Perinatal development of mammillotegmental connections in rats

Development of direct axonal connections of the hypothalamic mammillary bodies with ventral and dorsal tegmental nuclei of Gudden was studied on fixed rat brains from day 14 of embryonic development until day 10 of postnatal development using the method of diffusion of the lipophilic fluorescent carbocyanine tracer 1,1'-dioctadecyl-3,3,3',3'-tetramethylindocarbocyanine perchlorate along the neuronal membranes. The tracer was inserted into the mammillary bodies or into the tegmentum and after incubation in a fixative fluorescent nerve cells and nerve fibers were visualized in the brain tissue. The mammillotegmental tract was found to start developing earlier than other conducting systems of the mammillary bodies. On days 14-15 of embryonic development, it was visualized as a bundle of axons running from the mammillary bodies caudally to the midbrain. A group of neurons in the midbrain tegmentum and their axons going to the mammillary bodies via the mammillary peduncle were first visualized on day 19 of embryonic development. The mammillotegmental tract and mammillary peduncle developed progressively from the moment of birth. Ventral and dorsal tegmental nuclei were formed in the midbrain by day 10 of the postnatal development. Thus, the formation of reciprocal connections of the mammillary bodies with midbrain tegmental nuclei was first described during perinatal development in rats.     

Perinatal development of mammillotegmental connections in rats

Development of direct axonal connections of the hypothalamic mammillary bodies with ventral and dorsal tegmental nuclei of Gudden was studied on fixed rat brains from day 14 of embryonic development until day 10 of postnatal development using the method of diffusion of the lipophilic fluorescent carbocyanine tracer 1,1′-dioctadecyl-3,3,3′,3′-tetramethylindocarbocyanine perchlorate along the neuronal membranes. The tracer was inserted into the mammillary bodies or into the tegmentum and, after incubation in a fixative, fluorescent nerve cells and nerve fibers were visualized in the brain tissue. The mammillotegmental tract was found to start developing earlier than other projection systems of the mammillary bodies. On days 14–15 of embryonic development, it was visualized as a bundle of axons running from the mammillary bodies caudally to the midbrain. A group of neurons in the midbrain tegmentum and their axons going to the mammillary bodies via the mammillary peduncle were first visualized on day 19 of embryonic development. The mammillotegmental tract and mammillary peduncle developed progressively from the moment of birth. Ventral and dorsal tegmental nuclei were formed in the midbrain by day 10 of the postnatal development. Thus, the formation of reciprocal connections of the mammillary bodies with midbrain tegmental nuclei was first described during perinatal development in rats.     

The effect of a parietal meningoencephalocele on the morphogenesis of the neuroepithelium of the human brain]

Meningoencephalic hernia was studied in human embryo at the 5th week (stage 15) of the development. The analysis of parietal hernia showed that the anomalous development of cerebral tissue was related with disturbed shape-forming processes in the nerve tube. The medullar toruli were not closed at the stage of nerve plate to form a free edge of neuroepithelial layer. Its relaxation resulted in a spontaneous foldness and an enhanced proliferation of neuroepithelial cells. The proliferative activity induced hyperplasia of the layer end zones a disproportionately rapid growth of the brain disturbed the integrity of cephalic ectoderm and elicited formation of external cerebral hernias. It was suggested that disturbances of tangential mechanical tensions which control the proliferative activity in the neuroepithelium underlie the overgrowth of nervous tissue.     

A common biomechanical model for the formation of stationary cell domains and propagating waves in the developing organisms

Many important morphogenetic processes that take place in the development of an animal start from the segregation of a homogeneous layer of cells into a different number of the domains of columnar and flattened cells. In many cases, waves of cell shape transformation travel throughout embryonic tissues. A biomechanical model is presented which embraces both kinds of event. The model is based on the idea of interplay between short- and long-range factors. While the former promote the spreading of a given cell state along a cell row in the recalculation direction, long-range factors are associated with self-generated tensions which, after exceeding a certain threshold, induce active cell extension and hence the rise of tangential pressure. Different kinds of biologically realistic stationary structures, as well as various kinds of the running waves, can be modelled under different parameter values. Moreover, the current model can be coupled with the previous one (Beloussov and Grabovsky, Comput. Methods Biomech. Biomed. Eng., 6: 53-63 (2003)) permitting a common causal chain to be created, moving from the state of an initial homogeneous cell layer towards the complicated shapes of embryonic rudiments.     

