Abstract: Herein is reported a method for producing a bispecific antibody comprising the step of incubating (i) an antibody Fab fragment or a scFv antibody comprising within the 20 C-terminal amino acid residues the amino acid sequence LPX1TG (SEQ ID NO: 01), (ii) a one-armed antibody comprising a full length antibody heavy chain, a full length antibody light chain, and an Fc-heavy chain, whereby the full length antibody heavy chain and the full length antibody light chain are cognate antibody chains that thereof forms an antigen binding site, whereby the full length antibody heavy chain and the Fc-heavy chain are covalently linked to each other via one or more disulfide bonds forming an antibody hinge region, and whereby the Fc-heavy chain has an oligoglycine amino acid sequence at its N-terminus, and (iii) a Sortase A enzyme.

Abstract: The present invention relates to bispecific antibodies, methods for their production, pharmaceutical compositions containing said antibodies, and uses thereof.

Abstract: Herein is reported a method for recombinantly producing a polypeptide in a cell comprising the step of cultivating a cell which comprises a nucleic acid encoding the polypeptide, and recovering the polypeptide from the cell or the cultivation medium, wherein each of the amino acid residues of the polypeptide is encoded by at least one codon, whereby the different codons encoding the same amino acid residue are combined in one group and each of the codons in a group is defined by a specific usage frequency within the group, whereby the sum of the specific usage frequencies of all codons in one group is 100%, and wherein the usage frequency of a codon in the polypeptide encoding nucleic acid is about the same as its specific usage frequency within its group.

Abstract: The current invention reports a promoter having the nucleic acid sequence of SEQ ID NO: 02, or SEQ ID NO: 03, or SEQ ID NO: 04, or SEQ ID NO: 06, which is a 5? shortened SV40 promoter with reduced promoter strength especially useful for the limited expression of heterologous polypeptides or selectable markers.

Abstract: Herein is reported a method for the detection of a sortase in a sample, comprising the following steps: a) incubating the sample with a first substrate comprising an immobilization tag and a second substrate comprising a detectable label, whereby in the presence of a sortase in the sample a conjugate comprising the immobilization tag and the detectable label is formed, b) immobilizing the conjugate of step a) via/using the immobilization tag to a solid phase, c) detecting the immobilized conjugate via/using the detectable label and thereby detecting the sortase in the sample.

Abstract: Herein is reported a method for producing an enzymatic conjugation product of three polypeptides comprising the simultaneous incubation of i) a first polypeptide comprising the amino acid sequence LPXTG (SEQ ID NO: 20, wherein X can be any amino acid residue), a second polypeptide comprising the amino acid sequence LPXTA (SEQ ID NO: 31, wherein X can be any amino acid residue), a third polypeptide that has two N-termini whereby the polypeptide has an oligo-glycine Gm (m=2 (SEQ ID NO: 22), or 3 (SEQ ID NO: 23), or 4 (SEQ ID NO: 24), or 5 (SEQ ID NO: 25)) amino acid sequence at its first N-terminus and an oligo-alanine Am (m=2 (SEQ ID NO: 26), or 3 (SEQ ID NO: 27), or 4 (SEQ ID NO: 28), or 5 (SEQ ID NO: 29)) amino acid sequence at its second N-terminus, a fourth polypeptide with sortase activity whereby the polypeptide is derived from Staphylococcus aureus sortase A, and a fifth polypeptide with sortase activity whereby the polypeptide is derived from Streptococcus pyogenes sortase A and the recovering of the c

Abstract: In the method as reported herein the isolation of nucleic acid segments encoding antibody variable domains and the insertion of the isolated nucleic acid segments in eukaryotic expression plasmids is performed without the intermediate isolation and analysis of clonal intermediate plasmids. Thus, in the method as reported herein the intermediate cloning, isolation and analysis of intermediate plasmids is not required, e.g. by analysis of isolated transformed E. coli cells.

Abstract: Herein is reported a fusion polypeptide comprising i) at least one binding site, e.g. which comprises an antibody heavy chain variable domain and an antibody light chain variable domain, and which binds to an internalizing cell surface receptor, and ii) at least one pharmaceutically active compound, whereby the EC50-value of the binding pair that binds to an internalizing cell surface receptor determined at pH 5.5 is higher than the EC50-value of the same binding pair determined at pH 7.4 and its use for delivering a pharmaceutically active compound across the blood-brain-barrier.

Abstract: The current invention reports a method for the recombinant production of a secreted heterologous immunoglobulin in a CHO cell comprising the following steps: i) providing a CHO cell, which is adapted to growth in suspension culture, adapted to growth in serum-free medium, mycoplasma free, and virus free, ii) providing a vector comprising a prokaryotic origin of replication, a first nucleic add conferring resistance to a prokaryotic selection agent, a second nucleic acid encoding the heavy chain of said heterologous immunoglobulin, a third nucleic acid encoding the light chain of said heterologous immunoglobulin, a fourth nucleic acid conferring resistance to a eukaryotic selection agent, iii) transfecting said CHO cell, wherein said transfecting comprises a) transfecting said CHO cell with said vector comprising a fourth nucleic acid conferring resistance to a first eukaryotic selection agent, h) selecting a CHO cell by growth in cultivation medium containing said first eukaryotic selection agent, c) transfec

Abstract: Herein is reported a method for producing a fusion-polypeptide comprising the steps of a) cultivating a mammalian cell comprising a nucleic acid encoding a variant fusion-polypeptide wherein the amino acid sequence of the fusion-polypeptide has been modified by replacing in a pro-fusion-polypeptide the endogenous protease cleavage site between the pro-peptide and the fusion-polypeptide with an exogenous (with respect to the origins of the parts of the fusion-polypeptide) or artificial protease cleavage site, and b) recovering the fusion-polypeptide or fusion-pro-polypeptide from the cell or the cultivation medium and thereby producing the (recombinant) fusion-polypeptide.

