John M Squire

John M Squire
Born John Michael Squire
27 June 1945
Nationality United Kingdom
Alma mater King's College London
Occupation Professor of Structural Biophysics in the University of London
Visiting Professor of Biomedical Sciences at Imperial College London
Research fellow at University of Bristol

John Michael Squire is Professor of Structural Biophysics in the University of London, a Visiting Professor at Imperial College London [1] and a Research Fellow at the University of Bristol [2] where he researches Muscle Contraction and Blood Vessel Glycocalyx Structure. He is a Fellow of both the Institute of Physics and the Society of Biology. He is an Emeritus Member of the US Biophysical Society and an Honorary Member of the British Biophysical Society.

Education

Squire went to school at Fettes College, Edinburgh, and obtained a B.Sc (Physics, 1966), AKC and PhD (Biophysics, 1969) from King’s College, University of London, UK, the latter under the supervision of Dr Arthur Elliott.

Career

Squire started his career as a Senior Lecturer at the Biophysics Institute, Aarhus University, Denmark in 1969 followed by a brief period in the Zoology Department at Oxford University. In 1972 he moved to Imperial College of Science, Technology and Medicine in London, UK, to head the Biopolymer Group. He remained at Imperial College until his official retirement in 2006, when he was Head of the Biological Structure and Function Section of what was then the Biomedical Sciences Division at Imperial College. He was made Professor of Structural Biophysics in the University of London in 1995. At present he works as Honorary Research Fellow in the Department of Physiology & Pharmacology at Bristol University, UK, and as a Visiting Professor at Imperial College London, UK.

Research

The main focus of his research is on the structural basis of muscle contraction. His early contributions were the proposal of the steric blocking mechanism for the regulation of muscle contraction,[3] the discovery of face (side) polarity in the myosin filaments of vertebrate smooth muscle,[4] and the proposal of a general packing scheme of myosin molecules within the myosin filaments of all muscles.[5][6] He is an expert on the X-ray diffraction analysis of static and contracting muscle,[7] and recently has been involved in the structure analysis of isolated myosin and actin filaments by electron microscopy and single particle analysis.[8] He founded and chaired both the Collaborative Computational Project Number 13 (CCP13) for the analysis of fibre X-ray diffraction data [9] and the Imperial Muscle Initiative (IMI).[10] With Professor David Parry (biophysicist) he initiated and organized the first five Workshops on Coiled-coils, Collagen and Co-proteins held every four years in Alpbach, Austria. In 2002 a special issue of the Journal of Structural Biology based on one of these Alpbach Workshops and co-edited by Squire won the Best Professional/ Scholarly Publishing Journal: Medicine Award.[11] Squire has published well over 100 original papers, together with many reviews and in 1981 a 700-page monograph on The Structural Basis of Muscular Contraction.[12] He has also written or edited several other books on muscle and on fibrous proteins. At present he actively works on the unresolved problem of how myosin and actin molecules interact to bring about muscle contraction,[13] as well as the structure and function of the blood vessel glycocalyx.[14]

References

  1. http://www.med.ic.ac.uk/divisions/6a/imi/squire/books.html
  2. http://www.bris.ac.uk/phys-pharm/people/john-m-squire/research.html
  3. Parry DA, Squire JM. Structural role of tropomyosin in muscle regulation: analysis of the X-ray diffraction patterns from relaxed and contracting muscles. J Mol Biol. 1973 Mar 25;75(1):33-55.
  4. Small JV, Squire JM. Structural basis of contraction in vertebrate smooth muscle. J Mol Biol. 1972 Jun 14; 67(1):117-149.
  5. Squire JM. General model for the structure of all myosin-containing filaments. Nature. 1971 Oct 15;233(5320):457-462.
  6. Squire JM. General model of myosin filament structure. III. Molecular packing arrangements in myosin filaments. J Mol Biol. 1973 Jun 25;77(2):291-323.
  7. Harford JJ, Squire JM. Time-resolved diffraction studies of muscle using synchrotron radiation. Rep. Prog. Phys. 60, 1723-1787.
  8. Al-Khayat HA, Kensler RW, Squire JM, Marston SB, Morris EP. Atomic model of the human cardiac muscle myosin filament. Proc Natl Acad Sci U S A. 2013 Jan 2;110(1):318-323.
  9. http://www.diamond.ac.uk/Beamlines/Soft-Condensed-Matter/small-angle/SAXS-Software/CCP13.html
  10. http://www3.imperial.ac.uk/muscleinitiative
  11. Parry DAD, Squire JM (Eds) J Struct Biol. 2002 Jan-Feb;137(1-2):
  12. Squire JM (1981) The Structural Basis of Muscular Contraction. Plenum Press, New York.
  13. Knupp C, Offer G, Ranatunga KW, Squire JM. Probing muscle myosin motor action: X-ray (m3 and m6) interference measurements report motor domain not lever arm movement. J Mol Biol. 2009 Jul 10;390(2):168-181.
  14. Squire JM, Chew M, Nneji G, Neal C, Barry J, Michel C. Quasi-periodic substructure in the microvessel endothelial glycocalyx: a possible explanation for molecular filtering? J Struct Biol. 2001 Dec;136(3):239-255.
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