Correlating behaviour and gene expression endpoints in the dopaminergic system after modafinil administration in mouse.

The mechanisms of action of modafinil continue to be poorly characterised and its potential for abuse in preclinical models remains controverted. The aim of this study was to further elucidate the mechanism of action of modafinil, through a potential behavioural and molecular association in the mouse. A conditioned place preference (CPP) paradigm was implemented to investigate the rewarding properties of modafinil. Whole genome expression and qRT-PCR analysis were performed on the ventral tegmental area (VTA), nucleus accumbens (NAC) and prefrontal cortex (PFC) of modafinil-treated and control animals. Modafinil administration (65 mg/kg) induced an increase in locomotor activity, an increase in the change of preference for the drug paired side after a conditioning period as well as changes to gene expression profiles in the VTA (120 genes), NAC (23 genes) and PFC (19 genes). A molecular signature consisting of twelve up-regulated genes was identified as common to the three brain regions. Multiple linear correlation analysis showed a strong correlation (R(2)>0.70) between the behavioural and molecular endpoints in the three brain regions. We show that modafinil had a concomitant effect on CPP, locomotor activity, and up-regulation of interferon-γ (IFN-γ) regulated genes (Gbp2, Gbp3, Gbp10, Cd274, Igtp), while correlating the latter set of genes with behaviour changes evaluated through the CPP. A potential association can be proposed based on the dysregulation of p47 family genes and Gbp family of IFN-γ induced GTPases. In conclusion, these findings suggest a link between the behavioural and molecular events in the context of modafinil administration.

Regulation of H2O2 generation in thyroid cells does not involve Rac1 activation.

OBJECTIVES: The H2O2 generating system of the thyrocyte and the O2- generating system of macrophages and leukocytes present numerous functional analogies. The main constituent enzymes belong to the NADPH oxidase (NOX) family (Duox/ThOX for the thyroid and NOX2 /gp91phox for the leukocytes and macrophages), and in both cell types, H2O2 generation is activated by the intracellular generation of Ca2+ and diacylglycerol signals. Nevertheless, although the controls involved in these two systems are similar, their mechanisms are different. The main factors controlling O2- production by NOX2 are the cytosolic proteins p67phox and p47phox, and Rac, a small GTP-binding protein. We have previously reported that there is no expression of p67phox and p47phox in thyrocytes. Here, we investigated whether Rac1 is an actor in the thyroid H2O2-generating system. DESIGN AND METHODS: Ionomycin- and carbamylcholine-stimulated H2O2 generation was measured in dog thyroid cells pretreated with the Clostridium difficile toxin B, which inhibits Rac proteins. Activation of Rac1 was measured in response to agents stimulating H2O2 production, using the CRIB domain of PAK1 as a probe in a glutathione S-transferase (GST) pull-down assay. RESULTS: Among the various agents inducing H2O2 generation in dog thyrocytes, carbamylcholine is the only one which activates Rac1, whereas phorbol ester and calcium increase alone have no effect, and cAMP inactivates it. Moreover, whereas toxin B inhibits the stimulation of O2- generation by phorbol ester in leukocytes, it does not inhibit H2O2 generation induced by carbamylcholine and ionomycin in dog thyrocytes. CONCLUSIONS: Unlike in leukocytes, Rac proteins do not play a role in H2O2 generation in thyroid cells. A different regulatory cascade for the control of H2O2 generation remains to be defined.

Search for new cyclic AMP-binding proteins.

Today, there is evidence that the cAMP-dependent kinases (PKA) are not the only intracellular receptors involved in intracellular cAMP signalling in eukaryotes. Other cAMP-binding proteins have been recently identified, including some cyclic nucleotide-gated channels and Epac (exchange protein directly activated by cAMP) proteins. All these proteins bind cAMP through conserved cyclic nucleotide monophosphate-binding domains. However, all putative cAMP-binding proteins having such domains, as revealed by computer analysis, do not necessarily bind cAMP, indicating that their presence is not a sufficient criteria to predict cAMP-binding property for a protein.

The role of cyclic AMP and its effect on protein kinase A in the mitogenic action of thyrotropin on the thyroid cell.

