A cyclic AMP response element mediates repression of tyrosine aminotransferase gene transcription by the tissue-specific extinguisher locus Tse-1

Tyrosine aminotransferase (TAT) gene expression is liver specific and inducible by glucocorticoids and via the cAMP signaling pathway. In fibroblasts and other nonliver cells the gene is subject to negative control by the trans-dominant tissue-specific extinguisher locus Tse-1. We identified a hepatocyte-specific enhancer that is repressed by Tse-1. Two distinct sequence motifs are absolutely essential for function of this enhancer: a cAMP response element (CRE), which is the target for repression by Tse-1, and a hepatocyte-specific element. The specificity of the enhancer is generated by the combination of these two essential elements, which are fully interdependent. In vivo footprinting indicates that Tse-1 acts by affecting protein binding at the CRE. A direct antagonism between Tse-1 and the cAMP signaling pathway suggests that Tse-1 plays a role in control of developmental activation of the TAT gene.     

Differential activity of a tissue-specific extinguisher locus in hepatic and nonhepatic cells.

Tissue-specific extinguisher 1 (Tse-1) is a genetic locus on mouse chromosome 11 that can repress expression of several liver genes in trans. This locus is clearly active in fibroblasts, as hepatoma cells retaining fibroblast chromosome 11 are extinguished for both tyrosine aminotransferase and phosphoenolpyruvate carboxykinase gene expression. To assess the activity of Tse-1 in other tissues, we transferred mouse chromosome 11 from several different cell types into rat hepatoma recipients. Tse-1 was active in nonhepatic cell lines derived from each primary germ layer, but Tse-1 activity was not apparent in hybrids between hepatoma cells and primary mouse hepatocytes. These differences in the genetic activity of murine Tse-1 were apparently heritable in cis.     

Chromosomal assignment and trans regulation of the tyrosine aminotransferase structural gene in hepatoma hybrid cells.

The structural gene encoding liver-specific tyrosine aminotransferase (TAT; EC 2.6.1.5) was assigned to mouse chromosome 8 by screening a series of hybrid cell lines for retention of murine Tat-1 gene sequences by genomic Southern blotting. This assignment demonstrated that the Tat-1 structural gene was not syntenic with Tse-1, a chromosome 11-linked locus that negatively regulates TAT expression in trans (A. M. Killary and R. E. K. Fournier, Cell 38:523-534, 1984). We also showed that the fibroblast Tat-1 gene was systematically activated in hepatoma X fibroblast hybrids retaining fibroblast chromosomes 8 in the absence of chromosome 11 but was extinguished in cells retaining both fibroblast chromosomes. Thus, the TAT structural genes of both parental cell types were coordinately regulated in the intertypic hybrids, and the TAT phenotype of the cells was determined by the presence or absence of fibroblast Tse-1.     

Tse-2: a trans-dominant extinguisher of albumin gene expression in hepatoma hybrid cells.

Serum albumin gene expression is generally extinguished in hepatoma x fibroblast hybrids. To define the genetic basis of this phenomenon, we screened a panel of hepatoma hybrids retaining different fibroblast chromosomes for albumin production by immunofluorescence. We report that albumin extinction in these clones was strictly correlated with the retention of mouse chromosome 1. Furthermore, albumin was systematically reexpressed in chromosome 1 segregants. These data define a tissue-specific extinguisher locus (Tse-2) that affects albumin gene expression in trans. Two other liver genes, those encoding liver alcohol dehydrogenase and liv-10, were coordinately extinguished with albumin in monochromosomal hybrids that specifically retained mouse chromosome 1.     

A genetic analysis of extinction: trans-dominant loci regulate expression of liver-specific traits in hepatoma hybrid cells

Extinction is an operational term that refers to the lack of expression of tissue-specific traits that is generally observed in hybrid cells formed by fusing dissimilar cell types. To define the genetic basis of this phenomenon, a series of rat hepatoma x mouse fibroblast hybrids has been isolated and characterized. We report here that the extinction of hepatic marker traits in these clones was strictly correlated with the retention of five particular fibroblast chromosomes (autosomes 8, 9, 10, 11, and 13). In order to dissect this correlation into its component parts, hepatoma microcell hybrids containing single, specific fibroblast chromosomes were constructed. Hepatoma clones retaining only fibroblast chromosome 11 were specifically extinguished for liver-specific tyrosine aminotransferase (TAT) expression, while expression of four other hepatic traits and of numerous constitutive markers was unaffected. Furthermore, removal of fibroblast chromosome 11 from the populations by back-selection resulted in reexpression of TAT activity to full parental levels. These data define and localize a genetic locus, tissue-specific extinguisher-1 (Tse-1), which regulates hepatic TAT expression in trans. We also provide evidence that human Tse-1 resides on the homologous chromosome (human chromosome 17), and that hybrids retaining active Tse-1 loci lack TAT-specific mRNA.     

