Placenta-specific Slc38a2/SNAT2 knockdown causes fetal growth restriction in mice

Abstract Fetal growth restriction (FGR) is a complication of pregnancy that reduces birth weight, markedly increases infant mortality and morbidity and is associated with later-life cardiometabolic disease. No specific treatment is available for FGR. Placentas of human FGR infants have low abundance of sodium-coupled neutral amino acid transporter 2 (Slc38a2/SNAT2), which supplies the fetus with amino acids required for growth. We determined the mechanistic role of placental Slc38a2/SNAT2 deficiency in the development of restricted fetal growth, hypothesizing that placenta-specific Slc38a2 knockdown causes FGR in mice. Using lentiviral transduction of blastocysts with a small hairpin RNA (shRNA), we achieved 59% knockdown of placental Slc38a2, without altering fetal Slc38a2 expression. Placenta-specific Slc38a2 knockdown reduced near-term fetal and placental weight, fetal viability, trophoblast plasma membrane (TPM) SNAT2 protein abundance, and both absolute and weight-specific placental uptake of the amino acid transport System A tracer, 14C-methylaminoisobutyric acid (MeAIB). We also measured human placental SLC38A2 gene expression in a well-defined term clinical cohort and found that SLC38A2 expression was decreased in late-onset, but not early-onset FGR, compared with appropriate for gestational age (AGA) control placentas. The results demonstrate that low placental Slc38a2/SNAT2 causes FGR and could be a target for clinical therapies for late-onset FGR.

[1]  W. Kuebler,et al.  Sodium coupled neutral amino acid transporter SNAT2 counteracts cardiogenic pulmonary edema by driving alveolar fluid clearance. , 2021, American journal of physiology. Lung cellular and molecular physiology.

[2]  S. Ourselin,et al.  Magnetic Resonance Imaging Measurement of Placental Perfusion and Oxygen Saturation in Early-Onset Fetal Growth Restriction , 2020, BJOG : an international journal of obstetrics and gynaecology.

[3]  T. Powell,et al.  Changes in Placental Nutrient Transporter Protein Expression and Activity Across Gestation in Normal and Obese Women , 2020, Reproductive Sciences.

[4]  J. Zeitlin,et al.  Antenatal detection of fetal growth restriction and risk of stillbirth: population‐based case–control study , 2020, Ultrasound in obstetrics & gynecology : the official journal of the International Society of Ultrasound in Obstetrics and Gynecology.

[5]  Shogo Matoba,et al.  Paternal knockout of Slc38a4/SNAT4 causes placental hypoplasia associated with intrauterine growth restriction in mice , 2019, Proceedings of the National Academy of Sciences.

[6]  W. Dean,et al.  Mechanisms of early placental development in mouse and humans , 2019, Nature Reviews Genetics.

[7]  J. Kingdom,et al.  Defining early vs late fetal growth restriction by placental pathology , 2018, Acta obstetricia et gynecologica Scandinavica.

[8]  F. Figueras,et al.  Evidence‐based national guidelines for the management of suspected fetal growth restriction: comparison, consensus, and controversy , 2018, American journal of obstetrics and gynecology.

[9]  A. Park,et al.  Mortality in Infants Affected by Preterm Birth and Severe Small-for-Gestational Age Birth Weight , 2017, Pediatrics.

[10]  T. Henriksen,et al.  Uptake and release of amino acids in the fetal-placental unit in human pregnancies , 2017, PloS one.

[11]  T. Nishimura,et al.  Contributions of system A subtypes to α-methylaminoisobutyric acid uptake by placental microvillous membranes of human and rat , 2017, Amino Acids.

[12]  N. Marlow,et al.  EVERREST prospective study: a 6-year prospective study to define the clinical and biological characteristics of pregnancies affected by severe early onset fetal growth restriction , 2017, BMC Pregnancy and Childbirth.

[13]  D. Williams,et al.  Delivery of small‐for‐gestational‐age neonate and association with early‐onset impaired maternal endothelial function , 2016, Ultrasound in obstetrics & gynecology : the official journal of the International Society of Ultrasound in Obstetrics and Gynecology.

