A vaccine composition for birds comprising as an active ingredient a structure containing O-antigen derived from Gram-negative bacteria, provided that said structure does not contain a whole cell, and a process for preparing the same are provided. By using a structure containing O-antigen (e.g. lipopolysaccharide) derived from Gram-negative bacteria as an active ingredient in accordance with the present invention, alleviation of inoculation reaction and reduction in an amount of injection are attained as compared to the conventional whole-cells vaccine to thereby allow for the increase in the number of other antigens to be mixed therewith.

The present invention provides vaccine compositions and methods of producing such compositions. Other embodiments of the invention include methods of treating a pathogen infection, methods of vaccinating a subject against a pathogen infection, and methods for treating an antibiotic-resistance bacterial infection in a subject in need thereof. In further embodiments, the invention includes methods of decreasing the level of a pathogen in a subject having a pathogen infection, methods of increasing the surviving rate of a subject having a pathogen infection, methods of reducing the level of pain associated with a pathogen infection, and methods of reducing the level of distress associated with a pathogen infection in a subject in need thereof. Novel scaffold compositions and opsonin-bound or lectin-bound pathogen compositions, and uses thereof, are also provided herein.

A method for treatment of a subject having an inflammatory disease of the epithelium comprising the step of administering an amount of a composition comprising an isolated bacterial amyloid peptide to said subject. In embodiments, the composition is membrane-free. In embodiments, the composition comprises a curli fibril. In yet further embodiments, the isolated bacterial amyloid peptide is a CsgA polypeptide, a CsgA polypeptide fragment, a CsgB polypeptide or a CsgB polypeptide fragment. Also provided is a method for decreasing epithelium permeability in a tissue of a subject comprising epithelium comprising the step of administering an amount of a composition comprising an isolated bacterial amyloid peptide to the epithelium of the subject. In embodiments, the composition is membrane-free. In further embodiments, the composition comprises a curli fibril. In embodiments, the isolated bacterial amyloid peptide is a CsgA polypeptide, a CsgA polypeptide fragment, a CsgB polypeptide or a CsgB polypeptide fragment.

This invention relates to the medical use of pathogen associated molecular pattern (PAMP) displaying immunostimulatory microbial immuno-adjuvants [MIAs], as therapeutics when used in combination with check point inhibitors to treat various types of cancer and to methods of treatment which involve treating a subject with these compounds and compound mixtures and process methods for identifying and optimally composing them for their therapeutic use in cancer treatment. It also relates to the use of inhibitors of these PAMP displaying immunostimulatory microbial immuno-adjuvants [MIAs], as therapeutics when used to treat inflammatory bowel disease (IBD) including Crohn's Disease and ulcerative colitis and irritable bowel syndrome (IBS) and process methods for identifying and optimally composing them for their therapeutic use in IBD and IBS.

The present invention relates to a method of preparing a live attenuated vaccine by irradiation and a live attenuated vaccine composition prepared by the same, and more particularly, a method of preparing a live attenuated vaccine by irradiation including irradiating a pathogenic microorganism with a dose of 0.5 to 2 kGy of radiation per single radiation six to fifteen times; and a live attenuated vaccine composition including a pathogenic microorganism attenuated to not be revertant to a wild type by generation of at least one mutation of nucleotide insertion and nucleotide deletion by irradiation.

The present disclosure belongs to the technical field of veterinary biological products, and specifically relates to a triple vaccine for diseases caused by Salmonella typhimurium, Riemerella anatipestifer and Escherichia coli. In the triple vaccine, antigens are an inactivated Salmonella typhimurium E01 strain, an inactivated Riemerella anatipestifer R01 strain and an inactivated Escherichia coli E01 strain. The three strains used in the vaccine have high virulence, disable immunogenicity and disable cross-protection. The prepared vaccine has a desirable safety, causing no local or systemic adverse reactions. In a shelf life test, all indicators of the vaccine are stable and effective after a data analysis of traits, a safety test and an efficacy test; in addition, efficacy test results prove that the inactivated triple vaccine can produce desirable antibodies and relatively desirable attacking protection.

