PhD studentship opportunities 2021

The lab has several opportunities for competitive PhD studentship applications for the upcoming academic year starting in October 2021.

This year we are offering projects on bee pollination, plant speciation, invasive species and adaptive evolution, among other themes. The projects range from the applied to the theoretical and everything in between. We are looking for excellent, motivated students that are interested in working with a diverse team of people on the broad area of plant ecology and evolution.

The application calls are for PhD studentships awarded through a competitive application funded by NERC and BBSRC. Some of these calls are open to international applicants (NERC) but please check carefully for eligibility requirements.

If you are interested in any of these projects please contact me by email or contact the lead supervisor. Informal queries are very welcome, so please don’t be shy and get in touch!

Projects arranged by lead institution.

University of Stirling

Project 1. Behavioural biology of buzz-pollinating bees and flies. DTP IAPETUS2. NERC.

Supervisors: Mario Vallejo-Marin (U Stir), Susan Healy (U. St Andrews), Gema Martin-Ordas (U Stir).

Brief overview: More than 15,000 species of bees are capable of deploying powerful vibrations of their thorax to remove pollen from flowers with specialised morphologies. Pollination by these vibration-producing bees has given rise to the phenomenon of buzz pollination, which occurs in more than 20,000 species of flowering plants and includes important crops such as tomato, blueberries and kiwifruit. Previous work has shown that the use of vibrations to remove pollen from flowers is part of the behavioural repertoire available to some species of pollen-collecting insects, particularly bees. This project addresses two main questions (1) Why is buzz pollination is mostly restricted to a subset of bee species? (2) What determines when a bee capable of buzz pollination deploys vibrations to extract pollen from flowers?  

Application deadline: 8 January 2021.

More info and how to apply here.

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Project 2. Bees and buzz pollination in crops: Evaluating the potential for matching bee vibrations and buzz-pollinated crops to improve fruit yield. EastBio. BBSRC.

Supervisors: Mario Vallejo-Marin (U Stir), Jenni Stockan (James Hutton Institute), James Windmill (U Strathclyde).

Brief overview: Buzz-pollinated plants include important food crops such as tomato, blueberries, and kiwi.  Buzz-pollinated crops grown in greenhouses or outdoor settings often require supplemental pollination to achieve full fruit set and to improve fruit quality. This supplemental pollination is often provided using mechanical shakers, or additional pollinators such as honeybees or bumblebees. However, the effectiveness of these treatments is enormously varied even within the same crop species. This diversity of outcomes could be explained by variation at the plant, bee or environmental levels. Previous work has shown that buzz-pollinating bees differ widely in the type of vibrations they can produce, and that the type of vibration applied to a flower determines pollen release, and potentially fruit quality. Moreover, environmental variables such as temperature and humidity may influence both the likelihood of bees producing vibrations or the effectiveness of these vibrations to release pollen from different types of flowers. The main goal of this project is to investigate what type of supplemental pollination is more effective at maximising fruit yield in buzz-pollinated soft fruits including blueberries. In this project, we will use laboratory and field experiments to address three questions: (1) What is the relationship between vibration properties (amplitude, frequency and duration) and pollen release and fruit quality across different varieties of blueberries? (2) What are the properties of the vibrations used by buzz-pollinating bees while visiting experimental plots of different varieties of blueberries? (3) What is the effect of increased temperature and humidity on the capacity of buzz-pollinating bees to release pollen from flowers? 

Application deadline: 8 January 2021.

More info and how to apply here.


On the road: Range expansion of coastal plants under global change

Supervisors: Dan Chapman (UStir), James Bullock (CEH), Kevin Walker (CEH) and Mario Vallejo-Marin.

To cope with human-driven environmental change species must either move or adapt. Indeed, shifts in the geographical distributions of species are a clear ecological response to environmental change. Global climate change is driving poleward and uphill range expansions in many species, while other species exploit anthropogenic habitat modification and human-mediated dispersal to colonise new habitats. Better understanding of this range-shifting ability is needed to predict ecological responses to environmental change. This project will achieve that by identifying the species’ characteristics that are associated with successful range expansion.

The studentship will focus on range expansions by coastal specialist plants, which have been understudied compared to fully terrestrial species. Coastal salt tolerant plants (termed halophytes) are a tractable group to investigate multiple dimensions of range expansion in a way not possible for other species groups. This is because coastal halophytes have two potential routes for range shifting. First, climate change could allow them to colonise further north along the coastline. Second, winter de-icing of roads using salt has created new halophytic habitats, allowing some species to spread inland onto road networks, often using vehicles for rapid dispersal. This study will be the first to systematically investigate and compare range expansions into natural vs anthropogenic territory.

More information and how to apply here.


University of Edinburgh

Project 3. Dissecting the causes of reproductive mode variation in the plant Mimulus guttatus. E4 DTP. NERC.

Supervisors: Matthew Hartfield (U Edinburgh), Mario Vallejo-Marin (U Stir).

Brief overview: This project will analyse genome data from UK populations of Mimulus guttatus (yellow monkeyflower) to determine how the local ecology and geography affects its reproductive mode.

