Li B, Sun C, Li J. et al. Targeted genome-modification tools and their advanced applications in crop breeding. Nat Rev Genet. 2024; 25:603-22

Ma Z, Ma L, Zhou J. Applications of CRISPR/Cas genome editing in economically important fruit crops: recent advances and future directions. Mol Hortic. 2023; 3:1

Vondracek K, Altpeter F, Liu T. et al. Advances in genomics and genome editing for improving strawberry (Fragaria ×ananassa). Front Genet. 2024; 15:1382445

Zhang J, Lyu H, Chen J. et al. Releasing a sugar brake generates sweeter tomato without yield penalty. Nature. 2024; 635:647-56

Nonaka S, Arai C, Takayama M. et al. Efficient increase of γ-aminobutyric acid (GABA) content in tomato fruits by targeted mutagenesis. Sci Rep. 2017; 7:7057

Romero PA, Arnold FH. Exploring protein fitness landscapes by directed evolution. Nat Rev Mol Cell Biol. 2009; 10:866-76

Xu JJ, Lei Y, Zhang XF. et al. Design of CoQ10 crops based on evolutionary history. Cell. 2025; 188:1941-54.e15

Molina RS, Rix G, Mengiste AA. et al. In vivo hypermutation and continuous evolution. Nat Rev Methods Primers. 2022; 2:36

Ravikumar A, Arzumanyan GA, Obadi MKA. et al. Scalable, con-tinuous evolution of genes at mutation rates above genomic error thresholds. Cell. 2018; 75:1946-57.e13

Gionfriddo M, De Gara L, Loreto F. Directed evolution of plant processes: towards a green (r)evolution. Trends Plant Sci. 2019; 24: 999-1007

Oliveira-Filho ER, Voiniciuc C, Hanson AD. Adapting enzymes to improve their functionality in plants: why and how. Biochem Soc Trans. 2023; 51:1957-66

Gionfriddo M, Rhodes T, Whitney SM. Perspectives on improving crop rubisco by directed evolution. Semin Cell Dev Biol. 2024; 155: 37-47

Liu X, Zhang P, Zhao Q. et al. Making small molecules in plants: a chassis for synthetic biology-based production of plant natural products. J Integr Plant Biol. 2023; 65:417-43

Kababji AM, Butt H, Mahfouz M. Synthetic directed evolu-tion for targeted engineering of plant traits. Front Plant Sci. 2024; 15:1449579

Cheng GW, Breen PJ. Activity of phenylalanine ammonia-lyase (PAL) and concentrations of anthocyanins and phenolics in developing strawberry fruit. JAmSoHorticSci. 1991; 116:865-9

Li G, Wang H, Cheng X. et al. Comparative genomic analysis of the PAL genes in five Rosaceae species and functional identification of Chinese white pear. PeerJ. 2019; 7:e8064

Singh S, Chaudhary R, Lokya V. et al. Genome editing based trait improvement in crops: current perspective, challenges and opportunities. Nucleus. 2024; 67:97-126

Rix G, Williams RL, Hu VJ. et al. Continuous evolution of user-defined genes at 1 million times the genomic mutation rate. Science. 2024;386:eadm9073

Wurtzel ET, Vickers CE, Hanson AD. et al. Revolutionizing agri-culture with synthetic biology. Nat Plants. 2019; 5:1207-10

Silver PA, Way JC, Arnold FH. et al. Engineering explored. Nature. 2014; 509:166-7

Arnold FH. Engineering explored. Angew Chem Int Ed. 2019; 58:14420-6

Rix G, Liu CC. Systems for in vivo hypermutation: a quest for scale and depth in directed evolution. Curr Opin Chem Biol. 2021; 64:20-6

García-García JD, Van Gelder K, Joshi J. et al. Using continuous directed evolution to improve enzymes for plant applications. Plant Physiol. 2022; 188:971-83

Cai C, Shen J, Chen L. et al. Content, composition, and biosyn-thesis of anthocyanin in Fragaria species: a review. HortScience. 2023; 58:988-95

Ring L, Yeh SY, Hücherig S. et al. Metabolic interaction between anthocyanin and lignin biosynthesis is associated with per-oxidase FaPRX27 in strawberry fruit. Plant Physiol. 2013; 163: 43-60

Barros J, Dixon RA. Plant phenylalanine/tyrosine ammonia-lyases. Trends Plant Sci. 2020; 25:66-79

Montero T, Mollá E, Martín-Cabrejas MA. et al. Effects of gibberel-lic acid (GA3) on strawberry PAL (phenylalanine ammonia-lyase) and TAL (tyrosine ammonia-lyase) enzyme activities. J Sci Food Agric. 1998; 77:230-4

Cao S, Hu Z, Zheng Y. et al. Effect of BTH on anthocyanin content and activities of related enzymes in strawberry after harvest. J Agric Food Chem. 2010; 58:5801-5

Nishiyama Y, Yun CS, Matsuda F. et al. Expression of bacterial tyrosine ammonia-lyase creates a novel p-coumaric acid path-way in the biosynthesis of phenylpropanoids in Arabidopsis. Planta. 2010; 232:209-18

Amthor JS. Efficiency of lignin biosynthesis: a quantitative anal-ysis. Ann Bot. 2003; 91:673-95

Watts KT, Mijts BN, Lee PC. et al. Discovery of a substrate selectivity switch in tyrosine ammonia-lyase, a member of the aromatic amino acid lyase family. Chem Biol. 2006; 13:1317-26

