Experimental and Computational Studies on Domain-Swapped Structure Stabilization of an Antibody Light Chain by Disulfide Bond Introduction.

Development of different platforms would be useful for designing functional antibodies to improve the efficiency of antibody-based drugs. Three-dimensional domain swapping (3D-DS) may occur in the variable region of antibody light chain #4C214A, and a pair of domain-swapped dimers may interact with each other to form a tetramer. In this study, to stabilize the 3D-DS dimer structure in #4C214A, Val2 in strand A (swapping region) and Thr97 in strand G were replaced with Cys residues, generating #4 V2C/T97C/C214A with a Cys2-Cys97 disulfide bond that cross-links strands A and G of different protomers.

Enzymatization of mouse monoclonal antibodies to the corresponding catalytic antibodies.

Catalytic antibodies possess a dual function that enables both antigen recognition and degradation. However, their time-consuming preparation is a significant drawback. This study developed a new method for quickly converting mice monoclonal antibodies into catalytic antibodies using site-directed mutagenesis.

Structural and thermodynamic insights into antibody light chain tetramer formation through 3D domain swapping.

Overexpression of antibody light chains in small plasma cell clones can lead to misfolding and aggregation. On the other hand, the formation of amyloid fibrils from antibody light chains is related to amyloidosis. Although aggregation of antibody light chain is an important issue, atomic-level structural examinations of antibody light chain aggregates are sparse.

Direct conversion of a general antibody to its catalytic antibody and corresponding applications -Importance and role of Pro95 in CDR-3.

Catalytic antibodies possess unique features capable of both recognizing and enzymatically degrading antigens. Therefore, they are more beneficial than monoclonal antibodies (mAbs). Catalytic antibodies exhibit the ability to degrade peptides, antigenic proteins, DNA, and physiologically active molecules.

Obtaining Highly Active Catalytic Antibodies Capable of Enzymatically Cleaving Antigens.

A catalytic antibody has multiple functions compared with a monoclonal antibody because it possesses unique features to digest antigens enzymatically. Therefore, many catalytic antibodies, including their subunits, have been produced since 1989. The catalytic activities often depend on the preparation methods and conditions.

A new catalytic site functioning in antigen cleavage by H34 catalytic antibody light chain.

The cleavage reactions of catalytic antibodies are mediated by a serine protease mechanism involving a catalytic triad composed of His, Ser, and Asp residues, which reside in the variable region. Recently, we discovered a catalytic antibody, H34 wild type (H34wt), that is capable of enzymatically cleaving an immune-check point PD-1 peptide and recombinant PD-1; however, H34wt does not contain His residues in the variable region. To clarify the reason behind the catalytic features of H34wt and the amino acid residues involved in the catalytic reaction, we performed site-directed mutagenesis focusing on the amino acid residues involved in the cleavage reaction, followed by catalytic activity tests, immunological reactivity evaluation, and molecular modeling.

Finding and characterizing a catalytic antibody light chain, H34, capable of degrading the PD-1 molecule.

Programmed cell death 1 (PD-1) is an immune checkpoint molecule regulating T-cell function. Preventing PD-1 binding to its ligand PD-L1 has emerged as an important tool in immunotherapy. Here, we describe a unique human catalytic antibody light chain, H34, which mediates enzymatic degradation of human PD-1 peptides and recombinant human PD-1 protein and thus functions to prevent the binding of PD-1 with PD-L1.

A new algorithm to convert a normal antibody into the corresponding catalytic antibody.

Over thousands of monoclonal antibodies (mAbs) have been produced so far, and it would be valuable if these mAbs could be directly converted into catalytic antibodies. We have designed a system to realize the above concept by deleting Pro, a highly conserved residue in CDR-3 of the antibody light chain. The deletion of Pro is a key contributor to catalytic function of the light chain.

Decomposition of amyloid fibrils by NIR-active upconversion nanoparticles.

We demonstrate amyloid fibril (AF) decomposition induced by NIR-active upconversion nanoparticles complexed with photosensitisers. The process is triggered by upconversion, which initiates a photochemical reaction cascade that culminates in the generation of the highly reactive singlet-oxygen product 1O2 close to the amyloid superstructures, resulting in AF decomposition.

Role of the constant region domain in the structural diversity of human antibody light chains.

Issues regarding the structural diversity (heterogeneity) of an antibody molecule have been the subject of discussion along with the development of antibody drugs. Research on heterogeneity has been extensive in recent years, but no clear solution has been reached. Heterogeneity is also observed in catalytic antibody κ light chains (CLs).

Detection of influenza virus by a biosensor based on the method combining electrochemiluminescence on binary SAMs modified Au electrode with an immunoliposome encapsulating Ru (II) complex.

Recently, point of care testing (POCT) used for diagnosis of influenza infection has a problem showing false negative diagnosis because of the low sensitivity. We would like to report detection of influenza virus A (H1N1) by an immunosensor based on electrochemiluminescence (ECL) that uses an immunoliposome encapsulating tris(2,2'-bipyridyl)ruthenium(II) complex. By using the sensor, we could detect the virus that competed with hemagglutinin (HA) peptide immobilized on self-assembled monolayers (SAMs) in immunoreaction of the antibody bound on the surface of liposome.

A novel method of preparing the monoform structure of catalytic antibody light chain.

