Search
2024 Volume 4
Article Contents
REVIEW   Open Access    

Combating browning: mechanisms and management strategies in in vitro culture of economic woody plants

  • # Authors contributed equally: Chen Liu, Hongrui Fan

More Information
  • Received: 26 May 2024
    Revised: 11 July 2024
    Accepted: 06 August 2024
    Published online: 26 September 2024
    Forestry Research  4 Article number: e032 (2024)  |  Cite this article
  • Browning presents a significant challenge in the in vitro culture of economically important woody plants, primarily due to high levels of lignification and the accumulation of secondary metabolites. This phenomenon hampers the development of efficient regeneration and genetic transformation systems across diverse species. This review examines the internal and external factors contributing to browning, including genetic attributes, tree genotypes, physiological state of explants, explant surface sterilization, medium composition, and overall culture conditions. It explores the underlying mechanisms of browning, particularly enzymatic browning caused by the oxidation of phenolic compounds, and highlights the crucial role of redox pathways and phenolic metabolism. Conventional methods for assessing browning, such as sensory evaluation by researchers and the examination of paraffin sections stained with toluidine blue, are commonly used but introduce significant delays and potential biases. The review emphasizes the importance of accurate and timely browning assessment methods, notably the use of Fluorescein diacetate (FDA) staining, as a reliable and quantitative measure of cell viability to better evaluate browning intensity and progression. Additionally, this review explores the potential manipulation of key genes in the phenylpropanoid pathway to lower phenolic biosynthesis. Advanced strategies, such as regenerative gene manipulation and natural product encapsulation, are also discussed for their potential to improve regeneration outcomes. By integrating recent advancements in molecular biology and tissue culture techniques, this review offers novel insights and potential solutions for mitigating browning, thereby enhancing the regeneration capacities of woody plants. This comprehensive approach addresses the mechanistic bases of browning and underscores the importance of optimizing cultural practices and genetic strategies to overcome this challenge.
  • 加载中
  • [1]

    Liu C. 2009. Physiology mechanism and differential protein of fraxinus mandshurica somatic embrygenesis acompanied explant browning. Thesis. Northeast Forestry University, China. pp. 21−23

    [2]

    Wang J, Dong J, Liu W, Cao F, Wang G, et al. 2019. Research on growth, browning and flavonoid accumulation of Ginkgo biloba callus. Biotechnology Bulletin 35:16−22

    doi: 10.13560/j.cnki.biotech.bull.1985.2018-0672

    CrossRef   Google Scholar

    [3]

    Hao Z, Shi J, Wu H, Yan Y, Xing K, et al. 2023. Phytosulfokine contributes to suspension culture of Cunninghamia lanceolata through its impact on redox homeostasis. BMC Plant Biology 23:480

    doi: 10.1186/s12870-023-04496-1

    CrossRef   Google Scholar

    [4]

    Zhang D, Wang R, Xiao J, Zhu S, Li X, et al. 2022. An integrated physiology, cytology, and proteomics analysis reveals a network of sugarcane protoplast responses to enzymolysis. Frontiers in Plant Science 13:1066073

    doi: 10.3389/fpls.2022.1066073

    CrossRef   Google Scholar

    [5]

    Liu J, Zhang X, Poudyal BK, Zhang Y, Dong Z, et al. 2008. Studies on factors affecting browning of pear explants in vitro and anti-browning measures. Journal of Fruit Science 25:727−31

    Google Scholar

    [6]

    Duan Y, Guo W. 2009. Study on callus browning in relation to polyphenol content and polyphenol oxidase activity among various citrus embryogenic calli. Chinese Agricultural Science Bulletin 25:117−20

    Google Scholar

    [7]

    Li F, Li Z, Gao Z, Wang G, Li H, et al. 2023. A laccase gene (LcLac) was involved in polyphenol metabolism and tissue browning of litchi callus. Scientia Horticulturae 321:112291

    doi: 10.1016/j.scienta.2023.112291

    CrossRef   Google Scholar

    [8]

    Li JF, Deng Z, Dong H, Tsao R, Liu X. 2023. Substrate specificity of polyphenol oxidase and its selectivity towards polyphenols: unlocking the browning mechanism of fresh lotus root (Nelumbo nucifera Gaertn.). Food Chemistry 424:136392

    doi: 10.1016/j.foodchem.2023.136392

    CrossRef   Google Scholar

    [9]

    Mahmoud LM, Killiny N, Dutt M. 2024. Melatonin supplementation enhances browning suppression and improves transformation efficiency and regeneration of transgenic rough lemon plants (Citrus × jambhiri). PLoS One 19:e0294318

    doi: 10.1371/journal.pone.0294318

    CrossRef   Google Scholar

    [10]

    Xu X, Zhu D, Huan Z, Geng X, Ran J. 2023. Mechanisms of tissue culture browning in five Magnoliaceae family species. Plant Cell Tissue and Organ Culture 155:183−95

    doi: 10.1007/s11240-023-02568-6

    CrossRef   Google Scholar

    [11]

    Kim C, Dai W. 2020. Plant regeneration of red raspberry (Rubus idaeus) cultivars 'Joan J' and 'Polana'. In Vitro Cellular & Developmental Biology - Plant 56:390−97

    doi: 10.1007/s11627-019-10051-1

    CrossRef   Google Scholar

    [12]

    Wang J, Fang SZ. 2023. Effects of different anti-browning agents on enzyme activity and growth in callus of Cyclocarya paliurus. Journal of Nanjing Forestry University (Natural Sciences Edition), 47:167−74

    doi: 10.12302/j.issn.1000-2006.202203071

    CrossRef   Google Scholar

    [13]

    Li X, Wang C, Zhu J, He Q, Liu F. 2019. Effect of drying rate on cytochemical localization of phenolic substance and polyphenol oxidase and browning in thompson seedless grape. Science and Technology of Food Industry 40(05):99−107

    doi: 10.13386/j.issn1002-0306.2019.05.018

    CrossRef   Google Scholar

    [14]

    Bonga JM. 1987. Tree tissue culture applications. Advances in Cell Culture 5:209−39

    doi: 10.1016/B978-0-12-007905-6.50012-6

    CrossRef   Google Scholar

    [15]

    Cai X, Wei H, Liu C, Ren XX, Thi LT, et al. 2020. Synergistic effect of NaCl pretreatment and PVP on browning suppression and callus induction from petal explants of Paeonia Lactiflora Pall. 'Festival Maxima'. Plants 9:346

    doi: 10.3390/plants9030346

    CrossRef   Google Scholar

    [16]

    Taghizadeh M, Dastjerdi MG. 2021. Inhibition of browning problem during the callogenesis of Spartium junceum L. Ornamental Horticulture 27:68−77

    doi: 10.1590/2447-536x.v27i1.2230

    CrossRef   Google Scholar

    [17]

    Tarinejad A. 2013. Effects of disinfectants and antibiotics on contamination during propagation of walnut (Juglans regia L.). Research on Crops 14:219−25

    Google Scholar

    [18]

    Fang H, Dong Y, Zhou R, Wang Q, Duan Q, et al. 2022. Optimization of the induction, germination, and plant regeneration system for somatic embryos in apomictic walnut (Juglans regia L.). Plant Cell, Tissue and Organ Culture 150:289−97

    doi: 10.1007/s11240-022-02266-9

    CrossRef   Google Scholar

    [19]

    Wojtania A, Skrzypek E, Gabryszewska E. 2015. Effect of cytokinin, sucrose and nitrogen salts concentrations on the growth and development and phenolics content in Magnolia × soulangiana 'Coates' shoots in vitro. Acta Scientiarum Polonorum Hortorum Cultus 14:51−62

    Google Scholar

    [20]

    Han M, Gleave AP, Wang T. 2010. Efficient transformation of Actinidia arguta by reducing the strength of basal salts in the medium to alleviate callus browning. Plant Biotechnology Reports 4:129−38

    doi: 10.1007/s11816-010-0128-1

    CrossRef   Google Scholar

    [21]

    Panghal S, Soni SS. 2014. In vitro studies on effect of different concentration of NaCl on Jatropha curcas. Journal of Environmental Biology 35:709−12

    Google Scholar

    [22]

    Gou W, Zheng P, Wang K, Zhang L, Akram NA. 2016. Salinity-induced callus browning and re-differentiation, root formation by plantlets and anatomical structures of plantlet leaves in two Malus species. Pakistan Journal of Botany 48:1393−98

    Google Scholar

    [23]

    Lai S, Wu Z, Chen J, Ying Y. 2023. Mechanism and regulation of explants browning in tissue culture of Cyclobalanopsis chungii. Forest Science and Technology 66(08):75−78

    doi: 10.13456/j.cnki.lykt.2022.09.16.0001

    CrossRef   Google Scholar

    [24]

    Li S, Lin L, Jiang T, Zhu J, Liu B. 2023. Callus induction and culture conditions optimization of moso bamboo (Phyllostachys edulis). Molecular Plant Breeding 21:1265−71

    doi: 10.13271/j.mpb.021.001265

    CrossRef   Google Scholar

    [25]

    Feng J, Zhu C, Cao J, Liu C, Zhang J, et al. 2023. Genome-wide identification and expression analysis of the NRT genes in Ginkgo biloba under nitrate treatment reveal the potential roles during calluses browning. BMC Genomics 24:633

    doi: 10.1186/s12864-023-09732-4

    CrossRef   Google Scholar

    [26]

