Inhibition of neural tube closure by ionophore A23187 in chick embryos

Secretory pathway calcium ATPase 1 (SPCA1) controls mouse neural tube closure by regulating cytoskeletal dynamics

Neural tube closure relies on the apical constriction of neuroepithelial cells. Research in frog and fly embryos has found links between the levels of intracellular calcium, actomyosin dynamics and apical constriction. However, genetic evidence for a role of calcium in apical constriction during mammalian neurulation is still lacking. Secretory pathway calcium ATPase (SPCA1) regulates calcium homeostasis by pumping cytosolic calcium into the Golgi apparatus. Loss of function in Spca1 causes cranial exencephaly and spinal cord defects in mice, phenotypes previously ascribed to apoptosis. However, our characterization of a novel allele of Spca1 revealed that neurulation defects in Spca1 mutants are not due to cell death, but rather to a failure of neuroepithelial cells to apically constrict. We show that SPCA1 influences cell contractility by regulating myosin II localization. Furthermore, we found that loss of Spca1 disrupts actin dynamics and the localization of the actin remodeling protein cofilin 1. Taken together, our results provide evidence that SPCA1 promotes neurulation by regulating the cytoskeletal dynamics that promote apical constriction and identify cofilin 1 as a downstream effector of SPCA1 function.

The effects of folic acid in the prevention of neural tube development defects caused by phenytoin in early chick embryos

STUDY DESIGN

The effects of phenytoin and folic acid on the development of neural tube defects in early chick embryos were studies.

OBJECTIVE

To investigate the effects of folic acid in the prevention of neural tube development defects.

SUMMARY OF BACKGROUND DATA

Several studies have shown that phenytoin selectively inhibits neural tube closure. Folic acid supplementation has been reported to decrease the occurrence of neural tube defects.

METHODS

This study shows the effects of folic acid in preventing neural tube development defects caused by phenytoin in chicks based on light microscopy, transmission electron microscopy, and histopathological examination. Forty-five fertile Hubbard Broil eggs, all at Stage 8 (four somite) of development, were divided into three equal groups: Group 1 embryos (n = 15), the control group, were explanted and grown for 18 hours in a nutrient medium (thin albumin). Group 2 embryos (n = 15) were explanted and grown for 18 hours in a nutrient medium containing 500 microg/mL of phenytoin. Group 3 embryos (n = 15) were explanted and grown for 18 hours in a nutrient medium containing 500 microg/mL of phenytoin and 0.4 microg/mL of folic acid.

RESULTS

After the incubation period, 86.6% of the control embryos (Group 1) had intact neural tubes; 80% of Group 2 and 46.6% of Group 3 embryos showed neural tube defects.

CONCLUSIONS

The results of this study suggest that phenytoin causes neural tube defects, whereas folic acid decreases the incidence of neural tube development defects caused by phenytoin in early chick embryos.

Bending of the neural plate during mouse spinal neurulation is independent of actin microfilaments

To examine the role of actin microfilaments in mouse spinal neurulation, we stained cryosections of E8.5-10.5 CBA/Ca embryos with FITC-phalloidin. Microfilaments are present in the apical region of all cells throughout the neuroepithelium, irrespective of whether they are involved in bending of the neural plate. Disruption of the microfilaments with cytochalasin D inhibited closure of the cranial neural folds in cultured embryos, even at the lowest concentrations tested, and prevented the initiation of spinal neurulation (Closure 1) at higher concentrations. In contrast, closure of the posterior neuropore was resistant to cytochalasin D at the highest concentrations tested. Phalloidin staining and transmission electron microscopy confirmed that cytochalasin D is effective in disassembling microfilaments in spinal neuroepithelial cells. We conclude that spinal neural tube closure does not require microfilament function, in contrast to cranial neurulation which is strongly microfilament-dependent. Histological examination of cytochalasin D-treated embryos revealed that bending at hinge points, both in the midline (MHP) and dorsolaterally (DLHPs), continues in the absence of microfilaments, whereas the rigidity of non-bending regions of the neural plate is lost. This suggests that spinal neurulation can continue in the presence of cytochalasin D largely as a result of intrinsic bending of the neural plate at hinge points. Cytochalasin D treatment is a useful tool for revealing the localisation of hinge points in the neural plate. Analysis of treated embryos demonstrates a transition, along the spinal axis, from closure solely involving midline bending, at high levels of the spinal axis, to closure solely involving dorsolateral bending, low in the spinal region. These findings support the idea of mechanistic heterogeneity in mouse neurulation, along the body axis, and demonstrate that contraction of actin microfilaments is not obligatory for epithelial bending during embryonic morphogenesis. Dev Dyn 1999;215:273-283.

