Experimental Studies on Hemopoiesis in the Pronephros of Rana pipiens

Embryogenesis of hemopoietic cell populations in the pronephros of Rana pipiens was examined during embryonic and early larval development. Differential cell counts of Wright-Giemsa-stained cell suspensions demonstrated that granulopoiesis is the predominant hemopoietic activity in the pronephros, erythropoiesis accounts for a minor component of the hemopoietic activity (> 10%), and lymphopoiesis within the organ is negligible. Microdensitometric analysis of Feulgen-DNA stained granulocyte populations in pronephroses from larvae that had received chromosomally labeled pronephric anlagen transplants between 84 and 96 h of development demonstrated that hemopoiesis in this organ is dependent on colonization by an extrinsic hemopoietic stem cell. A similar analysis of pronephric hemopoiesis in larvae which had received chromosomally labeled, presumptive ventral blood island transplants between 62 and 67 h of development, indicates that granulopoietic cells are not derived from the embryonic blood islands. It is proposed that the pronephros may be the initial site of granulocyte differentiation during early embryogenesis. Although the embryonic origin of the hemopoietic stem cell is unknown, indirect evidence from this study indicates a dorsal stem cell compartment     

Experimental analysis of hematopoietic cell development in the liver of larval Rana pipiens.

Hematopoietic cell development in the liver of Rana pipiens throughout the larval period was examined. Differential counts of Wright/Giemsa-stained cell suspensions demonstrated that hepatic hematopoiesis includes lymphoid, myeloid, and erythroid cell lineages. Hematopoietic activity appeared to be initiated near the end of embryonic development (Shumway stages 24–25) and reached a substantial level by 30 days of development (Taylor and Kollros stage IV). Although lymphopoiesis became highly variable during later larval stages, granulopoiesis remained stable and erythropoiesis increased throughout the larval period. Erythropoiesis is the predominant hematopoietic activity in the larval liver. Histological examination of plastic embedded tissue demonstrated that hematopoietic activity is localized in discrete foci within the endothelial-lined sinusoids. These hematopoietic foci are found in both the subcapsular region and deeper portions of the organ. Microdensitometric analysis of experimental embryos which received chromosomally labeled presumptive ventral blood island transplants at Shumway stage 15 indicated that the derivatives of this embryonic region are limited to the circulating erythrocyte population of the early larvae. The hematopoietic cell populations of the liver appear to be derived from an extrinsic stem cell source which may be located in the dorsal region of the early embryo.     

Differentiation of hematopoietic cells in explants of embryonal organs of Rana temporaria L]

The potencies of isolated embryonic hemopoietic organs (pronephros and liver) of Rana temporaria L. to the formation of the foci of hemopoiesis were studied. The pronephros and liver rudiments were explanted at the early developmental stages (late neurula and early tail bud) and cultivated in vivo in the diffusion chambers. The blast hemopoietic elements and differentiated blood cells are found in the explants within 7 to 10 days of cultivation. A suggestion is put forward that the differentiation of hemopoietic cells in the embryonic hemopoietic organs proceeds from the local cells-precursors.     

Differential contribution of dorsal and ventral lateral plate mesoderm to hemopoiesis during Rana pipiens embryogenesis

Data obtained from studies on the origin and development of hemopoietic cells in several classes of vertebrate embryos argue for two distinct sources of hemopoietic cells, the intraembryonic dorsal lateral plate and the extraembryonic ventral blood island/yolk sac. In the present study, a stage by stage comparison of the hemopoietic potential of both of these regions was made during development of the frog, Rana pipiens. Either dorsal lateral plate or ventral blood island mesoderm was reciprocally transplanted between cytogenetically labeled triploid and diploid embryos. The ratio of donor-derived cells to host-derived cells (labeling index) was determined from Feulgen-stained DNA measurements of cells harvested from hemopoietic organs of young larvae. Blood island transplants consistently resulted in larvae with positive labeling of the circulating blood. Transplanted dorsal mesoderm supplied mesonephric granulocytes and thymocytes, but not circulating erythrocytes to larvae. However, the contribution of dorsal mesoderm to larval hemopoiesis fluctuated with respect to embryonic stage at transplantation.     

