A publication in Cell and Tissue Research

Muscle fibres: an unexpected organisation revealed by ULiège researchers

Longitudinal section illustrating the lattice-like configuration within the sonic muscle in Parophidion vassali. Credit Marc Thiry/University of Liège

Researchers at the University of Liège, Eric Parmentier and Marc Thiry have just made the unexpected discovery of a novel organisation of muscle fibres in Parophidion vassali, a fish that lives in the Mediterranean Sea and, like many fish, uses specialised muscles to produce sounds. This is an important discovery that could well change our understanding of muscle contraction. This research has been published in Cell and Tissue Research.

The history of the description of skeletal muscles has its origins in the observations made by the Dutch biologist Antoni van Leeuwenhoek, a precursor of cell biology and microbiology who, in an article published in 1712 in the Philosophical Transactions of the Royal Society, reported, thanks to the use of a portable single-lens microscope, the first description of muscle fibres from the whale. In 1840, the anatomist William Bowman provided a more precise description of the muscle, noting: "the existence and arrangement of alternately light and dark lines [...] which are of exquisite delicacy and finish" (See Muscle fibres below). Subsequent studies have led to increasingly clear descriptions, including identifying the molecules that make up the muscle and explaining how it works, particularly the model of muscle contraction proposed by the biophysicist Andrew Huxley in 1957. Over the last 300 years, numerous studies have extended the representation of muscle fibre organisation to different taxa. This has shown that the general organisation of striated muscle fibres has remained perfectly conserved in all groups of vertebrate animals studied to date.

However, the proportion of each of these cellular components can vary from one fibre to another, giving these fibres particular contraction properties. For example, a fibre rich in myofibrils with a poorly developed sarcoplasmic reticulum is found in muscles that develop force during contraction. Conversely, fibres low in myofibrils with an abundance of sarcoplasmic reticulum and numerous mitochondria are present in muscles that develop an increased speed of contraction. The fastest muscles are found in the sonic muscles of fish, where certain species produce sounds using muscles that contract at a frequency of between 100 and 300 Hz, i.e. 100 to 300 contraction/relaxation cycles per second.

A recent study in collaboration between the Functional and Evolutionary Morphology Laboratory and the Cell and Tissue Biology Laboratory (GIGA Neurosciences) revealed a new arrangement of myofibrils within the fibres of a sonic muscle in the fish Parophidion vassali. Rather than being arranged in parallel, the myofibrils form an enormous network within the muscle fibre," explains Prof Eric Parmentier, director of the Functional and Evolutionary Morphology Laboratory (Faculty of Science / FOCUS research unit) at ULiège. Each myofibril subdivides into two branches at each sarcomere, one connecting to the myofibril above and the other connecting to the myofibril below (Figure 1B). This new muscle fibre design could result in a rapidly contracted muscle while retaining strength. The paucity of myofibrils and the high volume occupied by the sarcoplasmic reticulum favour fibres that contract rapidly. The network structure of the myofibrils would allow more myosin heads to form cross-bridges with the actin myofilaments, increasing strength in this fast muscle," explains Prof Marc Thiry, Director of the Cell and Tissue Biology Laboratory. In addition, numerous mitochondria unusually arranged within the Z striae (very long in these fibres: 700 nm compared with 70 to 150 nm in a conventional muscle) appear to provide the energy needed to produce long-lasting sounds". This new type of organisation of striated muscle fibres, never before described in the scientific literature and which would therefore make it possible to combine muscular strength and speed, requires further studies to understand how it works and to determine whether there are adaptations at the level of the different molecules involved in these muscles.  

Fibres musculaires poisson(c)E.Parmentier

Comparison of the organisation of "classic" skeletal muscle with parallel myofibrils and sonic muscle with lattice myofibrils in Parophidion vassali. Credits: E.Parmentier/M.Thiry/Université de Liège

Scientific reference

Parmentier & M.Thiry, A new organisational design in skeletal muscle fibres, Cell and Tissue Research, mai 2023.

Your contacts at ULiège

Eric Parmentier

Marc Thiry


Muscle fibres

Striated skeletal muscle fibres or cells represent animals' elementary units of voluntary muscles (muscles that enable movements such as locomotion or posture maintenance). Each fibre is characterised by numerous contractile elements, actin and myosin myofilaments, organised in bundles parallel to the muscle fibre's long axis, called myofibrils. In the longitudinal section under the optical microscope, these fibres appear as a succession of light and dark bands located at the same level for each myofibril, giving the appearance of transverse striation to the muscle fibre.  A darker line divides the light band in the middle, known as the Z striation. The portion of the myofibril between two Z striae is called a sarcomere and represents the contractile unit of the myofibril. Each myofibril is therefore made up of many sarcomeres placed end to end. The myofibrils occupy a large cell volume and are surrounded by cisternae of the smooth endoplasmic reticulum (or sarcoplasmic reticulum), which stores the calcium essential for muscle contraction. In addition, mitochondria are located close to the myofibrils, the main source of ATP providing energy for muscle contraction.

Myofibrille fibre musculaire striéé (c) ULiège

Longitudinal section through a classical skeletal muscle. Credits: Marc Thiry/ Université de Liège

Share this news