The present invention is directed to novel polynucleotides, polypeptides, and polyproteins of Mycoplasma surface proteins, all of which are useful in detecting infection and for the preparation of vaccines for treating and preventing diseases in swine and other animals. Vaccines provided according to the practice of the invention are effective against Mycoplasma infections. Detection and therapeutic polyclonal and monoclonal antibodies are also a feature of the present invention. Assays, kits, systems, and nanoparticle encapsulated compositions related to the polynucleotides, polypeptides, polyproteins, antibodies or fragments, derivatives, and variants thereof are also disclosed.

The present invention is directed to novel polynucleotides, polypeptides, and polyproteins of Mycoplasma surface proteins, all of which are useful in detecting infection and for the preparation of vaccines for treating and preventing diseases in swine and other animals. Vaccines provided according to the practice of the invention are effective against Mycoplasma infections. Detection and therapeutic polyclonal and monoclonal antibodies are also a feature of the present invention. Assays, kits, systems, and nanoparticle encapsulated compositions related to the polynucleotides, polypeptides, polyproteins, antibodies or fragments, derivatives, and variants thereof are also disclosed.

Disclosed are a construction method of a recombinant drug-resistant Mycobacterium bovis (M. bovis) Bacillus Calmette-Guerin (BCG) strain and a pharmaceutical composition for treating tuberculosis (TB). The construction method includes: using BCG as an original bacterial strain to construct a drug-resistant BCG strain resistant to at least one selected from the group consisting of STR, LFX, EMB, PRO, PAS, and AMK; and further inserting sequence fragments that can express related antigens Ag85b and Rv2628 causing an immune response into a genome of the strain to construct a recombinant drug-resistant BCG strain. The recombinant drug-resistant BCG strain can compete with Mycobacterium tuberculosis (Mtb) for growth, thereby accelerating the death of Mtb. When used in combination with a drug for treating TB, the recombinant drug-resistant BCG strain can further enhance a therapeutic effect for Mtb, and can also avoid re-infection of a patient.

Disclosed are a construction method of a recombinant drug-resistant Mycobacterium bovis (M. bovis) Bacillus Calmette-Guerin (BCG) strain and a pharmaceutical composition for treating tuberculosis (TB). The construction method includes: using BCG as an original bacterial strain to construct a drug-resistant BCG strain resistant to at least one selected from the group consisting of STR, LFX, EMB, PRO, PAS, and AMK; and further inserting sequence fragments that can express related antigens Ag85b and Rv2628 causing an immune response into a genome of the strain to construct a recombinant drug-resistant BCG strain. The recombinant drug-resistant BCG strain can compete with Mycobacterium tuberculosis (Mtb) for growth, thereby accelerating the death of Mtb. When used in combination with a drug for treating TB, the recombinant drug-resistant BCG strain can further enhance a therapeutic effect for Mtb, and can also avoid re-infection of a patient.

Methods of eliciting and/or modulating immune responses, therapeutic methods, and antigen delivery methods that include the step of administering a protein particle derived from a cell, the protein particle comprising a diphtheria toxin Cross Reacting Material (CRM) amino acid sequence are disclosed. Included are diagnostic methods using the protein particle derived from a cell, the protein particle comprising a diphtheria toxin CRM amino acid sequence. The methods disclosed herein may be useful as an antigen carrier delivery system.

Methods of eliciting and/or modulating immune responses, therapeutic methods, and antigen delivery methods that include the step of administering a protein particle derived from a cell, the protein particle comprising a diphtheria toxin Cross Reacting Material (CRM) amino acid sequence are disclosed. Included are diagnostic methods using the protein particle derived from a cell, the protein particle comprising a diphtheria toxin CRM amino acid sequence. The methods disclosed herein may be useful as an antigen carrier delivery system.

The present disclosure is the first to identify a host cell protein and its function with which MPT63 and MPT64, secreted antigens of Mycobacterium tuberculosis, interact, and to construct a recombinant MPT protein including each domain of MPT63 and MPT64 interacting with the host cell protein, and the recombinant MPT protein may be applied to a use for the prevention and treatment of tuberculosis by confirming that the recombinant MPT protein targets the Mycobacterium tuberculosis-infected macrophages and increases the ROS level and inflammatory cytokine expression in macrophages, thereby inducing the death of Mycobacterium tuberculosis. And MPT protein of the present disclosure can improve the vaccine effect by the BCG vaccine so that it can be used as a tuberculosis vaccine and/or vaccine adjuvant either alone or together with known tuberculosis vaccines.

The present disclosure is the first to identify a host cell protein and its function with which MPT63 and MPT64, secreted antigens of Mycobacterium tuberculosis, interact, and to construct a recombinant MPT protein including each domain of MPT63 and MPT64 interacting with the host cell protein, and the recombinant MPT protein may be applied to a use for the prevention and treatment of tuberculosis by confirming that the recombinant MPT protein targets the Mycobacterium tuberculosis-infected macrophages and increases the ROS level and inflammatory cytokine expression in macrophages, thereby inducing the death of Mycobacterium tuberculosis. And MPT protein of the present disclosure can improve the vaccine effect by the BCG vaccine so that it can be used as a tuberculosis vaccine and/or vaccine adjuvant either alone or together with known tuberculosis vaccines.

Provided is a recombinant BCG employing a pMyong2 vector system to express HIV-1 p24 and a use thereof as a HIV-1 vaccine. rBCG-pMyong2-p24, which is a pMyong2 vector system, was found to induce the upregulation of HIV-1 p24 gag expression in rBCG and infected antigen-presenting cells (APC) and to induce improved p24-specific immune responses in vaccinated mice, compared to rBCG-pAL-p24 in a pAL5000 derived vector system. rBCG-pMyong2-p24 was identified to exhibit a higher p24-specific Ab production level than rSmeg-pMyong2-p24 in the same pMyong2 vector system. Therefore, the recombinant BCG employing rBCG-pMyong2-p24 to express HIV-1 p24 according to the present invention is identified to elicit enhanced immune responses to HIV-1 infection in mouse model systems and thus can be expected to be used as a prime vaccine in the heterologous prime-boost vaccination strategy against HIV-1 infection.

Provided is a recombinant BCG employing a pMyong2 vector system to express HIV-1 p24 and a use thereof as a HIV-1 vaccine. rBCG-pMyong2-p24, which is a pMyong2 vector system, was found to induce the upregulation of HIV-1 p24 gag expression in rBCG and infected antigen-presenting cells (APC) and to induce improved p24-specific immune responses in vaccinated mice, compared to rBCG-pAL-p24 in a pAL5000 derived vector system. rBCG-pMyong2-p24 was identified to exhibit a higher p24-specific Ab production level than rSmeg-pMyong2-p24 in the same pMyong2 vector system. Therefore, the recombinant BCG employing rBCG-pMyong2-p24 to express HIV-1 p24 according to the present invention is identified to elicit enhanced immune responses to HIV-1 infection in mouse model systems and thus can be expected to be used as a prime vaccine in the heterologous prime-boost vaccination strategy against HIV-1 infection.