TGFβ相关蛋白在爪蟾早期胚胎中的免疫组织化学的研究

By the method of immunocytochemistry, using the polyclonal antibodies raised against the 1-29 N-terminal residues of TGF beta-1, we found that the protein could bind to the antibodies was present in the early embryos of Xenopus. The protein was named TGF beta-related protein. It was distributed mainly in the endoderm from blastula (stg. 7) to late neurula. In the blastula (stg. 8), the protein was localized in the vegetal hemisphere near the floor of the blastocoel [Plate I, Fig. 1]. In the early gastrula (stg. 10.5) [Plate I, Fig. 2], it was localized in the central part of the vegetal hemisphere. In late gastrula (stg. 12), it was mainly distributed around the gastrocoel [Plate I, Fig. 3], but the fluorescence in endoderm cells (ventral part beneath the gastrocoel) was stronger than in the mesoderm cells (dorsal part of the gastrocoel). In the early neurula (stg. 14), the whole endoderm displayed strong fluorescence and the part of dorsal mesoderm (presumptive somite & notochord) close to endoderm was also found to be positively stained [Plate I, Fig. 4,5], but the part close to neural plate was negative. In The late neurula (stg. 20) [Plate I, Fig. 6], it was found in the central area of yolk mass (endoderm cells). No positive stain was detected in the unfertilized egg, embryos earlier than stage and later than stage 20/21.2+ protein in early development.     

Experimental approaches to the study of the formation of axial structures during early development of <Emphasis Type="Italic">Xenopus laevis</Emphasis>

The effect of mechanical extension on the differentiation of axial mesoderm in double explants (sandwiches) of Xenopus laevis embryonic tissues isolated during the early gastrula–late neurula developmen-tal period is studied. In explants at the early gastrula stage, artificial extension orients and stimulates isolated differentiation of the notochord and somites as well as their joint formation. Moreover, extension facilitated the formation of the normal anatomical structure of the notochord and affected expression of Chordin gene. At the late gastrula stage, the effect of artificial extension on joint somite–notochord differentiation was weaker. At the stage of late neurula, somites were sometimes formed in explants lacking a notochord anlage. Thus, at earlier stages, the formation of somites was stimulated by contacts with the notochord and joint development of both structures was mechanical dependent, while at the later stages, somites developed inde-pendently of the notochord. Thus, the role of tissue extension is primarily the establishment of normal mor-phology and expression of Chordin was located in the direction of extension.     

Topographic changes in nascent and early mesoderm in amphioxus embryos studied by DiI labeling and by in situ hybridization for a Brachyury gene

 In amphioxus embryos, the nascent and early mesoderm (including chorda-mesoderm) was visualized by expression of a Brachyury gene (AmBra-2). A band of mesoderm is first detected encircling the earliest (vegetal plate stage) gastrula sub-equatorially. Soon thereafter, the vegetal plate invaginates, resulting in a cap-shaped gastrula with the mesoderm localized at the blastoporal lip and completely encircling the blastopore. As the gastrula stage progresses, DiI (a vital dye) labeling demonstrates that the entire mesoderm is internalized by a slight involution of the epiblast into the hypoblast all around the perimeter of the blastopore. Subsequently, during the early neurula stage, the internalized mesoderm undergoes anterior extension mid-dorsally (as notochord) and dorsolaterally (in paraxial regions where segments will later form). By the late neurula stage, AmBra-2 is no longer transcribed throughout the mesoderm as a whole; instead, expression is detectable only in the posterior mesoderm and in the notochord, but not in paraxial mesoderm where definitive somites have formed. Received: 28 November 1996 / Accepted: 2 January 1997     

Signals from trunk paraxial mesoderm induce pronephros formation in chick intermediate mesoderm