A common biomechanical model for the formation of stationary cell domains and propagating waves in the developing organisms

Many important morphogenetic processes that take place in the development of an animal start from the segregation of a homogeneous layer of cells into a different number of the domains of columnar and flattened cells. In many cases, waves of cell shape transformation travel throughout embryonic tissues. A biomechanical model is presented which embraces both kinds of event. The model is based on the idea of interplay between short- and long-range factors. While the former promote the spreading of a given cell state along a cell row in the recalculation direction, long-range factors are associated with self-generated tensions which, after exceeding a certain threshold, induce active cell extension and hence the rise of tangential pressure. Different kinds of biologically realistic stationary structures, as well as various kinds of the running waves, can be modelled under different parameter values. Moreover, the current model can be coupled with the previous one (Beloussov and Grabovsky, Comput. Methods Biomech. Biomed. Eng., 6: 53–63 (2003)) permitting a common causal chain to be created, moving from the state of an initial homogeneous cell layer towards the complicated shapes of embryonic rudiments.     

Membrane bodies in the nuclei of cerebral cortex neurons of the progeny of rats sensitized to brain antigen

The ultrastructure of sensomotor cortical neurons was studied by electron microscopy in young rats born to females sensitized with brain antigen before mating. Different membranous inclusions were discovered in neuronal nuclei. The membranous bodies were seen on the second day after birth and could be detected until day 60. It is suggested that the nuclear membranous bodies have been formed in the prenatal period. They may be the result of intraplacental impact of neuroantibodies on the developing embryonic brain.     

Tension-dependent collective cell movements in the early gastrula ectoderm of Xenopus laevis embryos

Ventral ectodermal explants taken from early gastrula embryos of Xenopus laevis were artificially stretched either by two opposite concentrated forces or by a distributed force applied to the internal explant’s layer. These modes of stretching reflect different mechanical situations taking place in the normal development. Two main types of kinematic response to the applied tensions were detected. First, by 15 min after the onset of concentrated stretching a substantial proportion of the explant’s cells exhibited a concerted movement towards the closest point of the applied stretching force. We define this movement as tensotaxis. Later, under both concentrated and distributed stretching, most of the cell’s trajectories became reoriented perpendicular to the stretching force, and the cells started to intercalate between each other, both horizontally and vertically. This was accompanied by extensive elongation of the outer ectodermal cells and reconstruction of cell-cell contacts. The intercalation movements led first to a considerable reduction in the stretch-induced tensions and then to the formation of peculiar bipolar ”embryoid” shapes. The type and intensity of the morphomechanical responses did not depend upon the orientation of a stretching force in relation to the embryonic axes. We discuss the interactions of the passive and active components in tension-dependent cell movements and their relations to normal morphogenetic events. Received: 26 April 1999 / Accepted: 30 August 1999     

四种细胞因子在中华蟾蜍脑中的分布

采用免疫组织化学SABC法,研究白介素-1α、干扰素-γ、神经生长因子-β和肿瘤坏死因子-α在成体中华蟾蜍脑中的表达和分布特点。结果发现,白介素-1α阳性细胞数量很多,分布于脑的各个区域。白介素-1α多在细胞的胞体中,而原始海马锥体细胞,中脑的背前侧被盖核和腹后侧被盖核中的细胞可见阳性的突起。干扰素-γ阳性细胞数量较多,分布在端脑的原始海马和隔区,丘脑腹外侧核,下丘脑的视前区、视交叉上核和腹侧漏斗核,中脑被盖的背前侧被盖核、腹前侧被盖核、背后侧被盖核和腹后侧被盖核中,小脑的Purkinje细胞层和延髓的网状核,其中原始海马,背前侧被盖核和背后侧被盖核,视交叉上核,Purkinje细胞层和网状核中的细胞中可见阳性突起。神经生长因子-β阳性细胞数量较少,主要存在于下丘脑的视前区和视交叉上核,中脑被盖的腹前侧被盖核,小脑的Purkinje细胞层和延髓的网状核中,其中视前区、Purkinje细胞层和网状核中细胞可见阳性突起。肿瘤坏死因子-α阳性细胞数量最少,分布范围仅限于中脑被盖背前侧区和延髓的网状核及中缝核,但细胞具有阳性突起。因此,白介素-1α和干扰素-γ在成体动物脑中分布较为广泛,可能是神经细胞生命活动所必需的;而神经生长因子-β和肿瘤坏死因子-α在成体动物脑中分布范围狭窄,其作用可能仅限于脑中的某些特殊区域。     

