One such microalga is a species of diatom called Fistulifera solaris, which is emerging as a promising candidate for next-generation biofuel technology. Diatoms are microscopic algae that are major contributors to marine ecosystems; they are also the basis of diatomaceous earth, which is used by gardeners as a natural pest deterrent. Not only does F. solaris grow quickly and produce high levels of oils, it does both at the same time, unlike other oil-producing microalgae that produce their highest amounts of oil at stages when they grow slowly, if at all. These characteristics make F. solaris an excellent candidate for batch culture (see figure) to produce biomass from which oil for biofuels can be harvested.
F. solaris was originally isolated from samples taken at the junction of two rivers in Japan. A collaboration of scientists in Japan and France aimed to elucidate the molecular underpinnings of simultaneous growth and oil production by sequencing the genome of F. solaris and also cataloguing the transcriptome -- providing a read-out of all genes expressed at a given time. Lead scientist Dr. Tsuyoshi Tanaka of the Division of Biotechnology and Life Science in the Institute of Engineering at Tokyo University of Agriculture and Technology, highlights the need for this information, saying "Biofuel production using photosynthetic organisms such as microalgae is one of the most promising approaches to generating sustainable energy. However, the molecular functions of organisms such as oleaginous microalgae remain unclear, thus hampering efforts to improve productivity." Tokyo University of Agriculture and Technology.
Journal Reference:
Tsuyoshi Tanaka, Yoshiaki Maeda, Alaguraj Veluchamy, Michihiro Tanaka, Heni Abida, Eric Mar?chal, Chris Bowler, Masaki Muto, Yoshihiko Sunaga, Masayoshi Tanaka, Tomoko Yoshino, Takeaki Taniguchi, Yorikane Fukuda, Michiko Nemoto, Mitsufumi Matsumoto, Pui Shan Wong, Sachiyo Aburatani, Wataru Fujibuchi. Oil Accumulation by the Oleaginous DiatomFistulifera solarisas Revealed by the Genome and Transcriptome. The Plant Cell Online, 2015; tpc.114.135194 DOI: 10.1105/tpc.114.135194










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