Towards a molecular anatomy of the Xenopus pronephric kidney.

Kidney development is distinguished by the sequential formation of three structures of putatively equivalent function from the intermediate mesoderm, the pronephros, mesonephros, and metanephros. While these organs differ morphologically, their basic structural organization exhibits important similarities. The earliest form of the kidney, the pronephros, is the primary blood filtration and osmoregulatory organ of fish and amphibian larvae. Simple organization and rapid formation render the Xenopus pronephric kidney an ideal model for research on the molecular and cellular mechanisms dictating early kidney organogenesis. A prerequisite for this is the identification of genes critical for pronephric kidney development. This review describes the emerging framework of genes that act to establish the basic components of the pronephric kidney: the corpuscle, tubules, and the duct. Systematic analysis of marker gene expression, in temporal and spatial resolution, has begun to reveal the molecular anatomy underlying pronephric kidney development. Furthermore, the emerging evidence indicates extensive conservation of gene expression between pronephric and metanephric kidneys, underscoring the importance of the Xenopus pronephric kidney as a simple model for nephrogenesis. Given that Xenopus embryos allow for easy testing of gene function, the pathways that direct cell fate decisions in the intermediate mesoderm to make the diverse spectrum of cell types of the pronephric kidney may become unraveled in the future.     

Morphological peculiarities of pronephros in Russian sturgeon, Acipenser gueldenstaedtii Brandt (order acipenseriformes, family acipenseridae)

The structure of the pronephros in Russian sturgeon larvae, Acipenser gueldenstaedtii Brandt, at different stages of early postembryonic development (from hatching till 14 days old), was studied with histological and electron microscopy methods. The formed pronephros is represented by a system of bilaterally located pronephric tubules and an external single glomus, which is not integrated directly into pronephric tubules and is located in closed pronephric chamber. The glomus is positioned below the dorsal aorta and is vascularized by its capillaries. The thin structure of the glomus has the same characteristic features that are typical of and needed for the functions of any filtering organ. By the time when larvae transfer fully to exogenous feeding, the pronephros undergoes significant degradation and it is replaced by the mesonephric kidney which develops during the period of function of the pronephros. The peculiarities of the pronephros in acipenserids are discussed comparatively with the same organ in teleosts and amphibians.     

Collectrin/tmem27 is expressed at high levels in all segments of the developing Xenopus pronephric nephron and in the Wolffian duct

Collectrin/tmem27 encodes a transmembrane protein that plays a critical role in amino-acid transport. Originally described as being expressed only in collecting ducts, it has subsequently also been shown to also be expressed in the S1 segment of the proximal tubule of mammalian metanephric nephrons. In this report we describe the expression of collectrin in the simple embryonic kidney of amphibians, the pronephros. Each pronephros contains a single large nephron with a proximo-distal segmentation very similar to that of mammalian metanephric nephrons. Analysis of collectrin expression in pronephroi at a variety of embryonic stages indicates that this gene is expressed at very high levels throughout the pronephric system, including proximal and distal segments and the Wolffian duct. Expression in the pronephros commences at Xenopus embryonic stage 28 which corresponds to when epithelialization begins within the pronephric mesenchyme. Like the Na+K+ATPase/atp1a1, another highly expressed pronephric marker, collectrin is also expressed in the cloaca but not in the cloacal derived posterior segment of the Wolffian duct, the rectal diverticulum. Unlike the Na+K+ATPase, which is expressed at lower levels in proximal portions of the pronephric nephron, expression of collectrin is even throughout all of the pronephric epithelia. This expression domain extends far beyond that shown to express amino-acid transporters and indicates collectrin may function in facilitating additional transport processes. Its high level of expression and broad distribution make it an excellent marker with which to examine pronephric kidney development.     

