In vivo quantification of extrastriatal dopamine D2 receptors in the human brain /

Olsson, Hans,

January 2005

Diss. (sammanfattning) Stockholm : Karolinska institutet, 2005. / Härtill 5 uppsatser.

Behavioral sensitization effected by variable anxiogenic challenge and psychogenic stressor exposure in anxiety and motivational paradigms in CD-1 mice: in situ hybridization and immunohistochemical determinations in selective mesocorticolimbic sites /

Hebb, Andrea Lyn Olding,

January 1900

Thesis (Ph.D.) - Carleton University, 2002. / Includes bibliographical references (p. 264-326). Also available in electronic format on the Internet.

Validation of a simple, ethologically relevant paradigm for assessing anxiety in mice /

Levac, Carla,

January 1900

Thesis (M. Sc.)--Carleton University, 2003. / Includes bibliographical references (p. 50-81). Also available in electronic format on the Internet.

Evolution of the structure and function of vertebrate brain gonadotropin-releasing hormone

Powell, R C

January 1986

In this study, the structure and function of gonadotropin-releasing hormone (GnRH) in different vertebrate species, in the classes Aves, Reptilia and Pisces was investigated. Acetic acid extracts were subjected to gel filtration chromatography and semipreparative high performance liquid chromatography (HPLC) to partially purify the GnRHs. The GnRH immunoreactivity was then characterized by analytical HPLC, and by assaying HPLC fractions by radioimmunoassay with region-specific antisera generated against mammalian GnRH, Gln⁸-GnRH and Trp⁷,Leu⁸-GnRH and assessing luteinizing hormone (LH)-releasing activity of fractions in a chicken dispersed anterior pituitary cell bioassay. Five GnRH molecular forms have thusfar been structurally characterized in vertebrate brain. In mammals a GnRH with the structure pGlu-His-Trp-Ser-Tyr-Gly-Leu-Arg-Pro-Gly-NH₂ has been demonstrated in the hypothalamus (Matsuo et al., 1971; Burgus et al., 1972). Gln⁸-GnRH and His⁵,Trp⁷,Tyr⁸-GnRH were present in chicken hypothalamus (King and Millar, 1982a, 1982c; Miyamoto et al., 1983, 1984), Trp⁷,Leu⁸-GnRH in salmon brain (Sherwood et al., 1983) and Tyr³,Leu⁵,Glu⁶,Trp⁷,Lys⁸-GnRH in lamprey brain (Sherwood et al., 1986). In ostrich (Struthio camelus) hypothalamus two GnRHs with identical properties to Gln⁸-GnRH and His⁵,Trp⁷,Tyr⁸-GnRH have been demonstrated, as well as four other LR-releasing factors with different chromatographic and immunological properties to any of the known naturally-occurring GnRHs. Since Gln⁸-GnRH and His⁵,Trp⁷,Tyr⁸-GnRH