Engrailed-2 (EN2) - a novel biomarker in epithelial ovarian cancer

McGrath, S.E., Annels, N., Madhuri, T.K., Tailor, A., Butler-Manuel, S.A., Morgan, Richard, Pandha, H., Michael, A.

03 October 2018

Yes / Background: Epithelial ovarian cancer is a common malignancy, with no clinically approved diagnostic biomarker. Engrailed-2 (EN2) is a homeodomain-containing transcription factor, essential during embryological neural development, which is dysregulated in several cancer types. We evaluated the expression of EN2 in Epithelial ovarian cancer, and reviewed its role as a biomarker. Methods: We evaluated 8 Epithelial ovarian cancer cell lines, along with > 100 surgical specimens from the Royal Surrey County Hospital (2009–2014). In total, 108 tumours and 5 normal tissue specimens were collected. En2 mRNA was evaluated by semi-quantitative RT-PCR. Histological sub-type, and platinum-sensitive/−resistant status were compared. Protein expression was assessed in cell lines (immunofluorescence), and in > 150 tumours (immunohistochemistry). Results: En2 mRNA expression was elevated in serous ovarian tumours compared with normal ovary (p < 0.001), particularly in high-grade serous ovarian cancer (p < 0.0001) and in platinum-resistant tumours (p = 0.0232). Median Overall Survival and Progression-free Survival were reduced with high En2 expression (OS = 28 vs 42 months, p = 0.0329; PFS = 8 vs 27 months; p = 0.0004). Positive cytoplasmic EN2 staining was demonstrated in 78% of Epithelial ovarian cancers, with absence in normal ovary. EN2 positive high-grade serous ovarian cancer patients had a shorter PFS (10 vs 17.5 months; p = 0.0103). Conclusion: The EN2 transcription factor is a novel ovarian cancer biomarker. It demonstrates prognostic value, correlating with worse Overall Survival and Progression-free Survival. It is hoped that further work will validate its use as a biomarker, and provide insight into the role of EN2 in the development, progression and spread of ovarian cancer. / Oncology Research and Development Departments at the Royal Surrey County Hospital and the University of Surrey

Epithelial ovarian cancer

Biomarker

Engrailed-2

Serous

Platinum-resistant

Membrane insertion and secretion of the Engrailed-2 (EN2) transcription factor by prostate cancer cells may induce antiviral activity in the stroma

Punia, N., Primon, Monika, Simpson, G.R., Pandha, H.S., Morgan, Richard

26 March 2019

Yes / Engrailed-2 (EN2) is a homeodomain-containing transcription factor that has roles in boundary formation and neural guidance in early development, but which is also expressed in a range of cancers. In addition to transcriptional regulation, it is secreted by cells and taken up by others through a mechanism that is yet to be fully elucidated. In this study, the distribution of EN2 protein in cells was evaluated using immunofluorescence with a set of antibodies raised against overlapping epitopes across the protein, and through the use of an EN2-GFP construct. MX2 expression in primary prostate tumors was evaluated using immunohistochemistry. We showed that EN2 protein is present in the cell membrane and within microvesicles that can be secreted from the cell and taken up by others. When taken up by normal cells from the stroma EN2 induces the expression of MX2 (MxB), a protein that has a key role in the innate immune response to viruses. Our findings indicate that EN2 secretion by tumors may be a means of preventing viral-mediated immune invasion of tissue immediately adjacent to the tumor. / The Ringrose Family Trust supported this study through a studentship awarded to N.P.

