Role of growth hormone in the multihormonal regulation of messenger RNA for alpha2u globulin in the liver of hypophysectomized rats

A Fos-Jun element in the first intron of an alpha 2u-globulin gene

The hepatic expression of the alpha-2u-globulin gene family is controlled by a variety of hormones including steroids, growth hormone and insulin. The mechanisms by which these hormones affect alpha 2u-globulin expression are only partially understood. Recently we isolated and characterized clone RAP 01, an alpha 2u-globulin gene expressed in the liver. In preliminary experiments we noted that partial hepatectomy, a procedure which results in a sharp rise in the level of the oncoproteins c-Fos and c-Jun, also causes a transient induction of the messenger RNA corresponding to clone RAP 01. Using the DNAseI footprinting technique we were able to show that this clone contains a TPA (phorbol 12-myristate 13-acetate)-responsive element (TRE) in its first intron. This element (denoted as element X) is identical to the consensus AP-1 binding site (TGACTCAG) and is protected by rat liver nuclear extracts as well as by purified c-Jun. Gel retardation experiments show that an oligonucleotide containing the TRE consensus sequence competes for binding of liver nuclear proteins to element X and that antibodies directed against the M2 peptide of the mouse Fos protein or the PEP-2 peptide of Jun prevent the formation of specific complexes with the same element. Moreover, element X functions as a TRE in transfected BWTG3 hepatoma cells treated with TPA. Co-transfection with fos and jun expression vectors mimics the effects of TPA suggesting that AP-1 is in fact the mediator of the observed response. It is concluded that the first intron of RAP 01 contains a functional Fos-Jun element.

Interaction of estrogen receptor complexes with the promoter region of genes that are negatively regulated by estrogens: the alpha 2u-globulins

Since estrogens strongly suppress the expression of alpha 2u-globulin genes in the rat liver, we studied the binding of estrogen-receptor complexes to fragments derived from alpha 2u-globulin gene RAO 01 using a DNA-cellulose competition assay. Rat uterus cytosol labelled with [3H]estradiol was used as a source of the estrogen receptor. As a positive control in these experiments we used an oligonucleotide containing the estrogen response element (ERE) cloned into pUC18. Our experiments indicate that estrogen-receptor complexes bind specifically to the ERE and to a fragment of RAO 01 located in the 5'-upstream region (bp -606 up to -575). This fragment is conserved among other members of this gene family. This is the first time that in vitro estrogen receptor binding is observed to gene fragments derived from a gene that is repressed by this steroid in vivo.

Influence of growth hormone on the synthesis of rat liver alcohol dehydrogenase in primary hepatocyte culture

Growth hormone has previously been shown to increase the activity of alcohol dehydrogenase in primary hepatocyte culture from male rats. In this study, continuous exposure of cultured hepatocytes to growth hormone (1 microgram/ml) resulted in parallel increased in the enzyme activity of alcohol dehydrogenase and immunoreactive protein. Growth hormone increased the incorporation of [3H]leucine into alcohol dehydrogenase protein relative to the incorporation into cytosolic protein. The abundance of alcohol dehydrogenase mRNA increased on Days 3 and 4 of continuous exposure of the hepatocytes to growth hormone and returned to control levels on Day 5 of culture. Growth hormone increased the rate of transcription of the alcohol dehydrogenase gene as demonstrated by nuclear runoff experiments. These observations indicate that the effect of growth hormone in enhancing alcohol dehydrogenase activity is due to increased synthesis of the enzyme which is initiated at the level of gene transcription.

Tissue-specific and hormonally regulated expression of a rat alpha 2u globulin gene in transgenic mice

To investigate the tissue-specific and hormonal regulation of the rat alpha 2u globulin gene family, we introduced one cloned member of the gene family into the mouse germ line and studied its expression in the resulting transgenic mice. Alpha 2u globulingene 207 was microinjected on a 7-kilobase DNA fragment, and four transgenic lines were analyzed. The transgene was expressed at very high levels, specifically in the liver and the preputial gland of adult male mice. The expression in male liver was first detected at puberty, and no expression was detected in female transgenic mice. This pattern of expression is similar to the expression of endogenous alpha 2u globulin genes in the rat but differs from the expression of the homologous mouse major urinary protein (MUP) gene family in that MUPs are synthesized in female liver and not in the male preputial gland. We conclude that these differences between rat alpha 2u globulin and mouse MUP gene expression are due to evolutionary differences in cis-acting regulatory elements. The expression of the alpha 2u globulin transgene in the liver was abolished by castration and fully restored after testosterone replacement. The expression could also be induced in the livers of female mice by treatment with either testosterone or dexamethasone, following ovariectomy and adrenalectomy. Therefore, the cis-acting elements responsible for regulation by these two hormones, as well as those responsible for tissue-specific expression, are closely linked to the alpha 2u globulin gene.