    Swarnkar PL, Bohra SP, Chandra N. 1986. Biochemical changes during growth and differentiation of the callus of Solanum surattense. Journal of Plant Physiology 126:75−81

    doi: 10.1016/S0176-1617(86)80219-X

    CrossRef   Google Scholar

    [27]

    Gibson SI. 2000. Plant sugar-response pathways. Part of a complex regulatory web. Plant Physiology 124:1532−39

    doi: 10.1104/pp.124.4.1532

    CrossRef   Google Scholar

    [28]

    Jan R, Khan MA, Asaf S, Lee IJ, Kim KM. 2020. Modulation of sugar and nitrogen in callus induction media alter PAL pathway, SA and biomass accumulation in rice callus. Plant Cell, Tissue and Organ Culture 143:517−30

    doi: 10.1007/s11240-020-01938-8

    CrossRef   Google Scholar

    [29]

    Solfanelli C, Poggi A, Loreti E, Alpi A, Perata P. 2006. Sucrose-specific induction of the anthocyanin biosynthetic pathway in Arabidopsis. Plant Physiology 140(2):637−46

    doi: 10.1104/pp.105.072579

    CrossRef   Google Scholar

    [30]

    Kim SS, Guo DD, Jung DC, Kwon ST. 2003. Multiple shoots regeneration and in vitro bulblet formation from garlic callus. Journal of Plant Biotechnology 5:95−99

    Google Scholar

    [31]

    Rahman Z, Ramli A, Kamaruzaman R, Seman Z, Othman A, et al. 2015. Efficient plant regeneration of malaysian aromatic rice (Oryza sativa L.) via improved somatic embryogenesis pathway. Emirates Journal of Food and Agriculture 27:857−63

    Google Scholar

    [32]

    Yari Khosroushahi A, Naderi-Manesh H, Toft Simonsen H. 2011. Effect of antioxidants and carbohydrates in callus cultures of Taxus brevifolia: evaluation of browning, callus growth, total phenolics and paclitaxel production. Bioimpacts 1:37−45

    doi: 10.5681/bi.2011.006

    CrossRef   Google Scholar

    [33]

    Du Y, Li Y, Ma Y, Yang X. 2007. Factors affecting explant browning in tissue culture of Hippophae rhamnoides L. Journal of Agricultural University of Hebei 30:40−43

    Google Scholar

    [34]

    Harahap F, Diningrat DS, Poerwanto R, Nasution NEA, Hasibuan RFM. 2019. In vitro callus induction of Sipahutar pineapple (Ananas comosus L.) from north Sumatra Indonesia. Pakistan Journal of Biological Sciences 22(11):518−26

    doi: 10.3923/pjbs.2019.518.526

    CrossRef   Google Scholar

    [35]

    Ma NL, Khoo SC, Lee JX, Soon CF, Shukor NAB. 2020. Efficient micropropagation of Dendrobium aurantiacum from shoot explant. Plant Science Today 7:476−82

    doi: 10.14719/pst.2020.7.3.724

    CrossRef   Google Scholar

    [36]

    Zhang D, Wang Y, Shi P, Jin L, Zhao Z, et al. 2019. Different exogenous hormones in the process of callus induction: effects on the browning rate of oil palm leaf. Chinese Agricultural Science Bulletin 35:47−51

    Google Scholar

    [37]

    Wang J, Gao J, Fan W, Dong J, Tang F, et al. 2023. Construction of tissue culture system of Onobrychis viciaefolia Scop 'Mengnong' anthers. Legume Research 46:855−61

    doi: 10.18805/LRF-729

    CrossRef   Google Scholar

    [38]

    Lu Z, Xia Z. 1991. Study on tissue and protoplast culture of wild cotton (Gossypium davidsonii). Acta Botanica Sinica 33:98−103,172

    Google Scholar

    [39]

    Shirazi MR, Rahpeyma SA, Zolala J. 2020. A new approach to prevent hazelnut callus browning by modification of sub-culture. Biologia Plantarum 64:417−21

    doi: 10.32615/bp.2020.009

    CrossRef   Google Scholar

    [40]

    Gao J, Zhang P, Xue J, Xue Y, Wang S, et al. 2019. Advances in phenolic substances and their effects on browning in woody plant tissue culture. Acta Horticulturae Sinica 46:1645−54

    doi: 10.16420/j.issn.0513-353x.2018-0698

    CrossRef   Google Scholar

    [41]

    Wang Y, Dai X. 2023. Effect of different light treatments on callus formation and browning of Stellaria dichotoma. Journal of Agricultural Sciences 44:34−37

    doi: 10.3969/j.issn.1673-0747.2023.01.006

    CrossRef   Google Scholar

    [42]

    Yu N. 2020. Optimization on anti-browning culture conditions of young stem tip explants in tissue culture of Ginkgo biloba. Mole cular Plant Breeding 18:6135−42

    doi: 10.13271/j.mpb.018.006135

    CrossRef   Google Scholar

    [43]

    Chen Y, Lin H, Li Y, Lin M, Chen J. 2019. Non-enzymatic browning and the kinetic model of 5-hydroxymethylfurfural formation in residual solution of vinegar soaked-soybean. Industrial Crops and Products 135:146−52

    doi: 10.1016/j.indcrop.2019.04.034

    CrossRef   Google Scholar

    [44]

    Embs RJ, Markakis P. 1965. The mechanism of sulfite inhibition of browning caused by polyphenol oxidase. Journal of Food Science 30:753−58

    doi: 10.1111/j.1365-2621.1965.tb01836.x

    CrossRef   Google Scholar

    [45]

    Sae-leaw T, Benjakul S, Simpson BK. 2017. Effect of catechin and its derivatives on inhibition of polyphenoloxidase and melanosis of Pacific white shrimp. Journal of Food Science and Technology 54:1098−107

    doi: 10.1007/s13197-017-2556-1

    CrossRef   Google Scholar

    [46]

    Ahmad I, Jaskani MJ, Nafees M, Ashraf I, Qureshi R. 2016. Control of media browning in micropropagation of guava (Psidium guajava L.). Pakistan Journal of Botany 48:713−16

    Google Scholar

    [47]

    Chi M, Bhagwat B, Lane W, Tang G, Su Y, et al. 2014. Reduced polyphenol oxidase gene expression and enzymatic browning in potato (Solanum tuberosum L.) with artificial microRNAs. BMC Plant Biology 14:62

    doi: 10.1186/1471-2229-14-62

    CrossRef   Google Scholar

    [48]

    Pretzler M, Rompel A. 2018. What causes the different functionality in type-III-copper enzymes? A state of the art perspective. Inorganica Chimica Acta 481:25−31

    Google Scholar

    [49]

    Laukkanen H, Rautiainen L, Taulavuori E, Hohtola A. 2000. Changes in cellular structures and enzymatic activities during browning of Scots pine callus derived from mature buds. Tree Physiology 20:467−75

    doi: 10.1093/treephys/20.7.467

    CrossRef   Google Scholar

    [50]

    Tang W, Newton RJ. 2004. Increase of polyphenol oxidase and decrease of polyamines correlate with tissue browning in Virginia pine (Pinus virginiana Mill.). Plant Science 167:621−28

    doi: 10.1016/j.plantsci.2004.05.024

    CrossRef   Google Scholar

    [51]

    Zhao S, Wang H, Liu K, Li L, Yang J, et al. 2021. The role of JrPPOs in the browning of walnut explants. BMC Plant Biology 21:9

    doi: 10.1186/s12870-020-02768-8

    CrossRef   Google Scholar

    [52]

    Mittler R. 2017. ROS are good. Trends Plant Science 22:11−19

    doi: 10.1016/j.tplants.2016.08.002

    CrossRef   Google Scholar

    [53]

    Hesami M, Tohidfar M, Alizadeh M, Daneshvar MH. 2020. Effects of sodium nitroprusside on callus browning of Ficus religiosa: an important medicinal plant. Journal of Forestry Research 31:789−96

    doi: 10.1007/s11676-018-0860-x

    CrossRef   Google Scholar

    [54]

    Tomás-Barberán FA, Espín JC. 2001. Phenolic compounds and related enzymes as determinants of quality in fruits and vegetables. Journal of the Science of Food and Agriculture 81:853−76

    doi: 10.1002/jsfa.885

    CrossRef   Google Scholar

    [55]

    Pang B, Feng X, Huang J, Zhou Y, Huang Z. 2019. Effects of PBU and 6-BA on POD genes and enzyme activity in Eucalyptus urophyllus callus. Molecular Plant Breeding 17:283−87

    doi: 10.13271/j.mpb.017.000283

    CrossRef   Google Scholar

    [56]

    Xie J, Qi B, Mou C, Wang L, Jiao Y, et al. 2022. BREVIPEDICELLUS and ERECTA control the expression of AtPRX17 to prevent Arabidopsis callus browning. Journal of Experimental Botany 73:1516−32

    doi: 10.1093/jxb/erab512

    CrossRef   Google Scholar

    [57]

    Wang X, Zhang X, Jia P, Luan H, Qi G, et al. 2023. Transcriptomics and metabolomics provide insight into the anti-browning mechanism of selenium in freshly cut apples. Frontiers in Plant Science 14:1176936

    doi: 10.3389/fpls.2023.1176936

    CrossRef   Google Scholar

    [58]

