TY - JOUR
T1 - A pair of co-opted retroviral envelope syncytin genes is required for formation of the two-layered murine placental syncytiotrophoblast
AU - Dupressoir, Anne
AU - Vernochet, Cécile
AU - Harper, Francis
AU - Guégan, Justine
AU - Dessen, Philippe
AU - Pierron, Gérard
AU - Heidmann, Thierry
PY - 2011/11/15
Y1 - 2011/11/15
N2 - In most mammalian species, a critical step of placenta development is the fusion of trophoblast cells into a multinucleated syncytiotrophoblast layer fulfilling essential fetomaternal exchange functions. Key insights into this process came from the discovery of envelope genes of retroviral origin, the syncytins, independently acquired by the human (syncytin-1 and -2), mouse (syncytin-A and -B), and rabbit (syncytin-Ory1) genomes, with fusogenic properties and placenta-specific expression. We previously showed that mouse syncytin-A is essential for the formation of one of the two syncytiotrophoblast layers and for embryo survival. Here, we have generated syncytin-B KO mice and demonstrate that syncytin-B null placenta displays impaired formation of syncytiotrophoblast layer II (ST-II), with evidence of unfused apposed cells, and enlargement of maternal lacunae disrupting the placenta architecture. Unexpectedly, syncytin-B null embryos are viable, with only limited late-onset growth retardation and reduced neonate number. Microarray analyses identified up-regulation of the connexin 30 gene in mutant placentae, with the protein localized at the fetomaternal interface, suggesting gap junctionmediated compensatory mechanisms. Finally, double-KO mice demonstrate premature death of syncytin-A null embryos if syncytin- B is deleted, indicating cooperation between ST-I and ST-II. These findings establish that both endogenous retrovirus-derived syncytin genes contribute independently to the formation of the two syncytiotrophoblast layers during placenta formation, demonstrating a major role of retroviral gene capture, through convergent evolution, to generate multiple placental structures. Although some are absolutely required for completion of pregnancy, others are still amenable to "epigenetic" compensations, thus illustrating the complexity of the molecular machinery that developed during placental evolution.
AB - In most mammalian species, a critical step of placenta development is the fusion of trophoblast cells into a multinucleated syncytiotrophoblast layer fulfilling essential fetomaternal exchange functions. Key insights into this process came from the discovery of envelope genes of retroviral origin, the syncytins, independently acquired by the human (syncytin-1 and -2), mouse (syncytin-A and -B), and rabbit (syncytin-Ory1) genomes, with fusogenic properties and placenta-specific expression. We previously showed that mouse syncytin-A is essential for the formation of one of the two syncytiotrophoblast layers and for embryo survival. Here, we have generated syncytin-B KO mice and demonstrate that syncytin-B null placenta displays impaired formation of syncytiotrophoblast layer II (ST-II), with evidence of unfused apposed cells, and enlargement of maternal lacunae disrupting the placenta architecture. Unexpectedly, syncytin-B null embryos are viable, with only limited late-onset growth retardation and reduced neonate number. Microarray analyses identified up-regulation of the connexin 30 gene in mutant placentae, with the protein localized at the fetomaternal interface, suggesting gap junctionmediated compensatory mechanisms. Finally, double-KO mice demonstrate premature death of syncytin-A null embryos if syncytin- B is deleted, indicating cooperation between ST-I and ST-II. These findings establish that both endogenous retrovirus-derived syncytin genes contribute independently to the formation of the two syncytiotrophoblast layers during placenta formation, demonstrating a major role of retroviral gene capture, through convergent evolution, to generate multiple placental structures. Although some are absolutely required for completion of pregnancy, others are still amenable to "epigenetic" compensations, thus illustrating the complexity of the molecular machinery that developed during placental evolution.
KW - Cell-cell fusion
KW - Knockout mice
KW - Labyrinth
UR - http://www.scopus.com/inward/record.url?scp=81755187043&partnerID=8YFLogxK
U2 - 10.1073/pnas.1112304108
DO - 10.1073/pnas.1112304108
M3 - Article
C2 - 22032925
AN - SCOPUS:81755187043
SN - 0027-8424
VL - 108
SP - E1164-E1173
JO - Proceedings of the National Academy of Sciences of the United States of America
JF - Proceedings of the National Academy of Sciences of the United States of America
IS - 46
ER -