The present invention relates to extracted plant lipid, comprising fatty acids in an esterified form.

Methods of microbial screening for identifying alcohol acyltransferases for ester biosynthesis and submodules for ester pathways to produce butyryl-coenzyme A derived esters are disclosed. The method includes the introduction preselected plasmids into a respective host strain to form engineered microbes, in situ fermentation thereof followed by a colorimetric assay for quantification of production of the target ester. In situ fermentation includes inoculating each well of a microplate that have a culture media for producing target esters with one of the engineered microbes, adding an overlay of a solvent to each, and incubating the same. The colorimetric assay includes transfer of a quantity of the overlay from each well to respective clean wells of a new microplate, treatment of each well to form an iron-hydroxamic acid complex aqueous phase, centrifugation of the microplate, and measurement of the absorbance at 520 nm and comparison to a standard curve for the target ester.

Methods and compositions for producing fatty acid derivatives, for example, fatty esters, and commercial fuel compositions comprising fatty acid derivatives are described.

The present invention relates to a process for producing ethyl esters of polyunsaturated fatty acids, comprising transesterifying triacylglycerols in extracted plant lipid.

A method of directly microbially converting a plant oil, an animal fat, free fatty acid, or a combination thereof to wax esters includes growing a yeast or bacterial strain in a medium comprising the plant oil, the animal fat, the free fatty acid, or combination thereof, under conditions suitable to produce the wax esters, wherein the yeast or bacterial strain is engineered to express a FAR gene encoding fatty acid alcohol reductase and a WS gene encoding a wax ester synthase, and optionally isolating the produced wax esters. Similar methods of directly microbially converting a plant oil, an animal fat, free fatty acid, or a combination thereof to omega-3 fatty acids by growing a microorganism in a medium comprising the plant oil, the animal fat, the free fatty acid, or combination thereof, under conditions suitable to produce omega-3 fatty acids are also described.

The present invention relates to a process for producing ethyl esters of polyunsaturated fatty acids, comprising transesterifying triacylglycerols in extracted plant lipid.

The disclosure relates to mutant gene(s) that confer upon microorganisms that express them an improved capacity to utilize xylose and improved capacity to co-utilize glucose and xylose thereby resulting in improved growth of the microorganism. Further encompassed are methods of producing fatty acids and fatty acid derivatives from cellulosic biomass, xylose, and/or a glucose/xylose mix by employing the host cells expressing the engineered XylR variants and compositions of biologically produced fatty acids and fatty acid derivatives.

This invention relates to metabolically engineered microorganism strains, such as bacterial strains, in which there is an increased utilization of malonyl-CoA for production of a fatty acid or fatty acid derived product, wherein the modified microorganism produces fatty acyl-CoA intermediates via a malonyl-CoA dependent but malonyl-ACP independent mechanism.

The invention relates to the chemical synthesis of waxes. Specifically, the invention relates to systems and methods for the high-yield production of novel and high-value waxes in genetically-modified algae-based systems as a replacement for petroleum-based products.

The present invention relates to extracted plant lipid, comprising fatty acids in an esterified form.