Revision as of 13:20, 29 September 2024

crtI

Toulouse_INSA-UPS 2020contributed to the characterisation of this part by adding a new documentation learned form literature on the expression and stability of CrtI.
(--antonmykhailiuk 19:10, 08 October 2020 (UTC+2))

crtI encodes desaturase, which is able to convert phytoene into lycopene through two steps. It is the key factor in the synthesis of carotene from X. dendrorhous.

Improvement by Team Foshan-GreatBay

Group: Foshan-GreatBay iGEM 2024

New Improved Parts: BBa_K5419002 (pX-2-XdCrtE), BBa_K5419007 (pXII-5-XdCrtI), and BBa_K5419009 (pXI-2-XdCrtYB)

Existing Parts: BBa_K2407309 (CrtI), BBa_K530000 (CrtYB)

Summary

To construct Saccharomyces cerevisiae (S. cerevisiae) strain with high β-carotene production, we added new composite parts (BBa_K5419002, BBa_K5419007, and BBa_K5419009). At the same time, experimental data were also added to the existing parts (BBa_K2407309 (CrtI), BBa_K530000 (CrtYB)) that included:

• Construction of the integration plasmids coding XdCrtE, XdCrtI, and XdCrtYB, respectively.
• Integration of the genes by CRISPR/Cas9 technology into S. cerevisiae.
• Analysis of the expression levels of the genes and the testing of the combination of these genes for the production of β-carotene.

Documentation

a. Usage and Biology

In the S. cerevisiae, CrtE gene encodes GGPP synthase, in the presence of which FPP forms GGPP. The two GGPP molecules then form octahydrodicarbons via the CrtB gene-encoded octahydrodicarbon synthase. Then, octahydro lycopene dehydrogenase encoded by CrtI gene converts octahydro lycopene to lycopene. Finally, the CrtY-encoded lycopene β-cyclase will catalyze lycopene and eventually form β-carotene [1]. CrtYB gene, on the other hand, encodes a bifunctional gene that functions as both CrtB and CrtY (Figure 1). For the species origin of the genes, we chose CrtE, CrtI, and CrtYB genes from Xanthophyllomyces dendrorhous (X. dendrorhous), which are more suitable for expression in S. cerevisiae [2].

Figure 1 Construction of β-carotene biosynthesis pathway in S. cerevisiae [1].

b. Characterization/Measurement

(1) Construction Design

We constructed the plasmids by placing the genes under the regulation of a strong constitutive GAP promoter and a CYC terminator, respectively. Integration sequences were added upstream and downstream of the expression cassettes to integrate the target genes into the genome of S. cerevisiae using the CRISPR/Cas9 system (Figure 2).

Figure 2 Design diagrams of (A) pX-2-XdCrtE, (B) pXII-5-XdCrtI, and (C) pXI-2-XdCrtYB integration plasmids.

(2) Construction of integration plasmids

Firstly, we obtained the target gene expression frames (GAP promotor-gene-CYC terminator) by PCR amplification, and agarose gel electrophoresis results showed that we succeeded in obtaining these fragments. Next, we double-digested the target fragment and the vector (containing the S. cerevisiae X-2, XI-2, and XII-5 integration site genes, respectively) and obtained the plasmid by enzymatic ligation. Finally, we transformed the enzyme-ligation product into E. coli DH5α competent cells, and the colony PCR and sequencing results showed that we successfully constructed three integration plasmids (Figure 3).

Figure 3 The construction results of the (A) pX-2-XdCrtE, (B) pXII-5-XdCrtI, and (C) pXI-2-XdCrtYB integration plasmids.

(3) Integration of target genes into the yeast genome

We reserved NotI digestion sites upstream and downstream of the integration fragment, respectively. After successfully obtaining the integration plasmids, we used NotI restriction endonuclease to obtain the complete destination fragment (containing the sequence upstream of the integration site, the GAP promoter, the target gene, the CYC terminator, and the sequence downstream of the integration site). Subsequently, we recovered these integration fragments in combination with the corresponding gRNA plasmids (X-2-XII-5-gRNA-HYG and XI-2-gRNA-HYG) and introduced them into the modified S. cerevisiae 1974 strain (which had pre-integrated the Cas9 gene) by a modified lithium acetate transformation method. After two rounds of integration, we used yeast colony PCR to verify that the target fragments were successfully integrated into the yeast genome (Figure 4).

Figure 4 Construction results of yeast strain. (A) Strategy for constructing yeast strain. (B) Transformation plate and (C) colony PCR results of the yeast strain.

(4) Measurement: Quantitative analysis

We used the quantitative PCR (qPCR) technique to determine the transcript levels of target genes integrated into the yeast genome. The ACT1 gene was selected as an internal reference gene and the 2-ΔΔCt method was used to calculate the relative expression of the target gene. The primer amplification efficiency standard curves showed that this qPCR amplification has great reproducibility and accuracy (Figure 5). Subsequently, we analyzed the expression of the target genes in the recombinant yeast strains. The results showed that the expression of the target gene was increased 0.843~1.796-fold in this group compared to the control. These results confirmed that the target genes had been successfully integrated into the yeast genome and could be efficiently transcribed (Table 1).

