Your search keyword '"Fernando Salgado-Polo"' showing total 6 results

1. Imaging Autotaxin In Vivo with 18F-Labeled Positron Emission Tomography Ligands

Author

Ahmed Haider, Lee Josephson, Jian Rong, Anastassis Perrakis, Steven H. Liang, Fernando Salgado-Polo, Tuo Shao, Xiaoyun Deng, Yihan Shao, Richard Van, Zhiwei Xiao, and Jiahui Chen

Subjects

medicine.diagnostic_test, In vivo, Chemistry, Positron emission tomography, Drug Discovery, Radioligand, Biophysics, medicine, Molecular Medicine, Phosphodiesterase, Autotaxin, In vitro

Abstract

Autotaxin (ATX) is a secreted phosphodiesterase that has been implicated in a remarkably wide array of pathologies, especially in fibrosis and cancer. While ATX inhibitors have entered the clinical arena, a validated probe for positron emission tomography (PET) is currently lacking. With the aim to develop a suitable ATX-targeted PET radioligand, we have synthesized a focused library of fluorinated imidazo[1,2-a]pyridine derivatives, determined their inhibition constants, and confirmed their binding mode by crystallographic analysis. Based on their promising in vitro properties, compounds 9c, 9f, 9h, and 9j were radiofluorinated. Also, a deuterated analog of [18F]9j, designated as [18F]ATX-1905 ([18F]20), was designed and proved to be highly stable against in vivo radiodefluorination compared with [18F]9c, [18F]9f, [18F]9h, and [18F]9j. These results along with in vitro and in vivo studies toward ATX in a mouse model of LPS-induced liver injury suggest that [18F]ATX-1905 is a suitable PET probe for the non-invasive quantification of ATX.

Published

2021

2. Autotaxin impedes anti-tumor immunity by suppressing chemotaxis and tumor infiltration of CD8(+) T cells

Author

Antonio Mazzocca, Andrew J. Morris, Sander de Kivit, Apostolos Menegakis, Maaike van Zon, Wouter H. Moolenaar, Ton N. Schumacher, Joost H. van den Berg, Elisa Matas-Rico, Inge Verbrugge, John B. A. G. Haanen, Irene van der Haar Àvila, Telma Lança, Zoë Johnson, Elselien Frijlink, Fernando Salgado-Polo, Jan Koster, Anastassis Perrakis, Jannie Borst, [Matas-Rico,E, Salgado-Polo,F, Perrakis,A, Moolenaar,WH] Division of Biochemistry, Netherlands Cancer Institute, Amsterdam, the Netherlands. [Frijlink,E, van der Haar Àvila,I, de Kivit,S, Verbrugge,I, Borst,J] Division of Tumor Biology and Immunology, Netherlands Cancer Institute, Amsterdam, the Netherlands. [Frijlink,E, Menegakis,A, Lança,T, Schumacher,TN, Borst,J] Oncode Institute, Utrecht, the Netherlands. [Menegakis,A] Division of Cell Biology, Netherlands Cancer Institute, Amsterdam, the Netherlands. [van Zon,M, Haanen,J, van den Berg,JH] Division of Molecular Oncology and Immunology, Netherlands Cancer Institute, Amsterdam, the Netherlands. [Morris,AJ] Division of Cardiovascular Medicine, Gill Heart Institute and Lexington Veterans Affairs Medical Center, University of Kentucky, Lexington, KY, USA. [Koster,J] Laboratory for Experimental Oncology and Radiobiology, Amsterdam UMC, Amsterdam, the Netherlands. [Mazzocca,A] Interdisciplinary Department of Medicine, University of Bari School of Medicine, Bari, Italy. [Johnson,Z] Onctura SA, Campus Biotech Innovation Park, Geneva, Switzerland. [Matas-Rico,E] Department of Cell Biology, Genetics and Physiology, Malaga University, Malaga, Spain. [Matas-Rico,E] Genitourinary Cancer Translational Research Group, The Institute of Biomedical Research in Malaga (IBIMA), Malaga, Spain. [van der Haar Àvila,I] Amsterdam UMC, Department of Molecular Cell Biology and Immunology, Amsterdam UMC, Amsterdam, the Netherlands. [de Kivit,S, Borst,J] Department of Immunology, Leiden University Medical Center, Leiden, the Netherlands. [Verbrugge,I] Janssen Pharmaceutica NV, Beerse, Belgium. [van den Berg,JH] CellPoint BV, Oegstgeest, the Netherlands., This work was supported by private funding to W.H.M. and grants from the Dutch Cancer Society (NKI 2013-5951 and 10764 to I.V. and NKI 2017-10894 to J.B. and I.V.), the German Research Foundation (DFG) (ME 4924/1-1 to A. Mazzocca), and the NIH (P30 GM127211 to A.J.M.). E.M.-R. is supported by a ‘‘Ramón y Cajal’’ Award (RYC2019-027950-I) from Ministerio de Ciencia e Innovación (MICINN), Spain., Oncogenomics, AII - Cancer immunology, and CCA - Cancer biology and immunology

