Galanin and galanin fragment 1-15 modulate antidepressant responses by targeting 5-HT1AR-GALR heteroreceptor complexes of the ascending midbrain serotonin pathways.

Mood disorders, including depression and anxiety, are among the most prevalent mental illnesses with high socioeconomic impact. Although the underlying mechanisms have not yet been clearly defined in the last decade the importance of the role of neuropeptides, including Galanin (GAL), and/or their receptors in the treatment of stress-related mood disorders is becoming increasingly apparent. GAL is involved in mood regulation, including depression-related and anxiety-like behaviors. Activation of GALR1 and GALR3 receptors results in a depression like behavior while stimulation of GALR2 receptor leads to anti-depressant-like effects. Moreover, GAL modulates 5-HT1A receptors (5-HT1AR), a key receptor in depression at autoreceptor and postsynaptic level in the brain. This interaction can in part be due to the existence of GALR1-5-HT1AR heteroreceptor complexes in discrete brain regions [1]. Not only GAL but also the N-terminal fragments like GAL(1-15) are active in the Central Nervous System [2, 3]. Recently, we described that GAL(1-15) induces strong depression-related and anxiogenic-like effects in rats, and these effects were significantly stronger than the ones induced by GAL [4]. The GALR1-GALR2 heteroreceptor complexes in the dorsal hippocampus and especially in the dorsal raphe (DR), areas rich in GAL(1-15) binding sites [5] were involved in these effects [4, 6] and demonstrated also in cellular models. In the present study, we have analyzed the ability of GAL(1-15) to modulate 5-HT1AR located at postjunctional sites and at the soma-dendritic level in rats. We have analyzed the effect of GAL(1-15) on the 5-HT1AR-mediated response in a behavioral test of depression and the involvement of the GALR2 in these effects. GAL(1-15) enhanced the antidepressant effects induced by the 5-HT1AR agonist 8-OH-DPAT in the forced swimming test [7]. These effects were stronger than the ones induced by GAL. The mechanism of this action involved interactions at the receptor level in the plasma membrane with changes also at the transcriptional level. Thus, GAL(1-15) affected the binding characteristics as well as the mRNA level of 5-HT1AR in the dorsal hippocampus and DR. GALR2 was involved in these effects, since the specific GALR2 antagonist M871 blocked GAL(1-15) mediated actions at the behavioral and receptor level [7]. Furthermore, the results on the proximity ligation assay (PLA) in this work suggest the existence of GALR1-GALR2-5-HT1AR heteroreceptor complexes since positive PLA were obtained for both GALR1-5-HT1AR and GALR2-5-HT1AR complexes in the DR and hippocampus. Moreover the studies on RN33B cells, where GALR1, GALR2 and 5-HT1AR exist [4], also showed PLA-positive clusters indicating the existence of GALR1-5-HT1AR and GALR2-5-HT1AR complexes in these cells [7]. In conclusion, our results indicate that GAL(1–15) enhances the antidepressant effects induced by the 5-HT1AR agonist 8-OH-DPAT probably acting on GALR1-GALR2-5-HT1AR heteroreceptor located at postjunctional sites and at the soma-dendritic level. The development of new drugs specifically targeting these heteroreceptor complexes may offer a novel strategy for treatment of depression. This work has been supported by Junta de Andalucia CVI646 1. Borroto-Escuela, D.O., et al., Galanin receptor-1 modulates 5-hydroxtryptamine-1A signaling via heterodimerization. Biochem Biophys Res Commun, 2010. 393(4): p. 767-72. 2. Hedlund, P.B. and K. Fuxe, Galanin and 5-HT1A receptor interactions as an integrative mechanism in 5-HT neurotransmission in the brain. Ann N Y Acad Sci, 1996. 780: p. 193-212. 3. Diaz-Cabiale, Z., et al., Neurochemical modulation of central cardiovascular control: the integrative role of galanin. EXS, 2010. 102: p. 113-31. 4. Millon, C., et al., A role for galanin N-terminal fragment (1-15) in anxiety- and depression-related behaviors in rats. Int J Neuropsychopharmacol, 2015. 18(3). 5. Hedlund, P.B., N. Yanaihara, and K. Fuxe, Evidence for specific N-terminal galanin fragment binding sites in the rat brain. Eur J Pharmacol, 1992. 224(2-3): p. 203-5. 6. Borroto-Escuela, D.O., et al., Preferential activation by galanin 1-15 fragment of the GalR1 protomer of a GalR1-GalR2 heteroreceptor complex. Biochem Biophys Res Commun, 2014. 452(3): p. 347-53. 7. Millon, C., et al., Galanin (1-15) enhances the antidepressant effects of the 5-HT1A receptor agonist 8-OH-DPAT: involvement of the raphe-hippocampal 5-HT neuron system. Brain Struct Funct, 2016.

