Glial-lial-cell-line-derived neurotrophic factor (GDNF) has been isolated as neurotrophic factor for midbrain dopaminergic neurons. Because of its neurotrophic activity on a wide range of neuronal populations in vitro and in vivo, GDNF is being considered as a potential therapeutic agent for neuronal disorders. During mammalian development, it is expressed not only in the nervous system, but also very prominently in the metanephric kidney and the gastrointestinal tract, suggesting possible functions during organogenesis. We have investigated the role of GDNF during development by generating a null mutation in the murine GDNF locus, and found that mutant mice show kidney agenesis or dysgenesis and defective enteric innervation. We demonstrate that GDNF induces ureter bud formation and branching during metanephros development, and is essential for proper innervation of the gastrointestinal tract.
The circuits that control movement are comprised of discrete subtypes of motor neurons. How motor neuron subclasses develop and extend axons to their correct targets is still poorly understood. We show that LIM homeodomain factors Lhx3 and Lhx4 are expressed transiently in motor neurons whose axons emerge ventrally from the neural tube (v-MN). Motor neurons develop in embryos deficient in both Lhx3 and Lhx4, but v-MN cells switch their subclass identity to become motor neurons that extend axons dorsally from the neural tube (d-MN). Conversely, the misexpression of Lhx3 in dorsal-exiting motor neurons is sufficient to reorient their axonal projections ventrally. Thus, Lhx3 and Lhx4 act in a binary fashion during a brief period in development to specify the trajectory of motor axons from the neural tube.
During pituitary organogenesis, the progressive differentiation of distinct pituitary-specific cell lineages from a common primordium involves a series of developmental decisions and inductive interactions. Targeted gene disruption in mice showed that Lhx3, a LIM homeobox gene expressed in the pituitary throughout development, is essential for differentiation and proliferation of pituitary cell lineages. In mice homozygous for the Lhx3 mutation, Rathke's pouch formed but failed to grow and differentiate; such mice lacked both the anterior and intermediate lobes of the pituitary. The determination of all pituitary cell lineages, except the corticotrophs, was affected, suggesting that a distinct, Lhx3-independent ontogenetic pathway exists for the initial specification of this lineage.
Members of the muscarinic acetylcholine receptor family (M1-M5) are known to be involved in a great number of important central and peripheral physiological and pathophysiological processes. Because of the overlapping expression patterns of the M1-M5 muscarinic receptor subtypes and the lack of ligands endowed with sufficient subtype selectivity, the precise physiological functions of the individual receptor subtypes remain to be elucidated. To explore the physiological roles of the M2 muscarinic receptor, we have generated mice lacking functional M2 receptors by using targeted mutagenesis in mouse embryonic stem cells. The resulting mutant mice were analyzed in several behavioral and pharmacologic tests. These studies showed that the M2 muscarinic receptor subtype, besides its well documented involvement in the regulation of heart rate, plays a key role in mediating muscarinic receptor-dependent movement and temperature control as well as antinociceptive responses, three of the most prominent central muscarinic effects. These results offer a rational basis for the development of novel muscarinic drugs.Muscarinic acetylcholine receptors are known to regulate numerous fundamental physiological processes, including the muscarinic actions of acetylcholine on peripheral effector tissues and a multitude of central sensory, vegetative, and motor functions (1-4). In addition, disturbances in central muscarinic neurotransmission have been implicated in a variety of pathophysiological conditions, including Alzheimer's and Parkinson's diseases (1-4).Molecular cloning studies have revealed the existence of five molecularly distinct muscarinic receptor subtypes referred to as M1-M5 (5-7). The M1-M5 receptors are prototypical members of the superfamily of G protein-coupled receptors. Although the odd-numbered muscarinic receptor subtypes (M1, M3, and M5) are selectively linked to G q͞11 proteins, the even-numbered receptors (M2 and M4) are preferentially coupled to G proteins of the G i͞o family (5-7).The M1-M4 receptors are widely expressed throughout the central nervous system and the body periphery (6,(8)(9)(10). Studies with subtype-selective antibodies and in situ mRNA hybridization experiments have shown that most brain regions express several different muscarinic receptor subtypes (8-10). Based on this observation, it has been extremely difficult to assign specific central functions to individual muscarinic receptor subtypes.In addition, the lack of muscarinic agonists and antagonists with pronounced subtype selectivity also has represented a major limitation in studying the physiological roles of the M1-M5 receptors (5-7). This problem is accentuated further in the case of in vivo studies in which the actual concentrations of drugs at their sites of action are difficult to determine because of pharmacokinetic factors.In the body periphery, muscarinic receptors mediate the well known functions of acetylcholine at parasympathetically innervated effector organs, including contraction of smooth muscle, stimulatio...
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