Jeffrey Alan Dodge

Environmental estrogens : Effects on cholesterol lowering and bone in the ovariectomized rat

Representative non-steroidal estrogens, from common environmental sources such as plants, pesticides, surfactants, plastics, and animal health products, demonstrated an ability to lower serum cholesterol and prevent bone loss. Specifically, select environmental estrogens (coumestrol, genistein, methoxychlor, bisphenol A, and zeranol) effectively lowered total serum cholesterol in an estrogen-dependent animal model, the ovariectomized rat. Of these entities, coumestrol, methoxychlor, and zeranol prevented ovariectomy-induced bone loss. In an in vitro environment, these compounds competed with 17beta-estradiol for estrogen receptor binding and stimulated cell proliferation in a human breast cancer cell line (MCF-7). In addition to their well-documented effects on reproductive tissue, various environmental estrogens can dramatically affect non-reproductive parameters such as cholesterol lowering and bone metabolism.

DNA binding alters coactivator interaction surfaces of the intact VDR-RXR complex.

The vitamin D receptor (VDR) functions as an obligate heterodimer in complex with the retinoid X receptor (RXR). These nuclear receptors are multidomain proteins, and it is unclear how various domains interact with one another within the nuclear receptor heterodimer. Here, we show that binding of intact heterodimer to DNA alters the receptor dynamics in regions remote from the DNA-binding domains (DBDs), including the coactivator binding surfaces of both co-receptors, and that the sequence of the DNA response element can determine these dynamics. Furthermore, agonist binding to the heterodimer results in changes in the stability of the VDR DBD, indicating that the ligand itself may play a role in DNA recognition. These data suggest a mechanism by which nuclear receptors show promoter specificity and have differential effects on various target genes, providing insight into the function of selective nuclear receptor modulators.

Selective estrogen receptor modulators

Selective estrogen receptor modulators (SERMs) are structurally diverse compounds that bind to estrogen receptors (ER) and elicit agonist or antagonist responses depending on the target tissue and hormonal milieu. They are being evaluated primarily for conditions associated with aging, including hormone-responsive cancer, osteoporosis and cardiovascular disease. Several SERMs are marketed or are in clinical development, including triphenylethylenes (tamoxifen and its derivatives: toremifene, droloxifene and idoxifene), chromans (levormeloxifene), benzothiophenes (raloxifene, LY353381) and naphthalenes (CP336,156). Tamoxifen and toremifene, both used to treat advanced breast cancer, also have beneficial effects on bone mineral density and serum lipids in postmenopausal women. Tamoxifen was recently shown to decrease the risk of invasive breast cancer in women at high risk. Unfortunately, both drugs also have stimulatory effects on the endometrium. Raloxifene, used for prevention of postmenopausal osteoporosis and fragility fractures, also has favourable effects on bone mineral density, serum lipids and the incidence of invasive breast cancer in postmenopausal women but does not stimulate the endometrium. Like replacement estrogens, SERMs increase the risk of venous thromboembolism. SERMs offer postmenopausal women many of the advantages of estrogen replacement while mitigating some of the disadvantages, particularly the concern over breast cancer. Newer SERMs, exemplified by raloxifene, also eliminate the concerns over endometrial stimulation that were not addressed by first generation SERMs. The clinical success of SERMs has set the stage for a variety of drug therapies based on selective modulation of nuclear receptor activity.

Benzopyrans are selective estrogen receptor Beta agonists with novel activity in models of benign prostatic hyperplasia.

Benzopyran selective estrogen receptor beta agonist-1 (SERBA-1) shows potent, selective binding and agonist function in estrogen receptor beta (ERbeta) in vitro assays. X-ray crystal structures of SERBA-1 in ERalpha and beta help explain observed beta-selectivity of this ligand. SERBA-1 in vivo demonstrates involution of the ventral prostate in CD-1 mice (ERbeta effect), while having no effect on gonadal hormone levels (ERalpha effect) at 10x the efficacious dose, consistent with in vitro properties of this molecule.

Tetrahydroquinoline-based selective estrogen receptor modulators (SERMs)

A new series of estrogen receptor ligands based on a 6-hydroxy-tetrahydroquinoline scaffold is described, in addition to their binding affinity and functional activity in MCF-7 cells. Several 1,2-disubstituted tetrahydroquinolines bearing a basic side chain were shown to be high affinity ligands and antagonists in the MCF-7 proliferation assay. Compounds lacking the basic side chain were agonists in the MCF-7 assay.

