Existence of extrathyroidal conversion inhibitor (IEC) in starved animals and its influence on thyroid hormones deiodination in liver and kidney in vitro

To find out whether an inhibitor of extrathyroidal conversion of iodothyronines is present in sera of starved animals, pig liver and kidney homogenates were incubated with T4, T3 or rT3 and dithiotreitol in the presence of evaporated diethyl ether extracts of sera obtained from fed and starved (1-12 days) rabbits. Sera extracts of short-term (1-4 days) starved rabbits caused a significant inhibition of T4 to T3 conversion (54% on day 3) and T4 to rT3 deiodination (52% on day 2) in liver homogenates. Extracts of sera from long-term (8 and 12 days) starved animals diminished only liver T4 to T3 conversion on day 8 and had no influence on liver T4 to rT3 conversion. 5'-deiodination of rT3 (to 3,3'-T2) in liver was gradually decreased by extracts of sera from animals starved during 2-12 days. Liver rT3-5-deiodination (to 3',5'-T2) was significantly impaired on day 4 and totally depressed by long-term starvation. In vitro T3 to 3,3'-T2 conversion in liver was markedly (59-103%) increased by ether extracts of sera from short-term fasted rabbits and considerably inhibited (62-72%) by long-term fasting. T4 to T3 conversion in kidney was significantly influenced by sera extracts obtained neither from short-term fasted rabbits and considerably inhibited (62-72%) by long-term fasting. T4 to T3 conversion in kidney was significantly influenced by sera extracts obtained neither from short-term nor from long-term fasted rabbits but T4-5-deiodination (to rT3) was reduced by sera extracts of short-term fasted animals.(ABSTRACT TRUNCATED AT 250 WORDS)     

Changes in thyroid hormone levels in chicken liver during fasting and refeeding

In chickens, fasting results in increased plasma thyroxine (T(4)) levels and decreased plasma 3,5,3'-triiodothyronine (T(3)) levels. Refeeding, in turn, restores normal plasma T(3) and T(4) levels. The liver is an important tissue for the regulation of circulating thyroid hormone levels. Previous studies demonstrated that the increase in hepatic type III deiodinase in fasted chickens plays a role in the decrease of plasma T(3). Another factor that could be important is the level of T(4) and T(3) uptake by the liver. In mammals, caloric restriction is known to diminish transport of T(4) and T(3) into tissues. The present study examines whether this is also the case in chicken. Four-week-old chickens were subjected to a 24-h starvation period followed by refeeding. Blood and liver samples were collected at the start of refeeding and at different times of refeeding. Thyroid hormone levels were measured directly in plasma and in tissues following extraction. The results demonstrate that intrahepatic T(4) levels are increased and T(3) levels are decreased in fasted compared to ad libitum fed chickens. The parallel changes in plasma and hepatic T(3) and T(4) content demonstrate that T(4) availability in liver tissue is not diminished during fasting, suggesting that in chicken thyroid hormone uptake by the liver is not affected by nutritional status.     

Peripheral autoregulation of thyromimetic activity in man

This study describes an extrathyroidal mechanism for regulating serum concentration of triiodothyronine (T3) in thyroxine (T4) deficiency or excess. Serum levels of T3, T4, reverse T3 (rT3), and thyrotropin were determined in two series of athyreotic patients (n = 22 and n = 16, respectively) during various doses of T4 substitution therapy. The patients were followed from the severe hypothyroid state up to the modest hyperthyroid state, induced by stepwise increasing doses of administered T4. The periods of constant T4 replacement doses were 1 week (group I) and 5 weeks (group II), respectively. As serum T4 levels rose from less than 0.5 micrograms/dl to 18.9 micrograms/dl, serum T3 levels showed a curvilinear increase, which was pronounced in the very low T4 range while it was flattened at the higher end of the spectrum of T4 levels. As to rT3, an analogous course did not occur. The different character of the relationships between T4 and its conversion products was further elucidated by calculating the T3/T4 and rT3/T4 ratios. T3/T4 ratio declined fourfold from 43.3.10(-3) in the severe hypothyroid to 11.7.10(-3) in the hyperthyroid range. The results support the hypothesis of a peripheral autoregulation of T4 to T3 conversion which appears to be operative at both ends of the T4 spectrum and which serves to maintain or defend serum T3 levels.     

