Estudi d'un receptor quinasa atípic (Mark) i de les proteïnes que interaccionen amb el seu domini intracel·lular. Transducció del senyal i desenvolupament en blat de moro (Zea mays)

Aquesta tesi doctoral s'engloba dins d'un projecte general d'estudi de gens implicats en l'embriogènesi del blat de moro. L'embriogènesi del blat de moro, i en general la de totes les plantes superiors, es dóna en tres etapes: una primera etapa on es diferencien tots els diversos teixits que formaran l'embrió, una segona etapa on l'embrió acumula productes de reserva i un tercer període, la dormància, que finalitza quan les condicions ambientals són les idònies per a la germinació. En el laboratori estàvem interessats, concretament, en l'estudi de gens implicats en la primera etapa morfogenètica, on els diferents teixits i estructures embrionàries queden definides. Per tal d'estudiar gens que s'expressaven en aquest període, una de les estratègies que es va realitzar fou un crivellat diferencial entre teixit embrionari i teixit de planta adulta. D'entre els diferents clons obtinguts, un corresponia a un clon parcial que presentava similitud amb receptors quinasa i que fou objecte d'estudi. A partir d'aquest clon es va obtenir el clon complet i es va anomenar MARK (per Maize Atypical Receptor Kinase). MARK presenta una estructura típica d'un receptor quinasa amb un domini extracel.lular, que conté 6 còpies imperfectes de LRR (Leucine- Rich Repeats), un únic domini transmembrana i un domini quinasa intracel.lular. El domini quinasa de MARK presenta, però, algunes variacions en els residus aminoacídics que es consideren claus per a la funció catalítica dels dominis quinasa. En concret cinc dels aminoàcids considerats essencials per a la fosforilació es troben substituits en el domini quinasa de MARK (DK-MARK). Els experiments de fosforilació in vitro que es van realitzar al laboratori, van mostrar com MARK era incapaç de fosforilar in vitro. Aquesta característica no és, però, exclusiva de MARK. Una búsqueda en les bases de dades ens van permetre identificar altres seqüències que també presentaven els mateixos o altres canvis en aquestes posicions aminoacídiques. En les bases de dades de plantes es van identificar un conjunt de seqüències genòmiques o ESTs amb aquestes característiques i només una d'elles, la proteïna TMKL1 d'Arabidopsis, ha sigut descrita com un receptor quinasa incapaç de fosforilar in vitro. Respecte a la búsqueda de receptors similars a MARK en les bases de dades d'animals, es van identificar també un conjunt de proteïnes que, en alguns casos, s'ha descrit que no tenen activitat quinasa in vivo. Per exemple, un dels casos més ben estudiats és el del receptor erbB3 que forma part de la família de receptors del EGF (Epidermal Growth Factor). Aquesta família de receptors està formada per 4 receptors: erbB1, erbB2, erbB3 i erbB4, dels quals només l'erbB3 no presenta activitat catalítica. S'ha descrit que erbB3 és capaç, tot i no fosforilar in vivo, de participar activament en la transducció del senyal formant heterodímers amb els altres membres de la família. Així, erbB3 és fosforilat pel seu partner i pot iniciar la cascada de transducció del senyal. La participació d'erbB3 en la transducció del senyal és essencial ja que embrions de ratolí knock-out pel gen erbB3 són inviables. Així doncs, el fet que receptors quinasa catalíticament inactius participin en les cascades de transducció del senyal, suggereix l'existència de nous mecanismes d'acció per a la transducció del senyal. Per tant, l'objectiu d'aquest treball fou l'estudi del mecanisme d'acció de MARK mitjançant la caracterització les proteïnes capaces d'interaccionar amb el seu domini quinasa. Per tal d'assolir aquest objectiu, es va realitzar un crivellat de doble-híbrid amb una llibreria de cDNA d'embrions de blat de moro de 7 DAP. D'aquest crivellat es va obtenir un conjunt de possibles clons positius que foren seqüenciats i entre els quals es van escollir per un estudi més detallat aquells que s'havien obtingut més vegades com a clons independents. Aquests clons codificaven per: una SAMDC (S-Adenosil Descarboxilasa), una eIF5 (Eukaryotic translation initiation), una hypothetical protein, una unknown protein, una gamma-adaptina i una MAP4K. Amb aquests 6 clons es van fer estudis in vitro i in vivo per tal de confirmar al seva interacció amb DK-MARK. Els estudis in vivo es van realitzar amb la soca de llevat AH109, una soca més astringent que la utilitzada en el crivellat, ja que presenta tres gens marcadors: Histidina, Adenina i Lacz. Els resultats obtinguts van mostrar que els clons codificants per SAMDC i eIF5 no van créixer en un medi selectiu per His i Ade i, per tant o es tracta de falsos positius del sistema o la seva interacció amb DK-MARK és dèbil. D'altra banda, la resta dels clons analitzats (proteïna hipotètica, una proteïna de funció desconeguda, la gamma-adaptina i una MAP4K) van créixer en medis en absència de Histidina i Adenina. Els assatjos de b-galactosidasa van