Regeneration of the active zone at the frog neuromuscular junction

The active zone is a unique specialization of the presynaptic membrane and is believed to be the site of transmitter release. The formation of the active zone and the relationship of this process to transmitter release were studied at reinnervated neuromuscular junctions in the frog. At different times after a nerve crush, the cutaneous pectoris muscles were examined with intracellular recording recording and freeze-fracture electron microscopy. The P face of a normal active zone typically consists of two double rows of particles lined up in a continuous segment located opposite a junctional fold. In the initial stage of reinnervation, clusters of large intramembrane particles surrounding membrane elevations appeared on the P face of nerve terminals. Like normal active zones, these clusters were aligned with junctional folds. Vesicle openings, which indicate transmitter release, were seen at these primitive active zones, even though intramembrane particles were not yet organized into the normal pattern of two double rows. The length of active zones at this stage was only approximately 15% of normal. During the secondary stage, every junction was reinnervated and most active zones had begun to organize into the normal pattern with normal orientation. Unlike normal, there were often two or more discontinuous short segments of active zone aligned with the same junctional fold. The total length of active zone per junctional fold increased to one-third of normal, mainly because of the greater number of segments. In the third stage, the number of active zone segments per junctional fold showed almost no change when compared with the secondary stage. However, individual segments elongated and increased the total length of all active zone segments per junctional fold to about two-thirds of the normal length. The dynamic process culminated in the final stage, during which elongating active zones appeared to join together and the number of active zone segments per junctional fold decreased to normal. Thus, in most regions, regeneration of the active zones was complete. These results suggest that the normal organization of two double rows is not necessary for the active zone to be functional. Furthermore, localization of regenerating active zones is related to junctional folds and/or their associated structures.     

Development of rat soleus endplate membrane following denervation at birth

Rat soleus endplates develop some of their characteristic features before birth and others after birth. Specializations appearing before birth include a localized cluster of acetylcholine receptors (AChRs), an accumulation of acetylcholinesterase (AChE) in the synaptic basal lamina, and a cluster of nuclei near the endplate membrane. In contrast, postsynaptic membrane folds are elaborated during the first three weeks after birth. We denervated soleus muscles on postnatal day 1, before folds had appeared, and followed the subsequent development of endplate regions with light and electron microscopy. We found that the denervated endplates initiated fold formation on schedule and maintained their accumulations of AChRs, AChE, and endplate nuclei. However, the endplates stopped fold formation prematurely and eventually lost their rudimentary folds. At about the same time, the junctional AChR clusters were joined by ectopic patches of AChRs. The former endplate regions also became unusually elongated, possibly as a consequence of the lack of membrane folds. Apparently, endplate membranes have only a limited capacity for further development in the absence of both the nerve and muscle activity.     

Cephalic neurulation and optic vesicle formation in the early mouse embryo.

The overall pattern of cephalic neurulation and the concomitant early development of the optic vesicles in mouse embryos were examined by scanning electron microscopy. Paraffin-sectioned specimens were also examined. The overall pattern of closure of the cephalic neural folds accords well with earlier observations of this process. The earliest indication of optic placode formation was seen in histological sections of embryos at the 4-somite stage, while optic pit formation was first observed at the 5- to 6-somite stage. The upper halves of the optic vesicles were formed in 10- to 15-somite embryos by the fusion of the neural folds at the junction between the mesencephalon and prosencephalon, while closure of the lower halves was associated with the closure of the rostral neuropore, and was usually completed by about the 20-somite stage. By the 25- to 30-somite stage, a rapid increase in the volume of the forebrain was observed, so that the optic vesicles were displaced laterally. An overall increase in the volume of the optic vesicles and decrease in the diameter of the optic stalks were also observed at this time. This account of cephalic neurulation and optic organogenesis provides useful baseline data relevant to the study of the normal early development of the mouse. A comparison is made between similar events in the rat, the hamster, and the human embryo.     

