Abstract
Left–right brain asymmetry is a fundamental property observed across phyla from invertebrates to humans, but the mechanisms underlying its formation are still largely unknown. Rapid progress in our knowledge of the formation of body asymmetry suggests that brain asymmetry might be controlled by the same mechanisms. However, most of the functional brain laterality, including language processing and handedness, does not share common mechanisms with visceral asymmetry. Accumulating evidence indicates that asymmetry is manifested as chirality at the single cellular level. In neurons, the growth cone filopodia at the tips of neurites exhibit a myosin V-dependent, left-helical, and right-screw rotation, which drives the clockwise circular growth of neurites on adhesive substrates. Here, I propose an alternative model for the formation of brain asymmetry that is based on chiral neuronal motility. According to this chiral neuron model, the molecular chirality of actin filaments and myosin motors is converted into chiral neuronal motility, which is in turn transformed into the left–right asymmetry of neural circuits and lateralized brain functions. I also introduce automated, numerical, and quantitative methods to analyze the chirality and the left–right asymmetry that would enable the efficient testing of the model and to accelerate future investigations in this field.
Highlights
IntroductionThe body can be divided into left and right parts, which are connected along the midline
In bilateral animals, the body can be divided into left and right parts, which are connected along the midline
L–R brain asymmetry is a widespread in property that is observed among various brain asymmetry is a widespread property that is observed among various species
Summary
The body can be divided into left and right parts, which are connected along the midline. Most of the tissues on both sides are equivalent and bilaterally symmetric, but some tissues are asymmetric and not mirror-imaged. Internal organs, such as the heart, liver, pancreas, stomach, and intestines, exhibit obvious asymmetry in shape and location. Compared with the internal organs, the brain appears rather symmetric. The brain seems to have two equivalent structures in both hemispheres. The left hemisphere in humans is specialized for language processing, while the right hemisphere is specialized for certain visuospatial functions [1,2,3]
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