Eya1 is required for the morphogenesis of mammalian thymus,parathyroid and thyroid

Eyes absent (Eya) genes regulate organogenesis in both vertebrates and invertebrates. Mutations in human EYA1 cause congenital Branchio-Oto-Renal (BOR) syndrome, while targeted inactivation of murine Eya1 impairs early developmental processes in multiple organs, including ear, kidney and skeletal system. We have now examined the role of Eya1 during the morphogenesis of organs derived from the pharyngeal region, including thymus, parathyroid and thyroid. The thymus and parathyroid are derived from 3rd pharyngeal pouches and their development is initiated via inductive interactions between neural crest-derived arch mesenchyme, pouch endoderm, and possibly the surface ectoderm of 3rd pharyngeal clefts. Eya1 is expressed in all three cell types during thymus and parathyroid development from E9.5 and the organ primordia for both of these structures failed to form in Eya1(-/-) embryos. These results indicate that Eya1 is required for the initiation of thymus and parathyroid gland formation. Eya1 is also expressed in the 4th pharyngeal region and ultimobranchial bodies. Eya1(-/-) mice show thyroid hypoplasia, with severe reduction in the number of parafollicular cells and the size of the thyroid lobes and lack of fusion between the ultimobranchial bodies and the thyroid lobe. These data indicate that Eya1 also regulates mature thyroid gland formation. Furthermore, we show that Six1 expression is markedly reduced in the arch mesenchyme, pouch endoderm and surface ectoderm in the pharyngeal region of Eya1(-/-) embryos, indicating that Six1 expression in those structures is Eya1 dependent. In addition, we show that in Eya1(-/-) embryos, the expression of Gcm2 in the 3rd pouch endoderm is undetectable at E10.5, however, the expression of Hox and Pax genes in the pouch endoderm is preserved at E9.5-10.5. Finally, we found that the surface ectoderm of the 3rd and 4th pharyngeal region show increased cell death at E10.5 in Eya1(-/-) embryos. Our results indicate that Eya1 controls critical early inductive events involved in the morphogenesis of thymus, parathyroid and thyroid.     

Localised inhibition of FGF signalling in the third pharyngeal pouch is required for normal thymus and parathyroid organogenesis

The thymus and parathyroid glands are derived from the third pharyngeal pouch endoderm. The mechanisms that establish distinct molecular domains in the third pouch and control the subsequent separation of these organ primordia from the pharynx are poorly understood. Here, we report that mouse embryos that lack two FGF feedback antagonists, Spry1 and Spry2, display parathyroid and thymus hypoplasia and a failure of these organ primordia to completely separate from the pharynx. We show that FGF ligands and downstream reporter genes are expressed in highly regionalised patterns in the third pouch and that sprouty gene deletion results in upregulated FGF signalling throughout the pouch endoderm. As a consequence, the initiation of markers of parathyroid and thymus fate is altered. In addition, a normal apoptotic programme that is associated with the separation of the primordia from the pharynx is disrupted, resulting in the maintenance of a thymus-pharynx attachment and a subsequent inability of the thymus to migrate to its appropriate position above the heart. We demonstrate that the sprouty genes function in the pharyngeal endoderm itself to control these processes and that the defects in sprouty-deficient mutants are, at least in part, due to hyper-responsiveness to Fgf8. Finally, we provide evidence to suggest that parathyroid hypoplasia in these mutants is due to early gene expression defects in the third pouch, whereas thymus hypoplasia is caused by reduced proliferation of thymic epithelial cells in the thymus primordium.     

