The invention is in the field of therapy of antibody deficiencies such as immune diseases and inflammatory disorders. The inventors demonstrate for the first time the convergence of intestinal IgA and serum IgG responses toward the same microbial targets, under homeostatic conditions. Private anti-microbiota IgG specificities are induced in IgA-deficient patients, but are not found in IgG pools from healthy donors, partially explaining why substitutive IgG (IVIG) cannot regulate antibody deficiency-associated gut dysbiosis and intestinal translocation. Finally, in both controls and IgA-deficient patients, systemic anti-microbiota IgG responses correlate with reduced inflammation suggesting that systemic IgG responses contribute to the gut microbiota confinement. Accordingly, the invention relates to IVIGs (Intravenous immunoglobulins) composition containing at least 1% of immunoglobulins (Ig) from SIgAd (Selective IgA deficiency) patient and their use in the treatment of antibody deficiency disorders such as immune diseases, inflammatory disorders and autoimmune disease.

The invention is in the field of therapy of antibody deficiencies such as immune diseases and inflammatory disorders. The inventors demonstrate for the first time the convergence of intestinal IgA and serum IgG responses toward the same microbial targets, under homeostatic conditions. Private anti-microbiota IgG specificities are induced in IgA-deficient patients, but are not found in IgG pools from healthy donors, partially explaining why substitutive IgG (IVIG) cannot regulate antibody deficiency-associated gut dysbiosis and intestinal translocation. Finally, in both controls and IgA-deficient patients, systemic anti-microbiota IgG responses correlate with reduced inflammation suggesting that systemic IgG responses contribute to the gut microbiota confinement. Accordingly, the invention relates to IVIGs (Intravenous immunoglobulins) composition containing at least 1% of immunoglobulins (Ig) from SIgAd (Selective IgA deficiency) patient and their use in the treatment of antibody deficiency disorders such as immune diseases, inflammatory disorders and autoimmune disease.

The invention provides methods for using and compositions of humanized antibodies that bind tau protein that is phosphorylated at the serine at position 413.

Disclosed herein are methods for improving a parameter of a protein-related process comprising providing a viscosity-reducing excipient compound selected from the group consisting of hindered amines, aromatics and anionic aromatics, functionalized amino acids, oligopeptides, short-chain organic acids, low molecular weight aliphatic polyacids, diones and sulfones, zwitterionic excipients, and crowding agents with hydrogen bonding elements, and adding a viscosity-reducing amount of the viscosity-reducing excipient compound to a carrier solution for the protein-related process, wherein the carrier solution contains a protein of interest, and carrier solutions comprising a liquid medium in which is dissolved a protein of interest, and a viscosity-reducing excipient, wherein the viscosity of the carrier solution has a lower viscosity that that of a control solution that is substantially similar to the carrier solution except for the presence of the viscosity-reducing excipient.

The present disclosure relates to methods of modifying the isoelectric point of an antibody. The method includes providing an antibody comprising a first polypeptide comprising a heavy chain variable region and a second polypeptide comprising heavy chain variable region and substituting, in at least one of the first and second polypeptides of the antibody, one or more amino acid residues of the heavy chain variable region (V.sub.H) at positions 7, 9, 11, 14, 41, 70, 74, 82a, 84, and 113, according to the Kabat numbering system, wherein the substituting increases or decreases the isoelectric point of the antibody.

The present invention relates method for purifying antibodies, said method comprising a limited number of steps while still allowing obtaining high yields of purified antibodies with an appropriate degree of purity. Briefly, this method comprises only filtration and precipitation steps, omitting the need for chromatography steps.

Disclosed is a calibrator comprising IgA having a biotin group and a biotin-binding site, the calibrator being used to obtain a concentration of an IgA aggregate in a sample.

The present invention provides a compound for the sequestration of undesirable antibodies (e.g. related to an autoimmune disease) in a patient. The compound comprises an inert biopolymer scaffold and at least a first peptide n-mer of the general formula P(-S-P).sub.(n-1) and a second peptide n-mer of the general formula P(-S-P).sub.(n-1); wherein, independently for each occurrence, P is a peptide with a sequence length of 2-13 amino acids and S is a non-peptide spacer, wherein, independently for each of the peptide n-mers, n is an integer of at least 1, wherein each of the peptide n-mers is bound to the biopolymer scaffold. Also provided are pharmaceutical compositions comprising the compound, as well as a method of sequestering one or more antibodies present in an individual and a method of inhibiting an immune reaction to a treatment with an active agent.

Methods are provided for isolation of immunoglobulin G (IgG) from plasma, where IgG is initially fractioned by salt precipitation, followed by successive ion exchange steps in which IgG appears in unbound, flow-through fractions of the ion exchange steps. Some embodiments employ successive anion exchange steps. Other embodiments employ an anion exchange step followed by application of flow-through of the anion exchange step to a cation exchange step, with IgG collected in flow-through fractions from the cation exchange step. IgG is collected at high yield (typically about 75% or greater) and high purity. Avoidance of binding and elution from chromatography media simplifies processing and scale up without sacrificing IgG quality or yield.

Processes and methods of purifying or separating Single Domain Antigen Binding (SDAB) molecules that include one or more single binding domains (e.g., one or more nanobody molecules), substantially devoid of a complementary antibody domain and an immunoglobulin constant region, using Protein A-based affinity chromatography, are disclosed.