Neurulation in the pig embryo.

Neurulation is based on a multitude of factors and processes generated both inside and outside the neural plate. Although there are models for a general neurulation mechanism, specific sets of factors and processes have been shown to be involved in neurulation depending on developmental time and rostro-caudal location at which neurulation occurred in the species under investigation. To find a common thread amongst these apparently divergent modes of neurulation another representative mammalian species, the pig, was studied here by scanning electron microscopy. The data are compared to a series of descriptions in other species. Furthermore, the relation of axial curvature and neural tube closure rate is investigated. In the pig embryo of 7 somites, the first apposition of the neural folds occurs at somite levels 5-7. This corresponds to closure site I in the mouse embryo. At the next stage the rostral and caudal parts of the rhombencephalic folds appose, leaving an opening in between. Therefore, at this stage four neuropores can be distinguished, of which the anterior and posterior ones will remain open longest. The two rhombencephalic closure sites have no counterpart in the mouse, but do have some resemblance to those of the rabbit. The anterior neuropore closes in three phases: (1) the dorsal folds slowly align and then close instantaneously, the slow progression being likely due to a counteracting effect of the mesencephalic flexure; (2) the dorso-lateral folds close in a zipper-like fashion in caudo-rostral direction; (3) the final round aperture is likely to close by circumferential growth. At the stage of 22 somites the anterior neuropore is completely closed. In contrast to the two de novo closure sites for the anterior neuropore in the mouse embryo, none of these were detected in the pig embryo. The posterior neuropore closes initially very fast in the somitic region, but this process almost stops thereafter. We suggest that the somites force the neural folds to elevate precociously. Between the stages of 8-20 somites the width of the posterior neuropore does not change, while the rate of closure gradually increases; this increase may be due to a catch-up of intrinsic neurulation processes and to the reduction of axial curvature. At the stage of 20-22 somites the posterior neuropore suddenly reduces in size but thereafter a small neuropore remains for 5 somite stages. The closure of the posterior neuropore is completed at the stage of 28 somites.

Reduced glucose consumption in the curly tail mouse does not initiate the pathogenesis leading to spinal neural tube defects.

At embryonic stages of neural tube closure, the mouse embryo exhibits a high rate of glycolysis with glucose as the main energy source. In the curly tail mouse, often used as model system for study of human neural tube defects, a delay in closure of the posterior neuropore (PNP) is proposed to be indirectly caused by a proliferation defect in the caudal region. Because glucose is important for proliferation, we tested glucose uptake in curly tail and control embryos, and in a BALB/c-curly tail recombinant strain. The structure and expression of Glut-1, a glucose transporter molecule that is abundantly present during those embryonic stages and that has been mapped in the region of the major curly tail gene, were also studied; however, no strain differences could be demonstrated. Glucose uptake was determined by measuring glucose depletion from the medium in long-term embryo cultures that encompassed the stages of PNP closure and by measuring accumulation of 3H-deoxyglucose in short-term cultures at the stages of early and final PNP closure. Both approaches indicated a reduced glucose uptake by curly tail and recombinant embryos. Surprisingly, the uptake per cell appeared normal, accompanied by a significantly lower DNA content of the mutant embryos. Therefore, it is unlikely that reduced cell proliferation is caused by a reduction in glucose supply during the pathogenesis of the defects in curly tail embryos. The reduced DNA content as well as the reduced glucose uptake per embryo are likely downstream effects of the aberrant proliferation pattern.

Differences in axial curvature correlate with species-specific rate of neural tube closure in embryos of chick, rabbit, mouse, rat and human.

Studies on the mouse strain curly tail, a mutant for neural tube defects, have indicated that axial curvature is an important factor in neural tube closure. Previously reported results from experimental interventions in both mouse and chick embryos indicated that curvature along the craniocaudal axis and closure of the posterior neuropore (PNP) are inversely related, a correlation that is also proposed for the rabbit embryo. It was hypothesized that this relationship is a sign of a more general mechanism. Therefore, in the present report the number of species in which axial curvature is described along the craniocaudal axis was extended to include the rat and human. Next, the closure rate of the neural tube as well as the curvature of the PNP region was determined morphometrically for embryos of the following species: chick, rabbit, mouse, rat and human. Although the relationship between neural tube closure and axial curvature appeared specific for each species in the comparative analysis, a general association of increased rate of closure with a decreased curvature emerged. It is concluded that axial curvature is an important factor in neurulation.