Triiodothyronine but not thyroxine accelerates myofibrillar proteolysis via ATP production in cultured muscle cells

These experiments were done to clarify that the differential effects of thyroxine (T(4)) and triiodothyronine (T(3)) on skeletal muscle protein turnover are caused by their roles on ATP production. Primary cultured chick muscle cells were treated with a physiological level of T(4) (60 ng/ml), T(3) (12 ng/ml), or ATP (0.5 mM) for 6 days and the protein content, ATP production, proteasome activity, and myofibrillar protein breakdown were measured. The protein content measured as an index of cell growth was not affected by T(4), T(3), or ATP. The cellular ATP level was increased by T(3) and ATP, but not by T(4). Proteasome activity and N(tau)-methylhistidine (MeHis) release measured as an index of myofiblillar protein breakdown was also increased by T(3) and ATP, but not by T(4). These results indicate that T(3) but not T(4) increases ATP production followed by an increase in proteasome activity, and thus stimulates myofibrillar proteolysis.     

Effects of thyroxine and 3,5,3'-triiodothyronine in brown adipose tissue of rats

Rats of both sexes were either cold acclimated (6 +/- 1 degree C) or treated with thyroxine (T4) or 3,5,3'-triiodothyronine (T3) (500 micrograms/kg body wt daily s.c. for 3 weeks). Wet weight, total proteins, lipids and nucleic acids in the interscapular brown adipose tissue (IBAT) were measured. Values obtained with T4 treatment were similar to those obtained with T3 treatment. T3 is the main thyroidal hormone in the rat and it is formed from T4 deiodination in liver and kidney. As T4-treated rats have not received T3 directly and its IBAT has a similar composition to that of T3-treated rats, it is concluded that peripheral T4 deiodination is governed by the plasma T4 levels. Total proteins and DNA content were similar in cold-acclimated and T3- or T4-treated rats, which is interpreted as thyroidal hormones having an action at these levels.     

Thyroxine and triiodothyronine in milk of cows, goats, sheep, and guinea pigs

Milk was collected for the first 21 days of lactation twice daily from dairy cows and once daily from goats, sheep, and guinea pigs. Thyroxine (T4) and triiodothyronine (T3) were extracted from 100 microliter of milk using acidified ethanol. T4 and T3 were reconstituted in 100 microliter buffer and measured by radioimmunoassay. Concentrations (ng/ml) of T4 and T3 for milk of cows, goats, sheep, and guinea pigs, respectively, were: 0.97 and 0.94, 1.24 and 0.52, 0.99 and 0.79, and 1.41 and 0.53. T4 concentration for guinea pig milk was significantly higher than for cow and sheep milk, but not for goat milk (P less than 0.05). T3 was found in higher concentration in milk of cows and sheep than in milk of goats and guinea pigs (P less than 0.05). Species differences in conversion of T4 to T3 in mammary gland cells are suggested. Summations of T4 and T3 concentrations in milk indicated no differences among the four species. Regression analyses of changes in milk production, T4 and T3 concentrations, total T4 and T3 in milk per day, and ratios of T4 to T3 revealed variations in patterns. Concentrations of T4 or T3 tended to decrease as lactation progressed over 21 days. Total T3 tended to increase, and the ratio of T4 to T3 tended to decrease. Amounts of T4 and T3 available to offspring from milk were calculated to be minor sources (4 to 7%) of total requirements for maintenance of metabolic functions.     

A study of hepatic metabolism of thyroxine in BB/W rats treated with L-thyroxine

The effect of thyroxine (T4) on T4 conversion to triiodothyronine (T3) and reverse T3 (rT3) was studied in BB/W rats. A colony of 38 BB/W rats was obtained and half were treated with thyroxine (T4), 1 mg per liter of drinking water. At 106 days of age the following groups were identified: nondiabetic, no T4 treatment, 8 rats; nondiabetic, T4 treated, 8 rats; diabetic, no T4 treatment, 10 rats; diabetic, T4 treated, 7 rats. All animals with diabetes were treated with insulin. T4 conversion to T3 and rT3 was assessed in liver homogenates in 0.1 M Tris-HCl buffer, pH 7.4, with or without 5 mM dithiothreitol (DDT). Serum T4 and rT3 were significantly elevated in both T4-treated groups (P less than 0.001), while serum T3 was not affected in either. Basal T4 deiodination to T3 by the liver homogenate did not change on treatment with T4; the addition of DTT increased T3 production in the homogenate from T4 treated nondiabetic animals (P less than 0.05). In both nondiabetic and insulin-treated diabetic rats there was no effect of T4 on the rate of rT3 production. Since, in the rat, 30-40% of circulating T3 is a direct contribution of thyroid gland secretion, and that would be absent in our T4-suppressed animals, the normal serum T3 may reflect increased absolute peripheral T3 production from the greater concentration of circulating T4.     

