The Role of the Placenta in DOHaD

doi:10.1017/9781009272254.017

Chapter 16 - The Role of the Placenta in DOHaD

from Section IV - Mechanisms

Published online by Cambridge University Press: 01 December 2022

Rohan M. Lewis and

Amanda N. Sferruzzi-Perri

Edited by

Lucilla Poston ,

Keith M. Godfrey ,

Peter D. Gluckman and

Mark A. Hanson

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Lucilla Poston: Affiliation:
King's College London
Keith M. Godfrey: Affiliation:
University of Southampton
Peter D. Gluckman: Affiliation:
University of Auckland
Mark A. Hanson: Affiliation:
University of Southampton

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Summary

Placental function supports the growth and development of the fetus by providing nutrients, removing fetal waste and protecting the fetus from xenobiotics. The placenta also secretes hormones and other endocrine mediators that adapt maternal physiology to support the pregnancy. Where placental function is inadequate, fetal development may be compromised and result in persistent changes in organ structure and function that have consequences for later health.

Type: Chapter
Information: Developmental Origins of Health and Disease , pp. 166 - 175

DOI: https://doi.org/10.1017/9781009272254.017 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2022

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References

Fleming, T. P., Watkins, A. J., Velazquez, M. A., Mathers, J. C., Prentice, A. M., Stephenson, J., Barker, M., Saffery, R., Yajnik, C. S., Eckert, J. J., Hanson, M. A., Forrester, T., Gluckman, P. D., and Godfrey, K. M. (2018) Origins of lifetime health around the time of conception: causes and consequences. Lancet 391, 1842–1852Google Scholar

Burton, G. J., Fowden, A. L., and Thornburg, K. L. (2016) Placental origins of chronic disease. Physiol Rev 96, 1509–1565CrossRef Google Scholar

Sferruzzi-Perri, A. N., and Camm, E. J. (2016) The programming power of the placenta. Front Physiol 7, 33Google Scholar

Lewis, R. M., Cleal, J. K., and Hanson, M. A. (2012) Review: placenta, evolution and lifelong health. Placenta 33 Suppl, S28–32Google Scholar

Sibley, C. P. (2009) Understanding placental nutrient transfer – why bother? New biomarkers of fetal growth. Journal of Physiology 587, 3431–3440Google Scholar

Stirrat, L. I., Sengers, B. G., Norman, J. E., Homer, N. Z. M., Andrew, R., Lewis, R. M., and Reynolds, R. M. (2018) Transfer and metabolism of cortisol by the isolated perfused human placenta. J Clin Endocrinol Metab 103, 640–648Google Scholar

Sferruzzi-Perri, A. N., Vaughan, O. R., Forhead, A. J., and Fowden, A. L. (2013) Hormonal and nutritional drivers of intrauterine growth. Curr Opin Clin Nutr Metab Care 16, 298–309CrossRef Google Scholar

Bloise, E., Ortiga-Carvalho, T. M., Reis, F. M., Lye, S. J., Gibb, W., and Matthews, S. G. (2016) ATP-binding cassette transporters in reproduction: a new frontier. Hum Reprod Update 22, 164–181Google Scholar

Whitley, G. S., and Cartwright, J. E. (2010) Cellular and molecular regulation of spiral artery remodelling: lessons from the cardiovascular field. Placenta 31, 465–474Google Scholar

Camm, E. J., Botting, K. J., and Sferruzzi-Perri, A. N. (2018) Near to one’s heart: the intimate relationship between the placenta and fetal heart. Front Physiol 9, 629Google Scholar

Lewis, R. M., Cleal, J. K., and Sengers, B. G. (2020) Placental perfusion and mathematical modelling. Placenta 93, 43–48CrossRef Google Scholar

Schumacher, A., Sharkey, D. J., Robertson, S. A., and Zenclussen, A. C. (2018) Immune cells at the fetomaternal interface: how the microenvironment modulates immune cells to foster fetal development. J Immunol 201, 325–334Google Scholar

Napso, T., Yong, H. E., Lopez-Tello, J., and Sferruzzi-Perri, A. N. (2018) The role of placental hormones in mediating maternal adaptations to support pregnancy and lactation. Front Physiol 9, 1091Google Scholar

Sferruzzi-Perri, A. N., Lopez-Tello, J., Napso, T., and Yong, H. E. (2020) Exploring the causes and consequences of maternal metabolic maladaptations during pregnancy. Placenta 98, 43–51Google Scholar

Handwerger, S., and Freemark, M. (2000) The roles of placental growth hormone and placental lactogen in the regulation of human fetal growth and development. J Pediatr Endocrinol Metab 13, 343–356Google Scholar