Temporal changes in intracellular free calcium levels in the developing neuroepithelium during neurulation in the chick

Intracellular free calcium ion (Ca2+) levels of the developing chick neuroepithelium during neural tube closure (Hamburger and Hamilton stages 3-11 of embryonic development) were determined using the hydrophobic acetoxymethyl ester of the fluorescent dye fura-2 (fura-2/AM). Temporal changes in the free Ca2+ level in neuroepithelial cells are correlated with the degree of folding of the neuroepithelium. The concentration of intracellular Ca2+ in the neuroepithelium reaches its highest level when apposing neural folds are actively making contact.

A morphometric and computer-assisted three-dimensional reconstruction study of neural tube formation in chick embryos

The origin of the driving forces for neural tube formation remains uncertain but is currently thought to involve the participation of microfilament bundles situated in the apical ends of neuroepithelial cells. In the work presented here, we show how morphometric measurements that map local variations in the apical geometry of neuroepithelial cells (especially apical constriction) can provide information on the distribution of motive forces within the neuroepithelium during neural tube formation. When used in combination with computer-assisted, three-dimensional reconstruction, it becomes possible to analyze the morphometric data from a dynamic, three-dimensional perspective. As an example application of this method, we have used morphometry to evaluate the effects of ionomycin on the developing neuroepithelium. Treatment of early (stages 6-8) chick embryos with 5 microM ionomycin was found to cause rapid bending of the neuroepithelium within 1 min of exposure and a dramatic acceleration of the normal sequence of neural tube formation. Electron microscopy and morphometry revealed that this acceleration was coincident with a marked increase in the local degree of apical constriction of neuroepithelial cells, presumably a consequence of enhanced contractile activity of apical microfilament bundles. This work shows that transient elevation of free calcium levels can accelerate the usual sequential phases of NT formation. The rapidity of the response (hours of normal development reduced to minutes), increased prominence of apical microfilament bundles, and the enhanced degree of apical constriction strongly support a direct causal role for apical microfilament bundles and apical constriction of neuroepithelial cells in bending of the neuroepithelium.

Calcium in the developing Ambystoma neural axis shown by 3H and fluorescent chlortetracycline and atomic absorption spectrometry

The calcium ion has been implicated in the mediation of the morphogenetic movements that occur during neural tube formation. The present study identifies high levels of calcium in the neuroepithelium of the neural plate, folds, and tube. These levels are substantially higher than those discerned elsewhere in the embryo. The calcium is localized in morphogenetically active regions by using the antibiotic chlortetracycline (CTC) which chelates calcium and is demonstrated in this investigation by both autoradiography and calcium-linked fluorescence. The specificity of CTC reaction for calcium in the developing neural axis is confirmed by EGTA competition. A comparison of the actual calcium levels in the developing neural axis (dorsal) with equivalently weighted ventral tissues was obtained by atomic absorption spectrometry (AAS). This method provides a total count of the calcium without any loss during tissue processing. For AAS, living tissues were precisely excised and immediately dessicated. Each tissue sample (dry weight 1.5 mg) was then solubilized for analysis. The spectrometric data reveal that the embryonic dorsal aspect forming the neural tube contains 57% more calcium than an equivalent weight of the ventral aspect.

Neural tube formation in the mouse: a morphometric and computerized three-dimensional reconstruction study of the relationship between apical constriction of neuroepithelial cells and the shape of the neuroepithelium

Morphometry and computerized three-dimensional reconstruction were used to study the relationship between apical constriction of neuroepithelial cells and the pattern of bending of the neuroepithelium in the developing neural tube of the 12-somite mouse embryo. The neuroepithelium of the mouse exhibits prominent regional variations in size and shape along the embryo axis. The complex shape of most of the cephalic neural tube (e.g., forebrain and midbrain) is due to the coexistence of concave and convex bending sites whereas more caudal regions (e.g., hindbrain and spinal cord) generally lack sites of convex bending and have a relatively simple shape. The apical morphology of neuroepithelial cells was found to be correlated more closely with the local status of bending of the neuroepithelium than with the specific region of the neural tube in which they are located. In areas of enhanced apical constriction, microfilament bundles were particularly prominent. Morphometry revealed that patterns of bending of the neuroepithelium were correlated almost exactly with those of apical constriction throughout the forming neural tube. These findings support the idea that apical constriction of neuroepithelial cells, resulting from tension generated by microfilament bundles, plays a major role in bending of the neuroepithelium during neural tube formation in the mouse.

