Tissue-dependent regulation of protein tyrosine kinase activity during embryonic development

Protein tyrosine kinase activity was assayed in a variety of chicken tissues during embryonic development and in the adult. In some tissues protein tyrosine kinase activity decreased during embryonic development; however, in other tissues it remained high throughout development, it contrast to the level of protein tyrosine phosphorylation, which decreased during development. The highest levels of tyrosine kinase activity were detected in 17-d embryonic brain although only low levels of protein tyrosine phosphorylation were observed in this tissue. Several alternatives were examined in an effort to determine the mechanism responsible for the low levels of tyrosine phosphorylated proteins in most older embryonic and adult chicken tissues despite the presence of highly active tyrosine kinases. The results show that the regulation of protein tyrosine phosphorylation during embryonic development is complex and varies from tissue to tissue. Furthermore, the results suggest that protein tyrosine phosphatases play an important role in regulating the level of phosphotyrosine in proteins of many older embryonic and adult tissues.     

Phenolsulphotransferase: localization in kidney during human embryonic and fetal development

Summary The aim of our study was to localize phenolsulphotransferase (PST) in the developing mesonephric and metanephric kidneys of the human embryo and fetus using immunohistochemical methods with an antibody preparation recognizing members of the human phenolsulphotransferase enzyme family. In embryonic and early fetal development of the metanephric kidney, PST is located primarily in derivatives of the ureteric bud such as the ureter, pelvis, calyces and collecting ducts. This predominance declines by mid-fetal life: first, as nephrons evolve and develop they become increasingly PST-immunoreactive such that in mature metanephric kidney, the proximal tubules are highly PST-reactive, with other elements of the nephron also immunopositive (albeit at lower reactivities) and secondly, with the formation of an immunonegative transitional epithelium in ureter, pelvis and calyces, the reactivity retained in collecting ducts is only a small proportion of the total. The distribution of PST immunoreactivity is relatively uniform in proximal tubular cells throughout development, in contrast to collecting ducts, where, in fetal life, this reactivity is displaced to apices and bases by intracellular glycogen deposits. Mesonephric kidney tubules and the mesonephric duct are PST-immunoreactive and although mesonephric immunopositivity overlaps with that in the developing metanephric kidney the renal contribution to sulphation is absent or low at a time when the developing conceptus is most vulnerable to the potential toxic effects of teratogens.     

Catalase activity and rhythmic patterns in mouse brain, kidney and liver

To protect tissues from damaging effects of reactive oxygen species (ROS), organisms possess enzymatic and non-enzymatic antioxidant systems. Cytosolic-enzyme catalase (CAT) is a component of the antioxidant defence system that reduces hydrogen peroxide (H₂O₂) to water (H₂O). The aim of this study was to assess the variation of antioxidant enzyme CAT activity in brain, kidney and liver of adult male mice according to tissue-specific and temporal patterns within a 24-h period (12:12 L/D). The CAT activity was assayed at 4-h intervals. The Cosinor test programme was used to detect and confirm the best corresponding rhythm. In liver, the circadian rhythm of CAT was associated with ultradian components. The prominent circadian rhythm (with a period τ = 24 h) showed a peak located at the middle of the dark phase, more precisely  17 HALO (Hours After Light Onset). In kidney, only a circadian rhythm of CAT was validated with a peak time located at  17 HALO. However, in brain, the time pattern of CAT activity showed two peak times at  1 and  17 HALO, illustrating the existence of an ultradian rhythm (with a period τ = 12 h). The results showed significant organ differences with the highest activity in liver, compared with kidney (− 89%) and brain (− 98%). This might be related to several factors such as their respective physiological function, the risk of exposure to oxidative damage and the balance between synthesis and degradation of proteins during “normal metabolism”. Moreover, CAT activity revealed differences in time-related changes across a 24-h period that were more obvious in peak levels between the three tissues.     

Peptide hydrolase activity during embryonic carp development]

It was established that in the carp the process of embryonic and early postembryonic development was accompanied by the increase in the activity of both the trypsin- and chemotrypsin-like peptide hydrolases. This increase is most evident in larvae with resorbing yolk. The total and protein nitrogen content suffers no changes during embryonic and early postembryonic development. The content of non-protein nitrogen increases from the stage of the middle of segmentation on attaining the maximum level in larvae with resorbing yolk.     

Tet-system for the regulation of gene expression during embryonic development

The ability to control gene expression in a temporal and spatial manner provides a new tool for the study of mammalian gene function particularly during development and oncogenesis. In this study the suitability of the tet-system for investigating embryogenesis was tested in detail. The tTA ^CMV (M1) and rTA ^CMV-3 (reverse Tc-controlled transactivator) transgenic mice were bred with NZL-2 bi-reporter mice containing the vector with a tTA/rTA responsive bidirectional promoter that allows simultaneous regulation of expression of two reporter genes encoding luciferase and -galactosidase. In both cases reporter genes were found to be expressed in a wide spectrum of tissues of double transgenic embryos and adult mice. The earliest expression was detected in tTA ^CMV (M1)/NZL-2 embryos at embryonic day 10.5 (E10.5) and rTA ^CMV -3/NZL-2 embryos at E13.5. Doxycycline abolished -gal expression in tTA ^CMV (M1)/NZL-2 but induced it in rTA ^CMV -3/NZL-2 embryos including late stages of embryogenesis. The tTA and rtTA transactivators thus revealed a partially complementary mode of action during second half of embryonic development. These experiments demonstrated that both Tet regulatory systems function during embryonic development. We conclude that the Tet systems allows regulation of gene expression during embryonic development and that double reporter animals like the NZL-2 mice are useful tools for the characterization of newly generated tet transactivator lines expressing tTA (or rtTA) in embryonic as well as in adult tissues.     