Role of differential cell proliferation in the tail bud in aberrant mouse neurulation.

In the mouse mutant curly tail, the phenotypes spina bifida and curled tail result from a delay in closure of the posterior neuropore (PNP). At the developmental stage when this delay can first be recognized, the caudal region of the embryo demonstrates a transiently enhanced curvature of the body axis which likely inhibits elevation, convergence, and fusion of the neural folds. The enhanced curvature is thought to be the result of a decreased proliferation in the ventrally located gut endoderm and notochord, together with a normal proliferation of the overlying neuroepithelium of the PNP. However, the proliferation defect and the enhanced curvature were originally demonstrated at the same developmental stage, while it is expected that reduced proliferation should precede enhanced curvature and delayed PNP closure. The caudal region originates from the tail bud and we therefore propose that the enhanced curvature is induced by a disturbed dorso-ventral proliferation pattern in the tail bud. Using flow cytometry, proliferation patterns were determined separately for the dorsal and ventral halves of the tail bud of curly tail and of control embryos as well as of recombinant embryos having the curly tail phenotype with a genetic background which is matched to the BALB/c control strain. In general, it appeared that about half of the cell cycle duration in tail bud cells was occupied by S phase, about 40% by G0/G1 and the rest by G2/M. For the control embryos, no dorso-ventral differences in relative phase duration were demonstrated. However, curly tail and recombinant embryos at the 21-25 somite stage, prior to the onset of enhanced curvature, exhibited ventrally a higher proportion of G0/G1 phase cells than dorsally, and a complementary relationship for S phase cells. We interpret these observations as indicating a prolonged G1 phase at the ventral side of the tail bud, resulting in a prolongation of the cell cycle and thus a decreased proliferation. In 26-30 somite stage embryos, prior to the normalization of curvature in curly tail embryos, the dorso-ventral proliferation balance was re-established. We conclude that a reduced proliferation in the ventral part of the tail bud of the curly tail embryo precedes both the onset of enhanced curvature and the previously observed reduction in proliferation of the hindgut and notochord, and is a likely candidate for an early event in the pathogenetic sequence leading to the curly tail phenotype.

Neurulation in the rabbit embryo.

Among a broad range of factors and mechanisms involved in the complex process of neurulation a relationship between the curvature of the craniocaudal body axis and rate of neural tube closure has been proposed, but more examples and models are needed to further substantiate the existence of this relationship. This is particularly true for mammals, where marked differences in embryonic body curvature between species exist. The rabbit embryo has virtually no curvature during the main phase of neurulation and is therefore a suitable model, but neurulation is hardly documented in this species. In the present study, therefore, neural tube closure in the rabbit embryo is presented in detail by morphological and morphometrical parameters, as well as from scanning electron microscopic investigations. At the stages of 6-8 somites, the flat neural plate transforms into a V-shaped neural groove, beginning at the rhombo-cervical level. Between the stages of 8 and 9 somites, multiple closure sites occur simultaneously at three levels: at the incipient pros-mesencephalic transition, at the incipient mes-rhombencephalic transition, and at the level of the first pairs of somites. This results in four transient neuropores. The anterior and rhombencephalic neuropores close between the stages of 9-11 somites. The mesencephalic neuropore is very briefly present. The posterior neuropore is the largest and remains longest. Its tapered (cranial) portion closes fast within somite stages 9-10. Subsequently its wide (caudal) portion closes up to a narrow slit, but further closure slows down till full closure is achieved at the 22-somite stage. In comparing rabbit neurulation with that of chick and mouse, the sequence of multiple site closure resembles that of the mouse embryo, but other important aspects of neurulation resemble those of the chick embryo. In contrast to mouse and chick, no time lag between closure at the three closure sites in the rabbit was seen.