Receptors for native gonadotropins in amphibian liver

We demonstrate that highly purified bullfrog (f) follicle-stimulating hormone (FSH) and luteinizing hormone (LH) bind specifically and significantly to a crude plasma membrane fraction of bullfrog liver. The other extragonadal organs of the bullfrog showed little or no specific binding. Specific bindings of 125I-fFSH and 125I-fLH to plasma membranes are saturable processes, and are time-, pH-, and temperature-dependent. Scatchard plots of fFSH and fLH were linear. The association constant of equilibrium (Ka) of the specific fFSH binding sites was 4.77 +/- 1.24 X 10(9)M-1 (mean +/- SEM) and the number of sites was 0.262 +/- 0.042 fmol/mg protein (mean +/- SEM). The Ka of the specific fLH binding sites was 5.38 +/- 1.27 X 10(9)M-1 (mean +/- SEM) and the number was 0.315 +/- 0.019 fmol/mg protein (mean +/- SEM). Competition experiments revealed that both fFSH and fLH use the same single class of binding sites. Binding of rat, chicken, bullfrog, and salmon gonadotropins to plasma membranes of the testis and liver of various vertebrates was studied. A significant degree of specific binding was detected only in combinations of bullfrog gonadotropins and amphibian livers. The concentration of adenosine 3'-5'-monophosphate (cAMP) in mince or primary culture cells of bullfrog liver was greatly increased by adding fFSH and fLH to the medium. Bullfrog LH was more potent than fFSH in increasing cAMP concentration, although they were not distinguished by specific binding sites. These data suggest that not only the gonads but also the liver is the target of gonadotropins in the bullfrog, although the final hepatic function controlled by gonadotropins remains unknown.

Tissue-specific and hormonally regulated expression of a rat alpha 2u globulin gene in transgenic mice

To investigate the tissue-specific and hormonal regulation of the rat alpha 2u globulin gene family, we introduced one cloned member of the gene family into the mouse germ line and studied its expression in the resulting transgenic mice. Alpha 2u globulingene 207 was microinjected on a 7-kilobase DNA fragment, and four transgenic lines were analyzed. The transgene was expressed at very high levels, specifically in the liver and the preputial gland of adult male mice. The expression in male liver was first detected at puberty, and no expression was detected in female transgenic mice. This pattern of expression is similar to the expression of endogenous alpha 2u globulin genes in the rat but differs from the expression of the homologous mouse major urinary protein (MUP) gene family in that MUPs are synthesized in female liver and not in the male preputial gland. We conclude that these differences between rat alpha 2u globulin and mouse MUP gene expression are due to evolutionary differences in cis-acting regulatory elements. The expression of the alpha 2u globulin transgene in the liver was abolished by castration and fully restored after testosterone replacement. The expression could also be induced in the livers of female mice by treatment with either testosterone or dexamethasone, following ovariectomy and adrenalectomy. Therefore, the cis-acting elements responsible for regulation by these two hormones, as well as those responsible for tissue-specific expression, are closely linked to the alpha 2u globulin gene.

Developmental and hormonal regulation of alpha 2u-globulin gene transcription

Hepatic alpha 2u-globulin protein and RNA levels are under developmental and complex multihormonal control. The present studies directly evaluate the degree to which this regulation is transcriptional. alpha 2u-Globulin transcription was determined by measuring nuclear runoff RNA in vitro, and tissue alpha 2u-globulin mRNA levels were measured by dot blot hybridization. These studies reveal that (i) in male rats the transcriptional rate of the alpha 2u-globulin genes increases during postnatal development; (ii) no alpha 2u-globulin transcription is detectable in hepatic nuclei derived from hypophysectomized rats; (iii) growth hormone and glucocorticoid are both absolutely required, and glucocorticoid can replace androgen for alpha 2u-globulin gene transcription in the livers of hypophysectomized male rats; and (iv) chronic treatment of mature male rats with estrogen results in a progressive decrease in the hepatic transcription of alpha 2u-globulin genes. In all instances changes in the transcriptional rate of alpha 2u-globulin genes paralleled the tissue level of alpha 2u-globulin RNA. Thus transcriptional control predominates in regulating hepatic alpha 2u-globulin RNA levels.