Intrinsic and extrinsic factors collaborate to generate driving forces for neural tube formation in the chick: a study using morphometry and computerized three-dimensional reconstruction

The formation of the neural tube, the rudiment of the entire central nervous system, is one of the earliest morphogenetic movements. The origin of the driving forces for this process remains uncertain, but recent studies suggest the involvement of both intrinsic and extrinsic factors. In the present study, we have used morphometry, analysis of stereopair photographs of whole embryos, and computerized three-dimensional reconstruction to investigate the factors which constitute the bulk of the driving forces for neural tube formation in the developing midbrain of Hamburger and Hamilton stages 5-9 chick embryos. Results support the notion that neural tube formation is driven by a coordinated interplay of intrinsic and extrinsic forces. Initial bending of the neural plate along the midline of the embryo and uplifting of the neural folds is accomplished primarily through the combined action of intrinsic forces (resulting from apical constriction of neuroepithelial cells) and extrinsic forces (mostly a passive consequence of head-fold formation). However, once in the uplifted position, curling over of neural folds and closure of the neural tube is driven largely by apical constriction-mediated (intrinsic) forces that are generated by cells in the midlateral walls of the forming neural tube.

Biomechanical basis of diazepam-induced neural tube defects in early chick embryos: a morphometric study

The biomechanical basis of diazepam (Valium/Roche)-induced neural tube defects in the chick was investigated using a combination of electron microscopy and morphometry. Embryos at stage 8 (four-somite stage) of development were explanted and grown for 6 hr in nutrient medium containing 400 micrograms/ml diazepam. Nearly 80% of these embryos exhibited neural tube defects that were most pronounced in the forming midbrain region and typified by a "relaxation" or "collapse" of neural folds. The hindbrain and spinal cord regions were less affected. Electron microscopy revealed that neuroepithelial cells in diazepam-treated embryos had smoother apical surfaces and broader apical widths than did controls. Morphometric measurements supported this observation and further showed that these effects were focused at sites within the wall of the forming neural tube that typically exhibit the greatest degree of bending and apical constriction (i.e., the floor and midlateral walls). Overall results indicate that neural tube defects associated with exposure to diazepam are due largely to a general inhibition of the contractile activity of apical microfilament bundles in neuroepithelial cells. These findings 1) emphasize the important contribution of microfilament-mediated apical constriction of neuroepithelial cells in providing the driving forces for bending of the neuroepithelium during neural tube formation and 2) suggest that agents or conditions that impair their contractile activity could play a role in the pathogenesis of certain types of neural tube defects.

Studies on the mechanisms of neurulation in the chick: morphometric analysis of force distribution within the neuroepithelium during neural tube formation

Changes in the shape of neuroepithelial cells, particularly apical constriction, are generally thought to play a major role in generating the driving forces for neural tube formation. Our previous study [Nagele and Lee (1987) J. Exp. Zool., 241:197-205] has shown that, in the developing midbrain region of stage 8+ chick embryos, neuroepithelial cells showing the greatest degree of apical constriction are concentrated at sites of enhanced bending of the neuroepithelium (i.e., the floor and midlateral walls of neural tube), suggesting that driving forces resulting from apical constriction are concentrated at these sites during closure of the neural tube. In the present study, we have used morphometric methods to 1) measure regional variations in the degree of apical constriction and apical surface folding at selected regions along the anteroposterior axis of stage 8+ chick embryos, which closely resemble the various ontogenetic phases of neural tube formation, and 2) investigate how forces resulting from apical constriction are distributed within the neuroepithelium during transformation of the neural plate into a neural tube. Results show that, during neural tube formation, driving forces resulting from apical constriction are not distributed uniformly throughout the neuroepithelium but rather are concentrated sequentially at three distinct locations: 1) the floor (during transformation of the neural plate to a V-shaped neuroepithelium), 2) the midlateral walls (during transformation of the V-shaped neuroepithelium into a C-shaped neuroepithelium), and 3) the upper walls (during the transformation of the C-shaped neuroepithelium into a closed neural tube).

Toxic and teratologic effects of verapamil on early chick embryos: evidence for the involvement of calcium in neural tube closure

