The present invention relates to a Lyme disease vaccine, a genetic construct, recombinant protein, method for genetic construct design, method for vaccine delivery, method for recombinant proteins delivery, use of recombinant proteins in the production of Lyme disease vaccine. In particular, the method concerns the use of TROSPA and TROSPA-Salp15 recombinant proteins derived from castor bean tick (Ixodes riccinus) as a component of Lyme disease vaccine for animals. The antibodies present in blood of an immunized vertebrate directed against the TROSPA proteins considerably reduce the chance of infecting new ticks by blocking or hindering the interaction of TROSPA protein with OspA protein of Borrelia burgdorferi sensu lato. The interaction is crucial in the process of the spirochete entering a tick. The antibodies directed against the TROSPA-Salp15 protein protect vertebrates from infection on the stage of Borellia diffusion by destroying their protective coating formed at the surface as a result of the interaction between the Salp15 tick protein and OspC spirochete protein. The vaccine based on TROSPA tick proteins and TROSPA-Salp15 proteins may be used independently or together with the OspA recombinant proteins and OspC protein of Borrelia burgdorferi sensu lato.

The present invention includes compositions and methods for the use of an encapsulation additive having between about 0.1 to about 30 percent isolated and purified vitelline protein B to provide for mixed and extended release formulations.

Two antigenic and immunogenic proteins of the cattle tick, Rhipicephalus microplus, and the genes encoding these proteins, are effective for eliciting a protective immune response that controls and prevents infestations of bovines and other livestock by the tick. The proteins isolated from the cattle tick include an aquaporin protein and a TC5777 gut membrane protein. Each of the proteins elicit an immunoprotective response in livestock to the cattle tick, and can be formulated and administered as vaccines. Alternatively, the isolated DNA sequences which encode these proteins can be incorporated into nucleic acid constructs which could be utilized as DNA vaccines. The nucleic acid constructs can also be used for the transformation of cells and the production of recombinant proteins. Induction of the protective immune response controls and prevents infestations of the treated animals with the tick, thereby protecting them against tick-borne pathogen transmission.

The invention relates to antigenic polypeptides derived from a naturally occurring R. microplus protein, and nucleic acids encoding such polypeptides. The polypeptides elicit an immune response which, in turn, produces detrimental effects in R. microplus feeding on vaccinated cattle. Thus, the present disclosure provides novel vaccines to protect cattle from R. microplus infestation.

The present invention relates to the use of the pituitary adenylate cyclase activating peptide (PACAP) as a molecular adjuvant for vaccines. Among other applications, these vaccines may be used in the protection against infectious agents such as viruses, bacteria and ectoparasites affecting mammals, birds and aquatic organisms. The PACAP, combined with a particular antigen, demonstrates its effectiveness as adjuvant increasing the host immune response against that antigen. This type of response can be observed when the vaccine compositions or combinations that include PACAP are administered orally, by injection, or by immersion baths, in case of aquatic organisms.

Described herein is a method of generating tick immunity in a subject. The method includes administering to the subject in need thereof a therapeutically effective amount of at least one tick-salivary protein. Also described herein is a composition for generating tick immunity in a subject. In certain embodiments, the composition includes a therapeutically effective amount of at least one tick-salivary protein.

Disclosed are compositions and methods that provide synthetic nanocarriers that comprise hydrophobic polyester carrier material and rapamycin that is in a stable, super-saturated amount. In some embodiments, the synthetic nanocarriers are also initially sterile filterable. In other embodiments, the rapamycin is present in the synthetic nanocarrier compositions in an amount that is less than 50 weight % rapamycin/hydrophobic polyester carrier material in the composition.

Disclosed herein are immunogenic compositions for preventing or treating infection with filarial parasites and biomarkers for diagnosing infection with filarial parasites.

Provided herein are compositions and methods for reducing bacterial contamination during cell culture. Such compositions and methods utilize engineered peptides or recombinant cells capable of secreting such peptides into culture medium. Also provided are methods of using the engineered peptides for inhibiting bacterial growth during culturing of cells.

Disclosed herein are fusion proteins comprising a truncated thrombostasin protein having at least 85% sequence homology to a thrombostasin protein, wherein the thrombostasin protein has a carboxy terminal deletion; and a fusion partner protein that is a non-thrombostasin protein. Further disclosed are vaccine compositions thrombostasin proteins having a comprising a carboxy terminal deletion, and methods for inhibiting a response to a thrombostasin protein in a host in need thereof, comprising the disclosed fusion proteins or vaccine compositions. Further disclosed are methods for the preparation of a fusion protein composition.