We used Pax-2 mRNA expression and Lim 1/2 antibody staining as markers for the conversion of chick intermediate mesoderm (IM) to pronephric tissue and Lmx-1 mRNA expression as a marker for mesonephros. Pronephric markers were strongly expressed caudal to the fifth somite by stage 9. To determine whether the pronephros was induced by adjacent tissues and, if so, to identify the inducing tissues and the timing of induction, we microsurgically dissected one side of chick embryos developing in culture and then incubated them for up to 3 days. The undisturbed contralateral side served as a control. Most embryos cut parallel to the rostrocaudal axis between the trunk paraxial mesoderm and IM before stage 8 developed a pronephros on the control side only. Embryos manipulated after stage 9 developed pronephric structures on both sides, but the caudal pronephric extension was attenuated on the cut side. These results suggest that a medial signal is required for pronephric development and show that the signal is propagated in a rostral to caudal sequence. In manipulated embryos cultured for 3 days in ovo, the mesonephros as well as the pronephros failed to develop on the experimental side. In contrast, embryos cut between the notochord and the trunk paraxial mesoderm formed pronephric structures on both sides, regardless of the stage at which the operation was performed, indicating that the signal arises from the paraxial mesoderm (PM) and not from axial mesoderm. This cut also served as a control for cuts between the PM and the IM and showed that signaling itself was blocked in the former experiments, not the migration of pronephric or mesonephric precursor cells from the primitive streak. Additional control experiments ruled out the need for signals from lateral plate mesoderm, ectoderm, or endoderm. To determine whether the trunk paraxial mesoderm caudal to the fifth somite maintains its inductive capacity in the absence of contact with more rostral tissue, embryos were transected. Those transected below the prospective level of the fifth somite expressed Pax-2 in both the rostral and the caudal isolates, whereas embryos transected rostral to this level expressed Pax-2 in the caudal isolate only. Thus, a rostral signal is not required to establish the normal pattern of Pax-2 expression and pronephros formation. To determine whether paraxial mesoderm is sufficient for pronephros induction, stage 7 or earlier chick lateral plate mesoderm was cocultured with caudal stage 8 or 9 quail somites in collagen gels. Pax-2 was expressed in chick tissues in 21 of 25 embryos. Isochronic transplantation of stage 4 or 5 quail node into caudal chick primitive streak resulted in the generation of ectopic somites. These somites induced ectopic pronephroi in lateral plate mesoderm, and the IM that received signals from both native and ectopic somites formed enlarged pronephroi with increased Pax-2 expression. We conclude that signals from a localized region of the trunk paraxial mesoderm are both required and sufficient for the induction of the pronephros from the chick IM. Studies to identify the molecular nature of the induction are in progress.     

The migration of myogenic cells from the somites at the wing level in avian embryos

This study is concerned with establishing a morphological basis for the initiation of migration of putative myogenic cells from the somites into the presumptive wing bud in avian embryos. At the 22 somite stage (stage 14) vasculogenesis is a prevalent activity. By use of a quail specific monoclonal antibody to vascular endothelial cells, vascular cells are recognized in the lateral plate, on the intermediate mesoderm, and on somite surfaces. Cells that are found between the lateral plate mesoderm and somites are shown to be vascular endothelial cells. The lateral body folds progressively bring the lateral plate mesoderm close to the lateral margin of the somites and vascular elements disappear from surface view. It is not until the 24 somite stage (stage 15) that some cells in the ventral lateral margin of somites at the wing level can be seen in scanning electron micrographs to extend basal cell processes toward adjacent vascular tubes. These results provide a morphological basis for the early migratory behavior of myogenic cells and demonstrate their close proximity to the prepatterned vascular network.     

The influence of axial structures on chick somite formation

The influence of the axial structures on somite formation was investigated by culturing, on a nutritive agar substrate, segmental plates from chick embryos having 8 to 20 pairs of somites. In the first set of experiments, segmental plate was explanted together with adjacent notochord and approximately the lateral halves of the neural tube and node region. These explants formed 18 to 20 somites within 30 hr. In a second series of experiments, the notochord and neural tube were included as before, but further regression movements in the explants were prevented by removing the node region. These explants formed only 11.9 ± 1.1 somites. Finally, explants of segmental plate that included no neural tube, notochord, or node region were made. These explants had formed 10.7 ± 1.1 somites 14 to 17 hr later. When such explants were cultured for periods longer than 17 hr, there was a marked tendency for the more posterior somites to disperse and for all of the somites to develop a peculiar “hollow” morphology. It was concluded from these results that during the period of development when chick embryos possess 8 to 20 pairs of somites, the segmental plate mesoderm (1) represents about 12 prospective somites, (2) may segment into its full complement of somites without further contact with the axial structures, but (3) requires continued intimate contact with the axial structures for normal somite morphologic differentiation and stability.     

Tbx18 and boundary formation in chick somite and wing development

The chicken Tbx gene, Tbx18, is expressed in lateral plate mesoderm, limb, and developing somites. Here we show that Tbx18 is expressed transiently in axial mesenchyme during somite segmentation. We present evidence from overexpression and transplantation experiments that Tbx18 controls fissure formation in the late stages of somite maturation. In presumptive wing lateral plate mesoderm, ectopic Tbx18 expression leads to anterior extension of the wing bud. These results suggest that Tbx18 is involved in producing mesodermal boundaries, generating in paraxial mesoderm morphological boundaries between somites and in lateral plate mesoderm a wing- or non-wing-forming boundary.     

An early marker of axial pattern in the chick embryo and its respecification by retinoic acid.