FGF is essential for both condensation and mesenchymal-epithelial transition stages of pronephric kidney tubule development

The pronephros is a transient embryonic kidney that is essential for the survival of aquatic larvae. It is also absolutely critical for adult kidney development, as the pronephric derivative the wolffian duct forms the ductal system of the adult kidney and also triggers the condensation of metanephric mesenchyme into the adult nephrons. While exploring Xenopus pronephric patterning, we observed that epidermally delivered hedgehog completely suppresses pronephric kidney tubule development but does not effect development of the pronephric glomus, the equivalent of the mammalian glomerulus or corpuscle. This effect is not mediated by apoptosis. Microarray analysis of microdissected primordia identified FGF8 as one of the potential mediators of hedgehog action. Further investigation demonstrated that SU5402-sensitive FGF signaling plays a critical role in the very earliest stages of pronephric tubule development. Modulation of FGF8 activity using a morpholino has a later effect that blocks condensation of pronephric mesenchyme into the pronephric tubule. Together, these data show that FGF signaling plays a critical role at two stages of embryonic kidney development, one in the condensation of the pronephric primordium from the intermediate mesoderm and a second in the later epithelialization of this mesenchyme into the pronephric nephron. The data also show that in Xenopus, development of the glomus/glomerulus can be uncoupled from nephron formation via ectopic hedgehog expression and provides an experimental avenue for investigating glomerulogenesis in the complete absence of tubules.     

Embryonic Sources of Definitive Hemopoietic Stem Cells

A review of one of the key problems of experimental hematology: the origin of hemopoietic stem cells in the development of vertebrates (amphibians, birds, and mammals). The appearance and functioning of two independent sources of hemopoietic stem cells (extra- and intraembryonic) were considered in amphibians, birds, and mammals. The contribution of each source to the formation of definitive hemopoietic tissue was analyzed. It was shown for amphibians and birds that intraembryonic organs such as the dorsolateral plate and the mesenchyme of dorsal aorta are involved in the formation of adult hemopoietic tissue, while the extraembryonic organs such as ventral islets and the yolk sac are devoid of true stem cells and provide only for the primary, transient hemopoiesis. New data have been considered concerning the previously unknown intraembryonic hemopoietic organ in mammals, a region of aorta–gonad–mesonephros arising in embryogenesis simultaneously with the yolk sac. Two extreme views on the involvement of stem cells of all these organs in the formation of definitive hemopoiesis have been considered. The data are provided on the interaction of the embryonic hemopoietic stem cells and the hemopoietic microenvironment of adult recipients.     

In vitro induction of the pronephric duct in Xenopus explants

The earliest form of embryonic kidney, the pronephros, consists of three components: glomus, tubule and duct. Treatment of the undifferentiated animal pole ectoderm of Xenopus laevis with activin A and retinoic acid (RA) induces formation of the pronephric tubule and glomus. In this study, the rate of induction of the pronephric duct, the third component of the pronephros, was investigated in animal caps treated with activin A and RA. Immunohistochemistry using pronephric duct-specific antibody 4A6 revealed that a high proportion of the treated explants contained 4A6-positive tubular structures. Electron microscopy showed that the tubules in the explants were similar to the pronephric ducts of normal larvae, and they also expressed Gremlin and c-ret, molecular markers for pronephric ducts. These results suggest that the treatment of Xenopus ectoderm with activin A and RA induces a high rate of differentiation of pronephric ducts, in addition to the differentiation of the pronephric tubule and glomus, and that this in vitro system can serve as a simple and effective model for analysis of the mechanism of pronephros differentiation.     

Haemopoietic centres in the developing angelfish,Pterophyllum scalare (cuvier and valenciennes)

