Abstract: The present invention uses co-expression of protease inhibitors and protease sensitive therapeutic agents that results in their localized production within the target tissue and inactivation outside of the target tissue, thereby increasing therapeutic activity and reducing the systemic toxicity. Inactivation is also accomplished by engineering protease degradation sites within the therapeutic construct for proteases, preferably those that are under-expressed within the target tissue yet present in non-target tissues within the body, resulting in therapeutic activity within the target tissue and inactivation outside of the target tissue. Novel chimeric proteins secreted by bacteria are also described. The chimeric proteins include chimeric toxins targeted to neoplastic cells and cells of the immune system. Novel combination therapies of these protease inhibitor:chimeric toxin-expressing bacteria together with small-molecule and biologic agents are also described.

Abstract: A substantially purified substance having the properties of a bacterial microcin methionine analog, methionine synthesis inhibitor, tRNA-methionine synthase inhibitors or methionine competitive inhibitor capable of inhibiting tumor cell growth without inhibiting the growth of normal cells or treating neoplastic diseases, and may be used alone or in combination with other anti-cancer agents. The purified substance may also have anti-hyperhomocysteineuria and/or anti-infective properties, such as antifungal activity. The purified substance can be safely administered to animals including humans for the treatment of neoplastic, hyperhomocysteinemia and/or infectious diseases for the treatment of those diseases.

Abstract: Bacteria which co-express protease inhibitors and protease sensitive therapeutic agents, which are surface displayed, secreted and/or released and result in their localized production and maintenance within a target tissue and inactivation outside of the target tissue, thereby increasing therapeutic activity and reducing the systemic toxicity. The bacteria may be attenuated, non-pathogenic, low pathogenic or a probiotic. Protease sensitivity may be further accomplished by engineering protease degradation sites within the therapeutic agents, further enhancing the inactivation outside of the target tissue while retaining activity within the target tissue through co-expression of a protease inhibitor. Novel chimeric proteins secreted by bacteria, including chimeric toxins targeted to neoplastic cells, tumor matrix cells and cells of the immune system, and combination therapies of these protease inhibitor:chimeric toxin-expressing bacteria together with small-molecule and biologic agents are also described.

Abstract: The present invention relates to gram-negative bacterial mutants resistant to one or more stress conditions, including, but not limited to, CO2, acid pH, and high osmolarity. The present invention also relates more particularly to gram-negative bacterial mutants with reduced TNF-? induction having a mutation in one or more lipid biosynthesis genes, including, but not limited to msbB, that are rendered stress-resistant by a mutation in the zwf gene. The present invention provides compositions comprising one or more stress-resistant gram-negative bacterial mutants, preferably attenuated stress-resistant gram-negative bacterial mutants. In particular, the present invention relates to methods for prophylaxis or treatment of a virally induced disease in a subject comprising administering to said subject one or more stress-resistant gram-negative bacterial mutants, preferably attenuated stress-resistant gram-negative bacterial mutants.

Abstract: Chimeric proteins are expressed, secreted or released by a bacterium to immunize against or treat a parasite, infectious disease or malignancy. The delivery vector may also be attenuated, non-pathogenic, low pathogenic, or a probiotic bacterium. The chimeric proteins include chimeras of, e.g., phage coat and/or colicin proteins, bacterial toxins and/or enzymes, autotransporter peptides, lytic peptides, multimerization domains, and/or membrane transducing (ferry) peptides. The active portion of the immunogenic chimeric proteins can include antigens against a wide range of parasites and infectious agents, cancers, Alzheimer's and Huntington's diseases, and have enhanced activity when secreted or released by the bacteria, and/or have direct anti-parasite or infectious agent activity. The activity of the secreted proteins is further increased by co-expression of a protease inhibitor that prevents degradation of the effector peptides.

Abstract: Gram-negative bacteria, and compositions containing the bacteria, resistant to one or more stress conditions, including, but not limited to, CO2, acid pH, and high osmolarity, having reduced TNF-?induction having a mutation in one or more lipid biosynthesis genes, e.g., msbB, rendered stress-resistant by a mutation in the zwf gene are provided. Methods for prophylaxis or treatment of a virally induced disease in a subject comprising administering preferably attenuated stress-resistant gram-negative bacterial mutants. and for prophylaxis or treatment of a virally induced disease in a subject comprising administering one or more stress-resistant gram-negative bacterial mutants as vectors for the delivery of one or more therapeutic molecules are provided.