ser tots positius a excepció de la proteïna hipotètica suggerint que potser aquesta interacció sigui més feble. D'altra banda també es van realitzar estudis in vitro amb la tècnica del pull-down. Els resultats obtinguts amb aquesta tècnica van recolzar els obtinguts en cèl.lules de llevat, ja que tots els clons analitzats a excepció dels codificants per SAMDC i eIF5 van donar un resultat d'interacció amb KD-MARK in vitro positiu. Davant aquests resultats ens vam centrar en l'estudi de la proteïna similar a MAP4K, doncs algunes proteïnes de la seva família s'han relacionat amb receptors de membrana. Els clons que es va obtenir del crivellat codificaven per una proteïna similar amb el domini C-terminal a les proteïnes BnMAP4Ka1 i a2 de Brassica napus. Aquestes proteïnes presenten una forta similitud de seqüència amb proteïnes de la família GCK/SPS1 que formen part d'un grup particular de MAPK relacionades amb la proteïna Ste20 (sterile 20 protein) de llevat. Ste20p activa la MAP3K de llevat Ste11 directament per fosforilació, transduint d'aquesta manera el senyal del receptor de feromones de creuament de les cèl.lules de llevat i es pot, doncs, considerar com una proteïna del tipus MAP4K (mitogen-activated protein kinase kinase kinase kinase). En els darrers anys, s'han identificat un gran nombre de proteïnes similars a Ste20: fins a una trentena en mamífers, en Drosophila, en Caenorhabditis elegans i en altres organismes. Segons la seva estructura aminoacídica, la família Ste20 s'ha classificat en dues subfamílies: les proteïnes STE20/PAK (p21-activated kinases) i la subfamília GCK/SPS1 (germinal center kinases). Les dues subfamílies estan formades per proteïnes que contenen un domini quinasa i un domini regulador, però, mentre que les proteïnes PAK presenten el domini quinasa en la part C-terminal, les GCKs el presenten en la regió N terminal. Les proteïnes GCK presenten una elevada diversitat estructural en el domini regulador permetent la seva classificació en 6 subfamílies. Mitjançant la tècnica del RACE es va obtenir el clon de cDNA complet que es va anomenar MIK (MARK Interacting Kinase). Amb la tècnica del Southern blot es va poder determinar que el gen MIK és un gen de còpia única en el genoma de blat de moro. Per tal d'analitzar la possible interacció entre DK-MARK i MIK, es va estudiar tant el patró d'expressió d'ambdós gens com el seu patró d'acumulació d'ambdues proteïnes durant l'embriogènesi del blat de moro. El patró d'expressió, analitzat per Northen blot va mostrar uns patrons coincidents al llarg de l'embriogènesi des del seu inici fins als 20 DAP amb una acumulació màxima de mRNA en embrions de 15 DAP. D'altra banda per tal d'estudiar el patró d'acumulació de la proteïna MIK així com per comparar-lo amb el de MARK, es van realitzar estudis de Westerns blot. Els resultats també van mostrar una coincidència en el temps de l'acumulació de les proteïnes MARK i MIK durant l'embriogènesi de blat de moro amb una major acumulació en embrions de 15 i 20 DAP. Es van dur a terme també estudis d'immunolocalitzacions sobre embrions de blat de moro de 15 DAP per tal d'estudiar en quins teixits s'acumulaven ambdues proteïnes. Les immunolocalitzacions van mostrar una major acumulació tant de MARK com de MIK en les zones meristemàtiques i en el teixit vascular sobretot del coleòptil on s'aprecia una forta co-localització de MARK i MIK. Totes aquestes dades són compatibles, doncs, amb una possible interacció de les proteïnes MARK i MIK, tot i que no la demostren. Per tal de demostrar la interacció es van realitzar experiments d'immunoprecipitació in vivo a partir d'extractes d'embrions. Malauradament, els resultats no són clars i en aquests moments en el laboratori s'estan posant a punt aquests experiments. També es van realitzar estudis comparatius de seqüència amb diferents proteïnes de la família GCK, mostrant una major similitud amb les proteïnes de la subfamília GCK-III. La subfamília GCK-III ha estat molt poc estudiada i en formen part un conjunt de proteïnes amb funcions molt diverses des de l'apoptosi, la citoquinesi o l'anòxia cel.lular. Per tant, la similitud de seqüència possiblement fa referència a una conservació en el mecanisme d'acció més que no pas a una conservació funcional. La possible interacció de MARK amb el domini C-terminal de MIK (el domini regulador) podria activar aquesta última iniciant una cascada de transducció del senyal en un model en el que una proteïna del tipus GCK-III faria de lligam directa entre un receptor de membrana i una cascada de senyalització intracel.lular. Aquest tipus de lligam entre un recepctor de membrana i mòduls intracel.lulars de senyalització s'ha descrit per a altres proteïnes GCK, si bé no directament sinó a través de proteïnes adaptadores. D'altra banda, la interacció directa de MARK, un receptor quinasa atípic que no té activitat catalítica, amb MIK suggereix un mecanisme on receptors atípics podrien interaccionar en la transducció del senyal activant la via de les MAPK.