Cyclic AMP has been shown to inhibit cell proliferation in many cell types and to activate it in some. The latter has been recognized only lately, thanks in large part to studies on the regulation of thyroid cell proliferation in dog thyroid cells. The steps that led to this conclusion are outlined. Thyrotropin activates cyclic accumulation in thyroid cells of all the studied species and also phospholipase C in human cells. It activates directly cell proliferation in rat cell lines, dog, and human thyroid cells but not in bovine or pig cells. The action of cyclic AMP is responsible for the proliferative effect of TSH. It accounts for several human diseases: congenital hyperthyroidism, autonomous adenomas, and Graves' disease; and, by default, for hypothyroidism by TSH receptor defect. Cyclic AMP proliferative action requires the activation of protein kinase A, but this effect is not sufficient to explain it. Cyclic AMP action also requires the permissive effect of IGF-1 or insulin through their receptors, mostly as a consequence of PI3 kinase activation. The mechanism of these effects at the level of cyclin and cyclin-dependent protein kinases involves an induction of cyclin D3 by IGF-1 and the cyclic AMP-elicited generation and activation of the cyclin D3-CDK4 complex.

Cross signaling, cell specificity, and physiology.

The literature on intracellular signal transduction presents a confusing picture: every regulatory factor appears to be regulated by all signal transduction cascades and to regulate all cell processes. This contrasts with the known exquisite specificity of action of extracellular signals in different cell types in vivo. The confusion of the in vitro literature is shown to arise from several causes: the inevitable artifacts inherent in reductionism, the arguments used to establish causal effect relationships, the use of less than adequate models (cell lines, transfections, acellular systems, etc.), and the implicit assumption that networks of regulations are universal whereas they are in fact cell and stage specific. Cell specificity results from the existence in any cell type of a unique set of proteins and their isoforms at each level of signal transduction cascades, from the space structure of their components, from their combinatorial logic at each level, from the presence of modulators of signal transduction proteins and of modulators of modulators, from the time structure of extracellular signals and of their transduction, and from quantitative differences of expression of similar sets of factors.

The visual display of regulatory information and networks.

Cell regulation and signal transduction are becoming increasingly complex, with reports of new cross-signalling, feedback, and feedforward regulations between pathways and between the multiple isozymes discovered at each step of these pathways. However, this information, which requires pages of text for its description, can be summarized in very simple schemes, although there is no consensus on the drawing of such schemes. This article presents a simple set of rules that allows a lot of information to be inserted in easily understandable displays.

TSH and cAMP do not signal mitogenesis through Ras activation.

Ras activation by receptor tyrosine kinases or serpentine receptors is generally considered to be essential for G1 phase progression and mitogenesis. In the physiologically relevant model of primary dog thyrocytes, the accumulation of the GTP-bound form of Ras constituted an early convergence point of various mitogenic or comitogenic stimuli including EGF, HGF, phorbol esters, insulin and carbachol. By contrast, the basal level of GTP-Ras was slightly reduced by TSH and forskolin and did not increase during the TSH/cAMP-dependent progression into G1 phase. This rules out a role for the activation of Ras as a signal in the mitogenesis elicited by TSH via cAMP in these cells.

Activation of the small G protein Rap1 in dog thyroid cells by both cAMP-dependent and -independent pathways.

Thyrotropin, through a cAMP-dependent pathway, stimulates function, differentiation, and proliferation of dog and human thyroid cells. Our previous findings suggested that, in addition to PKA activation, another cAMP-dependent mechanism is involved in TSH action. In this work, we assess whether the newly identified cAMP-Epac-Rap1 cascade is involved in TSH-cAMP-mediated effects in dog thyroid cells. We first demonstrate that TSH and forskolin strongly activate Rap1 in a PKA-independent manner. However, activation of Rap1 is not specific for TSH or cAMP. Indeed, carbachol, TPA, insulin, or EGF, which activate different cAMP-independent cascades, all independently activate Rap1. Rap1 is therefore a common step in all these cascades which exert various effects on proliferation, differentiation, and function of thyroid cells. Moreover, the microinjection of the Rap1 protein alone or in combination with the catalytic C subunit of PKA fails to induce proliferation or expression of thyroglobulin.

A requirement for cyclin D3-cyclin-dependent kinase (cdk)-4 assembly in the cyclic adenosine monophosphate-dependent proliferation of thyrocytes.

