Abstract
Microalga Nannochloropsis oculata is a promising alternative feedstock for biodiesel. Elevating its oil-yielding capacity is conducive to cost-saving biodiesel production. However, the regulatory processes of multi-factor collaborative stresses (MFCS) on the oil-yielding performance of N. oculata are unclear. The duration effects of MFCS (high irradiation, nitrogen deficiency and elevated iron supplementation) on N. oculata were investigated in an 18-d batch culture. Despite the reduction in cell division, the biomass concentration increased, resulting from the large accumulation of the carbon/energy-reservoir. However, different storage forms were found in different cellular storage compounds, and both the protein content and pigment composition swiftly and drastically changed. The analysis of four biodiesel properties using pertinent empirical equations indicated their progressive effective improvement in lipid classes and fatty acid composition. The variation curve of neutral lipid productivity was monitored with fluorescent Nile red and was closely correlated to the results from conventional methods. In addition, a series of changes in the organelles (e.g., chloroplast, lipid body and vacuole) and cell shape, dependent on the stress duration, were observed by TEM and LSCM. These changes presumably played an important role in the acclimation of N. oculata to MFCS and accordingly improved its oil-yielding performance.
Highlights
Microalgae are a diverse group of microorganisms with various unique biological characteristics, including high photosynthetic energy transfer efficiency, high biomass productivity, excellent adaptability to various environments and capability of producing a broad variety of bioenergy [1,2,3]
We explored the variations in growth, cellular biochemistry, fatty acid (FA) and TAG production, biodiesel property and morphology of N. oculata during multi-factor collaborative stresses (MFCS)
Cell density on day 14 (8.351×107 cellsÁmL-1, the maximum value) increased by 35.0% compared to the initial value (6.185×107 cellsÁmL-1), while biomass concentration increased by 75.6% correspondingly, presumably due to the increased cellular volume and cellular specific gravity observed from microscopy
Summary
Microalgae are a diverse group of microorganisms with various unique biological characteristics, including high photosynthetic energy transfer efficiency, high biomass productivity, excellent adaptability to various environments and capability of producing a broad variety of bioenergy [1,2,3]. Responses of N. oculata to long-term stresses analysis, decision to publish, or preparation of the manuscript
Sign-in/Register to view highlights & summary 
Published Version (
Free)
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call