Professor Kathleen Shennan

Professor Kathleen Shennan
BSc Hons Pharmacology (Edinburgh, 1979) PhD (Birmingham, 1985)

Dean of QW/QA
Personal Chair

Professor Kathleen Shennan
Professor Kathleen Shennan

Contact Details

work +44 (0)1224 272028
The University of Aberdeen Room 014 University Office, Regent Walk, Old Aberdeen


I graduated with an Honours degree in Pharmacology from the University of Edinburgh in 1979 and moved to Birmingham to work in the Department of Medicine with Professors Michael Sheppard and Steve Franks. My research focused on the effects of neurotensin on the hypothalamo-pituitary-thyroid axis and I was awarded a PhD for this work in 1985. Post-doctoral research work with Professor Kevin Docherty, also in Birmingham, maintained my interest in endocrinology, though I became more interested in the biosynthesis of polypeptide hormones, particularly insulin, and their mechanism of targeting into secretory granules. I was appointed to a Lectureship in Aberdeen University in 1994 and promoted to Senior Lecturer in 2003.

Memberships and Affiliations


Director of Studies, Admissions (Science) - 0.75FTE - responsible for the recruitment of students into all of the University of Aberdeen's undergraduate BSc programmes.  

Convenor of the Students' Progress Committee, Science

Convenor of the Quality Assurance Committee

Member of the Senate Business Committee

Member of the University Committee for Teaching & Learning

Chair of the 'Developing and Supporting the Curriculum' Enhancement theme Institutional team

Ex officio member of Senate

Member of the Univeristy of Aberdeen Career Mentoring Programme Advisory Group


Member of QAA (Scotland) 'Developing & Supporting the Curriculum' Enhancement Theme Steering Group

Member of the North East Scotland College Joint Liaison Group

Member of the Dundee and Angus College Joint Liaison Group


Research Overview

Biosynthesis of polypeptide hormones

As a post-doc in Professor Docherty's lab I used a novel in vitro translation system derived from Xenopus laevii eggs to characterise the activity and biosynthesis of the newly identified prohormone convertases PC2 and PC2. These long sought after enzymes are responsible for the proteolytic cleavage of prohormones to their active form and my work was the first to characterise their enzymatic activity. Following this my interest turned to how these enzymes could be targeted into secretory granules along with the prohormones they act on.

Targeting of proteins within neuroendocrine cells

Neuroendocrine cells, such as pancreatic ß-cells, have two separate pathways for proteins to exit the cell; the constitutive secretory pathway (which is common to all cell types and allows for the continuous release of proteins to the cell surface) and the regulated secretory pathway (which is specific to neuroendocrine cells and allows for the storage of large amounts of proteins for secretion in response to a specific stimulus). My group were interested in the mechanism a cell uses to direct proteins into the regulated secretory pathway. Using the prohormone convertase PC2 as a model regulated secretory protein, we identified a region at the N-terminus of the protein which encodes a transferable, dominant membrane-association signal. Membrane association is thought to be an important step in the process of targeting to the regulated secretory pathway. We also showed that this membrane association occurs by an interaction with the lipid bilayer, rather than with any protein component of the membrane. More specifically, PC2 interacts with membrane microdomains known as lipid rafts. These areas of the membrane are enriched in cholesterol and sphingolipids and have previously been shown to be important for an analogous sorting event, that of sorting to the apical membrane of polarised epithelial cells. Several proteins destined for the regulated secretory pathway have now been shown to associate with lipid rafts, including the prohormone convertase PC3, carboxypeptidase E and thyroglobulin. It is, therefore, hypothesed that lipid rafts play a part in sorting to the regulated secretory pathway but the mechanism involved is unclear.

Involvement of lipid rafts in protein sorting and secretion

Lipid rafts have proposed roles in diverse cell processes, including cell signalling, mediating front-rear polarity in migrating cells, exocytosis, GLUT4 translocation and protein targeting. Since lipid rafts underpin many fundamental processes in the eukaryotic cell it is clear that the vast array of functions proposed for them must be dependent on their association with particular proteins, some of which will play a regulatory role either in lipid raft formation or in their downstream function. Identification of such proteins will be an important step in our understanding of lipid raft function. A family of proteins that associate with lipid rafts has been identified and the original member of this family, MAL, has a proposed role in raft-mediated protein targeting in epithelial cells. My group identified a new member of this family, MAL2 (also simultaneously identified by other groups and called TPD52 and CRHSP28) that has a more ubiquitous distribution. A study of this protein and its interactions with other cytoplasmic proteins will further our understanding of lipid raft formation and raft-mediated protein targeting.