were also present in chicken hypothalamus it appears likely that these two GnRHs occur in all birds. In alligator (Alligator mississippiensis) brain only two GnRHs were detected. These forms co-eluted with Gln⁸-GnRH and His⁵,Trp⁷,Tyr⁸-GnRH in two HPLC systems. They cross-reacted similarly to the two synthetic peptides with antisera directed against mammalian GnRH and Gln⁸-GnRH and released LH from chicken dispersed anterior pituitary cells in a similar manner to the synthetic peptides. The Archosaurs (alligators and crocodiles) are believed to be closely related to birds and therefore it seems likely that they should have identical GnRHs. In skink (Calcides ocellatus tiligugu) brain one GnRH, which co-eluted with His⁵,Trp⁷,Tyr⁸-GnRH, was demonstrated. Two other lizards (Cordylis nigra and Pordarcis s. sicula) have been studied (Powell et al., 1985; R.C. Powell, G. Ciarcia, V. Lance, R.P. Millar and J.A. King, submitted). In c. nigra four immunoreactive GnRHs were detected, two of which co-eluted released chicken LH similarly to, Trp⁷,Leu⁸-GnRH and with, and His⁵,Trp⁷,Tyr⁸-GnRH. In P. s. sicula a GnRH molecular form similar to Trp⁷,Leu⁸-GnRH occurred as well as two novel GnRHs. It thus appears that Gln⁸-GnRH does not occur in lower reptiles, but His⁵,Trp⁷,Tyr⁸-GnRH and/or Trp⁷,Leu⁸-GnRH do. His⁵,Trp⁷,Tyr⁸-GnRH appears to he a widespread GnRH, occurring in vertebrates as diverse as birds and elasmobranch fish. In dogfish (Poroderma africanum) brain seven factors, which stimulated release of LH from chicken dispersed anterior pituitary cells, were separated on analytical HPLC. Two of these factors were partially characterized as Trp⁷,Leu⁸-GnRH and His⁵,Trp⁷,Tyr⁸-GnRH. Three of the other forms cross-reacted with GnRH antisera, but appear to be novel GnRHs. In teleost (Coris julis) brain two GnRHs similar to Trp⁷,Leu⁸-GnRH and His⁵,Trp⁷,Tyr⁸-GnRH were present. These two GnRHs therefore appear to occur in both fish species studied. Trp⁷,Leu⁸-GnRH is widespread amongst teleost fish (Jackson and Pan, 1983; Sherwood et al., 1983; Breton et al., 1984; Sherwood et al., 1984; King and Millar, 1985). From these data it seems evident that the mammalian GnRH molecular form occurs only in mammals and amphibians, Gln⁸-GnRH in birds and higher reptiles, and Trp⁷,Leu⁸-GnRH in gnathostomes. His⁵,Trp⁷, Tyr⁸-GnRH appears to he present in numerous different vertebrates. Tyr³,Leu⁵,Glu⁶,Trp⁷,Lys⁸-GnRH has thus far only been detected in lamprey brain. A number of novel GnRHs, whose structures have not been elucidated are present.

