D.J.S. Sirinathsinghji scite author profile

Small synthetic molecules termed growth hormone secretagogues (GHSs) act on the pituitary gland and the hypothalamus to stimulate and amplify pulsatile growth hormone (GH) release. A heterotrimeric GTP-binding protein (G protein)-coupled receptor (GPC-R) of the pituitary and arcuate ventro-medial and infundibular hypothalamus of swine and humans was cloned and was shown to be the target of the GHSs. On the basis of its pharmacological and molecular characterization, this GPC-R defines a neuroendocrine pathway for the control of pulsatile GH release and supports the notion that the GHSs mimic an undiscovered hormone.

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Distribution of mRNA encoding the growth hormone secretagogue receptor in brain and peripheral tissues

Guan

Palyha

et al. 1997

Molecular Brain Research

1,054

754

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β-amyloid precursor protein-deficient mice show reactive gliosis and decreased locomotor activity

Zheng

Jiang

Trumbauer

et al. 1995

Cell

639

435

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In several pedigrees of early onset familial Alzheimer's disease (FAD), point mutations in the beta-amyloid precursor protein (APP) gene are genetically linked to the disease. This finding implicates APP in the pathogenesis of Alzheimer's disease in these individuals. To understand the in vivo function of APP and its processing, we have generated an APP-null mutation in mice. Homozygous APP-deficient mice were viable and fertile. However, the mutant animals weighed 15%-20% less than age-matched wild-type controls. Neurological evaluation showed that the APP-deficient mice exhibited a decreased locomotor activity and forelimb grip strength, indicating a compromised neuronal or muscular function. In addition, four out of six homozygous mice showed reactive gliosis at 14 weeks of age, suggesting an impaired neuronal function as a result of the APP-null mutation.

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Presenilin 1 is required for Notch 1 and Dll1 expression in the paraxial mesoderm

Wong

Zheng²,

Chen

et al. 1997

Nature

689

440

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Approximately 10% of cases of Alzheimer's disease are familial and associated with autosomal dominant inheritance of mutations in genes encoding the amyloid precursor protein, presenilin 1 (PS1) and presenilin 2 (PS2). Mutations in PS1 are linked to about 25% of cases of early-onset familial Alzheimer's disease. PS1, which is endoproteolytically processed in vivo, is a multipass transmembrane protein and is a functional homologue of SEL-12, a Caenorhabditis elegans protein that facilitates signalling mediated by the Notch/LIN-12 family of receptors. To examine potential roles for PS1 in facilitating Notch-mediated signalling during mammalian embryogenesis, we generated mice with targeted disruptions of PS1 alleles (PS1-/- mice). PS1-/- embryos exhibited abnormal patterning of the axial skeleton and spinal ganglia, phenotypes traced to defects in somite segmentation and differentiation. Moreover, expression of mRNA encoding Notch1 and Dll1 (delta-like gene 1), a vertebrate Notch ligand, is markedly reduced in the presomitic mesoderm of PS1-/- embryos compared to controls. Hence, PS1 is required for the spatiotemporal expression of Notch1 and Dll1, which are essential for somite segmentation and maintenance of somite borders.

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Tissue distribution of adenosine receptor mRNAs in the rat

Dixon

Gubitz

Sirinathsinghji

et al. 1996

British J Pharmacology

518

345

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1 A degree of ambiguity and uncertainty exists concerning the distribution of mRNAs encoding the four cloned adenosine receptors. In order to consolidate and extend current understanding in this area, the expression of the adenosine receptors has been examined in the rat by use of in situ hybridisation and the reverse transcription-polymerase chain reaction (RT-PCR). 2 In accordance with earlier studies, in situ hybridisation revealed that the adenosine A1 receptor was widely expressed in the brain, whereas A2A receptor mRNA was restricted to the striatum, nucleus accumbens and olfactory tubercle. In addition, A1 receptor mRNA was detected in large striatal cholinergic interneurones, 26% of these neurones were also found to express the A2A receptor gene. Central levels of mRNAs encoding adenosine A2B and A3 receptors were, however, below the detection limits of in situ hybridisation. 3 The more sensitive technique of RT-PCR was then employed to investigate the distribution of adenosine receptor mRNAs in the central nervous system (CNS) and a wide range of peripheral tissues.As a result, many novel sites of adenosine receptor gene expression were identified. Al receptor expression has now been found in the heart, aorta, liver, kidney, eye and bladder. These observations are largely consistent with previous functional data. A2A receptor mRNA was detected in all brain regions tested, demonstrating that expression of this receptor is not restricted to the basal ganglia. In the periphery A2A receptor mRNA was also found to be more widely distributed than generally recognised. The ubiquitous distribution of the A2B receptor is shown for the first time, A2B mRNA was detected at various levels in all rat tissues studied. Expression of the gene encoding the adenosine A3 receptor was also found to be widespread in the rat, message detected throughout the CNS and in many peripheral tissues. This pattern of expression is similar to that observed in man and sheep, which had previously been perceived to possess distinct patterns of A3 receptor gene expression in comparison to the rat. 4 In summary, this work has comprehensively studied the expression of all the cloned adenosine receptors in the rat, and in so doing, resolves some of the uncertainty over where these receptors might act to control physiological processes mediated by adenosine.

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