The mode of growth hormone administration is of major importance for the excretion of the major male rat urinary proteins

Male and female urinary proteins were analysed using chromatofocusing. Male rat urine had a higher protein content (measured as UV absorbance), particularly in the pI range 5.0-5.5, where female rat urine seemed to lack UV-absorbing material. The molecular weight of the major male rat urinary protein(s) is approximately 16 000 according to sodium dodecylsulphate (SDS)-polyacrylamide gel electrophoresis. The regulation of the major male rat urinary protein(s) (pI 5.3; MRUP) was studied in normal male rats and hypophysectomized rats treated for 1 week with various hormones. Urine was collected during the last day of hormone treatment and analysed by chromatofocusing and SDS-polyacrylamide gel electrophoresis. It was found that estrogen treatment of male rats suppressed the appearance of MRUP. This 'feminizing' effect was also observed following continuous infusion for 1 week of human growth hormone (hGH) or rat growth hormone (rGH) in male rats. Single injections of hGH, however, given once daily for 1 week and supplemented with glucocorticoid, thyroid hormone and androgen had an opposite effect and induced MRUP in hypophysectomized male rats. It is concluded that the mode of administration of GH is of great importance for the effects of the hormone and that continuous, as compared to intermittent, administration of GH may result in suppression or induction, respectively, of major male rat urinary protein(s).

Rat alpha 2u-globulin mRNA expression in the preputial gland

Rat alpha 2u-globulin and the mouse major urinary proteins (MUP) are encoded by homologous multigene families whose members exhibit diverse tissue-specific, developmental, and hormonal controls of expression. Although their patterns of expression and hormonal control appear to be very similar in many respects, we have found high levels of alpha 2u-globulin mRNA in rat preputial glands, whereas MUP mRNA could not be detected in the male mouse preputial gland. Male and female rat preputial have similar concentrations of alpha 2u-globulin mRNA, suggesting an absence of endocrine regulation as occurs in the liver and lachrymal glands. Two-dimensional polyacrylamide gel electrophoresis of proteins encoded by hybrid-selected alpha 2u-globulin mRNA indicates that the liver and lachrymal translation products have different mobilities. However, many of the preputial gland products comigrate with most or all of the liver and lachrymal products. Among the possibilities suggested by these results is that alpha 2u-globulin genes expressed in liver and lachrymal glands under endocrine control are also expressed constitutively in the preputial gland.

Subfamilies of the mouse major urinary protein (MUP) multi-gene family: sequence analysis of cDNA clones and differential regulation in the liver

The mouse major urinary proteins (MUPs) are the products of a multi-gene family of 30-35 genes whose members exhibit diverse tissue specific, developmental, and hormonal controls. Three cDNA clones corresponding to liver MUP mRNAs have been sequenced. Two of the clones (p499, C57BL/6 and p1057, BALB/c) share strong homology whereas a third clone (p199, C57BL/6) has diverged considerably from the others at the nucleic acid (85% homology) and protein (68% homology) levels. The 5' regions of p499 and p199 which show the most sequence divergence were subcloned and shown to hybridize to different liver MUP mRNAs. The p499-5' sequence was expressed in all MUP expressing tissues (liver, lachrymal, submaxillary and mammary) whereas the p199-5' sequence was expressed primarily in the liver and lachrymal. Analysis of liver RNA from mice in different endocrine states indicates that the p499-5' sequence is strongly regulated by thyroxine administration whereas the p199-5' sequence is not. Both sequences appear to be regulated by growth hormone and testosterone. Southern blot analysis of mouse genomic DNA indicates that there are multiple genes homologous to each sequence.