Toxic and teratologic effects of verapamil, a calcium antagonist, on chick embryos explanted at stage 8 (four-somite stage) and cultured for 6-8 hours were investigated. In general, embryos responded to verapamil in a dose-related manner. Concentrations lower than 2 micrograms/ml had no apparent effect on the development of embryos. A concentration of 15 micrograms/ml significantly increased the incidence of embryos (approximately 80% of viable embryos) with neural tube closure defects and less numerous somites. Higher concentrations (e.g., 30 micrograms/ml) were embryotoxic and over 90% of the embryos were either severely malformed or dead after 8 hours of incubation. Compared to controls, verapamil-treated neuroepithelial cells had smoother apical surfaces and less conspicuous microfilament bundles. The deleterious effects of verapamil (15 micrograms/ml) could be reversed by subculturing the affected embryos, within 3 hours of treatment, on nutrient medium alone or on nutrient medium containing 25 micrograms/ml chlorotetracycline (CTC), a calcium agonist, the latter being more effective provided that treatment did not exceed 4 hours. Exposure of the developing neuroepithelium to 15 micrograms/ml verapamil for 3-4 hours resulted in a significant reduction in free Ca2+ levels, as revealed by the pyroantimonate precipitation method, throughout neuroepithelial cells. Overall results suggest that verapamil causes neural tube closure defects by reducing intracellular free Ca2+ levels, thereby relaxing apical microfilament bundles of developing neuroepithelial cells.

Teratogenic effects of nigericin, a carboxylic ionophore

Nigericin (Na+ salt) was given intraperitoneally at doses of 5.0 or 7.0 mg/kg on one of gestation days 7-12 to pregnant CD-1 mice. Additional mice were injected ip with 2.5 mg/kg on day 11 or 12 only. Injections on single gestation days reduced fetal growth and increased prenatal deaths. Additional signs of toxicity to the conceptus included treatment-related extra ribs and delayed ossification. Treatment was also associated with gross and skeletal malformations, such as median facial cleft, exencephaly, encephalocele, fused ribs, and anomalous vertebrae and exoccipitals. With the possible exception of the 5.0 mg/kg dose given on gestation day 8, nigericin doses associated with gross or skeletal malformations also resulted in observable maternal toxicity.

Possible involvement of calmodulin in apical constriction of neuroepithelial cells and elevation of neural folds in the chick

Chlorpromazine and trifluoperazine HCl, antipsychotic drugs known to bind to calmodulin, reversibly inhibited elevation of neural folds by interfering with the contractile activity of apical microfilament bundles in developing chick neuroepithelial cells.

The role of Ca2+ in the regulation of embryogenesis in early amphibian and echinoderm embryos

It is difficult to measure intracellular calcium concentrations in dividing embryos and, furthermore, these interact with pHi and with cyclic nucleotides. Nevertheless, the evidence currently suggests that changing [Ca2+]i levels probably do not have a major role in controlling normal cell-to-cell communication and so do not integrate cell division during programmed cleavage in amphibian embryos. However, treatments that are known or expected to raise artificially cytoplasmic calcium to relatively high levels cause abnormal embryogenesis, probably via the uncoupling of intercellular communication of the blastomeres, and also cortical contractions in early echinoderm and amphibian embryos.

Effect of the calmodulin inhibitor R24571 (calmidazolium) on rat embryos cultured in vitro

The possible effects of inhibition of the calcium-binding protein, calmodulin, on mammalian morphogenesis have been investigated by culturing rat embryos in vitro from 9 1/2 to 11 1/2 days of development in the presence of R24571 (calmidazolium), a specific inhibitor of calmodulin. Embryos cultured in 10(-2) mM R24571 for 48 h show inhibited development and exhibit a range of morphogenetic abnormalities including assymetry and neural tube defects. Embryos exposed to R24571 for the first 24 h of a 48 h culture are more severely affected than embryos exposed to R24571 for the last 24 h.

Diazepam inhibits neurulation through its action on myosin-containing microfilaments in early chick embryos

Diazepam (Valium/Roche) inhibited the morphogenesis of explanted stage 8 chick embryos in a dose-related manner. Diazepam, at concn of 400-500 micrograms/ml, preferentially inhibited closure of the neural tube. This inhibition was accompanied by a significant reduction in myosin content of the developing neuroepithelium. Diazepam can be used as a probe to study the contributory role of myosin in cellular and morphogenetic movements.

Calcium, microfilaments and morphogenesis

Morphogenesis, the generation of tissue form, is important not only in the embryogenesis of a new individual, but also because a change in morphogenesis may be involved in the establishment of differences between individuals during evolution. Morphogenetic movements are effected in part by coordinated changes in the shapes of individual cells and over the past decade the cellular organelles responsible for cell shape have been identified as microfilaments and microtubules. In non-embryonic systems the contraction of microfilaments is controlled by the level of intracellular free calcium, and so calcium is implicated as an intermediate control mechanism in morphogenisis. Through techniques which perturb the calcium balance of cells, or which measure calcium ion concentration directly, evidence is accumulating that calcium is involved in morphogenetic movements such as gastrulation and neurulation, and related phenomena such as wound healing. Thus fundamental questions about the control of morphogenesis in embryogenesis and evolution may now be couched in more precise terms of the control of intracellular calcium ion balance.