Patterning of the third pharyngeal pouch into thymus/parathyroid by Six and Eya1

Previous studies have suggested a role of the homeodomain Six family proteins in patterning the developing vertebrate head that involves appropriate segmentation of three tissue layers, the endoderm, the paraxial mesoderm and the neural crest cells; however, the developmental programs and mechanisms by which the Six genes act in the pharyngeal endoderm remain largely unknown. Here, we examined their roles in pharyngeal pouch development. Six1-/- mice lack thymus and parathyroid and analysis of Six1-/- third pouch endoderm demonstrated that the patterning of the third pouch into thymus/parathyroid primordia is initiated. However, the endodermal cells of the thymus/parathyroid rudiments fail to maintain the expression of the parathyroid-specific gene Gcm2 and the thymus-specific gene Foxn1 and subsequently undergo abnormal apoptosis, leading to a complete disappearance of organ primordia by E12.5. This thus defines the thymus/parathyroid defects present in the Six1 mutant. Analyses of the thymus/parathyroid development in Six1-/-;Six4-/- double mutant show that both Six1 and Six4 act synergistically to control morphogenetic movements of early thymus/parathyroid tissues, and the threshold of Six1/Six4 appears to be crucial for the regulation of the organ primordia-specific gene expression. Previous studies in flies and mice suggested that Eya and Six genes may function downstream of Pax genes. Our data clearly show that Eya1 and Six1 expression in the pouches does not require Pax1/Pax9 function, suggesting that they may function independently from Pax1/Pax9. In contrast, Pax1 expression in all pharyngeal pouches requires both Eya1 and Six1 function. Moreover, we show that the expression of Tbx1, Fgf8 and Wnt5b in the pouch endoderm was normal in Six1-/- embryos and slightly reduced in Six1-/-;Six4-/- double mutant, but was largely reduced in Eya1-/- embryos. These results indicate that Eya1 appears to be upstream of very early events in the initiation of thymus/parathyroid organogenesis, while Six genes appear to act in an early differentiation step during thymus/parathyroid morphogenesis. Together, these analyses establish an essential role for Eya1 and Six genes in patterning the third pouch into organ-specific primordia.     

Thymic medullary structures: Microscopical picture of the thymic medullary structures in children with congenital heart defects

The aim of this work is to describe the structure of the thymus, especially its medullary part, in children with congenital heart defects. It is known that development of the thymus and the heart is also influenced by neural crest cells. During the early development of the heart and the thymus cells proliferate and migrate to their primordia. It is known that inadequate cephalic neural crest contribution during development of pharyngeal pouch derivatives results in defective organogenesis of the face, the thymus, parathyroid glands and also the heart. We studied the structure of the thymus in children with congenital heart defects from 0 to 12 years of life at light microscopic and electron-microscopic levels. Thymuses of the patients were surgically removed in the Children’s Cardiocenter in Bratislava. The results of our study confirmed the differences in the medullary structures of thymuses with chosen diagnoses. Hassall’s corpuscles in the thymic medulla were various in size and also in structure and number. The special structures of the thymic medullary region in children with ventricular septal defects and defects of outflow of the heart were big cystic Hassall’s corpuscles. In comparison with a size of Hassall’s corpuscles in normal thymuses the size of Hassall’s corpuscles in studied thymuses suprisingly ranged between 100–250 μm.     

Increased thymus- and decreased parathyroid-fated organ domains in Splotch mutant embryos

Embryos that are homozygous for Splotch, a null allele of Pax3, have a severe neural crest cell (NCC) deficiency that generates a complex phenotype including spina bifida, exencephaly and cardiac outflow tract abnormalities. Contrary to the widely held perception that thymus aplasia or hypoplasia is a characteristic feature of Pax3^Sp/Sp embryos, we find that thymic rudiments are larger and parathyroid rudiments are smaller in E11.5-12.5 Pax3^Sp/Sp compared to Pax3^+/+ embryos. The thymus originates from bilateral third pharyngeal pouch primordia containing endodermal progenitors of both thymus and parathyroid glands. Analyses of Foxn1 and Gcm2 expression revealed a dorsal shift in the border between parathyroid- and thymus-fated domains at E11.5, with no change in the overall cellularity or volume of each shared primordium. The border shift increases the allocation of third pouch progenitors to the thymus domain and correspondingly decreases allocation to the parathyroid domain. Initial patterning in the E10.5 pouch was normal suggesting that the observed change in the location of the organ domain interface arises during border refinement between E10.5 and E11.5. Given the well-characterized NCC defects in Splotch mutants, these findings implicate NCCs in regulating patterning of third pouch endoderm into thymus- versus parathyroid-specified domains, and suggest that organ size is determined in part by the number of progenitor cells specified to a given fate.     