Functional morphology of the mantle of Nautilus pompilius (Mollusca, Cephalopoda)

This study presents histological and cytological findings on the structural differentiation of the mantle of Nautilus pompilius in order to characterize the cells that are responsible for shell formation. The lateral and front mantle edges split distally into three folds: an outer, middle, and inner fold. Within the upper part of the mantle the mantle edge is divided into two folds only; the inner fold disappears where the hood is attached to the mantle. At the base of the outer fold of the lateral and front mantle edge an endo-epithelial gland, the mantle edge gland, is localized. The gland cells are distinguished by a distinct rough endoplasmic reticulum and by numerous secretory vesicles. Furthermore, they show a strong accumulation of calcium compounds, indicating that the formation of the shell takes place in this region of the mantle. Numerous synaptic contacts between the gland cells and the axons of the nerve fibers reveal that the secretion in the area of the mantle edge gland is under nervous control. The whole mantle tissue is covered with a columnar epithelium having a microvillar border. The analyses of the outer epithelium show ultrastructural characteristics of a transport active epithelium, indicating that this region of the mantle is involved in the sclerotization of the shell. Ultrastructural findings concerning the epithelium between the outer and middle fold suggest that the periostracum is formed in this area of the mantle, as it is in other conchiferan molluscs.     

Neural fold formation at newly created boundaries between neural plate and epidermis in the axolotl

According to a recent model, the cortical tractor model, neural fold and neural crest formation occurs at the boundary between neural plate and epidermis because random cell movements become organized at this site. If this is correct, then a fold should form at any boundary between epidermis and neural plate. To test that proposition, we created new boundaries in axolotl embryos by juxtaposing pieces of neural plate and epidermis that would not normally participate in fold formation. These boundaries were examined superficially and histologically for the presence of folds, permitting the following observations. Folds form at each newly created boundary, and as many folds form as there are boundaries. When two folds meet they fuse into a hollow "tube" of neural tissue covered by epidermis. Sections reveal that these ectopic folds and "tubes" are morphologically similar to their natural counterparts. Transplanting neural plate into epidermis produces nodules of neural tissue with central lumens and peripheral nerve fibers, and transplanting epidermis into neural plate causes the neural tube and the dorsal fin to bifurcate in the region of the graft. Tissue transplanted homotypically as a control integrates into the host tissue without forming folds. When tissue from a pigmented embryo is transplanted into an albino host, the presence of pigment allows the donor cells to be distinguished from those of the host. Mesenchymal cells and melanocytes originating from neural plate transplants indicate that neural crest cells form at these new boundaries. Thus, any boundary between neural plate and epidermis denotes the site of a neural fold, and the behavior of cells at this boundary appears to help fold the epithelium. Since folds can form in ectopic locations on an embryo, local interactions rather than classical neural induction appear to be responsible for the formation of neural folds and neural crest.     

Localization of the membrane-anchored MMP-regulator RECK at the neuromuscular junctions

Nerve apposition on nicotinic acetylcholine receptor clusters and invagination of the post-synaptic membrane (i.e. secondary fold formation) occur by embryonic day 18.5 at the neuromuscular junctions (NMJs) in mouse skeletal muscles. Finding the molecules expressed at the NMJ at this stage of development may help elucidating how the strong linkage between a nerve terminal and a muscle fiber is established. Immunohistochemical analyses indicated that the membrane-anchored matrix metalloproteinase regulator RECK was enriched at the NMJ in adult skeletal muscles. Confocal and electron microscopy revealed the localization of RECK immunoreactivity in secondary folds and subsynaptic intracellular compartments in muscles. Time course studies indicated that RECK immunoreactivity becomes associated with the NMJ in the diaphragm at around embryonic day 18.5 and thereafter. These findings, together with known properties of RECK, support the hypothesis that RECK participates in NMJ formation and/or maintenance, possibly by protecting extracellular components, such as synaptic basal laminae, from proteolytic degradation.     

Pattern of Pads and Folds in the Foot of European Oscines (Aves, Passeriformes)

A comparative study of pads and folds in the foot is made on 56 passerine species, classified in 18 families or subfamilies of the suborder Oscines. A basic pattern of thirteen pads is recognized: twelve in the digits, each related to one phalanx; the thirteenth in the central part of the foot, ventral to the trochleas of tarsometatarsus. Certain pads in the anterior digits are divided in species with long and narrow pads. The number of folds varies, even in the same species, but a basic pattern is recognized. There is one fold at each joint. Except for the fold at the distal joint in the four digits, these folds are comparable with pads in certain non-Passerifor-mes. The folds at the proximal phalanx of the third and the fourth digit are interpreted as reduced pads. Some folds are separated parts of phalanx pads. – Most passerine birds have this basic pattern of pads and folds, clearly adapted to a life on branches or on twigs. Certain species, exemplified by Alauda arvensis, Plectrophenax nicalis, Certhia familiaris , and Regulus regulus , have different morphology of pads and folds, depending on a reduced number of papillae, and being adaptations to life on the ground, on tree trunks, or on very thin twigs. Relatively few papillae occur in certain species that winter in temperate or cold climates. This means a reduced area of contact with the substrate and is probably important in heat regulation by reducing the conductive heat flow through the papillae to the substrate.–The pads and folds have a restricted value for the classification on family or subfamily level.     