Isolation and characterization of mouse hepatocyte lines carrying a lethal albino deletion.

Mice homozygous for chromosomal deletions at or around the albino locus on chromosome 7 express reduced levels of a group of liver genes, including tyrosine aminotransferase (TAT) and phosphoenolpyruvate carboxykinase (PEPCK), and generally die perinatally. Sequences within the deleted region are thought to encode a regulatory factor(s) that affects expression of these genes in trans. To facilitate study of the putative factors, we immortalized hepatocytes derived from newborn cch wild-type and c14CoS deletion homozygous mice as well as cch/c14CoS heterozygous mice using a SV40 temperature-sensitive A255 mutant virus. Three c14CoS deletion homozygous hepatocyte lines were characterized and compared with the homozygous wild-type and heterozygous lines. The SV40 tsA255 mutant-transformed hepatocyte lines were temperature-sensitive for maintenance of transformation and expressed many liver-specific genes. In agreement with in vivo studies, hepatocyte lines derived from mice homozygous for the deletion expressed reduced mRNA levels of a number of liver genes including TAT, PEPCK, X1, X2, and X7 in comparison with heterozygous and wild-type cell lines. Similar mRNA levels of transferrin and albumin, genes whose expression is unaffected by the mutation in vivo, were observed in all cell lines. The expression of two genes, X5 and metallothionein, reported to be reduced in newborn mutant mice, did not differ appreciably among cell lines. TAT and PEPCK have been shown to respond poorly to glucocorticoids and cAMP in newborn mutant mice. Interestingly, all affected liver genes tested were responsive to glucocorticoids and dibutyryl cAMP in deletion homozygous cell lines as well as in wild-type and heterozygote-derived cell lines. This may suggest that effects of the deletion on expression of liver-specific genes do not cause loss of responsiveness to glucocorticoids and cAMP. These immortalized hepatocyte lines, which express most, if not all, liver-specific genes, should provide a useful means for further investigation of the effects of the albino lethal deletion.     

COP9: a new genetic locus involved in light-regulated development and gene expression in arabidopsis.

We report here the identification and characterization of a new Arabidopsis light-regulatory locus, COP9, mutation that leads to a constitutive photomorphogenic phenotype. Dark-grown cop9 seedlings exhibit many morphological characteristics of light-grown seedlings, including short hypocotyls and open and enlarged cotyledons with cell-type and chloroplast differentiation. Furthermore, the cop9 mutation leads to high-level expression of light-inducible genes in the absence of light, probably by altering the promoter activities of these genes. These properties imply that the mutation in the COP9 locus uncouples the light/dark signals from morphogenesis and light-regulated gene expression. In addition, light-grown cop9 mutants are severely dwarfed and are unable to reach maturation and flowering. This adult-lethal phenotype indicates that the COP9 locus also plays a critical role for normal development of the light-grown plant. Similar to cop1 mutants, but not det1, the cop9 mutants show (1) no effect on the phytochrome control of seed germination and (2) deficiency in the dark-adaptive change of expression of light-regulated genes. Our results suggest that the cop9 and cop1 mutations result in the same range of phenotypes and therefore COP9 and COP1 loci may encode closely related components in the same regulatory pathway.     

Chromosome jumping from flanking markers defines the minimal region for alf/hsdr-1 within the albino-deletion complex.

The locus alf/hsdr-1, defined by the albino-deletion complex on mouse chromosome 7, is essential for neonatal survival. Animals homozygous for a subset of the deletions die shortly after birth due to impaired gene expression in liver parenchymal cells and kidney proximal tubular cells. Here, we describe a detailed analysis of the region containing alf/hsdr-1 by means of chromosome jumping from flanking markers. Three chromosome jumping libraries based on the restriction enzymes XmaI and SalI were constructed. Isolation of eight jumping clones distributed over 450 kb allowed more than 240 kb to be cloned in genomic lambda and cosmid libraries. Five of the probes map within the minimal genetic interval for alf/hsdr-1, which is defined by the proximal borders of the deletions c10R75M and c11DSD. The breakpoints of these deletions were precisely mapped, which allowed alf/hsdr-1 to be localized to a 310-kb interval.     

