Hexokinase isoenzymes in tissues of the adult and developing guinea pig

Changes in the activities and isoenzyme distribution of hexokinase were determined in a number of tissues during the development of the guinea pig. The total activity in the fetal liver showed a large fall during the second half of gestation to reach adult values by term. With normal diet the fetal, neonatal, and adult livers had isoenzymes I and III but little or no detectable IV (glucokinase). The fetal liver had predominantly type I, but the proportion of type III increased during development. The kinetics of the guinea pig isoenzymes were similar to those reported for the rat. Two additional isoenzymes with mobility between I and II were detected in the fetal liver and blood. They appear to have kinetic properties similar to type I. Detectable liver glucokinase activity was induced by glucose administration to adult guinea pigs. The total activity in kidney, brain and skeletal muscle showed a postnatal rise while in the fetal heart it was high and declined after birth. These tissues contained predominantly type I with varying proportions of type III hexokinase. The ratio of particulate-bound to soluble hexokinase varied from tissue to tissue. All except the liver showed a significant increase in binding after birth. The changes are discussed in relation to the control of glucose utilization in the fetal and neonatal periods.     

Efficient CPP-mediated Cre protein delivery to developing and adult CNS tissues

Background  

Understanding and manipulating gene function in physiological conditions is a major objective for both fundamental and applied research. In contrast to other experimental settings, which use either purely genetic or gene delivery (viral or non-viral) strategies, we report here a strategy based on direct protein delivery to central nervous system (CNS) tissues. We fused Cre recombinase with cell-penetrating peptides and analyzed the intracellular biological activity of the resulting chimerical proteins when delivered into cells endowed with Cre-mediated reporter gene expression.     

Immunohistochemical localization of phosphoenolpyruvate carboxykinase in adult and developing mouse tissues.

We used immunohistochemical techniques to analyze the cell distribution of phosphoenolpyruvate carboxykinase (PEPCK) in adult and developing mouse tissues. PEPCK immunoreactivity was detected in many tissues, including some that had not been previously reported to contain PEPCK enzyme activity (bladder, stomach, ovary, vagina, parotid gland, submaxillary gland, and eye). In some multicellular tissues, PEPCK immunoreactivity was observed in multiple cell types. Several tissues (spleen, thyroid, and submaxillary gland) contained no detectable PEPCK immunoreactivity. During development, PEPCK immunoreactivity was associated with the developing nervous system and somites in 15-day embryos. At prenatal day 18, PEPCK immunoreactivity was detected only in the nervous system. At prenatal day 20, PEPCK immunoreactivity was observed in many of the tissues that contain PEPCK in the adult, with the exception of liver, lung, and stomach. PEPCK immunoreactivity was detected in liver at postnatal day 1, lung at postnatal day 7, and stomach after postnatal day 21. The only tissue in which PEPCK immunoreactivity decreased during development was the pancreas, where PEPCK immunoreactivity was detected at prenatal day 20 and was present until postnatal day 21. These results suggest that PEPCK expression is cell-type specific, more widespread than previously thought, and differentially expressed during development.     

Uridine kinase activities in developing, adult and neoplastic rat tissues.

Uridine kinase activities were found chiefly in the soluble fractions of rat tissues. In normal adults the activities ranged from 13 munits/g in skeletal muscle to 178 munits/g in colon. Enzyme activities in several rat neoplasms were significantly higher (e.g. in a fibrosarcoma, mammary carcinoma, renal carcinoma, pancreatic carcinoma and lymphocytic lymphoma, but not in a fast-growing Morris hepatoma). The activities were not related to tumour growth rates or sizes. In normal foetal liver, lung, brain, heart and kidney, uridine kinase concentrations equalled or exceeded those in the adult homologous tissue, but maximal activities in liver were reached 3--5 days post partum. In suckling rats the intestinal activity decreased substantially immediately after birth and normally did not rise again until late in the third postnatal week. Premature upsurges could be evoked by an injection of cortisol or by starvation of the pups overnight. Pancreatic activity was absent from 1-day-old rats, and only about 5% of the adult activity was reached by day 20; adult activities were attained rapidly after weaning. In pancreas, precocious formation or uridine kinase was elicited by overnight starvation of 2-week-old rats.     

Localization of laminin alpha4-chain in developing and adult human tissues.

Recent studies suggest important functions for laminin-8 (Ln-8; alpha4beta1gamma1) in vascular and blood cell biology, but its distribution in human tissues has remained elusive. We have raised a monoclonal antibody (MAb) FC10, and by enzyme-linked immunoassay (EIA) and Western blotting techniques we show that it recognizes the human Ln alpha4-chain. Immunoreactivity for the Ln alpha4-chain was localized in tissues of mesodermal origin, such as basement membranes (BMs) of endothelia, adipocytes, and skeletal, smooth, and cardiac muscle cells. In addition, the Ln alpha4-chain was found in regions of some epithelial BMs, including epidermis, salivary glands, pancreas, esophageal and gastric glands, intestinal crypts, and some renal medullary tubules. Developmental differences in the distribution of Ln alpha4-chain were detected in skeletal muscle, walls of vessels, and intestinal crypts. Ln alpha4- and Ln alpha2-chains co-localized in BMs of fetal skeletal muscle cells and in some epithelial BMs, e.g., in gastric glands and acini of pancreas. Cultured human pulmonary artery endothelial (HPAE) cells produced Ln alpha4-chain as M(r) 180,000 and 200,000 doublet and rapidly deposited it to the growth substratum. In cell-free extracellular matrices of human kidney and lung, Ln alpha4-chain was found as M(r) 180,000 protein.     

