Blockade of angiogenesis can retard tumour growth, but may also paradoxically increase metastasis1,2. Vessel normalization (VN) may resolve this paradox3. VN involves increased pericyte coverage, improved tumour vessel perfusion, reduced vascular permeability, and consequently mitigated hypoxia3. While these processes alter tumour progression, their regulation is poorly understood. Here we show that Type 1 T helper (Th1) cells play a crucial role in VN. Bioinformatic analyses revealed that gene expression features related to VN correlate with immunostimulatory pathways, especially T lymphocyte (TL) infiltration/activities. To delineate the causal relationship, we employed various mouse models with VN or TL deficiencies. While VN disruption reduced TL infiltration as expected4, reciprocal depletion or inactivation of CD4+-TLs decreased VN, indicating a mutually-regulatory loop. Additionally, CD4+-TL activation by immune checkpoint blockade (ICB) increased VN. IFNγ+ Th1 cells are the major population associated with VN. Patient-derived xenograft (PDX) tumours growing in immunodeficient animal hosts exhibited enhanced hypoxia compared to the original tumours in immunocompetent human hosts, which was reduced by adoptive Th1 transfer. Our findings elucidate an unexpected role of Th1 in vasculature and immune reprogramming. Th1 cells may be a marker and a determinant of both ICB and anti-angiogenesis efficacies.
Using a chromatin immunoprecipitation-paired end diTag cloning and sequencing strategy, we mapped estrogen receptor α (ERα) binding sites in MCF-7 breast cancer cells. We identified 1,234 high confidence binding clusters of which 94% are projected to be bona fide ERα binding regions. Only 5% of the mapped estrogen receptor binding sites are located within 5 kb upstream of the transcriptional start sites of adjacent genes, regions containing the proximal promoters, whereas vast majority of the sites are mapped to intronic or distal locations (>5 kb from 5′ and 3′ ends of adjacent transcript), suggesting transcriptional regulatory mechanisms over significant physical distances. Of all the identified sites, 71% harbored putative full estrogen response elements (EREs), 25% bore ERE half sites, and only 4% had no recognizable ERE sequences. Genes in the vicinity of ERα binding sites were enriched for regulation by estradiol in MCF-7 cells, and their expression profiles in patient samples segregate ERα-positive from ERα-negative breast tumors. The expression dynamics of the genes adjacent to ERα binding sites suggest a direct induction of gene expression through binding to ERE-like sequences, whereas transcriptional repression by ERα appears to be through indirect mechanisms. Our analysis also indicates a number of candidate transcription factor binding sites adjacent to occupied EREs at frequencies much greater than by chance, including the previously reported FOXA1 sites, and demonstrate the potential involvement of one such putative adjacent factor, Sp1, in the global regulation of ERα target genes. Unexpectedly, we found that only 22%–24% of the bona fide human ERα binding sites were overlapping conserved regions in whole genome vertebrate alignments, which suggest limited conservation of functional binding sites. Taken together, this genome-scale analysis suggests complex but definable rules governing ERα binding and gene regulation.
Estrogens exert many important effects in bone, a tissue that contains both estrogen receptors alpha and beta (ERalpha and ERbeta). To compare the actions of these receptors, we generated U2OS human osteosarcoma cells stably expressing ERalpha or ERbeta, at levels comparable with those in osteoblasts, and we characterized their response to 17beta-estradiol (E2) over time using Affymetrix GeneChip microarrays to determine the expression of approximately 12,000 genes, followed by quantitative PCR verification of the regulation of selected genes. Of the approximately 100 regulated genes we identified, some were stimulated by E2 equally through ERalpha and ERbeta, whereas others were selectively stimulated via ERalpha or ERbeta. The E2-regulated genes showed three distinct temporal patterns of expression over the 48-h time course studied. Of the functional categories of the E2-regulated genes, most numerous were those encoding cytokines and factors associated with immune response, signal transduction, and cell migration and cytoskeleton regulation, indicating that E2 can exert effects on multiple pathways in these osteoblast-like cell lines. Of note, E2 up-regulated several genes associated with cell motility selectively via ERbeta, in keeping with the selective E2 enhancement of the motility of ERbeta-containing cells. On genes regulated equally by E2 via ERalpha or ERbeta, the phytoestrogen genistein preferentially stimulated gene expression via ERbeta. These studies indicate both common as well as distinct target genes for these two ERs, and identify many novel genes not previously known to be under estrogen regulation.
Posttranslational modifications of the estrogen receptor (ER) are emerging as important regulatory elements of cross talk between different signaling pathways. ER phosphorylation, in particular, has been implicated in the ligand-independent effects of ER and in tamoxifen resistance of breast tumors. In our studies, Western immunoblot analysis of endogenous ER in parental MCF-7 cells reveals specific, ligand-dependent phosphorylations at S118 and S167, with this ligand dependence being lost in tamoxifen-resistant, MCF-7 Her2/neu cells. Using highly purified components and sensitive fluorescence methods in an in vitro system, we show that phosphorylation by different kinases alters ER action through distinct mechanisms. Phosphorylation by Src and protein kinase A increases affinity for estradiol (E2), whereas ER phosphorylation by MAPK decreases trans-hydroxytamoxifen (TOT) binding. Affinity of ER for the consensus estrogen response element is also altered by phosphorylation in a ligand-specific manner, with decrease in affinity of MAPK- and Src-phosphorylated ER in the presence of TOT. ER phosphorylation by MAPK, AKT, or protein kinase A increases recruitment of steroid receptor coactivator 3 receptor interaction domain to the DNA-bound receptor in the presence of E2. Taken together, these results suggest that ER phosphorylation alters receptor functions (ligand, DNA, and coactivator binding), effecting changes that could lead to an increase in E2 agonism and a decrease in TOT antagonistic activity, reflecting changes encountered in tamoxifen resistance in endocrine therapy of breast cancer.