Current Research

My time is now split between my role as Director of Studies, Admissions (Science), a 0.75 FTE role, and my role as a member of the School of Medical Sciences (0.25 FTE). I have a major interest in teaching and enhancing the quality of teaching within the Institute, the latter of which I achieve through my roles as Convenor of the University's Quality Assurance Committee and Institutional Team leader for the Quality Assurance Agency's Developing & Supporting the Curriculum Enhancement Theme. My personal interests are in using innovative teaching techniques and interactive lecture formats. In 2011 I was awarded a student-led teaching award for "Teaching for Employability".

QAA (Scotland) Enhancement Theme Conference (2014) presentation.

An overview of the work that Aberdeen University carried out during the Developing & Supporting the Curriculum Enhancement Theme was presented at their Annual Conference in June 2014. The full Prezi can be viewed at and contains links to the various projects undertaken during the theme. Many thanks to Pat Bain for the illustrations and Phil Marston for advice on making the Prezi.


Teaching Responsibilities

Course Coordinator for BI25M7 (Energy for Life)

Contribute to teaching on:

BI25M7 (Energy for Life, level 2 course) - lectures on metabolic regulation and revision lectures

MB3006 (Molecular Biology of the Cell, level 3 course) - lectures on eukaryotic transcription and protein sorting

SM3001 (Frontiers in Molecular Medical Sciences, level 3 course) - lectures on protein:protein interactions

MB4050 (Advanced Molecular Biology, level 4 course) - lectures on eukaryotic secretory pathway

MB4505 (Honours Molecular Biology B, level 4 course) - research tutorial on non-classical secretory pathways



Currently viewing:
Filter by Publication Type

Page 1 of 2 Results 1 to 10 of 19

  • Signal peptide mutations in RANK prevent downstream activation of NF-κB

    Crockett, J. C., Mellis, D. J., Shennan, K. I. J., Duthie, A., Greenhorn, J., Wilkinson, D. I., Ralston, S. H., Helfrich, M. H., Rogers, M. J.

    Journal of Bone and Mineral Research, vol. 26, no. 8, pp. 1926-1938

    Contributions to Journals: Articles

  • TGF-β2 alters the characteristics of the neuromuscular junction by regulating presynaptic quantal size

    Fong, S. W., McLennan, I. S., McIntyre, A., Reid, J., Shennan, K. I. J., Bewick, G. S.

    PNAS, vol. 107, no. 30, pp. 13515-13519

    Contributions to Journals: Articles

  • Xenopus Egg Extracts: A Model System to Study Proprotein Convertases

    Shennan, K. I. J.

    Xenopus Protocols: Cell Biology and Signal Transduction. Liu, X. J. (ed.). Humana Press, pp. 199-212, 14 pages

    Chapters in Books, Reports and Conference Proceedings: Chapters

  • Protein secretory pathways

    Blazquez, M., Shennan, K. I. J.

    Nature Encyclopaedia of the Human Genome, Vol 4, pp. 849-853, 4 pages

    Chapters in Books, Reports and Conference Proceedings: Chapters

  • Association of prohormone convertase 3 with membrane lipid rafts

    Blazquez, M., Docherty, K., Shennan, K. I. J.

    Journal of Molecular Endocrinology, vol. 27, no. 1, pp. 107-116

    Contributions to Journals: Articles

  • Basic mechanisms of secretion: sorting into the regulated secretory pathway

    Blazquez, M., Shennan, K. I. J.

    Biochemistry and Cell Biology, vol. 78, pp. 181-191

    Contributions to Journals: Articles

  • Involvement of the membrane lipid bilayer in sorting prohormone convertase 2 into the regulated secretory pathway

    Blazquez, M., Thiele, C., Huttner, W. B., Docherty, K., Shennan, K. I. J.

    Biochemical Journal, vol. 349, pp. 843-852

    Contributions to Journals: Articles

  • Processing of synthetic pro-islet amyloid polypeptide (proIAPP) 'amylin' by recombinant prohormone convertase enzymes, PC2 and PC3, in vitro

    Higham, C. E., Hull, R. L., Lawrie, L., Shennan, K. I. J., Morris, J. F., Birch, N. P., Docherty, K., Clark, A.

    European Journal of Biochemistry, vol. 267, pp. 4998-5004

    Contributions to Journals: Articles

  • Inhibitory effect of Pax4 on the human insulin and islet amyloid polypeptide (IAPP) promoters

    Campbell, S. C., Cragg, H., Elrick, L. J., Macfarlane, W. M., Shennan, K. I. J., Docherty, K.

    FEBS Letters, vol. 463, pp. 53-57

    Contributions to Journals: Articles

  • Differences in the autocatalytic cleavage of pro-PC2 and pro-PC3 can be attributed to sequences within the propeptide and Asp310 of pro-PC2

    Scougall, K., Taylor, N. A., Jermany, J. L., Docherty, K., Shennan, K. I.

    Biochemical Journal, vol. 334 ( Pt 3), pp. 531-7

    Contributions to Journals: Articles

Show 10 | 25 | 50 | 100 results per page