The Centre of Plant Structural and Functional Genomics has been established to study the structure and function of nuclear genome in higher plants. The main focus is on economically important crops like cereals, legumes, bananas and plantains.
Methodological approaches involve classical and molecular cytogenetics, flow cytometry and sorting, recombinant DNA techniques and construction of chromosome and chromosome-arm specific BAC libraries. Because of the complexity of research projects, the Laboratory collaborates with many research groups throughout the world. The laboratory staff is also involved in teaching and technology transfer, including consultancy services in the above mentioned areas.
Flow cytogenetics involve chromosome analysis and sorting using flow cytometry applications of sorted chromosomes include physical mapping using PCR, targeted isolation of molecular markers, isolation of low-copy (genic) sequences from specific genome regions, high-throughput physical mapping of DNA sequences by hybridization to DNA arrays, as well as HAPPY and optical mapping.
The most attractive use of sorted chromosomes is the production of chromosome- and chromosome arm-specific DNA libraries. Such libraries provide a permanent and easily accessible molecular resource specific for a particular part of the genome, is expected to have a major impact on wheat genomics.
Flow cytometry is powerful technique with many application. We used it for genome size estimation, ploidy measurement and flow karyotype analysis of higher plants.
We interested in molecular evolution and organization of Musa genome and serve as the Musa Genome Resources Centre (MGRC). The primary aim of the Centre is to support research activities of the Musa Genomics Consortium by distributing Musa genome resources to Consortium Members and by developing new resources.
We are using molecular cytogenetic methods (FISH and GISH) to study genomic constitution of Festuca × Lolium hybrids, chromosome pairing during meiosis, and to map BAC clones on chromosomes of Festuca pratensis. In collaboration with other labs, we also developed set of introgression lines of all F. pratensis chromosomes in tetraploid L. multiflorum and DArT chip for five species within Festuca-Lolium complex.