Thesis title:
Evolutionary genomics of pelvic spine reduction in Gasterosteus aculeatus
Trial lecture topic:
Connecting micro and macro-evolutionary processes - insights from limb development
Evaluation Committee:
- Associate Professor Felicity C. Jones, Groningen Institute of Evolutionary Life Sciences, University of Groningen, Netherlands
- Researcher Andrew David Foote, Center for Ecological and Evolutionary Synthesis, University of Oslo
- Professor Leslie R. Noble, Faculty of Biosciences and Aquaculture, Nord University
Supervisory Committee:
- Main supervisor: Professor Jarle Tryti Nordeide, Faculty of Biosciences and Aquaculture, Nord University
- Co-supervisor: Professor Steinar Daae Johansen, Faculty of Biosciences and Aquaculture, Nord University
- Co-supervisor: Emeritus Professor Truls Borg Moum, Faculty of Biosciences and Aquaculture, Nord University
Thesis summary:
Marine threespine sticklebacks have colonised and adapted to freshwater lakes. Freshwater sticklebacks often have reduced body armour, like lateral plates and sometimes pelvic spines. Pelvis reduction in North American sticklebacks is convincingly linked to the PelA and PelB enhancers of the Pitx1 gene. In a subarctic Norwegian watercourse, an upper lake consists of sticklebacks with normal, asymmetrical and no pelvic spines. A downstream lake and a nearby marine site only have normally-spined sticklebacks. The present study examines mechanisms for the pelvic spine reduction of sticklebacks in this watercourse.
Sanger and next-generation sequencing were applied to examine the Pel enhancers and mitochondrial and nuclear genomic differences between the three populations. The Pel enhancers of sticklebacks in the upper lake seems not associated with pelvic spine reduction. Two distinct mitochondrial genome groups were identified in the upper lake, and only one of them was found in the downstream lake. Both the mito- and the nuclear-genomes varied more among marine than freshwater fish. The nuclear genomes were more different between the two freshwater populations than between the freshwater and the marine fish.
To conclude, the sticklebacks’ pelvic spine reduction in the upper lake seems to be determined by genomic regions other than those previously identified in North America, and a region at chromosome 9 is identified as promising.