Development of the external genitalia in rat fetuses

Development of the external genitalia in rat fetuses was studied with special reference to the formation of the labia pudenda and the determination of the stage at which the sex difference could be recognized from changes in the external structures. The urogenital fold located on either side of the external structures. The urogenital fold located on either side of the urogenital groove gradually enlarges and begins to enclose the genital tubercle with its counter fold on day 20 of gestation. Thus, the urogenital folds, which are known to become the labia minora and the prepuce of clitoris in the human, are differentiated only into the prepuce of clitoris in the rat. The genital swellings situated caudally to the urogenital folds are not well developed and come to be inconspicuously flat in situ at the end of gestation. However, the labia majora are formed by the time of puberty when the vagina opens. Therefore, it seems that the genital swellings contribute to the formation of the labia majora after birth. Sex difference in development of the external genitalia is recognized on day 17 of gestation; a small oval urogenital orifice is larger in male than in female and the genital swellings are better developed in male than in female.     

A model of growth restraints to explain the development and evolution of tooth shapes in mammals

The problem investigated here is control of the development of tooth shape. Cells at the growing soft tissue interface between the ectoderm and mesoderm in a tooth anlage are observed to buckle and fold into a template for the shape of the tooth crown. The final shape is created by enamel secreted onto the folds. The pattern in which the folds develop is generally explained as a response to the pattern in which genes are locally expressed at the interface. This congruence leaves the problem of control unanswered because it does not explain how either pattern is controlled. Obviously, cells are subject to Newton's laws of motion so that mechanical forces and constraints must ultimately cause the movements of cells during tooth morphogenesis. A computer model is used to test the hypothesis that directional resistances to growth of the epithelial part of the interface could account for the shape into which the interface folds. The model starts with a single epithelial cell whose growth is constrained by 4 constant directional resistances (anterior, posterior, medial and lateral). The constraints force the growing epithelium to buckle and fold. By entering into the model different values for these constraints the modeled epithelium is induced to buckle and fold into the different shapes associated with the evolution of a human upper molar from that of a reptilian ancestor. The patterns and sizes of cusps and the sequences in which they develop are all correctly reproduced. The model predicts the changes in the 4 directional constraints necessary to develop and evolve from one tooth shape into another. I conclude more generally expressed genes that control directional resistances to growth, not locally expressed genes, may provide the information for the shape into which a tooth develops.     

Plasma membrane folds on the mast cell surface and their relationship to secretory activity

Changes in the surface morphology of secreting mast cells have been followed by scanning electron microscopy. Mast cells isolated from the rat peritoneal cavity have folds of plasma membrane that form snake-like ridges on their surfaces. Fold length varies considerably from cell to cell, whereas fold width and depth appear to remain relatively constant. To assess the possible relationship between secretory activity and surface folding, a seimquantitative method was used for measuring fold length in control and secreting populations. A positive correlation is found between secretion of histamine and the extent of membrane folds on the mast cell surface. The source of the membrane required for fold formation is probably secretory granule membrane incorporated into the plasma membranene as a result of exocytosis. Furthermore, a distinct cell type devoid of surface folds, designated as a raspberry-type cell, is found to occur as an integral part of a normal population of mast cells. This cell type is resistant to stimulation by polymyxin.     

Study of development of ciliary folds and Zinn's zonules in Rana temporaria L. by means of scanning electron microscopy]

The development of ciliary folds and zonul of Zinn has been studied in the eyes of the common frog Rana temporaria L. by means of scanning electron microscopy. The development of ciliary folds begins at the stage 45 by the flexure of the external layer in the ciliary zone. At the stage 46 this process involves the internal layer and the folds become two-layered. The zonules of Zinn form before the folds of internal layer of the ciliary epithelium begin to form as separate bundles of fibers. At the stage 45 they are already distinct. Later the ciliary filaments fold in 2 felt-like layers -- zonula which pass from the equatorial lens zone and attach near orbiculum ciliaris. In the place of attachment the margin of zonul repeats the relief of folds, thus attaching to their whole surface, and individual filaments go farther, to orbiculum ciliaris. All these processes take place in they eye prior to the beginning of metamorphosis.     

