantly increased the absolute number of blood leukocytes, although liposomal GM-CSF markedly (threefold) enhanced the level of blood granulocytes. Collectively, these findings suggest that liposome-entrapped GM-CSF and TNF-alpha may be more efficacious immunomodulators than the soluble cytokines.

Enhanced Recognition of Human NK Receptors After Influenza Virus Infection

The NK cell cytotoxic activity is regulated by both inhibitory and activating NK receptors. Thus, changes in the expression levels and in the affinity or avidity of those receptors will have a major effect on the killing of target cells. In this study, we demonstrate that the binding of NK-inhibitory receptors is enhanced after influenza virus infection. Surprisingly, however, no change in the level of class I MHC protein expression was observed on the surface of the infected cells. The increased binding was general, because it was observed in both the killer cell Ig-like receptor 2 domain long tail 1 and leukocyte Ig-like receptor-1. The increased binding was functional, was not dependent on the interaction with viral hemagglutinin-neuraminidase, was not dependent on the glycosylation site, and was not abolished after mutating the transmembrane or cytosolic portions of the class I MHC proteins. Confocal microscopy experiments showed increased binding of NK receptor-coated beads to infected cells expressing the appropriate class I MHC proteins. In addition, specific cell-free bead aggregates covered with class I MHC proteins were observed only in infected cells. We therefore suggest that the influenza virus use a novel mechanism for the inhibition of NK cell activity. This mechanism probably involves the generation of class I MHC complexes in infected cells that cause increased recognition of NK receptors.

A novel liposomal influenza vaccine (INFLUSOME-VAC) containing hemagglutinin–neuraminidase and IL-2 or GM-CSF induces protective anti-neuraminidase antibodies cross-reacting with a wide spectrum of influenza A viral strains

A liposomal influenza vaccine (INFLUSOME-VAC) was developed with the objective of overcoming the major drawbacks of the currently used influenza vaccines: their relatively low efficacy in certain high-risk groups (the elderly, infants, the immunosuppressed) and the need for annual immunization. INFLUSOME-VAC consists of liposomes containing the viral surface proteins hemagglutinin (HA) and neuraminidase (NA) derived from various influenza strains and IL-2 or GM-CSF, as an adjuvant. Vaccination of mice showed that, whereas conventional vaccines induced a low- and short-term response against HA and very low or no anti-NA response, INFLUSOME-VAC produced high titers of both anti-HA and anti-NA antibodies (Abs) in young and old mice that persisted for at least 6 months. Moreover, the anti-NA Abs efficiently cross-reacted with several N2 viral subtypes spanning 20 years, and such vaccines afforded partial protection against heterosubtypic viral infection.

Targeted delivery of doxorubicin via sterically stabilized immunoliposomes : Pharmacokinetics and biodistribution in tumor-bearing mice

AbstractPurpose. To evaluate benefits in tumor localization, availability, and noncancerous organ distribution of doxorubicin (DOX) delivered via small (≤120 nm) sterically stabilized immunoliposomes targeted against a tumor-associated antigen in fibrosarcoma-bearing mice. Methods. DOX-loaded liposomes were prepared with (i) specific monoclonal IgG3 antibody (32/2, D-SSIL-32/2); (ii) non-specific IgG3 (D-SSIL-IgG); or (iii) no IgG (D-SSL) on their surface. Equal DOX amounts were injected intravenously via each type of liposome into BALB/c mice carrying experimental lung metastases of a polyoma virus-induced fibrosarcoma (A9 etc 220) expressing a polyoma virus-induced tumor-associated antigen (PAA) on their surface. Metastases occurred mainly in lung. Mice were treated at 3 stages of tumor development (micrometastases, medium-size metastases, and large, necrotic metastases). Performance evaluation was based on time-dependent quantification of DOX and DOX metabolites (DOX-M) in lung tumor, noncancerous organs, and plasma. Results. (i) DOX delivered via both SSIL retained the prolonged circulation time typical of DOX delivered via D-SSL. (ii) DOX accumulation in noncancerous organs was similar for all preparations. Low levels of DOX-M were obtained for all three preparations in all organs except liver, suggesting a similar processing, (iii) Preparations differed in behavior in lung tumor depending on tumor size and microanatomy. Only at the micrometastases stage were the specifically targeted D-SSIL-32/2 superior to D-SSL and D-SSIL-IgG, delivering 2–4 times more drug into the tumor, (iv) DOX-M level in all three tumor stages was in the following order: D-SSIL-32/2 >> D-SSL >> D-SSIL-IgG, suggesting that DOX delivered as D-SSIL-32/2 is most available to tumor cells. Conclusions. The advantage of specific targeting of sterically stabilized liposomes is expressed mainly in increasing availability of DOX to tumor cells in a way which is dependent on tumor microanatomy. The impact of this advantage to therapeutic efficacy remains to be determined.

