Literature DB >> 18462884

Prenatal expression of cholecystokinin (CCK) in the central nervous system (CNS) of mouse.

Paolo Giacobini1, Susan Wray.   

Abstract

Cholecystokinin (CCK) is a peptide found in both gut and brain. Although numerous studies address the role of brain CCK postnatally, relatively little is known about the ontogeny of CCK expression in the central nervous system (CNS). Recent work revealed that CCK modulates olfactory axon outgrowth and gonadotropin-releasing hormone-1 (GnRH-1) neuronal migration, suggesting that CCK may be an important factor during CNS development. To further characterize the developmental expression of CCK in the nervous system, in situ hybridization experiments were performed. CCK mRNA expression was widely distributed in the developing mouse brain. As early as E12.5, robust CCK expression is detected in the thalamus and spinal cord. By E17.5, cells in the cortex, hippocampus, thalamus and hypothalamus express CCK. In addition, CCK mRNA was also detected in the external zone of the median eminence where axons of the neuroendocrine hypophysiotropic systems terminate. Our study demonstrates that CCK mRNA is expressed prenatally in multiple areas of the CNS, many of which maintain CCK mRNA expression postnatally into adult life. In addition, we provide evidence that regions of the CNS known to integrate hormonal and sensory information associated with reproduction and the GnRH-1 system, expressed CCK already during prenatal development.

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Year:  2008        PMID: 18462884      PMCID: PMC2478750          DOI: 10.1016/j.neulet.2008.04.042

Source DB:  PubMed          Journal:  Neurosci Lett        ISSN: 0304-3940            Impact factor:   3.046


  30 in total

Review 1.  International Union of Pharmacology. XXI. Structure, distribution, and functions of cholecystokinin receptors.

Authors:  F Noble; S A Wank; J N Crawley; J Bradwejn; K B Seroogy; M Hamon; B P Roques
Journal:  Pharmacol Rev       Date:  1999-12       Impact factor: 25.468

2.  Phenotypical segregation among female rat hypothalamic gonadotropin-releasing hormone neurons as revealed by the sexually dimorphic coexpression of cholecystokinin and neurotensin.

Authors:  P Ciofi
Journal:  Neuroscience       Date:  2000       Impact factor: 3.590

Review 3.  Endocannabinoids in the central nervous system: from neuronal networks to behavior.

Authors:  Ester Fride
Journal:  Curr Drug Targets CNS Neurol Disord       Date:  2005-12

4.  Subcellular localization of preprogalanin messenger RNA in perikarya and axons of hypothalamo-posthypophyseal magnocellular neurons: an in situ hybridization study.

Authors:  M Landry; T Hökfelt
Journal:  Neuroscience       Date:  1998-06       Impact factor: 3.590

5.  Cholecystokinin directly inhibits neuronal activity of primary gonadotropin-releasing hormone cells through cholecystokinin-1 receptor.

Authors:  Paolo Giacobini; Susan Wray
Journal:  Endocrinology       Date:  2006-10-05       Impact factor: 4.736

6.  Murine prenatal expression of cholecystokinin in neural crest, enteric neurons, and enteroendocrine cells.

Authors:  J M Lay; P J Gillespie; L C Samuelson
Journal:  Dev Dyn       Date:  1999-10       Impact factor: 3.780

Review 7.  An introduction to neuronal cholecystokinin.

Authors:  M C Beinfeld
Journal:  Peptides       Date:  2001-08       Impact factor: 3.750

Review 8.  The physiology of learning and memory: role of peptides and stress.

Authors:  M A Gülpinar; B C Yegen
Journal:  Curr Protein Pept Sci       Date:  2004-12       Impact factor: 3.272

Review 9.  Cholecystokinin and learning and memory processes.

Authors:  Christina Hadjiivanova; Stiliana Belcheva; Iren Belcheva
Journal:  Acta Physiol Pharmacol Bulg       Date:  2003

10.  Cholecystokinin modulates migration of gonadotropin-releasing hormone-1 neurons.

Authors:  Paolo Giacobini; Alan S Kopin; Philip M Beart; Linda D Mercer; Aldo Fasolo; Susan Wray
Journal:  J Neurosci       Date:  2004-05-19       Impact factor: 6.167
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  6 in total

1.  Amygdala nuclei critical for emotional learning exhibit unique gene expression patterns.

Authors:  Alexander C Partin; Matthew P Hosek; Jonathan A Luong; Srihari K Lella; Sachein A R Sharma; Jonathan E Ploski
Journal:  Neurobiol Learn Mem       Date:  2013-07-02       Impact factor: 2.877

2.  Functional Differentiation of Cholecystokinin-Containing Interneurons Destined for the Cerebral Cortex.

Authors:  Daniela Calvigioni; Zoltán Máté; János Fuzik; Fatima Girach; Ming-Dong Zhang; Andrea Varro; Johannes Beiersdorf; Christian Schwindling; Yuchio Yanagawa; Graham J Dockray; Chris J McBain; Tomas Hökfelt; Gábor Szabó; Erik Keimpema; Tibor Harkany
Journal:  Cereb Cortex       Date:  2017-04-01       Impact factor: 5.357

3.  Molecular characterization of cholecystokinin in grass carp (Ctenopharyngodon idellus): cloning, localization, developmental profile, and effect of fasting and refeeding on expression in the brain and intestine.

Authors:  Ke Feng; Gui-Rong Zhang; Kai-Jian Wei; Bang-Xi Xiong; Tao Liang; Hai-Chao Ping
Journal:  Fish Physiol Biochem       Date:  2012-06-30       Impact factor: 2.794

4.  Infant satiety depends on transient expression of cholecystokinin-1 receptors on ependymal cells lining the third ventricle in mice.

Authors:  Tomoya Ozaki; Shahid Mohammad; Eri Morioka; Soichi Takiguchi; Masayuki Ikeda
Journal:  J Physiol       Date:  2012-12-24       Impact factor: 5.182

5.  Neuroendocrine transcriptional programs adapt dynamically to the supply and demand for neuropeptides as revealed in NSF mutant zebrafish.

Authors:  Deborah M Kurrasch; Linda M Nevin; Jinny S Wong; Herwig Baier; Holly A Ingraham
Journal:  Neural Dev       Date:  2009-06-23       Impact factor: 3.842

6.  Trajectory of the main GABAergic interneuron populations from early development to old age in the rat primary auditory cortex.

Authors:  Lydia Ouellet; Etienne de Villers-Sidani
Journal:  Front Neuroanat       Date:  2014-06-02       Impact factor: 3.856
  6 in total

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