[14]  F. Rosario,et al.  Regulation of Placental Amino Acid Transport and Fetal Growth. , 2017, Progress in molecular biology and translational science.

[15]  S. Weintraub,et al.  Down-Regulation of Placental Transport of Amino Acids Precedes the Development of Intrauterine Growth Restriction in Maternal Nutrient Restricted Baboons , 2016, Biology of reproduction.

[16]  P. Rozance,et al.  Chronically Increased Amino Acids Improve Insulin Secretion, Pancreatic Vascularity, and Islet Size in Growth-Restricted Fetal Sheep. , 2016, Endocrinology.

[17]  P. Rathjen,et al.  Regulation of amino acid transporters in pluripotent cell populations in the embryo and in culture; novel roles for sodium-coupled neutral amino acid transporters , 2016, Mechanisms of Development.

[18]  R. Anthony,et al.  Development of ovine chorionic somatomammotropin hormone-deficient pregnancies. , 2016, American journal of physiology. Regulatory, integrative and comparative physiology.

[19]  A. Papageorghiou,et al.  Consensus definition of fetal growth restriction: a Delphi procedure , 2016, Ultrasound in obstetrics & gynecology : the official journal of the International Society of Ultrasound in Obstetrics and Gynecology.

[20]  A. Fowden,et al.  Placental phenotype and resource allocation to fetal growth are modified by the timing and degree of hypoxia during mouse pregnancy , 2015, The Journal of physiology.

[21]  Madhulika B. Gupta,et al.  Increased ubiquitination and reduced plasma membrane trafficking of placental amino acid transporter SNAT-2 in human IUGR , 2015, Clinical science.

[22]  Y. Kanai,et al.  Expression and functional characterisation of System L amino acid transporters in the human term placenta , 2015, Reproductive Biology and Endocrinology.

[23]  Y. Kanai,et al.  Increased placental nutrient transport in a novel mouse model of maternal obesity with fetal overgrowth , 2015, Obesity.

[24]  Rohan M. Lewis,et al.  Integration of computational modeling with membrane transport studies reveals new insights into amino acid exchange transport mechanisms , 2015, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[25]  G. Hitman,et al.  Novel DNA methylation profiles associated with key gene regulation and transcription pathways in blood and placenta of growth-restricted neonates , 2015, Epigenetics.

[26]  D. Natale,et al.  Important aspects of placental-specific gene transfer. , 2014, Theriogenology.

[27]  F. Malone,et al.  Fetal growth restriction and the risk of perinatal mortality–case studies from the multicentre PORTO study , 2014, BMC Pregnancy and Childbirth.

[28]  E. Gratacós,et al.  Update on the Diagnosis and Classification of Fetal Growth Restriction and Proposal of a Stage-Based Management Protocol , 2014, Fetal Diagnosis and Therapy.

[29]  A. Hofman,et al.  Placental Vascular Dysfunction, Fetal and Childhood Growth, and Cardiovascular Development: The Generation R Study , 2013, Circulation.

[30]  E. Gratacós,et al.  Evaluation of an Optimal Gestational Age Cut-Off for the Definition of Early- and Late-Onset Fetal Growth Restriction , 2013, Fetal Diagnosis and Therapy.

[31]  K. Ozono,et al.  Sodium‐coupled neutral amino acid transporter 4 functions as a regulator of protein synthesis during liver development , 2013, Hepatology research : the official journal of the Japan Society of Hepatology.

[32]  I. Cetin,et al.  SNAT2 expression and regulation in human growth-restricted placentas , 2013, Pediatric Research.

[33]  D. Peebles,et al.  Paternal Metabolic and Cardiovascular Risk Factors for Fetal Growth Restriction , 2013, Diabetes Care.

[34]  Guoyao Wu,et al.  Arginine, Leucine, and Glutamine Stimulate Proliferation of Porcine Trophectoderm Cells Through the MTOR-RPS6K-RPS6-EIF4EBP1 Signal Transduction Pathway1 , 2013, Biology of reproduction.

