RESUMO
Sesame is considered as the queen of oil seeds owing to its high oil content of about 56-62% and good quality oil. Sesame oil alone or in combination with other vegetable oils can yield good quality biodiesel. Sesame biodiesel blends up to 20% yields fuel efficiency and power output on par with mineral diesel but superior in environmental performance. Though biodiesel from edible oil is highly criticized, the demand for renewable energy compels the development of high-performance sesame plants. Triacylglycerol synthesis in flowering plants follows an acyl CoA-dependent and independent manner. This study envisages transgenic approaches to enhance oil production in sesame biomass. The genes of choice for oil enhancement includes DGAT1, PDAT1, FAD3 and cytochrome b5F. Diacylglycerol acyltransferase (DGAT) and phospholipid diacylglycerol acyltransferases (PDAT) are key enzymes in TAG synthesis. Fatty acid desaturases (FAD) has the ability to enhance specific fatty acids, whereas cytochrome b5 genes augment the process by donating electrons. A combination of the above categories of genes which performed well in terms of oil content in the yeast expression system from our earlier studies is used in Agrobacterium-mediated sesame transformation experiments to evaluate the biodiesel potential of transgenic sesame plants. The transgenic construct with PDAT1 and FAD3 combination yielded a 10% increase in TAG content. The possibility of transgenic sesame as a biodiesel plant is discussed.
RESUMO
Global warming alerts and threats are on the rise due to the utilization of fossil fuels. Alternative fuel sources like bio-ethanol and biodiesel are being produced to combat against these threats. Bio-ethanol can be produced from a range of substrate. The present study is aimed at the Production of bioethanol from pretreated agricultural substrate using enzymatic hydrolysis and simultaneous saccharification with the addition of purified fungal enzyme. Most cellulosic biomass is not fermentable without appropriate pretreatment methods and so dilute sulfuric acid pretreatment was applied to make the cellulose contained in the waste susceptible to endoglucanase enzyme. A range of acid pretreatment of wheat bran was made in which the sample that was pretreated with 1% dilute sulfuric acid gave maximum yield of ethanol in both methods such as 5.83 g L(-1) and 5.27 g L(-1), respectively. Ethanol produced from renewable and cheap agricultural products (wheat bran) provides reduction in green house gas emission, carbon monoxide, sulfur, and helps to eliminate smog from the environment.