Subjects

autotaxin, Anatomy::Cells::Cells, Cultured::Cell Line::Cell Line, Tumor [Medical Subject Headings], Organisms::Eukaryota::Animals::Chordata::Vertebrates::Mammals::Rodentia::Muridae::Murinae::Mice::Mice, Inbred Strains::Mice, Inbred C57BL [Medical Subject Headings], medicine.medical_treatment, Phenomena and Processes::Cell Physiological Phenomena::Cell Physiological Processes::Cell Movement::Chemotaxis [Medical Subject Headings], CD8-Positive T-Lymphocytes, Receptores acoplados a proteínas G, Chemicals and Drugs::Amino Acids, Peptides, and Proteins::Proteins::Membrane Proteins::Receptors, Cell Surface::Receptors, G-Protein-Coupled::Receptors, Lysophospholipid::Receptors, Lysophosphatidic Acid [Medical Subject Headings], Organisms::Eukaryota::Animals::Chordata::Vertebrates::Mammals::Primates::Haplorhini::Catarrhini::Hominidae::Humans [Medical Subject Headings], Mice, chemistry.chemical_compound, G protein-coupled receptors, Neoplasms, Lysophosphatidic acid, Anatomy::Cells::Blood Cells::Leukocytes::Leukocytes, Mononuclear::Lymphocytes::Lymphocytes, Tumor-Infiltrating [Medical Subject Headings], Organisms::Eukaryota::Animals [Medical Subject Headings], Cytotoxic T cell, Receptors, Lysophosphatidic Acid, Biology (General), Melanoma, Chemistry, Chemotaxis, anti-cancer vaccination, Linfocitos T, Neoplasias, Chemorepulsion, Autotaxin, Tumor microenvironment, single-cell RNAseq, Chemicals and Drugs::Lipids::Membrane Lipids::Phospholipids::Glycerophosphates::Phosphatidic Acids::Lysophospholipids [Medical Subject Headings], Female, immunotherapy, Immunotherapy, Signal Transduction, QH301-705.5, T cells, chemorepulsion, Anti-cancer vaccination, Article, General Biochemistry, Genetics and Molecular Biology, Single-cell RNAseq, Lymphocytes, Tumor-Infiltrating, Células, Microambiente tumoral, Cell Line, Tumor, medicine, melanoma, Animals, Humans, tumor microenvironment, Inmunoterapia, LPAR2, Organisms::Eukaryota::Animals::Chordata::Vertebrates::Mammals::Rodentia::Muridae::Murinae::Mice [Medical Subject Headings], LPAR1, Analytical, Diagnostic and Therapeutic Techniques and Equipment::Therapeutics::Biological Therapy::Immunomodulation::Immunotherapy::Immunization::Immunotherapy, Active::Vaccination [Medical Subject Headings], Phosphoric Diester Hydrolases, Phenomena and Processes::Cell Physiological Phenomena::Cellular Microenvironment::Tumor Microenvironment [Medical Subject Headings], Iysophosphatidic acid, Mice, Inbred C57BL, Cancer research, Lysophospholipids, lysophosphatidic acid, Anatomy::Cells::Blood Cells::Leukocytes::Leukocytes, Mononuclear::Lymphocytes::T-Lymphocytes::CD8-Positive T-Lymphocytes [Medical Subject Headings], Chemicals and Drugs::Enzymes and Coenzymes::Enzymes::Hydrolases::Esterases::Phosphoric Diester Hydrolases [Medical Subject Headings]