Neuroinflammation and its modulation by flavonoids

There is increasing evidence to suggest that neuroinflammatory processes contribute to the cascade of events that lead to the progressive neuronal damage observed in neurodegenerative disorders such as Parkinson’s disease and Alzheimer’s disease. Therefore, treatment regimes aimed at modulating neuroinflammatory processes may act to slow the progression of these debilitating brain disorders. Recently, a group of dietary polyphenols known as flavonoids have been shown to exert neuroprotective effects in vivo and in neuronal cell models. In this review we discuss the evidence relating to the modulation of neuroinflammation by flavonoids. We highlight the evidence which suggests their mechanism of action involves: 1) attenuation of the release of cytokines, such as interleukin-1β (IL-1β) and tumor necrosis factor-alpha (TNF-α); 2) an inhibitory action against inducible nitric oxide synthase (iNOS) induction and subsequent nitric oxide (NO•) production; 3) inhibition of the activation of NADPH oxidase and subsequent reactive oxygen species generation; 4) a capacity to down-regulate the activity of pro-inflammatory transcription factors such as nuclear factor-κB (NF-κB); and 5) the potential to modulate signalling pathways such as mitogen-activated protein kinase (MAPK) cascade. We also consider the potential of these dietary compounds to represent novel therapeutic agents by considering their metabolism in the body and their ability to access the brain via the blood brain barrier. Finally, we discuss future areas of study which are necessary before dietary flavonoids can be established as therapeutic agents against neuroinflammation.

The citrus flavanone naringenin inhibits inflammatory signalling in glial cells and protects against neuroinflammatory injury

Neuroinflammation plays an integral role in the progression of neurodegeneration. In this study we investigated the anti-inflammatory effects of different classes of flavonoids (flavanones, flavanols and anthocyanidins) in primary mixed glial cells. We found that the flavanones naringenin and hesperetin and the flavols (+)-catechin and (-)-epicatechin, but not the anthocyanidins cyanidin and pelargonidin, attenuated LPS/IFN-gamma-induced TNF-alpha production in glial cells. Naringenin also inhibited LPS/IFN-gamma-induced iNOS expression and nitric oxide production in glial cells, thus showing the strongest antiinflammatory activity among all flavonoids tested. Moreover, naringenin protected against inflammatory-induced neuronal death in a primary neuronal-glial co-culture system. Naringenin also inhibited LPS/IFN-gamma-induced p38 mitogen-activated protein kinase (MAPK) phosphorylation and downstream signal transducer and activator of transcription-1 (STAT-1) in LPS/IFN-gamma stimulated primary mixed glial cells. Taken together, our results suggest that naringenin may produce an anti-inflammatory effect in LPS/IFN-gamma stimulated glial cells that may be due to its interaction with p38 signalling cascades and the STAT-I trascription factor. (C) 2009 Elseiver Inc. All rights reserved.

