Methods for the production of a bacterial toxin such as diphtheria toxin, and methods for producing conjugates of a bacterial toxins, are provided.

The present invention encompasses a novel S. aureus bioconjugate vaccine. More generally, the invention is directed to Gram-positive and other bioconjugate vaccines containing a protein carrier, at least one polysaccharide such as a capsular Gram-positive polysaccharide, and, optionally, an adjuvant or pharmaceutically acceptable carrier. The instant invention also includes methods of producing Gram-positive and other bioconjugate vaccines. An N-glycosylated protein is also provided that contains one or more polysaccharides such as Gram-positive polysaccharides. The invention is additionally directed to engineered prokaryotic organisms comprising nucleotide sequences encoding a glycosyltransferase of a first prokaryotic organism and a glycosyltransferase of a second prokaryotic organism. The invention further includes plasmids and prokaryotic cells transformed with plasmids encoding polysaccharides and enzymes which produce an N-glycosylated protein and/or bioconjugate vaccine. Further, the invention is directed to methods of inducing an immune response in a mammal comprising administering said bioconjugate vaccines.

Recombinant bacteria capable of producing and secreting therapeutically active EGF, pharmaceutical compositions thereof, and methods of treating disorders are disclosed.

The present invention is directed generally to host cells with artificial endosymbionts, wherein the artificial endosymbiont and the host cell communicate with each other to alter a phenotype of the host cell. In some embodiments, the communication comprises the secretion of a polypeptide from the artificial endosymbiont into the host cell. The secreted polypeptide can be a selectable marker, a reporter protein, a transcription factor, a signal pathway protein, a receptor, a growth factor, a cytokine, an effector molecule or other factors that can produce a phenotype in the host cell.

The present invention is a DNA expression vector comprising: a toxP; a mutant toxO that blocks Fe-mediated regulation of gene expression; and a DNA sequence encoding a protein, wherein the toxP and the mutant toxO regulate expression of the DNA segment encoding the protein. It is preferred that DNA expression vectors of the present invention include DNA sequences encoding a signal peptide so that a protein expressed is attached to the signal peptide prior to processing. Novel proteins are produced off of the DNA expression vector of the present invention.

The present invention is directed generally to host cells with artificial endosymbionts, wherein the artificial endosymbiont and the host cell communicate with each other to alter a phenotype of the host cell. In some embodiments, the communication comprises the secretion of a polypeptide from the artificial endosymbiont into the host cell. The secreted polypeptide can be a selectable marker, a reporter protein, a transcription factor, a signal pathway protein, a receptor, a growth factor, a cytokine, an effector molecule or other factors that can produce a phenotype in the host cell.

In alternative embodiments, provided are non-natural or genetically engineered vinylisomerase-dehydratase enzymes, including alkenol dehydratases, linalool dehydratases and crotyl alcohol dehydratases. In alternative embodiments, provided are non-natural or genetically engineered polypeptides having an activity comprising, for example, a vinylisomerase-dehydratase, an alkenol dehydratase, a linalool dehydratase and/or a crotyl alcohol dehydratase activity, or a combination thereof. In alternative embodiments, also provided are non-natural or genetically engineered nucleic acids (polynucleotides) encoding polypeptides described herein, expression or cloning vehicles comprising or having contained therein nucleic acids as described herein, and non-natural or genetically engineered cells comprising or having contained therein nucleic acids as described herein. In alternative embodiments, also provided are methods for making various organic compounds, including methyl vinyl carbinol and butadiene.

The present invention is directed to a bioconjugate vaccine, such as an O 1-bioconjugate vaccine, comprising: a protein carrier comprising a protein carrier containing at least one consensus sequence, DIE-X-N-Z-S/T, wherein X and Z may be any natural amino acid except proline; at least one antigenic polysaccharide from at least one pathogenic bacterium, linked to the protein carrier; and, optionally, an adjuvant. In another aspect, the present invention is directed to a method of producing an O 1-bioconjugate in a bioreactor comprising a number steps.

The present invention resides in the discovery that the specific interaction between Myeloid Differentiation factor 2 (MD2) and integrin, especially integrin ?v?3, is involved in cellular signaling mediated by MD2-integrin, such as inflammatory response including sepsis. Thus, this invention provides for a novel method for inhibiting integrin signaling by using an inhibitor of MD2-integrin binding, such as a dominant negative mutant of MD2 without integrin-binding capability. A method for identifying inhibitors of MD2-integrin binding is also described. Further disclosed are polypeptides, nucleic acids, host cells, and corresponding compositions for inhibiting MD2-integrin signaling.

A method for producing a fibroin-like protein is provided. A fibroin-like protein is produced by a method of culturing Escherichia coli having a gene encoding the fibroin-like protein in a medium, inducing expression of the gene encoding the fibroin-like protein, and collecting the fibroin-like protein, wherein accumulation of an organic acid at the time of inducing the expression is reduced, and wherein the gene is expressed under control of a tryptophan promoter.