| [1] |
Tetali SD. 2019. Terpenes and isoprenoids: a wealth of compounds for global use. |
| [2] |
Maaz M, Sultan MT, Khalid MU, Raza H, Imran M, et al. 2025. A comprehensive review on the molecular mechanism of lycopene in cancer therapy. |
| [3] |
López-Solís R, Castro-Barquero S, Donat-Vargas C, Corrado M, Arancibia-Riveros C, et al. 2025. Lycopene intake and prostate cancer risk in men at high cardiovascular risk: a prospective cohort study. |
| [4] |
Moran NE, Thomas-Ahner JM, Wan L, Zuniga KE, Erdman JW, et al. 2022. Tomatoes, lycopene, and prostate cancer: what have we learned from experimental models? |
| [5] |
Sharifi-Zahabi E, Soltani S, Malekahmadi M, Rezavand L, Clark CCT, et al. 2022. The effect of lycopene supplement from different sources on prostate specific antigen (PSA): a systematic review and meta-analysis of randomized controlled trials. |
| [6] |
Kulawik A, Cielecka-Piontek J, Zalewski P. 2023. The importance of antioxidant activity for the health-promoting effect of lycopene. |
| [7] |
Khan UM, Sevindik M, Zarrabi A, Nami M, Ozdemir B, et al. 2021. Lycopene: food sources, biological activities, and human health benefits. |
| [8] |
Li L, Liu Z, Jiang H, Mao X. 2020. Biotechnological production of lycopene by microorganisms. |
| [9] |
Nie X, Zuo Z, Zhou L, Gao Z, Cheng L, et al. 2024. Investigating the effect of high-voltage electrostatic field (HVEF) treatment on the physicochemical characteristics, bioactive substances content, and shelf life of tomatoes. |
| [10] |
Moroz P, Bartusiak A, Niewiadomska J, Szymański K, Janek T, et al. 2025. Advances in lycopene production: from natural sources to microbial synthesis using Yarrowia lipolytica. |
| [11] |
Li M, Xia Q, Zhang H, Zhang R, Yang J. 2020. Metabolic engineering of different microbial hosts for lycopene production. |
| [12] |
Ren J, Shen J, Thai TD, Kim MG, Lee SH, et al. 2023. Evaluation of various Escherichia coli strains for enhanced lycopene production. |
| [13] |
Boghigian BA, Salas D, Ajikumar PK, Stephanopoulos G, Pfeifer BA. 2012. Analysis of heterologous taxadiene production in K- and B-derived Escherichia coli. |
| [14] |
Yoon SH, Lee SH, Das A, Ryu HK, Jang HJ, et al. 2009. Combinatorial expression of bacterial whole mevalonate pathway for the production of β-carotene in E. coli. |
| [15] |
Liang Z, Zhi H, Fang Z, Zhang P. 2021. Genetic engineering of yeast, filamentous fungi and bacteria for terpene production and applications in food industry. |
| [16] |
Banerjee A, Wu Y, Banerjee R, Li Y, Yan H, et al. 2013. Feedback inhibition of deoxy-D-xylulose-5-phosphate synthase regulates the methylerythritol 4-phosphate pathway. |
| [17] |
Hu B, Zhou J, Li J, Chen J, Du G, et al. 2025. Efficient biosynthesis of furanocoumarin intermediate marmesin by engineered Escherichia coli. |
| [18] |
Li Y, Wang G. 2016. Strategies of isoprenoids production in engineered bacteria. |
| [19] |
Raghavan I, Juman R, Wang ZQ. 2024. The non-mevalonate pathway requires a delicate balance of intermediates to maximize terpene production. |
| [20] |
Rehman E, Hawaibam BS, Nguyen MP, Wang C, Yoon SH, et al. 2025. Enhancing lycopene production in Bacillus subtilis by overcoming a critical enzymatic bottleneck. |
| [21] |
Ajikumar PK, Xiao WH, Tyo KEJ, Wang Y, Simeon F, et al. 2010. Isoprenoid pathway optimization for taxol precursor overproduction in Escherichia coli. |
| [22] |
Perez-Gil J, Behrendorff J, Douw A, Vickers CE. 2024. The methylerythritol phosphate pathway as an oxidative stress sense and response system. |
| [23] |
Liu CL, Dong HG, Xue K, Sun L, Yang Y, et al. 2022. Metabolic engineering mevalonate pathway mediated by RNA scaffolds for mevalonate and isoprene production in Escherichia coli. |
| [24] |
Wang Y, Yu J, Zhang H, Xu M, Liu Q, et al. 2025. Shaping up a mevalonate pathway in the E. coli–E. coli coculture system for the production of sesquiterpenes. |
| [25] |
Li M, Chen H, Liu C, Guo J, Xu X, et al. 2019. Improvement of isoprene production in Escherichia coli by rational optimization of RBSs and key enzymes screening. |
| [26] |
Yang L, Wang C, Zhou J, Kim SW. 2016. Combinatorial engineering of hybrid mevalonate pathways in Escherichia coli for protoilludene production. |
| [27] |
Zhu X, Wu Y, Lv X, Liu Y, Du G, et al. 2022. Combining CRISPR–Cpf1 and recombineering facilitates fast and efficient genome editing in Escherichia coli. |
| [28] |
Hussain MH, Hong Q, Zaman WQ, Mohsin A, Wei Y, et al. 2021. Rationally optimized generation of integrated Escherichia coli with stable and high yield lycopene biosynthesis from heterologous mevalonate (MVA) and lycopene expression pathways. |
| [29] |
Wei Y, Mohsin A, Hong Q, Guo M, Fang H. 2018. Enhanced production of biosynthesized lycopene via heterogenous MVA pathway based on chromosomal multiple position integration strategy plus plasmid systems in Escherichia coli. |
| [30] |
Yoon SH, Lee YM, Kim JE, Lee SH, Lee JH, et al. 2006. Enhanced lycopene production in Escherichia coli engineered to synthesize isopentenyl diphosphate and dimethylallyl diphosphate from mevalonate. |
| [31] |
Yang C, Gao X, Jiang Y, Sun B, Gao F, et al. 2016. Synergy between methylerythritol phosphate pathway and mevalonate pathway for isoprene production in Escherichia coli. |
| [32] |
Rinaldi MA, Ferraz CA, Scrutton NS. 2022. Alternative metabolic pathways and strategies to high-titre terpenoid production in Escherichia coli. |
| [33] |
Niu FX, Lu Q, Bu YF, Liu JZ. 2017. Metabolic engineering for the microbial production of isoprenoids: carotenoids and isoprenoid-based biofuels. |
| [34] |
Liu N, Liu B, Wang G, Soong YV, Tao Y, et al. 2020. Lycopene production from glucose, fatty acid and waste cooking oil by metabolically engineered Escherichia coli. |
| [35] |
Tan JC, Hu Q, Scrutton NS. 2024. A growth-coupling strategy for improving the stability of terpenoid bioproduction in Escherichia coli. |