Along with the development of antibody drugs and catalytic antibodies, the structural diversity (heterogeneity) of antibodies has been given attention. For >20 yr, detailed studies on the subject have not been conducted, because the phenomenon presents many difficult and complex problems. Structural diversity provides some (or many) isoforms of an antibody distinguished by different charges, different molecular sizes, and modifications of amino acid residues.

Biochemical features and antiviral activity of a monomeric catalytic antibody light-chain 23D4 against influenza A virus.

Catalytic antibodies have exhibited interesting functions against some infectious viruses such as HIV, rabies virus, and influenza virus in vitro as well as in vivo. In some cases, a catalytic antibody light chain takes on several structures from the standpoint of molecular size (monomer, dimer, etc.) and/or isoelectronic point.

Biochemical features of a catalytic antibody light chain, 22F6, prepared from human lymphocytes.

Human antibody light chains belonging to subgroup II of germ line genes were amplified by a seminested PCR technique using B-lymphocytes taken from a human adult infected with influenza virus. Each gene of the human light chains was transferred into the Escherichia coli system. The recovered light chain was highly purified using a two-step purification system.

Highly efficient method of preparing human catalytic antibody light chains and their biological characteristics.

The ultimate goal of catalytic antibody research is to develop new patient therapies that use the advantages offered by human catalytic antibodies. The establishment of a high-throughput method for obtaining valuable candidate catalytic antibodies must be accelerated to achieve this objective. In this study, based on our concept that we can find antibody light chains with a high probability of success if they include a serine protease-like catalytic triad composed of Ser, His, and Asp on a variable region of the antibody structure, we amplified and cloned DNAs encoding human antibody light chains from germline genes of subgroup II by seminested PCR using two primer sets designed for this purpose.

Catalytic and biochemical features of a monoclonal antibody heavy chain, JN1-2, raised against a synthetic peptide with a hemagglutinin molecule of influenza virus.

It has long been an important issue to produce a catalytic antibody that possesses the ability to lose the infectivity of a bacteria or virus. The monoclonal antibody JN1-2 was generated using a synthetic peptide (TGLRNGITNKVNSVIEKAA) conjugated with human IgG. The peptide sequence includes the conserved region of the hemagglutinin molecule (HA(1) and HA(2) domains), which locates on the envelope of the influenza virus and plays an important role in influenza A virus infection.

Catalytic digestion of human tumor necrosis factor-α by antibody heavy chain.

It has long been an important task to prepare a catalytic antibody capable of digesting a targeting crucial protein that controls specific life functions. Tumor necrosis factor-α (TNF-α) is a cytokine and an important molecule concerned with autoimmune diseases such as rheumatoid arthritis, chronic obstructive pulmonary disease, and Crohn's disease. A mAb (ETNF-6 mAb) raised against human TNF-α was prepared, and the steric conformation was created by using molecular modeling after the cDNA was sequenced.

Characteristic features of InfA-15 monoclonal antibody recognizing H1, H3, and H5 subtypes of hemagglutinin of influenza virus A type.

Hemagglutinin molecule is an envelope protein of influenza virus and plays an important role in the infection to human cells. Many mutations are observed in the molecule, which generates sixteen subtypes (H1-H16) of the hemagglutinin molecule for influenza virus A type. The subtypes such as H1, H2, H3, and H5 out of the sixteen are underlined molecules, which are responsible to Spain, Asia, Hong Kong, and Avian Flu, respectively.

Attomole detection of hemagglutinin molecule of influenza virus by combining an electrochemiluminescence sensor with an immunoliposome that encapsulates a Ru complex.

An immunoliposome (80 nm in diameter) encapsulating a Ru complex with two aminobutyl moieties was prepared to detect the presence of hemagglutinin molecules, which play an important role in influenza virus infection. The highly sensitive detection was accomplished by electrochemiluminescence (ECL) from the Ru complex adsorbed onto Au electrodes after competitive immunoreactions. This method clarified that the adsorption of the Ru complex onto the electrode was an important factor in obtaining high sensitivity.

Therapeutic effects of molecularly designed antigen UREB138 for mice infected with Helicobacter pylori.

Helicobacter pylori (H. pylori) is a bacteria that is well known as the principal cause of chronic gastritis and peptic ulcer disease in humans. Because no effective vaccine has yet been established, we designed a new biomolecule as a vaccination antigen capable of preventing the infection of H.

Catalytic features and eradication ability of antibody light-chain UA15-L against Helicobacter pylori.

We have successfully developed a catalytic antibody capable of degrading the active site of the urease of Helicobacter pylori and eradicating the bacterial infection in a mouse stomach. This monoclonal antibody UA15 was generated using a designed recombinant protein UreB, which contained the crucial region of the H. pylori urease beta-subunit active site, for immunization.

Effects of vaccination by a recombinant antigen ureB138 (a segment of the beta-subunit of urease) against Helicobacter pylori infection.

Helicobacter pylori has to counteract acidity during colonization in the stomach. The most important region for the enzymic activity of H. pylori urease, consisting of 138 aa (ureB138), was determined by a comparison of the homology of amino acid sequences, and a structural analysis, between urease of H.

Pathogenicity of catalytic antibodies: catalytic activity of Bence Jones proteins from myeloma patients with renal impairment can elicit cytotoxic effects.

Some Bence Jones proteins (BJPs) can display catalytic activity. Although the catalytic activity of BJPs might be associated with the pathogenesis of disease, this relationship has not yet been established. We tested the effects of seven BJPs on LLC-PK1 cells to assess their pathogenicity.