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Bettoni, JC, Wang MR, Wang, QC. 2024. In vitro regeneration, micropropagation and germplasm conservation of horticultural plants. Horticulturae 10:45

Megia R, Haïcour R, Rossignol L, Sihachakr, D. 1992. Callus formation from cultured protoplasts of banana (Musa sp.). Plant Science 85:91−98

Martanti D, Handayani T, Talahatu JC, Azizi AAA, Pantouw CF, et al. 2024. Improved callus induction from immature seed of Indonesian wild banana (Musa acuminata ssp. malaccensis and rutilifes) for gene editing materials. BIO Web of Conferences 127:01010

Uddin MM, Goswami B, Uddin N, Hossain S, Islam M, et al. 2025. In vitro regeneration of exotic kiwi fruit (Actinidia deliciosa) in Bangladesh. Plant Tissue Culture and Biotechnology 35:33−40

Hriban T, Stănică F. 2024. In vitro culture of kiwifruit species (Actinidia sp.)—a review. Scientia Papers Series B Horticulture 68:93−97

Dibbisa Itana D, Yusuf Habib Z. 2022. In vitro micropropagation of apple (Malus domestica) through axillary buds and shoot apices culture. International Journal of Zoology and Applied Biosciences 7:1−7

Wada M, Nishitani C, Komori S. 2020. Stable and efficient transformation of apple. Plant Biotechnology 37:163−170

Khan EU, Fu XZ, Wang J, Fan QJ, Huang XS, et al. 2009. Regeneration and characterization of plants derived from leaf in vitro culture of two sweet orange (Citrus sinensis [L.] Osbeck) cultivars. Scientia Horticulturae 120:70−76

Abdi F, Yusuf Z, Petros Y, Desta M. 2023. Optimization of hormonal compositions of media in in vitro propagation of orange cultivars from shoot tip nodal segments. International Journal of Agronomy 2023:3581881

Thakur M, Sharma V, Luharch R. 2021. Propagation of plum (Prunus salicina L.) cultivar Frontier in vitro through control of shoot tip necrosis (STN) and validation of genetic integrity using ISSR markers. Plant Physiology Reports 26:238−246

Shi Q, Liu P, Wang J, Xu J, Ning Q, et al. 2015. A novel in vivo shoot regeneration system via callus in woody fruit tree Chinese jujube (Ziziphus jujuba Mill.). Scientia Horticulturae 188:30−35

Malabadi RB, Chalannavar RK, Kolkar KP. 2025. Plant cell totipotency: Plant tissue culture applications-an updated review. World Journal of Advanced Engineering Technology and Sciences 16:112−135

Quiroz LF, Khan M, Gondalia N, Lai L, McKeown PC, et al. 2025. Tissue culture-independent approaches to revolutionizing plant transformation and gene editing. Horticulture Research 12:uhae292

Yan C, Su C, Liu X. 2016. A breeding method for inducing polyploids from field-derived callus in Ziziphus jujuba Mill. cv. Huizao. Xinjiang Agricultural Reclamation Science and Technology 39:35−37 (in Chinese)

Stobbe H, Schmitt U, Eckstein D, Dujesiefken D. 2002. Developmental stages and fine structure of surface callus formed after debarking of living lime trees (Tilia sp.). Annals of Botany 89:773−782

Niu J, Luo X, Chen LN, Li HX, Liu BB, et al. 2018. Establishment of a callus induction and bud regeneration system for pomegranate in the field. Journal of Fruit Science 35:1225−1234 (in Chinese)

Jiang Y. 2023. Polyploid induction of grape under field and tissue culture conditions. Master's Thesis. Hebei Science and Technology Normal University, Qinhuangdao, China. pp. 17 (in Chinese) doi: 10.27741/d.cnki.ghbkj.2023.000229

Shi QH, Liu P, Liu MJ, Wang JR, Xu J. 2015. A novel method for rapid in vivo induction of homogeneous polyploids via calluses in a woody fruit tree (Ziziphus jujuba Mill.). Plant Cell Tissue and Organ Culture 121:423−433

Zhang H, Teng K, Zang H. 2023. Actinidia arguta (Sieb. et Zucc.) Planch. ex Miq.: a review of phytochemistry and pharmacology. Molecules 28:7820

Chen L, Song HF, Liu JX, Jiang XX, Ai J, et al. 2024. Genome-wide identification and expression profiling of the SWEET family in Actinidia polygama (Sieb. & Zucc.) Maxim. Fruit Research 4:e0041

He Y, Qin H, Wen J, Wang L, Cao W, et al. 2024. Characterization of amino acid composition, nutritional value, and taste of fruits from different Actinidia arguta resources. Journal of Food Quality 2024:1005194

Nishiyama I. 2007. Fruits of the Actinidia genus. Advances in Food and Nutrition Research 52:293−324

