Sunny Townsend

Room 314, Graham Kerr Building
Institute of Biodiversity, Animal Health & Comparative Medicine
College of Medicine, Veterinary & Life Sciences
University of Glasgow
Glasgow G12 8QQ

Tel:  + 44 (0)141  330 6638
Fax:  + 44 (0)141  330 5971

E-mail:   sunnytownsend@gmail.com

Academic History/Brief CV

• July 2010-2014: Post-doctoral research associate at the University of Glasgow "Understanding how a complex intervention works: designing large-scale vaccination programs". Data analysis and epidemiological modelling support for Bill and Melinda Gates Foundation rabies control program in three extensive areas of Africa and Asia. Funded by MRC.
• Feb-May 2010: Post-doctoral training assistant, Afrique One Research Consortium on Ecosystem and Population Health. Development and delivery of a five day course "Quantitative Methods in Ecology and Epidemiology" to suit the specific desired capacity of researchers and postgraduate students at five institutions in four countries across East and West Central Africa. Consortium funded by Wellcome Trust.
• Sep 2009-Jan 2010: Data analyst for Langoustine Lab, University of Glasgow.
• 2005-2009: PhD - 'Stability of Model Ecosystems' supervised by Dan Haydon and Louise Matthews.  Funded by NERC.
• 2004: Short term contract modelling fishing vessel movement, Centre of Environment, Fisheries and Aquaculture Science (Cefas), Lowestoft
• 2003-2004: MRes 'Ecology and Environmental management', University of York
• 2003: Volunteer marine biologist, Sherkin Island Marine Station, County Cork, Ireland
• 2002: Professional divemaster, Ocean Spirit Cruises, Cairns, Australia
• 1998-2001: BSc Zoology, UCL

Stability of model ecosystems

During my PhD I have been studying mathematical mechanisms of stability in general, large model ecosystems and using lower dimensional models to study the specific biological mechanisms that cause cyclic dynamics in Scottish populations of the mountain hare.

Periodic fluctuations in mountain hares
The reasons for cyclic dynamics in Scottish mountain hares are unclear, and this is the first attempt at using modelling to explore possible causes. Mountain hare cycles in Scotland have only really gained attention in the last few years with initiation of research by Scott Newey and Simon Thirgood at the Macaulay Institute in Aberdeen, although knowledge of the system has been greatly underpinned by many natural historical and specific population studies since the 1960s. During this recent focus on cyclic dynamics in mountain hares, time series of hare shooting records from across Scotland have been analysed to statistically confirm that about half of populations are cyclic, with a range of periods from 4 to 15 years and characteristically high amplitude with coefficients of variation of 0.39 to 1.80. Field experiments and surveys have been conducted and the currently favoured explanation implicates an extrinsic driver of cycles - the interaction with a helminth parasite Trichostrongylus retortaeformis that reduces female fecundity. Mathematical modelling has not yet been directed at this problem and, while this approach cannot directly test the parasitism hypothesis, modelling can assist in determining whether this interaction is capable of generating observed population dynamics.

I first approached this problem using a strategic model of the interaction between a host and macroparasite (Anderson & May 1978) to test whether realistic hare stable limit cycles can be generated with parameters based on the best available empirical data:

Sunny E. Townsend, Scott Newey, Simon J. Thirgood, Louise Matthews and Daniel T. Haydon (2009) Can parasites drive population cycles in mountain hares? Proceedings of the Royal Society B: Biological Sciences, 276, 1611-1617.

With this simple model, the interaction could not account for hare cycles. This left me with three options: either the parameterisation was inadequate, there were missing important biological details (and therefore structural inadequacies in the model formulation) or simply that parasites do not drive host cycles.

The effect of missing details is something I could test using models, by incorporating structure ignored in the simple model that may strongly influence the dynamics. Therefore I developed a individual based model to envelop a lot of ecological complexity, including maternal effects and devised mechanisms of parasite transmission. We found that the maternal effects were weakly destabilising (increased the propensity to cycle, but not very much) and stability was very sensitive to the parasite transmission mechanism:

Townsend, S. E., Newey, S., Thirgood, S. J. & Haydon, D. T. Dissecting the drivers of population cycles: interactions between parasites and mountain hare demography. In prep.

Another important 'detail' missing from the strategic models of classical population dynamics was space. In collaboration with Steve Webb, a mathematics lecturer at the University of Strathclyde, we have extended the non-spatial model and found some intriguing spatiotemporal patterns, although it does not appear to increase the likelihood of periodic behaviours in this system:

Townsend, S.E., Webb, S., Newey, S., Thirgood, S. J. & Haydon, D. T. Periodic travelling waves in a simple host-parasite model. In prep.

Model ecosystem stability-complexity relationships

In 1958 Charles Elton identified that a "wise principle of co-existence between man and nature" was needed to argue the case for nature conservation under the intensifying press of humanity. In contemplating the coupling of ecological diversity and stability he wrote:
"for if this can be shown to be anywhere near the truth, it will have to be admitted that there is something very dangerous about handling cultivated land as we handle it now, and even more dangerous if we continue to go farther down the present road of 'simplification for efficiency' . . . the whole matter is supremely important to the future of every species that inhabits the world".  In paradoxical contrast however, the first mathematical modelling (Gardner & Ashby 1970, May 1971, 1972. 1973) showed, with both mathematical and computational support, that more complex models had a vanishing probability of being stable.

The ecosystem structures we observe, therefore, should contain structure that enhances stability and allow complex systems to persist. A non-random pattern in ecosystems is the ubiquity of inequity in species abundances. Rarely do models link a static property like the abundance distribution to the dynamical properties of ecosystems. I have been indentifying analytical arguments and generating numerical results on the role of variance in abundance distributions on ecosystem stability-complexity relationships, and find that variance in the species abundance distribution generates a positive (local) stability-complexity relationship, but more skewed distributions tend to be less stable

Townsend, S. E., Matthews, L. & Haydon, D. T. Species abundance distributions and model ecosystem resilience-interactivity relationships. In prep.

The above models view the natural world as being at equilibrium, and test their stability against only small perturbations (locally). Thus local stability analysis excludes the possibility of instability in the face of a large perturbation or the existence of non-equilibrium attractors (e.g. a periodic or chaotic attractor). While local stability has made a major contribution to stability-complexity debate over the last few decades, permanence is widely considered to be a more satisfactory definition of ecosystem persistence and has relatively recently become available as a tool for assessing the global stability of Lotka-Volterra communities (Law and Blackford, 1992).  Here, we document positive relationships between permanence and Lotka-Volterra food web complexity and report a positive correlation between the probability of local and global stability - suggesting that at least in Lotka-Volterra systems, local stability may be a better measure of ecosystem persistence than previously thought:

Townsend, S. E., Haydon, D. T. & Matthews, L. On the generality of stability-complexity relationships in Lotka-Volterra ecosystems. In prep.