Augmentation of myocardial I dysregulates calcium homeostasis and causes adverse cardiac remodeling.

HCN channels underlie the depolarizing funny current (I) that contributes importantly to cardiac pacemaking. I is upregulated in failing and infarcted hearts, but its implication in disease mechanisms remained unresolved. We generated transgenic mice (HCN4) to assess functional consequences of HCN4 overexpression-mediated I increase in cardiomyocytes to levels observed in human heart failure.

The symptom complex of familial sinus node dysfunction and myocardial noncompaction is associated with mutations in the HCN4 channel.

Background: Inherited arrhythmias were originally considered isolated electrical defects. There is growing evidence that ion channel dysfunction also contributes to myocardial disorders, but genetic overlap has not been reported for sinus node dysfunction (SND) and noncompaction cardiomyopathy (NCCM).

Objectives: The study sought to investigate a familial electromechanical disorder characterized by SND and NCCM, and to identify the underlying genetic basis.

The neuromuscular junction: selective remodeling of synaptic regulators at the nerve/muscle interface.

The peripheral synapses between motoneurons and skeletal muscle fibers, the neuromuscular junctions, are ideal to investigate the general principles of synaptogenesis that depend on the interaction of activity-dependent and activity-independent signals. Much has been learned from gene "knock out" mouse models that helped to identify major synaptic regulators. The "knock out" approach, however, may not distinguish between changes arising from the disruption of molecular signaling pathways and changes caused by the absence of synaptic transmission.

Novel mouse model reveals distinct activity-dependent and -independent contributions to synapse development.

The balanced action of both pre- and postsynaptic organizers regulates the formation of neuromuscular junctions (NMJ). The precise mechanisms that control the regional specialization of acetylcholine receptor (AChR) aggregation, guide ingrowing axons and contribute to correct synaptic patterning are unknown. Synaptic activity is of central importance and to understand synaptogenesis, it is necessary to distinguish between activity-dependent and activity-independent processes.

Time lapse in vivo visualization of developmental stabilization of synaptic receptors at neuromuscular junctions.

The lifetime of nicotinic acetylcholine receptors (AChRs) in neuromuscular junctions (NMJs) is increased from <1 day to >1 week during early postnatal development. However, the exact timing of AChR stabilization is not known, and its correlation to the concurrent embryonic to adult AChR channel conversion, NMJ remodeling, and neuromuscular diseases is unclear. Using a novel time lapse in vivo imaging technology we show that replacement of the entire receptor population of an individual NMJ occurs end plate-specifically within hours.

Differential muscle-driven synaptic remodeling in the neuromuscular junction after denervation.

We used knock-in mice that express green fluorescent protein (GFP)-labeled embryonic-type acetylcholine receptors to investigate postsynaptic responses to denervation of fast-twitch and slow-twitch muscle fibers, and to visualize the integration of newly synthesized GFP-labeled embryonic-type receptors into adult synapses. The embryonic-type receptors are transiently expressed and incorporated into the denervated endplates. They replaced synaptic adult-type receptors in a directed fashion, starting from the endplate's periphery and proceeding to its central regions.

Transcription profiling of HCN-channel isotypes throughout mouse cardiac development.

Hyperpolarization-activated ion channels, encoded by four mammalian genes (HCN1-4), contribute in an important way to the cardiac pacemaker current I(f). Here, we describe the transcription profiles of the four HCN genes, the NRSF, KCNE2 and Kir2.1 genes from embryonic stage E9.

AChR channel conversion and AChR-adjusted neuronal survival during embryonic development.

We generated knock-in mice that express GFP-labeled embryonic-type acetylcholine receptors (AChR) to follow postsynaptic differentiation and innervation during embryonic development and to visualize the postnatally occurring channel conversion from embryonic- to adult-type AChR. The dynamics of AChRgamma/AChRepsilon conversion at the neuromuscular junction indicates that muscle-specific programs of receptor subunit gene transcription control AChR replacement. While conversion proceeds from peripheral to central regions for individual endplates, it does not occur simultaneously for all endplates.