Pamela L. Sharpe

Production of omega-3 eicosapentaenoic acid by metabolic engineering of Yarrowia lipolytica

The availability of the omega-3 fatty acids eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA) is currently limited because they are produced mainly by marine fisheries that cannot keep pace with the demands of the growing market for these products. A sustainable non-animal source of EPA and DHA is needed. Metabolic engineering of the oleaginous yeast Yarrowia lipolytica resulted in a strain that produced EPA at 15% of dry cell weight. The engineered yeast lipid comprises EPA at 56.6% and saturated fatty acids at less than 5% by weight, which are the highest and the lowest percentages, respectively, among known EPA sources. Inactivation of the peroxisome biogenesis gene PEX10 was crucial in obtaining high EPA yields and may increase the yields of other commercially desirable lipid-related products. This technology platform enables the production of lipids with tailored fatty acid compositions and provides a sustainable source of EPA.

Expression of bacterial hemoglobin genes to improve astaxanthin production in a methanotrophic bacterium Methylomonas sp.

Astaxanthin has been widely used as a feed supplement in poultry and aquaculture industries. One challenge for astaxanthin production in bacteria is the low percentage of astaxanthin in the total carotenoids. An obligate methanotrophic bacterium Methylomonas sp. 16a was engineered to produce astaxanthin. Astaxanthin production appeared to be dramatically affected by oxygen availability. We examined whether astaxanthin production in Methylomonas could be improved by metabolic engineering through expression of bacterial hemoglobins. Three hemoglobin genes were identified in the genome of Methylomonas sp. 16a. Two of them, thbN1 and thbN2, belong to the family of group I truncated hemoglobins. The third one, thbO, belongs to the group II truncated hemoglobins. Heterologous expression of the truncated hemoglobins in Escherichia coli improved cell growth under microaerobic conditions by increasing final cell densities. Co-expression of the hemoglobin genes along with the crtWZ genes encoding astaxanthin synthesis enzymes in Methylomonas showed higher astaxanthin production than expression of the crtWZ genes alone on multicopy plasmids. The hemoglobins likely improved the activity of the oxygen-requiring CrtWZ enzymes for astaxanthin conversion. A plasmid-free production strain was constructed by integrating the thbN1–crtWZ cassette into the chromosome of an astaxanthin-producing Methylomonas strain. It showed higher astaxanthin production than the parent strain.

Use of Transposon Promoter-Probe Vectors in the Metabolic Engineering of the Obligate Methanotroph Methylomonas sp. Strain 16a for Enhanced C40 Carotenoid Synthesis

ABSTRACT The recent expansion of genetic and genomic tools for metabolic engineering has accelerated the development of microorganisms for the industrial production of desired compounds. We have used transposable elements to identify chromosomal locations in the obligate methanotroph Methylomonas sp. strain 16a that support high-level expression of genes involved in the synthesis of the C40 carotenoids canthaxanthin and astaxanthin. with three promoterless carotenoid transposons, five chromosomal locations—the fliCS, hsdM, ccp-3, cysH, and nirS regions—were identified. Total carotenoid synthesis increased 10- to 20-fold when the carotenoid gene clusters were inserted at these chromosomal locations compared to when the same carotenoid gene clusters were integrated at neutral locations under the control of the promoter for the gene conferring resistance to chloramphenicol. A chromosomal integration system based on sucrose lethality was used to make targeted gene deletions or site-specific integration of the carotenoid gene cluster into the Methylomonas genome without leaving genetic scars in the chromosome from the antibiotic resistance genes that are present on the integration vector. The genetic approaches described in this work demonstrate how metabolic engineering of microorganisms, including the less-studied environmental isolates, can be greatly enhanced by identifying integration sites within the chromosome of the host that permit optimal expression of the target genes.

Bioengineering of Oleaginous Yeast Yarrowia lipolytica for Lycopene Production

Oleaginous yeast Yarrowia lipolytica is capable of accumulating large amount of lipids. There is a growing interest to engineer this organism to produce lipid-derived compounds for a variety of applications. In addition, biosynthesis of value-added products such as carotenoid and its derivatives have been explored. In this chapter, we describe methods to integrate genes involved in lycopene biosynthesis in Yarrowia. Each bacterial gene involved in lycopene biosynthesis, crtE, crtB, and crtI, will be assembled with yeast promoters and terminators and subsequently transformed into Yarrowia through random integration. The engineered strain can produce lycopene under lipid accumulation conditions.

Construction and Utilization of Carotenoid Reporter Systems: Identification of Chromosomal Integration Sites That Support Suitable Expression of Biosynthetic Genes and Pathways

In order to metabolically engineer microorganisms to produce compounds of interest, it is often desirable to integrate foreign genes into the chromosome of the host. However, the consequences of these genetic alterations are not always predictable. The use of a reporter system can often assist in determining chromosomal locations for optimal expression of foreign biosynthetic genes. The method described here involves the construction and utilization of promoterless carotenoid transposons, which provides a colorimetric screen for identifying the best chromosomal integration sites for the expression of the genes of interest. The transposons (pUTmTn5::392W and pUTmTn5::392) contain the carotenoid genes required for the production of canthaxanthin and astaxanthin, respectively. Thus, when promoterless transposons insert into the hosts genome, the color of the colonies will vary based on their chromosomal location. There is a correlation between the color intensity of the colonies and the expression of the carotenoid transposon. The transposon insertion site can be determined via direct chromosomal sequencing. This sequence information is used to guide the site-specific integration of biosynthetic genes and pathways of interest.