We study the earliest steps of human development from the zygote to an adult functional cell to learn fundamental principles about development and cell differentiation.
The Eglilab is located in New York City, United States.
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Developmental failure of the early embryo
The beginning of life is important because it will impact everything that occurs later. Unfortunately, we still know nearly nothing about early human embryonic development and essentially no mechanistic studies have been have been performed. This is also why our ability to help the health of the early embryo is nearly inexistent. Abnormal development and failure to develop is very common in our species, and human reproduction is associated with high risks of genetic and developmental abnormalities. We know more about the early development of mice or worms that we know about ourselves. This is a major gap of knowledge and of clinical capabilities and an area we do want to help address.
Our question is what are the mechanisms that result in abnormal and failed human development, and how can we prevent such adverse events. The promise of these studies is to improve the efficiency of fertility treatments, to reduce the burden of disease-causing genetic change, and increase the chances of parents to have a healthy child.
Understanding metabolic disease using pluripotent stem cells
An important question of cell biology are the limitations in cell proliferation of different cell types. These limitations determine size and proportions of adult organs, and the ability to regenerate. Beta cells and the cells of the pancreas have a low ability to regenerate, while stem cells have unlimited regenerative potential. What determines these differences, and how can they be exploited for therapeutic use? An important goal of these studies are to develop cell therapies for diabetes. We are now able to generate stem cells from a patient with diabetes, correct a gene, and show that these cells produce and secrete insulin when needed. This should allow the treatment of diabetes with the patient's own cells.
Genome stability during cell type transitions
We are using somatic cell reprogramming to address a fundamental question of cellular biology. What keeps cells within a specific differentiated state? Our studies identify an important role of genome instability and the cell cycle as the primary obstacle to induced cell type transitions. The origin and type of damage, as well as the repair pathways required to fix the damage are not entirely known. We are studying reprogramming mechanisms in two experimental systems, somatic cell nuclear transfer and induced pluripotency.
Cell Line Repository
We have an extensive list of various diabetes and control cell lines available in our cell line repository. Please see the Cell Line Repository Tab if you are interested in working with any of our cell lines.
If you have questions about our research, or would like to learn more, please consult the cell line repository page.
Our most recent published work:
Chromosomal consequences of a DSB in human embryos published in Cell.
Daniela Georgieva publishes a new method to sequence replicated DNA using pore sequencing. Read the article in NAR.
Read the preprint by Lina Sui on bioRXiv, showing how reducing replication fork speed promotes endocrine differentiation from pluripotent stem cells and controls growth potential.
Bryan Gonzalez publishes a Letter in Cell Stem Cell on the safety of Universal Stem Cells.
Ido Sagi, Michael Zuccaro and Joao de Pinho, in a collaboration with the Benvenisty laboratory publish on human pluripotent stem cells containing only a paternal genome. Cell Stem Cell 2019. This study helps understand reproductive tumors and developmental disorders such as Prader-Willi syndrome.
PhD student and China Scholarship council scholar Shuangyu Ma publishes proof of principle on gene and cell therapy for diabetes. Read more in Stem Cell Reports
In this manuscript postdoctoral fellow Lina Sui shows that stem cells matched to a patient with type 1 diabetes, derived by somatic cell nuclear transfer, can be differentiated with high efficiency to beta cells, and can protect mice from diabetes. Read more in Diabetes.
Celebrating 20 years of human ES cells:
read more in Nature