Engrailed-2 (EN2)

Secretion

Prostate cancer cells

Antiviral activity

Stroma

Étude quantitative du rôle spécifique de glycosaminoglycanes dans le mécanisme d'internalisation de l'homéoprotéine engrailed 2 / Quantitative study of glycosaminoglycan specific role on internalization mecanism of the homeoprotein engrailed 2

Cardon, Sébastien

12 October 2017

Les homéoprotéines sont des facteurs de transcription importants au cours du développement des organismes vivants, capables notamment de voyager de cellule en cellule. Ces protéines comportent une longue extrémité N-terminale désordonnée, suivie de trois hélices α séparées par une boucle et un tour. Des études de relations structure-activité ont montré que des domaines cationiques (riches en K et R) particuliers dans ces protéines sont responsables de ces propriétés de transfert cellulaire leur permettant d’être secrétées et internalisées dans les cellules. Ces processus impliquent que ces protéines hydrophiles soient capables de franchir la membrane plasmique composée d'un coeur hydrophobe. La membrane plasmique est en effet composée d’une bicouche lipidique, dans laquelle sont insérées de nombreuses protéines, telles que les protéoglycanes portant des ramifications de glycosaminoglycanes (GAG), polysaccharides anioniques. Dans le but de comprendre au niveau moléculaire le processus d'entrée des homéoprotéines dans des cellules eucaryotes, différentes constructions protéiques ont été produites et étudiées : le peptide pénétrant les cellules correspondant à l'hélice 3 (H3), la séquence correspondant à l'homéodomaine (HD), l'homéodomaine étendu d'une séquence putative de liaison aux GAG (NLS-HD) et la protéine entière (En2). La quantification absolue de l’entrée de ces constructions dans des cellules CHO-K1 par spectrométrie de masse a mis en évidence une efficacité d'entrée meilleure pour H3 > NLS-HD > HD, ainsi que l’importance des GAG de surface dans le processus et plus particulièrement celui des héparanes sulfates (HS). Des expériences complémentaires d’ITC, de dichroïsme circulaire et de RMN ont permis d'identifier deux sites d’interaction avec l’héparine (un site principal de haute affinité et un site secondaire de plus basse affinité), interagissant principalement avec le polysaccharide par interactions électrostatiques. In fine, ces études conduisent à une meilleure compréhension moléculaire du processus d'internalisation des homéoprotéines dans des cellules eucaryotes. / Homeoproteins are important transcription factors during the development of living organisms, and are able to travel from cell to cell. These proteins contain a long N-terminal extremity structurally disordered, followed by three α helices separated by a U-turn. Structure-activity relation studies have shown that in these proteins, some cationic domains (rich in K and R) confer them the cellular transfer properties, allowing them to be secreted by and internalized into cells. These processes imply that the hydrophilic proteins are able to cross plasma membrane. Indeed, the plasma membrane possess a hydrophobic heart and is composed by a lipidic bilayer, in which numerous proteins are inserted, such as proteoglycans carrying glycosaminoglycan (GAG) ramifications, that belong to anionic polysaccharids. In order to understand the entry process of homeoproteins into eukaryotic cells at a molecular level, different proteic constructions have been produced and studied: the cell penetrating peptide corresponding to the third α helix (H3), the sequence corresponding to its homeodomain (HD), the homeodomain with an added putative GAG-binding domain (NLS-HD), and the wild-type protein Engrailed 2 (En2). The absolute mass spectrometry quantification of the peptide and proteins in cells shows a range of internalization efficiency as follows: H3 > NLS - HD > HD. It also highlights the importance of cell-surface GAGs in the internalization and more particularly that of heparan sulfates (HS). Complementary experiments of ITC, circular dichroism and NMR have shown two interaction sites for the heparin (one principal site of high affinity and a secondary site showing a lower affinity) both interacting mainly with polysaccharidic residues using electrostatic interactions. In fine, these studies lead to a better molecular understanding of homeoproteins internalization process in eukaryotic cells.

Homéoprotéine Engrailed 2

Interaction protéine-Polysaccharides

Relation structure-Activité

ITC

RMN

Engrailed 2 homeoprotein

Protein-Polysaccharides interaction

Sulfate heparan and sulfate chondroitin

Structure-Activity relationship

ITC

NMR

541.2

Engrailed is Required in Maturing Serotonin Neurons to Regulate the Cytoarchitecture and Survival of the Dorsal Raphe Nucleus

Fox, Stephanie R.

27 August 2012

No description available.

Biomedical Research

Developmental Biology

Genetics

Molecular Biology

Neurosciences

Engrailed1

Engrailed 2

Pet-1

transcription factor

serotonin

development