Regulation of rat thyroxine-binding globulin and transthyretin: studies in thyroidectomized and hypophysectomized rats given tri-iodothyronine or/and growth hormone.

We have investigated the role of the thyroid compared with the hypophysis in the regulation of the two saturable thyroid hormone carriers of rat serum, thyroxine-binding globulin (TBG) and transthyretin (TTR). We examined, at serum and hepatic mRNA level, the responses of TBG and TTR to thyroidectomy (Tx), hypophysectomy (Hx) and replacement treatments with tri-iodothyronine (T3) or/and GH, both hormones which are depleted when the thyroid or hypophysis are removed. The studies were performed on male rats at the age of 8 weeks, when the developmentally regulated TBG becomes undetectable after its transient postnatal rise, while the nondevelopmentally regulated TTR presents its normal, age-independent level of expression. Tx-induced TBG re-expression was completely reversed by T3 replacement and unresponsive to GH replacement. TTR in the serum, on the other hand, was not affected by Tx or T3 replacement, moderately reduced by Tx in terms of the amount of mRNA, and markedly reduced by GH replacement. GH treatment, moreover, inhibited the expression of TTR in euthyroid controls. Hx, like Tx, induced TBG re-expression, an effect efficiently antagonized by T3 replacement. However, TBG synthesis was higher in Hx than in Tx rats and less effectively antagonized by T3 replacement. Most unexpectedly, GH induced a dramatic further increase in TBG synthesis, and the TBG synthesized in the GH-replaced Hx rats was entirely resistant to down-regulation by T3 replacement. TTR was markedly decreased at both serum and hepatic levels by Hx, unaffected by T3 and further decreased by GH replacement.(ABSTRACT TRUNCATED AT 250 WORDS)

Re-expression of thyroxine-binding globulin in post-weaning rats during protein or energy malnutrition.

Thyroxine-binding globulin, the highest affinity thyroid hormone binder of rat serum, was studied during 28 days of dietary protein restriction (6% protein vs 18% protein in isocaloric control diet) or energy restriction (60% intake of control diet). Studies were performed on male rats aged four weeks at the beginning of experiments: the animals had reached the ontogenic stage when the thyroxine-binding globulin had declined, after its high postnatal surge, to undetectable levels. Short-term administration (seven days) of one or the other restricted diet similarly induced resynthesis of the protein. Its serum concentrations reached 26-46% of those measured in eight-day pups (peak of the neonatal surge) and its liver mRNAs showed corresponding enhanced signals. Serum T4 binding activities were increased, although concomitantly transthyretin, second specific T4 carrier of the rat serum, decreased markedly (65-75% of controls) in response to the dietary restrictions. Longer-term diet administration (14 or 28 days) resulted in the further increase of the thyroxine-binding globulin in the protein-restricted rats, in contrast to its decline and eventual disappearance in the energy-restricted animals. Protein restriction was associated with increased total and free T3 serum concentrations, in contrast to energy restriction which little affected these parameters. These studies reveal rat thyroxine-binding globulin as a positive (increasing), highly sensitive reactant of malnutrition, able to discriminate between energy deficiency and composition dysequilibrium of diets. They suggest that up-regulation of its synthesis in the two dietary models involves differential mechanisms.

Structural and functional microheterogeneity of rat thyroxine-binding globulin during ontogenesis.

Thyroxine-binding globulin (TBG), the major carrier of thyroid hormones in human and murine sera, is in the rat a developmentally regulated protein, showing a large surge during post-natal growth followed by virtual disappearance in adults. Here we study as a function of age, from the 19-day embryo to 60 days after birth, the structural and binding characteristics of rat TBG microheterogeneity. Serum obtained throughout development, when pre-incubated with 125I-thyroxine (T4), was shown by isoelectric focusing (IEF; pH range 4-5) to contain six labelled isoforms of TBG, with isoelectric points between 4.25 and 4.55. These isoforms differ in their sialic acid content. The relative labelling densities of the isoforms show age-related changes: in neonates, the bulk of T4 is bound to the most alkaline (least sialylated) TBG isoforms; then, with advancing age, it shifts to the most acidic isoforms. To understand whether this progressive transfer of ligand reflects developmental changes in the relative abundance of isoforms, we submitted sera from rats of different ages to crossed immunoelectrofocusing analysis. We demonstrate that the relative proportions of the TBG isoforms remain fairly constant, independent of the level of total TBG. The most acidic forms always represented the majority (approximately 50%), with the most alkaline ones only representing 15% of total TBG. Experiments based on IEF of charcoal-treated sera, supplemented or not with lipidic serum extracts, further demonstrate that the paradoxical low labelling seen in the neonates for the most abundant highly sialylated isoforms is due to inhibition of their binding abilities by liposoluble components, which are particularly concentrated in the sera at the earlier post-natal ages. These studies represent the first analysis of concentration versus binding functions of rat TBG isoforms in the physiological conditions of normal ontogeny. Our results point to an important influence for the serum environment on the binding properties of TBG isoforms. The physiological significance of such interactions remains to be clarified.