Initial closure of the mesencephalic neural groove in the chick embryo involves a releasing zipping-up mechanism.

According to a traditional viewpoint, initial closure of the anterior neural groove involves bilateral elevation of the edges of the neural plate, flattening of the midline area, subsequent convergence of the dorsal neural folds, and finally adhesion and fusion of the medial fold edges. In a transverse view, the shape of the neural groove thereby changes from V > U > toppled C > O. This sequence implicates that the neural groove is wide almost from its inception. In the present study, a new mechanism of initial closure is proposed, based on observations in living chick embryos and on light and scanning electron microscopic observations during neurulation in the presumptive mesencephalic region. The medial part of the neural plate invaginates in ventral direction. The walls of the arising neural groove appose, beginning in the depth, and make subsequent contact. During continued invagination the neural walls extend in ventral direction, the apposition/contact zone shifts in dorsal direction up to the neural folds and the neural walls separate ventrally, resulting in the incipient neural tube lumen. The mechanism is best compared with a zipping-up releasing model. In a transverse view, the shape of the neural groove changes from V > Y > I > O. While, according to the traditional view, the neural folds have to converge from a distance in order to contact each other, in the present mechanism the walls and folds are sequentially in contact by the ventro-dorsal zipping-up mechanism, thereby avoiding the possibility of mismatch of the neural folds. The above process is initiated over a considerable longitudinal distance along the neural plate, but only at the mesencephalic level does the dorsal shift of the contact zone become complete. At other levels of the neuraxis, the contact zone releases prematurely and the neural walls become widely separated well before their dorsal neural folds are in contact. These folds have to converge, therefore, in order to close, but their matching is facilitated by the alignment of the previously contacted neural folds at the mesencephalic level as well as by guidance underneath the vitelline membrane.

Neural tube closure in the chick embryo is multiphasic.

Progression of neurulation in the chick embryo has not been well documented. To provide a detailed description, chick embryos were stained in ovo after the least manipulation possible to avoid distortion of the neural plate and folds. This allowed a morphological and morphometric description of the process of neurulation in relatively undisturbed chick embryos. Neurulation comprises several specific phases with distinct closure patterns and closure rates. The first closure event occurs, de novo, in the future mesencephalon at the 4-6 somite stage (sst 4-6). Soon afterwards, at sst 6-7, de novo closure is seen at the rhombocervical level in the form of multisite contacts of the neural folds. These contacts occur in register with the somites, suggesting that the somites may play a role in forcing elevation and apposition of the neural folds. The mesencephalic] and rhombocervical closure events define an intervening rhombencephalic neuropore, which is present for a brief period before it closes. The remaining pear-shaped posterior neuropore (PNP) narrows and displaces caudally, but its length remains constant in embryos with seven to ten somites, indicating that the caudal extension of the rhombocervical closure point and elongation of the caudal neural plate are keeping pace with each other. From sst 10 onward, the tapered cranial portion of the PNP closes fast in a zipper-like manner, and, subsequently, the wide caudal portion of the PNP closes rapidly as a result of the parallel alignment of its folds, with numerous button-like temporary contact points. A role for convergent extension in this closure event is suggested. The final remnant of the PNP closes at sst 18. Thus, as in mammals, chick neurulation involves multisite closure and probably results form several different development mechanisms at varying levels of the body axis.

Relationship between altered axial curvature and neural tube closure in normal and mutant (curly tail) mouse embryos.

Neural tube defects, including spina bifida, develop in the curly tail mutant mouse as a result of delayed closure of the posterior neuropore at 10.5 days of gestation. Affected embryos are characterized by increased ventral curvature of the caudal region. To determine whether closure of the neuropore could be affected by this angle of curvature, we experimentally enhanced the curvature of non-mutant embryos. The amnion was opened in 9.5 day embryos; after 20 h of culture, a proportion of the embryos exhibited a tightly wrapped amnion with enhanced curvature of the caudal region compared with the control embryos in which the opened amnion remained inflated. Enhanced curvature correlated with a higher frequency of embryos with an open posterior neuropore, irrespective of developmental stage within the range, 27-32 somites. Thus, within this somite range, caudal curvature is a more accurate determinant for normal spinal neurulation than the exact somite stage. Enhanced ventral curvature of the curly tail embryo correlates with an abnormal growth difference between the neuroepithelium and ventral structures (the notochord and hindgut). We experimentally corrected this imbalance by culturing under conditions of mild hyperthermia and subsequently determined whether the angle of curvature would also be corrected. The mean angle of curvature and length of the posterior neuropore were both reduced in embryos cultured at 40.5 degrees C by comparison with control embryos cultured at 38 degrees C. We conclude that the sequence of morphogenetic events leading to spinal neural tube defects in curly tail embryos involves an imbalance of growth rates, which leads to enhanced ventral curvature that, in turn, leads to delayed closure of the posterior neuropore.

