The autosomal dominant cerebellar ataxias (ADCAs) represent a heterogeneous group of neurodegenerative diseases with progressive ataxia and cerebellar degeneration. The current classification of this disease group is based on the underlying genetic defects and their typical disease courses. According to this categorization, ADCAs are divided into the spinocerebellar ataxias (SCAs) with a progressive disease course, and the episodic ataxias (EA) with episodic occurrences of ataxia. The prominent disease symptoms of the currently known and genetically defined 31 SCA types result from damage to the cerebellum and interconnected brain grays and are often accompanied by more specific extra-cerebellar symptoms. In the present review, we report the genetic and clinical background of the known SCAs and present the state of neuropathological investigations of brain tissue from SCA patients in the final disease stages. Recent findings show that the brain is commonly seriously affected in the polyglutamine SCAs (i.e. SCA1, SCA2, SCA3, SCA6, SCA7, and SCA17) and that the patterns of brain damage in these diseases overlap considerably in patients suffering from advanced disease stages. In the more rarely occurring non-polyglutamine SCAs, post-mortem neuropathological data currently are scanty and investigations have been primarily performed in vivo by means of MRI brain imaging. Only a minority of SCAs exhibit symptoms and degenerative patterns allowing for a clear and unambiguous diagnosis of the disease, e.g. retinal degeneration in SCA7, tau aggregation in SCA11, dentate calcification in SCA20, protein depositions in the Purkinje cell layer in SCA31, azoospermia in SCA32, and neurocutaneous phenotype in SCA34. The disease proteins of polyglutamine ataxias and some non-polyglutamine ataxias aggregate as cytoplasmic or intranuclear inclusions and serve as morphological markers. Although inclusions may impair axonal transport, bind transcription factors, and block protein quality control, detailed molecular and pathogenetic consequences remain to be determined.
Local thyroid hormone catabolism within the mediobasal hypothalamus (MBH) by thyroid hormone-activating (DIO2) and -inactivating (DIO3) enzymes regulates seasonal reproduction in birds and mammals. Recent functional genomics analysis in birds has shown that long days induce thyroid-stimulating hormone production in the pars tuberalis (PT) of the pituitary gland, which triggers DIO2 expression in the ependymal cells (EC) of the MBH. In mammals, nocturnal melatonin secretion provides an endocrine signal of the photoperiod to the PT that contains melatonin receptors in high density, but the interface between the melatonin signal perceived in the PT and the thyroid hormone levels in the MBH remains unclear. Here we provide evidence in mice that TSH participates in this photoperiodic signal transduction. Although most mouse strains are considered to be nonseasonal, a robust photoperiodic response comprising induced expression of TSHB (TSH  subunit), CGA (TSH ␣ subunit), and DIO2, and reduced expression of DIO3, was observed in melatonin-proficient CBA/N mice. These responses could not be elicited in melatonin-deficient C57BL/6J, but treatment of C57BL/6J mice with exogenous melatonin elicited similar effects on the expression of the abovementioned genes as observed in CBA/N after transfer to short-day conditions. The EC was found to express TSH receptor (TSHR), and ICV injection of TSH induced DIO2 expression. Finally, we show that melatonin administration did not affect the expression of TSHB, DIO2, and DIO3 in TSHR-null mice. Taken together, our findings suggest that melatonin-dependent regulation of thyroid hormone levels in the MBH appears to involve TSH in mammals.circadian rhythm ͉ melatonin ͉ pars tuberalis ͉ photoperiodism ͉ type 2 and 3 iodothyronine deiodinases O rganisms living outside the tropics detect and predict seasonal changes in day length (photoperiod) to adapt various metabolic and behavioral functions to the environment. This mechanism, called photoperiodism, allows animals to control the timing of reproduction so that they can raise their offspring in spring and summer when food is most abundant. Among vertebrates, birds possess a highly sophisticated photoperiodic mechanism and show robust responses to photoperiodic changes. Taking advantage of the elaborate avian photoperiodic system, we have recently revealed the gene cascade regulating the photoperiodic response of reproduction in Japanese quail (Coturnix japonica) by using a functional genomics approach (1, 2). Exposure to long days induced thyroid-stimulating hormone (TSH), a heterodimer of the TSH  subunit (TSHB), and the common glycoprotein ␣ subunit (CGA, also called TSH ␣ subunit), in the pars tuberalis (PT) of the pituitary gland. TSH triggers the expression of type 2 iodothyronine deiodinase (DIO2) in the ependymal cells (EC) lining the ventrolateral walls of the third ventricle (i.e., the infundibular recess) within the mediobasal hypothalamus (MBH). DIO2 is a thyroid hormoneactivating enzyme that converts the prohormone thyroxine...
