folA thyA knockout E. coli as a suitable surrogate model for evaluation of antifolate sensitivity against PfDHFR-TS.

A new superior bacteria complementation model was achieved for testing antifolate compounds and investigating antifolate resistance in the dihydrofolate reductase (DHFR) enzyme of the malaria parasite. Earlier models depended on the addition of trimethoprim (TMP) to chemically suppress the host Escherichia coli (Ec) DHFR function. However, incomplete suppression of EcDHFR and potential interference of antibiotics needed to maintain plasmids for complementary gene expression can complicate the interpretations. To overcome such limitations, the folA (F) and thyA (T) genes were genetically knocked out (Δ) in E. coli BL21(DE3). The resulting EcΔFΔT cells were thymidine auxotroph where thymidine supplementation or functional complementation with heterologous DHFR-thymidylate synthase (TS) is needed to restore the loss of gene functions. When tested against pyrimethamine (PYR) and its analogs designed to target Plasmodium falciparum (Pf) DHFR-TS, the 50 % inhibitory concentration values obtained from EcΔFΔT surrogates expressing wildtype (PfTM4) or double mutant (PfK1) DHFR-TS showed strong correlations to the results obtained from the standard in vitro P. falciparum growth inhibition assay. Interestingly, while TMP had little effect on the susceptibility to PYR and analogs in EcΔFΔT expressing PfDHFR-TS, it hypersensitized the chemically knockdown E. coli BL21(DE3) expressing PfTM4 DHFR-TS but desensitized the one carrying PfK1 DHFR-TS. The low intrinsic expression level of PfTM4 in E. coli BL21(DE3) by western blot analysis may explain the hypersensitive to antifolates of chemical knockdown bacteria surrogate. These results demonstrated the usefulness of EcΔFΔT surrogate as a new tool for antifolate antimalarial screening with potential application for investigation of antifolate resistance mechanism.

Metabolic Engineering of Saccharomyces cerevisiae for Production of Canthaxanthin, Zeaxanthin, and Astaxanthin.

The sustainable production of natural compounds is increasingly important in today's industrial landscape. This study investigates the metabolic engineering of Saccharomyces cerevisiae for the efficient biosynthesis of valuable carotenoids: canthaxanthin, zeaxanthin, and astaxanthin. Utilizing a tailored parental yeast strain, Sp_Bc, we optimized the carotenoid pathway by screening and identifying CrtW and CrtZ enzymatic variants. The CrtW variant from Bradyrhizobium sp. achieved a canthaxanthin titer of 425.1 ± 69.1 µg/L, while the CrtZ variant from Pantoea ananatis achieved a zeaxanthin titer of 70.5 ± 10.8 µg/L. Additionally, we optimized carotenoid production by exploring enzyme fusion strategies for all three studied carotenoids and organelle compartmentalization specifically for enhancing astaxanthin synthesis. We further improved carotenoid production by integrating the optimal gene constructs into the yeast genome and deleting the GAL80 gene, enabling the use of sucrose as a carbon source. The engineered strain Sp_Bc-Can001 ∆gal80 was evaluated in a 5 L bioreactor fermentation, achieving a notable canthaxanthin titer of 60.36 ± 1.51 mg/L using sucrose. This research conclusively establishes S. cerevisiae as a viable platform for efficient carotenoid biosynthesis and, for the first time in this yeast system, illustrates sucrose's viability as a carbon source for canthaxanthin production. These findings pave the way for sustainable, cost-effective carotenoid production at an industrial scale.