Perfil conductual de las drogas de diseño MBDB, MDEA y PMA en modelos animales de agresión y ansiedad

MBDB, MDEA y PMA son tres drogas de diseño, estructuralmente similares al MDMA (“éxtasis”), que se han identificado en la composición de pastillas distribuidas como “éxtasis” en entornos recreativos durante los últimos treinta años. Estas feniletilaminas sintéticas presentan un perfil psicotrópico de tipo entactógeno (con capacidad para facilitar la proximidad, el contacto y la comunicación empática), similar al del MDMA en el modelo de discriminación de drogas. El MDMA ha sido objeto de un creciente interés científico y es, hasta la fecha, la única sustancia con un perfil entactógeno de la que se han investigado sus efectos conductuales en modelos animales de agresión y ansiedad, si bien sus resultados no siempre coinciden. Aunque existen algunas evidencias de que el MDMA puede tener efectos ansiolíticos en animales de laboratorio (Lin, Burden, Christie, & Johnston, 1999; Morley & McGregor, 2000; Ho, Pawlak, Guo, & Schwarting, 2004), en otros estudios se han observado alteraciones conductuales y correlatos neuroquímicos que sugieren un efecto ansiogénico (Bhattacharya, Bhattacharya & Ghosal, 1998; Gurtman, Morley, Li, Hunt, & McGregor, 2002; Maldonado & Navarro, 2000;; Navarro & Maldonado, 2002). Asimismo, en otros trabajos se ha señalado que el MDMA induce efectos antiagresivos (reducción de las conductas de amenaza y ataque), que se acompañan de un marcado aumento de las conductas de evitación/huida y defensa/sumisión, así como de una reducción de las conductas de investigación social, sugiriendo también la existencia de un perfil ansiogénico en los encuentros agonísticos entre ratones machos (Maldonado & Navarro, 2001; Navarro & Maldonado, 1999). En contraste, hasta la fecha la información experimental de las drogas MBDB, MDEA y PMA se limita a la evaluación de sus efectos conductuales sobre la conducta motora, así como algunos estudios sobre su metabolismo y posible mecanismo de acción. El objetivo general de este trabajo de investigación ha sido estudiar el perfil conductual de MBDB, MDEA y PMA en modelos animales de agresión y ansiedad. Para ello, se han examinado los efectos del MBDB (2, 4 y 8 mg/kg), MDEA (5, 10 y 20 mg/kg) y PMA (2, 4, 8 y 12 mg/kg) utilizando el modelo de agresión inducida por aislamiento y el modelo de ansiedad del laberinto elevado en cruz en ratones machos. Los resultados indican que estas sustancias en general comparten un perfil antiagresivo inespecífico. Esta falta de especificidad se debe en unos casos al aumento de las conductas de inmovilidad (4-12 mg/kg PMA), pero también a la presencia de propiedades ansiogénicas durante la interacción social, en especial con dosis elevadas, mientras que solo las dosis más bajas parecen aumentar la proximidad social, en especial la dosis menor de MBDB. Además, estas drogas parecen alterar el patrón conductual agonístico ofensivo (MBDB y MDEA) y defensivo (MBDB, MDEA y PMA), produciendo cambios diádicos que resultan coherentes con un aumento del nivel de conflicto y de ansiedad. En consonancia, los resultados del modelo del laberinto elevado en cruz indican que el MBDB produce un aumento de la ansiedad de menor intensidad que el producido por el MDMA. Sin embargo, MDEA y PMA parecen generar un estado de hipoexploración, y solo en dosis determinadas (20 mg/kg de MDEA y 4 mg/kg de PMA) muestran alteraciones discretas que sugieren un efecto ansiogénico débil, un perfil que en conjunto podría sugerir cierta similitud con alteraciones conductuales propias de los compuestos alucinógenos. Debido a la diferencia del perfil conductual del MDEA y PMA hallados en ambos modelos, sería necesario evaluar la ansiedad y su posible relación con la dosis y/o con la presencia de un oponente en la prueba en otros modelos experimentales. Lin, H. Q., Burden, P. M., Christie, M. J., & Johnston, G. A. R. (1999). The anxiogenic-like and anxiolytic-like effects of MDMA on mice in the elevated plus-maze: A comparison with amphetamine. Pharmacology, Biochemistry and Behavior, 62(3), 403-408. Morley, K. C., & McGregor, I. S. (2000). (±)-3,4-methylenedioxymethamphetamine (MDMA, 'ecstasy') increases social interaction in rats. European Journal of Pharmacology, 408(1), 41-49. Bhattacharya, S. K., Bhattacharya, A., & Ghosal, S. (1998). Anxiogenic activity of methylenedioxymethamphetamine (Ecstasy): An experimental study. Biogenic Amines, 14(3), 217-237. Gurtman, C. G., Morley, K. C., Li, K. M., Hunt, G. E., & McGregor, I. S. (2002). Increased anxiety in rats after 3,4-methylenedioxymethamphetamine: Association with serotonin depletion. European Journal of Pharmacology, 446(1-3), 89-96. Ho, Y., Pawlak, C. R., Guo, L., & Schwarting, R. K. W. (2004). Acute and long-term consequences of single MDMA administration in relation to individual anxiety levels in the rat. Behavioural Brain Research, 149(2), 135-144. Maldonado, E., & Navarro, J. F. (2000). Effects of 3,4-methylenedioxy-methamphetamine (MDMA) on anxiety in mice tested in the light/dark box. Progress in Neuro-Psychopharmacology and Biological Psychiatry, 24(3), 463-472. Maldonado, E., & Navarro, J. F. (2001b). MDMA ('ecstasy') exhibits an anxiogenic-like activity in social encounters between male mice. Pharmacological Research, 44(1), 27-31. Navarro, J. F., & Maldonado, E. (1999). Behavioral profile of 3,4-methylenedioxy-methamphetamine (MDMA) in agonistic encounters between male mice. Progress in Neuro-Psychopharmacology and Biological Psychiatry, 23(2), 327-334. Navarro, J. F., & Maldonado, E. (2002). Acute and subchronic effects of MDMA ("ecstasy") on anxiety in male mice tested in the elevated plus-maze. Progress in Neuro-Psychopharmacology and Biological Psychiatry, 26(6), 1151-1154.

