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Professor Bertie Göttgens

107-Gottgens-2017Professor Bertie Göttgens

Cellular decision making in normal and leukaemic blood stem cells

Email: bg200@cam.ac.uk

Laboratory: Cambridge Stem Cell Institute, Jeffrey Cheah Biomedical Centre

Departmental Affiliation: Haematology

 

Biography

Bertie Göttgens graduated from Tübingen University in 1992 with a degree in biochemistry.  He received his DPhil in biological sciences from the University of Oxford in 1994 and then proceeded to a post-doc position in the Department of Haematology, University of Cambridge, between 1994-2001.  

Between 2002-2007 he was a Leukaemia Research Fund Lecturer in the Department of Haematology, Cambridge. He was then a University Lecturer, and subsequently a Reader in Haematology, between 2007-2011. 

Since October 2011, Bertie has been Professor of Molecular Haematology, University of Cambridge. 

 

Funding

MRC, Wellcome, Blood Cancer UK, Cancer Research UK, NIH, AZ, Aging Biology Foundation

 

 

Gottgens research 2018

Reconstruction of the haematopoietic differentiation landscape from 45,000 single cell transcriptomes generated from mouse bone marrow (lineage negative / Sca1 positive / Kit positive and lineage negative / Kit positive fractions). Each circle represents a single cell, with the circle colours reporting the results of unsupervised Louvain clustering. The labels indicate the stem/progenitor territory as well as entry points for differentiation trajectories into seven distinct blood lineages.

  

Research

The Göttgens group uses a combination of experimental and computational approaches to study how transcription factor networks control the function of blood stem cells and how mutations that perturb such networks cause leukaemia. This integrated approach has resulted in the discovery of new combinatorial interactions between key blood stem cell regulators, as well as experimentally validated computational models for blood stem cells. Current research focuses on (i) single cell genomics of early blood development, (ii) modelling the transcriptional landscape of blood stem and progenitor cell differentiation, (iii) transcriptional consequences of leukaemogenic mutations in leukaemia stem/progenitor cells, and (iv) molecular characterisation of human blood stem/progenitor cell populations used in cell and gene therapy protocols.

 

 Gottgens Lab 2020

Group Members

Melania Barile, Fernando Calero Nieto, Caroline Guibentif, Rebecca Hannah, Ivan Imaz-Rosshandler, Alison Kennedy, Sarah Kinston, Iwo Kucinski, Mariana Quiroga Londono, Kat Sturgess, Mai-Linh Ton, Sam Watcham, Xianon Wang, Nicola Wilson

 

Plain English

Blood stem cells ensure the constant supply of new blood cells throughout a person’s lifetime. The normal function of blood stem cells critically depends on the fine tuning of which genes should be active at any given time. Moreover, a large number of leukaemias arise, when this fine balance of gene activities is disturbed. Through our research, we want to answer the following questions: 

• What are the mechanisms that regulate gene activities to ensure normal blood stem cell function? 

• Can we identify new strategies to treat leukaemia by reversing the disturbed balance of gene activities? 

To answer these questions, we use a combination of experimental and computational approaches. This has allowed us to discover how individual regulatory genes are connected to form complex networks and how perturbation of these complex networks can cause leukaemia.

 

Key Publications