Abnormalities of caudal pharyngeal pouch development in Pbx1 knockout mice mimic loss of Hox3 paralogs

Pbx1 is a TALE-class homeodomain protein that functions in part as a cofactor for Hox class homeodomain proteins. Previous analysis of the in vivo functions of Pbx1 by targeted mutagenesis in mice has revealed roles for this gene in skeletal patterning and development and in the organogenesis of multiple systems. Both RNA expression and protein localization studies have suggested a possible role for Pbx1 in pharyngeal region development. As several Hox mutants have distinct phenotypes in this region, we investigated the potential requirement for Pbx1 in the development of the pharyngeal arches and pouches and their organ derivatives. Pbx1 homozygous mutants exhibited delayed or absent formation of the caudal pharyngeal pouches, and disorganized patterning of the third pharyngeal pouch. Formation of the third pouch-derived thymus/parathyroid primordia was also affected, with absent or hypoplastic primordia, delayed expression of organ-specific differentiation markers, and reduced proliferation of thymic epithelium. The fourth pouch and the fourth pouch-derived ultimobranchial bodies were usually absent. These phenotypes are similar to those previously reported in Hoxa3(-/-) single mutants and Hoxa1(-/-);Hoxb1(-/-) or Hoxa3(+/-);Hoxb3(-/-);Hoxd3(-/-) compound mutants, suggesting that Pbx1 acts together with multiple Hox proteins in the development of the caudal pharyngeal region. However, some aspects of the Pbx1 mutant phenotype included specific defects that were less severe than those found in known Hox mutant mice, suggesting that some functions of Hox proteins in this region are Pbx1-independent.     

Bmp4 and Noggin expression during early thymus and parathyroid organogenesis

The thymus and parathyroids originate from the third pharyngeal pouches, which form as endodermal outpocketings in the pharyngeal region beginning on embryonic day 9 (E9.0) of mouse development. Using organ-specific markers, we have previously shown that thymus and parathyroid-specific organ domains are established within the primordium prior to formation of the organs proper: Gcm2 expression defines the prospective parathyroid cells in the dorsal pouch from E9.5, while Foxn1 is expressed in the thymus domain from E11.25. Bmp (bone morphogenetic protein) signaling has been implicated in thymic epithelial cell differentiation and thymus organogenesis. In the present study, we report expression patterns of Bmp4 and Noggin, a Bmp4 antagonist, in the third pharyngeal pouch using two lacZ transgenic mouse strains. Results from this gene expression study revealed localization of Bmp4 expression to the ventral region of the third pharyngeal pouch endoderm at E10.5 and E11.5, in those cells that will express Foxn1 and form the thymus. Conversely, the expression of Noggin was confined to the dorsal region of the pouch and primordium at these stages, and thus appeared to be co-expressed with Gcm2 in the parathyroid domain. This represents the first detailed study of Bmp4 and Noggin expression during the early stages of thymus and parathyroid organogenesis.     

Localization and volume of the derivatives of the prechordal plate of the cephalic gut in vertebrates]

In order to determine the localization and volume of the prechordal lamina derivatives the initial stages of histogenesis of the cephalic gut epithelium lining were studied in embryos of chickens and mammals (rabbits, rats, mice) in early terms of the formation of the fore-part of their digestive tube. It has been established that the derivatives characteristics of the prechordal lamina such as the cephalic end of the chordal, larval mesodermal somites, are formed by the real enterocelic means only from the entodermal epithelium of the Seessel's pouch walls which is the most cranial end of the cephalic gut. In other parts of the dorsal wall of the pharynx, the more of the oesophagus, the prechordal lamina derivatives fail to be determined. This fact shows that the localization of the prechordal lamina coincides with the disposition of the Seessel's pouch lining, the histological nature of its material being identical to the entoderm.     

Altersabhängige Veränderungen im histochemischen Reaktionsmuster des Thymus bei Wistar-Ratten

Zusammenfassung Makrophagen und entodermale Retikulumzellen samt Ausläufern lassen sich im Thymus der Wistar-Ratte durch den histochemischen Nachweis der sauren Phosphatase und der unspezifischen Esterase selektiv darstellen, während die Lymphozyten nicht reagieren.Häufigkeit und Verteilung der Retikulumzellen und Makrophagen lassen altersabhängige Unterschiede erkennen: Auf Kosten der Retikulumzellen nimmt die Zahl der Makrophagen mit fortschreitendem Lebensalter zu. Bei geschlechtsreifen Tieren bilden sie einen Wall an der Mark-Rinden-Grenze.Die Bedeutung der sauren Phosphatase in entodermalen Retikulumzellen wird unter der Annahme diskutiert, daß es sich um lysosomengebundenes Ferment handelt. Lysosomen sind im involvierenden Thymus wahrscheinlich an autolytischen oder phagozytotischen Prozessen beteiligt. Es stellt sich die Frage, ob Lysosomen in entodermalen Retikulumzellen des Thymus neugeborener Tiere in die Abgabe einer humoral wirksamen Substanz eingreifen können.