    Wang H, Zhang S, Fu Q, Wang Z, Liu X, et al. 2023. Transcriptomic and metabolomic analysis reveals a protein module involved in preharvest apple peel browning. Plant Physiology 192:2102−22

    doi: 10.1093/plphys/kiad064

    CrossRef   Google Scholar

    [59]

    Wang P, Zhang L, Zhao L, Zhang X, Zhang H, et al. 2020. Comprehensive analysis of metabolic fluxes from leucoanthocyanins to anthocyanins and proanthocyanidins (PAs). Journal of Agricultural and Food Chemistry 68:15142−53

    doi: 10.1021/acs.jafc.0c05048

    CrossRef   Google Scholar

    [60]

    Yang X, Xu Q, Le L, Zhou T, Yu W, et al. 2023. Comparative histology, transcriptome, and metabolite profiling unravel the browning mechanisms of calli derived from ginkgo (Ginkgo biloba L.). Journal of Forestry Research 34:677−91

    doi: 10.1007/s11676-022-01519-9

    CrossRef   Google Scholar

    [61]

    Liao L, Vimolmangkang S, Wei G, Zhou H, Korban SS, et al. 2015. Molecular characterization of genes encoding leucoanthocyanidin reductase involved in proanthocyanidin biosynthesis in apple. Frontiers in Plant Science 6:243

    doi: 10.3389/fpls.2015.00243

    CrossRef   Google Scholar

    [62]

    Sun HJ, Luo ML, Zhou X, Zhou Q, Sun YY, et al. 2020. PuMYB21/PuMYB54 coordinate to activate PuPLDβ1 transcription during peel browning of cold-stored ‘Nanguo’ pears. Horticulture Research 7:136

    doi: 10.1038/s41438-020-00356-3

    CrossRef   Google Scholar

    [63]

    Sun Y, Luo M, Ge W, Zhou X, Zhou Q, et al. 2022. Phenylpropanoid metabolism in relation to peel browning development of cold-stored 'Nanguo' pears. Plant Science 322:111363

    doi: 10.1016/j.plantsci.2022.111363

    CrossRef   Google Scholar

    [64]

    Yang C, Sun N, Qin X, Liu Y, Sui M, et al. 2024. Multi-omics analysis reveals the biosynthesis of flavonoids during the browning process of Malus sieversii explants. Physiologia Plantarum 176:e14238

    doi: 10.1111/ppl.14238

    CrossRef   Google Scholar

    [65]

    Ackah S, Xue S, Osei R, Kweku-Amagloh F, Zong Y, et al. 2022. Chitosan treatment promotes wound healing of apple by eliciting phenylpropanoid pathway and enzymatic browning of wounds. Frontiers in Microbiology 13:828914

    doi: 10.3389/fmicb.2022.828914

    CrossRef   Google Scholar

    [66]

    Persic M, Mikulic-Petkovsek M, Halbwirth H, Solar A, Veberic R, et al. 2018. Red walnut: characterization of the phenolic profiles, activities and gene expression of selected enzymes related to the phenylpropanoid pathway in pellicle during walnut development. Journal of Agricultural and Food Chemistry 66:2742−48

    doi: 10.1021/acs.jafc.7b05603

    CrossRef   Google Scholar

    [67]

    Fraser CM, Chapple C. 2011. The phenylpropanoid pathway in Arabidopsis. The Arabidopsis Book 2011:e0152

    doi: 10.1199/tab.0152

    CrossRef   Google Scholar

    [68]

    Shi R, Shuford CM, Wang JP, Sun YH, Yang Z, et al. 2013. Regulation of phenylalanine ammonia-lyase (PAL) gene family in wood forming tissue of Populus trichocarpa. Planta 238:487−97

    doi: 10.1007/s00425-013-1905-1

    CrossRef   Google Scholar

    [69]

    Dong YS, Fu CH, Su P, Xu XP, Yuan J, et al. 2016. Mechanisms and effective control of physiological browning phenomena in plant cell cultures. Physiologia Plantarum 156:13−28

    doi: 10.1111/ppl.12382

    CrossRef   Google Scholar

    [70]

    Jones AMP, Saxena PK. 2013. Inhibition of phenylpropanoid biosynthesis in Artemisia annua L.: a novel approach to reduce oxidative browning in plant tissue culture. PLoS One 8:e76802

    doi: 10.1371/journal.pone.0076802

    CrossRef   Google Scholar

    [71]

    Chen M, Li H, Zhang W, Huang L, Zhu J. 2022. Transcriptomic analysis of the differences in leaf color formation during stage transitions in Populus × euramericana 'Zhonghuahongye'. Agronomy 12:2396

    doi: 10.3390/agronomy12102396

    CrossRef   Google Scholar

    [72]

    Coseteng MY, Lee CY. 1987. Changes in apple polyphenoloxidase and polyphenol concentrations in relation to degree of browning. Journal of Food Science 52:985−89

    doi: 10.1111/j.1365-2621.1987.tb14257.x

    CrossRef   Google Scholar

    [73]

    Xu Q, Yang XM, Wang GB, Cao FL. 2023. Transcriptome analysis of browning and non-browning callus of Ginkgo biloba. Molecular Plant Breeding 21:3237−44

    Google Scholar

    [74]

    Zhong J. 2019. Preliminary study of tissue culture system of Sapindus mukorossi Gaertn. Thesis. Beijing Forestry University, China. pp. 32−36

    [75]

    Aghayeh RNM, Abedy B, Balandari A, Samiei L, Tehranifar A. 2021. The first successful report: control of browning problem in in vitro culture of iranian seedless barberry, a medicinally important species. Erwerbs-Obstbau 63:319−29

    doi: 10.1007/s10341-021-00574-6

    CrossRef   Google Scholar

    [76]

    Tabiyeh DT, Bernard F, Shacker H. 2006. Investigation of glutathione, salicylic acid and GA3 effects on browning in Pistacia vera shoot tips culture. Acta Horticulturae 726:201−04

    doi: 10.17660/ActaHortic.2006.726.31

    CrossRef   Google Scholar

    [77]

    Chen J. 2011. Study on browning control in Cunninghamia lanceolata callus culture. Subtropical Plant Science 40:47−49

    doi: 10.3969/j.issn.1009-7791.2011.03.013

    CrossRef   Google Scholar

    [78]

    Rao H, Shao Z, Liu H, Wu Y, Qian P. 2015. Effect of browning inhibitors on callus subculture of phenolic compounds, enzyme and gene expression of grape. Plant Physiology Journal 51:1322−30

    Google Scholar

    [79]

    Haque M, Siddique AB, Islam SS. 2015. Effect of silver nitrate and amino acids on high frequency plants regeneration in barley (Hordeum vulgare L.). Plant Tissue Culture and Biotechnology 25:37−50

    doi: 10.3329/ptcb.v25i1.24124

    CrossRef   Google Scholar

    [80]

    Xi Y, Zeng B, Huang H, Wang Y, Yang P. 2022. Resolving the browning during the establishment of the in vitro propogation of Prunus avium cv. 'Fuchen'. Horticultural Science 49:1−9

    doi: 10.17221/51/2020-HORTSCI

    CrossRef   Google Scholar

    [81]

    Gao J, Xue J, Xue Y, Liu R, Ren X, et al. 2020. Transcriptome sequencing and identification of key callus browning-related genes from petiole callus of tree peony (Paeonia suffruticosa cv. Kao) cultured on media with three browning inhibitors. Plant Physiology and Biochemistry 149:36−49

    doi: 10.1016/j.plaphy.2020.01.029

    CrossRef   Google Scholar

    [82]

    Meziani R, Jaiti F, Mazri MA, Hassani A, Ben Salem S, et al. 2016. Organogenesis of Phoenix dactylifera L. cv. Mejhoul: influences of natural and synthetic compounds on tissue browning, and analysis of protein concentrations and peroxidase activity in explants. Scientia Horticulturae 204:145−52

    doi: 10.1016/j.scienta.2016.04.009

    CrossRef   Google Scholar

    [83]

    Thomas TD. 2008. The role of activated charcoal in plant tissue culture. Biotechnology Advances 26:618−31

    doi: 10.1016/j.biotechadv.2008.08.003

    CrossRef   Google Scholar

    [84]

    Deng X, Huang J, Zhang M, Wei X, Song H, et al. 2023. Metabolite profiling and screening of callus browning-related genes in lotus (Nelumbo nucifera). Physiologia Plantarum 175:e14027

    doi: 10.1111/ppl.14027

    CrossRef   Google Scholar

    [85]

    Pompili V, Mazzocchi E, Moglia A, Acquadro A, Comino C, et al. 2023. Structural and expression analysis of polyphenol oxidases potentially involved in globe artichoke (C. cardunculus var. scolymus L.) tissue browning. Scientific Reports 13:12288

    doi: 10.1038/s41598-023-38874-4

    CrossRef   Google Scholar

    [86]

    Wang H, Zhang S, Wang Z, Li D, Yan L, et al. 2024. Resistance index and browning mechanism of apple peel under high temperature stress. Horticultural Plant Journal 10:305−17

    doi: 10.1016/j.hpj.2022.10.013

    CrossRef   Google Scholar

    [87]

    Zhang K, Su J, Xu M, Zhou Z, Zhu X, et al. 2020. A common wild rice-derived BOC1 allele reduces callus browning in indica rice transformation. Nature Communication 11:443

    doi: 10.1038/s41467-019-14265-0

    CrossRef   Google Scholar

    [88]