Malic enzyme and fatty acid synthase in the uropygial gland and liver of embryonic and neonatal ducklings. Tissue-specific regulation of gene expression

Malic enzyme [L-malate-NADP oxidoreductase (decarboxylating), EC 1.1.1.40] and fatty acid synthase activities were barely detectable in the uropygial gland of duck embryos until 4 or 5 days before hatching, when they began to increase. These activities increased about 30- and 140-fold, respectively, by the day of hatching. Malic enzyme and fatty acid synthase activities were also very low in embryonic liver. However, hepatic malic enzyme activity did not increase until the newly hatched ducklings were fed. Hepatic fatty acid synthase began to increase the day before hatching and the rate of increase in enzyme activity accelerated markedly when the newly hatched ducklings were fed. Starvation of newly hatched or 12-day-old ducklings had no effect on the activities of malic enzyme and fatty acid synthase in the uropygial gland but markedly inhibited these activities in liver. Changes in the concentrations of both enzymes and in the relative synthesis rates of fatty acid synthase correlated with enzyme activities in both uropygial gland and liver. Developmental patterns for sequence abundance of malic enzyme and fatty acid synthase mRNAs in uropygial gland and liver were similar to those for their respective enzyme activities. Starvation of 4-day-old ducklings had no significant effect on the abundance of these mRNAs in uropygial gland but caused a pronounced decrease in their abundance in liver. It is concluded that developmental and nutritional regulation of these enzymes is tissue specific and occurs primarily at a pretranslational level in both uropygial gland and liver.

Differential, multihormonal regulation of the mouse major urinary protein gene family in the liver

The hormonal requirements for the regulation of the major urinary protein (MUP) mRNA levels in mouse liver have been examined. Previous experiments have shown that administration of testosterone to female or castrated male mice increases MUP mRNA levels approximately fivefold to normal male levels. We have found that thyroxine and the peptide hormone, growth hormone, each had a pronounced effect on MUP mRNA levels. MUP mRNA was reduced 150-fold in growth-hormone-deficient mutant mice (little). The administration of growth hormone and thyroxine induced MUP mRNA approximately 150-fold, and when administered together, they induced MUP mRNA approximately 1,000-fold. testosterone administration. When administered separately to these mice, growth hormone and thyroxine induced with MUP mRNA approximately 150-fold, and when administered together, they induced MUP mRNA approximately 1,000-fold. Testicular feminized mice, which lack a functional major testosterone receptor protein, can also be induced to male levels by treatment with both growth hormone and thyroxine. In addition, we present evidence which indicates that growth hormone, thyroxine, and testosterone differentially regulate the levels of distinct MUP mRNA species.

Differential, multihormonal regulation of the mouse major urinary protein gene family in the liver

The hormonal requirements for the regulation of the major urinary protein (MUP) mRNA levels in mouse liver have been examined. Previous experiments have shown that administration of testosterone to female or castrated male mice increases MUP mRNA levels approximately fivefold to normal male levels. We have found that thyroxine and the peptide hormone, growth hormone, each had a pronounced effect on MUP mRNA levels. MUP mRNA was reduced 150-fold in growth-hormone-deficient mutant mice (little). The administration of growth hormone and thyroxine induced MUP mRNA approximately 150-fold, and when administered together, they induced MUP mRNA approximately 1,000-fold. testosterone administration. When administered separately to these mice, growth hormone and thyroxine induced with MUP mRNA approximately 150-fold, and when administered together, they induced MUP mRNA approximately 1,000-fold. Testicular feminized mice, which lack a functional major testosterone receptor protein, can also be induced to male levels by treatment with both growth hormone and thyroxine. In addition, we present evidence which indicates that growth hormone, thyroxine, and testosterone differentially regulate the levels of distinct MUP mRNA species.

The gene family for major urinary proteins: expression in several secretory tissues of the mouse

The major urinary proteins (MUPs) of the mouse are encoded by a multigene family located at the Mup a locus on chromosome 4. Previous investigations have shown that the MUPs are synthesized in the liver, secreted and then excreted in the urine. We have found significant levels of MUP mRNA in several secretory tissues: the liver and the submaxillary, lachrymal and mammary glands. There are striking differences in hormonal and developmental regulation of MUP gene expression in these tissues. Furthermore, each tissue appears to express a characteristic pattern of MUP mRNAs. In particular, the lachrymal glands appear to express an entirely different set of MUP mRNAs. These results are discussed in relation to the organization of the MUP gene cluster and a possible function of the MUPs.