[35]  P. Rozance,et al.  Increased amino acid supply potentiates glucose-stimulated insulin secretion but does not increase β-cell mass in fetal sheep. , 2013, American journal of physiology. Endocrinology and metabolism.

[36]  Y. Kanai,et al.  Mammalian target of rapamycin signalling modulates amino acid uptake by regulating transporter cell surface abundance in primary human trophoblast cells , 2013, The Journal of physiology.

[37]  Asad Malik,et al.  Maternal and fetal risk factors for stillbirth: population based study , 2013, BMJ.

[38]  A. Fowden,et al.  Maternal corticosterone regulates nutrient allocation to fetal growth in mice , 2012, The Journal of physiology.

[39]  C. Sibley,et al.  eNOS knockout mouse as a model of fetal growth restriction with an impaired uterine artery function and placental transport phenotype. , 2012, American journal of physiology. Regulatory, integrative and comparative physiology.

[40]  P. Rozance,et al.  Insulin-like growth factor and fibroblast growth factor expression profiles in growth-restricted fetal sheep pancreas , 2012, Experimental biology and medicine.

[41]  M. Monuteaux,et al.  Systematic Review and Meta-Analysis of Preterm Birth and Later Systolic Blood Pressure , 2012, Hypertension.

[42]  T. Harris,et al.  Leucine and arginine regulate trophoblast motility through mTOR-dependent and independent pathways in the preimplantation mouse embryo. , 2012, Developmental biology.

[43]  G. Burton,et al.  Dietary composition programmes placental phenotype in mice , 2011, The Journal of physiology.

[44]  P. Rathjen,et al.  The amino acid transporter SNAT2 mediates L-proline-induced differentiation of ES cells. , 2011, American journal of physiology. Cell physiology.

[45]  Y. Kanai,et al.  Maternal Protein Restriction in the Rat Inhibits Placental Insulin, mTOR, and STAT3 Signaling and Down-Regulates Placental Amino Acid Transporters , 2011, Endocrinology.

[46]  C. Sibley,et al.  The contribution of SNAT1 to system A amino acid transporter activity in human placental trophoblast , 2010, Biochemical and biophysical research communications.

[47]  P. Rozance,et al.  Consequences of a compromised intrauterine environment on islet function. , 2010, The Journal of endocrinology.

[48]  C. Sibley,et al.  Isolation of Plasma Membrane Vesicles from Mouse Placenta at Term and Measurement of System A and System β Amino Acid Transporter Activity , 2010, Placenta.

[49]  T. Konno,et al.  In vivo genetic manipulation of the rat trophoblast cell lineage using lentiviral vector delivery , 2009, Genesis.

[50]  J. Glazier,et al.  The SNAT4 isoform of the system A amino acid transporter is functional in human placental microvillous plasma membrane , 2008, The Journal of physiology.

[51]  J. Rossant,et al.  Trophoblast-specific gene manipulation using lentivirus-based vectors. , 2007, BioTechniques.

[52]  M. Ikawa,et al.  Complementation of placental defects and embryonic lethality by trophoblast-specific lentiviral gene transfer , 2007, Nature Biotechnology.

[53]  V. Ganapathy,et al.  Down‐regulation of placental transport of amino acids precedes the development of intrauterine growth restriction in rats fed a low protein diet , 2006, The Journal of physiology.

[54]  P. Newsholme,et al.  Glutamine regulates expression of key transcription factor, signal transduction, metabolic gene, and protein expression in a clonal pancreatic beta-cell line. , 2006, The Journal of endocrinology.

[55]  H. Bernstein,et al.  SNAT expression in rat placenta. , 2006, Placenta.

[56]  Anne E Carpenter,et al.  A Lentiviral RNAi Library for Human and Mouse Genes Applied to an Arrayed Viral High-Content Screen , 2006, Cell.

[57]  P. Rozance,et al.  Attenuated insulin release and storage in fetal sheep pancreatic islets with intrauterine growth restriction. , 2006, Endocrinology.

[58]  H. Lafeber,et al.  Arginine and Mixed Amino Acids Increase Protein Accretion in the Growth-Restricted and Normal Ovine Fetus by Different Mechanisms , 2005, Pediatric Research.