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Age dependent histochemical changes in the thymus of the Wistar rat

Summary Macrophages and entodermal reticulum cells in the thymus of Wistar rats contrast by their rich contents of acid phosphatase and unspecific esterase activity with the negativ reacting lymphocytes.Frequency and distribution of the cells vary according to different stages of age: at cost of the entodermal reticular cells the number of macrophages increases with progressive age. In sexually mature animals they form a typical layer at the corticomedullary junction.The functional meaning of acid phosphatase in the entodermal reticulum cells is discussed under the assumption that this enzyme is lysosomebound. In the involuting thymus lysosomes are involved in autolytic or phagocytic processes.The question arises wether lysosomes in entodermal reticulum cells in the thymus of newborn animals can take part in the control of an humoral function of the thymus.

     

Effects of excess vitamin A on development of cranial neural crest-derived structures: a neonatal and embryologic study

BACKGROUND: Vitamin A and its metabolites have been shown to be teratogenic in animals and humans producing defects of neural crest derived structures that include abnormalities of the craniofacial skeleton, heart, and thymus. Our prior studies with retinoic acid have established that gestational day (gd) 9 is a sensitive embryonic age in the mouse for inducing craniofacial and thymic defects. METHODS: We exposed pregnant mice to variable doses of vitamin A (retinyl acetate) on gd 9 and embryos were evaluated for changes in developing pharyngeal arch and pouch morphology, neural crest cell migration and marker gene expression. Additionally, we investigated whether a single organ system was more sensitive to low doses of vitamin A and could potentially be used as an indicator of vitamin A exposure during early gestation. RESULTS: High (100 mg/kg) and moderate (50 and 25 mg/kg) doses of vitamin A resulted in significant craniofacial, cardiac outflow tract and thymic abnormalities. Low doses of vitamin A (10 mg/kg) produced craniofacial and thymic abnormalities that were mild and of low penetrance. Exposed embryos showed morphologic changes in the 2nd and 3rd pharyngeal arches and pouches, changes in neural crest migration, abnormalities in cranial ganglia, and altered expression of Hoxa3. CONCLUSIONS: These animal studies, along with recent epidemiologic reports on human teratogenicity with vitamin A, raise concerns about the potential for induction of defects (perhaps subtle) in offspring of women ingesting even moderate to low amounts of supplemental vitamin A during the early gestational period.     

Morphology of a newly discovered sensory array on the mouthhooks of Gasterophilus larvae

The distal mouthhooks of Gasterophilus intestinalis (DeGeer) (Diptera: Gasterophilidae) and G. nasalis (Linnaeus) (Diptera: Gasterophilidae) larvae were studied with scanning electron microscopy to determine the morphology of a previously unknown sensory array. The design of the 3rd stage G. intestinalis sensory array was used as the model for comparison to the 2nd stage of this species and the 2nd and 3rd stadia of G. nasalis. Some components forming the sensory array of the 3rd stage G. intestinalis mouthhook were found in 3rd stage G. nasalis. A major difference between these species was the replacement of shallow pits with sensilla-laden troughs in G. nasalis. Second-stage G. intestinalis has a distal mouthhook that varies considerably from the model type, lacking shallow pits and associated peg-like sensilla. By contrast, the sensory array of the 2nd stage G. nasalis larva is the most elaborate yet encountered, with extensive sensilla and troughs. The existence of other types of sensilla on the mouthhook is proposed, as well as a sensory role for the unsculptured surface. Possible uses of the sensory array by the parasite are discussed.     

Metamorphic changes in the hindgut of Sarcophaga ruficornis with special reference to the development of rectal pads

In Sarcophaga ruficornis, during normal metamorphosis the larval hindgut epithelium degenerates and the imaginal hindgut epithelium is formed from the proliferation and differentiation of the cells of the posterior imaginal ring. The newly formed hindgut becomes slightly dilated posteriorly to form the rectal pouch. At four places in this pouch, the epithelium becomes thick and forms the primordia of the rectal pads. The cells in the primordia begin to divide and project into the lumen of the pouch and later form the cortex cells of the rectal pads. The cavity of the primordia becomes filled with blood cells and fibrous material, which give rise to the medulla of the rectal pads.     

