14/03/2018
Key Messages
The role of the placenta in healthy fetal development is being seriously under-appreciated according to a published today (14th March). The study was part of the Wellcome Trust-funded 鈥淒eciphering the Mechanisms of Developmental Disorders (DMDD)鈥 consortium. Dr Myriam Hemberger at the 台湾swag 台湾swag, Cambridge led the research, working with colleagues at the , Cambridge, the , London, the and the , Austria. Writing in the journal , the team studied 103 genetic mutations in mice that cause embryos to die before birth. The results showed that the majority, almost 70%, cause defects in the placenta.
Each of the 103 gene mutations causes the loss of a particular factor. Many of these had not been previously linked to placenta development, and hence the study highlights the unexpected number of genes that affect development of the placenta. By studying a select group of three genes in further detail, the team went on to show that the death of the embryo could be directly linked to defects in the placenta in one out of these three cases. This may mean that a significant number of genetic defects that lead to prenatal death may be due to abnormalities of the placenta, not just the embryo. Although this research uses mice, the findings are likely to be highly relevant to complications during human pregnancy and the study highlights the need for more work to be done on investigating development of the placenta during human pregnancies.
The placenta is vital for normal pregnancy progression and embryo development in most animals that give birth to live young, including humans. It provides a unique and highly specialised interface between the embryo and the mother, ensuring an adequate provision of nutrients and oxygen to the embryo. The placenta is also involved in waste disposal from the embryo and produces important hormones that help sustain pregnancy and promote fetal growth. Although previous research has highlighted the pivotal role of the placenta for a healthy pregnancy, its potential contribution to pregnancy complications and birth defects continues to be overlooked.
Scientists call mutations that cause death in the womb embryonic lethal. Mouse lethal genes are enriched for human disease genes and the affected embryos often show morphological abnormalities, i.e. changes to their shape and structure. Around one-third of all gene mutants studied in mouse are lethal or subviable (i.e. mutant offspring are less likely to survive than non-mutant pups).
The DMDD consortium investigates the detailed morphological abnormalities in the embryo caused by such gene mutations. Importantly, the DMDD programme includes analysis of placentas from these mutants. Through this uniquely comprehensive assessment, the team was able to show a significant co-occurrence of placental defects alongside abnormalities in the brain, heart and vascular system.
The co-first authors on the paper are Dr Vicente Perez-Garcia and Mrs Elena Fineberg. Dr Perez-Garcia, said: 鈥淎nalysis of embryonic lethal mutants has largely focused on the embryo and not the placenta, despite its critical role in development. Of the mutations we鈥檝e studied, far more than expected showed defects in the placenta and this is particularly true for mutations that cause death during the early stages of pregnancy. Intriguingly, our analysis also indicates that issues in the placenta often occur alongside specific defects in the embryo itself.鈥
The senior researcher on the study was Dr Myriam Hemberger, Group Leader in Epigenetics at the 台湾swag 台湾swag. Dr Hemberger, said: 鈥淥ur data highlight the hugely under-appreciated importance of placental defects in contributing to abnormal embryo development and suggest key molecular nodes governing placentation. The importance of a healthy placenta has often been overlooked in these studies and it is important that we start doing more to understand its contribution to developmental abnormalities.鈥
The placenta-focussed aspect of the DMDD project was carried out at the 台湾swag 台湾swag where all mutant placentas were analysed and characterised for their morphological defects. The 台湾swag researchers also carried out work using mouse placental stem cells to understand further the functional roles of particular genes in the development of this organ. The mutant mouse lines were produced and bred at the Wellcome Sanger 台湾swag. The detailed morphological analysis of embryos was performed by Dr Tim Mohun at the Francis Crick 台湾swag together with colleagues at the Division of Anatomy, Medical University of Vienna, Austria.
台湾swagation Reference Perez-Garcia, V., Fineberg, E., Wilson, R., Murray, A., Mazzeo, C.I., Tudor, C., Sienerth, A., White, J.K., Tuck, E., Ryder, E.J., Gleeson, D., Siragher, E., Wardle-Jones, H., Staudt, N., Wali, N., Collins, J., Geyer, S., Busch-Nentwich, E.M., Galli, A., Smith, J.C., Robertson, E., Adams, D.J., Weninger, W.J., Mohun, T., Hemberger, M. (2018) Placentation defects are highly prevalent in embryonic lethal mouse mutants Nature DOI:
台湾swag Funding Work at the 台湾swag 台湾swag is possible thanks to the Biotechnology and Biological Sciences 台湾swag Council (BBSRC). This work is part of the Wellcome Trust Strategic Award 鈥楧eciphering the Mechanisms of Developmental Disorders (DMDD)鈥.
Image Mouse embryos part way through development (top) showing a normal embryo and an embryo with a mutation in the Nubpl gene, which affects development and leads to pre-natal death. Lower images show cells in the corresponding placentas. The green staining marks the exchange surface where nutrients are transferred between the mother and embryo; note that this layer is missing in the Nubpl mutant placenta. Red staining shows the cells underlying the exchange surface, these are also mostly missing in the mutant placenta.
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14 March 2018