Figure 5 Standard curves for primer amplification efficiency of (A) XdCrtE, (B) XdCrtI, and (C) XdCrtYB.

Table 1 Gene expression analysis

Contribution from other teams

==Toulouse_INSA-UPS 2020's contribution== ===''Characterisation''===

Since the CrtI (phytoene desaturase) is a part of the biosynthesis pathway of carotenoids (fig. 1), it is often co-expressed with the other enzymes of the pathway: such as CrtB or CrtY. Rabeharindranto et al. analyzed the expression of single domain CrtI, CrtY, and CrtB (fig.2). CrtB is unambiguously detected as an intense bands in all strains B, B/I or Y/B/I. On the other hand, CrtI can be observed at the expected size (67kDa) only when coexpressed with CrtY domain (strain Y/B/I). The explanation could be that CrtI protein needs to be co-expressed together with CrtY to have a normal production/stability. A faint band with 50kDa migration pattern could be observed in B/I strain which could further support the idea of low production or stability of CrtI in absence of CrtY.

[[File:K3570011-1.png|500px|thumb|center|Fig. 1: From Rabeharindranto et al. 2019. Presumed biosynthetic pathway for the synthesis of β-carotene in X. dendrorhous (Verdoes et al., 1999). The bifunctional lycopene cyclase/phytoene synthase (CrtYB) enzyme is depicted in orange, the phytoene desaturase enzyme (CrtI) is depicted in red. Orange or red boxes represent the localization of the modifications introduced by the CrtYB or CrtI enzymes respectively.]] [[File:BBa K2407309-1.png|300px|thumb|center|Fig. 2: From Rabeharindranto et al. 2019. Expression of the different constructs in crude extracts detected in western blots. For other details, please refer to [1] ]]

The second point concerns the presence of a natural fusion of CrtY (lycopene cyclase) and CrtB(phytoene synthase). Although, in eucaryotes, CrtB enzyme is predicted to be cytosolic and CrtY enzyme is predicted to be transmembrane [2], surprisingly, there is a natural fusion between CrtY and CrtB which gives CrtYB enzyme[3]. There is a strong opinion on the importance of this natural fusion on the activity of phytoene synthase [4,5]. Rabeharindranto et al. confirmed the impact of CrtY and CrtB splitting on the phytoene production as it has significantly decreased (40 times) in the B strain compared to the Y(yb)B strain (fig. 3). [[File:BBa K2407309.png|600px|thumb|center|Fig. 3: From Rabeharindranto et al. 2019. Quantification of carotenoids from the strains bearing single domains enzymes. Major carotenoids were quantified from strains expressing single domain enzymes (B, B/I, B/I/Y) and are compared to data obtained for strain Y(yb)B (left side) or Y(yb)B/I (right side). Metabolites are colored according to the legend in the right. The metabolic pathway from phytoene to carotene is depicted at the top with the same color code as previously, white squares correspond to intermediate metabolites that were not detected. Values represent the average ± S.D. of the quantification of each metabolite with three independent cultures. For other details, please refer to [1] ]] ===''References for Toulouse_INSA-UPS 2020's contribution''=== *[1]Rabeharindranto, H., Castaño-Cerezo, S., Lautier, T., Garcia-Alles, L. F., Treitz, C., Tholey, A., & Truan, G. (2019). Enzyme-fusion strategies for redirecting and improving carotenoid synthesis in S. cerevisiae. Metabolic Engineering Communications, 8, e00086. https://doi.org/10.1016/j.mec.2019.e00086 *[2]Schaub, P., Yu, Q., Gemmecker, S., Poussin-Courmontagne, P., Mailliot, J., McEwen, A.G., et al., 2012. On the structure and function of the phytoene desaturase CRTI from Pantoea ananatis, a membrane-peripheral and FAD-dependent oxidase/isomerase. PLoS One 7, e39550. http://dx.doi.org/10.1371/journal.pone.0039550 *[3]Verdoes, J.C., Krubasik, P., Sandmann, G., Van Ooyen, A.J.J., 1999. Isolation and functional characterisation of a novel type of carotenoid biosynthetic gene from Xanthophyllomyces dendrorhous. Mol. Gen. Genet. MGG 262, 453–461. *[4]Niklitschek, M., Alcaíno, J., Barahona, S., Sepúlveda, D., Lozano, C., Carmona, M., et al., 2008. Genomic organization of the structural genes controlling the astaxanthin biosynthesis pathway of Xanthophyllomyces dendrorhous. Biol. Res. 41, 93–108. http://dx.doi.org/10.4067/S0716-97602008000100011. *[5]Xie, W., Lv, X., Ye, L., Zhou, P., Yu, H., 2015a. Construction of lycopene-overproducing Saccharomyces cerevisiae by combining directed evolution and metabolic engineering. Metab. Eng. 30, 69–78. http://dx.doi.org/10.1016/j.ymben.2015.04.009. Sequence and Features BBa_K2407309 SequenceAndFeatures