The estrogen receptors, ERalpha and ERbeta, are important pharmaceutical targets. To develop ERbeta-selective ligands, we synthesized a series of nonsteroidal compounds having a phenyl-2H-indazole core with different groups at C-3. Several of these show high affinity and good ERbetaselectivity, especially those with polar and/or polarizable substituents at this site (halogen, CF(3), nitrile); the best compounds have affinities for ERbeta comparable to estradiol, with ERbetaaffinity selectivity >100. This potency and ERbeta selectivity is also seen in cell-based transcriptional assays, where several compounds showed ERbeta efficacies equivalent to that of estradiol with ERbeta potency selectivities of 100. These compounds might prove useful as selective pharmacological probes to study the biological actions of estrogens mediated through ERbeta, and they might lead to the development of useful pharmaceuticals. These findings also contribute to an evolving pharmacophore that characterizes certain nonsteroidal ligands having high ERbeta subtype affinity and potency selectivity.
Zika virus (ZIKV) is an emerging mosquito-borne (Aedes genus) arbovirus of the Flaviviridae family. Although ZIKV has been predominately associated with a mild or asymptomatic dengue-like disease, its appearance in the Americas has been accompanied by a multi-fold increase in reported incidence of fetal microcephaly and brain malformations. The source and mode of vertical transmission from mother to fetus is presumptively transplacental, although a causal link explaining the interval delay between maternal symptoms and observed fetal malformations following infection has been missing. In this study, we show that primary human placental trophoblasts from non-exposed donors (n = 20) can be infected by primary passage ZIKV-FLR isolate, and uniquely allowed for ZIKV viral RNA replication when compared to dengue virus (DENV). Consistent with their being permissive for ZIKV infection, primary trophoblasts expressed multiple putative ZIKV cell entry receptors, and cellular function and differentiation were preserved. These findings suggest that ZIKV-FLR strain can replicate in human placental trophoblasts without host cell destruction, thereby serving as a likely permissive reservoir and portal of fetal transmission with risk of latent microcephaly and malformations.
Estrogens, acting through their nuclear receptors have a broad impact on target cells, eliciting a transcriptional response program that involves gene repression as well as gene stimulation. While much is known about the mechanisms by which the estrogen-occupied estrogen receptor (ER) stimulates gene expression, the molecular events that lead to gene repression by the hormone-ER complex are largely unknown. Because estradiol represses expression of the cyclin G2 gene, which encodes a negative regulator of the cell cycle, our aim was to understand the mechanism by which cyclin G2 is repressed by estrogen. We show that cyclin G2 is a primary ER target gene in MCF-7 breast cancer cells that is rapidly and robustly down-regulated by estrogen. Promoter analysis reveals a responsive region containing a halfestrogen response element and GC-rich region that interact with ER and Sp1 proteins. Mutation of the half-ERE abrogates hormone-mediated repression. Mutational mapping of receptor reveals a requirement for its N-terminal region and DNA binding domain to support cyclin G2 repression. Following estradiol treatment of cells, chromatin immunoprecipitation analyses reveal recruitment of ER to the cyclin G2 regulatory region, dismissal of RNA polymerase II, and recruitment of a complex containing N-CoR and histone deacetylases, leading to a hypoacetylated chromatin state. Our study provides evidence for a mechanism by which the estrogen-occupied ER is able to actively repress gene expression in vivo and indicates a role for nuclear receptor corepressors and associated histone deacetylase activity in mediating negative gene regulation by this hormone-occupied nuclear receptor.In target cells, estrogen hormones act via their nuclear receptors to elicit a diverse transcriptional response program that involves gene repression as well as gene stimulation (1-3). Estrogen receptors (ERs) 3 share their modular domain structure with the other members of the steroid and nuclear receptor superfamily and are comprised of an N-terminal domain characterized by a ligand-independent activation function (AF-1), a central DNA binding domain (DBD) followed by a hinge region, and a C-terminal ligand binding domain (LBD), which contains a ligand-dependent activation function (AF-2) important for coregulator recruitment (4, 5).In the mammary gland, the actions of estrogens are essential for normal growth and development. In breast cancer, the presence of ERs is associated with likely response to endocrine therapy, most usually treatment with antiestrogens such as tamoxifen, or estrogen depletion by the use of aromatase inhibitors (6). Estrogens enhance the proliferation of ER-positive breast cancer cells, and recent studies have shown that this enhancement of proliferation involves both stimulation of the expression of many genes associated with cell cycle progression, as well as the suppression of genes that block the cell cycle (7). Most previous studies, focusing on the mechanisms that lead to stimulation of gene expression, have demonstrat...
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.