Structural organization of rabbit neocortex in prenatal ontogenesis

In the review on the basis of data of different authors, the development dynamics of the rabbit neocortex in prenatal life is presented. The main points of neurons development, interneuronal contacts, layer-by-layer and areal differentiation as well as neocortex afferental and efferental communications, that are elucidated ambiguously by investigators, are discussed. For the purpose of determination of the neocortex maturation to the birth-date the comparative analysis of the reference morphological data and author's own neurophysiological data is accomplished.     

Formation of structural and ultrastructural organization of striatum rat postnatal ontogenesis upon changes in their embryonal development

By light microscopy (by Nissl and Golgi), electron microscopy, and immunohistochemistry methods, formation of structure of the brain striatum dorsolateral part from birth to the 3-month age was studied in rats submitted to acute hypoxia at the period of embryogenesis. It has been established that hypoxia at the 13.5th day (E13.5) leads to a delay of neuronogenesis for the first two weeks of postnatal development as compared with control animals, while the majority of large neurons at this period are degenerated by the type of chromatolysis with swelling cell body and processes and lysis of cytoplasmic organoids. By the end of the 3rd week, shrunk hyperchromic or picnomorphic neurons with the electron-dense cytoplasm and enlarged tubules of endoplasmic reticulum and Golgi complex were also observed. An increased number of swollen processes of glial cells was detected in neuropil around degenerating neurons. By the 30th day as well as in adult rats there was observed destruction of mitochondrial apparatus, an increase of the number of lysosomes, and the appearance of bladed nuclei - signs of apoptotic cell death, which was also confirmed by an increased expression of proapoptotic p53 protein and its colocalization with caspase-3 in a part of neurons. Morphometrical analysis has shown a decrease of density of striatum cell arrangement and a change of ratio of different cell types in the rats submitted to hypoxia as compared with control group. At early stages of postnatal ontogenesis there was the greatest decrease (42.3% at the 5th day, 14.2% at the 10th day, p < 0.01) of the number of large neurons with the area more than 80 microm2. After 3 weeks of postnatal development the number of middlesize neurons (30-95 microm2) decreased (by 11.8-19.2%) as compared with control. The obtained data show that a change of conditions of embryogenesis (hypoxia) at the period of the most intensive proliferation of the forebrain neuroblasts leads to disturbances of the process of formation of the striatum nervous tissue. This can be the cause of delay of development and disturbances of behavior and learning observed in rats submitted to prenatal hypoxia.     

Cortico-subcortical interrelationships in the visual analyzer system at various stages of ontogenesis]

The influence of a corticofugal volley produced by single electrical stimulation of the visual projection cortical zone on the neuronal activity of LGB was studied in non-anaesthetized rabbits aged from three to thirty-five days. A coincidence was found between the time of appearance of nonspecific inhibitory corticofugal influences on the spontaneous activity of LGB neurons and the emergence of the first phasic-specific responses of the neurones of this level to a visual stimulus. It has been shown that the sensory flow at the LGB level can be controlled by non-specific inhibitory corticofugal influences at early periods of postnatal development. The appearance from the 15th day of life of specific responses to a corticofugal volley, including activation phases, leads to a greater complexity of the regulating Cortical influences on conduction of the afferent signal at the thalamic level. The data obtained are considered from the standpoint of integration of various levels of the visual analyser at different stages of ontogenesis.     

Formation of striatum structural and ultrastructural organization in rat postnatal ontogenesis at changes of conditions of their embryonic development