The interactions of flavonoids within neuronal signalling pathways

Emerging evidence suggests that dietary phytochemicals, in particular flavonoids, may exert beneficial effects in the central nervous system by protecting neurons against stress-induced injury, by suppressing neuroinflammation and by promoting neurocognitive performance, through changes in synaptic plasticity. It is likely that flavonoids exert such effects in neurons, through selective actions on different components within a number of protein kinase and lipid kinase signalling cascades, such as phosphatidylinositol-3 kinase (PI3K)/Akt, protein kinase C and mitogen-activated protein kinase. This review details the potential inhibitory or stimulatory actions of flavonoids within these pathways, and describes how such interactions are likely to affect cellular function through changes in the activation state of target molecules and/or by modulating gene expression. Although, precise sites of action are presently unknown, their abilities to: (1) bind to ATP binding sites on enzymes and receptors; (2) modulate the activity of kinases directly; (3) affect the function of important phosphatases; (4) preserve neuronal Ca2+ homeostasis; and (5) modulate signalling cascades lying downstream of kinases, are explored. Future research directions are outlined in relation to their precise site(s) of action within the signalling pathways and the sequence of events that allow them to regulate neuronal function in the central nervous system.

The impact of fruit flavonoids on memory and cognition

There is intense interest in the studies related to the potential of phytochemical-rich foods to prevent age-related neurodegeneration and cognitive decline. Recent evidence has indicated that a group of plant-derived compounds known as flavonoids may exert particularly powerful actions on mammalian cognition and may reverse age-related declines in memory and learning. In particular, evidence suggests that foods rich in three specific flavonoid sub-groups, the flavanols, anthocyanins and/or flavanones, possess the greatest potential to act on the cognitive processes. This review will highlight the evidence for the actions of such flavonoids, found most commonly in fruits, such as apples, berries and citrus, on cognitive behaviour and the underlying cellular architecture. Although the precise mechanisms by which these flavonoids act within the brain remain unresolved, the present review focuses on their ability to protect vulnerable neurons and enhance the function of existing neuronal structures, two processes known to be influenced by flavonoids and also known to underpin neuro-cognitive function. Most notably, we discuss their selective interactions with protein kinase and lipid kinase signalling cascades (i.e. phosphoinositide-3 kinase/Akt and mitogen-activated protein kinase pathways), which regulate transcription factors and gene expression involved in both synaptic plasticity and cerebrovascular blood flow. Overall, the review attempts to provide an initial insight into the potential impact of regular flavonoid-rich fruit consumption on normal or abnormal deteriorations in cognitive performance.

Beyond antioxidants: the cellular and molecular interactions of flavonoids and how these underpin their actions on the brain

The consumption of flavonoid-rich foods and beverages has been suggested to limit the neurodegeneration associated with a variety of neurological disorders and to prevent or reverse normal or abnormal deteriorations in cognitive performance. Flavonoids mediate these effects via a number of routes, including a potential to protect neurons against injury induced by neurotoxins, an ability to suppress neuroinflammation and a potential to promote memory, learning and cognitive function. Originally, it was thought that such actions were mediated by the antioxidant capacity of flavonoids. However, their limited absorption and their low bioavailability in the brain suggest that this explanation is unlikely. Instead, this multiplicity of effects appears to be underpinned by three separate processes: first, through their interactions with important neuronal and glial signalling cascades in the brain, most notably the phosphatidylinositol 3-kinase/Akt and mitogen-activated protein kinase pathways that regulate pro-survival transcription factors and gene expression; second, through an ability to improve peripheral and cerebral blood flow and to trigger angiogenesis and neurogenesis in the hippocampus; third, by their capacity to directly react with and scavenge neurotoxic species and pro-inflammatory agents produced in the brain as a result of both normal and abnormal brain ageing. The present review explores the potential inhibitory or stimulatory actions of flavonoids within these three systems and describes how such interactions are likely to underlie neurological effects.

