potassium-thiocyanate and Body-Weight

Potassium thiocyanate given in the drinking water of pregnant rats led to decreased body weight in their 14-day-old offspring (27%) without altering thyroid weight. Reduction of the suckling rat's body weight could be explained be defective thyroxinemia (38). Plasma FT3 and TSH were unchanged after thiocyanate treatment. The biochemical changes were in agreement with the histological aspects of the hypothyroid animals. The typical pattern was hyperplastic goiter. Colloid volume was reduced compared with controls. Presence of resorbed peripheral vacuoles, a sign of thyroid hyperactivity, was disclosed by a three-fold increase in radioiodide (131I) uptake compared with controls. When the antithyroid drug was removed from the mother's milk, the pups'weight increased but did not reach control values. Plasma thyroid hormone levels returned to normal and even exceeded control values in spite of partial recovery of thyroid iodine content when thiocyanate treatment was stopped for ten days.

Topics: Animals; Animals, Suckling; Antithyroid Agents; Body Weight; Female; Gestational Age; Goiter; Hypothyroidism; Iodine; Maternal-Fetal Exchange; Pregnancy; Rats; Thiocyanates; Thyroid Gland; Thyrotropin; Thyroxine

The influx of L-lysine into apical vesicles from the chicken jejunum occurs through two systems, one with low Michaelis constant (K(m)) and features of system b0,+ and the other with relatively high K(m) for L-lysine and with properties of system y+. In the present study the effect of a lysine-enriched diet (Lys, containing 68 g L-lysine/kg dietary protein, control animals 48 g/kg) on L-lysine uptake through both transport systems was investigated. Results show that 1) lysine enrichment had no effect on either body weight or the efficiency of food utilization. 2) In Lys-fed animals, the mediated L-lysine influx was best fitted to the two-system model with y+ and b0,+ activity. 3) In the presence of an Na+ gradient, total L-lysine uptake is significantly higher in Lys-fed animals than in control birds (about 40% increase). 4) Lys diet increases K(m)b0,+ 6-fold (KSCN gradient) and 12-fold (NaSCN gradient) and maximum velocity (Vmax) by 6- and 20-fold, respectively. The effects of Lys enrichment on the y(+)-like system are only observed on the Vmax and in the presence of a Na+ gradient (30% increase). 5) Na+ is involved in the activation of the transport process in the Lys-fed chickens, but there is no correlation between external Na+ concentration and L-lysine influx. In conclusion, both b(0,+)- and y(+)-like transport systems are upregulated by dietary lysine but with different kinetic profiles; the high-capacity y(+)-like carrier shows a Vmax increase without changes in K(m), whereas the low-capacity b(0,+)-like system shows an increase in Vmax as well as in the K(m).

Topics: Animals; Biological Transport; Body Weight; Chickens; Diet; Energy Metabolism; Ethylmaleimide; Glucose; Intestinal Mucosa; Jejunum; Kinetics; Lysine; Male; Microvilli; Sodium-Potassium-Exchanging ATPase; Sucrase; Thiocyanates

The hypothesis that a defect in the rate-limiting blood-brain barrier (BBB) nutrient transport may be one of the factors responsible for the brain defects seen in some iodine deficiency disorders was tested in Wistar/NIN rats fed potassium thiocyanate (KSCN), a synthetic goitrogen. The BBB nutrient transport was measured by the brain uptake index (BUI) method. Feeding KSCN to female rats (from weaning) through their growth, pregnancy and lactation (G1) but not from conception (G2) or parturition (G3) resulted in a significant decrease (approximately 23%) in the BBB transport of 2-deoxy-D-glucose (2-DG) in their offspring at weaning, compared with controls (C). Post-weaning KSCN-feeding (G4) of control pups did not affect their BBB 2-DG transport (BUI: 36.2 +/- 4.98, vs 38.8 +/- 4.11). The effects of different KSCN regimens on BBB transport of leucine (leu), tyrosine (tyr) and sucrose (background marker) were inconsistent, of smaller magnitude (approximately 10%) and appeared to be of little significance. Withdrawing KSCN from the diet of chronically KSCN-fed (G1) mothers from conception (G5) or parturition (G6) prevented the impairment of BBB 2-DG transport in pups (BUI: 27.0 +/- 4.98, 20.8 +/- 3.27, 26.9 +/- 3.99 and 28.3 +/- 3.47 in C, G1, G5 and G6 pups, respectively); this was reversed by feeding the control diet to G1 pups from weaning. Withdrawal of dietary KSCN did not affect BBB transport of leu, tyr and sucrose. The decreased BBB transport of 2-DG in G1 pups appears to be due to a decrease in affinity (Kt app 5.46 vs 4.15 mM) rather than in the capacity (Tmax app 0.94 vs 0.91 mumoles/g/min) of the transport system. Intracarotid injections of KSCN per se had no effect on BBB 2-DG transport, suggesting that the effects may be secondary to the altered thyroid status of the animal.

Topics: Amino Acids; Animals; Antimetabolites; Antithyroid Agents; Blood-Brain Barrier; Body Weight; Deoxyglucose; Diet; Female; Iodine; Iodine Radioisotopes; Organ Size; Rats; Rats, Wistar; Thiocyanates; Thyroxine

In farm minks the following effects were achieved by additional feeding of KSCN (0,9-2,6 mg SCN-/kg body weight) equivalent to twice til triple the usual SCN- intake (0,2-0,9 mg SCN-/kg body weight) during the 3. to 7. month of life: improvement of the coat structure and of length, density, and elasticity of the guard hairs, additionally to increase of body weight and length.

Topics: Animal Feed; Animals; Body Weight; Female; Food, Fortified; Hair; Male; Mink; Thiocyanates

To evaluate the mechanism of the promoting effect of goitrogens on thyroid tumorigenesis, well-known goitrogens having different pharmacologic action, i.e., thiourea, phenobarbital sodium (PB), potassium thiocyanate (KSCN), and 3,4,5,6-tetrachloro-2',4',5',7'-tetraiodo-fluorescein sodium salt (Rose Bengal B, FD&C Red No. 105) (FR105) were administered to the DHPN-initiated and non-initiated F344 male rats in the drinking water for 25 weeks. Remington's iodine deficient diet (I-def) was fed as a positive control. These goitrogens showed significant tumor promoting effect or promoting tendency on the rat thyroids. According to the changes in thyroid morphology and thyroid-related hormone titers observed in the present study, we proposed to classify goitrogens at least into 2 groups, i.e., iodine deficiency-type promoters and the iodine excess-type promoters. The former contains goitrogens inducing TSH-stimulated diffuse goiter composed of uniform follicles with activated tall follicular epithelial cells, such as thiourea, KSCN and PB, and the latter contains goitrogens inducing colloid goiter composed of a mixture of colloid-rich follicles with flat follicular cells and normal-looking follicles with cuboidal follicular cells, such as FR105. This classification may be useful for the risk assessment of goitrogens.

Topics: Animals; Antithyroid Agents; Body Weight; Carcinogens; Male; Nitrosamines; Organ Size; Phenobarbital; Rats; Rats, Inbred F344; Rose Bengal; Thiocyanates; Thiourea; Thyroid Gland; Thyroid Hormones; Thyrotropin