Jack H. Oppenheimer

Jack H. Oppenheimer's AcademicInfluence.com Rankings

Jack H. Oppenheimer

Biology

#5962

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#8571

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Developmental Biology

#63

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#67

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Molecular Biology

#586

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#600

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Neuroscience

#700

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#732

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Biology

Jack H. Oppenheimer's Degrees

PhD Molecular Biology University of California, San Diego
Bachelors Biology Stanford University

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Jack H. Oppenheimer's Published Works

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Total number of citations to an author for the works they published in a given year. This highlights publication of the most important work(s) by the author

Published Works

Molecular basis of thyroid hormone-dependent brain development. (1997) (513)
Thyroid hormone action at the cellular level. (1979) (476)
Advances in our understanding of thyroid hormone action at the cellular level. (1987) (441)
Tissue differences in the concentration of triiodothyronine nuclear binding sites in the rat: liver, kidney, pituitary, heart, brain, spleen, and testis. (1974) (438)
High incidence of decreased serum triiodothyronine concentration in patients with nonthyroidal disease. (1975) (371)
Replacement dose, metabolism, and bioavailability of levothyroxine in the treatment of hypothyroidism. Role of triiodothyronine in pituitary feedback in humans. (1987) (350)
Specific nuclear triiodothyronine binding sites in rat liver and kidney. (1972) (304)
Relationship of c-erbA mRNA content to tissue triiodothyronine nuclear binding capacity and function in developing and adult rats. (1990) (288)
Functional relationship of thyroid hormone-induced lipogenesis, lipolysis, and thermogenesis in the rat. (1991) (260)
BINDING OF THYROXINE BY SERUM PROTEINS EVALUATED BY EQUILIBRUM DIALYSIS AND ELECTROPHORETIC TECHNIQUES. ALTERATIONS IN NONTHYROIDAL ILLNESS. (1963) (246)
Role of plasma proteins in the binding, distribution and metabolism of the thyroid hormones. (1968) (244)
Propylthiouracil inhibits the conversion of L-thyroxine to L-triiodothyronine. An explanation of the antithyroxine effect of propylthiouracil and evidence supporting the concept that triiodothyronine is the active thyroid hormone. (1972) (237)
Determination of iodothyronine absorption and conversion of L-thyroxine (T 4 ) to L-triiodothyronine (T 3 ) using turnover rate techniques. (1973) (216)
Molecular Basis of Thyroid Hormone Action (1983) (195)
Thermogenesis and thyroid function. (1995) (182)
Quantitation of rat tissue thyroid hormone binding receptor isoforms by immunoprecipitation of nuclear triiodothyronine binding capacity. (1992) (175)
A new radioimmunoassay for plasma L-triiodothyronine: measurements in thyroid disease and in patients maintained on hormonal replacement. (1972) (174)
Replacement dosage of L-thyroxine in hypothyroidism. A re-evaluation. (1974) (164)
Quantitation of extrathyroidal conversion of L-thyroxine to 3,5,3'-triiodo-L-thyronine in the rat. (1971) (158)
Ontogenesis of 3,5,3'-triiodothyronine receptors in neonatal rat brain: dissociation between receptor concentration and stimulation of oxygen consumption by 3,5,3'-triiodothyronine. (1978) (156)
Nuclear receptors and the initiation of thyroid hormone action. (1976) (155)
Increased thyroxine turnover and thyroidal function after stimulation of hepatocellular binding of thyroxine by phenobarbital. (1968) (155)
Limited capacity binding sites for L-triiodothyronine in rat liver nuclei. Localization to the chromatin and partial characterization of the L-triiodothyronine-chromatin complex. (1973) (148)