The establishment of vascular-derived microenvironments in the developing chick wing

The results of previous studies on the temporal sequence of limb vascularization suggest that the prospective myogenic and chondrogenic areas of the mesoderm are distinguished by a differential vascularization pattern prior to the overt expression of muscle- and cartilage-specific phenotypes. The experiments presented here are designed to reveal the dynamic aspects of vascular flow in the limb by the observation of how an inert, particular tracer (india ink) is mobilized and dispersed at specific points in the mesoderm. Data are presented as a temporal sequence of fluid flow "maps" which detail both the rate and the direction of vascular flow in the limb. It is proposed that not only does the vasculature compartmentalize the mesoderm into prospective myogenic and chondrogenic zones but also that these broad areas are subcompartmentalized into discrete microenvironments that are spatially distinct with regard to their capacity for transporting the carbon particles. The developmental significance of this observation may be that limb mesodermal cells are granted precise, "positional" information in the form of the specific nutrient and oxygen levels they encounter during critical, or decisional, phases of morphogenesis.     

Immunohistochemical detection of subunit A(M) of lactate dehydrogenase in tissues of the developing chick

Summary The distribution of A(M) subunits of lactate dehydrogenase (mainly LDH₅) in developing muscle, heart, liver, lung, kidney and cartilage tissue of chicken embryos was examined by the indirect fluorescent antibody technique. Antibodies against porcine LDH₅, purified by affinity chromatography, were used for this purpose. In special areas of newly formed myofibrils in somitic myoblasts fluorescence was already detected after 4 days of incubation, and located at the same place in muscle tissue of all advanced developmental stages examined. During the myotube stage of muscle development staining was also located in the peripheral thickened cytoplasma of the myotubes. The myocardium did not exhibit any fluorescent staining in the developmental stages examined. Endocardium, epicardium and pericardium, however, were fluorescent in young developmental stages. The liver showed fluorescence in 5- to 8-day embryos mainly in the endothelial cells of the blood sinusoids. In 9- to 12-day embryos the bile ducts became fluorescent. In lungs after 9- to 12-day development the epithelium and the surrounding tissues of bronchi exhibited strong immunofluorescence. The mesonephros exhibited faint granular fluorescence in tubule-forming cells and their membranes after 4–9 days of incubation. Advanced developmental stages only exhibited fluorescent blood cells. This latter staining is at least partly due to non-specific reactions of blood cell membranes with FITC-conjugated anti-rabbit IgG. Cartilage is characterized by non-specific fluorescence, but in embryos older than 8 days strong granular fluorescence of chondrocytes and staining of the perichondrium distinguished sections treated with anti-LDH₅ antibodies from control sections reacted only with FITC-conjugated anti-rabbit IgG. In addition, strong fluorescent staining was detectable in certain areas of the 5-day neural tube and faint staining in the mucosa of the intestine from embryos older than 10 days.     

The excretion of salt load by the developing chick embryo

Salt loads (0.17 or 0.34 mmol Na+; 6 M NaCl solution labelled with 24Na) were administered into the amnion of 7-day-old chick embryos. The 24Na distribution in embryonic blood, amniotic and allantoic fluids was measured in 1, 2, 4, 8, 12 and 24 h intervals to assess the kinetics of salt load movements in particular egg compartments. The aim was to estimate the efficiency of the embryonic homeostatic apparatus to maintain ionic balance in the internal environment of the embryonic body. The Na+ concentration in amniotic fluid was expected to rise after salt loading by about 275 and 400 mM, respectively. More than 10% of the salt dose per ml appeared in the embryonic blood 2 h after salt load administration while only 0.2% were found in the urine (collected as allantonic fluid). The maximal rise of 24Na activity in the blood of salt-loaded embryos reached 11%-12% of the dose which corresponded to an increase of Na+ concentration by 19 and 41 mM, respectively. The maximum of 24Na activity appeared in the allantoic fluid with a delay of several hours and indicated an increment of Na+ concentration by 6% and 9% of the dose per ml in the case of salt-loaded embryos. The Na+ concentration in the allantoic fluid (urine) never exceeded that in the blood. The final Na+ activity (estimated in the blood 24 h after salt loading) was equal to 5% of the dose per ml in both cases, indicating a persistent elevation of Na+ concentration by 8.6 and 17.2 mM, respectively.     

Vitamin A economy of the developing chick embryo and of the freshly hatched chick

1. The changes in the net amounts of retinol, retinyl esters and retinal in both the developing chick embryo and the newly hatched chick were investigated. The embryo requires about 68nmol of the vitamin for its growth, whereas the baby chick requires about 108nmol during the first 7 days after hatching. 2. Retinal was present in the egg in fairly high concentrations at the beginning of the incubation but it virtually disappeared from the extra-embryonic tissue after day 17 of incubation. It was not found in the liver of the embryo or of the newly hatched chick up until day 7.