Tissue-specific control of alpha 2u globulin gene expression: constitutive synthesis in the submaxillary gland

Synthesis of alpha 2u globulin, previously thought to occur only in the male rat liver, has now been demonstrated in the submaxillary salivary gland. Unlike liver, submaxillary synthesis of alpha 2u globulin mRNA is constitutive--that is, independent of the endocrine state, age and sex. Liver and submaxillary alpha 2u globulin mRNAs are of similar size, and their 5' ends map to the same region of the gene. Isoelectric focusing of in vitro translation products revealed that submaxillary mRNA encodes a more acidic subset of alpha 2u globulins than does liver. Salivary alpha 2u globulin mRNA manifests 5% nucleotide divergence, encoding 20 amino acid substitutions, which specifies a more acidic polypeptide than its hepatic counterpart. Thus the liver and submaxillary gland synthesize alpha 2u globulin from different sets of genes that are subject to very different developmental and hormonal control.

Multihormonal induction of alpha 2u-globulin in an established rat hepatoma cell line

A subclone of the FU5-5 rat hepatoma cell line has been isolated which is inducible more than several hundred fold for the 20,000 dalton form of the major rat urinary protein alpha 2u-globulin. The basal relative synthetic rate (RSR) in growth medium containing 10% fetal calf serum was less than 2 X 10(-6) of total protein synthesis. Both dexamethasone and insulin were necessary for induction, and yielded a maximum induced RSR of 4-8 X 10(-3). Triiodothyronine (T3), dihydrotestosterone (DHT), rat growth hormone (GH), and estrogen, all of which have been shown to influence the induction of alpha 2u-globulin in the intact rat, were without effect on the cell line. A factor present in fetal calf serum was also necessary for maximum induction, since dexamethasone plus insulin in serum-free medium raised the RSR to only 3 X 10(-5); exogenous T3, GH, and DHT could not substitute for this serum factor. The kinetics of induction by dexamethasone were slow, with a lag of approximately 48 hr followed by a period of increasing RSR for 6-20 days. Removal of dexamethasone from induced cells led to an exponential decline in the RSR (t 1/2 15 hr). The concentrations of dexamethasone and insulin that could yield half maximum induction were 5 X 10(-8)M and 3 X 10(-11)M, respectively. Higher concentrations of insulin, although still in physiological range (10(-9)M), inhibited induction. At yet higher insulin levels, beyond the physiological range, alpha 2u-globulin synthesis returned to maximum values. The lack of DHT, T3, and GH requirement for alpha 2u-globulin induction in this cell line may mean that a regulatory aberrancy has occurred in this transformed cell line, or, alternatively, that these hormones act indirectly in the intact animal. This cell line should prove useful for the study of the molecular events associated with alpha 2u-globulin induction and for genetic approaches to the problem of multihormonal regulation of gene expression.

Some theoretical questions of the peptide and steroid hormone regulation. Part I.: The receptor-steroid variable complex (RSVC) hypothesis of genetic regulation

Steroids exert their known biological and biochemical effects in connection with specific receptors. These effects are so various and complex that it is impossible to explain them on the basis of a concept supposing the presence of only one unique receptor molecule in the target organs. The heterogeneity in the function of steroids requires a heterogeneity in the molecular composition of the receptor-steroid complexes. Direct and indirect evidence is presented to support a multiplex, heterogene receptor theory. The possible origin of this complexity is analyzed and a new concept of specific gene regulation by heterogene receptor-steroid complexes is suggested. in this theory the distribution and sequence of one or more steroids on the receptor can carry and serve highly specific and unique information capable or recognizing and binding to the acceptor site of the chromatin and regulating gene expressions specific for steroids. The formation of such Receptor-Steroid Variable Complexes (RSVC) has been mathematically analyzed and the properties of a chromatin protein capable of detecting both the DNA and the steroid sequences on the receptor are discussed.

The role of growth hormone in alpha 2u globulin synthesis: a reexamination

Hypophysectomy of adult male rats abolishes alpha 2u globulin synthesis; synthesis can be fully restored by daily administration of androgen, thyroid hormone, glucocorticoid and growth hormone for 12 days. It has been previously reported that growth hormone is not required to maintain alpha 2u globulin mRNA levels, and that growth hormone functions only translationally. We have reexamined the role of growth hormone in alpha 2u globulin synthesis using a cloned alpha 2u globulin cDNA probe. Measurement of alpha 2u globulin mRNA levels by hybridization and cell-free translation, and of alpha 2u globulin synthesis by pulse-labeling in vivo, demonstrates that growth hormone is required to maintain full, steady state hepatic levels of both alpha 2u globulin and its mRNA. Furthermore, the small amount of hepatic alpha 2u globulin mRNA that accumulates in the absence of growth hormone is efficiently translated in vivo. Thus we now find no evidence for growth-hormone-mediated translational control. We have also found that rats hypophysectomized prepubescently respond to the multihormonal restoration therapy to only 10% of the alpha 2u globulin mRNA levels observed in rats hypophysectomized as adults. This finding suggests that some unidentified pituitary factor(s) is required during puberty to potentiate normal alpha 2u globulin gene expression.