Thyroid hormone attenuates and augments hepatic gene expression at a pretranslational level. (1981) (147)
Depression of the serum protein-bound iodine level by diphenylhydantion. (1961) (146)
Determination of common parameters fo iodothyronine metabolism and distribution in man by noncompartmental analysis. (1975) (143)
Binding of selected iodothyronine analogues to receptor sites of isolated rat hepatic nuclei. High correlation between structural requirements for nuclear binding and biological activity. (1975) (141)
Levothyroxine dose requirements for thyrotropin suppression in the treatment of differentiated thyroid cancer. (1992) (141)
A rapid, inexpensive, quantitative technique for the analysis of two-dimensional electrophoretograms. (1982) (137)
Limited binding capacity sites for L-triiodothyronine in rat liver nuclei. Nuclear-cytoplasmic interrelation, binding constants, and cross-reactivity with L-thyroxine. (1974) (134)
Stimulation of hepatic mitochondrial alpha-glycerophosphate dehydrogenase and malic enzyme by L-triiodothyronine. Characteristics of the response with specific nuclear thyroid hormone binding sites fully saturated. (1977) (133)
Synergism of thyroid hormone and high carbohydrate diet in the induction of lipogenic enzymes in the rat. Mechanisms and implications. (1980) (131)
Rapid effects of triiodothyronine on hepatic gene expression. Hybridization analysis of tissue-specific triiodothyronine regulation of mRNAS14. (1984) (125)
Evidence for a factor in the sera of patients with nonthyroidal disease which inhibits iodothyronine binding by solid matrices, serum proteins, and rat hepatocytes. (1982) (123)
1 – The Nuclear Receptor–Triiodothyronine Complex: Relationship to Thyroid Hormone Distribution, Metabolism, and Biological Action (1983) (122)
Stereospecific transport of triiodothyronine from plasma to cytosol and from cytosol to nucleus in rat liver, kidney, brain, and heart. (1985) (122)
Concentration of L-thyroxine and L-triiodothyronine specifically bound to nuclear receptors in rat liver and kidney. Quantitative evidence favoring a major role of T3 in thyroid hormone action. (1977) (116)
Changes in the hepatic levels of messenger ribonucleic acid for malic enzyme during induction by thyroid hormone or diet. (1980) (113)
Quantitative aspects of iodothyronine binding by cytosol proteins of rat liver and kidney. (1974) (103)
In vitro binding of L-triiodothyronine to receptors in rat liver nuclei. Kinectics of binding, extraction properties, and lack of requirement for cytosol proteins. (1975) (103)
Beta 1 isoform-specific regulation of a triiodothyronine-induced gene during cerebellar development. (1992) (103)
Immunofluorescence localization of thyroid hormone receptor protein beta 1 and variant alpha 2 in selected tissues: cerebellar Purkinje cells as a model for beta 1 receptor-mediated developmental effects of thyroid hormone in brain. (1991) (103)
Widespread distribution of immunoreactive thyroid hormone beta 2 receptor (TR beta 2) in the nuclei of extrapituitary rat tissues. (1994) (102)
Nuclear triiodothyronine receptor sites in brain: probable identity with hepatic receptors and regional distribution. (1978) (102)
Effect of prednisone on thyroxine-binding proteins. (1966) (101)
High basal expression and 3,5,3'-triiodothyronine regulation of messenger ribonucleic acid S14 in lipogenic tissues. (1985) (98)
Free fatty acids: a possible regulator of free thyroid hormone levels in man. (1967) (97)
DETERMINATION OF FREE THYROXINE IN HUMAN SERUM: A THEORETICAL AND EXPERIMENTAL ANALYSIS. (1964) (95)
Thyroid hormone action at the nuclear level. (1985) (95)
Effect of thyroid hormone analogues on the displacement of 125I-L-triiodothyronine from hepatic and heart nuclei in vivo: possible relationship to hormonal activity. (1973) (94)
Specific Triiodothyronine Binding Sites in the Anterior Pituitary of the Rat (1972) (92)
