New androgen response elements in the murine pem promoter mediate selective transactivation.

The Pem homeobox transcription factor is expressed under androgen control in the testis and epididymis. It is also transcribed in the ovary, muscle, and placenta. The mouse Pem gene promoter was cloned and sequenced. It was analyzed in transactivation tests using CV-1 and PC-3 cells expressing the AR and found to be strongly stimulated by androgens. EMSAs and mutational analysis of the Pem promoter allowed the identification of two functional androgen response elements named ARE-1 and ARE-2. They both differed from the consensus semipalindromic steroid response element and exhibited characteristics of direct repeats of the TGTTCT half-site. Unlike the steroid response element, both Pem androgen response elements were selectively responsive to androgen stimulation. Specific mutations in the left half-site of Pem ARE-1 and ARE-2, but not of the steroid response element, were still compatible with AR binding in the EMSA. In addition, Pem ARE-1, but not ARE-2 or the steroid response element, showed some flexibility with regard to spacing between half-sites. These results strongly suggest that the AR interacts differently with direct repeats than with inverted repeats, potentially leading to cis element-driven selective properties. Thus, the existence of several classes of DNA response elements might be an essential feature of differential androgen regulation.

Androgen receptor signalling: comparative analysis of androgen response elements and implication of heat-shock protein 90 and 14-3-3eta.

Androgen receptor (AR) signalling was analysed using as models the cysteine-rich secretory protein-1 (CRISP-1) and CRISP-3 gene promoters, which are differentially regulated by androgen in vivo and contain multiple potential androgen response elements. Using electrophoretic mobility shift assay, we identified several elements with differing affinities for the AR at positions -3706, -1270, -1253 and -350 of the CRISP-1 promoter and at positions -369 and -349 of the CRISP-3 promoter. The strongest binding was observed for the -1253 element of CRISP-1. In transactivation assays using a PC-3 cell line stably transfected with the AR (PC-3/AR), the -1253 element placed as two or four copies upstream of the TK minimal promoter yielded a strong induction of luciferase reporter gene activity in the presence of the androgen methyltrienolone (R1881). In the context of the CRISP promoters a 2-fold induction by R1881 was measured for the CRISP-3 upstream region whereas only limited effects were noted for the CRISP-1 upstream region. The androgenic stimulation of the p(-1253 ARE)(4x)-TK-luciferase reporter construct was dose-dependently inhibited by geldanamycin and radicicol, two compounds that selectively interact with the chaperone protein, heat-shock protein 90. Cotransfection with an expression vector for the 14-3-3eta protein markedly enhanced the androgen-dependent stimulation. These results emphasize the influence of promoter context on androgen regulation and the importance of AR-associated proteins.

Differential androgen regulation of the murine genes for cysteine-rich secretory proteins (CRISP).

The androgen dependency of the genes coding for the cysteine-rich secretory proteins (CRISP) was analysed in their main sites of expression. Male mice were treated with the gonadotropin-releasing hormone antagonist Ac-DNapAla-DClPhAla-DPyrAla-Ser-Tyr-DCtl-Leu-Lys (Mor)-Pro-DAla-NH2 [DNapAla, D-2-naphthyl-Ala; DClPhAla, D-4-chlorphenyl-Ala; DPyrAla, D-pyridyn-3-yl-Ala; DCtl, D-citrulline; Lys(Mor), L-2-amino-6-(morpholin-4-yl)-hexanoic acid], and CRISP RNA levels were assessed by northern blot and competitive reverse transcriptase-mediated (RT)-PCR. In the salivary gland, CRISP-1 and to a lesser extent CRISP-3 expression was markedly reduced, in spite of an up-regulation of androgen receptor transcript levels. A down-regulation of CRISP-1 expression was also observed in the epididymis. Conversely, the levels of the testicular CRISP-2 transcripts were hardly affected at all. Female mice were ovariectomised and treated with testosterone propionate, and their salivary gland RNAs analysed. CRISP-1 and CRISP-3 RNA levels were significantly increased, and these effects were prevented by a concomitant treatment with the antiandrogen flutamide. Androgen receptor transcript levels were not affected by androgen administration but increased following antiandrogen treatment. CRISP expression during postnatal development was monitored by northern blot analysis. CRISP-1 and CRISP-2 transcripts were detected as early as 22 days after birth in the epididymis and testis, respectively, whereas CRISP-3 mRNA was visible only from day 30 in the salivary gland. A sharp increase of all CRISP levels was noted on day 40, coincident with the onset of sexual maturity. Altogether these results indicate that despite their high similarity, the CRISP genes are differentially regulated by androgens.