The in vitro generation of effector lymphocytes and their employment in tumor immunotherapy.

Publisher Summary The theory of immune surveillance against progressive neoplasia has been widely contested in recent years. The doubts casted on its axioms and corollaries have undermined much of the conceptual framework for efforts at tumor immunotherapy, and placed into serious question the validity of continued attempts in this direction. The probable irrelevance of most investigational models in tumor immunology to the natural history of neoplastic disease has been accentuated by the recent findings that signify the inability of neoplasms arising spontaneously in inbred experimental animals to evoke defensive immune reactions. These observations brought about a shift in analogies. Human cancers have come to be considered as analogous, immunologically, to spontaneous tumors of laboratory mice and rats rather than to those that have been the stock in trade of the experimental tumor immunologist. Currently, the climate of opinion regarding the role of immunologic responsiveness in cancer defenses has become pervasively unfavorable. Some investigators still entertain the possibility that immune surveillance may be prominent in the protection against cancers that do not normally come to appearance in nature, but that for those that do, immunologic function is thought to be excluded—as absent or inadequate—from the confrontation.

A novel influenza subunit vaccine composed of liposome-encapsulated haemagglutinin/neuraminidase and IL-2 or GM-CSF. I. Vaccine characterization and efficacy studies in mice

The aim of this study was to improve the potency of the currently used influenza subunit vaccines, which are of relatively low efficiency in high-risk groups. Influenza A virus (Shangdong/9/93) haemagglutinin/neuraminidase (H3N2), granulocyte-macrophage colony-stimulating factor (GM-CSF) and interleukin-2 (IL-2) were encapsulated, each separately or combined, in multilamellar vesicles composed of dimyristoyl phosphatidylcholine. BALB/c mice were immunized once, i.p. or s.c., with 0.05-2.0 microg HN administered either as free antigen (F-HN), adsorbed to aluminum hydroxide (Al-HN), or encapsulated in liposomes (Lip-HN), separately or together with 1 x 10(2)-4.5 x 10(4) units of free or encapsulated cytokines. Serum antibodies were assayed on days 11-360 by the haemagglutination-inhibition (HI) test and ELISA. Protective immunity against intranasal virus challenge was determined at 9-14 months post-vaccination. The following results were obtained: (1) The efficiency of encapsulation in liposomes was 95, 90 and 38% for HN, IL-2 and GM-CSF, respectively, and the liposomal preparations were highly stable as an aqueous dispersion for > 2 months at 4 degrees C. (2) Following immunization with 0.5 microg Lip-HN, there was an earlier, up to 50-fold stronger, and 3-5 times longer response than that obtained with nonliposomal HN. (3) Coimmunization with free cytokines further increased the response 2-20 times and the two cytokines had an additive effect. (4) Liposomal cytokines were 2-20 times more effective than the free cytokines and their stimulatory effect was more durable. (5) A 100% seroconversion (HI titer > or = 40) was achieved with only 10-25% of the routinely used antigen dose, by encapsulating either antigen or cytokine. (6) The level of protection following vaccination with the combined liposomal vaccines was 70-100% versus 0-25% in mice immunized with Al-HN alone, and no toxicity was observed. In conclusion, our animal experiments show that the liposomal vaccines are superior to the currently used influenza vaccines, increasing the response by 2-3 orders of magnitude in mice. This approach may also prove valuable for subunit vaccines against other microorganisms.