Latocha P. 2017. The nutritional and health benefits of kiwiberry (Actinidia arguta) – a review. Plant Foods for Human Nutrition 72:325−334

Česonienė L, Januškevičė V, Saunoriūtė S, Liaudanskas M, Žvikas V, et al. 2024. Phenolic compounds in berries of winter-resistant Actinidia arguta Miq. and Actinidia kolomikta Maxim.: evidence of antioxidative activity. Antioxidants 13:372

Li C. 2014. Application of in plant callus induction and bud regeneration system in Chinese jujube. Master's Thesis Dissertation. Hebei Agricultural University, Baoding, China. pp. 22 (in Chinese)

Shi Q, Liu P, Liu M, Wang J, Zhao J, Zhao Z. et al. 2016. In vivo fast induction of homogeneous autopolyploids via callus in sour jujube (Ziziphus acidojujuba Cheng et Liu). Horticultural Plant Journal 2:147−153

Ren C, Mohamed MSM, Aini N, Kuang Y, Liang, Z. 2024. CRISPR/Cas in grapevine genome editing: the best is yet to come. Horticulturae 10:965

Alam T. 2025. Advances in tissue culture-free genetic engineering and genome editing of peanut. Molecular Biotechnology

Singh SK, Pradhan S, Sankaran M, Jha AK, Kowsalya KB, et al. 2025. Fast-track breeding strategies for targeted genotype development in fruit crops. In Advances in Agri-Food Systems, eds. Pathak H, Lakra WS, Gopalakrishnan A, Bansal KC. Singapore: Springer. pp. 1–14 doi: 10.1007/978-981-96-0763-1_1

Cookson SJ, Clemente Moreno MJ, Hevin C, Nyamba Mendome LZ, Delrot S, Trossat-Magnin C, et al. 2013. Graft union formation in grapevine induces transcriptional changes related to cell wall modification, wounding, hormone signalling, and secondary metabolism. Journal of Experimental Botany 64:2997−3008

Loupit G, Valls Fonayet J, Tran J, Garcia V, Hummel I, et al. 2025. Graft union formation involves interactions among bud signals, carbon availability, dormancy release, wound responses and non-self-communication in grapevine. The Plant Journal 122:e70244

Sang YL, Cheng ZJ, Zhang XS. 2018. Plant stem cells and de novo organogenesis. New Phytologist 218:1334−1339

Li Y, Jiang Q, Cha L, Lin F, Tang F, et al. 2025. Highly efficient regeneration of Bombax ceiba via de novo organogenesis from hypocotyl and bud explants. Plants 14:2033

Bennur PL, O’Brien M, Fernando SC, Doblin MS. 2025. Genotype-independent de novo regeneration protocol in Cannabis sativa L. through direct organogenesis from cotyledonary nodes. Plant Methods 21:145

Yao W, Kong L, Lei D, Zhao B, Tang H, et al. 2023. An effective method for establishing a regeneration and genetic transformation system for Actinidia arguta. Frontiers in Plant Science 14:1204267

Guo HH, Lin CF, Jiang YB, Xu SX. 2024. Study of in vitro regeneration technology for Actinidia arguta Qiyimei No. 6. South China Fruits 53:169−175 (in Chinese)

Wang DP. 2007. Effects of different concentrations of hormone combinations on callus induction and bud differentiation in kiwifruit. Anhui Agricultural Science 36:11761, 11821 (in Chinese)

Wang GF. 2017. Anther culture and establishment of regeneration system for Actinidia arguta. Master's Thesis. Chinese Academy of Agricultural Sciences, Beijing, China. pp. 30 (in Chinese)

Zheng XH. 2008. Studies on in vitro culture of stems and leaves and plant regeneration in Actinidia arguta. Master's Thesis. Sichuan Agricultural University, Ya'an, China. pp. 32 (in Chinese)

Liu Z, Yang DJ, Qu M, Wang DP, Sun YM, et al. 2021. Different growth hormone concentrations on induction and differentiation influence of Actinidia arguta leaves. Horticulture and Seed 41:6−9 (in Chinese)

Carbajal EM, Milla-Lewis SR. 2026. Influence of auxin and cytokinin concentrations on callus induction, subculture growth, and somatic embryogenesis for plant regeneration in zoysiagrass (Zoysia spp.). Grass Research 6:e001

Ashouri N, Daylami SD, Karimi S. 2025. From callus to plantlet: unveiling the optimal hormonal synergy and sucrose supplementation for Zamioculcas zamiifolia micropropagation. Ornamental Horticulture 31:e312953

Long Y, Yang Y, Pan G, Shen Y. 2022. New insights into tissue culture plant-regeneration mechanisms. Frontiers in Plant Science 13:926752

Omary M, Matosevich R, Efroni I. 2023. Systemic control of plant regeneration and wound repair. New Phytologist 237:408−413