Using light microscopy (Nissl and Golgi techniques), electron microscopy and immunohistochemistry, formation of structure of the brain striatum dorsolateral part from birth to three month of age was studied in rats submitted to acute hypoxia at the period of embryogenesis. Hypoxia at the 13.5th day of pregnancy (E 13.5) was found to lead to a delay of neuronogenesis for the first two weeks of postnatal development as compared with control animals, and the majority of large neurons for this period were degenerated by the type of chromatolysis with swelling of the cell body and processes and lysis of cytoplasmic organelles. By the end of the third week, shrunken hyperchromic or pycnomorphic neurons with the electron-dense cytoplasm and enlarged tubules of endoplasmic reticulum and Golgi complex were also observed. An increased number of swollen processes of glial cells was found in neuropil around the degenerating neurons. By the 30th day as well as in adult animals, destruction of mitochondrial apparatus, an increased number of lysosomes, and blade-shaped nuclei, which are characteristics of the apoptotic cell death, were observed. This is also confirmed by an increased expression of proapoptotic protein (p53) and its co-localization with caspase-3 in a part of neurons. Morphometric analysis showed a decrease of the cell distribution density in striatum and a change of ratio of different cell types in hypoxia-exposed rats as compared with control group. The most pronounced decrease (42.3% at the 5th day, 14.2% at the 10th day, p < 0.01) of the number of large neurons (larger than 80 μm²) was revealed at early stages of postnatal ontogenesis. After 3 postnatal weeks, the number of middle-sized neurons (30–95 μm²) decreased (by 11.8–19.2% as compared with control, p < 0.05). The obtained data have shown that changes of embryogenesis conditions (hypoxia) at the period of the most intensive proliferation of telencephalon neuroblasts lead to impairment of the process of striatal nervous tissue formation. This might be the cause of delay of development and disturbances of behavior and learning, which are observed in rats exposed to prenatal hypoxia.     

The somatotopic organization of the olfactory bulb in elasmobranchs

The olfactory bulbs (OBs) are bilaterally paired structures in the vertebrate forebrain that receive and process odor information from the olfactory receptor neurons (ORNs) in the periphery. Virtually all vertebrate OBs are arranged chemotopically, with different regions of the OB processing different types of odorants. However, there is some evidence that elasmobranch fishes (sharks, rays, and skates) may possess a gross somatotopic organization instead. To test this hypothesis, we used histological staining and retrograde tracing techniques to examine the morphology and organization of ORN projections from the olfactory epithelium (OE) to the OB in three elasmobranch species with varying OB morphologies. In all three species, glomeruli in the OB received projections from ORNs located on only the three to five lamellae situated immediately anterior within the OE. These results support that the gross arrangement of the elasmobranch OB is somatotopic, an organization unique among fishes and most other vertebrates. In addition, certain elasmobranch species possess a unique OB morphology in which each OB is physically subdivided into two or more “hemi‐olfactory bulbs.” Somatotopy could provide a preadaptation which facilitated the evolution of olfactory hemibulbs in these species. J. Morphol., 2013. © 2012 Wiley Periodicals, Inc.     

Development and organization of the Drosophila olfactory system: An analysis using enhancer traps

Drosophila uses different olfactory organs at different developmental stages. The larval and adult olfactory organs are morphologically dissimilar and have different developmental origins: the antenno-maxillary complex (AMC), which houses the larval olfactory organ, is histolyzed during metamorphosis; the third antennal segment—the principal adult olfactory organ—derives from an imaginal disc. A screen for genes expressed in both larval and adult olfactory organs, but in relatively few other tissues, has been carried out. Seven enhancer trap lines showing reporter gene expression in both the larval AMC and in certain subsets of the adult antenna are described. The antennal staining pattern of one line shows a striking change over the first few days of adult life, with a time course comparable to that of the development of sexual maturity. A pronounced sexual dimorphism in antennal staining pattern is seen in another line. Some staining patterns resemble the patterns of certain classes of antennal sensilla; others show expression restricted to only a small number of cells. Some lines also show expression associated with other chemosensory organs at either the larval or adult stage, including the maxillary palps, labellum, and anterior wing margin. One line, which also shows staining in the male reproductive tract, is male sterile. The significance of these results is considered in terms of (1) the molecular organization of the olfactory system; (2) the recruitment of olfactory genes for use in two developmental contexts; (3) the sharing of genes among different sensory modalities; (4) the role of olfaction in sexual behavior; and (5) posteclosional changes in the olfactory system. © 1992 John Wiley & Sons, Inc.     

Small subfamily of olfactory receptor genes: structural features, expression pattern and genomic organization.

Olfactory receptors of the OR37 subfamily are characterized by distinct sequence features and are expressed in neurons segregated in a restricted area of the olfactory epithelium. In the present study, we have characterized the complement of OR37-like genes in the mouse. Five OR37-like genes were identified. They reside within only 60kb of DNA on chromosome 4. About 70kb distant from this cluster, two additional olfactory receptor genes are located, which are members of distinct receptor subfamilies. Phylogenetic analysis demonstrated that the two physically linked receptors are closely related to the OR37 subfamily. Studies of gene expression showed that both genes are also expressed in clustered neuron populations located in the typical OR37 region of the epithelium. These data suggest the involvement of locus-dependent mechanisms for the spatial control of OR gene expression.