Goitrogens and thyroid follicular cell neoplasia: evidence for a threshold process.

Thyroid neoplasia can result from many different causes. These include low iodine diets, subtotal thyroidectomy, radioactive iodine, natural goitrogens such as rape seed and cabbage, chemotherapeutic agents such as sulfathiazole, and pesticides such as amitrole. All of these appear to act through either direct or indirect interference with thyroid hormone synthesis. Decreased circulating levels of thyroid hormones in the blood result in increased release of thyroid-stimulating hormone by the anterior pituitary gland. This, in turn, results in hypertrophy and hyperplasia of the thyroid without a corresponding increase in blood thyroid hormone levels. Hyperplasia of the pituitary is also observed due to increased functional demand for continued production of thyroid-stimulating hormone. After prolonged stimulation of the pituitary/thyroid axis, hyperplasia may progress to neoplasia. Cessation of exposure prior to the induction of neoplasia results in a return to the normal state. It is clear that some degree of thyroid inhibition can be accommodated within the bounds of the normal feedback mechanism without the induction of either hyperplasia or neoplasia. A threshold for thyroid follicular neoplasia is therefore indicated.

Protein metabolism by rat lung: influence of fasting, glucose, and insulin.

We studied protein metabolism by rat lung slices. We found that phenylalanine is not metabolized to other substances by the lung and that the rate of incorporation of L-[U-14C]phenylalanine into protein, calculated using its intracellular specific radioactivity, reached a maximum within 20 min and remained stable for the rest of a 3-h incubation. The rate of protein degradation, determined using [12C]phenylalanine as a marker, was linear over a 3-h incubation. Fasting for 3 days slowed the increase in lung protein content of fasted compared to nonfasted rats; there was also a decrease in protein synthesis and an increase in proteolysis. In fed rats, glucose, insulin, and glucose plus insulin did not alter protein synthesis. Glucose, insulin alone, and glucose plus insulin decreased proteolysis. We conclude that the in vitro system reflected changes in the in vivo protein content of the lung. Fasting decreases protein synthesis and increases proteolysis. Glucose and insulin alone modulate protein metabolism in the lung by acting on the degradative rather than the synthetic process.

Influence of insulin on amino acid uptake by lung slices.

We examined the transport of amino acids by rat lung slices using mainly 14C-labeled alpha-aminoisobutyric acid ([14C]AIB) as a nonmetabolized amino acid. We found that [14C]AIB is accumulated by the lung in an energy-dependent fashion against a concentration gradient. The uptake is saturable, stereospecific, and follows Michaelis-Menten kinetics suggesting enzyme or carrier mediation across the plasma membrane. Insulin increases the uptake of [14C]AIB and insulin plus glucose increases its uptake even more. The diffusion constant (KD) in the presence of glucose, insulin, or glucose plus insulin is the same, 0.29 h-1; the Vmax is also the same, 83.0 mmol-1-1-h-1, under these three conditions. The apparent Km is 14.0 mM with glucose, 9.0 mM with insulin, and 4.0 mM in the presence of glucose and insulin. We conclude that the uptake of [14C]AIB is increased by insulin, and insulin plus glucose, and, based on this kinetic analysis, this is due to an increased affinity of the transport sites for AIB (decreased Km, unchanged Vmax, and KD).

Influence of fasting on lung oxygen consumption and respiratory quotient.

We measured the oxygen consumption (QO2) of lung slices from rats and rabbits and the respiratory quotient (RQ) of lung slices from fed and fasted rats. The QO2 of lung slices is lowered within 24 h after the onset of food deprivation; this decrease in QO2 lasts during at least 2 additional days of fasting and is not eliminated by addition of glucose to the reaction medium. In fed rats the RQ of lung slices after 30 min of incubation without glucose is 0.75 +/- 0.01 (mean +/- SE) and 0.96 +/- 0.02 with glucose present. Fasting for 72 h lowers the RQ of lung slices after 30 min of incubation without glucose to 0.68 +/- 0.03; addition of glucose raises the RQ of lung slices from 72-h-fasted rats to 0.76 +/- 0.02. We conclude that fasting depresses lung oxidative metabolism. In the fed rat glucose is a major substrate for oxidative processes but in the fasting rat the oxidation of glucose is impaired and lipids are an important source of lung energy.