Masamichi Koike

Establishment of humanized anti-interleukin-5 receptor alpha chain monoclonal antibodies having a potent neutralizing activity

Human interleukin-5 is the key cytokine involved in regulating the production and function of human eosinophils. IL-5 binds to its specific receptor composed of two heterogeneous alpha and beta polypeptide chains (hIL-5Ralpha and betac) that are expressed on the cell surface. The hIL-5Ralpha specifically binds IL-5 without involvement of the betac. It has been suggested that neutralizing antibodies to hIL-5Ralpha could serve as a therapeutic agent in eosinophil-associated diseases. We describe here the creation and biologic activities of a mouse monoclonal antibody against hIL-5Ralpha that blocks the following IL-5 dependent activities (a) binding of the IL-5 ligand to its receptor, (b) IL-5 dependent growth of hIL-5R expressing cells, and (c) IL-5-induced adhesion of human eosinophils. We also describe the process for humanization of the mouse Mab towards development of a therapeutic MAb. The humanized version of the monoclonal antibody also displayed potent neutralizing activity against IL-5 dependent activities.

Immunoglobulin class switch of anti-ganglioside monoclonal antibody from IgM to IgG.

Ganglioside GM2, which is one of the major gangliosides expressed on cell surface of neuroectodermal-origin human tumors, has been focused on as a target molecule for passive immunotherapy. One of the problems in this area was that monoclonal antibodies (mAbs) raised against GM2 were of IgM class even if donors of B cells were varied in mouse, rat or human. We stimulated two kinds of mice hybridomas having membrane-bound anti-GM2 IgM on their surface with GM2 incorporated in synthetic liposomes in the presence of the mouse thymocytes to accelerate the class switch of immunoglobulins (Igs). After the stimulation, protein A-reactive clones were sorted out using a cell sorter. We finally isolated two class switch variants generating mouse IgG3, designated KM796 and KM750, from original hybridomas producing mouse IgM anti-GM2 mAbs, KM696 and KM697, respectively after over 20-time repetitions of the sorting. ELISA with 11 common gangliosides revealed that one of the variant, KM750, retained the same binding specificity to N-acetyl GM2 as that of the parental IgM, KM697. By ELISA using panel of anti-idiotype (Id) mAbs to anti-GM2 mAbs, KM750 was shown to retain the parental KM697 Id. Another variant KM796 almost lost its activity in purification process in acidic condition and changes in Id were suggested. In immunofluorescence assay, KM750 was confirmed to bind to GM2-expressing tumor cell lines. The class switch hybridoma has been stably cultured with the production of the IgG3-class mAb for more than 22 months.

Allergic diseases: From bench to clinic - Contribution of the discovery of interleukin-5

T helper 2 cells produce a number of cytokines including inteleukin (IL)-5, IL-4 and IL-13. Group 2 innate lymphoid cells (ILC2s) also produce IL-5 under sterile conditions. IL-5 is interdigitating homodimeric glycoprotein and a member of the four α helical bundle motifs conserved among hematopoietic cytokines. IL-5 exerts its effects on target cells via IL-5 receptor (IL-5R), composed of an IL-5R α and βc subunit. The membrane proximal proline-rich motif of the cytoplasmic domain of both IL-5R α and βc subunits is essential for IL-5 signal transduction. Although IL-5 was initially identified by its ability to support the growth and terminal differentiation of mouse B cells into antibody-secreting cells, recombinant IL-5 exerts pleiotropic activities on various target cells. For example, IL-5 is now recognized as the major maturation and differentiation factor for eosinophils in mice and humans. Overexpression of IL-5 in mouse significantly increases eosinophil numbers and antibody levels in vivo, while mice lacking a functional gene for IL-5 or IL-5R display developmental and functional impairments in B cell and eosinophil lineages. In mice, the role of the IL-5/IL-5R system in the production and secretion of Immunoglobulin (Ig) M and IgA in mucosal tissues has been reported. Although eosinophils protect against invading pathogens including virus, bacteria and helminthes, they are also involved in the pathogenesis of various diseases, such as food allergy, asthma, and inflammatory bowel diseases. The recent expansion in our understanding in the context of IL-5 and IL-5-producing ILC2s in eosinophil activation and the pathogenesis of eosinophil-dependent inflammatory diseases has led to advances in therapeutic options. A new therapy currently under invetigarion in clinical trials uses humanized monoclonal antibodies against IL-5 or the IL-5R. In this review, we summarize our current understanding of the functions of IL-5 and its receptor, the innate regulation of IL-5-producing cells, and therapeutic potential of anti-IL-5 and anti-eosinophil (IL-5R) antibodies.

Enhancement of antibody production by the addition of Coenzyme-Q10

Recently, there has been a growing demand for therapeutic monoclonal antibodies (MAbs) on the global market. Because therapeutic MAbs are more expensive than low-molecular-weight drugs, there have been strong demands to lower their production costs. Therefore, efficient methods to minimize the cost of goods are currently active areas of research. We have screened several enhancers of specific MAb production rate (SPR) using a YB2/0 cell line and found that coenzyme-Q10 (CoQ10) is a promising enhancer candidate. CoQ10 is well known as a strong antioxidant in the respiratory chain and is used for healthcare and other applications. Because CoQ10 is negligibly water soluble, most studies are limited by low concentrations. We added CoQ10 to a culture medium as dispersed nanoparticles at several concentrations (Q-Media) and conducted a fed-batch culture. Although the Q-Media had no effect on cumulative viable cell density, it enhanced SPR by 29%. In addition, the Q-Media had no effect on the binding or cytotoxic activity of MAbs. Q-Media also enhanced SPR with CHO and NS0 cell lines by 30%. These observations suggest that CoQ10 serves as a powerful aid in the production of MAbs by enhancing SPR without changing the characteristics of cell growth, or adversely affecting the quality or biological activity of MAbs.

Controlling Fucosylation Levels of Antibodies with Osmolality During Cell Culture in Several Host Cell Lines

Since a cost of therapeutic Monoclonal antibodies (MAbs) is much higher than other compounds, it is critical to produce high-efficacy MAbs efficiently. One method is to increase the effectiveness of a MAb, which in turn affects antibody-dependent cellular cytotoxicity (ADCC) is related defucosylation level (deFuc%) of MAbs. Since deFuc% of MAbs must be regulated for their quality control, it leads to careful consideration of the type of host cell employed. Thus, it is quite important to grasp the effects of culture conditions on the deFuc% in each cell line for the launched on the market and development, except for like a Chinese hamster ovary cells (CHOs) with α-1,6-fucosyltransferase gene knock out (PotelligentTM, BioWa, USA). For the MAbs produced in a rat myeloma cells (YB2/0), we found that osmolality of the culture medium is the major determinant of the deFuc%. In addition, deFuc% was not affected by the type of osmolytes (NaCl, KCl, fucose, fructose, and mannitol). We succeeded in controlling the deFuc% of MAbs arbitrarily 45–85% by maintaining medium osmolality during cultures (perfusion and fed-batch). We found the same correlation between the deFuc% and the culture osmolality in NS0 and SP2/0 cells as the in the YB2/0 cells.