Thyroid hormone attenuates and augments hepatic gene expression at a pretranslational level

We have attempted to ascertain the proportion of the rat hepatic genome that is under the selective influence of thyroid hormones and to describe the response patterns of individual mRNA sequences in the transition between hypothyroidism and euthyroidism and between euthyroidism and hyperthyroidism. Poly(A)+RNA was extracted from livers of thyroidectomized, intact, euthyroid rats and of thyroidectomized rats rendered euthyroid and hyperthyroid with daily doses of triiodothyronine. The extracted RNA was translated in a reticulocyte lysate system in the presence of [35S]methionine, and the products were analyzed by two-dimensional gel electrophoresis. Triiodothyronine attenuates as well as augments the expression of certain genes at a pretranslational level. This could represent either a direct or an indirect action of the hormone. Triiodothyronine influences approximately 8% of the 231 mRNA sequences visualized, stimulating activity in 11 and inhibiting activity in 7 sequences. Translational activity of at least one mRNA sequence decreased in both thyroidectomized and hyperthyroid animals, compared to euthyroid levels. The relationship of mRNA response to receptor occupancy varied with examples of linear and amplified responses and responses that were maximal at less than full nuclear occupancy.

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

Previous studies from this laboratory have demonstrated an age-related decrease in hepatic malic enzyme (ME) levels and in the response of ME to triiodo-l-thyronine (T(3)). Moreover, we have recently shown a synergistic interaction of T(3) and a high carbohydrate diet in the induction of this enzyme. Studies were therefore undertaken to assess the response of aging rats to a high carbohydrate diet and to test the effect of such dietary manipulations on the responsiveness of ME to T(3). For this purpose, a new radio-immunoassay for ME was developed that, because of a 10-fold higher sensitivity, was particularly suited to the measurement of the low concentrations of hepatic enzyme in older animals. The level of ME per milligram of DNA fell approximately 70% between 1 and 6 mo with only minor further changes demonstrated between 6 and 18 mo. In contrast, the level of ME per milligram DNA in brain was slightly increased in the older animals. Although the absolute increment of hepatic ME resulting from seven daily injections of T(3) (15 mug/100 g body wt) fell with age, the ratio of the ME content per milligram DNA to that observed in control animals maintained on a regular chow diet remained relatively constant with an average value of 11.1. The responsivity of hepatic ME to a high carbohydrate, fat-free diet also decreased with age and could not be attributed exclusively to a reduction in food consumption. The age-related reduction in ME responsivity to dietary stimuli appeared to be due to a reduction in the formation of the specific messenger, (m)RNA for ME as determined in an in vitro translational assay. Our data are consistent with the following hypothesis. There is an age-related decreased hepatic responsivity to a high carbohydrate dietary stimulus. Thyroid hormone administration, as previously postulated by us, interacts with a product or an intermediate of carbohydrate metabolism in a multiplicative fashion. As a consequence, the absolute increment of ME induced by T(3) administration also declines with age.

Regulation of gene expression in primary cultures of adult rat hepatocytes on collagen gels