Cytomechanics of axonal development

Mechanical tension is a robust regulator of axonal development of cultured neurons. We review work from our laboratory, using calibrated glass needles to measure or apply tension to chick sensory neurons, chick forebrain neurons, and rat PC12 cells. We survey direct evidence for two different regimes of tension effects on neurons, a fluid-like growth regime, and a nongrowth, elastic regime. Above a minimum tension threshold, we observe growth effects of tension regulating four phases of axonal development:

1. Initiation of process outgrowth from the cell body;
2. Growth cone-mediated elongation of the axon;
3. Elongation of the axon after synaptogenesis, which normally accommodates the skeletal growth of vertebrates; and
4. Axonal elimination by retraction.

Significantly, the quantitative relationship between the force and the growth response is suprisingly similar to the simple relationship characteristic of Newtonian fluid mechanical elements: elongation rate is directly proportional to tension (above the threshold), and this robust linear relationship extends from physiological growth rates to far-above-physiological rates. Thus, tension apparently integrates the complex biochemistry of axonal elongation, including cytoskeletal and membrane dynamics, to produce a simple “force input/growth output” relationship. In addition to this fluid-like growth response, peripheral neurons show elastic behaviors at low tensions (below the threshold tension for growth), as do most cell types. Thus, neurites could exert small static forces without diminution for long periods. In addition, axons of peripheral neurons can actively generate modest tensions, presumably similar to muscle contraction, at tensions near zero. The elastic and force-generating capability of neural axons has recently been proposed to play a major role in the morphogenesis of the brain.     

Special smooth muscle cells along the submucosal surface of the guinea pig colon with reference to its spontaneous contractions

Antiperistalses occur from the flexure region of the guinea pig colon. We previously demonstrated that the circular muscle at the mesenteric border of the flexure region produced spontaneous regular contractions and found special smooth muscle cells believed to be pacemakers along the submucosal surface of the circular muscle layer. In this study, we revealed bipolar- and multipolar-type special smooth muscle cells along the submucosal surface of the muscle layer. Their slender cell processes contacted each other and formed a cellular network. Caveolae, filament structures expressing smooth muscle actin, vimentin, some desmin, and basal lamina were prominent features. The special smooth muscle cells corresponded to c-Kit-immunopositive cells and so-called interstitial cells or interstitial cells of Cajal in other reports. Their population was larger in the flexure region and the proximal colon than in the distal colon. The circular muscle layer at the flexure region was thicker than in other regions. The contraction in the flexure region showed the highest frequency and regularity. The dense population of special smooth muscle cells at the flexure region and thicker muscle layer may make the mechanical contraction more regular. The antiperistalsis from the flexure region could be explained in relation to the highest frequency of the pulsating contraction.     

Epithelial coating controls mesenchymal shape change through tissue-positioning effects and reduction of surface-minimizing tension

Signalling between mesenchymal and epithelial cells has a profound influence on organ morphogenesis. However, less is known about the mechanical function of epithelial-mesenchymal interactions. Here, we describe two principal effects by which epithelia can regulate shape changes in mesenchymal cell aggregates. We propose that during formation of the embryonic body axis, the epithelial layer relieves surface minimizing tensions that would force cell aggregates into a spherical shape, and controls the serial arrangement of cell populations along the axis. The combined effects permit the tissue to deviate from a spherical form and to elongate.     

Behavior and Differentiation of the Neural Stem Cells in vivo

We studied the behavior and differentiation of human and rat neural stem cells after transplantation in the adult rat brain without immunosuppression. The rat stem cells were isolated from the presumptive neocortex of 15-day-old embryos. The human cells were isolated from the ventricular brain zone of 9-week-old embryos and cultivated for two weeks before transplantation. The results of histomorphological studies suggest that the microenvironment factors did not suppress the growth or development of transplanted stem cells. Both rat and human embryonic multipotent neural cells showed similar behavior and differentiation into neurons and glial cells. After transplantation, they continued to mitotically divide and migrated from the graft area to the surrounding tissue of a recipient brain. The presumptive glial cells migrated preferentially along the capillaries and fibrous structures of the recipient brain. Similar behavior of the rat and human neural stem cells in the microenvironment of the recipient adult rat brain and the absence of immune reaction suggest that the transplantation into the rat brain may serve as a model for studying the developmental biology of the human stem cells.     

