Impaired proliferation and migration of HUVEC and melanoma cells by human anti-FGF2 mAbs derived from a murine hybridoma by guided selection.

Disadvantages of using murine monoclonal antibodies (mAb) in human therapy, such as immunogenicity response, led to the development of technologies to transform murine antibodies into human antibodies. The murine anti-FGF2 3F12E7 mAb was proposed as a promising agent to treat metastatic melanoma tumors; once it blocks the FGF2, responsible for playing a role in tumor growth, angiogenesis, and metastasis. Considering the therapeutic potential of anti-FGF2 3F12E7 mAb and its limited use in humans due to its origin, we used this antibody as the template for a guided selection humanization technique to obtain human anti-FGF2 mAbs. Three Fab libraries (murine, hybrid, and human) were constructed for humanization. The libraries were phage-displayed, and the panning was performed against recombinant human FGF2 (rFGF2). The selected human variable light and heavy chains were cloned into AbVec vectors for full-length IgG expression into HEK293-F cells. Surface plasmon resonance analyses showed binding to rFGF2 of seven mAbs out of 20 expressed. Assays performed with these mAbs resulted in two that showed proliferation reduction and cell migration attenuation of HUVEC and SK-Mel-28 melanoma cells. In-silico analyses predicted that these two human anti-FGF2 mAbs interact with FGF2 at a similar patch of residues than the chimeric anti-FGF2 antibody, comprehending a region within the heparin-binding domains of FGF2, essential for its function. These results are comparable to those achieved by the murine anti-FGF2 3F12E7 mAb and showed success in the humanization process and selection of two human mAbs with the potential to inhibit undesirable FGF2 roles.

The guided selection humanization process enabled the production of 20 human mAbs anti-FGF2;Seven human anti-FGF2 mAbs showed binding to the rFGF2 antigen in the SPR binding assay;Two human anti-FGF2 mAbs inhibited the proliferation and migration of HUVEC and SK-Mel-28 cells and were predicted to contact the FGF2 at a similar patch of residues than the original mAb.

Impaired proliferation and migration of HUVEC and melanoma cells by human anti-FGF2 mAbs derived from a murine hybridoma by guided selection

Disadvantages of using murine monoclonal antibodies (mAb) in human therapy, such as immunogenicity response, led to the development of technologies to transform murine antibodies into human antibodies. The murine anti-FGF2 3F12E7 mAb was proposed as a promising agent to treat metastatic melanoma tumors; once it blocks the FGF2, responsible for playing a role in tumor growth, angiogenesis, and metastasis. Considering the therapeutic potential of anti-FGF2 3F12E7 mAb and its limited use in humans due to its origin, we used this antibody as the template for a guided selection humanization technique to obtain human anti-FGF2 mAbs. Three Fab libraries (murine, hybrid, and human) were constructed for humanization. The libraries were phage-displayed, and the panning was performed against recombinant human FGF2 (rFGF2). The selected human variable light and heavy chains were cloned into AbVec vectors for full-length IgG expression into HEK293-F cells. Surface plasmon resonance analyses showed binding to rFGF2 of seven mAbs out of 20 expressed. Assays performed with these mAbs resulted in two that showed proliferation reduction and cell migration attenuation of HUVEC and SK-Mel-28 melanoma cells. In-silico analyses predicted that these two human anti-FGF2 mAbs interact with FGF2 at a similar patch of residues than the chimeric anti-FGF2 antibody, comprehending a region within the heparin-binding domains of FGF2, essential for its function. These results are comparable to those achieved by the murine anti-FGF2 3F12E7 mAb and showed success in the humanization process and selection of two human mAbs with the potential to inhibit undesirable FGF2 roles.

A new CHO (Chinese hamster ovary)-derived cell line expressing anti-TNFα monoclonal antibody with biosimilar potential.

Tumor necrosis factor alpha (TNFα) is a pro-inflammatory cytokine that mediates the homeostasis of immune responses; its exacerbated production is associated with the pathogenesis of autoimmune and chronic inflammatory diseases. Anti-TNFα drugs have revolutionized the treatment of inflammatory conditions such as rheumatoid arthritis and Crohn's disease. Currently, a worldwide race is on stage for the production of biosimilars moved by patent expiration of monoclonal antibodies (mAbs), such as anti-TNFα adalimumab. Our goal was to develop the first stage of an adalimumab biosimilar candidate with potential for national production, through the generation of a productive and stable cell line and assess its functionality. The robotic system ClonePix was used for screening and isolation of colonies from transfected CHO-S stable pools plated in semisolid medium. Selected clones were expanded based on growth and productivity. Purified mAbs from different clones were tested for binding and functional activity. The binding affinity of the denominated adabut clones to TNFα and FcRγ did not differ statistically when compared to reference adalimumab. One functional activity assay demonstrated the antibody neutralization capacity of the cytotoxicity induced by TNFα in L929 murine fibroblasts. A second assay confirmed adabut as an antagonist of the TNFα activity by the inhibition of the cell adhesion molecule expression in HUVEC cultures. The binding and functional activity analyses performed with selected adabut clones in comparison to reference adalimumab represent an important status of "non-inferiority," part of the process required for a biosimilar development. We generated and selected high-quality adabut clones which mAbs may be further developed as the first in-house made Brazilian biosimilar, demonstrating a success case for our incipient biotechnology industry, or also modified as biobetters, thus representing an innovative strategy for the patients' welfare.