The studies described in this paper demonstrate rather conclusively the efficacy of the study of the regulation of gene expression in primary cultures of adult rat hepatocytes. The utilization of these cells in completely defined medium allows one to determine the exact environmental conditions for the regulation of the expression of specific genes. In the studies described in this work, we have demonstrated that the regulation of glucokinase involved three hormones, insulin, corticosteroids, and T3. In contrast, the regulation of an enzyme involved primarily in fatty acid metabolism, ATP-citrate lyase, required only insulin and T3 for its full expression. Cyclic GMP appeared to be involved in the regulation of glucokinase, but not ATP-citrate lyase, a fact that would be extremely difficult to demonstrate clearly in vivo. The regulation of the gluconeogenic enzyme, ornithine aminotransferase, in vitro involved only a single hormone, glucagon, the inhibition of induction by corticoid steroids demonstrable in vivo being absent in cell culture. However, the repressive effect of glucose on the induction of this enzyme was quite comparable to that seen in vivo and was not mediated through cyclic AMP or insulin, based on findings in cell culture. Thus, the requirements for and the mechanisms involved in enzyme induction and repression by hormones and glucose may be much more easily studied in primary cultures of rat hepatocytes than in vivo, or even in hepatoma cell lines, where relatively few genes are expressed as compared with adult liver. In addition to the regulation of enzyme levels, the characteristics of protein secretion may be investigated in primary cultures of rat hepatocytes and compared with the biochemical and physiological parameters in the whole organism. This was exemplified by the study of the synthesis and secretion of alpha 2u-globulin that was secreted into the culture medium in both glycosylated and nonglycosylated forms but was maintained in the circulation in vivo, principally as the glycosylated form. Furthermore, the function of glycosylation in this particular instance may be deduced from a combination of the in vivo and in vitro approaches. The advantages of the use of primary hepatocyte cultures for the study of the regulation of gene expression in mammalian tissue has only recently been explored. Future investigations of the regulation of a variety of enzymes in these cultures as well as a study of the regulation of the synthesis of their messenger RNA are now possible and should provide an exciting system in which to understand at a molecular level the regulation of the expression of a number of genes.

Synergism of thyroid hormone and high carbohydrate diet in the induction of lipogenic enzymes in the rat. Mechanisms and implications

We have investigated the relationship between the administration of triiodothyronine (T3) and a high carbohydrate (CHO) fat-free diet in the induction of lipogenic enzymes in two rat tissues, liver, and fat. Male thyroidectomized rats were treated with graded daily doses of T3 and either supplemented with a high CHO diet or left on a regular diet. Enzymes studied included malic enzyme (ME), fatty acid synthetase, glucose-6-phosphate dehydrogenase, and 6-phosphogluconate dehydrogenase. In the liver, all four lipogenic enzymes showed a synergistic response between T3 administration and high CHO feeding. In fat, ME also responded synergistically. The interaction was reflected in an increased sensitivity to T3. The dose of T3 required to achieve 50% maximal response was reduced three- to seven-fold by the high CHO diet. This phenomenon could not be attributed to a dietary-induced alteration either in T3 metabolism or in number or affinity of the T3-nuclear receptors. Moreover, studies of the relative rate of synthesis of ME suggested a simultaneous time of onset in the induction of ME, within 2 h after the application of either T3 or CHO. Thus, it is unlikely that either stimulus is secondary to the other. Since parallel experiments from this laboratory (Towle, Mariash, and Oppenheimer,1980. Changes in hepatic levels of messenger ribonucleic acid for malic enzyme during induction by thyroid hormone or diet. Biochemistry. 19: 579-585.) show that ME induction both by CHO and T3 is mediated by an increase in specific messenger RNA for ME, the interaction of T3 and the dietary factor occurs at a pretanslational level.

Roles of growth hormone and testosterone in the synthesis of mouse kidney glucuronidase

Mouse kidney beta-glucuronidase production is under multihormonal control. In normal mice, kidney glucuronidase is induced over 100-fold by testosterone. However, hypophysectomy reduces this induction to about 5% of normal. This loss in inducibility was in part restored by growth hormone. Simultaneous administration to hypophysectomized female mice of growth hormone and testosterone, but not of prolactin and testosterone, restored kidney glucuronidase concentration to half that found in testosterone-treated normal female mice. Growth hormone alone had no effect in hypophysectomized females nor did it enhance glucuronidase activity in testosterone-treated normal females. Radiolabeling experiments demonstrated that the enhancement by growth hormone of glucuronidase activity was accompanied by a corresponding increase in its rate of synthesis. Kidney hypertrophy and kidney glucuronidase production may be under common hormonal regulation. Testosterone or growth hormone treatment alone of hypophysectomized mice had little or no effect on either process, but combined treatment with the two hormones significantly enhanced both. The rate of synthesis of kidney glucuronidase is controlled by the Gur gene. Relative differences in kidney glucuronidase synthesis in mice of different Gur genotype were maintained in testosterone-treated hypophysectomized mice. This suggests that control of glucuronidase synthesis by the Gur locus is exerted by interaction with androgens rather than pituitary products.