In different systems, cyclic adenosine monophosphate (cAMP) either blocks or promotes cell cycle progression in mid to late G1 phase. Dog thyroid epithelial cells in primary culture constitute a model of positive control of DNA synthesis initiation and G0-S prereplicative phase progression by cAMP as a second messenger for thyrotropin (TSH). The cAMP-dependent mitogenic pathway is unique as it is independent of mitogen-activated protein kinase activation and differs from growth factor-dependent pathways at the level of the expression of several protooncogenes/transcription factors. This study examined the involvement of D-type G1 cyclins and their associated cyclin-dependent kinase (cdk4) in the cAMP-dependent G1 phase progression of dog thyroid cells. Unlike epidermal growth factor (EGF)+serum and other cAMP-independent mitogens, TSH did not induce the accumulation of cyclins D1 and D2 and partially inhibited the basal expression of the most abundant cyclin D3. However, TSH stimulation enhanced the nuclear detection of cyclin D3. This effect correlated with G1 and S phase progression. It was found to reflect both the unmasking of an epitope of cyclin D3 close to its domain of interaction with cdk4, and the nuclear translocation of cyclin D3. TSH and EGF+serum also induced a previously undescribed nuclear translocation of cdk4, the assembly of precipitable cyclin D3-cdk4 complexes, and the Rb kinase activity of these complexes. Previously, cdk4 activity was found to be required in the cAMP-dependent mitogenic pathway of dog thyrocytes, as in growth factor pathways. Here, microinjections of a cyclin D3 antibody showed that cyclin D3 is essential in the TSH/ cAMP-dependent mitogenesis, but not in the pathway of growth factors that induce cyclins D1 and D2. The present study (a) provides the first example in a normal cell of a stimulation of G1 phase progression occurring independently of an enhanced accumulation of cyclins D, (b) identifies the activation of cyclin D3 and cdk4 through their enhanced assembly and/or nuclear translocation, as first convergence steps of the parallel cAMP-dependent and growth factor mitogenic pathways, and (c) strongly suggests that this new mechanism is essential in the cAMP-dependent mitogenesis, which provides the first direct demonstration of the requirement for cyclin D3 in a G1 phase progression.

Activation of cyclic AMP-dependent kinase is required but may not be sufficient to mimic cyclic AMP-dependent DNA synthesis and thyroglobulin expression in dog thyroid cells.

Thyrotropin (TSH), via a cyclic AMP (cAMP)-dependent pathway, induces cytoplasmic retractions, proliferation, and differentiation expression in dog thyroid cells. The role of cAMP-dependent protein kinase (PKA) in the induction of these events was assessed by microinjection into living cells. Microinjection of the heat-stable inhibitor of PKA (PKI) inhibited the effects of TSH, demonstrating that activation of PKA was required in this process. Overexpression of the catalytic (C) subunit of PKA brought about by microinjection of the expression plasmid pC alpha ev or of purified C subunit itself was sufficient to mimic the cAMP-dependent cytoplasmic changes and thyroperoxidase mRNA expression but not to induce DNA synthesis and thyroglobulin (Tg) expression. The cAMP-dependent morphological effect was not observed when C subunit was coinjected with the regulatory subunit (RI or RII subunit) of PKA. To mimic the cAMP-induced PKA dissociation into free C and R subunits, the C subunit was coinjected with the regulation-deficient truncated RI subunit (RIdelta1-95) or with wild-type RI or native RII subunits, followed by incubation with TSH at a concentration too low to stimulate the cAMP-dependent events by itself. Although the cAMP-dependent morphology changes were still observed, neither DNA synthesis nor Tg expression was stimulated in these cells. Taken together, these data suggest that in addition to PKA activation, another cAMP-dependent mechanism could exist and play an important role in the transduction of the cAMP signal in thyroid cells.

Study of TTF-1 gene expression in dog thyrocytes in primary culture.