Turco, M. Y., Gardner, L., Kay, R. G., Hamilton, R. S., Prater, M., Hollinshead, M. S., McWhinnie, A., Esposito, L., Fernando, R., Skelton, H., Reimann, F., Gribble, F. M., Sharkey, A., Marsh, S. G. E., O’Rahilly, S., Hemberger, M., Burton, G. J., and Moffett, A. (2018) Trophoblast organoids as a model for maternal-fetal interactions during human placentation. Nature 564, 263–267CrossRef Google Scholar

Vento-Tormo, R., Efremova, M., Botting, R. A., Turco, M. Y., Vento-Tormo, M., Meyer, K. B., Park, J. E., Stephenson, E., Polanski, K., Goncalves, A., Gardner, L., Holmqvist, S., Henriksson, J., Zou, A., Sharkey, A. M., Millar, B., Innes, B., Wood, L., Wilbrey-Clark, A., Payne, R. P., Ivarsson, M. A., Lisgo, S., Filby, A., Rowitch, D. H., Bulmer, J. N., Wright, G. J., Stubbington, M. J. T., Haniffa, M., Moffett, A., and Teichmann, S. A. (2018) Single-cell reconstruction of the early maternal-fetal interface in humans. Nature 563, 347–353CrossRef Google Scholar

Michelsen, T. M., Henriksen, T., Reinhold, D., Powell, T. L., and Jansson, T. (2019) The human placental proteome secreted into the maternal and fetal circulations in normal pregnancy based on 4-vessel sampling. FASEB J 33, 2944–2956Google Scholar

Sferruzzi-Perri, A. N. (2018) Assessment of placental transport function in studies of disease programming. Methods Mol Biol Chapter 14, 1735, 1239–1250Google Scholar

Roseboom, T., de Rooij, S., and Painter, R. (2006) The Dutch famine and its long-term consequences for adult health. Early Hum Dev 82, 485–491Google Scholar

Roseboom, T. J., Painter, R. C., de Rooij, S. R., van Abeelen, A. F., Veenendaal, M. V., Osmond, C., and Barker, D. J. (2011) Effects of famine on placental size and efficiency. Placenta 32, 395–399Google Scholar

van Abeelen, A. F., de Rooij, S. R., Osmond, C., Painter, R. C., Veenendaal, M. V., Bossuyt, P. M., Elias, S. G., Grobbee, D. E., van der Schouw, Y. T., Barker, D. J., and Roseboom, T. J. (2011) The sex-specific effects of famine on the association between placental size and later hypertension. Placenta 32, 694–698Google Scholar

Glazier, J. D., Hayes, D. J. L., Hussain, S., D’Souza, S. W., Whitcombe, J., Heazell, A. E. P., and Ashton, N. (2018) The effect of Ramadan fasting during pregnancy on perinatal outcomes: a systematic review and meta-analysis. BMC Pregnancy Childbirth 18, 421Google Scholar

Lewis, R. M., Wadsack, C., and Desoye, G. (2018) Placental fatty acid transfer. Curr Opin Clin Nutr Metab Care 21, 78–82Google Scholar

Vaughan, O. R., Rosario, F. J., Powell, T., and Jansson, T. (2017) Regulation of placental amino acid transport and fetal growth. Prog Mol Biol Transl Sci. 2017;145:217–251. doi: 10.1016/bs.pmbts.2016.12.008. Epub 2017 Jan 16.Google Scholar

Cleal, J. K., Day, P. E., Simner, C. L., Barton, S. J., Mahon, P. A., Inskip, H. M., Godfrey, K. M., Hanson, M. A., Cooper, C., Lewis, R. M., Harvey, N. C., and Group, S. W. S. S. (2015) Placental amino acid transport may be regulated by maternal vitamin D and vitamin D-binding protein: results from the Southampton Women’s Survey. Br J Nutr 113, 1903–1910Google Scholar

Fowden, A. L., Camm, E. J., and Sferruzzi-Perri, A. N. (2020) Effects of maternal obesity on placental phenotype. Curr Vasc Pharmacol 19, 113–131Google Scholar

Myatt, L., and Thornburg, K. L. (2018) Effects of prenatal nutrition and the role of the placenta in health and disease. Methods Mol Biol 1735, 19–46Google Scholar

Lewis, R. M., and Desoye, G. (2017) Placental lipid and fatty acid transfer in maternal overnutrition. Ann Nutr Metab 70, 228–231Google Scholar

Rad, H. S., Rohl, J., Stylianou, N., Allenby, M. C., Bazaz, S. R., Warkiani, M. E., Guimaraes, F. S. F., Clifton, V. L., and Kulasinghe, A. (2021) The effects of COVID-19 on the placenta during pregnancy. Front Immunol 12, 743022Google Scholar

