Sergio Scapin

Short-term effects of thyroid hormone in prenatal development and cell differentiation.

Extranuclear or nongenomic effects of thyroid hormones do not require interaction with the nuclear receptor, but are probably mediated by specific membrane receptors. This review will focus on the extranuclear effects of thyroid hormones on plasma membrane transport systems in non mammalian cells: chick embryo hepatocytes at two different stages of development, 14 and 19 days. At variance with mammals, the chick embryo develops in a closed compartment, beyond the influence of maternal endocrine factors. Thyroid hormones inhibit the Na+/K+-ATPase but stimulate the Na+/H+ exchanger and amino acid transport System A with different dose-responses: a bell-shaped curve in the case of the exchanger and a classic saturation curve in the case of System A. These effects are mimicked by the analog 3,5-diiodothyronine. Signal transduction is mediated by interplay among kinases, mainly protein kinase C and the MAPK pathway, initially primed by second messengers such as Ca2+, IP3, and DAG as in mammalian cells. Thyroid hormones and 3,5-diiodothyronine stimulate thymidine incorporation and DNA synthesis, associated with the increased levels and activity of cyclins and cyclin-dependent kinases involved in the G1/S transition, and also these effects have their starting point at the plasma membrane. Increasing evidence now demonstrates that thyroid hormones act as growth factors for chick embryo hepatocytes and their extranuclear effects are important for prenatal development and differentiation.

Short-term effects of thyroid hormones during development: Focus on signal transduction

Extranuclear or nongenomic effects of thyroid hormones are mediated by receptors located at the plasma membrane or inside cells, and are independent of protein synthesis. Recently the alphaVbeta3 integrin was identified as a cell membrane receptor for thyroid hormones, and a wide variety of nongenomic effects have now been shown to be induced through binding of thyroid hormones to this receptor. However, also other thyroid hormone receptors can produce nongenomic effects, including the cytoplasmic TRalpha and TRbeta receptors and probably also a G protein-coupled membrane receptor, and increasing importance is now given to thyroid hormone metabolites like 3,5-diiodothyronine and reverse T(3) that can mimick some nongenomic effects of T(3) and T(4). Signal transduction from the alphaVbeta3 integrin may proceed through at least three independent pathways (protein kinase C, Src or mitogen-activated kinases) but the details are still unknown. Thyroid hormones induce nongenomic effects on at least three important Na(+)-dependent transport systems, the Na(+)/K(+)-ATPase, the Na(+)/H(+) exchanger, and amino acid transport System A, leading to a mitogenic response in embryo cells; but modulation of the same transport systems may have different roles in other cells and at different developmental stages. It seems that thyroid hormones in many cases can modulate nongenomically the same targets affected by the nuclear receptors through long-term mechanisms. Recent results on nongenomic effects confirm the old theory that the primary role of thyroid hormones is to keep the steady-state level of functioning of the cell, but more and more mechanisms are discovered by which this goal can be achieved.

Seasonal variations of glycogen synthase and phosphorylase activities in the liver of the frog Rana esculenta

Abstract Glycogen metabolism has been studied in the liver of the frog Rana esculenta throughout the annual cycle. Hepatic glycogen reserves are high during winter and decrease during spring and summer, the changes being reflected by variations in the activities of the rate-limiting enzymes glycogen synthase and phosphorylase. Glycogen deposition is associated with increased levels of synthase D activity and no changes in the relative proportions of the active-inactive form of the enzyme, whereas during glycogen mobilization significant changes in both total phosphorylase and in the percent phosphorylase a are observed. Regression analysis indicates a positive correlation between glycogen content and synthase activity, and an inverse relationship between glycogen content and either total phosphorylase or phosphorylase a . The results suggest that glycogen deposition and/or mobilization could be mainly controlled by mechanisms related to either changes in the amount of enzyme protein or to allosteric effects of the metabolite glucose-6-phosphate on glycogen synthase and phorphorylase.

Annual variations in the binding of insulin to hepatic membranes of the frog Rana esculenta

Amphibia undergo regular annual cycles of metabolic activity that are influenced by both exogenous factors and hormones. Insulin binding to crude frog hepatic membranes was studied throughout the year. The general character of insulin binding was similar to that in other vertebrates; the maximum specific binding was achieved after 4 hr at 4 degrees, the optimum pH was 7.8, half-maximal displacement of bound insulin was from 9 x 10(-10) to 1 x 10(-9) M, and insulin analogs competed for the insulin receptor in line with their relative biological potencies. A biphasic Scatchard plot and negative cooperativity of the receptor were also observed in frog liver membranes. Affinity constants from Scatchard plots revealed high and low affinity binding sites which were unchanged during the year. The seasonal cycle, however, markedly affected the binding capacity for both sites. Maximum binding occurred in May-June and the minimum in November-December for both classes of receptors. Binding capacities ranged from 1.71 to 11.33 fmol/mg protein for the high affinity sites and from 432 to 3171 fmol/mg protein for the low affinity sites. It is concluded that annual cycles of insulin binding reflect modulation of receptor number rather than receptor affinity.