Intrinsic and extrinsic factors in the mechanism of neurulation: effect of curvature of the body axis on closure of the posterior neuropore.

Neurulation has been suggested to involve both factors intrinsic and extrinsic to the neuroepithelium. In the curly tail (ct) mutant mouse embryo, final closure of the posterior neuropore is delayed to varying extents resulting in neural tube defects. Evidence was presented recently (Brook et al., 1991 Development 113, 671-678) to suggest that enhanced ventral curvature of the caudal region is responsible for the neurulation defect, which probably originates from an abnormally reduced rate of cell proliferation affecting the hindgut endoderm and notochord, but not the neuroepithelium (Copp et al., 1988, Development 104, 285-295). This axial curvature probably generates a mechanical stress on the posterior neuropore, opposing normal closure. We predicted, therefore, that the ct/ct posterior neuropore should be capable of normal closure if the neuropore should be capable of normal closure if the neuroepithelium is isolated from its adjacent tissues. This prediction was tested by in vitro culture of ct/ct posterior neuropore regions, isolated by a cut caudal to the 5th from last somite. In experimental explants, the neuroepithelium of the posterior neuropore, together with the contiguous portion of the neural tube, were separated mechanically from all adjacent non-neural tissues. The posterior neuropore closed in these explants at a similar rate to isolated posterior neuropore regions of non-mutant embryos. By contrast, control ct/ct explants, in which the caudal region was isolated but the neuroepithelium was left attached to adjacent tissues, showed delayed neurulation. To examine further the idea that axial curvature may be a general mechanism regulating neurulation, we cultured chick embryos on curved substrata in vitro. Slight curvature of the body axis (maximally 1 degree per mm axial length), of either concave or convex nature, resulted in delay of posterior neuropore closure in the chick embryo. Both incidence and extent of closure delay correlated with the degree of curvature that was imposed. We propose that during normal embryogenesis the rate of neurulation is related to the angle of axial curvature, such that experimental alterations in curvature will have differing effects (either enhancement or delay of closure) depending on the angle of curvature at which neurulation normally occurs in a given species, or at a given level of the body axis.

Eicosanoids in breast cancer patients before and after mastectomy.

In 19 patients with a malignant breast tumor, tumor tissue and blood were taken to determine the eicosanoid profile and platelet aggregation. Values were compared with those of patients with benign tumors (n = 4), or undergoing a mammary reduction (n = 7). Postoperatively, blood was taken as well in order to compare pre- and postoperative values. Eicosanoids were measured in peripheral blood monocytes and mammary tissue by means of HPLC; furthermore, TXA2, 6-keto-PGF1 alpha, and PGE2 were determined by RIA. Differences in pre- and postoperative values of cancer patients were seen in plasma RIA values: PGE2 and 6-k-PGF1 alpha were significantly higher preoperatively when compared with postoperatively, however, such differences were seen in the control groups as well. Compared to benign tumor or mammary reduction test material the eicosanoid profile of tissue obtained from malignant mammary tumors showed important differences. Except for PGF2 alpha, HHT and 15-HETE no detectable quantities of eicosanoids were found in the non-tumor material, whereas in the malignant tumor material substantial quantities of a number of eicosanoid metabolites were present. Statistically significant correlations could be established between patient/histopathology data and the results of the platelet aggregation assays, e.g. between menopausal status and ADP aggregation; oestrogen receptor (+/-) and collagen and arachidonic acid aggregation, inflammatory cell infiltration score and arachidonic acid aggregation and fibrosis score and ADP aggregation. The results show that eicosanoid synthesis in material from mammary cancer patients is different from that in benign mammary tissue. The implications, in particular, in relation to future prognosis of the patient, remain obscure.