[59]  W. Hay,et al.  Diminished β-cell replication contributes to reduced β-cell mass in fetal sheep with intrauterine growth restriction , 2005 .

[60]  A. Ferguson-Smith,et al.  Developmental Dynamics of the Definitive Mouse Placenta Assessed by Stereology1 , 2004, Biology of reproduction.

[61]  William C Hahn,et al.  Lentivirus-delivered stable gene silencing by RNAi in primary cells. , 2003, RNA.

[62]  W. Reik,et al.  Placental-specific IGF-II is a major modulator of placental and fetal growth , 2002, Nature.

[63]  T. Powell,et al.  Glucose transport and system A activity in syncytiotrophoblast microvillous and basal plasma membranes in intrauterine growth restriction. , 2002, Placenta.

[64]  C. Meier,et al.  Activation of system L heterodimeric amino acid exchangers by intracellular substrates , 2002, The EMBO journal.

[65]  M. Kilberg,et al.  Physiological importance of system A-mediated amino acid transport to rat fetal development. , 2002, American journal of physiology. Cell physiology.

[66]  G. Pardi,et al.  Placental transport of leucine, phenylalanine, glycine, and proline in intrauterine growth-restricted pregnancies. , 2001, The Journal of clinical endocrinology and metabolism.

[67]  V. Ganapathy,et al.  Involvement of transporter recruitment as well as gene expression in the substrate-induced adaptive regulation of amino acid transport system A. , 2001, Biochimica et biophysica acta.

[68]  V. Ganapathy,et al.  Cloning and functional expression of ATA1, a subtype of amino acid transporter A, from human placenta. , 2000, Biochemical and biophysical research communications.

[69]  E. Liechty,et al.  Aromatic amino acids are utilized and protein synthesis is stimulated during amino acid infusion in the ovine fetus. , 1999, The Journal of nutrition.

[70]  V. Ganapathy,et al.  Human LAT1, a subunit of system L amino acid transporter: molecular cloning and transport function. , 1999, Biochemical and biophysical research communications.

[71]  C. Sibley,et al.  Association between the Activity of the System A Amino Acid Transporter in the Microvillous Plasma Membrane of the Human Placenta and Severity of Fetal Compromise in Intrauterine Growth Restriction , 1997, Pediatric Research.

[72]  G. Pardi,et al.  Maternal concentrations and fetal-maternal concentration differences of plasma amino acids in normal and intrauterine growth-restricted pregnancies. , 1996, American journal of obstetrics and gynecology.

[73]  C. Sibley,et al.  Amino Acid (System A) Transporter Activity in Microvillous Membrane Vesicles from the Placentas of Appropriate and Small for Gestational Age Babies , 1993, Pediatric Research.

[74]  C. Rodeck,et al.  Effects of Fetal Intravenous Glucose Challenge in Normal and Growth Retarded Fetuses , 1990, Hormone and metabolic research = Hormon- und Stoffwechselforschung = Hormones et metabolisme.

[75]  G. Pardi,et al.  Umbilical amino acid concentrations in normal and growth-retarded fetuses sampled in utero by cordocentesis. , 1990, American journal of obstetrics and gynecology.

[76]  K. Nicolaides,et al.  Plasma amino acids in appropriate- and small-for-gestational-age fetuses. , 1989 .

[77]  G. Meschia,et al.  Rates of protein synthesis and turnover in fetal life. , 1981, The American journal of physiology.

[78]  A. Fowden Effects of adrenaline and amino acids on the release of insulin in the sheep fetus. , 1980, The Journal of endocrinology.

[79]  L. Aerts,et al.  THE ENDOCRINE PANCREAS IN SMALL‐FOR‐DATES INFANTS , 1977, British journal of obstetrics and gynaecology.

[80]  R. Jensh,et al.  Prenatal growth in the albino rat: effects of number, intrauterine position and resorptions. , 1970, The American journal of anatomy.

[81]  L. B. Flexner,et al.  The transfer of radioactive sodium across the placenta of the white rat , 1941 .