OBSERVATIONS ON THE STRUCTURE OF RHODOSPIRILLUM MOLISCHIANUM

The lamellae of the bacterium Rhodospirillum molischianum originate as extensions of the cytoplasmic membrane into the cytoplasm of the cell. Initially, these extensions are narrow folds and occur independently of one another. The first lamellae to appear average about 80 A in width, representing one side of the infolded cytoplasmic membrane, or 160 A when the two sides of the fold are closely appressed. The 160-A lamellae increase in number and may associate to form larger lamellae, which represent varying degrees of association between adjacent folds. Later, the space within each fold increases; the two appressed regions of the cytoplasmic membrane in each fold separate to form distinct invaginations, and the lamellae observed at this stage are formed by an association of the sides of adjacent invaginations.     

Embryonic development of the jumping bristletail Pedetonutus unimaculatus Machida,with special reference to embryonic membranes (Hexapoda: Microcoryphia,Machilidae)

In the machilid Pedetonutus unimaculatus, a germ disc is formed by the aggregation and proliferation of cells within a broadly defined embryonic area. Cells adjacent to the embryonic area form the serosal fold that grows beneath the embryo. Then the embryonic margin is extended to form a cell layer or amnion that lies between the embryo and serosal fold. Thus, an amnioserosal fold is formed by the addition of the amnion to the serosal fold. Serosal cells cover the entire surface of the egg and begin to secrete a serosal cuticle. Soon the amnioserosal fold is withdrawn, and the embryo is exposed to the egg surface. The spreading amnion replaces the serosal cells that finally degenerate through the formation of a secondary dorsal organ. In the areas of amnion anterior and lateral to the embryo, yolk folds form and encompass the embryo. The amnion is a provisional dorsal closure and never participates in the formation of the definitive one. The amnioserosal fold of the Microcoryphia appears to have the functional role of secreting a serosal cuticle beneath the embryo. This fold of the Microcoryphia may be regarded as an ancestral form of the amnioserosal folds of the Thysanura-Pterygota. the yolk folds may appear to be passive transformation of the yolk mass linked to positioning of the growing embryo within the egg. There is no evidence that the yolk folds and the cavity appearing between them in the Microcoryphia are homologous to the amnioserosal fold and amniotic cavity in the Thysanura-Pterygota. The yolk folds appear to be one of the embryological autapomorphies in the Microcoryphia. © 1994 Wiley-Liss, Inc.     

Pathogenesis of nitrofen-induced congenital diaphragmatic hernia in fetal rats

Allan, Douglas W., and John J. Greer. Pathogenesis ofnitrofen-induced congenital diaphragmatic hernia in fetal rats. J. Appl. Physiol. 83(2): 338-347, 1997.Congenital diaphragmatic hernia (CDH) is a developmental anomalycharacterized by the malformation of the diaphragm and impaired lungdevelopment. In the present study, we tested several hypothesesregarding the pathogenesis of CDH, including those suggesting that theprimary defect is due to abnormal 1)lung development, 2) phrenic nerveformation, 3) developmentalprocesses underlying diaphragmatic myotube formation, 4) pleuroperitoneal canal closure,or 5) formation of the primordial diaphragm within the pleuroperitoneal fold. The2,4-dichloro-phenyl-p-nitrophenyl ether (nitrofen)-induced CDH rat model was used for thisstudy. The following parameters were compared between normal andherniated fetal rats at various stages of development:1) weight, protein, and DNA contentof lungs; 2) phrenic nerve diameter,axonal number, and motoneuron distribution;3) formation of the phrenic nerve intramuscular branching pattern and diaphragmatic myotube formation; and 4) formation of the precursor ofthe diaphragmatic musculature, the pleuroperitoneal fold. Wedemonstrated that previously proposed theories regarding the primaryrole of the lung, phrenic nerve, myotube formation, and the closure ofpleuroperitoneal canal in the pathogenesis of CDH are incorrect.Rather, the primary defect associated with CDH, at least in thenitrofen rat model, occurs at the earliest stage of diaphragmdevelopment, the formation of the pleuroperitoneal fold.