Samarina L, Malyukova L, Wang S, Bobrovskikh A, Doroshkov A, et al. 2024. In vitro vs. in vivo transcriptomic approach revealed core pathways of nitrogen deficiency response in tea plant (Camellia sinensis [L.] Kuntze). International Journal of Molecular Sciences 25:11726

Park SY, Shin KS, Paek KY. 2006. Increased ethylene and decreased phenolic compounds stimulate somatic embryo regeneration in leaf thin section cultures of Doritaenopsis hybrid. Journal of Plant Biology 49:358−363

Chalker-Scott L, Fuchigami LH. 1989. The role of phenolic compounds in plant stress responses. In Low Temperature Stress Physiology in Crops, ed. Li PH. 1^st Edition. Boca Raton, FL, USA: CRC Press. 211 pp. doi: 10.1201/9781351074186

Huh YS, Lee JK, Nam SY. 2017. Effect of plant growth regulators and antioxidants on in vitro plant regeneration and callus induction from leaf explants of purple passion fruit (Passiflora edulis Sims). Journal of Plant Biotechnology 44:335−342

Sgamma T, Thomas B, Muleo R. 2015. Ethylene inhibitor silver nitrate enhances regeneration and genetic transformation of Prunus avium (L.) cv Stella. Plant Cell, Tissue and Organ Culture 120:79−88

Zarei S, Ehsanpour AA. 2023. Ethylene inhibition with silver nitrate (AgNO₃) and pyrazinamide (PZA) ameliorates in vitro salt tolerance of tomato (Solanum lycopersicum L.) plantlets. Plant Cell, Tissue and Organ Culture (PCTOC) 154:239−247

Kumar V, Parvatam G, Ravishankar GA. 2009. AgNO₃-a potential regulator of ethylene activity and plant growth modulator. Electronic Journal of Biotechnology 12:8−9

Huang YW, Tsai YJ, Cheng TC, Chen JJ, Chen FC. 2014. Physical wounding and ethylene stimulated embryogenic stem cell proliferation and plantlet regeneration in protocorm-like bodies of Phalaenopsis orchids. Genetics and Molecular Research 13:9543−9557

Silva AS, Luz JMQ, Rodrigues TM, Bittar CA, de Oliveira Lino L. 2011. Callus induction and embryo regeneration in Coffea arabica L. anthers by silver nitrate and ethylene. Revista Ciência Agronômica 42:921−929

Shah SH, Ali S, Jan SA, Din J, Ali GM. 2014. Assessment of silver nitrate on callus induction and in vitro shoot regeneration in tomato (Solanum lycopersicum Mill.). Pakistan Journal of Botany 46:2163−2172

Enfeshi N, Abdulali E, Salama M, Geath Z, Shaaban A, et al. 2023. Effect of silver nitrate (AgNO₃) and copper sulphate (CuSO₄) on callus formation and plant regeneration from two pepper varieties (Chile Ancho and Misraty) in vitro. Scientific Journal of Faculty of Science Sirte University 3:150−157

Bagherzadeh Homaee M, Ehsanpour AA. 2015. Physiological and biochemical responses of potato (Solanum tuberosum) to silver nanoparticles and silver nitrate treatments under in vitro conditions. Indian Journal of Plant Physiology 20:353−359

Adly WMRM, Mazrou YSA, EL-Denary ME, Mohamed MA, Abd El-Salam, ET, et al. 2022. Boosting polyamines to enhance shoot regeneration in potato (Solanum tuberosum L.) using AgNO₃. Horticulturae 8:113

Şener S, Nasircilar AG, Karaçan A. 2024. The effects of silver nitrate and pre-cold treatments on callus formation in strawberry anther culture. Tekirdağ Ziraat Fakültesi Dergisi 21:15−23

Kevers C, Bisbis B, Le Dily F, Billard JP, Huault C, et al. 1995. Darkness improves growth and delays necrosis in a nonchlorophyllous habituated sugarbeet callus: biochemical changes. In Vitro Cellular & Developmental Biology-Plant 31:122−126

Kamarul Zaman MA, Azzeme AM, Ramle IK, Normanshah N, Ramli SN, et al. 2020. Induction, multiplication, and evaluation of antioxidant activity of Polyalthia bullata callus, a woody medicinal plant. Plants 9:1772

Robinson J, Yang G, Lu Z. 2023. In vitro callus and shoot initiation of Black cohosh (Actaea racemosa L.) pre-incubated in darkness treatments. Australian Journal of Crop Science 17:83−89

Liu J, Wu B, Xie T, Luan A, Ding Y, et al. 2022. Bud induction and observation of in vitro flowering from the callus of Ananas bracteatus var. tricolor. HortScience 57:595−598

Zhu F, Alseekh S, Koper K, Tong H, Nikoloski Z, et al. 2022. Genome-wide association of the metabolic shifts underpinning dark-induced senescence in Arabidopsis. The Plant Cell 34:557−578