Estimation of rapidly exchangeable cellular thyroxine from the plasma disappearance curves of simultaneously administered thyroxine-131-I and albumin-125-I. (1967) (92)
Lack of effect of thyroid hormone on late fetal rat brain development. (1997) (90)
Rapid synergistic interaction between thyroid hormone and carbohydrate on mRNAS14 induction. (1986) (90)
Decreased serum triiodothyronine in starving rats is due primarily to diminished thyroidal secretion of thyroxine. (1985) (86)
Metabolism of Iodine-131-Labeled Thyroxine-Binding Prealbumin in Man (1965) (85)
In vitro demonstration of specific triiodothyronine binding sites in rat liver nuclei. (1974) (84)
Immunocytochemical delineation of thyroid hormone receptor beta 2-like immunoreactivity in the rat central nervous system. (1993) (81)
Nuclear binding capacity appears to limit the hepatic response to L-triiodothyronine (T3). (1975) (81)
Interactions of thyroid hormone, growth hormone, and high carbohydrate, fat-free diet in regulating several rat liver messenger ribonucleic acid species. (1983) (79)
Differences in primary cellular factors influencing the metabolism and distribution of 3,5,3'-L-triiodothyronine and L-thyroxine. (1970) (79)
Nonlinear (amplified) relationship between nuclear occupancy by triiodothyronine and the appearance rate of hepatic alpha-glycerophosphate dehydrogenase and malic enzyme in the rat. (1978) (73)
Identification of thyroid hormone response elements in rodent Pcp-2, a developmentally regulated gene of cerebellar Purkinje cells. (1994) (73)
Partial purification of the triiodothyronine receptor from rat liver nuclei. Differences in the chromatographic mobility of occupied and unoccupied sites. (1977) (73)
Thyroid hormone action 1994: the plot thickens. (1994) (73)
An unsolved problem. Low serum PBI values in patients with chronic disease. (1969) (72)
Glucose and triiodothyronine both induce malic enzyme in the rat hepatocyte culture: evidence that triiodothyronine multiplies a primary glucose-generated signal. (1981) (72)
Studies on the thyroxine-diphenylhydantoin interaction: effect of 5,5'-diphenylhydantoin on the displacement of L-thyroxine from thyroxine-binding globulin (TBG). (1962) (70)
Comparison of the metabolism and distribution of L-triiodothyronine and triiodothyroacetic acid in the rat: a possible explanation of differential hormonal potency. (1976) (69)
Selective alterations in hepatic enzyme response after reduction of nuclear triiodothyronine receptor sites by partial hepatectomy and starvation. (1978) (67)
Displacement of thyroxine from human thyroxine-binding globulin by analogues of hydantoin. Steric aspects of the thyroxinebinding site. (1962) (65)
The regulation of lipogenesis by thyroid hormone and its contribution to thermogenesis. (1989) (65)
Immunofluorescent localization of thyroid hormone receptor isoforms in glial cells of rat brain. (1994) (63)
An analysis of the interrelationship of nuclear and plasma triiodothyronine in the sea lamprey, lake trout, and rat: evolutionary considerations. (1987) (62)
A pituitary parasellar tumor with extracranial metastases and high, partially suppressible levels of adrenocorticotropin and related peptides. (1983) (61)
POSTOPERATIVE CHANGES IN THE CONCENTRATION OF THYROXINE-BINDING PREALBUMIN AND SERUM FREE THYROXINE. (1964) (59)
Factors influencing the concentration of free and total thyroxine in patients with nonthyroidal disease. (1966) (59)
Nuclear receptors for 3,5,3'-triiodothyronine in human liver and kidney: characterization, quantitation, and similarities to rat receptors. (1979) (58)
Time course of hepatic 3-hydroxy-3-methylglutaryl coenzyme A reductase activity and messenger ribonucleic acid, biliary lipid secretion, and hepatic cholesterol content in methimazole-treated hypothyroid and hypophysectomized rats after triiodothyronine administration: possible linkage of cholestero (1989) (58)
Isoform-specific 3,5,3'-triiodothyronine receptor binding capacity and messenger ribonucleic acid content in rat adenohypophysis: effect of thyroidal state and comparison with extrapituitary tissues. (1996) (57)