Barros J, Serrani-Yarce JC, Chen F. et al. Role of bifunctional ammonia-lyase in grass cell wall biosynthesis. Nat Plants. 2016; 2: 1-9

Zhang J, Wang X, Yu O. et al. Metabolic profiling of strawberry (Fragaria × ananassa Duch.) during fruit development and mat-uration. JExp Bot. 2011; 62:1103-18

Min K, Yi G, Lee JG. et al. Comparative transcriptome and metabolome analyses of two strawberry cultivars with different storability. PLoS One. 2020; 15:e0242556

Yokoyama R, de Oliveira MVV, Kleven B. et al. The entry reaction of the plant shikimate pathway is subjected to highly complex metabolite-mediated regulation. Plant Cell. 2021; 33:671-96

El-Azaz J, Moore B, Takeda-Kimura Y. et al. Coordinated reg-ulation of the entry and exit steps of aromatic amino acid biosynthesis supports the dual lignin pathway in grasses. Nat Commun. 2023; 14:7242

Fan Z, Whitaker VM. Genomic signatures of strawberry domes-tication and diversification. Plant Cell. 2024; 36:1622-36

Sánchez-Sevilla JF, Vallarino JG, Osorio S. et al. Gene expression atlas of fruit ripening and transcriptome assembly from RNA-seq data in octoploid strawberry (Fragaria × ananassa). Sci Rep. 2017; 7:13737

Lutz S. Beyond directed evolution - semi-rational protein engi-neering and design. Curr Opin Biotechnol. 2010; 21:734-43

Takeda-Kimura Y, Moore B, Holden S. et al. Genomes of Poaceae sisters reveal key metabolic innovations preceding the emer-gence of grasses. bioRxiv. 2024;2024-11

Packer MS, Liu DR. Methods for the directed evolution of pro-teins. Nat Rev Genet. 2015; 16:379-94

Xiao H, Bao Z, Zhao H. High throughput screening and selec-tion methods for directed enzyme evolution. Ind Eng Chem Res. 2015; 54:4011-20

Zhong Z, Ravikumar A, Liu CC. Tunable expression systems for orthogonal DNA replication. ACS Synth Biol. 2018; 7:2930-4

Wu S, Xiang C, Zhou Y. et al. A growth selection system for the directed evolution of amine-forming or converting enzymes. Nat Commun. 2022; 13:7458

Urrestarazu A, Vissers S, Iraqui I. et al. Phenylalanine-and tyrosine-auxotrophic mutants of Saccharomyces cerevisiae impaired in transamination. Mol Gen Genet. 1998; 257:230-7

Zhou S, Liu P, Chen J. et al. Characterization of mutants of a tyrosine ammonia-lyase from Rhodotorula glutinis. Appl Microbiol Biotechnol. 2016; 100:10443-52

Van Gelder K, Gayen AK, Hanson AD. Mirages in continuous directed enzyme evolution: a cautionary case study with plan-tized bacterial THI4 enzymes. Plant Biotechnol J. 2025; 23:1070-2

Zong Y, Liu Y, Xue C. et al. An engineered prime editor with enhanced editing efficiency in plants. Nat Biotechnol. 2022; 40: 1394-402

Kummari D, Palakolanu SR, Kishor PK. et al. An update and per-spectives on the use of promoters in plant genetic engineering. J Biosci. 2020; 45:1-24

Smirnova OG, Kochetov AV. Choice of the promoter for tis-sue and developmental stage-specific gene expression. Biolis-tic DNA delivery in plants: Methods and Protocols. 2020; 2124: 69-106

Whitaker VM, Hasing T, Chandler CK. et al. Historical trends in strawberry fruit quality revealed by a trial of University of Florida cultivars and advanced selections. HortScience. 2011; 46: 553-7

Kelly K, Nunes C, Whitaker VM. A comparison of physical and chemical attributes of strawberry cultivars and advanced breed-ing selections from the University of Florida. Proc Fla State Hort Soc. 2016; 129:185-9

Castillejo C, Waurich V, Wagner H. et al. Allelic variation of MYB10 is the major force controlling natural variation in skin and flesh color in strawberry (Fragaria spp.) fruit. Plant Cell. 2020; 32:3723-49

Bansal P, Kaur N. Assessing risks associated with large-scale adoption of CRISPR gene-edited crops. J Crop Sci Biotechnol. 2025; 28:155-65

Leong BJ, Hanson AD. Continuous directed evolution of a feedback-resistant Arabidopsis arogenate dehydratase in plan-tized Escherichia coli. ACS Synth Biol. 2023; 12:43-50

Qian H, Shi H. Herbicide-resistant 4-hydroxyphenylpyruvate dioxygenase variants identified via directed evolution. JExp Bot. 2024; 75:7096-106

Engqvist MKM, Rabe KS. Applications of protein engineering and directed evolution in plant research. Plant Physiol. 2019; 179: 907-17

Irfan M, Chavez B, Rizzo P. et al. Evolution-aided engineering of plant specialized metabolism. aBIOTECH. 2021; 2:240-63

Mou Z, Zhao D. Gene rational design: the dawn of crop breeding. Trends Plant Sci. 2022; 27:633-6

Rao GS, Jiang W, Mahfouz M. Synthetic directed evolution in plants: unlocking trait engineering and improvement. Synth Biol (Oxf). 2021;6:ysab025

Hanson AD, Lorenzo V. Synthetic biology—high time to deliver? ACS Synth Biol. 2023; 12:1579-82

Khaipho-Burch M, Cooper M, Crossa J. et al. Genetic modifica-tion can improve crop yields—but stop overselling it. Nature. 2023; 621:470-3