Nelson, S. M., Coan, P. M., Burton, G. J., and Lindsay, R. S. (2009) Placental structure in Type 1 Diabetes 58, 2634–2641Google Scholar

Calderon, I. M., Damasceno, D. C., Amorin, R. L., Costa, R. A., Brasil, M. A., and Rudge, M. V. (2007) Morphometric study of placental villi and vessels in women with mild hyperglycemia or gestational or overt diabetes. Diabetes Res Clin Pract 78, 65–71Google Scholar

Castillo-Castrejon, M., and Powell, T. L. (2017) Placental nutrient transport in gestational diabetic pregnancies. Front Endocrinol (Lausanne) 8, 306Google Scholar

Mayhew, T. M., Wijesekara, J., Baker, P. N., and Ong, S. S. (2004) Morphometric evidence that villous development and fetoplacental angiogenesis are compromised by intrauterine growth restriction but not by pre-eclampsia. Placenta 25, 829–833Google Scholar

Hayward, C. E., Greenwood, S. L., Sibley, C. P., Baker, P. N., Challis, J. R., and Jones, R. L. (2012) Effect of maternal age and growth on placental nutrient transport: potential mechanisms for teenagers’ predisposition to small-for-gestational-age birth? Am J Physiol Endocrinol Metab 302, E233–242Google Scholar

Palomba, S., de Wilde, M. A., Falbo, A., Koster, M. P., La Sala, G. B., and Fauser, B. C. (2015) Pregnancy complications in women with polycystic ovary syndrome. Hum Reprod Update 21, 575–592Google Scholar

Maliqueo, M., Lara, H. E., Sanchez, F., Echiburu, B., Crisosto, N., and Sir-Petermann, T. (2013) Placental steroidogenesis in pregnant women with polycystic ovary syndrome. Eur J Obstet Gynecol Reprod Biol 166, 151–155Google Scholar

Clapp, J. F. (2006) Influence of endurance exercise and diet on human placental development and fetal growth. Placenta 27, 527–534Google Scholar

Brett, K. E., Ferraro, Z. M., Holcik, M., and Adamo, K. B. (2015) Prenatal physical activity and diet composition affect the expression of nutrient transporters and mTOR signaling molecules in the human placenta. Placenta 36, 204–212Google Scholar

Day, P. E., Ntani, G., Crozier, S. R., Mahon, P. A., Inskip, H. M., Cooper, C., Harvey, N. C., Godfrey, K. M., Hanson, M. A., Lewis, R. M., and Cleal, J. K. (2015) Maternal Factors are associated with the expression of placental genes involved in amino acid metabolism and transport. PloS one 10, e0143653Google Scholar

Mayhew, T. M. (2003) Changes in fetal capillaries during preplacental hypoxia: growth, shape remodelling and villous capillarization in placentae from high-altitude pregnancies. Placenta 24, 191–198Google Scholar

Zamudio, S., Baumann, M. U., and Illsley, N. P. (2006) Effects of chronic hypoxia in vivo on the expression of human placental glucose transporters. Placenta 27, 49–55CrossRef Google Scholar

Jauniaux, E., and Burton, G. J. (2007) Morphological and biological effects of maternal exposure to tobacco smoke on the feto-placental unit. Early Hum Dev 83, 699–706Google Scholar

Hayward, C. E., Greenwood, S. L., Sibley, C. P., Baker, P. N., and Jones, R. L. (2011) Effect of young maternal age and skeletal growth on placental growth and development. Placenta 32, 990–998CrossRef Google Scholar

Lean, S. C., Heazell, A. E. P., Dilworth, M. R., Mills, T. A., and Jones, R. L. (2017) Placental dysfunction underlies increased risk of fetal growth restriction and stillbirth in advanced maternal age women. Sci Rep 7, 9677Google Scholar

Perazzolo, S., Lewis, R. M., and Sengers, B. G. (2017) Modelling the effect of intervillous flow on solute transfer based on 3D imaging of the human placental microstructure. Placenta 60, 21–27CrossRef Google Scholar

Sferruzzi-Perri, A. N., Owens, J. A., Pringle, K. G., and Roberts, C. T. (2010) The neglected role of insulin-like growth factors in the maternal circulation regulating fetal growth. J Physiol 589, 7–20CrossRef Google Scholar

Fowden, A. L., Forhead, A. J., Sferruzzi-Perri, A. N., Burton, G. J., and Vaughan, O. R. (2015) Endocrine regulation of placental phenotype. Placenta 36, S50–59Google Scholar