    Boudet AM. 2007. Evolution and current status of research in phenolic compounds. Phytochemistry 68:2722−35

    doi: 10.1016/j.phytochem.2007.06.012

    CrossRef   Google Scholar

    [89]

    Wei R, Zhang W, Li C, Hao Z, Huang D, et al. 2023. Establishment of Agrobacterium-mediated transformation system to Juglans sigillata Dode 'Qianhe-7'. Transgenic Research 32:193−207

    doi: 10.1007/s11248-023-00348-8

    CrossRef   Google Scholar

    [90]

    Cho JS, Nguyen VP, Jeon HW, Kim MH, Eom SH, et al. 2016. Overexpression of PtrMYB119, a R2R3-MYB transcription factor from Populus trichocarpa, promotes anthocyanin production in hybrid poplar. Tree Physiology 36:1162−76

    doi: 10.1093/treephys/tpw046

    CrossRef   Google Scholar

    [91]

    Duan J, Yu H, Yuan K, Liao Z, Meng X, et al. 2019. Strigolactone promotes cytokinin degradation through transcriptional activation of CYTOKININ OXIDASE/DEHYDROGENASE 9 in rice. Proceedings of the National Academy of Sciences of the United States of America 116:14319−24

    doi: 10.1073/pnas.1810980116

    CrossRef   Google Scholar

    [92]

    Hao Z, Wu H, Zheng R, Li R, Zhu Z, et al. 2023. The plant peptide hormone phytosulfokine promotes somatic embryogenesis by maintaining redox homeostasis in Cunninghamia lanceolata. The Plant Journal 113:716−33

    doi: 10.1111/tpj.16077

    CrossRef   Google Scholar

    [93]

    Ikeuchi M, Iwase A, Ito T, Tanaka H, Favero DS, et al. 2022. Wound-inducible WUSCHEL-RELATED HOMEOBOX 13 is required for callus growth and organ reconnection. Plant Physiology 188:425−41

    doi: 10.1093/plphys/kiab510

    CrossRef   Google Scholar

    [94]

    Yang W, Zhai H, Wu F, Deng L, Chao Y, et al. 2024. Peptide REF1 is a local wound signal promoting plant regeneration. Cell 187:3024−3038.e14

    doi: 10.1016/j.cell.2024.04.040

    CrossRef   Google Scholar

    [95]

    McFarland FL, Collier R, Walter N, Martinell B, Kaeppler SM, et al. 2023. A key to totipotency: Wuschel-like homeobox 2a unlocks embryogenic culture response in maize (Zea mays L.). Plant Biotechnology Journal 21:1860−72

    doi: 10.1111/pbi.14098

    CrossRef   Google Scholar

    [96]

    Hassani SB, Trontin JF, Raschke J, Zoglauer K, Rupps A. 2022. Constitutive overexpression of a conifer WOX2 homolog affects somatic embryo development in Pinus pinaster and promotes somatic embryogenesis and organogenesis in Arabidopsis seedlings. Frontiers in Plant Science 13:838421

    doi: 10.3389/fpls.2022.838421

    CrossRef   Google Scholar

    [97]

    Zhu T, Moschou PN, Alvarez JM, Sohlberg JJ, Von-Arnold S. 2016. WUSCHEL-RELATED HOMEOBOX 2 is important for protoderm and suspensor development in the gymnosperm Norway spruce. BMC Plant Biology 16:19

    doi: 10.1186/s12870-016-0706-7

    CrossRef   Google Scholar

    [98]

    Li Z, Qian W, Qiu S, Wang W, Jiang M, et al. 2024. Identification and characterization of the WOX gene family revealed two WUS clade members associated with embryo development in Cunninghamia lanceolata. Plant Physiology and Biochemistry 210:108570

    doi: 10.1016/j.plaphy.2024.108570

    CrossRef   Google Scholar

    [99]

    Lee K, Park OS, Seo PJ. 2018. ATXR2 as a core regulator of de novo root organogenesis. Plant Signaling & Behavior 13:e1449543

    doi: 10.1080/15592324.2018.1449543

    CrossRef   Google Scholar

    [100]

    Maulidiya AUK, Sugiharto B, Dewanti P, Handoyo T. 2020. Expression of somatic embryogenesis-related genes in sugarcane (Saccharum officinarum L.). Journal of Crop Science and Biotechnology 23:207−14

    doi: 10.1007/s12892-020-00024-x

    CrossRef   Google Scholar

    [101]

    Min L, Hu Q, Li Y, Xu J, Ma Y, et al. 2015. LEAFY COTYLEDON1-CASEIN KINASE I-TCP15-PHYTOCHROME INTERACTING FACTOR4 network regulates somatic embryogenesis by regulating auxin homeostasis. Plant Physiology 169:2805−21

    doi: 10.1104/pp.15.01480

    CrossRef   Google Scholar

    [102]

    Debernardi JM, Tricoli DM, Ercoli MF, Hayta S, Ronald P, et al. 2020. A GRF–GIF chimeric protein improves the regeneration efficiency of transgenic plants. Nature Biotechnology 38:1274−79

    doi: 10.1038/s41587-020-0703-0

    CrossRef   Google Scholar

    [103]

    Yang E, Yang H, Li C, Zheng M, Song H, et al. 2022. Genome-wide identification and expression analysis of the Aux/IAA gene family of the drumstick tree (Moringa oleifera Lam.) reveals regulatory effects on shoot regeneration. International Journal of Molecular Sciences 23:15729

    doi: 10.3390/ijms232415729

    CrossRef   Google Scholar

    [104]

    Xiong J, Zhang W, Zheng D, Xiong H, Feng X, et al. 2022. ZmLBD5 increases drought sensitivity by suppressing ROS accumulation in Arabidopsis. Plants 11:1382

    doi: 10.3390/plants11101382

    CrossRef   Google Scholar

    [105]

    Liu S, Wang B, Li X, Pan J, Qian X, et al. 2019. Lateral Organ Boun daries Domain 19 (LBD19) negative regulate callus formation in Arabidopsis. Plant Cell, Tissue and Organ Culture 137:485−94

    doi: 10.1007/s11240-019-01584-9

    CrossRef   Google Scholar

    [106]

    Iwase A, Harashima H, Ikeuchi M, Rymen B, Ohnuma M, et al. 2017. WIND1 promotes shoot regeneration through transcriptional activation of ENHANCER OF SHOOT REGENERATION1 in Arabidopsis. The Plant Cell 29:54−69

    doi: 10.1105/tpc.16.00623

    CrossRef   Google Scholar

    [107]

    Wang X, Bi C, Wang C, Ye Q, Yin T, et al. 2019. Genome-wide identification and characterization of WUSCHEL-related homeobox (WOX) genes in Salix suchowensis. Journal of Forestry Research 30:1811−22

    doi: 10.1007/s11676-018-0734-2

    CrossRef   Google Scholar

    [108]

    Wang K, Shi L, Liang X, Zhao P, Wang W, et al. 2022. The gene TaWOX5 overcomes genotype dependency in wheat genetic transformation. Nature Plants 8:110−17

    doi: 10.1038/s41477-021-01085-8

    CrossRef   Google Scholar

    [109]

    Liu B, Zhang J, Yang Z, Matsui A, Seki M, et al. 2018. PtWOX11 acts as master regulator conducting the expression of key transcription factors to induce de novo shoot organogenesis in poplar. Plant Molecular Biology 98:389−406

    doi: 10.1007/s11103-018-0786-x

    CrossRef   Google Scholar

    [110]

    Lv J, Feng Y, Jiang L, Zhang G, Wu T, et al. 2023. Genome-wide identification of WOX family members in nine Rosaceae species and a functional analysis of MdWOX13-1 in drought resistance. Plant Science 328:111564

    doi: 10.1016/j.plantsci.2022.111564

    CrossRef   Google Scholar

    [111]

    Permadi N, Akbari SI, Prismantoro D, Indriyani NN, Nurzaman M, et al. 2024. Traditional and next-generation methods for browning control in plant tissue culture: current insights and future directions. Current Plant Biology 38:100339

    doi: 10.1016/j.cpb.2024.100339

    CrossRef   Google Scholar

    [112]

    Feng BS, Kang DC, Sun J, Leng P, Liu LX, et al. 2022. Research on melatonin in fruits and vegetables and the mechanism of exogenous melatonin on postharvest preservation. Food Bioscience 50:102196

    doi: 10.1016/j.fbio.2022.102196

    CrossRef   Google Scholar

    [113]

    Favre LC, dos Santos C, López-Fernández MP, Mazzobre MF, del Pilar Buera M. 2018. Optimization of β-cyclodextrin-based extraction of antioxidant and anti-browning activities from thyme leaves by response surface methodology. Food Chemistry 265:86−95

    doi: 10.1016/j.foodchem.2018.05.078

    CrossRef   Google Scholar

    [114]

    Martínez-Hernández GB, Castillejo N, Artés-Hernández F. 2019. Effect of fresh-cut apples fortification with lycopene microspheres, revalorized from tomato by-products, during shelf life. Postharvest Biology and Technology 156:110925

    doi: 10.1016/j.postharvbio.2019.05.026

    CrossRef   Google Scholar

    [115]

    Xiao Y, He J, Zeng J, Yuan X, Zhang Z, et al. 2020. Application of citronella and rose hydrosols reduced enzymatic browning of fresh-cut taro. Journal of Food Biochemistry 44:e13283

    doi: 10.1111/jfbc.13283

    CrossRef   Google Scholar

    [116]

