Assessing Estrogenic Activity of Classical Estrogen Receptor-Binding Compounds.

The classical estrogen receptor α (ERα) has been a clinical therapeutic target for decades. ERα-targeted drugs have shown great clinical success, in particular as antagonists for the treatment of ERα-positive breast cancers. However, ERα-targeted agonists have also been clinically useful (e.g., for the treatment of osteoporosis). The breast cancer field is regularly identifying novel ERα-binding compounds with the goal of identifying new potential ERα-targeted therapeutics. To determine whether such newly identified ERα-binding compounds have clinical potential, it is important to characterize the estrogenic activity (i.e., both receptor-mediated agonism and/or antagonism) of these compounds. This chapter focuses on methods that allow determination of whether an ERα-binding compound acts as an agonist or antagonist of the receptor and whether the compound induces degradation of the receptor.

G Protein-Coupled Estrogen Receptor in Cancer and Stromal Cells: Functions and Novel Therapeutic Perspectives.

Estrogen is involved in numerous physiological and pathophysiological systems. Its role in driving estrogen receptor-expressing breast cancers is well established, but it also has important roles in a number of other cancers, acting both on tumor cells directly as well as in the function of multiple cells of the tumor microenvironment, including fibroblasts, immune cells, and adipocytes, which can greatly impact carcinogenesis. One of its receptors, the G protein-coupled estrogen receptor (GPER), has gained much interest over the last decade in both health and disease. Increasing evidence shows that GPER contributes to clinically observed endocrine therapy resistance in breast cancer while also playing a complex role in a number of other cancers. Recent discoveries regarding the targeting of GPER in combination with immune checkpoint inhibition, particularly in melanoma, have led to the initiation of the first Phase I clinical trial for the GPER-selective agonist G-1. Furthermore, its functions in metabolism and corresponding pathophysiological states, such as obesity and diabetes, are becoming more evident and suggest additional therapeutic value in targeting GPER for both cancer and other diseases. Here, we highlight the roles of GPER in several cancers, as well as in metabolism and immune regulation, and discuss the therapeutic value of targeting this estrogen receptor as a potential treatment for cancer as well as contributing metabolic and inflammatory diseases and conditions.

A Selective Ligand for Estrogen Receptor Proteins Discriminates Rapid and Genomic Signaling.

Estrogen exerts extensive and diverse effects throughout the body of women. In addition to the classical nuclear estrogen receptors (ERα and ERß), the G protein-coupled estrogen receptor GPER is an important mediator of estrogen action. Existing ER-targeted therapeutic agents act as GPER agonists. Here, we report the identification of a small molecule, named AB-1, with the previously unidentified activity of high selectivity for binding classical ERs over GPER. AB-1 also possesses a unique functional activity profile as an agonist of transcriptional activity but an antagonist of rapid signaling through ERα. Our results define a class of small molecules that discriminate between the classical ERs and GPER, as well as between modes of signaling within the classical ERs. Such an activity profile, if developed into an ER antagonist, could represent an opportunity for the development of first-in-class nuclear hormone receptor-targeted therapeutics for breast cancer exhibiting reduced acquired and de novo resistance.

ERα-targeted endocrine therapy, resistance and the role of GPER.

Endocrine therapy is an effective option for the treatment of estrogen receptor alpha (ERα)-positive breast cancers. Unfortunately, a large fraction of women relapse with endocrine-resistant tumors. The presence of constitutively active ERα mutants, found in a subset of relapse tumors, is thought to be an important endocrine resistance mechanism and has prompted the search for more effective anti-hormone drugs that can effectively inhibit these mutant versions of the receptor. The G protein-coupled estrogen receptor (GPER) is also thought to contribute to the development of endocrine resistance, in part, due to its activation by clinically used selective estrogen receptor modulators and downregulators (SERMs/SERDs). Therefore, next-generation drugs should be screened for potential activity towards GPER. Here, we highlight the need for truly ERα-selective SERMs and SERDs that do not cross-react with GPER for the treatment of ERα-positive breast cancers.

Targeting hepatocyte growth factor receptor (Met) positive tumor cells using internalizing nanobody-decorated albumin nanoparticles.

The hepatocyte growth factor receptor (HGFR, c-Met or Met) is a receptor tyrosine kinase that is involved in embryogenesis, tissue regeneration and wound healing. Abnormal activation of this proto-oncogene product is implicated in the development, progression and metastasis of many cancers. Current therapies directed against Met, such as ligand- or, dimerization-blocking antibodies or kinase inhibitors, reduce tumor growth but hardly eradicate the tumor. In order to improve anti-Met therapy, we have designed a drug delivery system consisting of crosslinked albumin nanoparticles decorated with newly selected anti-Met nanobodies (anti-Met-NANAPs). The anti-Met NANAPs bound specifically to and were specifically taken up by Met-expressing cells and transported to lysosomes for degradation. Treatment of tumor cells with anti-Met NANAPs also resulted in downregulation of the total Met protein. This study shows that anti-Met NANAPs offer a potential system for lysosomal delivery of drugs into Met-positive tumor cells.