Gonadotropins

Pituitary Hormone-Releasing Hormones

Vertebrates

Brain chemistry

Flesh, Blood, and Word: Creativity and Writing as Physiological Phenomena

Povozhaev, Lea May

23 September 2005

No description available.

Neurology

creativity

writing

brain chemistry

body and mind writing

physiology of writing

Modulation of Brain Chemistry with Small Molecule Probes: From Opioid to Growth Factor Signaling Systems

Gassaway, Madalee McKown

January 2016

This report describes the use of small molecule probes in the modulation of brain chemistry with the ultimate goal of developing novel therapeutics for the treatment of mood disorders. With an increasing number of people suffering from depression, there is a need to explore more diverse mechanisms of these diseases to better understand their cause and therefore provide insight into their treatment. Chapter 1 serves as an introduction and describes the current understanding of depression mechanisms, as well as a history of antidepressant therapeutics. The chapter then goes on to discuss, in depth, the mechanisms of G Protein-Coupled Receptor (GPCR) function and the implications of biased signaling. There is also an introductory overview of basic pharmacological terms. The chapter finishes with a summary of current technology available to measure GPCR function, including those utilized in the rest of this report. The remainder of the report is broken up into two parts. In the first part, I will describe my work to understand the opioid receptor system in the context of mood disorders. In Chapter 2, the atypical antidepressant tianeptine is discovered to act through the mu-opioid receptor (MOR), and a biochemical exploration is reported including an exploration of its unique properties in the context of G protein-dependent and -independent signaling, as well as preliminary in vivo and structure activity relationship studies into the mechanism of action. In Chapter 3, I will describe the biological characterization of the Mitragyna speciosa alkaloids at the opioid receptors. In particular, the major alkaloids mitragynine and 7-OH mitragynine are found to be partial agonists at the MOR and antagonists at the kappa-opioid receptor (KOR) with apparent G protein bias. In Chapter 4, alkaloids inspired by those found in Tabernanthe iboga, such as ibogaine, are synthesized and characterized at the opioid receptors. Through a novel 12- hydroxy-oxaibogamine scaffold, opioid activity is uncovered that is greatly increased in comparison to the ibogaine metabolite noribogaine. Analogs tested have varying degrees of potency and efficacy at all three opioid receptors, and one analog in particular is found to be a selective G protein biased partial KOR agonist. In Chapter 5, I will conclude the opioid section by taking a critical examination of commonly used assays for measuring arrestin recruitment by dissecting assay components and analyzing what is necessary to determine accurate calculations of bias within a cellular system. The alleged G protein bias of KOR agonist dynorphin is studied at great length, and a discussion on the future of understanding ligand bias is presented. In the second part of this report, I move away from opioids and instead focus on the growth factor signaling system as a second approach to uncovering novel therapeutics for depression. In Chapter 6, I describe a second potential mechanism of action of the natural product ibogaine in the context of glial cell line-derived neurotrophic factor (GDNF) signaling. The deconstructed iboga analog XL-008 is studied that is a superior releaser of GDNF and potentiates the signaling of a second growth factor, fibroblast growth factor 2 (FGF2). In the final Chapter 7, I look to the FGF family, both receptor and growth factor, as a novel target for depression. In order to identify small molecule modulators of the FGF receptor 1 (FGFR1), cell- based assays are developed and validated in a pilot screen. The strength of these assays are assessed, and the initial results from a full high throughput screen are presented.