Delivery of cytokines by liposomes: hematopoietic and immunomodulatory activity of interleukin-2 encapsulated in conventional liposomes and in long-circulating liposomes.

Although liposomal delivery of interleukin-2 (IL-2) and other cytokines improves their pharmacokinetics and biologic activity in vivo, there are no comparative functional studies of various liposomal formulations as cytokine carriers. In the present investigation, recombinant human IL-2 was encapsulated in two formulations of large (mean diameter 0.75-1.5 microns) multilamellar vesicles (MLV, referred to as conventional liposomes) or in small (mean diameter, 60 nm), unilamellar, long-circulating liposomes (referred to as sterically stabilized liposomes, SSL). The biologic activity of the liposomal formulations and of free IL-2 was tested in parallel in vitro and in mice. The main observations were as follows: (a) All the liposomal IL-2 (Lip-IL-2) formulations were more efficient than soluble IL-2 in stimulating spleen cell proliferation and lymphokine-activated killer (LAK) cell activation in vitro, particularly at low cytokine doses (1-100 CU/mL). (b) After i.v. injection, the circulation time of MLV-IL-2 and SSL-IL-2 was 7 and 17 times greater, respectively, than that of soluble IL-2. (c) In comparison with IL-2, all Lip-IL-2 formulations caused a marked increase in the leukocyte levels in blood, spleen, and peritoneal exudate, especially in those of myeloid origin (neutrophils, eosinophils, immature granulocytes, and macrophages). (d) Although SSL-IL-2 exhibited the longest circulation time, MLV-IL-2 was more potent in elevating leukocyte levels and in triggering LAK cell activity in vivo. (e) The route of Lip-IL-2 administration greatly affected the immunomodulatory activity in the various compartments. (f) MLV-IL-2 proved to be a much more efficient immunoadjuvant than free IL-2 for influenza subunit vaccines as well as for tumor cell vaccines. These findings lend support to our previous studies in which we demonstrated the superior immunomodulatory activity of liposomal IL-2, and suggest that cytokine pharmacokinetics, biodistribution, and pharmacodynamics are markedly influence both by liposomal formulation and route of administration.

Immunogenicity and safety of a novel IL-2-supplemented liposomal influenza vaccine (INFLUSOME-VAC) in nursing-home residents.

Influenza and its complications account for substantial morbidity and mortality, especially among the elderly. In young adults, immunization provides 70-90% protection, while among the elderly the vaccine may be only </=50% effective; hence, the need for new, more immunogenic vaccines. We compared the safety and immunogenicity of a novel, interleukin-2 (IL-2) -supplemented trivalent liposomal influenza vaccine (designated INFLUSOME-VAC) with that of a commercial trivalent split virion vaccine in community-residing elderly volunteers (mean age 81 years) in winter of 2000/2001. Eighty-one individuals were randomly assigned to be vaccinated intramuscularly, either with the standard vaccine (n=33) or with INFLUSOME-VAC (n=48) prepared from the former. The two vaccines contained equal amounts of hemagglutinin (HA) ( approximately 15 microgram of each viral strain); INFLUSOME-VAC consisted of liposomal antigens admixed with liposomal human IL-2 (Lip IL-2) (33 microgram = 6x10(5) IU/dose). At 1 month post-vaccination, seroconversion rates (tested by hemagglutination inhibition) for the A/New Caledonia (H1N1) and A/Moscow (H3N2) strains were significantly higher (P=0.04) in the INFLUSOME-VAC group (65 versus 45%, 44 versus 24%, respectively). Moreover, INFLUSOME-VAC induced a greater anti-neuraminidase (NA-N2) response (P<0.05). Anti-IL-2 antibodies were undetected, and no increase in anti-phospholipid IgG antibodies was found in the INFLUSOME-VAC group. Adverse reactions were similar in both groups. Thus, INFLUSOME-VAC appears to be both safe and more immunogenic than the currently used vaccine in the elderly.