Abstract: The present invention uses co-expression of protease inhibitors and protease sensitive therapeutic agents that results in their localized production within the target tissue and inactivation outside of the target tissue, thereby increasing therapeutic activity and reducing the systemic toxicity. Inactivation is also accomplished by engineering protease degradation sites within the therapeutic construct for proteases, preferably those that are under-expressed within the target tissue yet present in non-target tissues within the body, resulting in therapeutic activity within the target tissue and inactivation outside of the target tissue. Novel chimeric proteins secreted by bacteria are also described. The chimeric proteins include chimeric toxins targeted to neoplastic cells and cells of the immune system. Novel combination therapies of these protease inhibitor:chimeric toxin-expressing bacteria together with small-molecule and biologic agents are also described.

Abstract: Bacteria which co-express protease inhibitors and protease sensitive therapeutic agents, which are surface displayed, secreted and/or released and result in their localized production and maintenance within a target tissue and inactivation outside of the target tissue, thereby increasing therapeutic activity and reducing the systemic toxicity. The bacteria may be attenuated, non-pathogenic, low pathogenic or a probiotic. Protease sensitivity may be further accomplished by engineering protease degradation sites within the therapeutic agents, further enhancing the inactivation outside of the target tissue while retaining activity within the target tissue through co-expression of a protease inhibitor. Novel chimeric proteins secreted by bacteria, including chimeric toxins targeted to neoplastic cells, tumor matrix cells and cells of the immune system, and combination therapies of these protease inhibitor:chimeric toxin-expressing bacteria together with small-molecule and biologic agents are also described.

Abstract: A live bacterium, having a DNA construct stabilized against transduction of other bacteria, having a promoter sequence and encoding a fusion peptide, comprising a bacterial secretion peptide portion and a non-bacterial immunogenic polypeptide portion, having a nucleotide sequence coding for the non-bacterial immunogenic polypeptide portion which has at least one codon optimized for bacterial expression. The bacterium has a secretion mechanism which interacts with at least the bacterial secretion peptide portion to cause a secretion of the fusion peptide from the bacterium, and a genetic virulence attenuating mutation. The bacterium is adapted to act as an animal vaccine, to transiently infect a tissue of the animal, and cause an immunity response to the non-bacterial immunogenic polypeptide portion in the animal to a non-bacterial organism associated with the non-bacterial immunogenic polypeptide portion.

Abstract: A live bacterium, having a DNA construct stabilized against transduction of other bacteria, having a promoter sequence and encoding a fusion peptide, comprising a bacterial secretion peptide portion and a non-bacterial immunogenic polypeptide portion, having a nucleotide sequence coding for the non-bacterial immunogenic polypeptide portion which has at least one codon optimized for bacterial expression. The bacterium has a secretion mechanism which interacts with at least the bacterial secretion peptide portion to cause a secretion of the fusion peptide from the bacterium, and a genetic virulence attenuating mutation. The bacterium is adapted to act as an animal vaccine, to transiently infect a tissue of the animal, and cause an immunity response to the non-bacterial immunogenic polypeptide portion in the animal to a non-bacterial organism associated with the non-bacterial immunogenic polypeptide portion.

Abstract: The present invention relates to gram-negative bacterial mutants resistant to one or more stress conditions, including, but not limited to, CO2, acid pH, and high osmolarity. The present invention also relates more particularly to gram-negative bacterial mutants with reduced TNF-? induction having a mutation in one or more lipid biosynthesis genes, including, but not limited to msbB, that are rendered stress-resistant by a mutation in the zwf gene. The present invention provides compositions comprising one or more stress-resistant gram-negative bacterial mutants, preferably attenuated stress-resistant gram-negative bacterial mutants. In particular, the present invention relates to methods for prophylaxis or treatment of a virally induced disease in a subject comprising administering to said subject one or more stress-resistant gram-negative bacterial mutants, preferably attenuated stress-resistant gram-negative bacterial mutants.

Abstract: The present invention relates to gram-negative bacterial mutants resistant to one or more stress conditions, including, but not limited to, CO2, acid pH, and high osmolarity. The present invention also relates more particularly to gram-negative bacterial mutants with reduced TNF-? induction having a mutation in one or more lipid biosynthesis genes, including, but not limited to msbB, that are rendered stress-resistant by a mutation in the zwf gene. The present invention provides compositions comprising one or more stress-resistant gram-negative bacterial mutants, preferably attenuated stress-resistant gram-negative bacterial mutants. In particular, the present invention relates to methods for prophylaxis or treatment of a virally induced disease in a subject comprising administering to said subject one or more stress-resistant gram-negative bacterial mutants, preferably attenuated stress-resistant gram-negative bacterial mutants.

Abstract: The present invention provides a vaccine, method of use, and kit employing genetically isolated and stabilized, live attenuated bacterial strains including Salmonella that express one or more avian influenza antigens for use in live vaccine compositions that can be orally administered to an individual to protect against avian influenza. Genetic stabilization may be achieved through deletion of IS200 elements and bacteria phage and prophage elements. The bacterial strains may be genetically isolated from external phage infection by constitutive expression of a P22 phage repressor.