Parkinson’s disease (PD) and dementia with Lewy bodies (DLB) are among the human synucleinopathies, which share the neuropathological features of alpha-synuclein immunoreactive neuronal and/or glial aggregations, as well as progressive neuronal loss in select brain regions (e.g. dopaminergic substantia nigra and ventral tegmental area, cholinergic pedunculopontine nucleus). Despite a number of studies about brainstem pathologies in PD and DLB, there is currently no detailed information available regarding the presence of alpha-synuclein immunoreactive inclusions (a) in the cranial nerve, precerebellar, vestibular and oculomotor brainstem nuclei and (b) in brainstem fiber tracts and oligodendroctyes. Therefore, we performed a detailed analysis of the alpha-synuclein immunoreactive inclusion pathologies in the brainstem nuclei (Lewy bodies, LB; Lewy neurites, LN; coiled bodies, CB) and fiber tracts (LN, CB) of clinically diagnosed and neuropathologically confirmed PD and DLB patients. As also reported in previous studies, LB and LN were most prevalent in the substantia nigra, ventral tegmental area, pedunculopontine and raphe nuclei, periaqueductal gray, locus coeruleus, parabrachial nuclei, reticular formation, prepositus hypoglossal, dorsal motor vagal, and solitary nuclei. However, we for the first time demonstrated LB and LN in all cranial nerve nuclei, premotor oculomotor, precerebellar and vestibular brainstem nuclei, as well as LN in all brainstem fiber tracts. CB were present in nearly all brainstem nuclei and brainstem fiber tracts containing LB and/or LN. These novel brainstem findings can account for or contribute to a large variety of less well-explained PD and DLB symptoms (e.g. gait and postural instability, impaired balance and postural reflexes, falls, ingestive and oculomotor dysfunctions), and point to the occurrence of disturbances of intra-axonal transport processes and a transneuronal spread of the underlying pathological processes of PD and DLB along anatomical pathways in a prion-like manner.
In mammals, many daily cycles are driven by a central circadian clock, which is based on the cell-autonomous rhythmic expression of clock genes. It is not clear, however, how peripheral cells are able to interpret the rhythmic signals disseminated from this central oscillator. Here we show that cycling expression of the clock gene Period1 in rodent pituitary cells depends on the heterologous sensitization of the adenosine A2b receptor, which occurs through the nocturnal activation of melatonin mt1 receptors. Eliminating the impact of the neurohormone melatonin simultaneously suppresses the expression of Period1 and evokes an increase in the release of pituitary prolactin. Our findings expose a mechanism by which two convergent signals interact within a temporal dimension to establish high-amplitude, precise and robust cycles of gene expression.
We have previously shown that the extracellular nucleoside triphosphate-hydrolyzing enzyme NTPDase2 is highly expressed in situ by stem/progenitor cells of the two neurogenic regions of the adult murine brain: the subventricular zone (type B cells) and the dentate gyrus of the hippocampus (residual radial glia). We explored the possibility that adult multipotent neural stem cells express nucleotide receptors and investigated their functional properties in vitro. Neurospheres cultured from the adult mouse SVZ in the presence of epidermal growth factor and fibroblast growth factor 2 expressed the ecto-nucleotidases NTPDase2 and the tissue nonspecific isoform of alkaline phosphatase, hydrolyzing extracellular ATP to adenosine. ATP, ADP and, to a lesser extent, UTP evoked rapid Ca 2+ transients in neurospheres that were exclusively mediated by the metabotropic P2Y 1 and P2Y 2 nucleotide receptors. In addition, agonists of these receptors and low concentrations of adenosine augmented cell proliferation in the presence of growth factors. Neurosphere cell proliferation was attenuated after application of the P2Y 1 -receptor antagonist MRS2179 and in neurospheres from P2Y 1 -receptor knockout mice. In situ hybridization identified P2Y 1 -receptor mRNA in clusters of SVZ cells. Our results infer nucleotide receptor-mediated synergism that augments growth factor-mediated cell proliferation. Together with the in situ data, this supports the notion that extracellular nucleotides contribute to the control of adult neurogenesis.
Biological rhythms are driven in mammals by a central circadian clock located in the suprachiasmatic nucleus (SCN). Light-induced phase shifting of this clock is correlated with phosphorylation of CREB at Ser133 in the SCN. Here, we characterize phosphorylation of CREB at Ser142 and describe its contribution to the entrainment of the clock. In the SCN, light and glutamate strongly induce CREB Ser142 phosphorylation. To determine the physiological relevance of phosphorylation at Ser142, we generated a mouse mutant, CREB(S142A), lacking this phosphorylation site. Light-induced phase shifts of locomotion and expression of c-Fos and mPer1 in the SCN are significantly attenuated in CREB(S142A) mutants. Our findings provide genetic evidence that CREB Ser142 phosphorylation is involved in the entrainment of the mammalian clock and reveal a novel phosphorylation-dependent regulation of CREB activity.
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