Margaret Robinson

Robinson eventually started a postdoctoral research with Barbara Pearse. Her interest was in clathrin-coated vesicles that binds to cargo. She eventually succeeded in purifying components of the coat that were not clathrin and are now known as adaptor proteins. These proteins sit between clathrin, which forms the vesicle’s outer shell and also the vesicle membrane. Continuing, Margaret discovered that there were two different populations of clathrin-coated vesicles, one that uses AP-2 at the plasma membrane and one that uses AP-1 and was associated with intracellular membranes. AP-1 and AP-2 are both heterotetramers with related subunits. They both have two large subunits and the other subunit is closely related in AP-1 and AP-2.

Robinson’s work explains how coated vesicles sort cargo but also provides tools that can be used by others to address their own favorite problems. For instance, her newly developed method called knocksideways. Knocksideways gets rid of proteins rapidly. Her technique has found its way into other labs who are also interested in how particular proteins contribute to different stages of cell division.

As of 2016 Robinson has a lab at Cambridge Institute for Medical Research. She specifically works with coated vesicles. The best-characterized coated vesicles are the clathrin-coated vesicles (CCVs). The coats on CCVs are primarily of clathrin, adaptor protein (AP) complexes, and alternative adaptors. Her working hypothesis is that for each trafficking pathway, there are a number of different adaptors, each of which is recruited independently onto the appropriate membrane. Once on the membrane, the various adaptors would work together to package different types of cargo into the newly forming vesicle. Robinson and her researchers use several approaches to look for novel adaptors and other components of the trafficking machinery, including proteomic analyses of sub cellular fractions, genome-wide siRNA library screening, insertional mutagenesis, and a new method they developed for rapidly inactivating proteins, called ‘knock sideways’. Her current projects include establishing the functions of AP-1 and other adaptors in differentiated cells; matching up machinery and cargo proteins; investigating how clathrin and adaptors are hijacked by the HIV-1-encoded protein Nef; determine why mutations in the non-clathrin adaptors AP-4 and AP-5 cause hereditary spastic paraplegia; and exploring the evolution of adaptors. Her laboratory uses many techniques including immunolocalisation at the light and electron microscope levels, sub cellular fractionation, protein purification, proteomics, flow cytometry, live cell imaging, and X-ray crystallography.

Robinson received her Bachelor of Arts degree in Biology from Smith College in Massachusetts. She completed her PhD at Harvard University supervised by David Albertini and also Barbara Pearse. In 2003 she was appointed Professor of Molecular Cell Biology at the Cambridge Institute for Medical Research and is conducting research on coated vesicle proteins.

Robinson has received many honors working as a cellular biologist. She was awarded a Wellcome Trust Principal Research Fellowship in 1999 and in 2003 she was appointed Professor of Molecular Cell Biology. She was elected a Fellow of the Academy of Medical Sciences and member of the European Molecular Biology Organization. She was elected a Fellow of the Royal Society (FRS) in 2012. The Wellcome Trust also has funded her research for over 25 years.

Margaret Scott Robinson (born 1951) FRS FMedSci is a British molecular cell biologist, a professor and researcher in the Cambridge Institute for Medical Research, at the University of Cambridge.