Lauri Saxén

Early organogenesis of the kidney

The mammalian permanent kidney consists of three cell lineages of different origin: the epithelial cells of the ureter bud, the mesenchymal cells of the nephric blastema and the endothelial cells of the capillaries. Organogenesis is governed by a cascade of morphogenetic interactions between these cell populations, a reciprocal epithelial-mesenchymal interaction between the branching ureter and the metanephric mesenchyme, homotypic interactions between cells of the tubular anlagen, stimulation of angiogenesis by the differentiating blastema and a mesenchymal-endothelial interaction guiding the migration of the capillary endothelial cells. While the biology of these interactive events is well known, as described in this overview, the molecular mechanisms are less well mapped out.

Differentiation and vascularization of the metanephric kidney grafted on the chorioallantoic membrane.

The origin and development of mouse kidney vasculature were examined in chorioallantoic grafts of early kidney rudiments and of experimentally induced explants of separated metanephric mesenchymes. Whole kidney rudiments developed into advanced stages, expressed the segment-specific antigenic markers of tubules and the polyanionic coat of the glomeruli. In contrast to development in vitro, these grafts regularly showed glomeruli with an endothelial component and a basement membrane expressing type IV collagen and laminin. The glomerular endothelial cells in these grafts were shown to carry the nuclear structure of the host. This confirms the outside origin of these cells and the true hybrid nature of the glomeruli. When in vitro induced mesenchymes were grafted on chorioallantoic membranes, abundant vascular invasion was regularly found but properly vascularized glomeruli were exceptional. Uninduced, similarly grafted mesenchymal explants remained avascular as did the undifferentiated portions of partially induced mesenchymal blastemas. It is concluded that the stimulation of the host endothelial cells to invade into the differentiating mesenchyme requires the morphogenetic tissue interaction between the ureter bud and the mesenchyme. The induced metanephric cells presumably start to produce chemoattractants for endothelial cells at an early stage of differentiation. Kidney development thus seems to require an orderly, synchronized development of the three cell lineages: the branching ureter, the induced, tubule-forming mesenchyme, and the invading endothelial cells of outside origin.

ACTIVIN DISRUPTS EPITHELIAL BRANCHING MORPHOGENESIS IN DEVELOPING GLANDULAR ORGANS OF THE MOUSE

We report that activin profoundly alters epithelial branching morphogenesis of embryonic mouse salivary gland, pancreas and kidney rudiments in culture, indicating that it may play a role as a morphogen during mammalian organogenesis. In developing pancreas and salivary gland rudiments, activin causes severe disruption of normal lobulation patterns of the epithelium whereas follistatin, an activin-binding protein, counteracts the effect of activin. In the kidney, activin delays branching of the ureter bud and reduces the number of secondary branches. TGF-beta induces a pattern of aberrant branching in the ureter bud derived epithelium distinct from that seen for activin. Reverse-transcriptase polymerase chain reaction, Northern hybridization and in situ hybridization analyses indicate that these developing tissues express the mRNA transcripts for activin subunits, follistatin or activin receptors. Our results are suggestive of a potential role for the activin-follistatin system as an intrinsic regulator of epithelial branching morphogenesis during mammalian organogenesis.

Changes in the glycosylation pattern during embryonic development of mouse kidney as revealed with lectin conjugates.