Paulsen, M. E., Rosario, F. J., Wesolowski, S. R., Powell, T. L., and Jansson, T. (2019) Normalizing adiponectin levels in obese pregnant mice prevents adverse metabolic outcomes in offspring. FASEB J 33, 2899–2909Google Scholar

Vaughan, O. R., Sferruzzi-Perri, A. N., and Fowden, A. L. (2012) Maternal corticosterone regulates nutrient allocation to fetal growth in mice. J Physiol 590, 5529–5540Google Scholar

Sferruzzi-Perri, A. N., Vaughan, O. R., Coan, P. M., Suciu, M. C., Darbyshire, R., Constancia, M., Burton, G. J., and Fowden, A. L. (2011) Placental-specific Igf2 deficiency alters developmental adaptations to undernutrition in mice. Endocrinology 152, 3202–3212Google Scholar

Yong, H. E., Lopez-Tello, J., Sandovici, I., Constancia, M., and Sferruzzi-Perri, A. N. (2017) Mice with placental junctional zone Igf2 deletion fail to metabolically adapt to pregnancy. Placenta 57, 247–248Google Scholar

Aykroyd, B. R. L., Tunster, S. J., and Sferruzzi-Perri, A. N. (2020) Igf2 deletion alters mouse placenta endocrine capacity in a sexually-dimorphic manner. J Endocrinol 246, 93–108Google Scholar

Hemberger, M., Hanna, C. W., and Dean, W. (2020) Mechanisms of early placental development in mouse and humans. Nat Rev Genet 21, 27–43Google Scholar

Vlahos, A., Mansell, T., Saffery, R., and Novakovic, B. (2019) Human placental methylome in the interplay of adverse placental health, environmental exposure, and pregnancy outcome. PLoS Genet 15, e1008236Google Scholar

Wen, X., Triche, E. W., Hogan, J. W., Shenassa, E. D., and Buka, S. L. (2011) Association between placental morphology and childhood systolic blood pressure. Hypertension 57, 48–55Google Scholar

Hemachandra, A. H., Klebanoff, M. A., Duggan, A. K., Hardy, J. B., and Furth, S. L. (2006) The association between intrauterine growth restriction in the full-term infant and high blood pressure at age 7 years: results from the collaborative perinatal project. Int J Epidemiol 35, 871–877Google Scholar

Risnes, K. R., Romundstad, P. R., Nilsen, T. I., Eskild, A., and Vatten, L. J. (2009) Placental weight relative to birth weight and long-term cardiovascular mortality: findings from a cohort of 31,307 men and women. Am J Epidemiol 170, 622–631Google Scholar

Barker, D. J., Larsen, G., Osmond, C., Thornburg, K. L., Kajantie, E., and Eriksson, J. G. (2012) The placental origins of sudden cardiac death. Int J Epidemiol 41, 1394–1399Google Scholar

Poston, L. (2010) Developmental programming and diabetes – The human experience and insight from animal models. Best Pract Res Clin Endocrinol Metab 24, 541–552Google Scholar

Reynolds, L. P., Borowicz, P. P., Caton, J. S., Vonnahme, K. A., Luther, J. S., Hammer, C. J., Maddock Carlin, K. R., Grazul-Bilska, A. T., and Redmer, D. A. (2010) Developmental programming: the concept, large animal models, and the key role of uteroplacental vascular development. J Anim Sci 88, E61–72Google Scholar

Lopez-Tello, J., Arias-Alvarez, M., Gonzalez-Bulnes, A., and Sferuzzi-Perri, A. N. (2019) Models of Intrauterine growth restriction and fetal programming in rabbits. Mol Reprod Dev 86, 1781–1809Google Scholar

Carter, A. M. (2012) Evolution of placental function in mammals: the molecular basis of gas and nutrient transfer, hormone secretion, and immune responses. Physiol Rev 92, 1543–1576CrossRef Google Scholar

Mikaelsson, M. A., Constancia, M., Dent, C. L., Wilkinson, L. S., and Humby, T. (2013) Placental programming of anxiety in adulthood revealed by Igf2-null models. Nat Commun 4, 2311Google Scholar

Harrison, D. J., Creeth, H. D. J., Tyson, H. R., Boque-Sastre, R., Hunter, S., Dwyer, D. M., Isles, A. R., and John, R. M. (2021) Placental endocrine insufficiency programs anxiety, deficits in cognition and atypical social behaviour in offspring. Hum Mol Genet Sep 15; 30(19):1863-1880. doi: 10.1093/hmg/ddab154.Google Scholar

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Chapter 16 - The Role of the Placenta in DOHaD

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