Estrus synchronization systems involving prostaglandin F(2alpha) and progesterone pretreatment in beef heifers

Two trials were conducted to evaluate treatments combining progesterone pretreatment and prostaglandin F(2alpha) (PGF(2alpha)) on estrus response, pregnancy and calving rate in heifers. Treatments in Trial 1 were 1) control (T(1); n=59), 2) 25 mg PGF(2alpha) on Day 0 (T(2); n=58), 3) 150 mg progesterone (P(4), i.m.) in corn oil on Day -24 plus PGF(2alpha) (T(3); n=61), and 4) 150 mg P(4) on Day -5 plus PGF(2alpha) (T(4); n=59). Trial 2 had T(2) and T(4) only. Heifers were artificially inseminated 8 to 16 h after detection of estrus for 10 and 5 d in Trials 1 and 2, respectively. In Trial 1 more heifers in T(3) and T(4) showed estrus by 72 h compared to T(1) and T(2). In T(3), percentages were greater at 84 and 96 h than in T(1) and T(2). There were no differences between T(3) and T(4) or T(1) and T(2) over time. Cumulative distributions of responses showed that more heifers in T(3) and T(4) were in estrus by 84 h after PGF(2alpha) than after other treatments, while T(3) showed the greatest total number of heifers in estrus by 84 h; this difference persisted for 180 h. In Trial 2, percentages of heifers observed in estrus for T(1) and T(4) were not different. Average interval from PGF(2alpha) to estrus was shorter in Trial 1 for T(3) heifers compared to other treatments. No difference was observed in interval to estrus for T(2) and T(4) in Trial 2; this interval averaged 58 h. Artificial insemination pregnancy rates were not different among treatments in either trial and averaged 67.4%. In Trial 1, a greater proportion of heifers in T(2), T(3) and T(4) calved by 35 days into the calving season compared to T(1), but in Trial 2 calving rates for T(2) and T(4) were not different. Progesterone pretreatment combined with PGF(2alpha) appeared to enhance estrus synchronization without influencing either pregnancy or calving rates.     

Anomalies in thyroid function in children with trisomy 21

Thyroid function of 60 children with Down (DS) aged 3 months to 16 years was studied by evaluation of serum concentration of ultra-sensitive thyroid stimulating hormone (TSH), free T4 and T3 (FT4, FT3), total T4 and T3 (T4 and T3) and reverse T3 (rT3). Each DS child was matched to a control of the same age. The concentration of TSH was increased in DS children while the concentration of rT3 of the DS children was significantly decreased compared to the controls as was the ratio rT3/TSH. These results showed that thyroid function of DS children is abnormal.     

Amiodarone inhibits T4 to T3 conversion and alpha-glycerophosphate dehydrogenase and malic enzyme levels in rat liver

Amiodarone has been found to decrease serum T3 by blocking peripheral T4 5'-deiodinase. This reduction in T3 levels may contribute to the effectiveness of this drug in moderating cardiac arrhythmias. To further characterize the effect of amiodarone on thyroid hormone metabolism and biological action, male Sprague-Dawley rats were thyroidectomized and then fed 500 ug T4 or 50 ug T3 and 500 mg amiodarone/kg of powdered diet for 6 to 8 weeks. Hepatic and cardiac levels of T4, T3, alpha-glycerophosphate dehydrogenase (GPD) and malic enzyme (ME) were used as indicators of thyroid hormone availability and action at the cellular level. Conversion of T4 to T3 was measured in liver homogenates. Serum TSH, T4 and T3 were also measured. Amiodarone reduced hepatic GPD and ME in thyroidectomized rats receiving dietary T4. Liver T4 levels were significantly increased by amiodarone and the T3/T4 ratio was reduced (P less than .05). Amiodarone inhibited hepatic T4 to T3 conversion and decreased serum T3. The decreased T3 action at the cellular level, indicated by the reduction in hepatic GPD and ME, is not due to pharmacologic effects of amiodarone since these enzyme levels were not affected by amiodarone in thyroidectomized rats replaced with T3.     