Affective disorders

Opioids

Depression, Mental--Etiology

Brain chemistry

Chemistry

Biology

Pharmacology

Regulation of corticotropin-releasing factor concentration and overflow in the rat central nervous system.

McClure-Sharp, Jilliane Mary, mikewood@deakin.edu.au

January 1998

Corticotropin-releasing factor (CRF) is the primary hormone of the hypothalamo-pituitary adrenal axis (HPA-axis). In addition to its endocrine function, it has been proposed that CRF acts as a neurotransmitter. The widespread distribution of CRF immunoreactivity and CRF receptors in the rat central nervous system (CNS) supports this theory. Immunohistochemical studies have demonstrated high levels of CRF immunoreactivity the rat hypothalamus, a brain region involved in the regulation and integration of a variety of endocrine and autonomic homeostatic mechanisms. CRF has been shown to be involved in a number of these activities such as blood pressure control, food and water intake, behaviour and emotional integration. Many of these activities demonstrate progressive dysfunction as ageing proceeds. The aim of this thesis was to investigate the regulation of CRF in the rat CNS, particularly over the period of maturation and ageing. Tissue extraction and peptide radioimmunoassay (RIA) techniques were developed in order to measure regional CRF concentrations as a function of age in the rat CNS. Seven brain regions were examined including the hypothalamus, pituitary, medulla oblongata, pons, cerebral cortex, cerebellum and midbrain. Three age ranges were investigated: 3 – 4 weeks, 4 – 5 months and 14 – 18 months, representing young, mature and old age groups. Data for the tissues of individual rats from each age group were analysed using one-way analysis of variance (ANOVA) with post-hoc Scheffé tests (SPSS Release 6 for Windows, 1989 – 1993). CRF were detected in measurable quantities in all brain regions examined. Different age-related patterns of change were observed in each brain region. CRF concentrations (ng/g tissue) were highest in the pituitaries of young rats and were significantly reduced over the period of maturation (P< 0.05). However, the high CRF concentration of the young rat pituitary was likely to be a factor of the smaller tissue mass. Although the absolute CRF content (ng/tissue) of this tissue appeared to decline with maturation and ageing, the reduction was not significant (P>0.05). Therefore the pituitary of the young rat was relatively enriched with CRF per gram tissue. The highest CRF concentration in mature and aged rats was measured in the hypothalamus, in accordance with previous immunohistochemical studies. Hypothalamic CRF concentrations (ng/g tissue) demonstrated no significant alterations with maturation and ageing. The absolute CRF content (ng/tissue) of the hypothalamus was significantly less in the young rat compared to mature and aged animals, however this was accompanied by a smaller tissue mass (P<0.05). The CRF concentrations (ng/g tissue) of the rat cerebral cortex and medulla oblongata demonstrated significant reduction with advancing age (P<0.05), however in both cases this appeared to be due to significant increases in mean tissue mass. The absolute CRF content of these tissues (ng/tissue) were not significantly different over the period of maturation and ageing (P>0.05). CRF concentration (ng/g tissue) and absolute content (ng/tissue) of the pons demonstrated a trend to increase with advanced age in the rat, however this was not significant in both cases (P>0.05). Of interest were the significant increases observed in the CRF concentrations of the cerebellum and midbrain (ng/g tissue with advanced ageing (P<0.05). Significant increases were also observed in the mean tissue mass and absolute CRF content (ng/tissue) of these regions in aged rats (P<0.05). These findings perhaps indicate increased CRF synthesis and or decreased CRF turnover in these tissues with advancing age. The second stage of these studies examined age-related alterations in basal and potassium-stimulated hypothalamic CRF and overflow over the period of maturation and ageing in the rat, and required the preliminary development of an in vitro tissue superfusion system. The concomitant release of the co-modulatory compound, neuropeptide Y (NPY) was also measured. NPY has been shown to positively regulate CRF release and gene expression in the hypothalamus. In addition, NPY has been demonstrated to be involved in a number of hypothalamic activities, including blood pressure control and food intake regulation. Hypothalamic superfusion data were analysed using one factor repeated measures ANOVA (SPSS Release 6 for Windows, 1989-1993) followed by least significant difference tests ( Snedecor and Cochran, 1967) to enable both time and age comparisons. Basal hypothalamic CRF overflow was unaltered with maturation and ageing in the rat. Potassium stimulation (56 mM) elicted a significant 2 – 3 fold increase in hypothalamic CRF overflow across age groups (P<0.05). Stimulated hypothalamic CRF overflow was significantly greater in the young rat compared to the mature and aged animals (P<0.05). The enhanced response to depolarizing stimulus was observed at an age when the absolute CRF content of the hypothalamus was significantly less that of other age groups. It is possible that the enhanced responsiveness of the young rat may be of survival advantage in life threatening situations. Basal hypothalamic NPY overflow was much less than that of CRF, and potassium stimulation resulted in a very different age-related profile. The hypothalamic NPY response to depolarization was significantly reduced in the young rat and declined significantly with advanced ageing (P<0.05). The contrasting profiles of stimulated CRF and NPY overflow may indicate the activity of alternative regulatory factors present in the hypothalamus, whose activity may also be affected in an age-related manner. The final stage of these studies examined the nature of NPY modulation of hypothalamic CRF overflow in the mature rat. The facilitatory effect of NPY on hypothalamic CRF overflow was confirmed. The application of NPY (0.1 µM) significantly increased CRF overflow approximately 4 fold of basal (P<0.05). In addition, the role of the NPY-Y1 receptor was investigated by the prior application of Y1 receptor antagonists, GW1229 (0.05 µM). At this concentration GW1229 significantly reduced hypothalamic CRF overflow induced by perfusion with NPY (0.1 µm), P<0.05. It was concluded the Y1 receptor does have a role in the regulation of hypothalamic CRF overflow by NPY.