Toxic and teratologic effects of caffeine on explanted early chick embryos

The toxic and teratologic effects of caffeine on chick embryos explanted at stages 4-7 and cultured for 19-22 hours were investigated. Caffeine, at 200-300 micrograms/ml, significantly increased the incidence of neural tube defects regardless of the developmental stage at treatment. Concentrations of 500 micrograms/ml or higher inhibited morphogenesis of nearly all organ primordia. In general, the effects of caffeine were concentration dependent and younger embryos were more susceptible to treatment than their older counterparts. Microscopic studies confirmed that the developing neuroepithelium was most sensitive to treatment. Caffeine, at concentrations sufficient to inhibit neural tube closure, caused no apparent alteration in the ultrastructure of cellular components except that apical microfilament bundles were thinner and less conspicuous than usual. Furthermore, caffeine (400 micrograms/ml) selectively inhibited uplifting of neural folds (and hence, closure of the neural tube) in embryos explanted at stage 8 and cultured for 4-6 and 16 hours. Affected neuroepithelial cells lacked the typical bottle-shaped characteristic and folded apical surfaces. Overall results of this study suggest that caffeine causes neural tube defects, at least in part, through its inhibitory action on the contractile activity of apical microfilament bundles in developing neuroepithelial cells.

Calcium dependence and contraction in somite formation

The existence of a calcium-dependent contractile process in the formation of somites from segmental plate mesoderm was investigated using a Ca2+ agonist and Ca2+ and calmodulin antagonists. The contribution of cell movement and apical constriction in the segmentation process were assessed using SEM of normal and drug-treated somite and segmental plate tissue. Explants that contained segmental plates of stage 14-15 chick embryos were cultured on vitelline membranes in calcium- and magnesium-free (CMF) Hands' solution, liquid culture medium, and medium containing drugs. Ca2+ ionophore A23187 promoted the rapid completion of one new somite pair. CMF halted segmentation. The Ca2+ antagonists verapamil and papaverine reversibly inhibited segmentation. Theophylline did not inhibit segmentation, suggesting that the effects of the Ca2+ antagonists are not due to inhibition of phosphodiesterase activity. These results suggest that somitogenesis is Ca2+-dependent. Two drugs that inhibit the binding of calmodulin, chlorpromazine and trifluoperazine (TFP), halted segmentation. The inhibitory effect of TFP was reversible. The effects of TFP on somites were compared with those of cytochalasin D. The contribution of microtubules to cell shape and movement in somitogenesis was examined by incubation with nocodazole, a reversible inhibitor of tubulin polymerization. Cell elongation and somitogenesis were inhibited.

Diazepam-induced neural tube closure defects in explanted early chick embryos

The effects of diazepam on the development of explanted stage 4 chick embryos were investigated. Diazepam, at 10-120 micrograms/ml, preferentially inhibited closure of the neural tube. This effect was reversible. Concentrations of 150-200 micrograms/ml inhibited not only neural tube closure but also blastodermal expansion, somite formation, and heart development in 52% of the embryos. Concentrations above 200 micrograms/ml were highly embryotoxic. Electron microscopy of affected neuroepithelial cells revealed that 1) apical surfaces were much smoother than usual and 2) apical filament bundles, which are generally thought to provide motive forces for uplifting of neural folds, were not well organized and often lacked alternating dark and light areas along their length. These findings and the fact that changes in cell surface topography reflect the contractile activities of underlying filament bundles suggest that the observed "smoothing" effect on apical cell surfaces and neural tube closure defects are due, at least in part, to the impaired ability of these filament bundles to contract.

Neural tube closure defects caused by papaverine in explanted early chick embryos

Papaverine (50 micrograms/ml) preferentially inhibited uplifting of neural folds in explanted stage 8 chick embryos. Affected neuroepithelial cells often lost their wedge-shaped and elongated appearance. Also, luminal surfaces of most affected cells were smoother than usual as evidenced by the marked decrease in the number of cytoplasmic extensions, but the integrity of other structures (including cytoskeletal components) was not noticeably affected. The observed changes in cell surface topography were due, at least in part, to the imparied ability of apical microfilaments to contract and their eventual relaxation. The "relaxing" effect of papaverine on neural folds could be reversed by subsequent treatment with ionophore A23187. Since papaverine and ionophore A23187 are known to alter the normal distribution of intracellular Ca2+ and changes in cell surface topography are correlated with contractile activities of apical microfilaments, papaverine elicits neural tube closure defects by lowering intracellular free Ca2+ levels, thereby relaxing contracted apical microfilaments in neuroepithelial cells.