    Ranjith FH, Muhialdin BJ, Arroo R, Yusof NL, Mohammed NK, et al. 2022. Lacto-fermented polypeptides integrated with edible coatings for mango (Mangifera indica L.) bio-preservation. Food Control 134:108708

    doi: 10.1016/j.foodcont.2021.108708

    CrossRef   Google Scholar

    [117]

    Julaeha E, Nurzaman M, Wahyudi T, Nurjanah S, Permadi N, et al. 2022. The development of the antibacterial microcapsules of Citrus essential oil for the cosmetotextile application: a review. Molecules 27:8090

    doi: 10.3390/molecules27228090

    CrossRef   Google Scholar

  • Cite this article

    Liu C, Fan H, Zhang J, Wu J, Zhou M, et al. 2024. Combating browning: mechanisms and management strategies in in vitro culture of economic woody plants. Forestry Research 4: e032 doi: 10.48130/forres-0024-0026
    Liu C, Fan H, Zhang J, Wu J, Zhou M, et al. 2024. Combating browning: mechanisms and management strategies in in vitro culture of economic woody plants. Forestry Research 4: e032 doi: 10.48130/forres-0024-0026

Figures(2)  /  Tables(2)

Article Metrics

Article views(1404) PDF downloads(403)

REVIEW   Open Access    

Combating browning: mechanisms and management strategies in in vitro culture of economic woody plants

Forestry Research  4 Article number: e032  (2024)  |  Cite this article

Abstract: Browning presents a significant challenge in the in vitro culture of economically important woody plants, primarily due to high levels of lignification and the accumulation of secondary metabolites. This phenomenon hampers the development of efficient regeneration and genetic transformation systems across diverse species. This review examines the internal and external factors contributing to browning, including genetic attributes, tree genotypes, physiological state of explants, explant surface sterilization, medium composition, and overall culture conditions. It explores the underlying mechanisms of browning, particularly enzymatic browning caused by the oxidation of phenolic compounds, and highlights the crucial role of redox pathways and phenolic metabolism. Conventional methods for assessing browning, such as sensory evaluation by researchers and the examination of paraffin sections stained with toluidine blue, are commonly used but introduce significant delays and potential biases. The review emphasizes the importance of accurate and timely browning assessment methods, notably the use of Fluorescein diacetate (FDA) staining, as a reliable and quantitative measure of cell viability to better evaluate browning intensity and progression. Additionally, this review explores the potential manipulation of key genes in the phenylpropanoid pathway to lower phenolic biosynthesis. Advanced strategies, such as regenerative gene manipulation and natural product encapsulation, are also discussed for their potential to improve regeneration outcomes. By integrating recent advancements in molecular biology and tissue culture techniques, this review offers novel insights and potential solutions for mitigating browning, thereby enhancing the regeneration capacities of woody plants. This comprehensive approach addresses the mechanistic bases of browning and underscores the importance of optimizing cultural practices and genetic strategies to overcome this challenge.

    • The technique of in vitro culture is critical in forestry, agriculture, and horticulture, offering significant advantages for plant propagation, precise genetic engineering, and conservation. However, the in vitro propagation of woody and medical plants often encounters challenges of browning, primarily caused by high levels of secondary metabolites such as lignin, tannins, and other phenolic compounds. Browning leads to discoloration and necrosis of explants or callus, ultimately impeding their growth and causing cell death. Recognized as one of the three major challenges in plant tissue culture, browning frequently occurs at various stages such as explant induction[1], tissue healing[2], suspension cell culture[3], and protoplast culture[4]. Addressing browning is therefore crucial for the successful in vitro propagation of these valuable plants.

      This review comprehensively examines the recent advancements in understanding browning in the in vitro cultures of economically important woody plants, including its mechanisms and potential solutions. It analyzes the primary factors influencing browning, which could be categorized into internal factors and external factors. Additionally, this review examines the browning assessment methods, delves into the current understanding of the mechanisms underlying browning, and discusses potential strategies for its mitigation.

    • Browning in vitro culture is influenced by a complex interplay of both internal and external factors. Internal factors primarily include genetic characteristics, such as species and genotypes of tree species, and the physiological status of explants. External factors contain explant treatment, nutrient ingredients, growth regulators, and environmental conditions.

    • Geographic and species-specific isolation contributes to the diverse characteristics observed in plant populations, including their susceptibility to browning. The susceptibility varies significantly among different plant species and genotypes, largely due to the differing levels of phenolic compounds. For instance, species with higher inherent phenolic content are more prone to browning, making it crucial to select appropriate genotypes for tissue culture. Liu et al.[5] demonstrated a positive correlation between the degree of browning in tissue-cultured pear seedlings and the concentration of soluble phenols across different species; however, no significant correlation was observed with insoluble phenols. Duan & Guo[6] revealed that embryogenic tissues of tangerines, which have higher levels of polyphenols are more susceptible to browning compared to grapefruit and sweet oranges. Similar patterns were also observed in other species such as in litchi (Litchi chinensis)[7], lotus (Nelumbo nucifera)[8], lemon (Citrus × jambhiri)[9], and various Magnoliaceae species[10]. These findings collectively illustrate the complex interplay between polyphenolic content and genetic predisposition towards browning, emphasizing the necessity of genotype selection for tissue culture.

    • The selection of explants, including their developmental stage, tissue type, and physiological condition play a critical role in browning. Young, actively growing tissues are generally less susceptible to browning compared to older, more lignified tissues, and they may responsd differently to tissue culture conditions. For example, 7-day-old leaf explants of red raspberry (Rubus idaeus) show higher regeneration frequency than 14-day-old explants[11]. Furthermore, different parts of the same plant, serving distinct functions and containing different levels of enzymes, hormones, and free amino acids, exhibit distinct metabolic, physiological, and biochemical characteristics that contribute to varying degrees of browning during callus initiation[12]. Thus, it is crucial to experiment with different tissues to identify the plant parts with the least susceptibility to browning. Additionally, mechanical damage such as wounds can disrupt the physical distance between phenolic substrate and the oxidase, leading to oxidative reactions[13]. Therefore, selecting an appropriate explant and incision size can help reduce the occurrence of browning[14].

      Browning in explants can be effectively mitigated through specific pretreatment methods. For example, pretreating explants with NaCl solution has proven effective in suppressing browning in peony (Paeonia lactiflora Pall.)[15]. The choice of surface sterilization protocol also significantly impacts the physical state of explants and influences the success rate of culture initiation. For instance, explants from Spartium junceum L., treated with ethanol for 30 s and sodium hypochlorite for 10 min, show the lowest rate of browning[16]. Similarly, Tarinejad[17] observed that explants of walnut yield the optimal surface sterilization results when disinfected using 70% ethanol for 2 min, followed by 5% sodium hypochlorite for 20 min, and 0.7 g/L mercury chloride for 3 min. These cases highlight the importance of developing tailored explant treatment strategies based on specific plant characteristics and requirements. While the inherent properties of the material play a crucial role in browning, it is important to consider that external cultural conditions also significantly impact explant browning.

    • The nutrient composition of the culture medium significantly impacts both the growth and browning of plant materials in vitro. Different salts can influence the ionic balance and osmotic pressure, thereby affecting cell metabolism and viability. Excessive concentrations of inorganic salts can exacerbate the degree of browning in explants by promoting the oxidation of phenolic compounds. For woody plant species, media with lower concentration of basal salts are typically favored. Commonly utilized formulations include 1/2MS (Murashige and Skoog Medium), B5 (Gamborg B5 Medium), WPM (Woody Plant Medium), and DCR (Gupta and Durzan Medium). A comparative study on walnut revealed that DKW (Driver and Kuniyuki Walnut Medium) not only supports notably higher germination and seedling regeneration rates compared to WPM and MS, but also facilitates faster germination, and promotes more robust and greener seedling growth[18]. Nitrogen salts in MS medium significantly influence leaf and axillary shoot formation in Magnolia × soulangiana, as well as phenolic content[19]. An excessive concentration of inorganic salts in the medium can lead to phenolic spillover, resulting in the browning of the explants[20]. Conversely, reducing the concentration of inorganic salts like NaCl has been shown to mitigate browning in jatropha (Jatropha curcas)[21] and apple[22]. Similarly, explants of Cyclobalanopsis chungii experience less browning rate when cultured on a 1/4 MS medium compared to a normal MS medium[23]. Furthermore, substituting nitrate with ammonium salt, which is more heat-stable, decreases the browning mortality rate of bamboo (Phyllostachys edulis) callus to 1.2%[24]. Feng et al.[25] also found that elevated nitrate concentrations in Ginkgo callus led to severe browning.

    • Carbon source (sugar), as a principal component of tissue culture medium, is essential for cell proliferation and differentiation[26]. Also, serving as an osmotic agent, sugar plays a unique role in callus induction and regeneration by affecting the physiology and growth of callus[27]. Variations in sugar content can alter the development and morphology of callus by modifying secondary metabolites and related genes[28,29]. Optimal sugar concentrations and specific carbon sources can markedly enhance callus induction and regeneration capabilities[30]. However, high sugar concentrations can worsen browning and even cause the death of callus[31]. Additionally, the browning of explants is also influenced by the ratios of sugar composition. For instance, a specific blend of glucose (5 g/L), sucrose (5 g/L), and fructose (10 g/L) has been shown to effectively control browning in Taxus brevifolia[32].