Distribution of lectin-binding sites in adult and developing mouse kidney was studied with fluorochrome- and peroxidase-coupled lectins. Effects of fixation methods on lectin-binding patterns were also compared. Un-induced mesenchymal cells and ureter bud of the early metanephros reacted with Concanavalin A, Lens culinaris, Ricinus communis I, and wheat germ agglutinins, whereas binding sites for both soybean and peanut (PNA) agglutinins were seen only in ureter bud tissue. On induction, PNA positivity rapidly appeared in the induced, condensed areas of the metanephrogenic mesenchyme. Early glomeruli expressed heterogeneously terminal galactosyl and N-acetylgalactosaminyl moieties in the podocytes. Later, these sites disappeared and were apparently covered by sialic acids. Endothelia also displayed a comparable sialylation of terminal saccharide moieties during maturation. Binding sites for many of the above lectins were also found in the developing proximal and distal tubules. Terminal fucosyl residues, characteristic of mature proximal tubules, appeared during day 13 of development. Dolichos biflorus agglutinin reactivity, typically seen in the collecting ducts, appeared by day 13. Griffonia simplicifolia-I-B4 isolectin reactivity was exclusively localized to endothelial in adult kidney cortex, but in embryonic kidneys reactivity with collecting duct and podocytes was also seen. These results suggest that the compartmentalized expression of cell glycoconjugates in adult mouse kidney is acquired in a sequential manner during development. Such sequential appearance of the mature glycosylation pattern probably reflects functional maturation of the nephron.

Epithelial-mesenchymal interactions regulate the stage-specific expression of a cell surface proteoglycan, syndecan, in the developing kidney☆

Morphogenesis of the kidney is regulated by reciprocal tissue interactions between the epithelial ureter bud and the metanephric mesenchyme. The differentiation of the kidney involves profound changes in the extracellular matrix, and therefore matrix receptors may have an important role in this process. We studied the expression of syndecan, a cell surface proteoglycan acting as a receptor for interstitial matrix materials, by using a monoclonal antibody against the core protein of the molecule. Syndecan was not detected in the uninduced metanephric mesenchyme. During the formation of the ureter bud from the Wolffian duct, syndecan appeared in the mesenchymal cells around the invaginating bud. Simultaneously with the first branching of the ureter bud, the whole nephric mesenchyme became syndecan positive, but a 3- to 10-cell-thick layer around the branching ureter bud, representing the presumptive tubular cells, was most intensely stained. During the assembly of the mesenchyme cells into pretubular aggregates, syndecan was detected in these aggregates and, to a lesser degree, in the morphologically undifferentiated mesenchyme. Thereafter syndecan was found only in the differentiating epithelium, from which it was gradually lost during maturation of the nephron. It was last detected in the periphery of the kidney, where tubulogenesis still continued. In transfilter cultures we showed that syndecan appeared in the nephric mesenchyme during the period when the mesenchyme becomes programmed to transform into epithelial structures. By using interspecies recombinations and a species-specific antibody we excluded the possibility that syndecan in the mesenchyme would originate from the inductor. We conclude that syndecan expression is regulated by epithelial-mesenchymal interactions. The findings that syndecan appeared as an early response to induction and that its distribution showed both spatial and temporal correlation with kidney morphogenesis suggest an important role for this molecule in development.

Fibronectin in the development of embryonic chick eye

Abstract The time course of appearance and distribution of fibronectin in the developing eye have been studied in chick embryos by indirect immunofluorescence. At the 12-somite stage, fibronectin was detected as a layer under the ectodermal cells overlying the forebrain vesicle; it was also present in the head mesenchyme. During formation of the lens placode and its invagination, a zone containing fibronectin persisted around the lens as a component of the capsule. The fibronectin-containing layer was separated from the corneal epithelial cells during the formation of the acellular stroma. The migrating corneal endothelial cells were seen posterior to the fibronectin layer. The secondary stroma was strongly positive for fibronectin. Fibronectin disappeared from the cornea starting from its posterior part along with the corneal condensation. In the newborn chicken cornea, fibronectin was present only in Descemets membrane. In addition, the embryonic vitreous body had a network of fibronectin-containing material. The distribution of fibronectin in the developing cornea, as well as other data available on this glycoprotein, is consistent with the proposed role of fibronectin in positioning and migration of cells and in organization of the extracellular matrix.

The origin of the glomerular endothelium.