Visualization of Rostral Migratory Stream in the Developing Rat Brain by In Vivo Electroporation

Interneurons in the olfactory bulb (OB) are generated from neuronal precursor cells migrating from anterior subventricular zone (SVZa) not only in the developing embryo but also throughout the postnatal life of mammals. In the present study, we established an in vivo electroporation assay to label SVZa cells of rat both at embryonic and postnatal ages, and traced SVZa progenitors and followed their migration pathway and differentiation. We found that labeled cells displayed high motility. Interestingly, the postnatal cells migrated faster than the embryonic cells after applying this assay at different ages of brain development. Furthermore, based on brain slice culture and time-lapse imaging, we analyzed the detail migratory properties of these labeled precursor neurons. Finally, tissue transplantation experiments revealed that cells already migrated in subependymal zone of OB were transplanted back into rostral migratory stream (RMS), and these cells could still migrate out tangentially along RMS to OB. Taken together, these findings provide an in vivo labeling assay to follow and trace migrating cells in the RMS, their maturation and integration into OB neuron network, and unrecognized phenomena that postnatal SVZa progenitor cells with higher motility than embryonic cells, and their migration was affected by extrinsic environments.     

Shape and orientation of nuclei of embryonal fibroblast-like cells cultured on substrates with ordered relief]

Embryo fibroblasts of hamster, rat, mouse, and were cultured 24 hrs on polyvinylchloride plates with regular relief of grooves with cylindric surfaces in between. Most cells were accumulated on the middle part of spaces between the grooves, their nuclei were elongated and oriented in the direction of grooves. Nuclear elongation was assessed quantitatively by the ratio of long to short nuclear axes. Contact orientation was measured as deviation of the long nuclear axes from the grooves direction. Both contact orientation and elongation considered respectively as "orientation reaction" is maximal and the "form reaction", increased with increasing cylinder curvature (i. e. when the radii diminished from 333 to 61 mcm). Both reactions are well expressed in cultures of the human and (less distinctly) the rat cells. In murine cells, the "orientation reaction" is maximal and the "form reaction" is weak while for the hamster cells the opposite is true. Therefore, both types of reaction seem to be independent characteristics of cells.     

The influence of the metameric pattern in the mesoderm on migration of cranial neural crest cells in the chick embryo

In recent studies of chick embryos, the cranial paraxial mesoblast was found to be patterned into segmental units termed somitomeres. Anterior to the first segmental cleft, seven contiguous segments are aligned, with somitomeric interfaces forming grooves at right angles to the midline. In this study, the morphological relationship between the migratory pathways of cranial neural crest cells and patterned primary mesenchyme was analyzed with the scanning electron microscope, utilizing stereo imaging. In addition, the development of neuromeres in the adjacent neural tube was monitored. It was found that cranial neural crest first appears along the dorsal midline as a ridge of cells which loosens from the wall of the neural tube and migrates laterally as discrete populations. The mesencephalic crest appears first, immediately following neural tube fusion at that level, and migrates over the dorsal surface of the adjacent third somitomere and into the grooves formed by its juncture with the second and fourth somitomeres. Later, the addition of prosencephalic and rostral rhombencephalic crest extends the mesencephalic population to form a shelf of crest which spreads over the dorsal surface of the first four somitomeres. Component cells of this most cranial crest shelf become oriented and mimic the metameric pattern of the subjacent somitomeres. Crest cells adjacent to the fifth somitomeres appear along the midline, but do not migrate, creating a gap anterior to the otic crest. By stage 9, a narrow finger-like segment of the otic crest migrates from a specific neuromere into the grooved interface between the fifth and sixth somitomeres, delimiting the rostral border of the otic placode in the ectoderm above. By the end of stage 9, crest cells delimiting the caudal border of the placode have migrated along the interface of the seventh and eighth somitomeres. The crest cells adjacent to the sixth and seventh somitomeres, between the rostral and caudal otic populations, appear but do not migrate, remaining condensed along the midline. Thus, otic crest cells form a ring which circumscribes the invaginating otic placode. This study suggests that the precise distribution of cranial neural crest cells may result from their introduction at specific times, as specific populations from specific brain regions (neuromeres), onto a patterned mesodermal layer.     

