Cells, Organisms and Molecular Genetics

Our research team

The Cells, Organisms and Molecular Genetics team here at the University of Nottingham’s School of Life Sciences is a diverse, collaborative group of researchers. We’re academics, postdoctoral research fellows, research technicians and postgraduate students, all working together to break new ground and make a real impact on the world around us.

Image of Sara Goodacre

Sara Goodacre

Professor of Evolutionary Biology and Genetics, Faculty of Medicine & Health Sciences

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Biography

Professor of Evolutionary Biology and Genetics, University of Nottingham

2006-2011 RCUK Fellow, University of Nottingham, 2002-2005 Research Fellow, University of East Anglia, 2000-2001 Research Fellow, University of Oxford, 1999 Ph.D., University of Nottingham, 1995 B.A. (1998 M. A.) Natural Sciences, Gonville and Caius College, University of Cambridge.

Research Summary

The 'SpiderLab' at Nottingham studies the diversity of spiders and of their silks, in order to understand what factors drive and explain the current distribution of diversity seen today. Insights… read more

Selected Publications

Current Research

The 'SpiderLab' at Nottingham studies the diversity of spiders and of their silks, in order to understand what factors drive and explain the current distribution of diversity seen today. Insights from these studies allow us to understand how we might best maximise the pest-controlling potential of spiders in a farmers field, and how we might copy particular genetic templates for spider silk to make our own, synthetic versions that give materials with new possibilities for use in medicine or engineering.

Studies of dispersal show that at least in some cases, interactions between the spider host and internal microbial species influence tendencies of spiders to disperse long distances using silk as a sail. These aeronautic behaviours, coupled with acrobatic tendencies when landing on water, may help to explain how genetic variation is shared amongst populations across large spatial scales. Conversely, reproductive incompatibitilies caused by these same microorganisms may explain why some host genetic variants remain more localised than the apparent potential for long-distance dispersal might suggest.

Molecular genetic studies of spider silks across the entire spider family have helped us to understand how these complicated proteins have evolved to fulfill such a diversity of functions, from silken sails that allow flying using the power of the wind, to intricate, composite silken structures in which to hide above ground or beneath the surface of a pond. We have used these insights to create our own, synthetic versions of silks through collaborating with biological chemists. Insights from the field of chemistry have enabled us to make these versions functionalised, through chemically adding molecules that confer useful properties, such as antibiotics, cell-growth factors or dyes visible under particular wavelengths of light.

The SpiderLab has championed the use of spiders in public engagement, and in the development of genetic and genomic resources to aid in the study of spiders in need of direct conservation action.

Cells, Organisms and Molecular Genetics

School of Life Sciences
University of Nottingham
Medical School
Queen's Medical Centre
Nottingham NG7 2UH