    • PGRs such as auxins and cytokinins play a vital role in cell division and differentiation. Common PGRs utilized for regeneration include indole acetic acid (IAA), indole butyric acid (IBA), 2,4-dichlorophenoxyacetic acid (2,4-D), naphthalene acetic acid (NAA), 6-benzyl adenine (6-BA), thiadiazole phenyl urea (TDZ), and kinetin (KT). Cytokinins like 6-BA and KT enhance polyphenol oxidase (PPO) activity and phenolic compound biosynthesis. Elevated concentrations of 6-BA have been associated with increased browning[33]; however, auxins like 2,4-D can delay polyphenol synthesis and reduce browning[34]. The combination, concentration, and ratio of PGRs can markedly affect browning in various species. For example, adding 10 mg/L 2,4-D induces callus browning in Dendrobium officinale[35]. The applications of 6-BA and IBA intensify browning in oil palm[36], while specific concentrations of 6-BA and KT reduce callus browning in Onobrychis viciaefolia[37]. In cotton, successful plant regeneration has been achieved by supplementing MS medium with appropriate amounts of BA, ZT, or NAA, whereas combinations of 2,4-D, ZT, and NAA lead to browning and plant death[38]. Experimentation with different hormone balances can identify optimal conditions to mitigate browning for each species, though this approach requires significant investment of labor and resources.

    • The phase and pH of the culture medium, and environmental conditions are critical factors influencing browning. The hardness of the medium has an impact on the diffusion rate of phenolic substances. Within a specific range, increasing agar concentration elevates medium hardness and reduces browning[33]. For instance, liquid media typically result in less browning compared to solid media with the same composition, as observed in hazelnut (Corylus avellana L.) tissue culture[39]. pH levels affect the osmotic pressure of the medium and impact the binding sites of phenolics and oxidative enzymes. Generally, pH levels below 5.0 increase susceptibility to browning[40]. Environmental factors such as light and temperature also play crucial roles. For instance, light exposure has been linked to increased callus browning severity in Stellaria dichotoma, particularly under illumination levels of 8,000, 10,000, and 16,700 lx[41]. Furthermore, optimal temperature control is crucial for effectively controlling browning. Maintaining temperatures between 15 and 20 °C has been shown to effectively control the browning rate of young stem tips to less than 10% in Ginkgo[42].

    • To optimize culture conditions and medium formulations, recent research has delved deeply into the mechanisms of browning, to identify strategies to mitigate or prevent browning, improve the preservation and propagation techniques, and expand the range of plant biotechnology applications.

    • Browning during in vitro culture can be categorized into non-enzymatic browning and enzymatic browning. Non-enzymatic browning occurs through processes such as the Maillard reaction and sugar pyrolysis, and is not associated with the accumulation of phenolic compounds[43]. This type of browning can often be alleviated by successive subculturing and generally does not impede the normal growth and development of the cultured materials. Enzymatic browning, on the other hand, involves the oxidation of phenolics by enzymes such as PPO and peroxidase (POD), leading to the formation of brown quinones that inhibit cell growth and proliferation. This form of browning, which is predominant in plant tissue culture, presents a significant challenge.

      Typically, phenolics are stored in the vesicles, while oxidative enzymes are located in the cytoplasm. This compartmentalized distribution serves to prevent oxidative reactions under normal conditions[44]. However, stress or damage to plant tissues can disrupt this cellular arrangement, causing contact and reaction of substrate and enzyme, thereby resulting in the production of quinones[45]. These quinones further dehydrate and polymerize into black-brown substances, hindering the normal growth of the material. For instance, guava (Psidium guajava L.) experienced browning or blackening of explants during in vitro culture due to the leaching of phenolics[46]. Nevertheless, the propensity for browning varies significantly among different plants, influenced by their phenolic species and content generated within their enzymatic browning pathway.

    • The accumulation of phenolics makes woody plants more prone to browning due to oxidative reactions. PPO, a member of the oxidoreductase family, plays a central role in this process through its two main activities: hydroxylating monophenols, and oxidizing o-diphenols to o-quinones[47]. PPO is classified into three distinct types—tyrosinases, catechol oxidases, and laccases—based on their specific substrates and mechanisms of action[48]. The involvement of PPO in enzymatic browning has been extensively studied (Table 1). In Scots pine, callus induced from shoots shows significant browning and increases PPO levels after 2 weeks compared to unbrowned materials[49]. Similarly, high PPO activity of callus in Virginia pine (Pinus virginiana) leads to browning[50]. In walnut, the JrPPO2 substantially influences browning across different explants[51]. Although oxidative reactions mediated by PPO are the direct cause of browning in vitro, it is worth noting that under various abiotic stresses, the burst of reactive oxygen species (ROS) can disrupt lipid peroxidation and organelle envelope cytoarchitecture, break the homeostasis of phenols and oxidase, and indirectly affect the occurrence of browning[52,53].

      Table 1.  Genes related to browning in economically important woody plants.

      Pathway Gene Species Function Ref.
      Oxidative reaction LAC L. chinensis Overexpression LcLAC promotes callus browning and is involved in polyphenols polymerization. [7]
      LAC7 Malus domestica MdWRKY31 binds the promoter of MdLAC7, positively regulating its activity to promote peel browning. [58]
      POD E. urophylla PUB and 6-BA enhance POD activity, alleviating browning. [49]
      PPO2 Juglans regia JrPPO2 shows high activity in browning calluses. [51]
      Phenylpropanoid pathway DFRa Camellia sinensis CsDFRa is involved in the regulation of metabolic flux affecting secondary metabolism and phenotypic characteristics. [59]
      FLS, UGT Ginkgo biloba L. Expression of FLS and UGT in the flavonoid pathway are significantly higher in browning callus than in green callus. [60]
      LAR1 M. domestica MdLAR1 inhibits the expression of other genes in the anthocyanin biosynthesis. [61]
      MYB21, MYB54 Pyrus ussuriensis
      Maxim.
      PuMYB21/PuMYB54 enhance the degradation of membrane phospholipids leading to pericarp browning. [62]
      PAL, 4CL Pyrus spp Down-regulated expression of PuPAL and Pu4CL result in browning. [63]
      PAL, 4CL, F3H, CYP73A, CHS, CHI, ANS, DFR, PGT1 Malus sieversii Genes related to flavonoid biosynthesis increase flavonoid accumulation during browning. [64]
      PAL, C4H, 4CL,
      CCR, CAD
      M. domestica Genes increase the biosynthesis of phenolic compounds contributing to browning. [65]
      PAL, ANS J. regia These genes are involved in the synthesis of phenolic compounds and color changes in walnuts. [66]

      POD, a class of single-electron oxidizing enzymes, is prevalent in plants, animals, and microorganisms, and acts as a crucial endogenous ROS scavenger in cells[54]. Pang et al.[55] demonstrated a synergistic effect between the cytokinin N-phenyl-N-thiazolylurea (PBU) and 6-benzylaminopurine (6-BA), which not only enhanced POD activity but also reduced callus browning of Eucalyptus urophylla, and promoted embryonic callus differentiation. This study also found that PBU and 6-BA have differential effects on the expression of POD isozymes. In Arabidopsis thaliana, transcription factors BREVIPEDICELLUS (KNAT1/BP) and ERECTA (ER) directly binds to the Arabidopsis POD (AtPRX17) promoter, supporting normal growth and browning control in callus by scavenging H2O2[56]. Interestingly, PPO and POD may act synergistically in the oxidation of phenolics, as H2O2 produced by PPO enhances POD activity[57]. Additionally, research on the browning in apple pericarp and callus has revealed the role of laccase (LAC) enzyme[7]; especially, the MdLAC7 protein catalyzes the oxidation of catechin and other phenolic acids such as vanillic acid, anthocyanin, tannic acid, and erucic acid, leading to browning[58] (Table 1).

    • Plant phenolics, such as phenylpropanes, flavonoids, and tannins, are predominantly synthesized via the phenylpropanoid pathway. This pathway commences with the conversion of phenylalanine, which is produced via the shikimate synthesis pathway, into p-coumaroyl coenzyme A. This conversion involves the enzymes phenylalanine ammonia-lyase (PAL), cinnamic acid 4-hydroxylase (C4H) and 4-coumarate-CoA ligase (4CL)[67]. The p-Coumaroyl-coenzyme A then serves as a precursor for subsequent transformations into lignin and flavonoid synthesis pathway (Fig. 1a). Phenylalanine can be converted to free phenolic substrates for POD production through the catalytic activity of PAL, which also promotes PPO synthesis and enhances healing tissue browning[68,69]. Various studies have highlighted the pivotal role of genes related to the phenylpropanoid in regulating browning (Table 1). For instance, inhibiting PAL activity has demonstrated a reduction in browning in Acer saccharum and Ulmus americana[70]. Similarly, the expression of leucoanthocyanidin reductase (LAR) and anthocyanidin reductase (ANR) genes have been linked to browning in apple pulp through the biosynthesis of catechins and epicatechins[61]. Further studies have implicated genes like chalcone synthase (CHS), dihydroflavanol 4-reductase (DFR), anthocyanidin synthase (ANS), flavonol synthase (FLS), Bronze 1 (BZ1), bHLH35, and bHLH63 in the color formation of poplar leaves via the flavonoid metabolism pathway[71]. Transcriptomes and metabolomics comparison of green and browning callus in Ginkgo have shown that the accumulation of flavonoid glycosides is primarily controlled by flavonol synthase (FLS) and UDP-glucurono-syltransferase (UGT) genes[60].

