Class I major histocompatibility complex (class I MHC) molecules, known to be important for immune responses to antigen, are expressed also by neurons that undergo activity-dependent, longterm structural and synaptic modifications. Here, we show that in mice genetically deficient for cell surface class I MHC or for a class I MHC receptor component, CD3ζ, refinement of connections between retina and central targets during development is incomplete. In the hippocampus of adult mutants, N-methyl-D-aspartate receptor-dependent long-term potentiation (LTP) is enhanced, and long-term depression (LTD) is absent. Specific class I MHC messenger RNAs are expressed by distinct mosaics of neurons, reflecting a potential for diverse neuronal functions. These results demonstrate an important role for these molecules in the activity-dependent remodeling and plasticity of connections in the developing and mature mammalian central nervous system (CNS).The development of precise connections in the CNS is critically dependent on neural activity, which drives the elimination of inappropriate connections and the stabilization of appropriate ones. In the visual system of higher mammals, the refinement of initially imprecise axonal connections requires spontaneously generated activity early in development and visually driven activity later (1-4). Fine-tuning of neural connectivity is thought to result from changes in synaptic strength, driven by patterned impulse activity (1,2,5,6).To identify molecules critical for activity-dependent structural remodeling, we previously conducted an unbiased screen for mRNAs selectively regulated by blocking spontaneously generated activity in the developing cat visual system. This manipulation prevents the remodeling of retinal axons from each eye into layers within the lateral geniculate nucleus (LGN) (7-9). Although many known neural genes were not detectably regulated by activity blockade, this screen revealed to our surprise that members of the class I MHC protein family are expressed by neurons and are regulated by spontaneous and evoked neural activity (10). Neuronal class I MHC expression corresponds to well-characterized times and regions of activity-dependent development and plasticity of CNS connections, including retina, LGN, and hippocampus. Furthermore, the mRNA for CD3ζ [a class I MHC receptor subunit in the immune system (11)] is also expressed by neurons (10), consistent with its interaction with class I MHC during activity-dependent remodeling and plasticity. Although class I MHC is primarily known for its function in cell-mediated immune recognition, the above findings from our differential screen suggest that class I MHC molecules may play roles in structural and synaptic remodeling in the developing and mature CNS.
T cell immune responses begin within organized lymphoid tissues. The pace, topology, and outcomes of the cellular interactions that underlie these responses have, so far, been inferred from static imaging of sectioned tissue or from studies of cultured cells. Here we report dynamic visualization of antigen-specific T cells interacting with dendritic cells within intact explanted lymph nodes. We observed immunological synapse formation and prolonged interactions between these two cell types, followed by the activation, dissociation, and rapid migration of T cells away from the antigenic stimulus. This high-resolution spatiotemporal analysis provides insight into the nature of cell interactions critical to early immune responses within lymphoid structures.
Genetic disorders affecting cellular responses to DNA damage are characterized by high rates of translocations involving antigen receptor loci and increased susceptibility to lymphoid malignancies. We report that the Nijmegen breakage syndrome protein (NBS1) and histone gamma-H2AX, which associate with irradiation-induced DNA double-strand breaks (DSBs), are also found at sites of VDJ (variable, diversity, joining) recombination-induced DSBs. In developing thymocytes, NBS1 and gamma-H2AX form nuclear foci that colocalize with the T cell receptor alpha locus in response to recombination activating gene (RAG) protein-mediated VDJ cleavage. Our results suggest that surveillance of T cell receptor recombination intermediates by NBS1 and gamma-H2AX may be important for preventing oncogenic translocations.
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