Glucocorticoid receptor of frog (Rana esculenta) liver

The presence of a glucocorticoid soluble receptor is demonstrated in frog liver cytosol. The kinetic characterization of frog liver cytosolic receptor for glucocorticoids is reported and its steroid specificity assessed. Results indicate a gross similarity between frog liver and mammalian glucocorticoid receptor, being a major difference the reduced binding capacity.

Tyrosine aminotransferase activity of frog (Rana esculenta) liver—III. A circannual study

A circannual study of tyrosine aminotransferase and other metabolic enzymes in frog liver is reported. The subcellular distribution of all enzymatic activities under investigation was also studied. Results show significant oscillations of all enzymatic activities throughout the year; in particular tyrosine aminotransferase has a marked summer maximum. The subcellular distribution of tyrosine aminotransferase shows significant variations: the soluble activity of the enzyme presents a bimodal circannual distribution, which has its counterpart in an increased activity of heavier fractions.

Glycogen phosphorylase activity in the liver of the frog Rana esculenta

1. Phosphorylase activity has been assayed in liver extracts of the frog, Rana esculenta, during the winter period. In native conditions, most of the phosphorylase is present as AMP-independent activity and shows properties similar to those of the a form of the liver enzyme from other vertebrates. 2. It is suggested that regulation of phosphorylase activity is through interconversion between a and b forms operated by endogenous phosphorylase kinase and phosphatase. 3. Kinetic studies show hyperbolic saturation curves for glycogen with apparent Km of 2.91 mM and 9.67 mM for a and b forms, respectively. 4. A hyperbolic saturation curve is also observed for glucose 1-P in the case of phosphorylase a, with an apparent Km of 3.95 mM, whereas a sigmoidal kinetic is shown by the b form for the same substrate; from Hill plots an S0.5 of 24.2 mM was derived. 5. Hyperbolic responses were observed in the case of AMP, and Ka of 70 microM and 0.31 mM were calculated for phosphorylase a and b, respectively.

Phospholipid and fatty acid composition of frog (Rana esculenta) liver—a circannual study

Liver lipid composition of the frogRana esculenta was examined on a circannual basis. In particular, phospholipid and cholesterol content, relative phospholipid distribution, and fatty acid patterns have been studied. Seasonal acclimatization is associated with significant modifications of phospholipid content and of the relative proportion of phospholipid classes, while cholesterol level is unchanged throughout the year. In regard to the fatty acid composition of total phospholipids as well as of the four major phospholipid classes—phosphatidylcholine (PC); phosphatidylethanolamine (PE); sphingomyelin (SM); phosphatidylserine (PS)—it appears that the liver of “summer animals” is characterized by a higher unsaturation index due to a decrease of saturated fatty acids and to an increased content of n−3 and n−6 polyunsaturated fatty acids. The results suggest that relevant compositional changes occur mainly in spring and autumn: these changes could be interpreted as being the result of both a nutritionally- and thermally-induced seasonal adaptation directed toward the preservation of membrane-associated physiological activities that are linked to the transition from the active to the inactive state of the animal.

Tyrosine aminotransferase activity of frog (Rana esculenta) liver

1. The presence of tyrosine aminotransferase is reported both in particulate and soluble fractions of frog liver. 2. The activity of the soluble enzyme of frog liver was investigated with regard to its dose and time dependence, its substrate specificity and concentration dependence, its thermal sensitivity as well as pH and temperature dependence. 3. It appears that the properties of the soluble tyrosine aminotransferase of frog liver are in close agreement with those reported for the mammalian liver enzyme.

Tyrosine aminotransferase activity of frog (Rana esculenta) liver. II: Comparative aspects of intracellular distribution.

1. A subcellular fractionation procedure for frog liver is reported and validated by the distribution pattern of several marker enzymes, also in comparison with rat liver. 2. The subcellular distribution of tyrosine aminotransferase was investigated in frog liver as compared to rat liver: a different distribution of the enzyme was observed, being the activity mostly recovered in mitochondrial and cytosolic compartments. 3. Results indicate that mitochondrial tyrosine aminotransferase of both frog and rat liver is a matrix enzyme, even if differences are observed concerning its release from the organelles upon detergent treatment.