Structural and functional interaction between polyamine related molecules and biological membranes

Changes induced by PA on nucleic acid (NA) conformation and synthesis is proven to be a major reason for PA essentiality (1-3). However, PA interactions with other polyanions, for instance polyanionic membrane lipid bilayers and glyosaminoglycans have received less attention (3-4). The functional importance of these interactions still is an obscure but interesting area of cell and molecular biology, especially in mammalian cells for which specific PA transport systems are not fully characterized (5). In mammals, activity and turnover of the polyamine (PA) synthesis key enzyme is controlled by a set of proteins: Antizymes (OAZ1-3) and antizyme inhibitors (AZIN1 and 2). It is demonstrated that AOZ modulate polyamine uptake (6), and that PA transport to mitochondria is linked to the respiratory chain state and modulates mitochondrial permeability transition (7). Antizyme expression variants have been located in mitochondria, being proposed as a proapoptotic factor (7-8). AZIN 2 is only expressed in a reduced set of tissues that includes mast cells, where it is associated to mast cell granules membrane (9). This fact, together to the abnormalities observed in bone marrow derived mast cell granules when they are differentiated under restricted PA synthesis conditions (10 and unpublished results), point out to important roles of PA and their related proteins in structure and function of mast cell granules. We will also present novel biophysical results on tripartite interactions of PA that remark the interest of the characterization of PA interactions with lipid bilayers for biomedicine and biotechnology. Thus, the information reported in this paper integrates previously reported information with our still unpublished results, all indicating that PA and their related proteins also are important factors for structure and dynamics of biological membranes and their associated functions essential in human physiology; for instance, solute interchange with the environment (uptake and secretion), oxidative metabolism and apoptosis. The importance of these involved processes for human homeostasis claim for further research efforts. 1. Ruiz-Chica J, Medina MA, Sánchez-Jiménez F and Ramírez FJ (2001) Fourier Transform Raman study of the structural specificities on the interaction between DNA and biogenic polyamines. Biophysical J. 80:443-454. 2. Lightfoot HL, Hall J (2014) Endogenous polyamine function--the RNA perspective. Nucleic Acids Res. 42:11275-11290. 3. Igarashi K, Kashiwagi K (2010) Modulation of cellular function by polyamines. Int J Biochem Cell Biol. 42:39-51. 4. Finger S, Schwieger C, Arouri A, Kerth A, Blume A (2014) Interaction of linear polyamines with negatively charged phospholipids: the effect of polyamine charge distance. Biol Chem. 395:769-778. 5. Poulin R, Casero RA, Soulet D. (2012) Recent advances in the molecular biology of metazoan polyamine transport. Amino Acids. 42:711-723. 6. Kahana C (2009) Regulation of cellular polyamine levels and cellular proliferation by antizyme and antizyme inhibitor. Essays Biochem. 4:47-61. 7. Agostinelli E, Marques MP, Calheiros R, Gil FP, Tempera G, Viceconte N, Battaglia V, Grancara S, Toninello A (2010) Polyamines: fundamental characters in chemistry and biology. Amino Acids 38:393-403. 8. Liu GY, Liao YF, Hsu PC, Chang WH, Hsieh MC, Lin CY, Hour TC, Kao MC, Tsay GJ, Hung HC (2006) Antizyme, a natural ornithine decarboxylase inhibitor, induces apoptosis of haematopoietic cells through mitochondrial membrane depolarization and caspases' cascade. Apoptosis 11:1773-1788. 9. Kanerva K, Lappalainen J, Mäkitie LT, Virolainen S, Kovanen PT, Andersson LC (2009). Expression of antizyme inhibitor 2 in mast cells and role of polyamines as selective regulators of serotonin secretion. PLoS One 31:e6858. 10. García-Faroldi G, Rodríguez CE, Urdiales JL, Pérez-Pomares JM, Dávila JC, Pejler G, Sánchez-Jiménez F, Fajardo I (2010) Polyamines are present in mast cell secretory granules and are important for granule homeostasis. PLoS One 30:e15071.