Islet1 and Islet2 have equivalent abilities to promote motoneuron formation and to specify motoneuron subtype identity

The expression of LIM homeobox genes islet1 and islet2 is tightly regulated during development of zebrafish primary motoneurons. All primary motoneurons express islet1 around the time they exit the cell cycle. By the time primary motoneurons undergo axogenesis, specific subtypes express islet1, whereas other subtypes express islet2, suggesting that these two genes have different functions. Here, we show that Islet1 is required for formation of zebrafish primary motoneurons; in the absence of Islet1, primary motoneurons are missing and there is an apparent increase in some types of ventral interneurons. We also provide evidence that Islet2 can substitute for Islet1 during primary motoneuron formation. Surprisingly, our results demonstrate that despite the motoneuron subtype-specific expression patterns of Islet1 and Islet2, the differences between the Islet1 and Islet2 proteins are not important for specification of the different primary motoneuron subtypes. Thus, primary motoneuron subtypes are likely to be specified by factors that act in parallel to or upstream of islet1 and islet2.     

Electrical properties of motoneurons in the spinal cord of rat embryos

Electrical properties of immature motoneurons were studied in vitro using isolated segments of spinal cords of rat embryos aged 14-21 days of gestation. Stable resting potentials and evoked synaptic potentials were recorded for more than 9 hr, indicating that motoneurons remain viable for many hours. Motoneurons are electrically excitable at 14 days of gestation and from the onset of excitability the action potentials are Na+-dependent but slow rising long-duration Ca2+-dependent action potentials can be evoked if K+ conductance is reduced. Thus, during embryonic development the regenerative potential inward current is Na+-and Ca2+-dependent. During motoneurons' differentiation there are some changes in their electrical properties: resting membrane potential increases, input resistance decreases, input capacitance increases, threshold for action potential decreases, and maximum rate of rise of action potential increases. Afferent motoneuron contacts are formed at 16-18 days of gestation when excitatory synaptic potentials can first be evoked in response to dorsal root stimulation. The changes in input capacitance and threshold for action potential occur at the onset of functional afferent motoneuron contacts, but it is not known whether these changes are autonomous or are influenced by the newly formed sensory inputs.     

Simulations of the alpha motoneuron pool electromyogram reflex at different preactivation levels in man

The alpha motoneuron pool and the surface electromyogram (EMG) of the human soleus muscle are modelled, respectively, by an alpha motoneuron pool model generating the firing patterns in the motor units of e muscle and by a muscle model using these discharge patterns to simulate the surface EMG. In the alpha motoneuron pool model, we use a population of motoneurons in which cellular properties like cell size and membrane conductance are distributed according to experimentally observed data. By calculating the contribution from each motor unit, the muscle model predicts the EMG. Wave forms of the motor unit action potentials in the surface EMG are obtained from experimental data. Using the model, we are able to give a quantitative prediction of the motoneuron pool activity and the reflex EMG output at different preactivation levels. The simulated data are consistent with experimentally obtained results in healthy humans. During static isometric muscle preactivations, the simulations show that the reflex strength is highly dependent on the intrinsic threshold properties of the alpha motoneuron pool. Received: 27 April 1993/Accepted in revised form: 8 September 1993     

Drosophila Polycomb complexes restrict neuroblast competence to generate motoneurons

Similar to mammalian neural progenitors, Drosophila neuroblasts progressively lose competence to make early-born neurons. In neuroblast 7-1 (NB7-1), Kruppel (Kr) specifies the third-born U3 motoneuron and Kr misexpression induces ectopic U3 cells. However, competence to generate U3 cells is limited to early divisions, when the Eve(+) U motoneurons are produced, and competence is lost when NB7-1 transitions to making interneurons. We have found that Polycomb repressor complexes (PRCs) are necessary and sufficient to restrict competence in NB7-1. PRC loss of function extends the ability of Kr to induce U3 fates and PRC gain of function causes precocious loss of competence to make motoneurons. PRCs also restrict competence to make HB9(+) Islet(+) motoneurons in another neuroblast that undergoes a motoneuron-to-interneuron transition, NB3-1. In contrast to the regulation of motoneuron competence, PRC activity does not affect the production of Eve(+) interneurons by NB3-3, HB9(+) Islet(+) interneurons by NB7-3, or Dbx(+) interneurons by multiple neuroblasts. These findings support a model in which PRCs establish motoneuron-specific competence windows in neuroblasts that transition from motoneuron to interneuron production.     

Expression of K(Ca) channels in identified populations of developing vertebrate neurons: role of neurotrophic factors and activity.

Changes in the intrinsic spike discharge properties in one neuronal population can alter the functions and even the formation of an entire neuronal network. Therefore it is important to understand the factors that regulate acquisition of a mature electrophysiological phenotype. Here we focus on large-conductance K(Ca) channels, which shape the pattern of repetitive discharge and which are therefore likely to play a role in the refinement of neural networks during development. In the parasympathetic ciliary ganglion of chick, the developmental expression of K(Ca) channels coincides with stages at which ciliary cells form synapses with target tissues. Moreover, K(Ca) expression requires formation of synapses with target tissues, and with afferent preganglionic inputs. The trophic effect of targets is mediated by TGFbeta1, whereas the effect of the preganglionic input is mediated by an isoform of beta-neuregulin-1. These trophic factors act synergistically, and this appears to be a normal feature of their actions in vivo. The acute effects of TGFbeta1 entail translocation of preexisting K(Ca) channels from intracellular stores to the plasma membrane. This requires activation of the signaling enzymes Ras, Erk MAP kinase and PI3 kinase. TGFbeta1 also causes a more sustained increase in K(Ca) channels (i.e. for up to 2 weeks) that requires synthesis of new channel proteins. Inductive regulation of K(Ca) expression is also observed in CNS cells that form more complex networks. In lumbar motoneurons, the largest changes in K(Ca) expression coincide with the elimination of synapses with hindlimb targets. Interactions with target tissues play a key role in regulation of motoneuron K(Ca) expression, and this trophic effect of target muscle is mediated by GDNF or a closely related factor. In addition, K(Ca) expression in motoneurons is dependent on ongoing electrical activity both in vivo and in vitro. This provides an additional mechanism for use-dependent refinement of neural networks during embryonic development.