Difference between revisions of "FCCT Biochemistry Lab:Research:Cyanobacterial Biotechnology"
(New page: == The great potential of Cyanobacteria == Cianobacteria evolved as first microorganisms that were able to use solar light as energy source to convert carbon dioxide into oxygen that slowl...)
Revision as of 03:15, 9 August 2012
The great potential of Cyanobacteria
Cianobacteria evolved as first microorganisms that were able to use solar light as energy source to convert carbon dioxide into oxygen that slowly accumulated to such levels that other organisms could use it for breathing. As the name says, they are bacteria (although some still call them blue-green algae) with a rather typical prokaryotic cell structure and are thus in principle easy to study and modify.
Today, cyanobacteria still produce a large part of the oxygen on this planet. They live in oceans, lakes and rivers, but they can also be found in soil and elsewhere. Under the microscope, they appear as multicellular threads or as single cells or small groups of cells. The range and abundance of cyanobacteria is enormous.
Several cyanobacterial species are exploited for different applications, from food supplements to biomass and biofuel production. Their potential can be further expanded by genetic modifications. Several strains are naturally competent, which means they spontaneously accept foreign DNA. We just have to find the missing genes and incorporate them together with compatible regulatory elements.
We believe cyanobacterial cells are as difficult to work with as this was the case 30 years ago. There was little progress in making these cells user-friendly for researchers and engineers who would like to genetically modify cyanobacteria. There are several problems we would like to tackle, the first being biosafety. Cyanobacteria that are standardly used in laboratories around the world were isolated from nature and they can survive in nature if they are released from laboratories. Genetic modifications might impose a load that can reduce the fitness of gentically modified cells in the environment, but this cannot be taken as a serious safety measure. We would thus like to genetically modify cyanobacteria in a way that would prevent laboratory strains from growing outside a laboratory or a photobioreactor.
In addition, we would like to expand the range of useful vectors and promoters, specially for (over)production of proteins of interest. We would like to prepare plasmid-derived vectors and develop protocols for gene cloning and expression in Cyanobacteria.
Although not our prime interest, we are establishing cooperations with other groups on cyanobacterial biomass production and bioremediation strategies involving cyanobacteria.
Who we are
- Marko Dolinar, associate professor and PI
- Nejc Jelen, PhD, teaching assistant
- Blaž Bakalar, Kristina Bremec, Sabina Kolar, Žan Železnik (undegraduate biochemistry students (2011/12))
Currently, We are hiring a researcher for a EU project - apply by August 17, 2012!