Deceleration and acceleration in the rate of posterior neuropore closure during neurulation in the curly tail (ct) mouse embryo.

Curly tail (ct) is a mouse mutant producing spinal neural tube defects as a result of delayed closure of the posterior neuropore (PNP). The purpose of the present study was to determine in ct/ct embryos the time of onset of the delay in PNP closure, and the pattern of this closure, as well as to study the possibility that reopening of the neural tube occurs. Normal spinal neurulation was studied in non-mutant Swiss (Sw) embryos. In the latter, the average PNP length diminished steadily between the 7- and 25-somite stages, and then decreased more rapidly, indicating an acceleration of closure rate, until the 30- to 32-somite stage, when all PNPs closed. PNP width decreased steadily between the stages of 7 and 30 somites. In ct/ct embryos the average PNP length showed a slight increase between the stage of 23 to 28 somites, indicating a temporary deceleration of closure rate, and the range of PNP sizes increased markedly. This was followed by a decrease in PNP length until the 37-somite stage, indicating an acceleration of closure rate. From the stage of 32 somites onwards, the proportion of embryos with closed PNPs gradually increased to 90%. The population of ct/ct embryos was subdivided. Embryos with large PNPs showed a marked deceleration of closure rate during a period of 11 somite stages, followed by a brief but very high acceleration of closure rate.(ABSTRACT TRUNCATED AT 250 WORDS)

Angiotensin II stimulates angiogenesis in the chorio-allantoic membrane of the chick embryo.

Angiotensin II was applied daily in doses of 67 or 670 ng to a section of the chick embryo chorio-allantoic membrane from day 7 to day 14 after fertilization of the eggs. During this one-week period, it caused a significant, dose-dependent increase in the vascular density index. The increase obtained with 670 ng daily was comparable to that after daily administration of 1.7 micrograms adenosine, a known stimulator of angiogenesis. The data suggest a possible role for angiotensin II as a mediator of vascular growth.

Development of floor plate, neurons and axonal outgrowth pattern in the early spinal cord of the notochord-deficient chick embryo.

The notochord is probably involved in the development of the neural tube. In this study, a fragment of caudal notochord was extirpated in ovo from chick embryos at 1.5 days of incubation. At 4.5 days a distinct notochord-deficient region at thoracolumbar level was found. Profound effects were seen, especially at the cranial site of this region. Somites were smaller than normal, or even not recognizable, and in some cases the myotomes were fused in the midline. The spinal cord appeared reduced in size and lacked a floor plate. The average amount of spinal cord neurons was 23% of the normal value, the cells being located circularly along the outer margin of the spinal cord, except for the roof plate. Axonal roots left the cord in the ventral midline only. Caudal to this site, neurons or floor plate cells were alternately present in the ventral spinal cord, and axonal roots left bilaterally. In a caudal direction, a normal morphology gradually reappeared. The possibility is discussed that reduction in spinal cord size and amount of neurons is a direct or indirect effect of the absence of the notochord, and that the sclerotome may be involved.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of the notochord on proliferation and differentiation in the neural tube of the chick embryo.

After implantation of a notochord fragment lateral to the neural tube in a 2-day chick embryo, at 4 days the ipsilateral neural tube half was increased in size and axons left the neural tube in a broad dorsoventral area (van Straaten et al. 1985). This enlargement appears to coincide with an increased area of AChE-positive basal plate neuroblasts, as determined with scan-cytophotometry. The effect was ipsilateral and local: clear effects were seen only when the implant was localized less than 80 microns from the neural tube and over 120 microns from the ventral notochord. In order to investigate the expected enhancement of proliferation, the mitotic density and the number of cells at the site of the implant at 3 days was determined and the mitotic index calculated. All three parameters showed an increase. It was concluded that the cell cycle was shorter in the implant area relative to the control area, at least during the third day. At 4 days the number of cells was still increased, predominantly in the basal plate. It appeared that the numerical increase was for the larger part due to neuroblasts. The synergism of two notochords thus resulted in enhancement of proliferation and differentiation in the neural tube. It is suggested that the notochord merely regulates and arranges the surrounding sclerenchymal cells, which are the effective cells in the regulation of neural tube development.