Endocrine Manifestations of Intracranial Extrasellar Lesions (1962) (57)
Thyroid hormone receptor isoform content in cultured type 1 and type 2 astrocytes. (1996) (56)
Revised nomenclature for tests of thyroid hormones and thyroid-related proteins in serum. (1987) (55)
Transcellular and transnuclear transport of 3,5,3'-triiodothyronine in isolated hepatocytes. (1985) (55)
Stimulation of S14 mRNA and lipogenesis in brown fat by hypothyroidism, cold exposure, and cafeteria feeding: evidence supporting a general role for S14 in lipogenesis and lipogenesis in the maintenance of thermogenesis. (1987) (55)
Comparison of the response characteristics of four lipogenic enzymes to 3,5,3'-triiodothyronine administration: evidence for variable degrees of amplification of the nuclear 3,5,3'-triiodothyronine signal. (1980) (54)
Two unusual variants of Nelson's syndrome. (1979) (54)
Paradoxical effects of cycloheximide on the ultra-rapid induction of two hepatic mRNA sequences by triiodothyronine (T3). (1982) (53)
Quantitation of rat liver messenger ribonucleic acid for malic enzyme during induction by thyroid hormone. (1981) (52)
ISOLATION AND CHARACTERIZATION OF HUMAN THYROXINE-BINDING PREALBUMIN. (1965) (51)
Acromegaly: reassessment of the long-term therapeutic effectiveness of transsphenoidal pituitary surgery. (1981) (49)
Ontogeny of hepatic nuclear triiodothyronine receptor isoforms in the rat. (1992) (49)
Beta receptor isoforms are not essential for thyroid hormone-dependent acceleration of PCP-2 and myelin basic protein gene expression in the developing brains of neonatal mice (1998) (48)
Physiologic and biochemical actions of thyroid hormone. (1978) (48)
Chicken Ovalbumin Upstream Promoter-Transcription Factor (COUP-TF) Modulates Expression of the Purkinje Cell Protein-2 Gene (1998) (48)
A therapeutic controversy. Thyroid hormone treatment: when and what? (1995) (47)
Response to thyrotropin releasing hormone: an objective criterion for the adequacy of thyrotropin suppression therapy. (1977) (47)
Formation of iodoprotein during the peripheral metabolism of 3,5,3'-triiodo-L-thyronine-125I in the euthyroid man and rat. (1969) (45)
Evolving concepts of thyroid hormone action. (1999) (45)
Factors determining the level of activity of 3,5,3'-triiodothyronine-responsive hepatic enzymes in the starved rat. (1980) (45)
Glucagon administration decreases hepatic nuclear triiodothyronine binding capacity. (1978) (45)
Glucagon influences the expression of thyroid hormone action: discrepancy between nuclear triiodothyronine receptor number and enzyme responses. (1979) (45)
Resistance to thyroid hormones. A disorder frequently confused with Graves' disease. (1982) (44)
Transient stimulation of myelin basic protein gene expression in differentiating cultured oligodendrocytes: a model for 3,5,3'-triiodothyronine-induced brain development. (1997) (43)
Relationship between the accumulation of pituitary growth hormone and nuclear occupancy by triiodothyronine in the rat. (1978) (43)
Determination of the maximal binding capacity and protein concentration of thyroxine-binding prealbumin in human serum. (1966) (42)
Hepatic accumulation of 125I-thyroxine in the rat: augmentation by phenobarbital and chlordane. (1968) (42)
Triiodothyronine-stimulated formation of poly(A)-containing nuclear RNA and mRNA in rat liver. (1978) (41)
Stimulation of malic enzyme formation in hepatocyte culture by metabolites: evidence favoring a nonglycolytic metabolite as the proximate induction signal. (1984) (41)
Messenger RNA content and complexity of euthyroid and hypothyroid rat liver. (1979) (40)
Thyroid hormone receptor-containing fragment released from chromatin by deoxyribonuclease I and micrococcal nuclease. (1980) (39)
The metabolic significance of exchangeable cellular thyroxine. (1969) (37)
Disturbance of the pituitary-adrenal interrelationship in diseases of the central nervous system. (1961) (37)