     

The early development of retinal ganglion cells with uncrossed axons in the mouse: retinal position and axonal course

The carbocyanine dye, DiI, has been used to study the retinal origin of the uncrossed retinofugal component of the mouse and to show the course taken by these fibres through the optic nerve and chiasm during development. Optic axons first arrive at the chiasm at embryonic day 13 (E13) but do not cross the midline until E14. After this stage, fibres taking an uncrossed course can be selectively labelled by unilateral tract implants of DiI. The earliest ipsilaterally projecting ganglion cells are located in the dorsal central retina. The first sign of the adult pattern of distribution of ganglion cells with uncrossed axons located mainly in the ventrotemporal retina is seen on embryonic day 16.5, thus showing that the adult line of decussation forms early in development. A small number of labelled cells continue to be found in nasal and dorsal retina at all later stages. At early stages (E14-15), retrogradely labelled uncrossed fibres are found in virtually all fascicles of the developing nerve, intermingling with crossed axons throughout the length of the nerve. At later stages of development (E16-17), although uncrossed fibres pass predominantly within the temporal part of the stalk, they remain intermingled with crossed axons. A significant number of uncrossed axons also lie within the nasal part of the optic stalk. The position of uncrossed fibres throughout the nerve in the later developmental stages is comparable to that seen in the adult rodent (Baker and Jeffery, 1989). The distribution of uncrossed axons thus indicates that positional cues are not sufficient to account for the choice made by axons when they reach the optic chiasm.     

Proliferation and relocation of developing lobster neuromuscular synapses

The development of multiterminal innervation from a single identifiable excitatory motoneuron to the lobster distal accessory flexor muscle (DAFM) was studied by serial section electron microscopy. The number, size, and location of neuromuscular synapses and presynaptic dense bars within the peripheral branching pattern of the axon was determined in cross sections of the DAFM in 1st (24-hr-old)-, 4th (2-week-old)-, and 12th (1-year-old)-stage lobsters. The mean size of synapses remains fairly constant in these three stages but synaptic density, i.e., the number of synapses per unit length of fiber, increased more than 20-fold between the 1st and 4th stages and more than 5-fold between the 4th and 12th stages. Synaptic surface area per fiber length showed a parallel increase. Consequently there is a proliferation of synapses along the length of individual muscle fibers during primary development. Furthermore from the 1st stage where only a few fibers are innervated, synapses proliferate to many more fibers in the 4th and to all fibers in the 12th stage. The neuromuscular synapses are distributed in different proportions within the axonal branching pattern in the three stages. Based on the number and size of synapses and presynaptic dense bars, the main axon and primary branches provide almost equal amounts of innervation in the 1st stage. With further branching in the 4th stage, the main axon accounts for only 20–25% of the innervation; the primary branches for 45% and other finer branches the remainder. By the 12th-stage synapses are found only on branches other than the main axon and its primary offshoots. There is therefore a shift in innervation from the main axon to the primary branches and then to the finer branches during primary development. This shift in innervation involves the formation of new synaptic terminals and the restructuring of existing ones into axonal areas. In this way the multiterminal innervation arising from an identifiable motoneuron is remodeled.     

Dynamic topology of the cephalochordate to amniote morphological transition: a self-organized system of Russian dolls

This note presents a mechanistic explanation of the transition between the morphology of cephalochordates to that of amniotes. By a careful study of the morphogenetic movements which occur during the early stages of development of a typical amniote (a chicken embryo), we are able to show that the formation of a vertebrate body follows a sequence: first, formation of dorsal folds, then head and heart as dorsal and ventral folds, and finally another dorsal fold, which eventually builds up the chorion. This order has a physical origin linked to the velocity field of the tissue flow. These folds form at right angles to the flow direction, and the topology of the chordates flow is hyperbolic. This mechanism explains the differences between the successive bauplans, by the cumulate forward and backward movement of the flow. Eventually, the entire phenomenon can be described as a self-organized system of Russian dolls, by which the heart finds itself inside the embryo, and the embryo itself inside the chorion. In addition, the phenomenon has a mirror symmetry in the anterior and in the posterior part, thereby explaining naturally the existence of animals having a caudal heart.     