      Figure 1. 

      Techniques and perspectives on controlling browning in in vitro cultures of woody plants. (a) Traditional management strategies for controlling enzymatic browning. (b) Prospective strategies for addressing browning: genetic approaches by targeting key metabolic pathways and regenerative genes, encapsulation of natural products.

    • Enzymatic browning is the primary type of browning that occurs in exosomes which requires the simultaneous presence of substrates, enzymes, and oxygen[72]. Therefore, callus browning can be prevented by removing oxidizing substances, capturing or reducing intermediates in the polymerization reaction, and inhibiting the relevant enzyme activity. Nevertheless, callus browning is frequently influenced by various factors. Numerous methods exist to prevent browning, each with specific applicability and limitations. Consequently, addressing callus browning requires adopting appropriate measures to inhibit or mitigate browning effectively.

    • The presence of browning in callus can be discerned through its appearance and morphology. Normal callus exhibits well-organized and densely packed cells with growth potential. In contrast, browning callus displays disorganized, loosely distributed with a darker color and signs of ruptured cells, indicating a tendency towards cell death[73]. However, the morphology of normal or brown callus varies considerably between different explants. For instance, in Ginkgo, normal callus cells contain more starch and lipid droplets, while brown callus cells are richer in tannins[60]. In hickory, browning callus cells exhibited increased browning components within the cytoplasm and cell shrinkage, whereas normal callus cells were active in cell division (Fig. 2a & b).

      Figure 2. 

      Comparison of healthy and browning callus in Carya cathayensis Sarg. Microscopic view of (a) healthy cells and (b) browning cells. Scale bars = 50 μm. Phenotypic progression of callus after subculture: (c) non-browning callus at day 10, (d) slightly browning callus at day 17, and (e) browning callus at day 24. Scale bars = 4 mm. FDA staining indicating viability of (f) non-browning callus, (g) slightly browning callus, and (h) browning callus. Scale bars = 4 mm. (i)−(j) Total phenolic content and total flavonoid content of non-browning callus at day 10, slightly browning callus at day 17, and browning callus at day 24. Error bars represent the SD (n = 3). Statistical analysis was performed using one-way ANOVA for each treatment (** p < 0.01, *** p < 0.001, **** p < 0.0001).

      Browning can be prevented by evaluating the health status of callus in advance. Conventional methods rely heavily on visual coloration, which is prone to subjective biases and can be compromised by chlorophyll masking the brown pigments. This highlights the necessity for standardized assessment techniques that encompass cell viability, division rate, differentiation capabilities, as well as morphological and cytological criteria to systematically evaluate browning levels. Fluorescein diacetate (FDA), an esterase substrate permeable to the cell membrane, has proven effective for analyzing cell viability. In our study on hickory, we utilized FDA to track the viability changes of callus after subculture (Fig. 2ch). After ten days of subculture, the callus exhibited a white or light-yellow color, characterized by rapid proliferation and intense fluorescence (Fig. 2c & f), along with relatively low levels of total phenolic and flavonoid contents (Fig. 2i & j). By day 17, the callus proliferation diminished, fluorescence intensity decreased (Fig. 2d & g), and browning increased, accompanied by a lower accumulation of total phenolic and flavonoid contents (Fig. 2i & j). By day 24, the callus showed extensive browning, minimal fluorescence (Fig. 2e & h), and significantly elevated levels of total phenolic and flavonoid contents (Fig. 2i & j). The FDA staining method not only indicates browning similar to visual evaluation but is more sensitive to subtle color changes, reducing biases among different researchers. Moreover, it effectively monitors the progression of browning, helping researchers to implement suitable interventions as necessary, offering enhanced convenience and adaptability.

      In conclusion, our study demonstrates the limitations of traditional visual assessments for browning and confirm the efficacy of FDA as a precise and quantifiable indicator of cell viability in hickory callus cultures. This substantiates the need for standardized methods that integrate FDA analysis to enhance accuracy in monitoring and optimizing tissue culture conditions.

    • Traditionally, preventing browning in tissue culture involves the application of various browning inhibitors that target specific stages of the browning process. There are three main types of reagents commonly employed to mitigate browning in tissue culture: antioxidants, adsorbents, and competitive inhibitors.

    • Antioxidants, including ascorbic acid (VC)[74], citric acid[75], glutathione (GSH)[76], L-cysteine[77], mannitol[78], and silver nitrate (AgNO3)[79], and sodium thiosulfate (Na2S2O3)[80], play critical roles in improving the intracellular redox environment. They protect against oxidative stress that damage cellular structure and maintain phenolic homeostasis. 1.0 g/L ascorbic acid significantly inhibits explants browning in Sapindus mukorossi[74], while 0.1 g/L ascorbic acid or 0.2 g/L L-cysteine is sufficient in the callus of Cunninghamia lanceolata[77]. Immersing barberry (Berberis integerrima) explants in a 0.3 g/L citric acid solution for 30 min and supplementing the culture medium with 0.225 g/L of citric acid efficiently manage browning[75]. Treating pistachio (Pistacia vera) shoot tips with a 0.1 mM GSH solution before further processing is also beneficial[76]. Additionally, controlling grape (Vitis vinifera) callus browning can be achieved with 2.0 g/L PVP, 20 g/L mannitol, or 0.02 g/L AgNO3[78].

    • Adsorbents like polyvinylpyrrolidone (PVP)[81], and charcoal[82] absorb phenolic compounds that contribute to browning. PVP, available in various molecular weights, requires careful selection to ensure efficacy[78]. Charcoal operates through intermolecular hydrogen bonding and van der Waals forces to absorb substances that cause browning[83]. A 1 g/L PVP treatment can reduce the production of phenolic compounds and promote callus regeneration in tree peony (Paeonia suffruticosa Andrews)[81]. Charcoal is often used in conjunction with other browning inhibitors. For instance, a combination of 1.0 g/L activated carbon (AC) and 30 g/L Na2S2O3 effectively inhibit browning in Prunus avium[80]. In addition, date stone-based activated carbon (DSAC) is an efficient natural anti-browning compound for date palm organogenesis. A concentration of 1.5 g/L DSAC significantly improves shoot bud proliferation and reduces tissue browning in Phoenix dactylifera[82].

    • Disodium ethylenediaminetetraacetic acid (EDTA) acts as a competitive inhibitor capable of binding to polyphenol oxidase, thereby reducing phenol oxidation[40]. Although EDTA's broad chelation properties limit its use in vitro, it illustrates the specificity of chelators in managing phenolic reactions. Enzyme inhibitors like aminoindane-2-phosphonic acid (AIP) effectively inhibit the activity of PAL and is added to media to limit substrate-enzyme interactions and mitigate browning[70]. In addition, epigallocatechin gallate (EGCG) exhibits high inhibition towards PPO, making it a potential browning inhibitor[45].

      These browning inhibitors can be used individually or in combination, either by presoaking explants or adding them directly to the culture medium. However, due to the inherent variability among plant species, no single method of using browning inhibitors is universally effective for all plants.

    • Although some browning inhibitors can mitigate the effect of browning on explants, they typically address the symptoms rather than the underlying cause, particularly in plants prone to browning. To fundamentally resolve the browning issue, further research is required to elucidate the molecular mechanisms underlying this phenomenon. Increasing attention is focusing on the novel functions of genes related to redox and phenolics metabolism, which play crucial roles in regulating browning in tissue-cultured materials. Genetic modification tools have been applied to develop varieties less prone to browning by targeting these specific pathways (Fig. 1b).

    • Manipulating the gene expression of PPOs and PODs in callus can inhibit their browning. Transcriptomic analysis by Deng et al. found that the expression of two PPOs and 17 PODs is significantly upregulated during the browning process in lotus callus[84]. In addition, Pompili et al. discovered that overexpressing PPO6, PPO7, and PPO11 in the callus of globe artichoke (Cynara cardunculus var. scolymus L.) lead to browning phenotypes due to phenol oxidation[85]. In Arabidopsis, AtPRX17 maintains rapid callus growth without promoting callus induction and is regulated by BREVIPEDICELLUS (KNAT1/BP) and ERECTA (ER), which inhibit callus browning[56]. Similarly, in apples, knockout MdPPO1 via CRISPR/Cas9 successfully reduces browning[86]. Zhang et al.[87] identified BROWNING OF CALLUS1 (BOC1) in indica rice (Oryza sativa L.), which encodes a SIMILAR TO RADICAL-INDUCED CELL DEATH ONE (SRO) protein. Up-regulating BOC1 reduces callus browning and improves the genetic transformation efficiency, suggesting its role in mitigating oxidative stress-induced cell senescence and death.

