Segmentation in the human nervous system
Segmentation is the physical characteristic by which the human body is divided into repeating subunits called segments arranged along a longitudinal axis. In humans, the segmentation characteristic observed in the nervous system is of biological and evolutionary significance. Segmentation is a crucial developmental process involved in the patterning and segregation of groups of cells with different features, generating regional properties for such cell groups and organizing them both within the tissues as well as along the embryonic axis.
Introduction
Human nervous system consists of the central nervous system, which comprises the brain and spinal cord, and the peripheral nervous system comprising the nerve fibers that branch off from the spinal cord to all parts of the body. Both parts of the nervous system are actively involved in communicating signals between various parts of the body to ensure the smooth and efficient transfer of information that controls and coordinates the movement of muscles, and regulates organ functions. Neurons, which form the elemental unit of the nervous system, receive messages from their dendrites, relay the information as an electrical signal down the axon and releases chemical messengers known as neurotransmitters, thus converting the electrical signal into a chemical signal.Segmentation
Segmentation is a crucial patterning process that is involved in the development of both the central nervous system and peripheral nervous system. In the central nervous system, segmentation is involved in the patterning of the neuronal population. Added to that, segmentation guides the developing axons and contribute to the development of the peripheral nervous system. In bilateral animals, the fundamental body plan involves the left and right sides as mirror images to each other with a hollow tube of gut cavity from mouth to anus along with a nerve cord with a structure named ganglion for each segment of the body. In fact, most evolutionary evidences point to the postulate that segmentation is an independent evolutionary event that arose multiple times and that the cellular and molecular pathways of segmentation might show differences in different contexts due to this fact.Biological significance of segmentation
The nervous system segmentation confers several developmental advantages to the vertebrate body as humans possess a body plan that is bilaterally segmented at the nervous system level. The segmentation is involved at all levels of the human nervous system with increasing level of complexity in the innervation from the brain to limbs. The presence of conserved features in various species of animals serves as a strong point to the nervous system’s origin from a common ancestor. Also, the neural segments form the basic building block of the human nervous system and these sub units possess their own level of autonomy in both the singular and collective sense. The segments that compose the nervous system, although initially similar in their composition, are later modified by gene expression patterns that are specific to them. Segmental pattern in human beings can be observed clearly during early developmental phase.Embryonic process of segmentation
In humans, the spinal cord comprises a major part of the central nervous system. Along with the brain, it develops from the dorsal nerve cord in the embryonic stage. The spinal cord consists of such segmental enlargements called ganglia. These ganglia form the basis for the peripheral nervous system’s sensory and motor neurons that innervate various parts of the body. The vertebral segmentation is a process that forms a distinctive feature of the group. At first, somites form as a spherical epithelial structure with a central lumen lined by radially arranged cells. Structures such as mesenchymal sclerotome which later develop as the vertebral column along with notochord, and dermomyotome which further divides to form two types of cells, develop from these somites. The sequential epithelialization of the mesodermal mesenchymal rods lead to the formation of somites and the vertebrae originate from these structures. In higher vertebrates such as humans, the segmental plates are laid down during the process of gastrulation and the segmental plates appear on both sides of the mid-line neural epithelium. Later, the process of neurulation occurs in the mid-line and the segmental plates proceed to the side of the neural tube and notochord. Even though mitotic cell divisions create more cells within these plates, the length of the plates is maintained constant. Although intercellular connections mechanisms such as gap junctions and tight junctions are formed in the cells of the segmental plates, tight junctions are not involved in large network of cells as observed commonly in mature epithelium. A cell-cell adhesion chemical, namely calcium dependent N-cadherin, is present at varying concentrations in the anterior and posterior parts as it is expressed at a higher concentration in the anterior portion of the segmental plate and at lower concentration at the posterior part. During segmentation, the concentration of N-cadherin increases at the apical portion of the cell surface. Later, the ventromedial part of the somite is dis-aggregated from the sclerotome after a measurable loss of immunoreactivity of N-cadherin in this region. The observed change in the concentration of this chemical exemplifies the role of the mediatory molecular mechanism in the cell-cell adhesion during the formation of somites.The segmentation pattern observed in the spinal nerves is in fact governed by the somatic mesoderm. In the embryonic stages of higher vertebrates including humans, the segmentation of these spinal nerves follows the directions from both the anterior and posterior sections of the somite mesoderm. The segmentation pattern observed in the peripheral nervous system derives itself from the paraxial mesoderm. The paraxial mesoderm is arranged along the sides of the notochord and neural tube as repetitive structures called somites. In fact, somites are one of the first embryonic structures to display segmentation. Structures associated with the peripheral nervous system such as dorsal root ganglia develop a segmental alignment with the somites. In fact, the axons from the developing embryo neurons work under the direction of a variety of long-range and short-range cues. These cues are responsible for the determination of the trajectory of the neuron, and the mechanism of their development. Axons can follow various mechanisms including attractive/permissive or repulsive /inhibitory pathways of development. The confinement of the axons arising from the dorsal root ganglia, the neural crest cells and the motor neurons from ventral neural tube to the anterior portion of the mesodermal somite is a striking feature in higher vertebrates.