Post embryonic development of the central nervous system of the spider Argiope aurantia (Lucas)

Volumetric and histological changes of the central nervous system were studied during post embryonic development of a spider, Argiope aurantia. The neural mass of Argiope grows allometrically with respect to volume of the cephalothorax and body weight. In the first instar 46% of the cephalothoracic volume constitutes the neural mass and this is reduced to 4% in the female (9th stage) and 12% in the male (7th stage) spider. Growth curves for the cephalic ganglion, measured at all stages, represent a straight line. The neural mass of females is two and a half times larger than that of the males. The ganglion increased 24 fold in female and 10 fold in male spiders. Addition of neural mass occurs in all stages. The brain volume is greater than that of the subesophageal ganglion in the first two instars. In subsequent stadia, the subesophageal ganglion grows faster, and in females it is finally three times and in males two times larger than the brain. Growth of cortex and neuropile depict exponential curves. Comparison of growth patterns of these shows an inverse relationship during development. While the volume of the cortex is higher in the first two or three stages, the volume of the neuropile is higher in the remaining stadia. The causes for this growth pattern are discussed. Counts of cell numbers show that there is a constant population of neurons throughout the post-embryonic development. The number of nerve cells in females is higher than in males, 11% in the subesophageal ganglion and 58% in the brain. The growth of the cortex is partly accomplished by an increase in cell volume. In male and female spiders the increase in Type-B cells is 20 and 50 fold, while that of large motor neurons is 200 and 600 fold respectively. The motor neurons of 20 μ and above number 63 in male and 916 in female adult spiders. The growth of neuropile occurs through an increase of dendritic arborization and axonal branching. The largest axons measure 1 μ in the first and 16 μ in adult stages. An increase of incoming sensory fibers is also noticed during development. Invasion of neural lamella into cortex and neuropile increases during development. Neural lamella which are 1-2 μ in the first stage grow to 40–100 μ thickness in adult female spiders, near the origin of the main nerves. One type of astral cells, counted in neuropile, increases 10 fold. The appearance of a central body and the beginning of web construction coincide during the second instar. The relationship between these two is discussed.     

Non-invasive in vivo measurement of the shear modulus of human vocal fold tissue

Voice is the essential part of singing and speech communication. Voice disorders significantly affect the quality of life. The viscoelastic mechanical properties of the vocal fold mucosa determine the characteristics of the vocal folds oscillations, and thereby voice quality. In the present study, a non-invasive method was developed to determine the shear modulus of human vocal fold tissue in vivo via measurements of the mucosal wave propagation speed during phonation. Images of four human subjects' vocal folds were captured using high speed digital imaging (HSDI) and magnetic resonance imaging (MRI) for different phonation pitches, specifically fundamental frequencies between 110 and 440 Hz. The MRI images were used to obtain the morphometric dimensions of each subject's vocal folds in order to determine the pixel size in the high-speed images. The mucosal wave propagation speed was determined for each subject and at each pitch value using an automated image processing algorithm. The transverse shear modulus of the vocal fold mucosa was then calculated from a surface (Rayleigh) wave propagation dispersion equation using the measured wave speeds. It was found that the mucosal wave propagation speed and therefore the shear modulus of the vocal fold tissue were generally greater at higher pitches. The results were in good agreement with those from other studies obtained via in vitro measurements, thereby supporting the validity of the proposed measurement method. This method offers the potential for in vivo clinical assessments of vocal folds viscoelasticity from HSDI.     

Correlative ontogenetic development of catecholamine- and LHRH-containing nerve endings in the median eminence of the rat

Summary The ontogenetic development of catecholamine (CA)-and LHRH-containing nerve endings in the median eminence of the rat was investigated by combining fluorescence histochemistry and immunohistochemistry in the same tissue section. LHRH-terminals appeared earlier than CA-terminals and were already detectable in the lateral part of the external layer of the central ME on the first day after birth. CA-nerve endings were first seen in a corresponding region of the ME on the seventh postnatal day. At this stage both types of terminals showed the earliest manifestation of a correlative pattern of their distribution. Subsequently the development of both types of nerve endings proceeded rapidly, and at 14 days their distribution pattern corresponded to that in adult animals. The authors conclude that at this stage the CA-neurons play a constant and significant role in the release of LHRH into the portal capillaries. The correlation between both types of nerve endings and the ontogenetic development of the capillary plexuses of the hypophysial portal system is discussed.This work was supported in part by a grant (No. 248093, 321426) from the Ministry of Education, Science and Culture, Japan