Abstract
Animals are able to move and react in numerous ways to external stimuli. Thus, environmental stimuli need to be detected, information must be processed and finally an output decision must be transmitted to the musculature to get the animal moving. All these processes depend on the nervous system which comprises an intricate neuronal network and many glial cells. In the last decades, a neurono-centric view on nervous system function channeled most of the scientific interest toward the analysis of neurons and neuronal functions. Neurons appeared early in animal evolution and the main principles of neuronal function from synaptic transmission to propagation of action potentials are conserved during evolution. In contrast, not much is known on the evolution of glial cells that were initially considered merely as static support cells. Although it is now accepted that glial cells have an equally important contribution as their neuronal counterpart to nervous system function, their evolutionary origin is unknown. Did glial cells appear several times during evolution? What were the first roles glial cells had to fulfil in the nervous system? What triggered the formation of the amazing diversity of glial morphologies and functions? Is there a possible mechanism that might explain the appearance of complex structures such as myelin in vertebrates? Here, we postulate a common evolutionary origin of glia and depict a number of selective forces that might have paved the way from a simple supporting cell to a wrapping and myelin forming glial cell.
Highlights
We will consider the interplay of glia and neurons as driving force of the evolution of elaborated computing devices as we find them in our own brain, focusing on the origin of wrapping glial cells and myelin
As we will discuss below, such an advance in nervous system function requires a close interplay of neurons and glial cells
We find simple nervous systems that might resemble the evolutionary intermediate described above where all of the major components defining a neuron are in place
Summary
Fossil records demonstrate that evolution of metazoan animals started more than 650 million years ago with the appearance of Demospongiae, primitive Porifera (sponges) lacking true tissues, and organs (Leys & Hill, 2012; Love et al, 2009). Neurons residing in the nervous system, or the brain, use evolutionary conserved mechanisms to direct behavior, thoughts and emotions of the animal, which over the last century resulted in a neurono-centric view of brain function It is long known, since Virchow's first descriptions of glial cells in 1846 and 1858 and Deiter's first drawing. The formation of sensory cilia, which are present in Porifera, caused morphological specializations of the apical cell domain (Mah & Leys, 2017) This quite likely caused restrictions in feeding from the external world by endocytosis compared to normal neighboring epithelial cells. We postulate that neurons and glial cells evolved at the same time to meet one of the biggest challenges neuronal cells are facing: nutrient supply
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