Abstract

SUMMARY Autotaxin (ATX; ENPP2) produces lysophosphatidic acid (LPA) that regulates multiple biological functions via cognate G protein-coupled receptors LPAR1–6. ATX/LPA promotes tumor cell migration and metastasis via LPAR1 and T cell motility via LPAR2, yet its actions in the tumor immune microenvironment remain unclear. Here, we show that ATX secreted by melanoma cells is chemorepulsive for tumor-infiltrating lymphocytes (TILs) and circulating CD8+ T cells ex vivo, with ATX functioning as an LPA-producing chaperone. Mechanistically, T cell repulsion predominantly involves Gα12/13-coupled LPAR6. Upon anti-cancer vaccination of tumor-bearing mice, ATX does not affect the induction of systemic T cell responses but, importantly, suppresses tumor infiltration of cytotoxic CD8+ T cells and thereby impairs tumor regression. Moreover, single-cell data from melanoma tumors are consistent with intratumoral ATX acting as a T cell repellent. These findings highlight an unexpected role for the pro-metastatic ATX-LPAR axis in suppressing CD8+ T cell infiltration to impede anti-tumor immunity, suggesting new therapeutic opportunities., In brief Through LPA production, ATX modulates the tumor microenvironment in autocrine-paracrine manners. Matas-Rico et al. show that ATX/LPA is chemorepulsive for T cells with a dominant inhibitory role for Gα12/13-coupled LPAR6. Upon anticancer vaccination, tumor-intrinsic ATX suppresses the infiltration of CD8+ T cells without affecting their cytotoxic quality., Graphical Abstract

Published

2021

3. Autotaxin impedes anti-tumor immunity by suppressing chemotaxis and tumor infiltration of CD8+ T cells

Author

Maaike van Zon, Elisa Matas-Rico, Andrew J. Morris, Inge Verbrugge, Sander de Kivit, John B. A. G. Haanen, Telma Lança, Joost H. van den Berg, Zoë Johnson, Irene van der Haar Àvila, Fernando Salgado-Polo, Elselien Frijlink, Ton N. Schumacher, Jan Koster, Anastassis Perrakis, Jannie Borst, Apostolos Menegakis, Antonio Mazzocca, and Wouter H. Moolenaar

Subjects

Cell type, chemistry.chemical_compound, LPAR1, chemistry, Melanoma, Lysophosphatidic acid, medicine, Cancer research, Cytotoxic T cell, Chemotaxis, Autotaxin, medicine.disease, CD8

Abstract

SummaryAutotaxin (ATX) is secreted by diverse cell types to produce lysophosphatidic acid (LPA) that regulates multiple biological functions via G protein-coupled receptors LPAR1-6. ATX/LPA promotes tumor cell migration and metastasis mainly via LPAR1; however, its actions in the tumor immune microenvironment remain unclear. Here, we show that ATX secreted by melanoma cells is chemorepulsive for tumor-infiltrating lymphocytes and circulating CD8+ T cells ex vivo, with ATX functioning as an LPA-producing chaperone. Mechanistically, T-cell repulsion predominantly involves Gα12/13-coupled LPAR6. Upon anti-cancer vaccination of tumor-bearing mice, ATX does not affect the induction of systemic T-cell responses but suppresses tumor infiltration of cytotoxic CD8+ T cells and thereby impairs tumor regression. Moreover, single-cell data from patient samples are consistent with intra-tumor ATX acting as a T-cell repellent. These studies highlight an unexpected role for the pro-metastatic ATX-LPAR axis in suppressing CD8+ T-cell infiltration to impede anti-tumor immunity, suggesting new therapeutic opportunities.

Published

2020

4. Sequence-dependent trafficking and activity of GDE2, a GPI-specific phospholipase promoting neuronal differentiation

Author

Elisa Matas-Rico, Michiel van Veen, Kees Jalink, Anastassis Perrakis, Wouter H. Moolenaar, Daniela Leyton-Puig, Bram van den Broek, and Fernando Salgado-Polo

Subjects

Glycosylphosphatidylinositols, media_common.quotation_subject, Mutant, Phospholipase, Biology, Endocytosis, 03 medical and health sciences, Mice, Neuroblastoma, 0302 clinical medicine, medicine, Animals, Neurodegeneration, Internalization, 030304 developmental biology, media_common, 0303 health sciences, GPI-anchored protein, Glycerophosphodiester phosphodiesterase, Phosphoric Diester Hydrolases, Phosphodiesterase, Cell Differentiation, Cell Biology, medicine.disease, In vitro, Cell biology, Glycosylphosphatidylinositol, Regulatory sequence, Phospholipases, 030217 neurology & neurosurgery, Rab GTPase, Research Article