Age-related reduction in response of hepatic enzymes to 3,5,3'-triiodothyronine administration. (1979) (37)
Starvation and hypothyroidism exert an overlapping influence on rat hepatic messenger RNA activity profiles. (1983) (36)
Thyroid hormone-carbohydrate interaction in the rat: correlation between age-related reductions in the inducibility of hepatic malic enzyme by triiodo-L-thyronine and a high carbohydrate, fat-free diet. (1981) (35)
Distribution and metabolism of L- and D-triiodothyronine (T3) in the rat: preferential accumulation of L-T3 by hepatic and cardiac nuclei as a probable explanation of the differential biological potency of T3 enantiomers. (1983) (35)
Analysis of the rapid interchange of thyroxine between plasma and liver and plasma and kidney in the intact rat. (1968) (35)
Letter: (to the editor). Erratum: revised calculations of common parameters of iodothyronine metabolism and distribution by noncompartmental analysis. (1975) (34)
Quantitative investigation of hepatic genomic response to hormonal and pathophysiological stimuli by multivariate analysis of two-dimensional mRNA activity profiles. (1984) (34)
Quantitative assessment of pituitary resistance to thyroid hormone from plots of the logarithm of thyrotropin versus serum free thyroxine index. (2000) (34)
Nuclear Receptors for Triiodothyronine: A Physiological Perspective (1978) (31)
Effect of phenobarbital administration on the subcellular distribution of 125-I-thyroxine in rat liver: mportance of microsomal binding. (1969) (31)
Opposing effects of glucagon and triiodothyronine on the hepatic levels of messenger ribonucleic acid S14 and the dependence of such effects on circadian factors. (1986) (30)
Chromatin structure and methylation state of a thyroid hormone-responsive gene in rat liver. (1987) (30)
Metabolism of phenolic- and tyrosyl-ring labeled L-thyroxine in human beings and rats. (1971) (30)
Purkinje cell protein-2 cis-elements mediate repression of T3-dependent transcriptional activation (1997) (30)
Radioiodinated impurities in commercial preparations of 131-I-thyroxine and their effect on the measurement of free thyroxine in human serum by equilibrium dialysis. (1967) (29)
T3 stimulates the synthesis of a specific mRNA in primary hepatocyte culture. (1984) (29)
Association of the thyroid hormone receptor with rat liver chromatin. (1981) (29)
Triiodothyronine nuclear binding capacity in rat tissues correlates with a 6.0 kilobase (kb) and not a 2.6 kb messenger ribonucleic acid hybridization signal generated by a human c-erbA probe. (1988) (28)
Nuclear receptors and thyroid hormone action: a progress report. (1979) (28)
Rat hepatic mRNA-S14 and lipogenic enzymes during weaning: role of S14 in lipogenesis. (1987) (28)
Interrelationship of triiodothyronine concentration, metabolism, protein binding, and nuclear occupancy in the induction of malic enzyme by cultured adult rat hepatocytes. (1983) (25)
Prolonged fasting reduces rat hepatic beta 1 thyroid hormone receptor protein without changing the level of its messenger ribonucleic acid. (1991) (24)
Heparin administration appears to decrease cellular binding of thyroxine. (1973) (24)
Thyroxine stimulation of amino acid incorporation into mitochondrial protein: differences between in vivo and in vitro effects. (1973) (24)
Slow fractional removal of nonextractable iodine from rat tissue after injection of labeled L-thyroxine and 3,5,3'-triiodo-L-thyronine. A possible clue to the mechanism of initiation and persistence of hormonal action. (1972) (24)
Increased Deiodination of L-Thyroxine and L-Triiodothyronine by Liver Microsomes from Rats treated with Phenobarbital (1969) (23)
Diurnal variation in hepatic expression of the rat S14 gene is synchronized by the photoperiod. (1987) (23)
Kinetics of induction by thyroid hormone of the two hepatic mRNAs coding for cytosolic malic enzyme in the hypothyroid and euthyroid states. Evidence against an obligatory role of S14 protein in malic enzyme gene expression. (1989) (23)