The project will involve the analysis of new genomic data from previously–collected samples to quantify the extent of self-fertilisation and clonal reproduction in natural populations in the UK. This data can then be compared with geographical, ecological, and climatic data to determine if these factors correlate with the local reproductive mode. Genetic data from UK samples will then be compared with those from the United States, to determine their population history and investigate if different degrees of asexual and sexual reproduction arose at specific times in the past. These data will allow us to investigate how the evolutionary history differs between populations exhibiting different reproductive modes. There will also be scope to develop theoretical models to further investigate the consequences of reproductive mode on genetic variation, or to collect more samples for analysis. The project will provide the student with cutting-edge genomics and bioinformatics skills, which are essential for modern biological research, and put them at the forefront of developing an exciting new model for evolutionary genetics study.

Application deadline: 7 January 2021.

To find out more and to apply follow this link. NERC E4 DTP.

or

To find out more and to apply follow this link. EASTBIO BBSRC.


Project 4. Adaptive introgression and cold tolerance in British Rhododendron ponticum-a genomic approach. EastBIO. BBSRC.

Supervisors: Richard Milne (U Edinburgh), Mario Vallejo-Marin (U Stir).

Brief overview: Rhododendron ponticum is invasively naturalised over much of the British Isles, which is much colder than its native range (Spain and Turkey).  Naturalised material contains introgressed (transferred by hybridisation) DNA from the highly cold-tolerant American R. catawbiense, and such DNA is more frequent in colder regions of the UK, suggesting but not proving that introgression from R. catawbiense confers increased cold tolerance.  

This project would make use of the full genome sequence of R. ponticum, recently generated by co-supervisor Dr Jianquan Liu’s group in China.  This will be used as a basis for designing a set of RNA baits to capture sequence data from hybrid populations and herbarium samples.  The bait set will comprise candidate cold tolerant genes, plus single copy genes well dispersed over the genome, to allow for FST scanning to detect frequency of introgressed regions from R. catawbiense, and to determine if cold-tolerance associated genes are over-represented in the introgressed set. 

Application deadline: 8 January 2021.

To find out more information and to apply, follow this link.

Royal Botanic Gardens, Edinburgh

Project 5. Diversity of floral morphology within buzz pollinated plants: All about the bees? E4 DTP. NERC.

Supervisors: Tiina Sarkinen (RBGE), Caroline Lehman (RBGE), Mario Vallejo-Marin (U Stir).

Brief overview: Buzz pollinated plants require buzzing bees for their effective pollination. This project explores whether different floral morphologies have evolved in response to different buzz pollinating bees.

Buzz pollination has evolved among thousands of flowering plants, including species of agricultural importance such as the tomato. Buzz pollination is a specialised form of pollination in which bees extract pollen from flowers that have specialised poricidal anthers that unlock only under vibrations produced by bees.

Buzz pollinated plants rely on buzzing bees for their pollination. Yet we know relatively little about the interaction of buzz pollinating bees and different floral morphologies. In the face of worldwide declines in bee diversity, this project aims to explore how different floral morphologies evolve in response to different types of bees. 

The project will explore the diversity of floral traits across buzz pollinated plants in the context of what we know about the biomechanics of buzz pollination, buzzing behaviour in bees, and other aspects of bee behaviour and diversity. For example, bees are known to prefer to visit darker coloured flowers in colder temperatures, which may in turn affect floral morphology and colouration in a given climate. Such hypothesis can be tested using georeferenced occurrence data of buzz pollinated plants, their corolla colouration, and the bioclimate of each occurrence point. There is also space within the project for the student to develop experiments using plants and bees.

The work will be undertaken in a cross-disciplinary research team between the Royal Botanic Garden Edinburgh (plant evolution & taxonomy), University of Edinburgh (ecology), and University of Stirling (plant reproduction, plant & bee interactions, buzz pollination). 

Application deadline: 7 January 2021.

To find out more and to apply follow this link


Durham University

Project 6. Rapid evolution of reproductive isolation in newly allopatric invasive populations. DTP IAPETUS2. NERC.

Supervisors: Adrian Brennan (Durham), Mario Vallejo-Marin (U Stir).

Brief overview: Invasive populations are ideal model systems to understand the early stages of allopatric speciation, a keystone concept of evolutionary biology (1). Divergent selection to different environments can drive to reproductive isolation and, eventually, speciation (2). The annual, Centaurea solstitialis, (yellow starthistle) is an ideal system to study selection and speciation during a biological invasion. It is native from Eurasia, and invasive in Australia and the Americas (3). It developed different sets of local adaptations to different regions, including some degree of reproductive isolation (1,3-6). The fundamental research undertaken in this PhD project, will address the emergence and maintenance of reproductive isolation in yellow starthistle, and investigate how the balance of selective or neutral processes can lead to incipient speciation in a new allopatric range. This research will contribute substantially to our understanding of how biodiversity is generated and maintained , as well as establishing the likely impacts of invasive populations on biodiversity.

Application deadline: 8 January 2021.

To find out more and to apply follow this link

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