Cathy Hawes

Multi-Trophic Interactions

Photograph of a beetle on chicory flowerMulti-trophic Interactions is a new major research topic in Agroecology that combines existing lines of study at both SCRI and the University of Dundee. Trophic (or feeding) interactions drive the cycling of energy and nutrients in farmland. Insects and other invertebrates feed on plants and in turn are fed on by other insects, spiders, various symbionts, pathogens and vertebrates. A very small proportion of the total species in trophic interactions are pests of agriculture. Most mediate processes that are essential to the cropping cycle, such as the breakdown of dead organisms (crops, weeds, wood, animals), the regulation of pests and the pollination of flowers. These trophic interactions are exceedingly complex and are studied using advanced concepts and methods in organism biology, molecular biology and mathematical modelling.  Through gaining basic knowledge, the topic aims to provide a scientific basis for future management of invertebrate populations in farmland.

Plants and plant communities

Photograph of happy field workers sampling plantsResearch in Plants and Plant Communities aims to define those properties of crops and arable plants that would maintain yield and the purity of yield while reducing the environmental footprint of cropping. The work includes basic studies of plant processes such as germination, flowering and nutrition, genetic and physiological variation in model crops and arable plants, the ecology of plant (seedbank) communities, plants as the base of the arable food web and models of geneflow, selection and evolution. The practical output will be combinations of plant traits that can be targeted in crop improvement or encouraged by agronomy. Disciplines and methods include plant physiology, genetics, statistics, modelling, microscopy and field survey.

Agroecology News Archive

Ecological roles of weeds In an invited plenary talk, Geoff Squire represented the group's ideas on the roles of weeds at the XIII Colloque International sur la Biologie des Mauvaises Herbes held at Dijon, France 8-10 September 2009. The main points of the talk were: weeds have been with us in northern Europe for more than 5000 years - we haven't got rid of them; so we need to understand them better, spend less trying to remove them and make use of their positive roles in the ecosystem. Arable cropping in Scotland is already some way towards coexisting with weeds: its cereal yields and weed seedbanks are both among the highest in the UK!  (Added 14 September 2009)

Publications archive

Refereed publications and major reports from the Agroecology group

Newton, A.C., Begg, G.S., Swanston, J.S. 2008. Deployment of diversity for enhanced crop function. Annals of Applied Biology (doi:10.1111/j.1744-7348.2008.00303.x).

Monocultures are used in high-input systems to maximise short term profitability, but over time yield and quality can become unstable. This paper considers how diversity can be reintroduced to cropping systems to confer stability without compromising quality. It combines expertise between three of SCRI's programmes: Pathology (ACN), Genetics (JSS) and Environment (GSB).

Squire, G.R., Hawes, C., Begg, G.S., Young, M.W. 2009. Cumulative impact of GM herbicide-tolerant cropping on arable plants assessed through species-based and functional taxonomies. Environmental Science and Pollution Research 16(1), 85-94. Published online 2 December 2008 (doi: 10.1007/s11356-008-0072-6).

Co-existence with GM crops in European Agriculture

SIGMEA logoThe EU project SIGMEA is examining the feasibility of growing GM and other crops together in the agricultural landscapes of Europe. A central part of the project - Workpackage 2 or WP2 - collates and analyses experimental studies on geneflow by seed and pollen, but also considers field experiments on the ecological impacts of GM cropping. WP2 has over 20 partners who are sharing and analysing definitive data on over 100 field experiments, making the SIGMEA database the most comprehensive of its type. The agroecology group at SCRI co-ordinates this unique synthesis of biology and agronomy. Contact: Geoff Squire

Above-ground - below-ground trophic interactions

There is now emerging consensus that above-ground and below-ground compartments are intimately linked, with many examples of spatially separated organisms interacting to shape community dynamics via plant-mediated mechanisms. Research at SCRI aims to gain a mechanistic understanding of the genetic and chemical plant-mediated processes which underpin interactions between organisms that exploit different parts of the plant. By understanding these key processes, we aim to exploit natural resistance mechanisms to herbivore attack and manipulate trophic interactions to manage crop pests and maintain system stability.

We work on several systems including barley, raspberry and brassicas, focusing on how soil-dwelling herbivores (predominantly root-feeding insects) affect above-ground herbivores, their antagonists (for example, parasitoids) and plant pathogens. At present our experimental and modelling research is funded by the Scottish Government, the Natural Environmental Research Council and the Engineering and Physical Sciences Research Council. Examples of our current research include the following.Image of aphids

Ecological biosafety and gene flow

Image of Laying out field experiment in the Carse of GowrieThe agroecology group at SCRI continues to make major contributions through research and extension to questions on GM crops. We examine their potential roles in cropping systems, their positive and negative environmental effects, the movement of genetic material through pollen and seed and the  means by which GM and other crops might coexist in European agriculture. We combine knowledge of biology, modelling and molecular science to answer some of the most important topical questions in ecological biosafety. All our findings are made public. Members of the group are regularly invited to advise national and international commissions in biosafety and to develop training methods for environmental risk assessment.

Farm Scale Evaluations (FSEs) of GM Herbicide Tolerant Crops

Map showing FSE sites 2000 - 2002

The group conducts impartial and independent assessment of GM crops by research financed through public funding. The Farm Scale Evaluations (FSE) of GM herbicide tolerant (GMHT) crops was commissioned by government and, including follow-up studies on GM persistence, ran from 1999 to 2006. It arose out of general concerns that the intensification of farming had reduced arable biodiversity to the point where species were disappearing from the UK and essential functions of the habitat were impaired. Despite potential benefits of GM cropping with herbicide tolerant varieties, concerns were raised that GMHT cropping would lead to even further impairment of arable systems. The FSE was commissioned to investigate the potential effects of this type of biotechnology.

Environment Plant Interactions

Image of the SCRI site looking towards the River TaySCRI's environmental science research spans across disciplines to gain a holistic understanding of how plants respond to and modify environmental processes. Scottish Government commissioned research is gaining an in-depth understanding of the environment in arable farming systems and this is being used to advise on policy development in Scotland. These skills have also been applied to emerging issues relevant to the UK and Europe, including the UK’s Farm Scale Evaluations, international working groups, IPDM-based alternatives to pesicides and EU-wide studies on the ecological impacts of GM plants.

The environment and the ecology of plants and pests are our key research areas, investigated by a strong multidisciplinary team of scientists in entomology, pathology, plant sciences, vegetation ecology, phytochemistry, mathematical modelling and soil sciences. A major area of interest is integrating processes that occur above ground and in the soil. Research conducted on plant interactions with soil has extended from the understanding of sustainable arable systems to ‘green’ engineering solutions for slope stabilisation with vegetation.

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