Anti-CD40 Antibodies Fused to CD40 Ligand Have Superagonist Properties
Spotlight (1) Ceglia V (2) Zurawski S (3) Montes M (4) Bouteau A (5) Wang Z (6) Ellis J (7) Igyrt BZ (8) Lvy Y (9) Zurawski G
Ceglia et al. directly fused CD40L to CD40 agonist Abs (agCD40) to develop various agCD40–CD40L Abs that acted as superagonists to CD40. These agCD40–CD40L Abs promoted CD40 cell surface clustering and internalization, increased DC activation and cytokine secretion, and enhanced B cell proliferation. In human CD40 transgenic mice, agCD40–CD40L Abs appeared to be more potent than parental agCD40 Abs. Similarly, the researchers showed that OX40L fused to agonistic OX40 Abs formed OX40 superagonists that increased CD4+ T cell proliferation and cytokine production in vitro, and released the Ab from its dependence on cross-linking.
Contributed by Lauren Hitchings
(1) Ceglia V (2) Zurawski S (3) Montes M (4) Bouteau A (5) Wang Z (6) Ellis J (7) Igyrt BZ (8) Lvy Y (9) Zurawski G
Ceglia et al. directly fused CD40L to CD40 agonist Abs (agCD40) to develop various agCD40–CD40L Abs that acted as superagonists to CD40. These agCD40–CD40L Abs promoted CD40 cell surface clustering and internalization, increased DC activation and cytokine secretion, and enhanced B cell proliferation. In human CD40 transgenic mice, agCD40–CD40L Abs appeared to be more potent than parental agCD40 Abs. Similarly, the researchers showed that OX40L fused to agonistic OX40 Abs formed OX40 superagonists that increased CD4+ T cell proliferation and cytokine production in vitro, and released the Ab from its dependence on cross-linking.
Contributed by Lauren Hitchings
ABSTRACT: CD40 is a potent activating receptor within the TNFR family expressed on APCs of the immune system, and it regulates many aspects of B and T cell immunity via interaction with CD40 ligand (CD40L; CD154) expressed on the surface of activated T cells. Soluble CD40L and agonistic mAbs directed to CD40 are being explored as adjuvants in therapeutic or vaccination settings. Some anti-CD40 Abs can synergize with soluble monomeric CD40L. We show that direct fusion of CD40L to certain agonistic anti-CD40 Abs confers superagonist properties, reducing the dose required for efficacy, notably greatly increasing total cytokine secretion by human dendritic cells. The tetravalent configuration of anti-CD40-CD40L Abs promotes CD40 cell surface clustering and internalization and is the likely mechanism of increased receptor activation. CD40L fused to either the L or H chain C termini, with or without flexible linkers, were all superagonists with greater potency than CD40L trimer. The increased anti-CD40-CD40L Ab potency was independent of higher order aggregation. Moreover, the anti-CD40-CD40L Ab showed higher potency in vivo in human CD40 transgenic mice compared with the parental anti-CD40 Ab. To broaden the concept of fusing agonistic Ab to natural ligand, we fused OX40L to an agonistic OX40 Ab, and this resulted in dramatically increased efficacy for proliferation and cytokine production of activated human CD4(+) T cells as well as releasing the Ab from dependency on cross-linking. This work shows that directly fusing antireceptor Abs to ligand is a useful strategy to dramatically increase agonist potency.
Author Info: (1) Baylor Scott & White Immunology Research, Dallas, TX. Universite Paris-Est Creteil, Creteil, France. Vaccine Research Institute, INSERM, Institut Mondor de Recherche Biomedical
Author Info: (1) Baylor Scott & White Immunology Research, Dallas, TX. Universite Paris-Est Creteil, Creteil, France. Vaccine Research Institute, INSERM, Institut Mondor de Recherche Biomedicale, Creteil, France. (2) Baylor Scott & White Immunology Research, Dallas, TX. Vaccine Research Institute, INSERM, Institut Mondor de Recherche Biomedicale, Creteil, France. (3) Baylor Scott & White Immunology Research, Dallas, TX. Vaccine Research Institute, INSERM, Institut Mondor de Recherche Biomedicale, Creteil, France. (4) Institute of Biomedical Studies, Baylor University, Waco, TX; and. Department of Microbiology and Immunology, Thomas Jefferson University, Philadelphia, PA. (5) Baylor Scott & White Immunology Research, Dallas, TX. Vaccine Research Institute, INSERM, Institut Mondor de Recherche Biomedicale, Creteil, France. (6) Baylor Scott & White Immunology Research, Dallas, TX. Vaccine Research Institute, INSERM, Institut Mondor de Recherche Biomedicale, Creteil, France. (7) Department of Microbiology and Immunology, Thomas Jefferson University, Philadelphia, PA. (8) Universite Paris-Est Creteil, Creteil, France. Vaccine Research Institute, INSERM, Institut Mondor de Recherche Biomedicale, Creteil, France. (9) Baylor Scott & White Immunology Research, Dallas, TX; gerardz@baylorhealth.edu. Vaccine Research Institute, INSERM, Institut Mondor de Recherche Biomedicale, Creteil, France.
Citation: J Immunol 2021 Sep 22 Epub09/22/2021