Cocaine strengthens excitatory synapses onto midbrain dopamine neurons through the synaptic delivery of GluR1-containing AMPA receptors. This cocaine-evoked plasticity depends on NMDA receptor activation, but its behavioral significance in the context of addiction remains elusive. Here, we generated mice lacking the GluR1, GluR2, or NR1 receptor subunits selectively in dopamine neurons. We report that in midbrain slices of cocaine-treated mice, synaptic transmission was no longer strengthened when GluR1 or NR1 was abolished, while in the respective mice the drug still induced normal conditioned place preference and locomotor sensitization. In contrast, extinction of drug-seeking behavior was absent in mice lacking GluR1, while in the NR1 mutant mice reinstatement was abolished. In conclusion, cocaine-evoked synaptic plasticity does not mediate concurrent short-term behavioral effects of the drug but may initiate adaptive changes eventually leading to the persistence of drug-seeking behavior.
The nucleolus represents an essential stress sensor for the cell. However, the molecular consequences of nucleolar damage and their possible link with neurodegenerative diseases remain to be elucidated. Here, we show that nucleolar damage is present in both genders in Parkinson's disease (PD) and in the pharmacological PD model induced by the neurotoxin 1,2,3,6-tetrahydro-1-methyl-4-phenylpyridine hydrochloride (MPTP). Mouse mutants with nucleolar disruption restricted to dopaminergic (DA) neurons show phenotypic alterations that resemble PD, such as progressive and differential loss of DA neurons and locomotor abnormalities. At the molecular level, nucleolar disruption results in increased p53 levels and downregulation of mammalian target of rapamycin (mTOR) activity, leading to mitochondrial dysfunction and increased oxidative stress, similar to PD. In turn, increased oxidative stress induced by MPTP causes mTOR and ribosomal RNA synthesis inhibition. Collectively, these observations suggest that the interplay between nucleolar dysfunction and increased oxidative stress, involving p53 and mTOR signaling, may constitute a destructive axis in experimental and sporadic PD.
The thyroid-stimulating hormone͞thyrotropin (TSH) is the most relevant hormone in the control of thyroid gland physiology in adulthood. TSH effects on the thyroid gland are mediated by the interaction with a specific TSH receptor (TSHR). We studied the role of TSH͞TSHR signaling on gland morphogenesis and differentiation in the mouse embryo using mouse lines deprived either of TSH (pit dw ͞pit dw ) or of a functional TSHR (tshr hyt ͞tshr hyt and TSHRknockout lines). The results reported here show that in the absence of either TSH or a functional TSHR, the thyroid gland develops to a normal size, whereas the expression of thyroperoxidase and the sodium͞iodide symporter are reduced greatly. Conversely, no relevant changes are detected in the amounts of thyroglobulin and the thyroid-enriched transcription factors TTF-1, TTF-2, and Pax8. These data suggest that the major role of the TSH͞TSHR pathway is in controlling genes involved in iodide metabolism such as sodium͞iodide symporter and thyroperoxidase. Furthermore, our data indicate that in embryonic life TSH does not play an equivalent role in controlling gland growth as in the adult thyroid. T he mouse thyroid gland begins to develop at embryonic day (E)8.5 as an endodermal thickening in the floor of the primitive pharynx. After loosing all connections with the pharynx, the thyroid bud migrates caudally, reaching its final position in front of the trachea ϷE13 (1). Only after completion of migration do thyroid follicular cells begin their differentiative program and express thyroid-specific genes such as thyroglobulin (Tg), thyroid-stimulating hormone͞thyrotropin (TSH) receptor (TSHR), thyroperoxidase (TPO), and the sodium͞iodide symporter (NIS) (2). Finally, primitive follicles appear, and the gland displays its final morphological organization. Since E8.5, thyroid precursor cells express a combination of transcription factors such as TTF-1 (encoded by the titf1͞nkx2.1 gene) (3), TTF-2 (encoded by the titf2͞foxe1 gene) (4), and Pax8 (5). Gene-targeting experiments demonstrated that all these factors are required for the early stages of thyroid development (6-8). However, it still is unclear what the mechanisms are that lead to the initiation of functional differentiation that only occurs at E14.TSH is known as the main regulator of the adult thyroid gland. Indeed, after binding to its receptor, TSH stimulates the thyroid cells in almost every aspect of their metabolism including synthesis and secretion of thyroid hormones (9). Several groups have demonstrated clearly that TSH regulates mRNA levels of several thyroid-specific genes such as Tg (10-13), TPO (13-15), and NIS (16,17).TSH also stimulates the aggregation of porcine thyroid cells in follicles (18), and its presence is necessary to maintain the follicular architecture (19). In the rat, there is a temporal correlation between the increased expression of TSHR and the formation of follicles. Indeed, TSHR mRNA is expressed by E15 (3, 20), and its expression increases on E17-E18. At this stage, thyroid-speci...
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