Activity of lysosomal hydrolases in human placenta, amnion, decidua and myometrium in the 2nd and 3rd trimester

Six lysosomal hydrolases were studied in tissues of human placenta, amnion, decidua, and myometrium obtained in the 2nd and 3rd trimester. No significant increase in the activity of any lysosomal hydrolase was found in the 3rd-trimester values compared with those obtained in the 2nd trimester. Thus, the increased activity of lysosomal hydrolases in maternal serum at term, previously described in several studies, seems not to be paralleled by a corresponding increase in the activity of these enzymes in the tissues of the pregnant uterus. We speculate that the increase in maternal serum towards term may reflect a macrophage activation initiated by elevated estrogen concentrations in the 3rd trimester.     

Constraint on di-nucleotides by codon usage bias in bacterial genomes

It has been reported earlier that the relative di-nucleotide frequency (RDF) in different parts of a genome is similar while the frequency is variable among different genomes. So RDF is termed as genome signature in bacteria. It is not known if the constancy in RDF is governed by genome wide mutational bias or by selection. Here we did comparative analysis of RDF between the inter-genic and the coding sequences in seventeen bacterial genomes, whose gene expression data was available. The constraint on di-nucleotides was found to be higher in the coding sequences than that in the inter-genic regions and the constraint at the 2nd codon position was more than that in the 3rd position within a genome. Further analysis revealed that the constraint on di-nucleotides at the 2nd codon position is greater in the high expression genes (HEG) than that in the whole genomes as well as in the low expression genes (LEG). We analyzed RDF at the 2nd and the 3rd codon positions in simulated coding sequences that were computationally generated by keeping the codon usage bias (CUB) according to genome G+C composition and the sequence of amino acids unaltered. In the simulated coding sequences, the constraint observed was significantly low and no significant difference was observed between the HEG and the LEG in terms of di-nucleotide constraint. This indicated that the greater constraint on di-nucleotides in the HEG was due to the stronger selection on CUB in these genes in comparison to the LEG within a genome. Further, we did comparative analyses of the RDF in the HEG rpoB and rpoC of 199 bacteria, which revealed a common pattern of constraints on di-nucleotides at the 2nd codon position across these bacteria. To validate the role of CUB on di-nucleotide constraint, we analyzed RDF at the 2nd and the 3rd codon positions in simulated rpoB/rpoC sequences. The analysis revealed that selection on CUB is an important attribute for the constraint on di-nucleotides at these positions in bacterial genomes. We believe that this study has come with major findings of the role of CUB on di-nucleotide constraint in bacterial genomes.     

Hoxa3 and pax1 regulate epithelial cell death and proliferation during thymus and parathyroid organogenesis

The thymus and parathyroid glands in mice develop from a thymus/parathyroid primordium that forms from the endoderm of the third pharyngeal pouch. We investigated the molecular mechanisms that promote this unique process in which two distinct organs form from a single primordium, using mice mutant for Hoxa3 and Pax1. Thymic ectopia in Hoxa3(+/-)Pax1(-/-) compound mutants is due to delayed separation of the thymus/parathyroid primordium from the pharynx. The primordium is hypoplastic at its formation, and has increased levels of apoptosis. The developing third pouch in Hoxa3(+/-)Pax1(-/-) compound mutants initiates normal expression of the parathyroid-specific Gcm2 and thymus-specific Foxn1 genes. However, Gcm2 expression is reduced at E11.5 in Pax1(-/-) single mutants, and further reduced or absent in Hoxa3(+/-)Pax1(-/-) compound mutants. Subsequent to organ-specific differentiation from the shared primordium, both the parathyroids and thymus developed defects. Parathyroids in compound mutants were smaller at their formation, and absent at later stages. Parathyroids were also reduced in Pax1(-/-) mutants, revealing a new function for Pax1 in parathyroid organogenesis. Thymic hypoplasia at later fetal stages in compound mutants was associated with increased death and decreased proliferation of thymic epithelial cells. Our results suggest that a Hoxa3-Pax1 genetic pathway is required for both epithelial cell growth and differentiation throughout thymus and parathyroid organogenesis.