Triiodothyronine rapidly reverses inhibition of S14 gene transcription by glucagon. (1988) (23)
The laboratory evaluation of thyroid function. (1979) (23)
Common clinical indices of thyroid hormone action: relationships to serum free 3,5,3'-triiodothyronine concentration and estimated nuclear occupancy. (1980) (23)
Multihormonal regulation and kinetics of induction of a hepatic mRNA sequence which is slowly responsive to triiodothyronine. (1986) (22)
Dissociation between thyroxine metabolism and hormonal action in phenobarbital-treated rats. (1971) (22)
Anterior mediastinal mass in a patient with Graves' disease. (1982) (21)
Comparison of effectiveness of thyrotropin-suppressive doses of D- and L-thyroxine in treatment of hypercholesterolemia. (1984) (21)
Incomplete suppression of thyrotropin secretion after single injection of large L-triiodothyronine doses into hypothyroid rats. (1976) (21)
Abnormalities of Thyroxine Binding in Analbuminemia1 (1968) (21)
Stereospecific transport of triidothyronine to cytoplasm and nucleus in GH1 cells (1986) (21)
Labile proteins are necessary for T3 induction of growth hormone mRNA in normal rat pituitary and rat pituitary tumor cells. (1987) (21)
CLINICAL ENDOCRINOLOGY & METABOLISM (1992) (21)
TSH response to TRH in euthyroid, hypercholesterolemic patients treated with graded doses of dextrothyroxine. (1981) (20)
Tissue iodoprotein formation during the peripheral metabolism of the thyroid hormones. (1969) (19)
Breast cancer and thyroid therapy. Statement by the American Thyroid Association. (1977) (19)
Effects of triiodothyronine and glucose on cultured rat hepatocyte gene expression. (1983) (19)
Triiodothyronine-Induced Gene during Cerebellar Development (1992) (19)
Inhibition of malic enzyme induction by triiodothyronine in the diabetic rat: reversal by fructose feeding. (1980) (18)
Limitations in the conventional analysis of the interaction of triiodothyronine with solubilized nuclear receptor sites. Inapparent binding of triiodothyronine to nonspecific binding sites. (1981) (18)
Comparison of age-related decreases in the basal and carbohydrate inducible levels of lipogenic enzymes in adipose tissue and liver. (1983) (18)
Differences in antibody recognition of the triiodothyronine nuclear receptor and c-erbA products. (1988) (18)
LETTER TO THE EDITOR: Turnover of 131I-Thyroxine in Patients Subjected to Surgical Trauma1 (1967) (18)
Identification of rat S14 protein and comparison of its regulation with that of mRNA S14 employing synthetic peptide antisera. (1989) (17)
Immunofluorescence localization of thyroid hormone receptor protein /31 and variant a2 in selected tissues: Cerebellar Purkinje cells as a model for /81 receptor-mediated developmental effects of thyroid hormone in brain (17)
Effect of penicillin on thyroxine-binding by plasma proteins. (1963) (17)
CHAPTER 5 – Biochemical Basis of Thyroid Hormone Action (1975) (16)
Alpha-amanitin administration results in a temporary inhibition of hepatic enzyme induction by triiodothyronine: further evidence favoring a long-lived mediator of thyroid hormone action. (1977) (16)
Influence of Cortisone on Leptomeningeal Reaction Induced by Talc.∗ (1953) (16)
Thyroid hormone-, carbohydrate, and age-dependent regulation of a methylation site in the hepatic S14 gene. (1989) (16)
Abnormalities of thyroxine binding in analbuminemia. (1968) (15)
9 – Thyroid Hormone–Carbohydrate Interaction (1983) (15)
Hepatic messenger ribonucleic acid activity profiles in experimental azotemia in the rat. Relationship to food intake and thyroid function. (1984) (14)
Composition of nonextractable radioactivity formed after injection of labeled L-thyroxine and 3,5,3'-triiodo-L-thyronine in rats. (1970) (14)
Molecular mechanisms of thyroid hormone action. A physiologic perspective. (1993) (14)
