Human Placental Development and the Uterine Microenvironment

The central question of this project is: how does the human placenta develop and how is this process influenced by the maternal uterine environment? The placenta is a temporary organ that forms during pregnancy to support the developing baby. It provides oxygen and nutrients, removes waste, and plays a key role in protecting the fetus. In humans placentation is quite unique, as the placenta embeds itself deeply within the lining of the uterus (decidua).

Despite major advances in medical research, pregnancy complications remain common and can have serious consequences for both mother and baby. Conditions such as miscarriage, pre-eclampsia, fetal growth restriction and stillbirth are linked to problems in placental development during the earliest stages of pregnancy. A key step in early pregnancy is the controlled invasion of specialised placental cells, known as extravillous trophoblast cells, into the uterine tissue. These cells remodel maternal blood vessels to ensure an adequate blood supply to the fetus. Both insufficient and excessive invasion can also be harmful, meaning that successful pregnancy depends on a finely balanced interaction between these fetal and maternal tissues.

However, these critical events occur at a time that is extremely difficult to study in humans for both ethical and practical reasons. As a result, we have a limited understanding of how two tissues interact and establish a functional connection. A major challenge has been the lack of suitable in vitro models to study these processes. To overcome this, we developed three-dimensional culture systems called organoids, derived from human placental and uterine tissues. These models closely mimic key features of the original tissues and provide a unique opportunity to study early pregnancy in the laboratory. Using these systems, we aimed to:
(i) identify the molecular mechanisms that control the formation of invasive placental cells;
(ii) determine how signals from the maternal uterine glands influence placental development; and
(iii) reconstruct the interaction between maternal and fetal tissues by developing bioengineered tissue-like models

By enabling the study of early human placental development and maternal-fetal interactions in vitro, this project provides new insights into how these tissues form and function. These advances improve our understanding of the origins of pregnancy disorders and lay the foundation for improved diagnostics and therapies.

Over the course of this project, we made several major findings that advance our understanding of human placental development and its interaction with the maternal uterus.

Firstly, we generated one of the first detailed maps of the cells that make up the human uterine lining before pregnancy and the maternal-fetal interface in early pregnancy. In parallel, we systematically compared placental and uterine organoid models to their tissues of origin to assess how accurately they reflect their biology. To achieve this, we used advanced technologies that measure gene activity in individual cells while preserving their spatial organisation within tissues. This allowed us to identify the different cell types present, determine where they are located, and understand how they change as they develop into specialised cell types. In particular, we focused on invasive placental cells (extravillous trophoblast), which enter the uterus to establish the blood supply required for fetal development, a process that had not previously been characterised at this level of detail in humans. Importantly, we found that these organoid models faithfully reproduce key features of the original human tissues. Together, these advances provide a unique resources to study early human pregnancy and establish a foundation for investigating interactions between maternal and fetal tissues.

Secondly, we not only defined the cell types present at the maternal-fetal interface but also began to understand how they communicate with each other. We identified key signals exchanged between maternal and placental cells that regulate placental development and invasion. We then tested these signals experimentally, focusing on interactions between placental cells and maternal cell types, including glandular cells and uterine natural killer cells. Using an image-based screening approach, we found that factors produced by maternal immune cells, particularly uterine natural killer cells, promote the development and invasive behaviour of placental cells. This demonstrates an active role of the mother in regulating placental development.

Thirdly, we developed bioengineered models that combine placental and uterine organoids to recreate key aspects of the maternal-fetal interface. These systems allow us for the first time, to experimentally investigate how maternal and fetal tissues interact in a controlled human setting and to identify the signals exchanged between them.

Overall, this work provides both a reference map of human uterine and placental cell types and experimental systems to study their interactions. By moving from describing tissues to experimentally testing how they communicate, the project represents a significant advance in understanding early human pregnancy and the origins of pregnancy disorders.

Over the course of the project, we established resources and new human experimental systems that enable the study of early pregnancy processes that were previously inaccessible. These advances allow for the first time, the investigation of how maternal and fetal tissues interact during the earliest stages of human placental development.

On the fetal side, we identified key genes in specialised placental cells, known as extravillous trophoblast cells, which are responsible for invading maternal tissue during early pregnancy. This has provided new insights into how these cells develop and how placental invasion is regulated.

On the maternal side, we characterised glandular cells of the endometrium and uterine natural killer cells, as well as the factors they secrete, revealing how the uterine environment actively shapes placental development. By combining this with an imaging-based screening approach, we were able to systematically assess multiple maternal signals and disentangle their individual contributions.

A major advance of this project is the integration of these two compartments. Using bioengineered systems based on organoid models, we established platforms that recreate key aspects of the maternal-fetal interface and enable direct investigation of how maternal and fetal cells communicate. This represents a significant step beyond the current state of the art as such interactions in early pregnancy could not previously be studied.

Importantly, this work shifts the field from studying maternal and fetal tissues in isolation to analysing their interactions in a systematic manner. This provides a framework to dissect the dynamic “dialogue” between tissues that underpins early placental development. Thus our achievements opens new avenues for understanding the mechanisms that regulate placental invasion and early pregnancy success. In the longer term, these advances provide a foundation for research into pregnancy disorders and the development of improved diagnostic and therapeutic strategies.