Multistrain influenza protection induced by a nanoparticulate mucosal immunotherapeutic

All commercial influenza vaccines elicit antibody responses that protect against seasonal infection, but this approach is limited by the need for annual vaccine reformulation that precludes efficient responses against epidemic and pandemic disease. In this study we describe a novel vaccination approach in which a nanoparticulate, liposome-based agent containing short, highly conserved influenza-derived peptides is delivered to the respiratory tract to elicit potent innate and selective T cell-based adaptive immune responses. Prepared without virus-specific peptides, mucosal immunostimulatory therapeutic (MIT) provided robust, but short-lived, protection against multiple, highly lethal strains of influenza in mice of diverse genetic backgrounds. MIT prepared with three highly conserved epitopes that elicited virus-specific memory T-cell responses but not neutralizing antibodies, termed MITpep, provided equivalent, but more durable, protection relative to MIT. Alveolar macrophages were more important than dendritic cells in determining the protective efficacy of MIT, which induced both canonical and non-canonical antiviral immune pathways. Through activation of airway mucosal innate and highly specific T-cell responses, MIT and MITpep represent novel approaches to antiviral protection that offer the possibility of universal protection against epidemic and pandemic influenza.

Distribution of camptothecin after delivery as a liposome aerosol or following intramuscular injection in mice

PURPOSE

The plant alkaloid camptothecin (CPT) has shown significant antitumor activity against a wide variety of human tumors xenografted in nude mice. In previous studies we have found that administration of dilauroylphosphatidylcholine (DLPC) liposome aerosols containing 9-nitrocamptothecin (9-NC) inhibits the growth of human breast, colon and lung cancer xenografts. The purpose of this study was to analyze the pharmacokinetics and tissue distribution of inhaled CPT formulated in DLPC liposomes.

METHODS

C57BL/6 mice with subcutaneous Lewis lung carcinoma, Swiss nu/nu mice with human lung carcinoma xenografts and BALB/c mice without tumors were used for pharmacokinetic studies of CPT administered as a liposome aerosol and BALB/c mice were given CPT intramuscularly.

RESULTS

After 30 min inhalation of CPT liposome aerosol, drug was deposited in the lungs (310 ng/g) and was followed promptly by the appearance of high concentrations in the liver (192 ng/g) and with lesser amounts appearing in other organs. Drug concentration in the brain was 61 ng/g. After intramuscular injection of CPT dissolved in DMSO, drug was released from the site of injection very slowly and accumulated mainly in the liver (136 ng/g). Only trace amounts appeared in the lungs (2-4 ng/g). These results demonstrate a prompt pulmonary and later systemic distribution of CPT following liposome aerosol administration.

CONCLUSIONS

The substantial concentrations of CPT in lungs and other organs following inhalation of liposome aerosol suggest the possible benefit of it and of its more active derivative, 9-NC, in the treatment of lung, liver, kidney and brain cancer in humans.

Localization of the high and low affinity [3H]ryanodine binding sites on the skeletal muscle Ca2+ release channel

The Ca2+ release channel of skeletal muscle sarcoplasmic reticulum is modulated in a biphasic manner by the plant alkaloid ryanodine and there are two distinct binding sites on this channel for ryanodine. The Ca2+ release channel is a homotetramer with a subunit of 5037 amino acids. The ability of sarcoplasmic reticulum membranes to bind [3H]ryanodine to the high affinity site is lost upon proteolysis with trypsin. [3H]Ryanodine, however, bound before proteolysis remains bound after trypsin digestion. If the high affinity site is first occupied with [3H]ryanodine and then 100 microM ryanodine is added to occupy the low affinity sites, almost all of [3H]ryanodine bound to the high affinity site remains bound after proteolysis. Proteolysis causes the solubilized Ca2+ release channel containing bound [3H]ryanodine to undergo four discrete shifts in sedimentation (30 S-->28 S-->26 S-->19 S-->14 S). Polypeptides having apparent molecular masses of 76, 66, 56, 45, 37, and 27 kDa can be identified in the 14 S complex. The 76-, 56-, 45-, and 27-kDa polypeptides have been partially sequenced from the NH2 terminus. In addition, the 76-, 66-, and 27-kDa fragments are recognized by an antibody to the last 9 amino acids at the carboxyl terminus of the skeletal muscle ryanodine receptor and the 76-, 66-, and 37-kDa fragments are recognized by an antibody to a peptide matching the sequence 4670-4685. The 56-kDa and the 45-kDa fragments are not Ca2+ release channel fragments. Both high and low affinity ryanodine binding sites are found in the 14 S complex and are, therefore, most likely located between Arg-4475 and the carboxyl terminus.