Thyroid hormones influence starvation-induced hepatic protein loss in the rat: possible role of thyroid hormones in the generation of labile protein. (1980) (14)
Effect of Thyroid Hormone on the Ploidy of Rat Liver Nuclei as Determined by Flow-Cytometry (1978) (14)
Interaction of dietary carbohydrate and glucagon in regulation of rat hepatic messenger ribonucleic acid S14 expression: role of circadian factors and 3',5'-cyclic adenosine monophosphate. (1987) (13)
Triiodothyronine regulation of multiple rat hepatic genes: requirement for ongoing protein synthesis. (1987) (13)
INTERACTION OF DRUGS WITH THYROID HORMONE BINDING SITES * (1973) (13)
Interaction of thyroid hormone and nutritional signals on thyroid hormone action (1985) (13)
American thyroid association statement: breast cancer and thyroid hormone therapy. (1977) (13)
Dissociation of hepatic messenger ribonucleic acidS14 levels and nuclear transcriptional rates in suckling rats. (1986) (12)
Pituitary tumor with primary hypothyroidism. Possible etiologic relationship. (1975) (12)
Revised nomenclature for tests of thyroid hormones and thyroid-related proteins in serum. (1987) (12)
Thyroidectomy increases rat hepatic ferritin iron. (1981) (11)
Difference between thyroidectomized and hypophysectomized animals in their hepatic ribonucleic acid response to thyroid hormone. (1980) (11)
Thyroid hormone and circadian regulation of the binding activity of a liver-specific protein associated with the 5'-flanking region of the S14 gene. (1989) (11)
The molecular basis of thyroid hormone action: scattered pieces of jigsaw puzzle. (1981) (10)
Morphological and functional studies of thyroid tissue cultures. (1956) (10)
Cellular and plasma protein determinants in the differential distribution and metabolism of D- and L-thyroxine in the rat. (1971) (10)
Interaction of T3 and carbohydrate in the induction of lipogenic enzymes. (1981) (9)
Growth hormone acts at a pretranslational level in hepatocyte cultures. (1983) (9)
Tissue-specific regulation of malic enzyme by thyroid hormone in the neonatal rat. (1996) (9)
Use of Thyroxine-Displacing Drugs in Identifying Serum Thyroxine-Binding Proteins Separated by Starch Gel Electrophoresis.∗ (1963) (9)
In vitro formation of apparent covalent complexes between L-triiodothyronine and plasma protein. (1973) (8)
Demonstration of membrane-linked iodoprotein in hepatic microsomes following metabolism of the thyroid hormones. (1970) (8)
Thyroid hormones in liver. (1972) (8)
Thyroid function tests in nonthyroidal disease. (1982) (8)
Replacement Treatment of Hypothyroidism (1974) (8)
Distribution of thyroid hormone-responsive translated products in rat liver polysome and postribosomal ribonucleoprotein populations. (1984) (8)
Formation of nondissociable hormone-protein complexes during the in vitro incubation of L-thyroxine and 3,5,3'-triiodo-L-thyronine with hepatic microsomes. (1971) (7)
Use of the dexamethasone-adrenocorticotropin test to assess the requirement for continued glucocorticoid replacement therapy after pituitary surgery. (1985) (7)
Turnover of 131-I-thyroxine in patients subjected to surgical trauma. (1967) (7)
Regulation of gene S-14 by triiodothyronine in liver. (1987) (7)
Thermodynamics of triiodothyronine nuclear receptor interaction. Role of hydrophobicity in triiodothyronine binding to its receptor. (1982) (7)
Studies of a thyroid hormone and androgen dependent protein in rat liver cytosol. (1977) (6)
The peripheral action of the thyroid hormones. (1975) (6)
Molecular mechanisms at the tissue level in hyperthyroidism. (1978) (6)
Thyroid Function & Disease (1989) (6)
Kinetic model of the response of precursor and mature rat hepatic mRNA-S14 to thyroid hormone. (1994) (5)
Hepatic messenger ribonucleic acid activity profile of rats subjected to alterations in thyroidal and adrenocortical states: evidence for significant interaction. (1985) (5)
[47] Methods for determining the conversion of l-thyroxine (T4) to l-triiodothyronine (T3) (1975) (5)