A new CHO (Chinese hamster ovary)-derived cell line expressing anti-TNFa monoclonal antibody with biosimilar potential

Tumor necrosis factor alpha (TNF alpha) is a pro-inflammatory cytokine that mediates the homeostasis of immune responses; its exacerbated production is associated with the pathogenesis of autoimmune and chronic inflammatory diseases. Anti-TNF alpha drugs have revolutionized the treatment of inflammatory conditions such as rheumatoid arthritis and Crohn's disease. Currently, a worldwide race is on stage for the production of biosimilars moved by patent expiration of monoclonal antibodies (mAbs), such as anti-TNF alpha adalimumab. Our goal was to develop the first stage of an adalimumab biosimilar candidate with potential for national production, through the generation of a productive and stable cell line and assess its functionality. The robotic system ClonePix was used for screening and isolation of colonies from transfected CHO-S stable pools plated in semisolid medium. Selected clones were expanded based on growth and productivity. Purified mAbs from different clones were tested for binding and functional activity. The binding affinity of the denominated adabut clones to TNF alpha and FcR gamma did not differ statistically when compared to reference adalimumab. One functional activity assay demonstrated the antibody neutralization capacity of the cytotoxicity induced by TNF alpha in L929 murine fibroblasts. A second assay confirmed adabut as an antagonist of the TNF alpha activity by the inhibition of the cell adhesion molecule expression in HUVEC cultures. The binding and functional activity analyses performed with selected adabut clones in comparison to reference adalimumab represent an important status of "non-inferiority," part of the process required for a biosimilar development. We generated and selected high-quality adabut clones which mAbs may be further developed as the first in-house made Brazilian biosimilar, demonstrating a success case for our incipient biotechnology industry, or also modified as biobetters, thus representing an innovative strategy for the patients' welfare.

A new CHO (Chinese hamster ovary)-derived cell line expressing anti-TNFa monoclonal antibody with biosimilar potential

Tumor necrosis factor alpha (TNF alpha) is a pro-inflammatory cytokine that mediates the homeostasis of immune responses; its exacerbated production is associated with the pathogenesis of autoimmune and chronic inflammatory diseases. Anti-TNF alpha drugs have revolutionized the treatment of inflammatory conditions such as rheumatoid arthritis and Crohn's disease. Currently, a worldwide race is on stage for the production of biosimilars moved by patent expiration of monoclonal antibodies (mAbs), such as anti-TNF alpha adalimumab. Our goal was to develop the first stage of an adalimumab biosimilar candidate with potential for national production, through the generation of a productive and stable cell line and assess its functionality. The robotic system ClonePix was used for screening and isolation of colonies from transfected CHO-S stable pools plated in semisolid medium. Selected clones were expanded based on growth and productivity. Purified mAbs from different clones were tested for binding and functional activity. The binding affinity of the denominated adabut clones to TNF alpha and FcR gamma did not differ statistically when compared to reference adalimumab. One functional activity assay demonstrated the antibody neutralization capacity of the cytotoxicity induced by TNF alpha in L929 murine fibroblasts. A second assay confirmed adabut as an antagonist of the TNF alpha activity by the inhibition of the cell adhesion molecule expression in HUVEC cultures. The binding and functional activity analyses performed with selected adabut clones in comparison to reference adalimumab represent an important status of "non-inferiority," part of the process required for a biosimilar development. We generated and selected high-quality adabut clones which mAbs may be further developed as the first in-house made Brazilian biosimilar, demonstrating a success case for our incipient biotechnology industry, or also modified as biobetters, thus representing an innovative strategy for the patients' welfare.

Comparison of humanized IgG and FvFc anti-CD3 monoclonal antibodies expressed in CHO cells.

Two humanized monoclonal antibody constructs bearing the same variable regions of an anti-CD3 monoclonal antibody, whole IgG and FvFc, were expressed in CHO cells. Random and site-specific integration were used resulting in similar expression levels. The transfectants were selected with appropriate selection agent, and the surviving cells were plated in semi-solid medium for capture with FITC-conjugated anti-human IG antibody and picked with the robotic ClonePix FL. Conditioned media from selected clones were purified by affinity chromatography and characterized by SDS-PAGE, Western-blot, SEC-HPLC, and isoelectric focusing. Binding to the target present in healthy human mononuclear cells was assessed by flow cytometry, as well as by competition between the two constructs and the original murine monoclonal antibody. The humanized constructs were not able to dislodge the murine antibody while the murine anti-CD3 antibody could dislodge around 20% of the FvFc or IgG humanized versions. Further in vitro and in vivo pre-clinical analyses will be carried out to verify the ability of the humanized versions to demonstrate the immunoregulatory profile required for a humanized anti-CD3 monoclonal antibody.

Comparison of Humanized IgG and FvFc Anti-CD3 Monoclonal Antibodies Expressed in CHO Cells

Two humanized monoclonal antibody constructs bearing the same variable regions of an anti-CD3 monoclonal antibody, whole IgG and FvFc, were expressed in CHO cells. Random and site-specific integration were used resulting in similar expression levels. The transfectants were selected with appropriate selection agent, andthe surviving cells were plated in semi-solid medium for capture with FITC-conjugated anti-human IG antibody andpicked with the robotic ClonePix FL. Conditioned media from selected clones were purified by affinity chromatographyand characterized by SDS-PAGE, Western-blot, SEC-HPLC, and isoelectric focusing. Binding to the targetpresent in healthy human mononuclear cells was assessed by flow cytometry, as well as by competition between thetwo constructs and the original murine monoclonal antibody. The humanized constructs were not able to dislodgethe murine antibody while the murine anti-CD3 antibody could dislodge around 20% of the FvFc or IgG humanizedversions. Further in vitro and in vivo pre-clinical analyses.