Mitogen activation of human peripheral T lymphocytes induces the formation of new cyclic AMP response element-binding protein nuclear complexes

A large body of evidence indicates that experimental agents which raise cellular cAMP levels inhibit T cell growth and division. By contrast, many studies have reported that mitogen activation of T cells increases cAMP levels, implying a positive physiological role for cAMP in the activation process. In the present study we demonstrate that mitogen activation of human peripheral T lymphocytes induces nuclear factors that form complexes with cyclic AMP response element-binding protein (CREB). Four complexes are identified by the electrophoretic mobility shift assay, two of which are induced by mitogen activation. All four complexes contain CREB and are bound to the cAMP response element (CRE) core sequence (TGACGTCA), as indicated by antibody and oligonucleotide competition experiments. Binding of the four complexes to CRE is prevented by dephosphorylation of nuclear extracts and is restored by rephosphorylation with cAMP-dependent protein kinase or endogenous kinases. Similar complexes are detected in nuclear extracts of Jurkat cells. Mitogen induction of the electrophoretic mobility shift assay complexes is not accounted for by protein phosphorylation or by induction of CREB. Rather, the data indicate that mitogen increases the levels of a nuclear factor(s) that dimerizes with CREB. Induction of new CREB complexes implies a physiological role for cAMP in mitogen activation of T lymphocytes.     

The mouse elongation factor-2 gene: isolation and characterization of the promoter

Elongation factor 2 (EF-2) is a protein involved in peptide chain elongation in eukaryotes. We isolated the mouse EF-2 gene and characterized its promoter. We showed that the majority of enhancer elements were located within 500 bp of the flanking sequence and identified a factor binding site sequence (CGTCACGTGACGC) located between nucleotides -58 and -47 containing two CGTCA motifs separated by two nucleotides. The motif represents a half-site for binding of the cAMP response element (CRE) binding protein (CREB). Mutation analysis indicated that the presence of one CGTCA site alone conferred cAMP inducibility, but the presence of one or two CGTCA sites and spacing nucleotides elicited cAMP-independent, constitutive expression. UV cross-linking and DNA affinity chromatography revealed that three 40-, 43-, and 65-kD proteins bound to the CRE-like element. Of these, the 65-kD protein was unique to the CRE-like element. The 40-kD protein was ATF1 and the 43-kD protein with the molecular size of CREB was not CREB, on the basis of reactivity to their respective antibodies. Because ATF1 responds poorly to cAMP induction, it is likely the contributor to the constitutive expression rather than inductive expression of the CRE-like element, and, thus, the EF-2 gene.     

Pharmacological profiles of absence seizure-induced increases in CRE- and AP-1 DNA-binding activities in gamma-butyrolactone-treated mice

Absence seizures are characterised by a well-defined disturbance of thalamocortical function, and there is no spread to other systems. In this study, we continue our examination of the mechanisms underlying the increased nuclear cyclic AMP responsive element (CRE)- and activator protein 1 (AP-1) DNA-binding activities in a gamma-butyrolactone (GBL)-induced mouse model of absence seizure. The administration of GBL increased CRE- and AP-1 DNA-binding activities in the cerebral cortex and thalamus, but not in other regions such as the hippocampus, cerebellum or pons + medulla oblongata, at doses which induced absence seizures. Not only the absence-seizure behavior but also the increased CRE- and AP-1 DNA-binding activities in the thalamocortical regions were reversibly inhibited by ethosuximide, a typical anti-absence drug, and the GABAB antagonists CGP 35348 and CGP 46381. A gel-supershift assay revealed that the GBL-induced CRE-binding activity was supershifted by an anti-CRE-binding protein (CREB) antibody, and that AP-1 DNA-binding activity was blocked by anti-c-Jun and anti-c-Fos antibodies. These results suggest that increased CRE- and AP-1 DNA-binding activities in the cerebral cortex and thalamus are related to the pathogenesis of generalized absence seizures and that these increases in DNA-binding activity are related to ethosuximide- and GABAB antagonist-sensitive abnormal neuronal activity in the thalamocortical circuit.     

Distinct nuclear proteins competing for an overlapping sequence of cyclic adenosine monophosphate and negative regulatory elements regulate tissue-specific mouse renin gene expression

The mouse renin locus (Ren-1d) exhibits specific patterns of tissue expression. It is expressed in kidney but not submandibular gland (SMG). This locus contains a negative regulatory element (NRE) and a cAMP responsive element (CRE) that share an overlapping sequence. In the kidney, CRE binding proteins (CREB) and NRE binding proteins (NREB) compete for binding to this sequence, with the CREB having a greater affinity. In the SMG, CREB is inactivated by an inhibitory protein, permitting NREB to bind to the sequence, thus inhibiting Ren-1d expression. We hypothesize that the competition between NREB and CREB for this sequence governs tissue-specific expression of mouse renin. We speculate that this may be a general paradigm that determines tissue-specific gene expression.     

Unique regulation of immediate early gene and tyrosine hydroxylase expression in the odor-deprived mouse olfactory bulb

Tyrosine hydroxylase (TH), expressed in a population of periglomerular neurons intrinsic to the olfactory bulb, displays dramatic down-regulation in response to odor deprivation. To begin to elucidate the importance of immediate early genes (IEG) in TH gene regulation, the present study examined expression of IEGs in the olfactory bulb in response to odor deprivation. In addition, the composition of TH AP-1 and CRE binding complexes was investigated in control and odor-deprived mice. Immunocytochemical studies showed that c-Fos, Fos-B, Jun-D, CRE-binding protein (CREB), and phosphorylated CREB (pCREB) are colocalized with TH in the dopaminergic periglomerular neurons. Unilateral naris closure resulted in down-regulation of c-Fos and Fos-B, but not Jun-D, CREB, or pCREB, in the glomerular layer of the ipsilateral olfactory bulb. Gel shift assays demonstrated a significant decrease (32%) in TH AP-1, but not CRE, binding activity in the odor-deprived bulb. Fos-B was found to be the exclusive member of the Fos family present in the TH AP-1 complex. CREB, CRE modulator protein (CREM), Fos-B, and Jun-D, but not c-Fos, all contributed to the CRE DNA-protein complex. These results indicated that Fos-B, acting through both AP-1 and CRE motifs, may be implicated in the regulation of TH expression in the olfactory bulb dopaminergic neurons.     

Expression and localization of brain ankyrin isoforms and related proteins during early developmental stages of rat nervous system

Expression and localization of two isoforms of brain ankyrin, 440- and 220-kDa ankyrinB, were studied in the developing nervous system of the rat fetus. The 440-kDa ankyrinB appeared on as early as embryonic day 13, and its level increased progressively toward the day of birth, which was similar to the expression pattern of growth-associated protein (GAP)-43, a well-established axonal protein. On the other hand, 220-kDa ankyrinB was expressed at a low level but constitutively throughout the latter prenatal period and was a major isoform even before embryonic day 14. Whereas the localization of 440-kDa ankyrinB was essentially confined to the axons, judging from the similarity with that of GAP-43, 220-kDa ankyrinB showed a rather general distribution in neural tissue. The localization of L1, known as an ankyrinB-binding protein, was similar to that of 440-kDa ankyrinB in the brain tissue, whereas it was similar to that of 220-kDa ankyrinB in cultured neurons, suggesting that the interaction of L1 with brain ankyrins in neurons is affected by their environment.