Extinction of Albumin Gene Expression in a Panel of Human Chromosome 2 Microcell Hybrids

Expression of the serum albumin gene is extinguished in rat hepatoma microcell hybrids that retain mouse chromosome 1. These data define atrans-dominant extinguisher locus,Tse-2,on mouse chromosome 1. To localize the human TSE2 locus, we prepared and characterized rat/human microcell hybrids that contained either human chromosome 1 or chromosome 2, the genetic homologues of mouse chromosome 1. Rat hepatoma microcell hybrids retaining a derivative human chromosome 1 [der 1 t(1;17)(p34.3;q11.2)] expressed their serum albumin genes at levels similar to those of parental hepatoma cells. In contrast, microcell transfer of human chromosome 2 into rat hepatoma recipients produced karyotypically heterogeneous collections of hybrid clones, some of which displayed dramatic albumin extinction phenotypes. For example, albumin mRNA levels in several extinguished microcell hybrids were reduced at least 500-fold, similar to albumin mRNA levels in hepatoma × fibroblast whole-cell hybrids. Expression of several other liver genes, including α1-antitrypsin, aldolase B, alcohol dehydrogenase, and phosphoenolpyruvate carboxykinase, was also affected in some of the microcell hybrids, but expression of these genes was not concordant with expression of albumin. Hybrid segregants were prepared from the albumin-extinguished hybrids, and reexpression of albumin mRNA and protein was observed in sublines that had lost or fragmented human chromosome 2. Finally, expression of mRNAs encoding the liver-enrichedtransactivators HNF-1, HNF-4, HNF-3α, and HNF-3β was not affected in any of the chromosome 2-containing hybrids. These data define and map a genetic locus on human chromosome 2 that extinguishes albumin gene expression intrans,and they suggest that TSE2-mediated extinction is independent of HNF-1, -4, -3α, and -3β expression.     

A petunia MADS box gene involved in the transition from vegetative to reproductive development.

We have identified a novel petunia MADS box gene, PETUNIA FLOWERING GENE (PFG), which is involved in the transition from vegetative to reproductive development. PFG is expressed in the entire plant except stamens, roots and seedlings. Highest expression levels of PFG are found in vegetative and inflorescence meristems. Inhibition of PFG expression in transgenic plants, using a cosuppression strategy, resulted in a unique nonflowering phenotype. Homozygous pfg cosuppression plants are blocked in the formation of inflorescences and maintain vegetative growth. In these mutants, the expression of both PFG and the MADS box gene FLORAL BINDING PROTEIN26 (FBP26), the putative petunia homolog of SQUAMOSA from Antirrhinum, are down-regulated. In hemizygous pfg cosuppression plants initially a few flowers are formed, after which the meristem reverts to the vegetative phase. This reverted phenotype suggests that PFG, besides being required for floral transition, is also required to maintain the reproductive identity after this transition. The position of PFG in the hierarchy of genes controlling floral meristem development was investigated using a double mutant of the floral meristem identity mutant aberrant leaf and flower (alf) and the pfg cosuppression mutant. This analysis revealed that the pfg cosuppression phenotype is epistatic to the alf mutant phenotype, indicating that PFG acts early in the transition to flowering. These results suggest that the petunia MADS box gene, PFG, functions as an inflorescence meristem identity gene required for the transition of the vegetative shoot apex to the reproductive phase and the maintenance of reproductive identity.     

An alpha-subunit-secreting cell line derived from a mouse thyrotrope tumor.

The anterior pituitary contains multiple distinct endocrine cell types that secrete individual hormones. To derive a pure cell culture population in which to study the regulation of the alpha-subunit of TSH free of other hormones and cell types, we have developed a clonal continuous cell line from the transplantable thyrotrope tumor MGH101A. This cell line expresses alpha-subunit mRNA, secretes alpha-subunit protein, and has maintained a stable phenotype for over 3 yr in culture. However, as is the case for the transplantable tumor from which they are derived, these cells do not express the beta-subunit of TSH or respond to TRH or thyroid hormone. We have used this cell line to investigate regulation of the alpha-subunit mRNA by the second messengers, cAMP and phorbol esters, and by glucocorticoids. Phorbol esters increase alpha-subunit mRNA levels significantly (3.5-fold), as does cAMP (1.8-fold). In contrast, glucocorticoids decrease mRNA levels from cAMP-induced or basal levels (2-fold). These cells should prove valuable for study of alpha-subunit gene expression in an isolated renewable clonal cell culture system.     