Abstract: Herein is reported a method for the recombinant production of a polypeptide, which comprises the dipeptide AR, characterized in that the method comprises the recovering of the polypeptide from the cells or the cultivation medium of a cultivation of a cell comprising a nucleic acid encoding the polypeptide and thereby producing the polypeptide, whereby the dipeptide AR comprised in the polypeptide is encoded by the oligonucleotide gca cgt, or the oligonucleotide gcg cgt, or the oligonucleotide gcc cgt.

Abstract: The current invention reports a method for the recombinant production of a secreted heterologous immunoglobulin in a CHO cell comprising the following steps: i) providing a CHO cell, which is adapted to growth in suspension culture, adapted to growth in serum-free medium, mycoplasma free, and virus free, ii) providing a vector comprising a prokaryotic origin of replication, a first nucleic acid conferring resistance to a prokaryotic selection agent, a second nucleic acid encoding the heavy chain of said heterologous immunoglobulin, a third nucleic acid encoding the light chain of said heterologous immunoglobulin, a fourth nucleic acid conferring resistance to a eukaryotic selection agent, iii) transfecting said CHO cell, wherein said transfecting comprises a) transfecting said CHO cell with said vector comprising a fourth nucleic acid conferring resistance to a first eukaryotic selection agent, b) selecting a CHO cell by growth in cultivation medium containing said first eukaryotic selection agent, c) transfe

Abstract: The current invention comprises a fusion polypeptide comprising a serpin-finger polypeptide conjugated to a biologically active polypeptide optionally via a peptidic linker polypeptide. Another aspect is a protein complex of the serpin-finger fusion polypeptide and a serpin, wherein the fusion polypeptide is incorporated in the serpin into the middle of beta-sheet A as strand 4a. Also an aspect of the current invention is the in vitro preparation of the protein complex. The serpin-finger polypeptide targets and anchors the biologically active polypeptide with high affinity and functional spatial orientation.

Abstract: The present invention relates to multispecific, especially bispecific antibodies comprising full length antibodies and single chain Fab fragments, methods for their production, pharmaceutical compositions containing the antibodies, and uses thereof.

Abstract: The current invention reports a promoter having the nucleic acid sequence of SEQ ID NO: 02, or SEQ ID NO: 03, or SEQ ID NO: 04, or SEQ ID NO: 06, which is a 5? shortened SV40 promoter with reduced promoter strength especially useful for the limited expression of heterologous polypeptides or selectable markers.

Abstract: Herein is reported a method for producing a polypeptide in a prokaryotic cell, comprising the step of cultivating a prokaryotic cell comprising one or more nucleic acids encoding the polypeptide in a chemically defined minimal growth medium and recovering the polypeptide from the prokaryotic cell or the periplasm of the prokaryotic cell or from the medium, wherein the prokaryotic cell is an amino acid auxotrophy cured prokaryotic cell, wherein growth of the amino acid auxotrophy cured prokaryotic cell compared to the non-cured prokaryotic cell under the same cultivation conditions and in the same growth medium requires the supplementation of fewer amino acids to the growth medium, and wherein the chemically defined minimal growth medium is free of the amino acid corresponding to the auxotrophy that has been cured in the auxotrophy cured prokaryotic cell.

Abstract: Herein is reported a method for recombinantly producing a polypeptide in a cell comprising the step of cultivating a cell which comprises a nucleic acid encoding the polypeptide, and recovering the polypeptide from the cell or the cultivation medium, wherein each of the amino acid residues of the polypeptide is encoded by at least one codon, whereby the different codons encoding the same amino acid residue are combined in one group and each of the codons in a group is defined by a specific usage frequency within the group, whereby the sum of the specific usage frequencies of all codons in one group is 100%, and wherein the usage frequency of a codon in the polypeptide encoding nucleic acid is about the same as its specific usage frequency within its group.

Abstract: Herein is reported a method for producing a bispecific antibody comprising the step of incubating (i) an antibody Fab fragment or a scFv antibody comprising within the 20 C-terminal amino acid residues the amino acid sequence LPX1TG (SEQ ID NO: 01), (ii) a one-armed antibody comprising a full length antibody heavy chain, a full length antibody light chain, and an Fc-heavy chain, whereby the full length antibody heavy chain and the full length antibody light chain are cognate antibody chains that thereof forms an antigen binding site, whereby the full length antibody heavy chain and the Fc-heavy chain are covalently linked to each other via one or more disulfide bonds forming an antibody hinge region, and whereby the Fc-heavy chain has an oligoglycine amino acid sequence at its N-terminus, and (iii) a Sortase A enzyme.

Abstract: Herein is reported a method for producing an antibody Fc-region conjugate comprising as first component an antibody Fc-region and as second component at least one binding entity that specifically binds to a target using a transpeptidase for enzymatic conjugation of the antibody Fc-region to at least one binding entity.

Abstract: Herein is reported a method for determining a combination of antigen binding sites comprising the steps of (i) determining the binding specificity and/or affinity and/or effector function and/or in vivo half-life of a multitude of bispecific antibodies prepared by combining each member of a first multitude of antibody Fab fragments or scFv antibody fragments with each member of a second multitude of antibody Fab fragments or scFv antibody fragments, and a linker comprising at one of its termini the second member of the first binding pair and at the respective other terminus the second member of the second binding pair, whereby the first multitude specifically binds to a first cell surface molecule and the second multitude specifically binds to a second cell surface molecule, and (ii) choosing the bispecific antibody with suitable binding specificity and/or affinity and/or effector function and/or in vivo half-life and thereby determining a combination of antigen binding sites.