Thymidine kinase activity in cardiac muscle during embryonic and postnatal development

Cytoplasmic thymidine kinase from cardiac muscle of the rat has been characterized. It has a pH optimum of 9.0 and a K(m) value for thymidine of 1.6mum. The sedimentation coefficient of this enzyme in sucrose gradients is 4.5S, which represents a molecular weight of approx. 69000. Thymidine kinase prepared from cardiac muscle of foetal, neonatal and adult rats is inhibited by dTTP and dTDP; there is neither inhibition nor stimulation by dTMP, dCTP, dATP, dGTP or cyclic AMP. The activity of thymidine kinase in differentiating cardiac muscle of foetal and neonatal rats declines progressively with development, reaching adult values of almost zero by the fifteenth to seventeenth day of postnatal development. This represents a 70-fold decrease in enzyme activity from 3 days before birth to 17 days after birth. The loss of thymidine kinase activity in differentiating cardiac muscle correlates temporally with the cessation of DNA biosynthesis and the loss of cytoplasmic DNA polymerase activity in this tissue.     

Retinoic acid signaling in regulation of meiosis during embryonic development in mice

In the embryonic gonads of mice, the genetic and epigenetic regulatory programs for germ cell sex specification and meiosis induction or suppression are intertwined. The quest for garnering comprehensive understanding of these programs has led to the emergence of retinoic acid (RA) as an important extrinsic factor, which regulates initiation of meiosis in female fetal germ cells that have attained a permissive epigenetic ground state. In contrast, germ cells in fetal testis are protected from the exposure to RA due to the activity of CYP26B1, an RA metabolizing enzyme, which is highly expressed in fetal testis. In this review, we provide an overview of the molecular mechanisms operating in fetal gonads of mice, which enable regulation of meiosis via RA signaling.     

Acid phosphatase activity in the chick ovary during embryonic development

Acid phosphatase activity was studied in the left and right ovaries of the chick during embryonic development. The cytochemical study indicated that local enzymatic activity is localized mainly in germ and somatic cells. From the results obtained in the study on the specific activity of this acid hydrolase, it can be inferred that the higher concentration of this enzyme in the right ovary would be determined by a decrease of total proteins in the total homogenate and in the cellular fractions of this organ. Besides, a decrease in the enzymatic activity of this ovary is not observed, but it occurs in the left ovary. This finding would indicate a lack of enzymatic segregation that could be related to the phenomenon of ovarian atrophy. Finally, the electrophoretic study indicated that it would apparently exist only one molecular form of the enzyme. Our results support the hypothesis that acid phosphatase would be involved in the atrophic processes of the right ovary during embryonary differentiation.     

Fatty acid synthesis in chick embryonic heart and liver during development.

Fatty acid synthesis by subcellular fractions of heart and liver of chick embryos at varying stages of development has been studied. Fatty acid synthetase activity is associated with the embryonic heart at early stages of development, as suggested by substrate requirement, Schmidt decarboxylation of synthesized fatty acids and gas liquid chromatographic identification of the products as palmitic and stearic acids. The fatty acid synthetase activity decreases in heart cytosol with age of the embryo and is absent in the newly hatched chick and in older chicken. The acetyl CoA carboxylase activity is negligible in embryonic and adult chicken heart. The fatty acid synthetase activity in liver is low, but measurable during the entire embryonic development. The activity increases by about three-fold on hatching and thereafter in fed, newly hatched chicks by about 35-fold, over the basal embryonic activity. The acetyl and malonyl transacylase activities in the heart and liver cytosols during development followed closely the fatty acid synthetase activities in heart and liver, respectively. A non-coordinate induction of fatty acid synthetase and acetyl CoA carboxylase activities in liver was observed during development. The microsomal chain elongation in liver and heart followed the pattern of fatty acid synthetase activity in liver and heart, respectively. The mitochondrial chain elongation in embryonic heart is initially low and increases with age; while this activity in liver is higher in early stages of embryonic development than in the older embryos and the chicks. Measurement of lipogenesis from acetate-1-¹⁴C by liver and heart slices from chick embryos and newly hatched chicks support the conclusions reached in the studies with the subcellular fractions. The results obtained indicate that the major system of fatty acid synthesis in embryonic and adult heart is the mitochondrial chain elongation. In embryonic liver, fatty acid synthesis proceeds by chain elongation, while the de novo system is the major contributor to the lipogenic capacity of the liver after hatching.