- work +44 (0)1224 437495
- work +44 (0)1224 437460
- The University of Aberdeen MRC Centre for Medical Mycology, School of Medicine, Medical Sciences & Nutrition, University of Aberdeen, Room 4.22 Institute of Medical Sciences, Foresterhill, Aberdeen AB25 2ZD. Office tel: +44 (0)1224-437495.
The Brand Lab is part of the Aberdeen Fungal Group:
The AFG is now the Medical Research Council Centre for Medical Mycology at the University of Aberdeen. Watch a short movie about the Brand group's research focus at:
The AFG is also affiliated to the Wellcome Trust Strategic Award: Medical Mycology and Fungal Immunology Group:
How I came to be a scientist https://www.youtube.com/watch?v=t2IRfzpPJ9E
2017 - 22 Wellcome Senior Fellowship
2018 - 21 IMS Researcher Development Lead
2014 - 20 BBSRC Commitee E panel member
2013 Elected Fellow of the Royal Society of Biology
2015 - 18 Co-Lead, Microbiology Research Programme, University of Aberdeen
2010 British Mycological Society Berkeley Award for Early-Career Scientists
2010 - 14 Medical Research Council New Investigator
2009 - 17 Royal Society University Research Fellow
2006 - 09 Researcher Co-Investigator, BBSRC, with Prof Neil Gow
2004 PhD in Microbiology, University of Aberdeen
2000 Bsc Biochemistry 1st Class, University of Aberdeen
2005 Access Course, University of Aberdeen
Directional growth in polarised cells
Eukaryotic cells that grow by polarised extension perform specialised, essential functions in vertebrates, plants and fungi. This disparate group of cells, which includes neurons, pollen tubes, root hairs and fungal hyphae, all share a similar function – they extend through their environment in order to make contact with their own specific target. To be successful, they must be able to interpret local signals that tell them which direction to grow (navigate) and they must be able to change their direction of growth if necessary (steer). The environmental signals that help neurons, pollen tubes and fungi to navigate differ greatly but they may share similar steering mechanisms because the cell components that regulate polarised growth are highly conserved. We are using the dimorphic fungus, Candida albicans, as a model organism in which to study how polarised cells navigate and steer. C. albicans displays tropic, or pre-programmed, growth behaviour under certain conditions and we are using these responses to study the molecular links between environmental signalling and the machinery that drives tip re-orientation. We have shown that loss of normal regulation in the hyphal tip correlates with the inability of the fungus to form normal lesions in internal organs during systemic infection. We want to understand which signals within the human body influence how the hyphal tip behaves during disease progression.
Fungi are nature's great re-cyclers and can degrade all kinds of organic and inorganic material into the simple building blocks needed for new growth. The downside of this phenomenon for human health is that fungi biodegrade medical plastic devices, causing them to malfunction and need replacing. The upside is that fungi produce a host of bioactive compounds that can be harnessed for medical and industrial use. With collaborators in the Pharmacy and Chemistry Departments at Queen's Belfast and the University of Edinburgh, respectively, we are interested in both combating and exploiting the complexities of fungal growth.
Professor Paul Janmey, University of Pennsylvania (Cell mechanics)
Dr Dominic Campopiano, School of Chemistry, University of Edinburgh
Dr Andrew Goryachev, Computational Cell Biology, University of Edinburgh (Cell polarity)
Prof Ken Sawin, University of Edinburgh (S. pombe)
Dr Stewart Smith, University of Edinburgh (Bioelectronics)
Professor Peter Sudbery, University of Sheffield (Polarised growth in fungi)
Cheryl Gale, MD, University of Minnesota (Fungal tip regulation and pathogenesis)
Mr Kim Ah-See, ENT Consultant, Aberdeen Royal Infirmary
Dr Marco Thiel, University of Aberdeen (Mathematical Biology)
Professor Joe Heitman, Duke University, N. Carolina (Evolution & host-sensing in pathogenic fungi)
Dr Alison Crossley, Department of Materials, University of Oxford (Surface chemistry)
2017 Wellcome Trust Senior Research Fellowship
2016 Wellcome Trust ISSF Seed-corn award
2015 Wellcome Trust ISSF Seed-corn award
2015 Wellcome Trust Strategic Award studentship
2015 University of Aberdeen Elphinstone studentship
2014 BBSRC Eastbio PhD studentship
2013 SEB-funded 4-year PhD studentship
2013 EU Marie Curie studentship 'FungiBrain' with N. Gow, Co-ordinator: Nick Read, Manchester
2012 MSD-SULSA award
2012 MRC Centenary Fund Award
2012 BMS Summer Studentship
2011 Royal Society Equipment Grant
2011 BMS Summer Studentship
2010 BBSRC PhD studentship
2009 MRC New Investigator Grant
2009 - 2017 Royal Society University Research Fellowship
2007 BBSRC Researcher Co-Investigator (project grant with Prof Neil AR Gow)
3rd-Year MC3504 Microbiology practical course
MSc MC5507 Current Techniques in Microbiology
1st-Year SM1501 The Cell 'Fungi - Moulds, Manufacturers and Models'
Honours Year Statistics workshop
Personal tutor for Biochemistry, Genetics, Immunology and Biotechnology undergraduates.
- Further Info
BBSRC Committee E Member
Royal Society Newton International Fellowship Panel
Royal Society Research Grant Board: Biological Sciences
IMS Researcher Development Lead
Course Co-ordinator: MB5024 MRes
The tropic growth of Candida albicans hyphae is calcium-dependent.
False colour image of thigmotropic growth of C. albicans hyphae on a microfabricated quartz slide with a ridge height of 3.25 ?m. Growing hyphal tips change direction on contact with obstacles in the substratum. Deletion of calcium ion channels, or removal of calcium from the growth medium, reduces the sensitivity of hyphal tips to changes in the substratum.
C. albicans hyphae form 2-dimension sinusoidal curves and 3-dimensional helices when grown on semi-solid medium. Septa are generally located at the apices of alternate curves, suggesting that curve formation is linked to the cell-cycle. The formation of curved hyphae is attenuated in mutant strains where calcium ion channels have been deleted, so normal calcium flux and homeostasis is required for the initiation of this growth behaviour.
Like many tip-growing cells, C. albicans hyphae align towards the cathode in an applied electric field. This effect can be heightened or reduced by the addition or chelation of calcium ions, respectively.
Group Members Past Members
Tina Bedekovic Dr Silvia Wehmeier
Mariana Almeida Emma Morrison
Ben Rutter Dr Darren Thomson
Ijeoma Okoliegbe Dr Brandon Childers
'Killer Fungi' Explorathon. September 2018
Organiser of the Annual Microbiology Schools Lecture.
UK Fungus Day 2017 'Fantastic Fungi' - part of the City of Aberdeen Explorathon Programme
Royal Society 2016 Summer Science Exhibition ' Killer Fungus' : https://royalsociety.org/science-events-and-lectures/summer-science-exhibition/exhibits/killer-fungus/
The Royal Society 'I wasn't always a Scientist: https://royalsociety.org/policy/projects/leading-way-diversity/i-wasnt-always-a-scientist/
The Hay Festival, 2014: 'The Next Big Thing': http://www.hayfestival.com/p-8222-liz-tunbridge-alexandra-brand-lucie-green-and-ana-cavalcanti.aspx and https://royalsociety.org/events/2014/05/the-next-big-thing/
Naked Science broadcast: http://www.thenakedscientists.com/HTML/podcasts/show/2011.08.28/
Naked Science webpage: http://www.thenakedscientists.com/HTML/content/interviews/interview/1783/