Repression of Acetolactate Synthase Activity through Antisense Inhibition (Molecular and Biochemical Analysis of Transgenic Potato (Solanum tuberosum L. cv Desiree) Plants).

Acetolactate synthase (ALS), the first enzyme in the biosynthetic pathway of leucine, valine, and isoleucine, is the biochemical target of different herbicides. To investigate the effects of repression of ALS activity through antisense gene expression we cloned an ALS gene from potato (Solanum tuberosum L. cv Desiree), constructed a chimeric antisense gene under control of the cauliflower mosaic virus 35S promoter, and created transgenic potato plants through Agrobacterium tumefaciens-mediated gene transfer. Two regenerants revealed severe growth retardation and strong phenotypical effects resembling those caused by ALS-inhibiting herbicides. Antisense gene expression decreased the steady-state level of ALS mRNA in these plants and induced a corresponding decrease in ALS activity of up to 85%. This reduction was sufficient to generate plants almost inviable without amino acid supplementation. In both ALS antisense and herbicide-treated plants, we could exclude accumulation of 2-oxobutyrate and/or 2-aminobutyrate as the reason for the observed deleterious effects, but we detected elevated levels of free amino acids and imbalances in their relative proportions. Thus, antisense inhibition of ALS generated an in vivo model of herbicide action. Furthermore, expression of antisense RNA to the enzyme of interest provides a general method for validation of potential herbicide targets.

A visible marker for antisense mRNA expression in plants: inhibition of chlorophyll synthesis with a glutamate-1-semialdehyde aminotransferase antisense gene.

Glutamate 1-semialdehyde aminotransferase [(S)-4-amino-5-oxopentanoate 4,5-aminomutase, EC 5.4.3.8] catalyzes the last step in the conversion of glutamate to delta-aminolevulinate of which eight molecules are needed to synthesize a chlorophyll molecule. Two full-length cDNA clones that probably represent the homeologous Gsa genes of the two tobacco (Nicotiana tabacum) genomes have been isolated. The deduced amino acid sequences of the 468-residue-long precursor polypeptides differ by 10 amino acids. The cDNA sequence of isoenzyme 2 was inserted in reverse orientation under the control of a cauliflower mosaic virus 35S promoter derivative in an expression vector and was introduced by Agrobacterium-mediated transformation into tobacco plants. Antisense gene expression decreased the steady-state mRNA level of glutamate 1-semialdehyde aminotransferase, the translation of the enzyme, and chlorophyll synthesis. Remarkably, partial or complete suppression of the aminotransferase mimics in tobacco a wide variety of chlorophyll variegation patterns caused by nuclear or organelle gene mutations in different higher plants. The antisense gene is inherited as a dominant marker.

Purification and properties of an Arthrobacter oxydans P52 carbamate hydrolase specific for the herbicide phenmedipham and nucleotide sequence of the corresponding gene.

Arthrobacter oxydans P52 isolated from soil samples was found to degrade the phenylcarbamate herbicides phenmedipham and desmedipham cometabolically by hydrolyzing their central carbamate linkages. The phenylcarbamate hydrolase (phenmedipham hydrolase) responsible for the degradative reaction was purified to homogeneity. The enzyme was shown to be a monomer with a molecular weight of 55,000. A 41-kb wild-type plasmid (pHP52) was identified in A. oxydans P52, but not in a derivative of this strain that had spontaneously lost the ability to hydrolyze phenylcarbamates, indicating that the gene for phenylcarbamate degradation (pcd) is plasmid encoded. Determination of two partial amino acid sequences allowed the localization of the coding sequence of the pcd gene on a 3.3-kb PstI restriction fragment within pHP52 DNA by hybridization with synthetic oligonucleotides. The phenylcarbamate hydrolase was functionally expressed in Escherichia coli under control of the lacZ promoter after the 3.3-kb PstI fragment was subcloned into the vector pUC19. A stretch of 1,864 bases within the cloned Pst fragment was sequenced. Sequence analysis revealed an open reading frame of 1,479 bases containing the amino acid partial sequences determined for the purified enzyme. Sequence comparisons revealed significant homology between the pcd gene product and the amino acid sequences of esterases of eukaryotic origin. Subsequently, it was demonstrated that the esterase substrate p-nitrophenylbutyrate is hydrolyzed by phenmedipham hydrolase.