The origin of the glomerular endothelium has remained unsettled, although it has mostly been assumed that it is derived from the metanephric mesenchyme, like, the other parts of the nephron. Since our recent observations did not support this concept, the development of the vasculature of the kidney and of the glomerular endothelium was studied using both mouse/quail and quail/chick interspecies grafts. Undifferentiated 11-day mouse kidney anlagen were transplanted onto quail chorioallantoic membrane and allowed to develop for 7-10 days. Upon examination, grafts were well-vascularized, and both the glomerular and the vessel endothelium expressed the quail nuclear marker. Similar results were obtained in quail/chick transplantation experiments. Hence, we suggest that the endothelium of the glomeruli is derived from outside vasculature rather than by conversion of cells in the nephrogenic mesenchyme.

In vitro segregation of the metanephric nephron

Abstract In vitro segregation of the metanephric nephron was examined using three probes for the main segments: fluorochrome-conjugated wheat germ agglutinin (WGA) binding to the glomerular epithelial surface, an antiserum against the brush-border antigens (BB) of the proximal tubules, and an antiserum against the Tamm-Horsfall glycoprotein (TH) of the distal tubules. In vivo , these markers appeared sequentially on Days 13 to 15. The same sequence was obtained in experimental recombinants of the metanephric mesenchyme and its inductor. When the inductor was removed after a 24 hr initial transfilter contact with the mesenchyme, segregation was similarly observed after subculture of the isolated mesenchyme. Hence, the sequential, multiphase differentiation of the nephron is initiated during a short induction period.

Transient expression of syndecan in mesenchymal cell aggregates of the embryonic kidney

Induction of the embryonic kidney mesenchyme is followed by formation of cell aggregates which subsequently transform into epithelial tubules. Syndecan, which binds various matrix components and growth factors, is a candidate molecule to be involved in this process. We have analyzed the changes in the expression of syndecan during tubule morphogenesis by using in situ hybridization and slot-blot analysis. The expression pattern of syndecan was compared with the distribution of cell proliferation analyzed by immunohistochemistry. Furthermore, the expression of syndecan during formation of the pretubular aggregates was studied in hanging-drop cultures of experimentally induced mesenchymal cells. Syndecan mRNA was expressed in the metanephric mesenchyme prior to induction, was intensely present during formation of the pretubular cell aggregates, but was lost during maturation of the nephron. Slot-blot analyses of the kidney mesenchymes (11-day kidney) cultured in a transfilter situation with a heterotypic inductor tissue that triggers a complete tubulogenic program in the nephric mesenchyme during the first 24 hr suggested the presence of syndecan mRNA in the uninduced mesenchymes with no change during induction. Expression of mRNA was stimulated later (13-day kidney) followed by subsequent decrease. Immunoisolation of sulfate-labeled syndecan, however, revealed a marked stimulation in the induced kidney mesenchyme during the first 24-hr inductive period when the DNA level still remained constant. In hanging-drop cultures where either induced or uninduced mesenchymal cells were dissociated and reaggregated, syndecan was detected only in the induced and aggregating mesenchymal cells. Double-immunostaining demonstrated a close correlation between syndecan expression and cell proliferation analyzed by bromodeoxyuridine incorporation. Thus, it appears that syndecan expression in the mesenchyme is initially induced post-transcriptionally and later during differentiation at the mRNA level. Syndecan may have a dual function during early kidney morphogenesis; it may be involved in cell aggregation through its adhesive properties, and it may contribute to proliferation of the induced mesenchymal cells by binding growth factors.

Morphogenetic Interaction of Presumptive Neural and Mesodermal Cells Mixed in Different Ratios

Cells of the presumptive forebrain region and axial mesoderm of Triturus neurulae were disaggregated and combined in different ratios. The differentiation of the central nervous systen in these explants was dependent on the relative amount of mesodermal cells present: an increase of mesodermal cells resulted in a corresponding increase in the frequency with which caudal structures of the central nervous system developed and a gradual loss of the forebrain formations.