Summary The first haemopoietic centres in the embryo ofPterophyllum scalare are found in the blood islands of the yolk sac. These results are in contrast to the classical theory of blood formation in teleosts, which maintains that the first blood formation occurs intraembryonically, in the so-called intermediate cell mass of Oellacher. InPterophyllum, the intermediate cell mass forms only the axial blood vessels. Haemopoiesis in the post-embryo is carried out by the pronephros. This organ remains haemopoietic to the adult stage. In the adult, the pronephric tubules are degenerated; the organ is filled with haemopoietic tissue and also contains strands of adrenal tissue. The adult kidney (mesonephros) is also haemopoietic, though to a much lesser degree than the pronephros.The blood islands in the yolk sac form only stem cells (haemocytoblasts) and proerythroblasts. Released into the circulation, they differentiate and mature into round, disc-like erythrocytes (erythrocytes-E). Erythropoiesis in the pronephros produces elliptical erythrocytes (erythrocytes-ImA). Thus for the latter part of the postembryonic phase, until complete absorption of the yolk, there is a mixed erythrocyte population in circulation. During metamorphosis into the laterally-compressed adult, the adult type of erythrocyte (erythrocyte-A) makes its first appearance. Leucocytes and thrombocytes appear much later in development than the red blood cells. They are formed in the pronephros and are seen in circulation only after the yolk has been absorbed.     

Development of an Automated Imaging Pipeline for the Analysis of the Zebrafish Larval Kidney

The analysis of kidney malformation caused by environmental influences during nephrogenesis or by hereditary nephropathies requires animal models allowing the in vivo observation of developmental processes. The zebrafish has emerged as a useful model system for the analysis of vertebrate organ development and function, and it is suitable for the identification of organotoxic or disease-modulating compounds on a larger scale. However, to fully exploit its potential in high content screening applications, dedicated protocols are required allowing the consistent visualization of inner organs such as the embryonic kidney. To this end, we developed a high content screening compatible pipeline for the automated imaging of standardized views of the developing pronephros in zebrafish larvae. Using a custom designed tool, cavities were generated in agarose coated microtiter plates allowing for accurate positioning and orientation of zebrafish larvae. This enabled the subsequent automated acquisition of stable and consistent dorsal views of pronephric kidneys. The established pipeline was applied in a pilot screen for the analysis of the impact of potentially nephrotoxic drugs on zebrafish pronephros development in the Tg(wt1b:EGFP) transgenic line in which the developing pronephros is highlighted by GFP expression. The consistent image data that was acquired allowed for quantification of gross morphological pronephric phenotypes, revealing concentration dependent effects of several compounds on nephrogenesis. In addition, applicability of the imaging pipeline was further confirmed in a morpholino based model for cilia-associated human genetic disorders associated with different intraflagellar transport genes. The developed tools and pipeline can be used to study various aspects in zebrafish kidney research, and can be readily adapted for the analysis of other organ systems.     

Effect of the lining of the thymus gland on hematopoietic stem cell kinetics in a suspension of embryonic mouse liver]

A study was made of the kinetics of hemopoietic stem cells in the organic culture of a suspension of mouse embryonic liver cultivated directly on the filters and on the preliminarily grown embryonic thymic feeder. It was shown that stem hemopoietic cells were retained in the course of one month of cultivation in the embryonic liver suspensions; during the first two weeks hemopoiesis in the suspension practically failed to differ from such in the fragments of the same age and cultivation period, whereas during the subsequent periods hemopoiesis proved to be more active in the suspension cultivated on thymic feeder. A possible participation of the thymus in the hemopoiesis is discussed.     

Pescadillo homologue 1 and Peter Pan function during Xenopus laevis pronephros development

Background information. pes1 (pescadillo homologue 1) and ppan (Peter Pan) are multifunctional proteins involved in ribosome biogenesis, cell proliferation, apoptosis, cell migration and regulation of gene expression. Both proteins are required for early neural development in Xenopus laevis, as previously demonstrated. Results. We show that the expression of both genes in the developing pronephros depends on wnt4 and fzd3 (frizzled homologue 3) function. Loss of pes1 or ppan by MO (morpholino oligonucleotide)‐based knockdown approaches resulted in strong malformations during pronephric tubule formation. Defects were already notable during specification of pronephric progenitor cells, as shown by lhx1 expression. Moreover, we demonstrated that Xenopus pes1 and ppan interact physically and functionally and that pes1 and ppan can cross‐rescue the loss of function phenotype of one another. Interference with rRNA synthesis, however, did not result in a similar early pronephros phenotype. Conclusion. These results demonstrate that pes1 and ppan are required for Xenopus pronephros development and indicate that their function in the pronephros is independent of their role in ribosome biosynthesis.