The pituitary control of rat thyroxine binding globulin.

Thyroxine-binding globulin (TBG) is in the rat a developmentally regulated protein, actively synthesized in postnatal developing pups and in aging animals, but undetectable in adults. Experimental depletion of thyroid hormones (TH) in adults by thyroidectomy (Tx) or by hypophysectomy (Hx) results in marked reexpression of TBG synthesis. T3 replacement in both cases antagonizes this effect, though only moderately in Hx rats. These observations point to a regulatory pathway of TBG synthesis common to TX and Hx rats, characterized by an inverse relationship between TBG and TH levels. However, along with this thyroid-dependent TBG regulation, important differences between Tx and Hx rats are evidenced, pointing to specific pituitary factors of TBG control. The most striking difference concerns the effect of growth hormone (GH) replacement: the TBG of Tx rats is not affected, in contrast to that of Hx rats which is further increased by GH administration. The TBG response of the GH-treated Hx rats, which is strongly resistant to inhibition by T3, might involve deshomeostasis of GH-controlled functions not necessarily linked to the thyroid, e.g. the pancreatic functions regulating carbohydrate or lipid metabolism. In the light of these studies, it may be envisaged that the high surge of rat TBG during postnatal development involves a transient sensitivity of the TBG gene to stimulation by endogenous GH, and that this sensitivity lasts until functional maturity of the hypothalamic-pituitary-thyroid axis has been achieved.

A senescence up-regulated protein: the rat thyroxine-binding globulin (TBG).

Thyroxine-binding globulin (TBG), the major carrier of thyroid hormones in human serum, was thought to be absent in most species, including rodents. We demonstrated recently that in fact the rat possesses a TBG gene, virtually non-expressed in young adults, but actively transcribed during post-natal development. We now find that the TBG gene is also increasingly re-expressed during senescence. Evidence is presented suggesting that physiologically decreased thyroid hormone levels, characteristic of neonates and of ageing rats, might constitute a common factor inducing up-regulation of TBG in both developmental and ageing processes. Rat TBG is to our knowledge the first biochemical 'positive' (i.e. increasing) marker of non-pathological senescence, expressed at both biosynthetic and bloodstream levels.

Immunological quantitation of rat and mouse thyroxine-binding globulins. Ontogenesis and sex-dependence of the circulating levels of the thyroxine-binding globulins.

We describe the preparation of monospecific antisera against a thyroxine-binding globulin partially purified from immature rat sera by affinity chromatography on thyroxine-Sepharose. The antisera are used for the rocket immunoelectrophoresis assay of rat thyroxine-binding globulin and also, owing to their partial cross-reactivity with mouse thyroxine-binding globulin, for the quantitation of this serum binding protein in the mouse. The thyroxine-binding globulin is measured in developing rats and in sexually mature male and female rats and mice. The results of the ontogenetic study confirm the postnatal surge of serum thyroxine-binding globulin levels, formerly demonstrated with binding techniques. They allow further to define the correlations, dependent on age, of the immunoquantitated thyroxine-binding globulin and transthyretin levels with the abilities of the sera to bind thyroxine. In sexually mature rats and mice we demonstrate an opposite sex-dependence of thyroxine-binding globulin levels, characterized by increased levels of the protein in the female rats versus increased levels of the protein in the male mice. This is the first report of immunological quantitation of rat and mouse thyroxine-binding globulins.