Migration Behavior of Granule Cell Neurons in Cerebellar Cultures I. A PKH26 Labeling Study in Microexplant and Organotypic Cultures

Granule cells were dissociated from early postnatal mouse cerebella and labeled with a fluorescent dye probe PKH26. Small number of the labeled cells were mixed with cerebellar cortical microexplant cultures or transplanted into cerebellar cortical organotypic explants, and their time-dependent morphological changes during cultures were examined with fluorescence microscopy. Granule cell neurons first extended asymmetrical short bipolar processes in both cultures, and migrated actively in microexplant cultures. After elongation of symmetrically bipolar long and thin neurites, they sprouted short thick processes from cell bodies and migrated perpendicular to neurite bundles that were devoid of glia in microexplant cultures, or migrated vertically inward into the internal granular layer in the organotypic explant. During such migrations, they extended short thick processes in front and thin processes behind the cell body. The latter processes were connected to thin long neurites with T- or Y-shaped junctions in both cultures. Finally, they extended many short thick processes from cell bodies in both cultures. Such behaviors of granule cell neurons in microexplant cultures were, thus, similar to those in organotypic explant cultures despite of the absence of Bergmann glial cells. These migration patterns may be closely related to migration of granule cells in histogenesis of the cerebellar cortex.     

Development, Histochemistry and Ultrastructure of Gum-resin Ducts in Commiphora mukul Engl.

Gum-resin ducts are present in the primary and secondary phloemof Commiphora mukul Engl. The important gum-resin, known commerciallyas ‘guggul’, is secreted and collected in ductswhich develop schizogenously. The duct initials have dense cytoplasm,large nuclei, increased cytoplasmic RNA and proteins. The lumenof newly-formed ducts widens accompanied by anticlinal divisionsand subsequent tangential elongation of epithelial cells. Histochemicaltests reveal that the epithelial cells have apparently largeamounts of proteins, cytoplasmic RNA, and DNA in the nucleus.Lipid globules are also present in these cells. Epithelial cellwalls in contact with the duct are thin and of a loose fibrillarmesh. Microtubules, randomly oriented in the epithelial cellsare always parallel and adjacent to the wall. The cytoplasmis rich in ribosomes, endoplasmic reticulum, mitochondria, plastidsand vacuoles containing osmiophilic substances. At the peripheralregion of the duct, electron-transparent bodies containing densely-stainedmaterial are present close to the tangential wall.     

Mechanical aspects of the lungs as cancer cell-killing organs during hematogenous metastasis

A substantial proportion of many different types of circulating cancer cells appear to be killed during their interactions with the pulmonary microcirculation. Different tensions exist during respiration within alveolar units, and hence the pulmonary capillaries. We have calculated the effects of these tensions on the entry and subsequent fate of circulating cancer cells. Our calculations indicate that during expiration, when tension in the capillary walls is low, cancer cells can enter and travel along the capillaries without damage, because the vessels are deformed by the cells and the hydrodynamic field surrounding them. During normal inspiration when the alveoli are stretched, the increased tension within the capillary walls serves to compress the contained cancer cells. This compression, together with previously calculated blood pressure differentials between the ends of the cells, is thought in some cases, to increase their membrane tensions above the critical level for rupture, resulting in cytolysis, in accord with experimental observations. In deep inspiration, when a very substantial increase in capillary wall tension occurs, cancer cells already within the capillaries, entering them and in transit along them are expected to develop membrane tensions greatly exceeding the critical values for rupture. It is suggested that these respiration-induced effects may act as an important rate-regulating step in the metastatic process, where the development of pulmonary metastases plays a central role. Furthermore, induced deep inspiration may conceivably be utilized in the inhibition of pulmonary metastasis.     

Immunohistochemical localization of the calcium/calmodulin-dependent protein phosphatase,calcineurin, in the mouse testis: its unique accumulation in spermatid nuclei

Immunohistochemical localization of a calmodulin-dependent protein phosphatase, calcineurin, was studied in the mouse testis in relation to previous observations showing that calmodulin is unusually rich in spermatogenic stages from mid-pachytene spermatocytes to elongating spermatids. The antibodies raised against calcineurin from scallop testis reacted with subunit B, but not subunit A, of calcineurin isoforms from mouse brain and testis. Indirect immunofluorescence using these antibodies on the mouse testis revealed positive reactions only in the nuclei of round or elongating spermatids: calcineurin started to accumulate in nuclei from the acrosomal cap phase, peaked at the initial stage of nuclear elongation, and decreased thereafter. There was almost no signal in the cytoplasm; spermatogenic cells at other stages, including spermatogonia, spermatocytes, mature sperm, and other somatic cells in the seminiferous tubules were totally negative. Immuno-electron microscopy gave the same result, on the basis of measuring the density of immunogold particles. These results suggest a role for calcineurin in remodeling of the nuclear chromatin in metamorphosing spermatids.