Duchenne muscular dystrophy is frequently associated with a non-progressive cognitive deficit attributed to the absence of 427,000 mel. wt brain dystrophin, or to altered expression of other C-terminal products of this protein, Dp71 and/or Dp140. To further explore the role of these membrane cytoskeleton-associated proteins in brain function, we studied spatial learning and ex vivo synaptic plasticity in the mdx mouse, which lacks 427,000 mel, wt dystrophin, and in the mdx(3cv) mutant, which shows a dramatically reduced expression of all the dystrophin gene products known so far. We show that reference and working memories are largely unimpaired in the two mutant mice performing a spatial discrimination task in a radial maze. However, mdx(3cv) mice showed enhanced emotional reactivity and developed different strategies in learning the task, as compared to control mice. We also showed that both mutants display apparently normal levels of long-term potentiation and paired-purse facilitation in the CAI field of the hippocampus. On the other hand, an increased post-tetanic potentiation was shown by mdx, but not mdx(3cv) mice, which might be linked to calcium-regulatory defects. Otherwise, immunoblot analyses suggested an increased expression of a 400,000 moi, wt protein in brain extracts from both mdx and mdx(3cv) mice, but not in those from control mice. This protein might correspond to the dystrophin-homologue utrophin. The present results suggest that altered expression of dystrophin or C-terminal dystrophin proteins in brain did not markedly affect hippocampus-dependent spatial learning and CA1 hippocampal long-term potentiation in mdx and mdx(3cv) mice. The role of these membrane cytoskeleton-associated proteins in normal brain function and pathology remains to be elucidated. Furthermore, the possibility that redundant mechanisms could partially compensate for dystrophins' deficiency in the mdx and mdx(3cv) models should be further considered. (C) 1998 IBRO. Published by Elsevier Science Ltd.