Conclusion and future directionsOur

Conclusion and future directions

Our review demonstrates the versatility of cyanobacteria to biotechnological applications. They are potent sources of bioactive compounds, biofertilizers, bioplastics, energy, food and have currently been used in drugs discovery, medical diagnostics, and bioremediation. However, further research needs to focus on the satisfactory axenic culturing of these micro-organisms in order to facilitate their exploitation. Additionally, new methods need to be developed to allow the cultivation of previously ‘uncultivable’ strains. The methods should consider the organism’s requirements in the field and these conditions should be mimicked in the laboratory. The cultivation efforts should be directed towards unique environments, particularly those with extreme conditions of salinity, temperature, pH, UV and light intensity. These environments are likely to contain novel strains with strong potential in biotechnology. To circumvent cultivability problem, metagenomics could serve as an alternative approach (Handelsman 2004). This approach involves construction of metagenomic clone libraries from nucleic acids extracted directly from environmental samples. The clone libraries are then screened for the presence of functional genes that are involved in the biosynthesis of certain biotechnologically significant compounds (Zhang et al. 2005). These genes are transferred to cultivable hosts, which can be directly used for the production of the desired compounds.