Adrenal glucocorticoids regulate adipsin gene expression in genetically obese mice

Adipsin expression at the protein and mRNA levels is greatly reduced in several distinct syndromes of obesity in the mouse: genetic obesity due to the db/db and ob/ob genes, and a chemically induced model secondary to neonatal exposure to monosodium glutamate. We considered first the possibility that the adipsin gene might be identical to the db or ob locus and the lowered expression of this protein might result from a mutation in this gene. We show here that the adipsin structural gene is located on chromosome 10 and hence is physically distinct from any obesity genes so far identified in the mouse. A major role for the adrenal gland and adrenal glucocorticoids in the aberrant regulation of adipsin in these models of obesity is indicated by several experiments. Adrenalectomy of the ob/ob mouse raises the circulating levels of adipsin protein and the amount of this mRNA in epididymal fat pads (5-fold), although neither is increased to the levels seen in lean controls. Exogenous administration of corticosterone completely blocks the effects of adrenalectomy on adipsin, suggesting that the effect of this endocrine ablation is through reduction of adrenal glucocorticoids. Corticosterone administration also causes suppression in the levels of adipsin mRNA and protein in lean mice, although this decrease is never as severe as that seen in obese mice. The effect of exogenous corticosterone in lean mice occurs within 2 days and hence is not secondary to the obesity which these hormones eventually elicit. These results indicate that glucocorticoids can regulate adipsin expression in vivo and strongly suggest that the hyperglucocorticoid state seen in certain obese models plays a significant role in lowering adipsin mRNA and protein levels. Quantitative analysis of these experiments suggests that other as yet unknown neuroendocrine factors also function to suppress adipsin in obesity.     

Disruption of glucocorticoid receptor exon 2 yields a ligand-responsive C-terminal fragment that regulates gene expression

Mice in which exon 2 of the glucocorticoid receptor (GR) has been disrupted [GR exon 2 knockout (GR2KO)] have been used as a model to study the requirement for this receptor in a number of biological systems. A recent report showed that these mice actually express a truncated ligand-binding GR fragment, prompting us to ask whether this mutation truly results in a glucocorticoid-insensitive phenotype. Based on cDNA microarray analysis of fetal thymocytes, we found that glucocorticoids were able to enhance or repress activation-induced gene expression in GR2KO and wild-type thymocytes to a similar degree. Moreover, although changes in gene expression induced by glucocorticoids alone were blunted, the expression of a substantial number of genes in GR2KO thymocytes was modulated by stimulation with glucocorticoids. Among these genes, as confirmed by quantitative real-time PCR, was the classic glucocorticoid-responsive gene glutamine synthetase as well as genes implicated in T cell development and function such as IL-7 receptor alpha-chain and glucocorticoid-induced leucine zipper (GIL2). Thus, the truncated C-terminal GR2KO product, which lacks the major transactivation domain, retains, to a large extent, the ability to regulate gene expression both positively and negatively in a ligand-responsive manner when expressed in vivo.     

cAMP signaling in <Emphasis Type="Italic"> Aspergillus fumigatus </Emphasis>is involved in the regulation of the virulence gene <Emphasis Type="Italic"> pksP </Emphasis>and in defense against killing by macrophages

Aspergillus fumigatus is an important pathogen of immunocompromised hosts, causing pneumonia and invasive disseminated disease and resulting in high mortality. In order to determine the importance of the cAMP signaling pathway for virulence, three genes encoding putative elements of the pathway have been cloned and characterized: the adenylate cyclase gene acyA, and gpaA and gpaB, both of which encode alpha subunits of heterotrimeric G proteins. The acyA and gpaB genes were each deleted in A. fumigatus. Both mutants showed reduced conidiation, with the deltaacyA mutant producing very few conidia. The growth rate of the deltaacyA mutant was also reduced, in contrast to that of the deltagpaB mutant. Addition of 10 mM dibutyryl-cAMP to the culture medium completely restored the wild-type phenotype in both mutant strains. To study the influence of GPAB on the expression of the gene pksP, which encodes a virulence factor that is involved in pathogenicity, a pksPp-lacZ gene fusion was generated and integrated as a single copy at the pyrG gene locus of both the parental strain and the deltagpaB mutant strain. The deltagpaB mutant showed reduced expression of the pksPp-lacZ reporter gene relative to that in the parental strain. In mycelia of both the parental strain and the deltagpaB mutant pksPp-lacZ expression was increased when isobutyl-methyl-xanthine, an inhibitor of intracellular phosphodiesterases, was added to the medium. The survival rate of conidia after ingestion by human monocyte-derived macrophages was also determined. The killing rate for conidia from deltaacyA and deltagpaB strains was significantly higher than that for wild-type conidia. Taken together, these findings suggest that cAMP triggers a system that protects A. fumigatus from the effects of immune effector cells of the host.