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Signals That Initiate Somatic Hypermutation of B Cells In Vitro¹

Sigridur Bergthorsdottir^*, Aoife Gallagher^2,*, Sandra Jainandunsing^*, Debra Cockayne, James Sutton^*, Tomas Leanderson and David Gray^2,3,*

^* Department of Immunology, Division of Medicine, Imperial College School of Medicine, Hammersmith Hospital, London, United Kingdom; Neurobiology Unit, Roche Bioscience, Palo Alto, CA 94304; and Immunology Unit, University of Lund, Lund, Sweden

Somatic hypermutation is initiated as B lymphocytes proliferate in germinal centers. The signals that switch on the mutation process are unknown. We have derived an in vitro system to define signals that will initiate mutation in normal, naive splenic B cells. We find that three signals are required to allow detection of somatic mutation in vitro; these are anti-Ig, anti-CD40, and anti-CD38. If any one of these is omitted, mutation remains off. We show that CD40 is obligatory in vivo, as CD40 knockout mice exhibit no Ag-driven mutation. In contrast, CD38 is not, as CD38 knockout mice mutate normally. We believe that, in vitro, CD38, in combination with other stimuli, drives extensive cell division, allowing the detection of mutated sequences. However, in germinal centers in vivo, proliferative activity is instigated by a different molecule. This is the first demonstration of the initiation of hypermutation in vitro with normal splenic B cells using defined stimuli.

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