American Thyroid Association statement on breast cancer and thyroid hormone therapy. (1977) (5)
Evidence for post-transcriptional effects of T3 on hepatic ferritin synthesis. (1982) (4)
Possible clues in the continuing search for the subcellular basis of thyroid hormone action. (1973) (4)
4 – Distribution and Metabolism of the Thyroid Hormones (1990) (4)
A method of preparative starch-gel electrophoresis. (1966) (4)
Cycloheximide inhibits S-14 gene transcription and abolishes DNase I hypersensitive S-14 sites in the livers of euthyroid but not hypothyroid rats. (1987) (4)
Effect of thyroid hormones and high carbohydrate feeding on gene expression in rat epididymal adipose tissue. (1987) (4)
Thyroid hormone-carbohydrate interaction at the hepatic nuclear level. (1982) (4)
A purkinje cell protein-2 intronic thyroid hormone response element binds developmentally regulated thyroid hormone receptor-nuclear protein complexes (2007) (3)
Hypercortisolism due to an autonomously functioning pituitary adenoma: limitations in diagnostic test procedures. (1988) (3)
Association of thyroid hormone receptors with chromatin (2004) (2)
Interaction of Thyroid Hormone and Carbohydrates on Hepatic Gene Expression (1987) (2)
Direct measurement of L thyroxine (T4) and L triiodothyronine (T3) at thyroid hormone receptor sites in rat liver nuclei (1976) (2)
Thyroid hormones: comparative structural requirements for activity in vivo and for binding to rat liver nuclei. (1975) (2)
Bone minerals and levothyroxine. Authors' replies (1992) (2)
Methods for determining the conversion of L-thyroxine (T4) TO L-triiodothyronine (T3)1. (1975) (1)
Recurrent episodes of spontaneously resolving hyperthyroidism due to thyroiditis. (1983) (1)
Interaction of thyroid hormones with target tissues: effects of hepatic mRNA population. (1979) (1)
Ontogeny of Hepatic Nuclear Triiodothyronine Isoforms in the Rat (1992) (1)
Recent studies of thyroid hormone action at the hepatocellular level. (1984) (1)
6 – Measurement of Thyroid Function (1990) (1)
5 – Tissue and Cellular Effects of Thyroid Hormones and Their Mechanism of Action (1990) (0)
CHAPTER 33 – Abnormalities of Neuroendocrine Functions in Man (1967) (0)
Iodinated lipids: a possible artifact in isotopic equilibration with dietary iodide. (1968) (0)
ATA statement on breast cancer and thyroid hormone therapy. (1977) (0)
Stimulation ofS14mRNA andlipogenesis inbrownfatby hypothyroidism, coldexposure, andcafeteria feeding: Evidence supporting ageneral roleforS14inlipogenesis andlipogenesis in themaintenance ofthermogenesis (1987) (0)
Hypothyroidism Inhibits the Rapid Response of mRNA-S14 to Carbohydrate Feeding (1986) (0)
Mechanisms of thyroid hormone action. (1980) (0)
Citation for the 1997 Edwin B. Astwood Lecture Award of The Endocrine Society to John D. Baxter. (1997) (0)
MECHANISM OF THYROID HORMONE ACTION: STRUCTURAL REQUIREMENTS FOR NUCLEAR BINDING AND EVIDENCES FOR ITS BIOGICAL SIGNIFICANCE (1975) (0)
Quantitative aspects of L triiodothyronine (T3) binding by rat liver and kidney cytosol (1974) (0)
Effect of thyroid hormones and carbohydrate diet on mRNA activity profiles in rat adipose tissue (1986) (0)
Messenger Rna-S14 as a Model of Thyroid Hormone Action at the Hepatocellular Level (1987) (0)
Chromatin Structure and Methylation State of a Thyroid Hormone-responsive Gene in Rat (2001) (0)
Demonstration of a thyroid hormone dependent protein in liver cytosol of male rats (1975) (0)
Bone minerals and levothyroxine. (1992) (0)
Glucagon Causes Disappearance of a T3 and Carbohydrate-Inducible Rat Hepatic mRNA (mRNAS14): Unexpected Circadian Dependency of Response (1986) (0)
Summation of the workshop proceedings (1981) (0)
Relationship to Food Intake and Thyroid Function (1984) (0)
Evaluation of the response to thyrotropin releasing hormone (TRH) in the management of thyrotropin (TSH) suppression therapy (1976) (0)

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University of Minnesota

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