AK is a former JR’s PhD student. Her interests focus on the impact of parasites on evolution and ecology of their hosts. WB uses molecular tools to study historical processes at and below the species level. AB is an Adiunct at the Department of Parasitology, Institute of Zoology, University of Warsaw. Her scientific interests are in ecology and epidemiology of intestinal and vector-borne parasites, including molecular epidemiology. ES is a Professor at the Faculty of Biology, University of Warsaw, Poland. His research interests include the parasite biology, inter-relationships between immunity and pathology, as well as the ecology of host-parasite interactions in wild animals and molecular epidemiology of vector (ticks)-transmitted pathogens. JR is a Professor at the Institute of Nature Conservation, Polish Academy of Sciences and at the Institute of Environmental Sciences, Jagiellonian University. His interests focus on sexual selection, its evolutionary-genetic background and conservation genetic implications.
Effects of an MHC-DRB genotype and allele number on the load of gut parasites in the bank vole Myodes glareolus
Article first published online: 10 FEB 2010
© 2010 Blackwell Publishing Ltd
Special Issue: Next Generation Molecular Ecology
Volume 19, Issue Supplement s1, pages 255–265, March 2010
How to Cite
KLOCH, A., BABIK, W., BAJER, A., SIŃSKI, E. and RADWAN, J. (2010), Effects of an MHC-DRB genotype and allele number on the load of gut parasites in the bank vole Myodes glareolus. Molecular Ecology, 19: 255–265. doi: 10.1111/j.1365-294X.2009.04476.x
- Issue published online: 10 FEB 2010
- Article first published online: 10 FEB 2010
- Received 10 June 2009; revision received 14 September 2009; accepted 17 September 2009
- 454 sequencing;
- bank vole;
The major histocompatibility complex (MHC) genes code for the proteins responsible for pathogen recognition. The MHC class II DRB gene is multiplicated in the bank vole, Myodes glareolus, with different numbers of loci found in different individuals. Possessing large numbers of loci should increase the probability of pathogen recognition, but according to the optimality hypothesis, there is a cost of possessing too many MHC alleles. Using 454 technology, we determined the individual DRB allelic diversity and related it to the load of intestinal parasites in voles collected from three sites separated by a distance of 12 to 27 km. The analysis of six microsatellite loci revealed significant population structure (FST = 0.07). The sites differed significantly in the prevalence and abundance of nematode species as well. We found two significant associations between MHC alleles and the intensity of the infection with the most prevalent nematode, Aspiculuris tetraptera. One of these associations was population-specific. This result suggests that the directions of selection can differ between populations connected by a low level of gene flow, which may contribute to the maintenance of high DRB allele diversity. In accordance with the optimality hypothesis, individuals with an intermediate number of alleles carried the lowest number of nematode species and had the lowest prevalence of A. tetraptera. However, the intensity of infection with A. tetraptera was linearly and negatively associated with the number of alleles.