TTF-1 is a homeodomain-containing transcription factor mainly expressed in the thyroid where it controls the tissue-specific expression of the thyroglobulin, thyroperoxidase and TSH receptor genes. It is therefore potentially implicated in the hormonal control exerted by thyrotropin via the second messenger cyclic AMP on the transcription of these genes in thyrocytes. In order to investigate whether there exists a relationship between the stimulation of the cAMP pathway and TTF-1 gene expression in these cells, we have compared the amounts of TTF-1 protein, its state of phosphorylation and its subcellular distribution in control and cAMP-stimulated dog thyrocytes in primary culture. Dog TTF-1 was expressed in bacteria as a fusion protein and antibodies were raised against the dog TTF-1 moiety. Stimulation of the thyrocytes by cyclic AMP agonist only marginally increased TTF-1 gene expression as shown for the mRNA by RNase protection assay and for the protein by immunoblotting and immunoprecipitation of extracts from 35S-methionine labelled cells. The phosphorylation state of TTF-1 was investigated by immunoprecipitation of extracts from 32P-labelled thyrocytes. Phosphorylation level appeared to be essentially unaffected by forskolin treatment of the cells. We also looked for differences in the use of phosphorylation sites by partial proteolytic digestion of immunoprecipitated 32P-labelled TTF-1 with Glu-C and Asp-N endoproteases. Comparison of radioactivity distribution amongst the generated fragments did not reveal any difference in the pattern of TTF-1 phosphorylation in control and forskolin conditions. Lastly, in situ detection of TTF-1 by immunofluorescence demonstrated that the protein was localized in the nucleus of the cells, irrespective of the culture conditions. No major change in TTF-1 gene expression upon stimulation of the thyrocyte with a cAMP agonist could thus be detected in this study. The absence of an obvious modification of the TTF-1 protein itself in response to cAMP stimulation may indicate that other transcription factor(s) or co-factor(s) are involved in the control exerted by cAMP on the expression of thyroid-specific genes.

Mitogenic, dedifferentiating, and scattering effects of hepatocyte growth factor on dog thyroid cells.

Hepatocyte growth factor (HGF)/scatter factor (SF) is a potent mitogenic factor or motility factor in different cells, acting through the tyrosine kinase receptor encoded by the met protooncogene. In the present work, we demonstrate the powerful mitogenic activity of this growth factor on dog thyroid cells in primary culture. This effect, maximal at 50 ng/ml, was superior to those of other thyroid mitogenic agents, such as TSH, forskolin, and epidermal growth factor (EGF). HGF inhibited both TSH- and forskolin-stimulated iodide uptake (a thyroid-specific differentiation marker) in the same way as EGF. However, as with basic fibroblast growth factor, this dedifferentiating action appeared only during the growing phase concomitantly with the enhanced proliferation. HGF treatment also markedly decreased TSH receptor and thyroglobulin messenger RNA levels, two other markers of differentiated thyrocytes. Besides its proliferative and dedifferentiating effects, HGF enhanced the motility of the cultured thyroid cells. Concerning the mechanism of its action, we showed that HGF had no effect on basal cAMP levels, but like EGF and 12-O-tetradecanoyl-phorbol 13-acetate, it induced the rapid tyrosine phosphorylation of mitogen-activated protein kinases p42 and p44. These data establish HGF as the strongest mitogenic agent for dog thyroid cells and may explain the important role of met oncogene expression in human thyroid tumors.

Apoptosis in dog thyroid cells.

Apoptosis, a physiological cell death, has been shown to be involved in tissue homeostasis as well as in tissue regression due to hormone deprivation. The cell population slowly turns over, with cell loss compensating mitogenicity. In the absence of thyrotropin, the cell population decreases. The possible involvement of apoptosis in this loss has been studied. We show in this report that deprivation of serum, epidermal growth factor and thyrotropin triggers internucleosomal DNA fragmentation and morphological modifications characteristic of apoptotic cell death in dog thyroid cells in primary culture; cycloheximide treatment has the same effect. This indicates that thyrocytes are endowed with a constitutive apoptosis "program" and that the latter might be involved in the thyroid regression observed in vivo in the absence of full growth stimulation of the gland.

Cloning of cDNA specifically involved in the thyroid cAMP mitogenic pathway.

The activation of the cyclic AMP cascade in dog and human thyroid cells in primary culture induces the expression of differentiated gene expression, hyperfunction and proliferation. These programs are developed simultaneously in quiescent dedifferentiated cells. In this paper the strategy followed by our group to define the genes involved in the cAMP mitogenic cascade is outlined.