Dendritic cells regulate T-cell deattachment through the integrin-interacting protein CYTIP.

When T cells are primed by dendritic cells (DCs) to initiate antigen-specific immune responses screening for matching antigen receptor-MHC/peptide pairs takes place in DC-T-cell conjugates. For an immune response DC-T-cell conjugates formed during priming events need to dissolve. Although detailed knowledge on molecules involved in the conjugate formation is available, dissolving of them has not been considered to be an active process. Here, we identify CYTIP (cytohesin-interacting protein) to mediate DC-T-cell deattachment. CYTIP, which is induced during maturation of DCs, shortly accumulates to the contact zones with T cells within the first hour of coculture. Specific silencing of CYTIP results in stronger adhesion of DCs to T cells and to fibronectin. When a need for deattachment is created in a T-cell priming assay by only partially loading DCs with antigen, CYTIP silencing causes reduced priming capacity. Thus, CYTIP allows DCs to actively control DC-T-cell interactions.

Adenosine slows migration of dendritic cells but does not affect other aspects of dendritic cell maturation.

We report the induction and reduction of adenosine receptor A2a and A3 mRNAs, respectively, during maturation of human monocyte-derived dendritic cells. Adenosine, an immunomodulatory molecule, is unstable in vitro; therefore we tested a stable agonist, 5'-(N-ethylcarboxamido)-adenosine, to explore the effect of adenosine receptor activation on dendritic cell function. We clearly show that adenosine receptor engagement affects the migratory activity of dendritic cells in three distinct settings. In human skin explant culture experiments the emigration of epidermal and dermal dendritic cells was diminished by the addition of 5'-(N-ethylcarboxamido)-adenosine. In a murine contact hypersensitivity assay 5'-(N-ethylcarboxamido)-adenosine caused a reduction in the numbers of epidermal and dermal dendritic cells arriving in the draining lymph node. In a chemotaxis assay of human dendritic cells in response to macrophage inflammatory protein 3beta (MIP-3beta)/CCL19, adenosine caused a delay in transmigration. Expression of a number of molecules involved in dendritic cell migration (CCR5, MIP-3beta/CCL19, and MDR-1) was reduced. Importantly, all other features of dendritic cells tested--phenotype, antigen uptake, cytokine production, T cell activation, and the T cell subset induction--remained unchanged. Dendritic cells carry antigens from the periphery to secondary lymphoid organs, where initiation of immune responses occurs. Increased adenosine release may modulate immune responses by delaying the encounter of antigen-loaded dendritic cells with T cells.

Reinforcing effect of subcutaneous morphine in a modified Ettenberg runway.

Alley running has been successfully used as an operant to demonstrate both the positive and negative reinforcing effect of intravenously administered drugs of abuse in a bona fide operant conditioning paradigm, the Ettenberg runway, in which confounding drug effects on motor performance and drug accumulation are avoided. While Ettenberg and colleagues focus on the intravenous route of drug administration, we tested the practicability of the subcutaneous route of administration in this runway paradigm in Sprague Dawley rats, using morphine as the investigated drug of abuse. We also modified the Ettenberg runway, most notably in that either food (sweetened condensed milk), no food, morphine, or saline was presented outside the runway in a separate cage. This made shaping, i.e., the initial presentation of a food reinforcer within the runway, necessary to establish responding. The manipulations necessary to administer subcutaneous (sc) injections were well tolerated by over 90% of the tested rats (n = 93). However, sc injections increased runtimes to the experimenter cutoff of 60 s within 20 once-daily sessions. Because of strong experimenter effects, all morphine doses or saline had to be adminstered blind. Under these experimenter-blind conditions, 0.1 and 1 mg/kg subcutaneous morphine proved to be reinforcing in that these doses significantly slowed down the gradual increase in runtimes imposed upon by the sc injection procedure. Thus, morphine can be demonstrated to be a positive reinforcer in a modified Ettenberg runway even when given subcutaneously. This effect, however, is eventually overcome by the negative reinforcing effect of subjecting the animals to sc injection procedure.