Identification and isolation of a T4+T8+ cell with high T3 expression in human thymus: a possible late intermediate in thymocyte differentiation

By using sensitive three-color fluorescence flow cytometric techniques, we were able to identify a T4+T8+ thymocyte with high T3 surface density (T3H) representing 4 to 9% of thymocytes. To characterize the T3HT4+T8+ cell, thymic subpopulations with high T3 surface density (T3H) and lower T3 density (T3L/T3-) were compared with regard to T6 expression. The T3H subpopulation was characterized by lower numbers of T6+ cells and reduced levels of T6 antigen density, whereas the T3L/T3- population was greater than 90% T6+ and expressed this antigen at high cell surface density. In addition, T3H fractions appeared to possess higher levels of nuclear activation with respect to the T3L/T3- population as indicated by increased log 90 degrees scatter profiles. These results suggest that thymocytes with high T3 surface expression are not only more differentiated, but also more activated than the majority of the thymic population. The T3HT4+T8+ fraction could be distinguished from T4+T8+ thymocytes with lower T3 density not only by an increased log 90 degrees scatter profile, but also by the presence of T4+T8+ cells with reduced levels of T8 surface antigen. Our results indicate that T4+T8+ thymocytes with high T3 surface density are a distinct subpopulation and may represent the immediate precursors of the phenotypically more mature T3HT4+T8- and T3HT8+T4- subpopulations found in human thymus.     

Acute, nongenomic effect of thyroid hormones in preventing calcium overload in newborn rat cardiocytes

In this study, we examined the acute effects of thyroid hormones (TH) T(3) and T(4), leading to improvement of myocardial function through activation of Ca(2+) extrusion mechanisms and, consequently, prevention of intracellular calcium overload. Extracellular calcium elevation from 1.8 to 3.8 mM caused immediate increase in intracellular calcium level ([Ca(2+)](i)) in newborn cardiomyocyte cultures. Administration of 10 or 100 nM T(3) or T(4) rapidly (within 10 sec) decreased [Ca(2+)](i) to its control level. Similar results were obtained when [Ca(2+)](i) was elevated by decreasing extracellular Na(+) concentration, causing backward influx of Ca(2+) through Na(+)/Ca(2+) exchanger, or by administration of caffeine, releasing Ca(2+) from the sarcoplasmic reticulum (SR). Under these conditions, T(3) or T(4) decreased [Ca(2+)](i). T(3) and T(4) also exhibited protective effects during ischemia. T(3) or T(4) presence during hypoxia for 120 min in culture medium restricted the increase of [Ca(2+)](i) and prevented the pathological effects of its overload. An inhibitor of SR Ca(2+)-ATPase (SERCA2a), thapsigargin, increases [Ca(2+)](i) and in its presence neither T(3) nor T(4) had any effect on the [Ca(2+)](i) level. The reduction of [Ca(2+)](i) level by T(3) and T(4) was also blocked in the presence of H-89 (a PKA inhibitor), and by calmodulin inhibitors. The effect of TH on the reduction of [Ca(2+)](i) was prevented by propranolol, indicating that the hormones exert their effect through interaction with adrenergic receptors. These results support our hypothesis that TH prevent calcium overload in newborn rat cardiomyocytes, most likely by a direct, acute, and nongenomic effect on Ca(2+) transport into the SR.     

3,5-T2 stimulates oxygen consumption, but not glucose uptake in human mononuclear blood cells.

L-thyroxine (T4), L-triiodothyronine (T3) and 3,5-di-iodothyronine (T2) rapidly (within 30 min) stimulated oxygen consumption in human mononuclear blood cells, whereas the D isomers of T4 and T3 and Triac had no stimulatory effect. Oxygen consumption was stimulated by the same magnitude by equimolar concentrations (5-500 nmol/l) of L-T4, L-T3 and 3,5-T2 reaching a plateau at 100 nmol/l of 0.025 umol/mg DNA x h. The stimulatory effects of T4 and T3, but not of T2 were inhibited by PTU. Glucose uptake was stimulated only by L-T4 and L-T3, whereas 3,5-T2, Triac and the D-isomers of T4 and T3 had no effect. The dose response curve reached an apparent maximum at 100 nmol/l of 0.30 mmol/l x mg DNA x h and PTU had no effect on iodothyronine stimulated glucose uptake. We conclude that 3,5-T2 is a significant intracellular stimulator of oxygen consumption, whereas T3 and T4 stimulate glucose uptake.     

