Liposomes (phospholipid bilayer vesicles) are versatile and robust delivery systems for induction of antibody and T lymphocyte responses to associated subunit antigens. In the last 15 years, liposome vaccine technology has matured and now several vaccines containing liposome-based adjuvants have been approved for human use or have reached late stages of clinical evaluation. Given the intensifying interest in liposome-based vaccines, it is important to understand precisely how liposomes interact with the immune system and stimulate immunity. It has become clear that the physicochemical properties of liposomal vaccines – method of antigen attachment, lipid composition, bilayer fluidity, particle charge, and other properties – exert dramatic effects on the resulting immune response. Here, we present a comprehensive review of the physicochemical properties of liposomal vaccines and how they influence immune responses. A discussion of novel and emerging immunomodulators that are suitable for inclusion in liposomal vaccines is also presented. Through a comprehensive analysis of the body of liposomal vaccine literature, we enumerate a series of principles that can guide the rational design of liposomal vaccines to elicit immune responses of a desired magnitude and quality. We also identify major unanswered questions in the field, pointing the direction for future study.
High-affinity nitrilotriacetic acids (NTA) have great potential in the molecular manipulation of His-tagged proteins. We have developed a facile method to synthesize multivalent NTA and its conjugates. Starting with appropriately protected lysine, we synthesized the mono-NTA synthons functionalized with either an amino group or a carboxylic group. We then obtained tri-NTA through the condensation of the amino NTA and the carboxylic NTA. Using amino tri-NTA as the key intermediate, we synthesized a series of tri-NTA conjugates with a variety of functional units including biotin, dialkyl, fluorescein, and a hydroxybenzimidate moiety. The biotin-tri-NTA was employed to convert a Biacore streptavidin chip into a high-affinity tri-NTA chip. The equilibrium dissociation constants of tri-NTA/His-tagged protein complexes measured by surface plasmon resonance are in the 20 nM range. Histidine(6)-tagged yeast cytosine deaminase (His6-yCD) was incorporated onto the liposome surface by the lipid-tri-NTA conjugate without any activity loss. Fluorescein-tri-NTA formed a stable 1:1 complex with His6-yCD without significant fluorescence quenching. Specific tri-NTA derivatives for the radiolabeling and coupling of two His-tagged proteins to each other are described. Thus, we have added to the toolbox a number of high-affinity tri-NTA adaptors for the manipulation of His-tagged molecules.
Nitrilotriacetic acid (NTA) has moderate affinity (10 µM) for hexahistidine (His6) and is widely used in the purification of His6-tagged proteins. The affinity can be increased significantly (10 nM) through multivalency such as using a tris-NTA. We show that the binding affinity of tris-NTA is dependent on the flexibility and length of the spacer between the mono-NTA and the scaffold: the shorter the spacer, the higher the affinity. A series of biotinylated tris-NTA having different spacers were synthesized and used to prepare tris-NTA sensor chips for surface plasmon resonance measurement of binding affinity. Sub-nanomolar affinity can be achieved with a short spacer. The new high affinity tris-NTA enables the formation of stable complexes with hexahistidine containing molecules and provides a convenient method to non-covalently attach proteins to various surfaces.
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