    • Phenolics that promote enzymatic browning are mainly derived from the phenylpropanoid pathway, which controls the biosynthesis of flavonoids and lignans[88]. Discovering the genes related to the phenylpropanoid pathway and then manipulating phenolic synthesis through molecular biology technology can alleviate or inhibit callus browning. In recent years, researchers have found that genes such as PALs, HCTs (hydroxycinnamoyl transferases), CHIs (chalcone isomerases) and other related genes are more highly expressed in brown callus compared to normal callus through fluorescence quantitative PCR and transcriptome analysis[60,69], suggesting that these genes can promote callus browning. Additionally, Wei et al.[89] transformed the JsFLS5 (flavonol synthetase) gene into the leaf-derived callus of 'Qianhe-7', resulting in improved content of total flavonoids, implying that JsFLS5 inhibits the browning of walnut callus. In poplar, overexpressing PtrMYB119 or PtrMYB120 shows elevated accumulation of cyanidin-3-O-glucoside, with upregulation of PtrCHS1 (chalcone synthase1) and PtrANS2 (anthocyanin synthase2)[90].

    • Utilizing a range of regeneration-promoting genes can significantly enhance the regeneration efficiency in woody plants, effectively addressing browning issues (Table 2). These genes include those involved in hormone signaling, cell differentiation, growth, and regeneration. Duan et al.[91] identified CYTOKININ OXIDASE/DEHYDROGENASE 9 (OsCKX9) as a key strigolatone-responsive gene. Overexpression of OsCKX9 upregulates rice type-A response regulator1 (OsRR1) and OsRR2, reducing total cytokinin content and decreasing browning. Phytosulfokine (PSK), a plant peptide hormone, promotes somatic embryogenesis in C. lanceolata. When heterologously expressed in Arabidopsis, ClPSK promotes root growth by maintaining H2O2 homeostasis[92]. Furthermore, the Wuschel-like homeobox protein (WOX) 13 alters the cell wall properties to enhance efficient callus formation and organ reattachment[93]. The conserved wound signal molecule Regeneration factor1 (REF1) boosts regeneration and genetic transformation efficiency in tomatoes, overcoming species and genotype limitations[94]. WOX2a in maize facilitates embryogenic callus and somatic embryo formation, leading to the regeneration of phenotypically normal plants and progeny (Zea mays)[95]. Similar functions are also observed in Pinus pinaster[96], Picea abies[97], and C. lanceolata[98].

      Table 2.  Regeneration-promoting genes used in plant genetic transformation.

      Gene Species Organ Function Ref.
      ATXR2 A. thaliana Callus, root ATXR2 promotes callus formation and lateral root growth [99]
      BBM Saccharum officinarum L. Callus
      BBM exhibits high levels of expression in embryogenic callus [100]
      CKI Gossypium hirsutum Hypocotyl section Overexpression of GhCKI inhibits somatic embryo formation and plant regeneration [101]
      GRF4-GIF1 Triticum aestivum GRF4-GIF1 improves regeneration efficiency and overcomes genotypic limitation [102]
      IAA Moringa oleifera Lam. Shoot IAA13 inhibits shoot regeneration [103]
      LBD5 Z. mays Overexpression of ZmLBD5 in Arabidopsis reduces ROS [104]
      LBD19 A. thaliana Callus Negatively regulates callus formation [105]
      LEC S. officinarum L. Callus LEC exhibits high levels of expression in embryogenic callus [100]
      PSK C. lanceolata
      Somatic embryogenesis Overexpression of ClPSK in Arabidopsis enhances somatic embryogenesis capabilities and lowers hydrogen peroxide levels [92]
      REF1 Solanum lycopersicum L. Callus, shoot Upon cellular damage, REF1 serves as an initial wound signal molecule and is recognized by the receptor PORK1, activating the expression of key cell reprogramming regulator SlWIND1 [94]
      WIND A. thaliana Callus, shoot WIND1 promotes callus formation and shoot regeneration [106]
      WOX Salix suchowensis Shoot WOX promotes shoot regeneration [107]
      WOX2 P. abies Somatic embryos Down-regulation of PaWOX2 early in embryo development significantly decreases in the yield of mature embryos [97]
      P. pinaster Callus WOX2 serves as a marker gene for somatic embryogenesis [96]
      WOX5 T. aestivum Callus WOX5 increases transformation efficiency with less genotype dependency [108]
      C. lanceolata Leaf Overexpression of WOX5 improves shoot regeneration but causes aborted embryo development, resulting in a partially sterile phenotype [98]
      WOX6 C. lanceolata Leaf Overexpression of WOX6 improves shoot regeneration [98]
      WOX11 '84K' (P. alba  × 
      P. glandulosa)
      Leaf PtWOX11 promotes de novo root, shoot organogenesis in poplar [109]
      WOX13-1 Malus × domestica Callus
      MdWOX13-1 increases callus weight and enhanced ROS scavenging ability [110]

      These genetic modifications not only accelerate cell proliferation and promote cell metabolism but also rapidly consume or reduce the accumulation of browning substances, thereby alleviating the browning.

    • Recent advances have increasingly focused on the utilization of natural products derived from botanical sources for postharvest preservation[111]. These natural products include polyphenols[112], carotenoids[113], terpenoids[114], organic acids[115] and bioactive peptides[116]. However, maintaining the efficacy of these active compounds is challenging due to their susceptibility to degradation from oxygen and humidity. One method, known as encapsulation, has been developed to protect these bioactive substances from degradation and oxidation, ensuring sustained efficacy throughout the culture process[111]. Encapsulation of natural products is a novel and promising strategy for mitigating browning in plant tissue cultures. This technique encases bioactive compounds, such as antioxidants and anti-browning agents, within protective matrices to enhance their stability and facilitating controlled release[117]. Such encapsulation has been shown to significantly reduce browning due to their antioxidant properties and ability to inhibit enzymatic activities responsible for browning (Fig. 1b).

    • This review provides an overview of the predominant strategies to mitigate tissue culture browning and explores potential future directions, such as the application of genetic modification techniques and natural products. However, certain obstacles must be addressed to advance this field.

      Numerous key genes are involved in the metabolic pathways of phenolic compounds, but their roles in browning, whether positive or negative, remains unclear. Comprehensive and systematic research on the browning regulation network, utilizing high-throughput sequencing technologies, is needed. Additionally, key genes in metabolic pathways and regenerative genes variably affect the development and growth of different species. Identifying regenerative-related marker genes common in most plants is crucial. By regulating these maker genes' expression, browning in tissue culture can be significantly reduced, leading to superior varieties.

      Innovations in genetic transformation are crucial for future research. Traditional methods like Agrobacterium and gene guns often damage plant materials, leading to tissue culture browning. Novel and optimized transgenic approaches hold promise for reducing browning and enhancing transformation efficiency. For instance, carbon nanomaterials are increasingly favored for their small size and minimal damage to plants. These novel transformation vectors could become mainstream technologies in the future.

      While natural products are widely used in post-harvest storage, they are less applied in plant tissue culture. Further screening of natural products for culture media is needed, and their efficient utilization must be optimized to prevent ineffectiveness. In conclusion, future trends in tissue culture may involve the discovery of natural products with strong anti-browning capabilities, ease of use, and long-lasting effectiveness.

    • Browning significantly impedes the regeneration and genetic transformation of economically important woody plants. Extensive research into browning has encompassed physiological, biochemical, and advanced molecular dimensions. However, traditional methods of browning assessment based on visual evaluation are inadequate. The present findings underscore the effectiveness of FDA staining as a reliable, quantitative measure of cell viability.

      By deepening our understanding of the pathways and regulatory mechanisms involved in browning and integrating advanced strategies such as genetic manipulation and natural product encapsulation, we can develop more targeted approaches to control browning in tissue cultures. This will ultimately enhance the efficiency of plant regeneration technologies and significantly contribute to advancements in plant tissue culture and the broader field of plant biotechnology. Moreover, by strategically redirecting its metabolic flux, we can mitigate browning without disrupting the production of essential metabolites.

    • The authors confirm contribution to the paper as follows: conception and design: Zhou X, Cao F; data collection: Fan H, Wu J; data analysis and manuscript preparation: Liu C, Fan H, Zhang J; manuscript revision: Tao G, Liu C, Zhou X. All authors reviewed the results and approved the final version of the manuscript.

    • All data generated or analyzed during this study are included in this published article.

      • This work was funded by grants from the Zhejiang Provincial Natural Science Foundation of China (No. LQ21C160003), Zhejiang Provincial Natural Science Foundation of China (No. LZ24C160002), Key Scientific and Technological Grant of Zhejiang for Breeding New Agricultural Varieties (2021C02066-12), the National Natural Science Foundation of China (No. 32001326), and the Talent Research Foundation of Zhejiang A&F University (No. 2019FR055). We would like to extend our sincere gratitude and appreciation to the editors, and reviewers for the effort and time spent giving helpful comments to improve our work.

      • The authors declare that they have no conflict of interest.

      • # Authors contributed equally: Chen Liu, Hongrui Fan

      • Copyright: © 2024 by the author(s). Published by Maximum Academic Press, Fayetteville, GA. This article is an open access article distributed under Creative Commons Attribution License (CC BY 4.0), visit https://creativecommons.org/licenses/by/4.0/.
    Figure (2)  Table (2) References (117)
  • About this article
    Cite this article
    Liu C, Fan H, Zhang J, Wu J, Zhou M, et al. 2024. Combating browning: mechanisms and management strategies in in vitro culture of economic woody plants. Forestry Research 4: e032 doi: 10.48130/forres-0024-0026
    Liu C, Fan H, Zhang J, Wu J, Zhou M, et al. 2024. Combating browning: mechanisms and management strategies in in vitro culture of economic woody plants. Forestry Research 4: e032 doi: 10.48130/forres-0024-0026

Catalog

    /

    DownLoad:  Full-Size Img  PowerPoint
    Return
    Return