central nervous systems

central nervous system in rats

corticotropin realasing hormone

neuroendocrinology

brain chemistry

stress

Gene expression in the human brain: adaptive changes associated with tobacco and alcohol exposure

Flatscher-Bader, Traute

Unknown Date

Alcohol and tobacco are drugs of abuse which are legal to sell and consume in most western societies. Addiction to these two substances has major social and health implications worldwide. The brain structure known to mediate addictive behaviour is the dopaminergic mesocorticolimbic system. Dopaminegic neurons arise from the ventral tegmental area, project to the nucleus accumbens and interact with the amygdala and the prefrontal cortex. Chronic alcoholism elicits marked damage in the prefrontal cortex with significant loss of neurons and glia. The key components of addiction, tolerance and dependence, are thought to be the result of semipermanent adaptive changes in gene expression. Gene expression profiling of the mesocorticolimbic system from human alcoholics and alcohol-dependent animals has revealed highly region-specific alterations. How these molecular changes result in the development of alcohol dependence in humans is not fully understood. Complicating factors in human alcoholism include a high comorbidity with smoking, socioeconomic factors and the prevalence of underlying psychological pathologies. Gene expression profiling of the prefrontal cortex of six alcoholics and six controls resulted in the identification of functional gene groups sensitive to alcoholism. Mitochondrial function was found down regulated while mRNA levels of genes involved in stress response and cell protection were elevated. These results correlate with the pathology of the prefrontal cortex in chronic alcoholism. Some of the control cases used for gene expression profiling were later identified as chronic smokers, while all of the alcoholics were heavy smokers. To date the heavy co-morbidity of alcoholism with smoking has not been taken into account. Thus the expression of selected genes were investigated by realtime PCR in an extended case set of non-smoking alcoholics, smoking alcoholics, smoking non-alcoholics and non-smoking, non-alcoholics. This study revealed that alcoholism itself had a significant impact on the expression of midkine, the high affinity glial glutamate transporter, member 1 and the tissue inhibitor of the metalloproteinase 3. Heavy smoking itself led to a small but significant elevation of MDK mRNA levels as well as an increase in variation of excitatory amino acid transporter 1 and metalloproteinase inhibitor, member 3 expression. Apolipoprotein D however was induced by chronic smoking but not by alcohol dependence. These results highlight the need of careful case selection in future studies on gene expression in the human alcoholic brain. Peptide antibodies were produced to midkine and a polyclonal antibody against the excitatory amino acid transporter 1 was obtained from a collaborating laboratory. Western blots utilizing these antibodies revealed a marked increase in midkine and excitatory amino acid transporter 1 protein in alcoholics compared to non-smoking and non-drinking controls. In coronal sections of human prefrontal cortex of alcoholics and non-smoking non-drinking controls, immunofluorescence of midkine was obtained from nuclei throughout the layers of the cortex and from the cell bodies of a distinct set of astrocytes in cortical layer II. Double staining with glial fibrillary acidic protein revealed that a portion of midkine-positive nuclei were localised in glial cells. There was no difference in immunostaining of alcohol and control sections with midkine. In summary these results indicate that midkine protein is induced in the prefrontal cortex of the chronic alcoholic. However, this increase in protein may not be strong enough to be visualised by immunohistochemistry. Midkine induction may be reflective of reparative processes in the prefrontal cortex of the chronic alcoholic. Excitatory amino acid transporter 1 staining in non-alcoholic, non-smoking control cases were obtained as a confluent band in cortical layer II and sparsely in deeper cortical layers. Excitatory amino acid transporter 1 immunoreactivity overlapped partially with glial fibrillary acidic protein labelling. In chronic alcoholics, excitatory amino acid transporter 1 staining in the area between the cortical layer II and VI was significantly increased. At withdrawal, glutamate levels may reach toxic levels in the cortex. The increase in cells expressing excitatory amino acid transporter 1 throughout the cortical layers may indicate a protective measure of this brain region in the chronic alcoholic. Additionally, layer specific expression of midkine and excitatory amino acid transporter 1 in the prefrontal cortex of the healthy individual may implicate a specialised role of these astrocytes.

270201 Gene Expression

780105 Biological sciences

gene expression

brain chemistry

alcohol

tobacco

drug dependency

Proteomics in neurological disease

Ottervald, Jan,

January 2009

Diss. (sammanfattning) Stockholm : Karolinska institutet, 2009.

The relationship between lipid metabolism and suicidal behaviour : clinical and molecular studies

Lalovic, Aleksandra.

January 2007

Suicide continues to claim hundreds of thousands of lives worldwide each year, in spite of the significant progress of research efforts aimed at understanding the complexity of this tragic behaviour. Data accumulated over the last decades suggest a certain biological predisposition to suicidal behaviour. Among the possible biological risk factors, cholesterol has frequently been cited. Several lines of evidence support the relationship between altered lipid metabolism, particularly low levels of serum cholesterol, and suicidal behaviour, yet the possible mechanisms governing the relationship remain to be elucidated. Three separate strategies were employed in order to explore the link between lipid metabolism and suicidal behaviour, each one from a novel perspective on this issue. The first approach aimed to substantiate the existing evidence of an association between low serum cholesterol and suicidality by examining psychiatric data, suicidality and related behavioural characteristics in a sample of Smith-Lemli-Opitz syndrome heterozygotes---a clinically normal population with altered cholesterol metabolism due to an inherited partial deficiency in the 7-dehydrocholesterol reductase enzyme---compared with controls. The second approach consisted in measuring the lipid profile in brain tissue from suicide completers, in order to address whether there are alterations in cholesterol and/or fatty acids in the brain. The final approach involved the use of exploratory gene expression studies to identify novel candidate genes and proteins that may be involved in mediating the link between lipid metabolism and suicidality. The results of these studies will be presented and discussed.

Suicide.

Brain Chemistry.