Expression and purification of a recombinant form of human aromatase from Escherichia coli.

Aromatase converts androgen to estrogen, a hormone that plays an important role in the development of breast cancer. Aromatase inhibitors have been shown to be a useful endocrine regimen for estrogen-dependent breast cancer. Structure-function studies of aromatase can generate critical structural information for designing highly potent and specific inhibitors. However, aromatase structure-function studies have been hampered by a lack of purified protein. In this report, we describe the construction and expression of a recombinant derivative of human aromatase in Escherichia coli using the pET vector system, and the purification of the enzyme by means of nickel-agarose affinity chromatography. We examined the expression of the full-length, Del-38, C-6xHis-tagged Del-38, and NC-6xHis-tagged Del-38 forms of aromatase. The recombinant aromatase without the first 38 amino acids from the amino-terminus (i.e. Del-38) was found to have a higher activity than the full-length enzyme. Moreover, the addition of two separate hexameric histidine tags at both the amino and the carboxyl-termini (i.e. NC-6xHis-tagged Del-38) increased the binding affinity of the recombinant enzyme to the nickel-agarose. The expressed aromatase (i.e. NC-6xHis-tagged Del-38 aromatase) was eluted from the nickel-agarose with 80 mM EDTA. The total aromatase activity of the 80 mM EDTA-eluted fractions was significantly higher than the detergent-solubilized protein extract, indicating a renaturation process during the nickel-agarose affinity chromatography. Purified aromatase exhibited a single band when analyzed by SDS-PAGE, and activity up to 5.8 nmol/mg/min was obtained using the tritiated water release assay. The K(m) value for androstenedione was determined to be 62+/-24 nM by enzyme kinetic analysis. The recombinant aromatase preparation was also characterized by reduced CO-difference spectral analysis, reaction product extraction assay, and inhibition studies using two aromatase inhibitors (letrozole and anastrozole). The results indicate that the recombinant aromatase from E. coli has catalytic properties identical to those of the enzyme expressed in human tissue and will be very useful for further structure-function studies of aromatase.

Prevention and treatment of breast cancer by suppressing aromatase activity and expression.

Estrogen promotes the proliferation of breast cancer cells. Aromatase is the enzyme that converts androgen to estrogen. In tumors, expression of aromatase is upregulated compared to that of surrounding noncancerous tissue. Tumor aromatase is thought to stimulate breast cancer growth in both an autocrine and a paracrine manner. A treatment strategy for breast cancer is to abolish in situ estrogen formation with aromatase inhibitors. In addition, aromatase suppression in postmenapausal women is being evaluated as a potential chemopreventive modality against breast cancer. One area of aromatase research in this laboratory is the identification of foods and dietary compounds that can suppress aromatase activity. In vitro and in vivo studies have found that grapes and mushrooms contain chemicals that can inhibit aromatase. Therefore, a diet that includes grapes and mushrooms would be considered preventative against breast cancer. Another area of our aromatase research is the elucidation of the regulatory mechanism of aromatase expression in breast cancer tissue. Increased aromatase expression in breast tumors is attributed to changes in the transcriptional control of aromatase expression. Whereas promoter I.4 is the main promoter that controls aromatase expression in noncancerous breast tissue, promoters II and I.3 are the dominant promoters that drive aromatase expression in breast cancer tissue. Our recent gene regulation studies revealed that in cancerous versus normal tissue, several positive regulatory proteins (e.g., nuclear receptors and CREB1) are present at higher levels and several negative regulatory proteins (e.g., snail and slug proteins) are present at lower levels. This may explain why the activity of promoters II and I.3 is upregulated in cancerous tissue. In addition, our in vitro transcription/translation analysis using plasmids containing T7 promoter and the human snail gene as a reporter capped with different untranslated exon Is revealed that exon PII-containing transcripts were translated more effectively than were exon I.3-containing transcripts. An understanding of the molecular mechanisms of aromatase expression between noncancerous and cancerous breast tissue, at both transcriptional and translational levels, may help in the design of a therapy based on suppressing aromatase expression in breast cancer tissue.

Homogenous assays for Escherichia coli DnaB-stimulated DnaG primase and DnaB helicase and their use in screening for chemical inhibitors.

Escherichia coli DnaG primase is a single-stranded DNA-dependent RNA polymerase. Primase catalyzes the synthesis of a short RNA primer to initiate DNA replication at the origin and to initiate Okazaki fragment synthesis for synthesis of the lagging strand. Primase activity is greatly stimulated through its interaction with DnaB helicase. Here we report a 96-well homogeneous scintillation proximity assay (SPA) for the study of DnaB-stimulated E. coli primase activity and the identification of E. coli primase inhibitors. The assay uses an adaptation of the general priming reaction by employing DnaG primase, DnaB helicase, and ribonucleotidetriphosphates (incorporation of [(3)H]CTP) for in vitro primer synthesis on single-stranded oligonucleotide and M13mp18 DNA templates. The primase product is captured by polyvinyl toluene-polyethyleneimine-coated SPA beads and quantified by counting by beta-scintography. In the absence of helicase as a cofactor, primer synthesis is reduced by 85%. The primase assay was used for screening libraries of compounds previously identified as possessing antimicrobial activities. Primase inhibitory compounds were then classified as direct primase inhibitors or mixed primase/helicase inhibitors by further evaluation in a specific assay for DnaB helicase activity. By this approach, specific primase inhibitors could be identified.