Chick Ghox 2.9 protein, a homeodomain-containing polypeptide, is first detected in the mid-gastrula stage embryo and its levels increase rapidly in the late gastrula. At this time, the initially narrow band of expression along the primitive streak expands laterally to form a shield-like domain that encompasses almost the entire posterior region of the embryo and extends anteriorly as far as Hensen's node. We have found that this expression domain co-localizes with a morphological feature that consists of a stratum of refractile, thickened mesoderm. Antibody-staining indicates that Ghox 2.9 protein is present in all cells of this mesodermal region. In contrast, expression within the ectoderm overlying the region of refractile mesoderm varies considerably. The highest levels of expression are found in ectoderm near the streak and surrounding Hensen's node, regions that recent fate mapping studies suggest that primarily destined to give rise to neurectoderm. At the definitive streak stage (Hamburger and Hamilton stage 4) the chick embryo is especially sensitive to the induction of axial malformations by retinoic acid. Four hours after the treatment of definitive streak embryos with a pulse of retinoic acid the expression of Ghox 2.9 protein is greatly elevated. This ectopic expression occurs in tissues anterior to Hensen's node, including floor plate, notochord, presumptive neural plate and lateral plate mesoderm, but does not occur in the anteriormost region of the embryo. The ectopic induction of Ghox 2.9 is strongest in ectoderm, and weaker in the underlying mesoderm. Endoderm throughout the embryo is unresponsive. At stage 11, Ghox 2.9 is normally expressed at high levels within rhombomere 4 of the developing hindbrain. In retinoic-acid-treated embryos which have developed to this stage, typical rhombomere boundaries are largely absent. Nevertheless, Ghox 2.9 is still expressed as a discrete band, but one that is widened and displaced to a more anterior position.     

Positive and Negative Regulation of the Differentiation of Ventral Mesoderm for Erythrocytes in Xenopus laevis

To elucidate the mechanism of determination and regulation of hemopoiesis in the early Xenopus embryo, explants of dorsal and ventral mesoderm from various stage embryos were cultured alone or combined with various tissues derived from the same stage embryo. Western blot analysis of larvae-specific globin expression using monoclonal antibody L5.41 revealed that extensive erythropoiesis occurred in the explants of ventral mesoderm from st. 22 tailbud embryo, but not in those of dorsal mesoderm. Experiments using combined explants at this stage demonstrated that the in vitro differentiation of erythrocytes in the ventral mesoderm could be completely inhibited by the dorsal tissue, including neural tube, notochord, and somite mesoderm, but not by other mesoderms, gut endoderm, or forebrain. Subsequent explant studies showed that the notochord alone is sufficient for this inhibition. Furthermore, the ventral mesoderm explant from the st. 10⁺ early gastrula embryo was not able to differentiate into erythroid cells. However, small amounts of globin were expressed if ventral mesoderm of this stage was combined with animal pole cells which were mainly differentiated to epidermis. This stimulation was enhanced when both tissues were excised together without separation, while none of the other parts of st. 10⁺ embryo had this stimulatory effect. These observations found in the combined explants suggest that in vivo interactions between the ventral mesoderm and adjacent tissues are important for normal development of erythroid precursor cells.     

Loss of late primitive streak mesoderm and interruption of left-right morphogenesis in the Ednrb(s-1Acrg) mutant mouse

This study characterizes defects associated with abnormal mesoderm development in mouse embryos homozygous for the induced Ednrb(s-1Acrg) allele of the piebald deletion complex. The Ednrb(s-1Acrg) deletion results in recessive embryonic lethality and mutant embryos exhibit a truncated posterior body axis. The primitive streak and node become disfigured, consistent with evidence that cell migration is impaired in newly formed mesoderm. Additional defects related to mesoderm development include notochord degeneration, somite malformations, and abnormal vascular development. Arrested heart looping morphogenesis and a randomized direction of embryonic turning indicate that left-right development is also perturbed. The expression of nodal and leftb, Tgf-beta-related genes involved in a left-determinant signaling pathway, is variably lost in the left lateral plate mesoderm. Mutational analysis has demonstrated that Fgf8 and Brachyury (T) are required for normal mesoderm and left-right development and the asymmetric expression of nodal and leftb. Fgf8 expression in nascent mesoderm exiting the primitive streak is dramatically reduced in mutant embryos, and diminished T expression accompanies the progressive loss of paraxial, lateral, and primitive streak mesoderm. In contrast, axial mesoderm persists and T and nodal appear to be appropriately expressed in their specific domains in the node and notochord. We propose that this mutation disrupts a morphogenetic pathway, likely involving FGF signaling, important for the development of streak-derived posterior mesoderm and lateral morphogenesis.     