Aeromonas hydrophila is a reemerging pathogen of channel catfish (Ictalurus punctatus); recent outbreaks from 2009 to 2014 have caused the loss of more than 12 million pounds of market size catfish in Alabama and Mississippi. Genome sequencing revealed a clonal group of A. hydrophila isolates with unique genetic and phenotypic features that is highly pathogenic in channel catfish. Comparison of the genome sequence of a representative catfish isolate (ML09-119) from this virulent clonal group with lower virulence A. hydrophila isolates revealed four fimbrial proteins unique to strain ML09-119. In this work, we expressed and purified four A. hydrophila fimbrial proteins (FimA, Fim, MrfG, and FimOM) and assessed their ability to protect and stimulate protective immunity in channel catfish fingerlings against A. hydrophila ML09-119 infection for vaccine development. Our results showed catfish immunized with FimA, Fim, FimMrfG, and FimOM exhibited 59.83%, 95.41%, 85.72%, and 75.01% relative percent survival, respectively, after challenge with A. hydrophila strain ML09-119. Bacterial concentrations in liver, spleen, and anterior kidney were significantly (p<0.05) lower in vaccinated fish compared to the non-vaccinated sham groups at 48 h post-infection. However, only the Fim immunized group showed a significantly higher antibody titer in comparison to the non-vaccinated treatment group (p<0.05) at 21 days post-vaccination. Altogether, Fim and FimMrfG recombinant proteins have potential for vaccine development against virulent A. hydrophila infection. Genomic subtraction revealed three outer membrane proteins present in strain ML09-119 but not in the low virulence reference A. hydrophila strain; the major outer membrane protein OmpAI (OmpA1), TonB-dependent receptor (TonB-DR), and transferrin-binding protein A (TbpA). Here, the genes encoding OmpAI, tonB-DR, and tbpA were cloned from A. hydrophila ML09-119 and were expressed into Escherichia coli. The purified recombinant OmpA, TonB-DR, and TbpA proteins had estimated molecular weights of 37.26, 78.55, and 41.67 kDa, respectively. Catfish fingerlings vaccinated with OmpA1, TonB-DR, and TbpA emulsified with non-mineral oil adjuvant were protected against the subsequent A. hydrophila ML09-119 infection with 98.59%, 95.59%, and 47.89% relative percent survival (RPS), respectively. Furthermore, the mean liver, spleen, and anterior kidney bacterial loads were significantly lower in catfish vaccinated with the OmpA1 and TonB-DR than the non-vaccinated control group. ELISA demonstrated that catfish immunized with OmpA1, TonB-DR, an

Aeromonas hydrophila is a reemerging pathogen of channel catfish (Ictalurus punctatus); recent outbreaks from 2009 to 2014 have caused the loss of more than 12 million pounds of market size catfish in Alabama and Mississippi. Genome sequencing revealed a clonal group of A. hydrophila isolates with unique genetic and phenotypic features that is highly pathogenic in channel catfish. Comparison of the genome sequence of a representative catfish isolate (ML09-119) from this virulent clonal group with lower virulence A. hydrophila isolates revealed four fimbrial proteins unique to strain ML09-119. In this work, we expressed and purified four A. hydrophila fimbrial proteins (FimA, Fim, MrfG, and FimOM) and assessed their ability to protect and stimulate protective immunity in channel catfish fingerlings against A. hydrophila ML09-119 infection for vaccine development. Our results showed catfish immunized with FimA, Fim, FimMrfG, and FimOM exhibited 59.83%, 95.41%, 85.72%, and 75.01% relative percent survival, respectively, after challenge with A. hydrophila strain ML09-119. Bacterial concentrations in liver, spleen, and anterior kidney were significantly (p < 0.05) lower in vaccinated fish compared to the non-vaccinated sham groups at 48 h post-infection. However, only the Fim immunized group showed a significantly higher antibody titer in comparison to the non-vaccinated treatment group (p < 0.05) at 21 days post-vaccination. Altogether, Fim and FimMrfG recombinant proteins have potential for vaccine development against virulent A. hydrophila infection. Genomic subtraction revealed three outer membrane proteins present in strain ML09-119 but not in the low virulence reference A. hydrophila strain; the major outer membrane protein OmpAI (OmpA1), TonB-dependent receptor (TonB-DR), and transferrin-binding protein A (TbpA). Here, the genes encoding OmpAI, tonB-DR, and tbpA were cloned from A. hydrophila ML09-119 and were expressed into Escherichia coli. The purified recombinant OmpA, TonB-DR, and TbpA proteins had estimated molecular weights of 37.26, 78.55, and 41.67 kDa, respectively. Catfish fingerlings vaccinated with OmpA1, TonB-DR, and TbpA emulsified with non-mineral oil adjuvant were protected against the subsequent A. hydrophila ML09-119 infection with 98.59%, 95.59%, and 47.89% relative percent survival (RPS), respectively. Furthermore, the mean liver, spleen, and anterior kidney bacterial loads were significantly lower in catfish vaccinated with the OmpA1 and TonB-DR than the non-vaccinated control group. ELISA demonstrated that catfish immunized with OmpA1, TonB-DR, and TbpA produce significant anti

A live attenuated Edwardsiella ictaluri bacterium lacking a viable gene encoding a functional evpB protein and a method of using the same to protect fish against infection from virulent Edwardsiella ictaluri. The methods and compositions for protecting fish against infection from virulent Edwardsiella ictaluri comprising administering to a fish a therapeutically effective amount of an attenuated Edwardsiella ictaluri bacterium lacking a viable gene encoding a functional protein selected from the group consisting of evpB, fur and hfq. The bacterium may include an insertion and/or deletion mutation in the gene. The fish include catfish, preferably catfish fingerling or a catfish fry. The composition may be delivered via immersion delivery, an injection delivery, an oral delivery, or combinations thereof.

The present invention provides vaccine compositions and methods of producing such compositions. Other embodiments of the invention include methods of treating a pathogen infection, methods of vaccinating a subject against a pathogen infection, and methods for treating an antibiotic-resistance bacterial infection in a subject in need thereof. In further embodiments, the invention includes methods of decreasing the level of a pathogen in a subject having a pathogen infection, methods of increasing the surviving rate of a subject having a pathogen infection, methods of reducing the level of pain associated with a pathogen infection, and methods of reducing the level of distress associated with a pathogen infection in a subject in need thereof. Novel scaffold compositions and opsonin-bound or lectin-bound pathogen compositions, and uses thereof, are also provided herein.