Prediction of the tissue-specificity of selective estrogen receptor modulators by using a single biochemical method

Here, we demonstrate that a single biochemical assay is able to predict the tissue-selective pharmacology of an array of selective estrogen receptor modulators (SERMs). We describe an approach to classify estrogen receptor (ER) modulators based on dynamics of the receptor-ligand complex as probed with hydrogen/deuterium exchange (HDX) mass spectrometry. Differential HDX mapping coupled with cluster and discriminate analysis effectively predicted tissue-selective function in most, but not all, cases tested. We demonstrate that analysis of dynamics of the receptor–ligand complex facilitates binning of ER modulators into distinct groups based on structural dynamics. Importantly, we were able to differentiate small structural changes within ER ligands of the same chemotype. In addition, HDX revealed differentially stabilized regions within the ligand-binding pocket that may contribute to the different pharmacology phenotypes of the compounds independent of helix 12 positioning. In summary, HDX provides a sensitive and rapid approach to classify modulators of the estrogen receptor that correlates with their pharmacological profile.

Evaluation of the major metabolites of raloxifene as modulators of tissue selectivity

Raloxifene (LY139481 HCl) is a selective estrogen receptor modulator (SERM) which blocks the effects of estrogen on some tissues, such as the breast and uterus, while mimicking estrogen in other tissues, such as bone. To study the origins of this unique pharmacology, we have prepared the major metabolites of raloxifene as chemical probes for examining the estrogen receptor function in vitro and in vivo. In human breast cancer cell (MCF-7) related assays, these glucuronide conjugates show little affinity for the estrogen receptor and are more than two orders of magnitude less potent at inhibiting cell proliferation than raloxifene. In non-traditional estrogen target tissue, such as bone, these metabolites are less effective than the parent at inhibiting cytokine-stimulated bone resorbing activity in rat osteoclasts or producing transforming growth factor beta-3 (TGF-beta3). In animal models, tissue distribution studies with radiolabelled metabolite indicate that conversion to raloxifene occurs readily in a variety of tissues including the liver, lung, spleen, kidney, bone and uterus. Differential conversion of metabolite in target organs, such as bone and the uterus, is not observed indicating that the origin of raloxifenes pharmacology does not result from tissue-selective deconjugation of metabolite to parent.

Unique Ligand Binding Patterns between Estrogen Receptor α and β Revealed by Hydrogen−Deuterium Exchange

Here we present the use of hydrogen-deuterium exchange (HDX) mass spectrometry in analyzing the estrogen receptor beta ligand binding domain (ERbeta LBD) in the absence and presence of a variety of chemical compounds with different binding modes and pharmacological properties. Previously, we reported the use of HDX as a method for predicting the tissue selectivity of ERalpha ligands. HDX profiles of ERalpha LBD in complex with ligand could differentiate compounds of the same chemotype. In contrast, similar analysis of ERbeta LBD showed correlation to the compound chemical structures but little correlation with compound tissue selectivity. The different HDX patterns observed for ERbeta LBD when compared to those for ERalpha LBD bound to the same chemical compounds serve as an indication that ERbeta LBD undergoes a different structural response to the same ligand when compared to ERalpha LBD. The conformational dynamics revealed by HDX for ERbeta LBD together with those for ERalpha LBD shed light on ER ligand interactions and offer new structural insights. The compound-specific perturbations in HDX kinetics observed for each of the two isoforms should aid the development of subtype-selective ER ligands.

Growth hormone secretagogues

Growth hormone secretagogues (GHSs) are synthetic molecules that stimulate and amplify pulsatile pituitary growth hormone release, via a separate pathway distinct from GH releasing hormone/somatostatin. The activity of GHSs is not fully specific for GH secretion; some GHSs also have slight releasing activity on other pituitary hormones and mediate GH independent biological activities. The first GHSs were discovered in 1977. Since then, an intensive research to synthesize a potent oral GHSs has been undertaken. Although the potential applications of GHSs are numerous, long term trials are needed to evaluate the clinical efficacy and safety of these substances. In the present article we review the historic background of GHSs, their potential clinical uses, the types and the main GHSs that have been synthesized hitherto.

Estrogen Receptor Modulators: Relationships of Ligand Structure, Receptor Affinity and Functional Activity

The estrogen receptor is a regulator of a wide range of physiological functions, including the female reproductive system, in addition to bone, cardiovascular and CNS function. ER ligands have been approved for the treatment of menopausal symptoms, breast cancer and osteoporosis, however the search continues for new modulators of ER function with improved properties. Progress in medicinal chemistry programs has resulted in the identification of structurally diverse molecules with unique biological properties. Recent advances in the design and synthesis of these non-steroidal and steroidal estrogen receptor ligands is reviewed. The relationship between the structural features of the ligand and receptor function is also discussed.