Abstract

GDE2 (also known as GDPD5) is a multispanning membrane phosphodiesterase with phospholipase D-like activity that cleaves select glycosylphosphatidylinositol (GPI)-anchored proteins and thereby promotes neuronal differentiation both in vitro and in vivo. GDE2 is a prognostic marker in neuroblastoma, while loss of GDE2 leads to progressive neurodegeneration in mice; however, its regulation remains unclear. Here, we report that, in immature neuronal cells, GDE2 undergoes constitutive endocytosis and travels back along both fast and slow recycling routes. GDE2 trafficking is directed by C-terminal tail sequences that determine the ability of GDE2 to cleave GPI-anchored glypican-6 (GPC6) and induce a neuronal differentiation program. Specifically, we define a GDE2 truncation mutant that shows aberrant recycling and is dysfunctional, whereas a consecutive deletion results in cell-surface retention and gain of GDE2 function, thus uncovering distinctive regulatory sequences. Moreover, we identify a C-terminal leucine residue in a unique motif that is essential for GDE2 internalization. These findings establish a mechanistic link between GDE2 neuronal function and sequence-dependent trafficking, a crucial process gone awry in neurodegenerative diseases. This article has an associated First Person interview with the first author of the paper., Summary: GDE2, a six-transmembrane GPI-specific phospholipase, undergoes constitutive endosomal recycling via newly identified sequences and a unique leucine residue in its C-terminal tail as a way to regulate neuronal differentiation.

Published

2019

5. Sequence-dependent trafficking of GDE2, a GPI-specific phospholipase promoting neuronal differentiation

Author

Michiel van Veen, Fernando Salgado-Polo, Roy Baas, Daniela Leyton-Puig, Bram van den Broek, Wouter H. Moolenaar, Anastassis Perrakis, and Elisa Matas-Rico

Subjects

Nervous system, Glypican, biology, Endosome, Phospholipase, biology.organism_classification, Endocytosis, medicine.disease, Cell biology, medicine.anatomical_structure, Neuroblastoma, medicine, Secretion, Zebrafish

Abstract

SummaryGDE2 is a six-transmembrane glycerophosphodiesterase with phospholipase D-like activity that cleaves select glycosylphosphatidylinositol (GPI)-anchored proteins and thereby influences biological signaling cascades. GDE2 promotes neuronal differentiation cell-autonomously through glypican cleavage and is a prognostic marker in neuroblastoma, while GDE2 deficiency causes progressive neurodegeneration in mice and developmental defects in zebrafish. However, the regulation of GDE2 remains unclear. Here we show that in undifferentiated neuronal cells, GDE2 undergoes constitutive internalization and traffics back along both fast and slow recycling routes, while a small percentage is sorted to late endosomes. GDE2 trafficking is dictated by distinctive C-terminal tail sequences that determine secretion, endocytosis and recycling preference, respectively, and thereby regulate GDE2 function both positively and negatively. Our study reveals the sequence determinants of GDE2 trafficking and surface localization, and provides insight into the control of GPI-anchored protein activities with potential implications for nervous system disorders associated with impaired trafficking and beyond.

Published

2019

6. The Structural Binding Mode of the Four Autotaxin Inhibitor Types that Differentially Affect Catalytic and Non-Catalytic Functions

Author

Anastassis Perrakis and Fernando Salgado-Polo

Subjects

autotaxin, 0301 basic medicine, Cancer Research, orthosteric, Cell, Integrin, Allosteric regulation, Review, lcsh:RC254-282, allosteric, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Lysophosphatidic acid, lipid chaperone, medicine, signalling, Receptor, G protein-coupled receptor, gpcr, biology, Chemistry, lcsh:Neoplasms. Tumors. Oncology. Including cancer and carcinogens, inhibitor, 030104 developmental biology, medicine.anatomical_structure, Lysophosphatidylcholine, Oncology, Biochemistry, 030220 oncology & carcinogenesis, biology.protein, lipids (amino acids, peptides, and proteins), Autotaxin, lysophosphatidic acid

Abstract

Autotaxin (ATX) is a secreted lysophospholipase D, catalysing the conversion of lysophosphatidylcholine (LPC) to bioactive lysophosphatidic acid (LPA). LPA acts through two families of G protein-coupled receptors (GPCRs) controlling key cellular responses, and it is implicated in many physiological processes and pathologies. ATX, therefore, has been established as an important drug target in the pharmaceutical industry. Structural and biochemical studies of ATX have shown that it has a bimetallic nucleophilic catalytic site, a substrate-binding (orthosteric) hydrophobic pocket that accommodates the lipid alkyl chain, and an allosteric tunnel that can accommodate various steroids and LPA. In this review, first, we revisit what is known about ATX-mediated catalysis, crucially in light of allosteric regulation. Then, we present the known ATX catalysis-independent functions, including binding to cell surface integrins and proteoglycans. Next, we analyse all crystal structures of ATX bound to inhibitors and present them based on the four inhibitor types that are established based on the binding to the orthosteric and/or the allosteric site. Finally, in light of these data we discuss how mechanistic differences might differentially modulate the activity of the ATX-LPA signalling axis, and clinical applications including cancer.

Published

2019