The present invention is directed to antibodies and fragments thereof and humanized versions thereof having binding specificity for IL-6. Another embodiment of this invention relates to the antibodies described herein, and binding fragments thereof, comprising the sequences of the V.sub.H, V.sub.L and CDR polypeptides described herein, and the polynucleotides encoding them. The invention also contemplates conjugates of anti-IL-6 antibodies and binding fragments thereof conjugated to one or more functional or detectable moieties. The invention also contemplates methods of making said anti-IL-6 antibodies and binding fragments thereof. Embodiments of the invention also pertain to the use of anti-IL-6 antibodies, and binding fragments thereof, for the diagnosis, assessment and treatment of diseases and disorders associated with IL-6. These antibodies may bind at least one of soluble IL-6, cell surface expressed IL-6, IL-6/IL-6R and/or prevent the association of IL-6 and IL-6R, the association of IL-6/IL-6R and gp130 and or the formation of IL-6/IL-6R/gp130 multimers and thereby inhibit a biological effect associated with any of the foregoing.

The present invention is directed to antibodies and fragments thereof and humanized versions thereof having binding specificity for IL-6. Another embodiment of this invention relates to the antibodies described herein, and binding fragments thereof, comprising the sequences of the V.sub.H, V.sub.L and CDR polypeptides described herein, and the polynucleotides encoding them. The invention also contemplates conjugates of anti-IL-6 antibodies and binding fragments thereof conjugated to one or more functional or detectable moieties. The invention also contemplates methods of making said anti-IL-6 antibodies and binding fragments thereof. Embodiments of the invention also pertain to the use of anti-IL-6 antibodies, and binding fragments thereof, for the diagnosis, assessment and treatment of diseases and disorders associated with IL-6. These antibodies may bind at least one of soluble IL-6, cell surface expressed IL-6, IL-6/IL-6R and/or prevent the association of IL-6 and IL-6R, the association of IL-6/IL-6R and gp130 and or the formation of IL-6/IL-6R/gp130 multimers and thereby inhibit a biological effect associated with any of the foregoing.

The present invention relates to a method for preparing a recombinant Phe-free or Phe-low protein, the method comprising using B. subtilis or B. licheniformis as an expression system and/or a recombinant host cell into which a nucleotide encoding a recombinant Phe-free or Phe-low protein has been inserted into the genome.

A vaccine is disclosed that promotes CD4+ T cell-independent host defense mechanisms to defend against infection by fungi such as Pneumocystis spp. The vaccine may be used to prevent or to treat fungal infections. The novel vaccine can provide protective immunity, even for immunocompromised individuals such as HIV patients having reduced levels of CD4+ T cells.

A vaccine is disclosed that promotes CD4+ T cell-independent host defense mechanisms to defend against infection by fungi such as Pneumocystis spp. The vaccine may be used to prevent or to treat fungal infections. The novel vaccine can provide protective immunity, even for immunocompromised individuals such as HIV patients having reduced levels of CD4+ T cells.

The present invention relates to a fusion protein, comprising the structure N-PCS.sup.Y-degSig.sub.N-M-PCS.sup.X-degSig.sub.C-C; wherein N represents the N-terminus; PCS.sup.Y and PCS.sup.X each represent a protease cleavage site (PCS), which differ from each other in at least one amino acid residue: degSig.sub.N represents a degradation signal which promotes degradation of the fusion protein in a host cell if PCS.sup.Y is cleaved by a protease such that the first amino acid of degSig.sub.N becomes the new N-terminus of the remaining fusion; M represents a cytoplasmic selection marker; and degSig.sub.C represents a second degradation signal which promotes degradation of the fusion protein in a host cell if PCS.sup.X is not cleaved by a protease; and C represents the C-terminus. Further provided is a nucleic acid construct, comprising a nucleic acid sequence coding for said fusion protein, a nucleic acid expression construct library, comprising a plurality of such nucleic acid expression constructs in diversified form, and methods using the fusion protein and nucleic acid constructs coding therefor. Finally, the present invention provides variants of bdSUMO and bdSENP1 which have been identified by the methods of the present disclosure, and which exhibit improved properties over existing orthogonal protease/protease cleavage site-pairs which are currently used with wild-type bdSUMO and wildtype bdSENP1.

The present invention relates to a fusion protein, comprising the structure N-PCS.sup.Y-degSig.sub.N-M-PCS.sup.X-degSig.sub.C-C; wherein N represents the N-terminus; PCS.sup.Y and PCS.sup.X each represent a protease cleavage site (PCS), which differ from each other in at least one amino acid residue: degSig.sub.N represents a degradation signal which promotes degradation of the fusion protein in a host cell if PCS.sup.Y is cleaved by a protease such that the first amino acid of degSig.sub.N becomes the new N-terminus of the remaining fusion; M represents a cytoplasmic selection marker; and degSig.sub.C represents a second degradation signal which promotes degradation of the fusion protein in a host cell if PCS.sup.X is not cleaved by a protease; and C represents the C-terminus. Further provided is a nucleic acid construct, comprising a nucleic acid sequence coding for said fusion protein, a nucleic acid expression construct library, comprising a plurality of such nucleic acid expression constructs in diversified form, and methods using the fusion protein and nucleic acid constructs coding therefor. Finally, the present invention provides variants of bdSUMO and bdSENP1 which have been identified by the methods of the present disclosure, and which exhibit improved properties over existing orthogonal protease/protease cleavage site-pairs which are currently used with wild-type bdSUMO and wildtype bdSENP1.

The present invention provides methods of reducing nonprocessed Factor VIII or a chimeric polypeptide comprising Factor VIII comprising co-transfecting in a host cell a polynucleotide encoding Factor VIII with a polynucleotide encoding a protein convertase, where the endogenous processing enzymes of the host cell are insufficient to convert all of the Factor VIII to its processed isoform; expressing a proprotein convertase from a second polynucleotide in the host cell; and reducing the nonprocessed Factor VIII by processing with said proprotein convertase.

The present invention provides methods of reducing nonprocessed Factor VIII or a chimeric polypeptide comprising Factor VIII comprising co-transfecting in a host cell a polynucleotide encoding Factor VIII with a polynucleotide encoding a protein convertase, where the endogenous processing enzymes of the host cell are insufficient to convert all of the Factor VIII to its processed isoform; expressing a proprotein convertase from a second polynucleotide in the host cell; and reducing the nonprocessed Factor VIII by processing with said proprotein convertase.

The present invention is directed to antibodies and fragments thereof and humanized versions thereof having binding specificity for IL-6. Another embodiment of this invention relates to the antibodies described herein, and binding fragments thereof, comprising the sequences of the V.sub.H, V.sub.L and CDR polypeptides described herein, and the polynucleotides encoding them. The invention also contemplates conjugates of anti-IL-6 antibodies and binding fragments thereof conjugated to one or more functional or detectable moieties. The invention also contemplates methods of making said anti-IL-6 antibodies and binding fragments thereof. Embodiments of the invention also pertain to the use of anti-IL-6 antibodies, and binding fragments thereof, for the diagnosis, assessment and treatment of diseases and disorders associated with IL-6. These antibodies may bind at least one of soluble IL-6, cell surface expressed IL-6, IL-6/IL-6R and/or prevent the association of IL-6 and IL-6R, the association of IL-6/IL-6R and gp130 and or the formation of IL-6/IL-6R/gp130 multimers and thereby inhibit a biological effect associated with any of the foregoing.