The role of the L3T4 molecule in mitogen and antigen-activated signal transduction

We investigated the role of the L3T4 molecule in mitogen and antigen-initiated signal transduction in the L3T4(+) murine T cell hybridoma, 3DT52.5.9 and an L3T4(-) variant, 3DT52.5.24. Both Concanavalin A (Con A) and specific antigen stimulated increases in cytosolic-free calcium ([Ca2+]i), phosphatidylinositol turnover, and interleukin-2 (IL-2) production in both cell lines. About 85% of the stimulated rise in [Ca2+]i was from an extracellular source. Anti-L3T4 monoclonal antibody (MAb) inhibited 90% of antigen- and 50% of Con A-stimulated increases in [Ca2+]i and IL-2 production but had no effect on the ability of either activation signal to stimulate phosphatidylinositol turnover in the parent L3T4(+) cells. Stimulus-response coupling in the L3T4(-) cells was unaffected by the MAb. The anti-L3T4-insensitive increase in [Ca2+]i induced by Con A was inhibited by EGTA, suggesting that this mitogen also stimulated an influx of Ca2+ via an additional transport mechanism distinct from that stimulated by antigen. The fact that anti-L3T4 antibodies inhibit antigen and Con A-stimulated Ca2+ transport and IL-2 production without affecting phosphatidylinositol turnover suggests that L3T4 may play a critical role in modulating the activation of the T cell receptor-associated Ca2+ transporter in T cell stimulus-response coupling.     

Measurement of thyroid hormone concentrations in human placenta

Concentrations of thyroxine (T4), 3,5,3'-triiodothyronine (T3) and 3,3',5'-triiodothyronine (rT3) in the placenta were measured in 7 patients with abortion, in 9 patients with premature delivery, in 16 normal pregnancies and in 4 pregnant women with Graves' disease. The placentas, obtained at delivery, were homogenized and centrifuged at 800 X g. T4, T3 and rT3 concentrations in the supernatants were extracted with 3 vol. of 99% ethanol and measured by RIAs. In normal pregnancy, placental T4, T3 and rT3 concentrations were 18.8 +/- 5.9 (mean +/- SD), 0.026 +/- 0.012, and 1.70 +/- 0.49 ng/g tissue, respectively. Ratios of rT3/T3 and rT3/T4 in the placenta were about 12 and 2.3 times as high as those in the fetal sera, respectively. There was a significant positive correlation between the placental T4 and the maternal or cord serum T4 concentrations. However, no correlation was found between the placental T3 or rT3 concentrations and the maternal or cord T3 or rT3 concentrations. In 4 patients with Graves' disease, the placental T4 concentration was elevated. These results indicate that the placental T4 concentration is influenced by both the maternal and fetal serum T4, and elevated ratios of rT3/T3 and rT3/T4 in the placenta might be due to the active placental 5-monodeiodination.     

Effects of glucocorticoids on circulating concentrations of thyroxine (T4) and triiodothyronine (T3) and on peripheral monodeiodination in pre- and post-hatching chickens

The administration of either glucocorticoids (dexamethasone or corticosterone) or adrenocorticotropic hormone (ACTH) to chicken embryos was followed by increase in the circulating concentration of triiodothyronine (T3), the T3 to thyroxine (T4) ratio and the activity of liver T4-5' monodeiodinase. No consistent changes in plasma concentrations of T4 or GH were observed. In post-hatching chicks, corticosterone and dexamethasone depressed the circulating concentrations of both T4 and T3. Iopanoc acid, an inhibitor of liver T4-5' monodeiodinase, elevated plasma concentrations of T4 and depressed those of T3 in both chicken embryos and young chicks. It is suggested that glucocorticoids affect circulating concentrations of T4 and T3 both by affecting the activity of the liver T4-5' monodeiodinase and by influencing the hypothalamo-pituitary axis.     

Decline of T3 and elevation in reverse T3 induced by hyperglucagonemia: changes in thyroid hormone metabolism, not altered release of thyroid hormones

Recently we reported that hyperglucagonemia induced by glucagon infusion causes a decline in serum Triiodothyronine (T3) and a rise in reverse T3 (rT3) in euthyroid healthy volunteers. These changes in T3 and rT3 levels were attributed to altered T4 metabolism in peripheral tissues. However, the contribution of altered release of thyroid hormones by the thyroid gland could not be excluded. Since the release of thyroid hormones is suppressed by exogenous administration of L-thyroxine (L-T4) in appropriate dosage, we studied thyroid hormone levels for up to 6 hours after intravenous administration of glucagon in euthyroid healthy subjects after administration of L-T4 for 12 weeks. A control study was conducted using normal saline infusion. Plasma glucose rose promptly following glucagon administration demonstrating its physiologic effect. Serum T4, Free T4 and T3 resin uptake were not altered during both studies. Glucagon infusion induced a significant decline in serum T3 (P less than 0.01) and a marked rise in rT3 (P less than 0.01) whereas saline administration caused no alterations in T3 or rT3 levels. Thus the changes in T3 and rT3 were significantly different during glucagon study when compared to saline infusion. (P less than 0.01 for both comparisons). Therefore, this study demonstrates that changes in serum T3 and rT3 caused by hyperglucagonemia may be secondary to altered thyroid hormone metabolism in peripheral tissues and not due to altered release by the thyroid gland, since the release of thyroid hormones is suppressed by exogenous L-T4 administration.     