Effect of the notochord on the differentiation of a floor plate area in the neural tube of the chick embryo.

The role of a notochord fragment on the origin of an additional floor plate area in the neural tube is investigated by quantitative morphological methods. In 1.5 to 2 day chick embryos a notochordal fragment was implanted in close apposition to the lateral wall of the neural groove in the region between prospective wing and leg bud. At 4 days, adjacent to the implant a distinct area of the neural wall was present, which resembled the natural floor plate with respect to its thickness, the abluminal location of elongated nuclei and the absence of neuroblasts. The mitotic density of this area was reduced. This "additional floor plate" was distinct when the experiment was performed at 1.5 days but was hardly recognizable when it was carried out at 2 days. From these results it is concluded that a) the notochord induces floor plate like structures and diminishes proliferation, and b) that the period of floor plate induction by the notochord is very restricted.

Differentiation of gut endoderm in dependence of the notochord.

Presumptive intraembryonic endoderm, either isolated or together with adhering mesoderm, from 19-h chick embryos, was grafted to the coelom of 50-h host embryos. The viability of such grafts was low and endodermal differentiation was poor. In a second series the endoderm (with or without adhering mesoderm) was combined with a fragment of notochordal tissue from 48-60-h donor embryos. Then the recovery was much higher, notably after longer periods of in vivo culture. After 10 days of cultivation well-developed entero-endocrine (argyrophilic) cells were found among the regular enterocytes in both series.

The demonstration of acetylcholinesterase in plastic sections. Its application as a marker of early neuronal development.

In this paper a histotechnical procedure with respect to the demonstration of acetylcholinesterase in Technovit 7100 (a recently developed GMA) sections is described. From fixation up to embedding several procedural steps were varied and tested, resulting in a suitable procedure. The embedded tissue or sections can be stored for months at 7 degrees C with only a slight reduction of the enzymic activity. The enzyme also appears relatively temperature resistant and independent of section thickness (2-10 microns). The enzymic activity remains constant during incubation. The technique has been applied to our subject of study in order to qualify and quantify several aspects of the development of neuroblasts.

Induction of an additional floor plate in the neural tube.

The role of the notochord in the morphogenesis of the neural tube was investigated by implanting a notochord fragment laterally to the neural wall of a 1.5 day chick embryo. Embryos were sacrificed at 4 days. In the basal part of the neural tube an additional floor plate was induced in the vicinity of the implant. This floor plate was characterized by a low proliferative activity, a thin wall, spindle-like nuclei crowded peripherally and some neuroblast-like cells. It was either blending with the natural floor plate or separated from it, depending on the exact position of the implant. In the latter case neuroblasts were observed in between both floor plates. The additional floor plate was present only when the implanted notochord was less than 25 micron apart from the neural tube; at larger distance an increase of the ventral horn neuroblast area could be seen. It is concluded that the implanted notochord is able to induce a floor plate at 1.5 days of incubation. The specific influence of the notochord on the morphogenesis of the neural tube, its inductive period as well as the presence of the neuroblast-like cells in the additional floor plate are discussed.

Effect of a notochordal implant on the early morphogenesis of the neural tube and neuroblasts: histometrical and histological results.

The role of the notochord on the early development of ventral horn neuroblasts was investigated in chick embryos by implanting an additional notochord fragment near the right side of the thoracic neural tube. When the implant was located directly lateral to the neural tube, an enlargement of the right half of the neural tube and of the area of neuroblasts occurred, and axons were found to pass through the outer membrane of the neural tube over a broad dorsoventral trajectory. When the notochord was located ventrolaterally a population of neuroblasts including their efferent axons was found at a more dorsal location. It is concluded that a notochordal implant is able to influence the differentiation of neuroblasts.