Endothelin signalling in the cardiac myocyte and its pathophysiological relevance

Endothelin A (ET(A)) transmembrane receptors predominate in rat cardiac myocytes. These are G protein-coupled receptors whose actions are mediated by the G(q) heterotrimeric G proteins. Through these, ET-1 binding to ET(A)-receptors stimulates the hydrolysis of membrane phosphatidylinositol 4,5-bisphosphate to diacylglycerol and inositol 1,4,5-trisphosphate. Diacylglycerol remains in the membrane whereas inositol 1,4,5-trisphosphate is soluble (though its importance in the cardiac myocyte is still debated). Isoforms of the phospholipid-dependent protein kinase, protein kinase C (PKC), are intracellular receptors for diacylglycerol. Cytoplasmic nPKCdelta and nPKCepsilon detect increases in membrane diacylglycerols and translocate to the membrane. This brings about PKC activation, though modifications additional to binding to phospholipids and diacylglycerol are involved. The next event (probably associated with PKC activation) is the activation of the membrane-bound small G protein Ras by exchange of GTP for GDP. Ras.GTP loading translocates Raf family mitogen-activated protein kinase (MAPK) kinase kinases to the membrane, initiates the activation of Raf, and thus activates the extracellular signal-regulated kinase 1/2 (ERK1/2) cascade. Over longer times, two analogous protein kinase cascades, the c-Jun N-terminal kinase and p38-mitogen-activated protein kinase cascades, become activated. As the signals originating from the ET(A) receptor are transmitted through these protein kinase pathways, other signalling molecules become phosphorylated, thus changing their biological activities. For example, ET-1 increases the expression of the c-jun transcription factor gene, and increases abundance and phosphorylation of c-Jun protein. These changes in c-Jun expression and phosphorylation are likely to be important in the regulation of gene transcription.

Inflame my heart (by p38-MAPK).

Although many studies have explored the stimuli which promote hypertrophic growth or death in cardiac myocytes and the signaling pathways which they activate, the mechanisms by which these pathways promote the pathophysiological responses are still obscure. The mitogen-activated protein kinase (MAPK) cascades (in which MAPKs are phosphorylated and activated by upstream MAPK kinases [MKKs] which are, in turn, phosphorylated and activated by MKK kinases [MKKKs]) were identified in the early- to mid-1990s as potentially key regulatory pathways in cardiac myocyte pathophysiology.1,2 The principal MAPKs investigated in cardiac myocytes are the extracellular signal-regulated kinases 1/2 (ERK1/2), c-Jun N-terminal kinases (JNKs), and p38-MAPKs. ERK1/2 are potently activated by hypertrophic stimuli, whereas JNKs and p38-MAPKs are potently activated by cellular stresses (eg, oxidative stress). However, there is cross-talk such that JNKs and p38-MAPKs are activated by hypertrophic stimuli and ERK1/2 are activated by cellular stresses, and the contribution of each pathway to the overall cardiac myocyte response is not entirely clear. MAPKs phosphorylate a number of known transcription factors to alter their transactivating activities thus, presumably, influencing gene expression to elicit the cellular response.3 Nevertheless, the immediate consequences (ie, the transcription factors which are phosphorylated) and downstream consequences (ie, genes with altered expression) of MAPK signaling in the heart or specifically in cardiac myocytes are still largely unknown. To start to address this issue for the p38-MAPK pathway in the (rat) heart (Figure), Tenhunen et al4 directly injected adenoviruses encoding wild-type (WT) p38-MAPKα together …

Oxidative stress and growth-regulating intracellular signaling pathways in cardiac myocytes

The toxic effects of oxidative stress on cells (including cardiac myocytes, the contractile cells of the heart) are well known. However, an increasing body of evidence has suggested that increased production of reactive oxygen species (ROS) promotes cardiac myocyte growth. Thus, ROS may be 'second messenger' molecules in their own right, and growth-promoting neurohumoral agonists might exert their effects by stimulating production of ROS. The authors review the principal growth-promoting intracellular signaling pathways that are activated by ROS in cardiac myocytes, namely the mitogen-activated protein kinase cascades (extracellular signal-regulated kinases 1/2, c-Jun N-terminal kinases, and p38-mitogen-activated protein kinases) and the phosphoinositide 3-kinase/protein kinase B (Akt) pathway. Possible mechanisms are discussed by which these pathways are activated by ROS, including the oxidation of active site cysteinyl residues of protein and lipid phosphatases with their consequent inactivation, the potential involvement of protein kinase C or the apoptosis signal-regulating kinase 1, and the current models for the activation of the guanine nucleotide binding protein Ras.

