Agents that increase intracellular cAMP inhibit the activation and function of T cells and can lead to cell death. Recently, it has been postulated that cAMP inhibits T cell function in large part by acting as a brake on the T cell receptor and costimulatory receptor pathways. Therefore, for full activation of the T cell to occur, this inhibitory influence must be removed. One likely mechanism for accomplishing this is by up-regulation and͞or activation of specific cyclic nucleotide phosphodiesterases (PDEs), and such a mechanism for one phosphodiesterase, PDE7A1, has been reported. In this paper, we extend this mechanism to another isozyme variant of the same PDE family, PDE7A3. We also report the full-length sequence of human PDE8A1 and show that it also is induced in response to a combination of T cell receptor and costimulatory receptor pathway activation. However, the time course for induction of PDE8A1 is slower than that of PDE7A1. The basal level measured and, therefore, the apparent fold induction of PDE7A1 mRNA and protein depend in large part on the method of isolation of the T cells. On the other hand, regardless of the isolation method, the basal levels of PDE7A3 and PDE8A1 are very low and fold activation is much higher. Constitutively expressed PDE8A1 and PDE7A3 also have been isolated from a human T cell line, Hut78.
Granulocyte-macrophage colony-stimulating factor (GM-CSF) is a major regulator of monocyte to macrophage differentiation. In both humans and mice, the main phenotype of decreased GM-CSF function is pulmonary proteinosis due to aberrant function of alveolar macrophages. Recently, this cytokine has been shown to up-regulate a cyclic nucleotide phosphodiesterase, PDE1B. Two PDE1B variants with unique N-terminal sequences, PDE1B1 and PDE1B2, have been identified. Here, we report that the previously uncharacterized PDE1B2 is selectively increased by GM-CSF by stimulation of transcription at a previously unknown transcriptional start site. Analysis of the exon and intron organization of the PDE1B gene reveals that PDE1B2 has a different N-terminal sequence because of a separate first exon that is located 11.5 kb downstream from the PDE1B1 first exon. By using 5 -RACE, alignment of EST sequences, and a luciferase-reporter system, we provide evidence that PDE1B2 has a separate transcriptional start site from PDE1B1 that can be activated by monocyte differentiation. Furthermore, IL-4 treatment in the presence of GM-CSF, which shifts the differentiation from a macrophage to a dendritic cell phenotype, suppresses the up-regulation of PDE1B2. Induction of PDE1B2 is also found in T cells upon activation by PHA. Therefore, PDE1B2 may have a regulatory role in multiple immune cell types. Last, characterization of the catalytic properties of recombinant PDE1B2 shows that it prefers cGMP over cAMP as a substrate and, thus, is likely to regulate cGMP in macrophages. Also, PDE1B2 has a nearly 3-fold lower EC50 for activation by calmodulin than PDE1B1.cAMP ͉ cGMP ͉ phosphodiesterase
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