Experimental analysis of the mechanisms of somite morphogenesis

Earlier studies have suggested influences on somite morphogenesis by “somite-forming centers,” primitive streak regression, Hensen's node and notochord, and neural plate. Contradictions among these studies were unresolved.Our experiments resolve these conflicts and reveal roles of the primitive streak and notochord in shearing the prospective somite mesoderm into right and left halves and releasing somite-forming capabilities already present. The neural plate appears to be the principal inductor of somites.Embryo fragments containing no somite-forming centers, node, notochord, or streak nevertheless formed somites within 10 hr. Such somites disperse within the next 14–24 hr, which may explain why others failed to see them. In these fragments, an incision alongside the streak substitutes for streak regression in releasing somite formation. All such somites form simultaneously rather than in the normal anteroposterior progression. These fragments contain neural plate, but not notochord. We believe that physical attachment of somites to notochord in normal embryos stabilizes them and prevents dispersal.Pieces of epiblast were rotated 180° putting neural plate over lateral plate mesoderm regions. Somites were induced from the lateral plate by the displaced neural plate region. This is additional evidence of the powerful ability of neuroepithelium to induce somites.     

Mediolateral cell intercalation in the dorsal, axial mesoderm of Xenopus laevis

The pattern of mediolateral cell intercalation in mesodermal tissues during gastrulation and neurulation of Xenopus laevis was determined by tracing cells labeled with fluorescein dextran amine (FDA). Patches of the involuting marginal zone (IMZ) of early gastrula stage embryos, labeled by injection of FDA at the one-cell stage, were grafted to the corresponding regions of unlabeled host embryos. The host embryos were fixed at several stages, serially sectioned, and examined with fluorescence microscopy and three-dimensional reconstruction. Patterns of mixing of labeled and unlabeled cells show that mediolateral cell intercalation occurs in the posterior, dorsal mesoderm as this region undergoes convergent extension and differentiates into somites and notochord. In contrast, it does not occur in any dorsoventral sector of the anterior, leading edge of the mesodermal mantle. These results, taken with other evidence, suggest that the mesoderm of Xenopus consists of two subpopulations, each with a characteristic morphogenetic movement, cell behavior, and tissue fate. The migrating mesoderm (1) does not show convergent extension; (2) migrates and spreads on the blastocoel roof; (3) is dependent on this substratum for its morphogenesis; (4) shows little mediolateral intercalation; (5) consists of the anterior, early-involuting region of the mesodermal mantle; and (6) differentiates into head, heart, blood island, and lateral body wall mesoderm. The extending mesoderm (1) shows convergent extension; (2) is independent of the blastocoel roof in its morphogenesis; (3) shows extensive mediolateral intercalation; (4) consists of the posterior, late-involuting parts of the mesodermal mantle; and (5) differentiates into somite and notochord.     

Vegetalising factor extracted from the fish swimbladder and tested on presumptive ectoderm ofTriturus embryos

Summary Vegetalising factor was isolated from swimbladder of crusian carp (Carassius auratus) by solubilishing with 8 M urea the precipitate obtained after digesting the swimbladder with collagenase. The urea-soluble fraction vegetalised isolated presumptive ectoderm ofTriturus gastrula and produced both undifferentiated mesodermal and endodermal cells. Brief heating of the fraction changed its capacity to produce organised mesodermal tissues, such as notochord and somite, and the frequency of induction of undifferentiated cells was reduced. By inserting the urea-soluble fraction into the blastocoel of an early gastrula, embryos without epidermis were obtained. Some of the embryos consisted of undifferentiated mesodermal and endodermal cells, but in the remaining ones small fragments of notochord, small numbers of somites and pronephros developed, enclosed by endodermal cells.     

Three developmental compartments involved in rib formation

When the thoracic somitic mesoderm was separated from the neural tube and the notochord with a piece of aluminum foil in two-day chick embryos, seven days after the operation ribs lacked their proximal part. The embryos were rescued by co-transplanting the notochord, the ventral half of neural tube, or QT6 cells transformed with Shh, on the somite side of the aluminum foil insert. Thus, proximal rib development depends on the notochord and the ventral neural tube, an effect which might be mediated through Shh secreted by these axial tissues. On the other hand, when the thoracic somitic mesoderm was separated from the surface ectoderm by a piece of polyethylene terephthalate film, the distal parts of the ribs were missing, suggesting that distal rib development depends on surface ectoderm. In these embryos, expression of Pax3 was weak and perturbed showing that the dermomyotome developed abnormally. It is not clear whether the development of distal rib is mediated by the dermomyotome, or the ectoderm. It has previously been shown that sternal rib development depends on lateral plate mesoderm. As to the distal rib, it is considered to be composed of two parts. Thus, the rib is composed of three developmental compartments, in agreement with a recently presented classification of somite derivatives as primaxial and abaxial.