Initiation of human myoblast differentiation via dephosphorylation of Kir2.1 K+ channels at tyrosine 242.

Myoblast differentiation is essential to skeletal muscle formation and repair. The earliest detectable event leading to human myoblast differentiation is an upregulation of Kir2.1 channel activity, which causes a negative shift (hyperpolarization) of the resting potential of myoblasts.

Myogenic precursor cell transplantation in pigs: a step towards a clinical use for muscle regeneration?

It is most probable that, in a near future, myogenic precursor cell transplants will have clinical applications in domains as different as orthopaedics, endocrinology, management of heart infarct, and therapies of muscle diseases. We have proposed to introduce the use of myogenic precursor cell transplantation in patients, after preliminary tests in a large animal model, the pig. Our initial effort was centred on the domain of orthopaedics.

The calcineurin pathway links hyperpolarization (Kir2.1)-induced Ca2+ signals to human myoblast differentiation and fusion.

In human myoblasts triggered to differentiate, a hyperpolarization, resulting from K+ channel (Kir2.1) activation, allows the generation of an intracellular Ca2+ signal. This signal induces an increase in expression/activity of two key transcription factors of the differentiation process, myogenin and MEF2.

Calcium sources used by post-natal human myoblasts during initial differentiation.

Increases in cytoplasmic Ca(2+) are crucial for inducing the initial steps of myoblast differentiation that ultimately lead to fusion; yet the mechanisms that produce this elevated Ca(2+) have not been fully resolved. For example, it is still unclear whether the increase comes exclusively from membrane Ca(2+) influx or also from Ca(2+) release from internal stores. To address this, we investigated early differentiation of myoblast clones each derived from single post-natal human satellite cells.

[How should a muscular disease be studied?].

Muscle diseases are an expanding field, mainly due to the progress in genetics and biochemistry. Evaluation starts with a thorough history of the patient's symptoms and signs. The leading clinical manifestations are weakness, atrophy, myalgia, fatigue, more rarely myotonia and in the child hypotonia or walking difficulty.

Membrane hyperpolarization triggers myogenin and myocyte enhancer factor-2 expression during human myoblast differentiation.

It is widely thought that myogenin is one of the earliest detectable markers of skeletal muscle differentiation. Here we show that, during human myoblast differentiation, an inward rectifier K(+) channel (Kir2.1) and its associated hyperpolarization trigger expression and activity of the myogenic transcription factors, myogenin and myocyte enhancer factor-2 (MEF2).

Acceleration of human myoblast fusion by depolarization: graded Ca2+ signals involved.

We have previously shown that human myoblasts do not fuse when their voltage fails to reach the domain of a window T-type Ca(2+) current. We demonstrate, by changing the voltage in the window domain, that the Ca(2+) signal initiating fusion is not of the all-or-none type, but can be graded and is interpreted as such by the differentiation program. This was carried out by exploiting the properties of human ether-à-go-go related gene K(+) channels that we found to be expressed in human myoblasts.

Presence of functional oxytocin receptors in cultured human myoblasts.

In the present report, we provide for the first time evidence that functional oxytocin receptors (OTRs) are present in human myoblasts obtained from clonal cultures of postnatal satellite cells. First, binding studies performed with a non selective vasopressin (AVP) and oxytocin (OT) radioligand indicated the presence of a single class of binding sites. Second, OTR mRNA was detected by RT-PCR analysis whereas transcripts for AVP V(1a), V(1b) or V(2) receptors (V(1a)R, V(1b)R and V(2)R respectively) were not detected.

Human myoblast differentiation: Ca(2+) channels are activated by K(+) channels.

In a paradigm of cellular differentiation, human myoblast fusion, we investigated how a Ca(2+) influx, indispensable for fusion, is triggered. We show how newly expressed Kir2.1 K(+) channels, via their hyperpolarizing effect on the membrane potential, generate a window Ca(2+) current (mediated by alpha 1H T-type Ca(2+) channels), which causes intracellular Ca(2+) to rise.