Role of gonadal and adrenal steroids and thyroid hormones in the regulation of molting in domestic goose

Plasma levels of testosterone (T), 17-β-estradiol (E2), progesterone (P4), dehydroepiandrosterone (DHEA), corticosterone (B), thyroxine (T4) and triiodothyronine (T3) were monitored during postnuptial and the prenuptial molt in domestic goose (Anser anser domesticus) in both sexes. 1. At the beginning of postnuptial molt (when the old, worn dawny-, and cover feathers' loss starts) in ganders, the levels of T, E2, P4 decrease while DHEA and B significantly increase. The elevated levels of T4 and low T3 concentrations characteristic of the last phase of the reproduction, remain unchanged. In layers, similar changes were observed, however, B decreases. 2. In the early phase of outgrowth of wing and cover feathers, plasma levels of T, E2 and P4 are low. Elevated B, DHEA and T4 concentrations decrease in ganders, while in layers DHEA increases and B and T4 levels remain unchanged. T3 increases in both sexes. 3. The subsequent intensive outgrowth period of wing- and cover feathers both in ganders and in layers is characterized by very low levels of T, E2, DHEA and T4, but P4 increased, and T3 concentration remain high. 4. At the end of postnuptial molt - when the outgrowth of dawny, cover-, and wing feathers stops - very low T, E2, P4, DHEA and T4 levels and and high T3 plasma levels were found in both sexes. Fast increase of plasma B was detected in ganders, while in geese, B concentration remain high. 5. During prenuptial molting (outgrowth of contour and tail feathers) low E2, P4 and T4, increasing T and DHEA, but very high T3 and B plasma concentration were measured in ganders. In layers, very low T, E2, P4, DHEA and T4 levels, and very high B and T3 levels were found. 6. At the beginning of the fall-winter sexual repose (postmolting stage) T, E2, P4, DHEA and T4 levels increase, T3 and B declines in both sexes. 7. In the subsequent phase of fall-winter period (preparatory stage) there is a further increase in T, P4 and T4, a fast increase of B and a decrease of E2, DHEA and T3 in ganders. In layers, T, P4 and DHEA decrease, B increases and the T4 and T3 do not change. 8. At the beginning of reproduction high T level, unchanged DHEA, slightly declined P4, and decreased E2, T4, T3 and a strong decline of B concentrations occur in ganders. In layers, T is further increased, E2 and P4 shows high levels, and, at the same time DHEA and T3 remain unchanged, while B and T4 decrease.     

Graft-vs-host reaction limited to a class II MHC difference results in a selective deficiency in L3T4+ but not in Lyt-2+ T helper cell function

Hybrid mice of the (B6 X bm12)F1 combination were inoculated i.v. with parental B6 spleen cells to induce a class II graft-vs-host disease (GVH). Such mice failed to generate in vitro cytotoxic T lymphocyte (CTL) responses that were dependent upon L3T4+ T helper cell (Th) function (e.g., anti-B6-TNP) but were capable of generating in vitro CTL responses that could be mediated by Lyt-2+ Th cells (anti-allo class I). When Th function was assayed directly by interleukin 2 (IL 2) secretion, class II GVH animals were found to be deficient in L3T4+ but not Lyt-2+ IL 2-secreting Th cells. This selective deficiency in L3T4+ Th function correlates with a selective decrease in class II GVH mice of host-derived derived L3T4+ T cells. In addition, it was found that the spleens of class II GVH mice contained cells capable of selectively suppressing L3T4+ Th function. In contrast, mice in which a class I + II GVH occurred were depleted of both L3T4+ and Lyt-2+ Th function as assessed by IL 2 production. The findings that class II GVH selectively depletes L3T4+ T cells and T cell functions are discussed with respect to the immune function of distinct T cell subsets in normal and diseased states.