Y1 Mouse Adrenocortical Cells Research Articles

Suppression of cAMP-mediated signal transduction in mouse adrenocortical cells which express apolipoprotein E.

We have reported previously that expression of the human apolipoprotein E (apoE) gene in mouse Y1 adrenocortical cells suppresses basal and adrenocorticotropin (ACTH)-stimulated steroidogenesis. To understand the mechanism of this suppression, we have examined the integrity of cAMP regulated events required for adrenal steroidogenesis. Both acute and chronic responses to ACTH or cAMP are suppressed in Y1 cells which express apoE (Y1-E cells) as compared with parental Y1 cells. Acute morphologic changes in response to cAMP and acute induction of steroidogenesis by cAMP are suppressed in the Y1-E cell lines. Constitutive expression of P450-cholesterol side chain cleavage enzyme mRNA, the rate-limiting enzyme in steroid hormone synthesis, is reduced up to 11-fold in the Y1-E cell lines. The level of mRNA encoding P450-cholesterol side chain cleavage correlates directly with the reduction in basal steroid production observed in the individual Y1-E cell lines. Expression of P450-11 beta-hydroxylase mRNA, although readily detectable in Y1 parent cells, is absent or reduced in the Y1-E cell lines. Inhibition of cAMP-regulated gene expression is not restricted to genes required for steroid synthesis, since cAMP induction of ornithine decarboxylase mRNA is also inhibited in the Y1-E cell lines. These data indicate that suppression of steroidogenesis in Y1-E cells is due, at least in part, to inhibition of cAMP-regulated gene expression. These effects are not due to a defective cAMP-dependent protein kinase, since kinase activity in vitro and activation in vivo are unaltered in the Y1-E cell lines. These results suggest that expression of apoE in Y1 cells blocks cAMP-mediated signal transduction at a point distal to activation of cAMP-dependent protein kinase.

A Shared Promoter Element Regulates the Expression of Three Steridogenic Enzymes

The adrenal cortex of the mouse coordinately expresses three cytochrome P450 enzymes that are required for the biosynthesis of corticosteroids: cholesterol side-chain cleavage enzyme (SCC), steroid 21-hydroxylase (21-OHase), and steroid 11 beta-hydroxylase (11 beta-OHase). Within their 5'-flanking regions, we previously identified six elements containing variations of an AGGTC motif that regulated expression in mouse Y1 adrenocortical cells: 21-OHase elements at -210, -140, and -65; SCC elements at -70 and -40; and an 11 beta-OHase element at -310. We demonstrate here that all six elements interact with the same, or closely related, DNA-binding protein(s). First, these elements all formed complexes of similar mobility in gel shift assays, suggesting that they interacted with protein(s) of similar size. Additional larger complexes were seen with those probes containing exact AGGTCA sequences. Second, competition experiments confirmed that the factor(s) interacting with different elements had closely related or identical recognition specificities. Finally, indistinguishable profiles of shift activities were seen upon fractionation of nuclear proteins over sequential chromatographic columns. Collectively, these results suggest that related elements interact with a shared protein to regulate three essential steroidogenic enzymes. An AGGTCA sequence motif comprises the response element for several members of the nuclear hormone receptor family. Oligonucleotide competitions and specific effects of antisera in gel shift assays implicated chicken ovalbumin upstream promoter-transcription factor in the formation of the larger complexes seen with the elements containing exact AGGTCA sequences. Therefore, this member of the nuclear hormone receptor family also may regulate the expression of the adrenal steroidogenic enzymes.

Activation of transcription in cell-free extracts by a novel cAMP-responsive sequence from the bovine CYP17 gene

An in vitro transcription system has been developed to study the transcriptional control of steroid hydroxylase gene expression in steroidogenic tissues using upstream sequences of these genes in rabbit beta-globin promoter/reporter constructs. Analysis of deletion mutants of the upstream region of the bovine CYP17 (p45017 alpha) gene in whole cell extracts prepared from mouse Y1 adrenocortical cells revealed that sequences activating transcription in vitro are identical to those previously identified in vivo, namely the novel cAMP-responsive sequences crsI (-243 to -225 base pairs) and crsII (-80 to -40 base pairs). These sequences do not contain the known cAMP response elements, CRE or AP-2. In similar extracts from nonsteroidogenic mouse SVT2 cells, crsI was unable to activate transcription. Partially purified protein factor(s) binding to crsI were prepared from Y1 extracts by crsI-specific DNA affinity chromatography. This fraction activated transcription in vitro in SVT2 extracts only when crsI was present in the template. This in vitro transcription system will permit further investigation of crsI and its cognate factors and of the transcriptional regulation of the other steroid hydroxylase genes.

Expression of the human apolipoprotein E gene suppresses steroidogenesis in mouse Y1 adrenal cells.

The lipid transport protein, apolipoprotein E (apoE), is expressed in many peripheral tissues in vivo including the adrenal gland and testes. To investigate the role of apoE in adrenal cholesterol homeostasis, we have expressed a human apoE genomic clone in the Y1 mouse adrenocortical cell line. Y1 cells do not express endogenous apoE mRNA or protein. Expression of apoE in Y1 cells resulted in a dramatic decrease in basal steroidogenesis; secretion of fluorogenic steroid was reduced 7- to greater than 100-fold relative to Y1 parent cells. Addition of 5-cholesten-3 beta,25-diol failed to overcome the suppression of steroidogenesis in these cells. Cholesterol esterification under basal conditions, as measured by the production of cholesteryl [14C]oleate, was similar in the Y1 parent and the apoE-transfected cell lines. Upon incubation with adrenocorticotropin or dibutyryl cAMP, production of cholesteryl [14C]oleate decreased 5-fold in the Y1 parent cells but was unchanged in the apoE-transfected cell lines. These results suggest that apoE may be an important modulator of cholesterol utilization and steroidogenesis in adrenal cells.

MRNA from mutant Y1 adrenal cells directs the synthesis of altered regulatory subunits of type 1 cAMP-dependent protein kinase.

The molecular basis for altered cyclic AMP-dependent protein kinase activity was examined in three different mutant clones (Kin-1, Kin-7, and Kin-8) derived from the Y1 mouse adrenocortical cell line. Parental Y1 cells and the Kin mutants were labeled with L-[35S] methionine and the regulatory subunit of the type 1 cAMP-dependent protein kinase isozyme (RI) was immunoprecipitated from each clone with a specific guinea pig antiserum. When analyzed by electrophoresis on isoelectric focusing gels, the immunoprecipitates from mutant clones exhibited parental forms of RI plus an additional acidic variant form which likely accounted for altered cAMP-dependent protein kinase activity. Poly(A+) RNA was isolated from Y1 and Kin mutant cells and was translated in a cell-free, reticulocyte lysate system in the presence of L-[35S]methionine. The RI synthesized from poly(A+) RNA was immunoprecipitated from the translation mixture and analyzed on isoelectric focusing gels. The poly(A+) RNA from the Kin mutant clones directed the synthesis of parental and acidic variant forms of RI. These results suggest that the altered electrophoretic forms of RI arise from mutations in one of two RI genes rather than from post-translational modifications of the protein. The coexistence of parental and variant forms of RI in the Kin mutants indicate that the mutations are codominant.