Context-dependent regulation of immunoglobulin mutagenesis by p53

• Published in: Molecular immunology Vol. 138; pp. 128 - 136
• Main Authors: Böttcher, Katrin, Braunschmidt, Kerstin, Hirth, Gianna, Schärich, Karsten, Klassert, Tilman E., Stock, Magdalena, Sorgatz, Janine, Fischer-Burkart, Sabine, Ullrich, Steffen, Frankenberger, Samantha, Kritsch, Daniel, Kosan, Christian, Küppers, Ralf, Strobl, Lothar J., Slevogt, Hortense, Zimber-Strobl, Ursula, Jungnickel, Berit
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.10.2021
• Subjects: antibodies; Class switch recombination; DNA damage; DNA repair; genetic instability; Germinal center; humans; immunoglobulins; lymphoma; Lymphomagenesis; mutagenesis; p53; Somatic hypermutation; stress response; Translesion synthesis; Somatic hypermutation; Class switch recombination; Lymphomagenesis; Translesion synthesis; Germinal center; p53
• ISSN: 0161-5890; 1872-9142; 1872-9142
• DOI: 10.1016/j.molimm.2021.08.005

•p53 affects somatic hypermutation by action in non-B cells.•p53 defects in germinal center B cells do not affect variable region hypermutation.•p53 defects during class switch recombinatoin alter the mutagenesis pattern.•p53 defects in lymphoma cells lead to increased somatic hypermutation. p53 plays a major role in genome maintenance. In addition to multiple p53 functions in the control of DNA repair, a regulation of DNA damage bypass via translesion synthesis has been implied in vitro. Somatic hypermutation of immunoglobulin genes for affinity maturation of antibody responses is based on aberrant translesion polymerase action and must be subject to stringent control to prevent genetic alterations and lymphomagenesis. When studying the role of p53 in somatic hypermutation in vivo, we found altered translesion polymerase-mediated A:T mutagenesis in mice lacking p53 in all organs, but notably not in mice with B cell-specific p53 inactivation, implying that p53 functions in non-B cells may alter mutagenesis in B cells. During class switch recombination, when p53 prevents formation of chromosomal translocations, we in addition detected a B cell-intrinsic role for p53 in altering G:C and A:T mutagenesis. Thus, p53 regulates translesion polymerase activity and shows differential activity during somatic hypermutation versus class switch recombination in vivo. Finally, p53 inhibition leads to increased somatic hypermutation in human B lymphoma cells. We conclude that loss of p53 function may promote genetic instability via multiple routes during antibody diversification in vivo.