Integration of steroid hormone initiated membrane action to genomic function in the brain

Estrogen is a ligand for the estrogen receptor (ER), which on binding 17beta-estradiol, functions as a ligand-activated transcription factor and regulates the transcription of target genes. This is the slow genomic mode of action. However, rapid non-genomic actions of estrogen also exist at the cell membrane. Using a novel two-pulse paradigm in which the first pulse rapidly initiates non-genomic actions using a membrane-limited estrogen conjugate (E-BSA), while the second pulse promotes genomic transcription from a consensus estrogen response element (ERE), we have demonstrated that rapid actions of estrogen potentiate the slower transcriptional response from an ERE-reporter in neuroblastoma cells. Since rapid actions of estrogen activate kinases, we used selective inhibitors in the two-pulse paradigm to determine the intracellular signaling cascades important in such potentiation. Inhibition of protein kinase A (PKA), PKC, mitogen activated protein kinase (MAPK) or phosphatidylinositol 3-OH kinase (PI-3K) in the first pulse decreases potentiation of transcription. Also, our data with both dominant negative and constitutive mutants of Galpha subunits show that Galpha(q) initiates the rapid signaling cascade at the membrane in SK-N-BE(2)C neuroblastoma cells. We discuss two models of multiple kinase activation at the membrane Pulses of estrogen induce lordosis behavior in female rats. Infusion of E-BSA into the ventromedial hypothalamus followed by 17beta-estradiol in the second pulse could induce lordosis behavior, demonstrating the applicability of this paradigm in vivo. A model where non-genomic actions of estrogen couple to genomic actions unites both aspects of hormone action.

Thyroid hormone can increase estrogen-mediated transcription from a consensus estrogen response element in neuroblastoma cells

Thyroid hormones (T) and estrogens (E) are nuclear receptor ligands with at least two molecular mechanisms of action: (i) relatively slow genomic effects, such as the regulation of transcription by cognate T receptors (TR) and E receptors (ER); and (ii) relatively rapid nongenomic effects, such as kinase activation and calcium release initiated at the membrane by putative membrane receptors. Genomic and nongenomic effects were thought to be disparate and independent. However, in a previous study using a two-pulse paradigm in neuroblastoma cells, we showed that E acting at the membrane could potentiate transcription from an E-driven reporter gene in the nucleus. Because both T and E can have important effects on mood and cognition, it is possible that the two hormones can act synergistically. In this study, we demonstrate that early actions of T via TRalpha1 and TRbeta1 can potentiate E-mediated transcription (genomic effects) from a consensus E response element (ERE)-driven reporter gene in transiently transfected neuroblastoma cells. Such potentiation was reduced by inhibition of mitogen-activated protein kinase. Using phosphomutants of ERalpha, we also show that probable mitogen-activated protein kinase phosphorylation sites on the ERalpha, the serines at position 167 and 118, are important in TRbeta1-mediated potentiation of ERalpha-induced transactivation. We suggest that crosstalk between T and E includes potential interactions through both nuclear and membrane-initiated molecular mechanisms of hormone signaling.

Estrogens and thyroid hormone: Non-genomic effects are coupled to transcription.

Estrogens and thyroid hormones are regulators of important diverse physiological processes such as reproduction, thermogenesis, neural development, neural differentiation and cardiovascular functions. Both are ligands for receptors in the nuclear receptor superfamily, which act as ligand-dependent transcription factors, regulating transcription. However, estrogens and thyroid hormones also rapidly (within minutes or seconds) activate kinase cascades and calcium increases, presumably initiated at the cell membrane. We discuss the relevance of both modes of hormone action, including the membrane estrogen receptor, to physiology, with particular reference to lordosis behavior. We first showed that estrogen restricted to the membrane can, in fact, lead to subsequent increases in transcription from a consensus estrogen response element-based reporter in the neuroblastoma cell line, SK-N-BE(2)C. Using a novel hormonal paradigm, we also showed that the activation of protein kinase A, protein kinase C, mitogen activated protein kinase and increases in calcium were important in the ability of the membrane-limited estrogen to potentiate transcription. We discuss the source of calcium important in transcriptional potentiation. Since estrogens and thyroid hormones have common effects on neuroprotection, cognition and mood, we also hypothesized that crosstalk could occur between the rapid actions of thyroid hormones and the genomic actions of estrogens. In neural cells, we showed that triiodothyronine acting rapidly via MAPK can increase transcription by the nuclear estrogen receptor ERa from a consensus estrogen response element, possibly by the phosphorylation of the ERa. Novel mechanisms that link signals initiated by hormones from the membrane to the nucleus are physiologically relevant and can achieve neuroendocrine integration

Estrogen receptor-mediated transcription involves the activation of multiple kinase pathways in neuroblastoma cells

While many physiological effects of estrogens (E) are due to regulation of gene transcription by liganded estrogen receptors (ERs), several effects are also mediated, at least in part, by rapid non-genomic actions of E. Though the relative importance of rapid versus genomic effects in the central nervous system is controversial, we showed previously that membrane-limited effects of E, initiated by an estradiol bovine serum albumin conjugate (E2-BSA), could potentiate transcriptional effects of 17beta-estradiol from an estrogen response element (ERE)-reporter in neuroblastoma cells. Here, using specific inhibitors and activators in a pharmacological approach, we show that activation of phosphatidylinositol-3-phosphate kinase (PI3K) and mitogen activated protein kinase (MAPK) pathways, dependent on a Galphaq coupled receptor signaling are important in this transcriptional potentiation. We further demonstrate, using ERalpha phospho-deficient mutants, that E2-BSA mediated phosphorylation of ERalpha is one mechanism to potentiate transcription from an ERE reporter construct. This study provides a possible mechanism by which signaling from the membrane is coupled to transcription in the nucleus, providing an integrated view of hormone signaling in the brain.

Effect of Mussel`s Gender and Size on a Stress Response Biomarker

In mussels, stress signals such as heat, osmotic shock and hypoxia lead to the activation of the phosphorylated p38 mitogen activated protein kinase (pp38-MAPK). This stress activated protein has been efficiently used as a biomarker to several natural and anthropogenic stresses. However, what has not been tested is whether differences in gender or size can affect the response of this biomarker. The present study tested whether there was variation in the expression of pp38-MAPK in mussels Perna perna of different gender and size classes when exposed to natural stress conditions, such as air exposure. The results show that gender does not affect the expression of pp38-MAPK. However, size does have an effect, where mussels smaller than 6.5 cm displayed significantly (p < 0.05) lower levels of pp38-MAPK when compared to those larger than 7 cm. Mussels are one of the most used bioindicator species and the use of biomarkers to determine the health status of an ecosystem has been greatly increasing over the years. The present study highlights the importance of using mussels of similar size classes when performing experiments using stress-related biomarkers.

Amyloid beta-peptide activates nuclear factor-kappa B through an N-methyl-D-aspartate signaling pathway in cultured cerebellar cells

Amyloid P-peptide (A beta) likely causes functional alterations in neurons well prior to their death. Nuclear factor-kappa B (NF-kappa B), a transcription factor that is known to play important roles in cell survival and apoptosis, has been shown to be modulated by A beta in neurons and glia, but the mechanism is unknown. Because A beta has also been shown to enhance activation of N-methyl-D-aspartate (NMDA) receptors, we investigated the role of NMDA receptor-mediated intracellular signaling pathways in A beta-induced NF-kappa B activation in primary cultured rat cerebellar cells. Cells were treated with different concentrations of A beta 1-40 (1 or 2 mu M) for different periods (6, 12, or 24 hr). MK-801 (NMDA antagonist), manumycin A and FTase inhibitor 1 (farnesyltransferase inhibitors), PP1 (Src-family tyrosine kinase inhibitor), PD98059 [mitogen-activated protein kinase (MAPK) inhibitor], and LY294002 [phosphatidylinositol 3-kinase (PI3-k) inhibitor] were added 20 min before A beta treatment of the cells. A beta induced a time- and concentration-dependent activation of NF-kappa B (1 mu M, 12 hr); both p50/p65 and p50/p50 NF-kappa B dimers were involved. This activation was abolished by MK-801 and attenuated by manumycin A, FTase inhibitor 1, PP1, PD98059, and LY294002. AP at 1 mu M increased the expression of inhibitory protein I kappa B, brain-derived neurotrophic factor, inducible nitric oxide synthase, tumor necrosis factor-alpha, and interleukin-1 beta as shown by RTPCR assays. Collectively, these findings suggest that AP activates NF-kappa B by an NMDA-Src-Ras-like protein through MAPK and PI3-k pathways in cultured cerebellar cells. This pathway may mediate an adaptive, neuroprotective response to A beta. (c) 2007 Wiley-Liss, Inc.