A Comprehensive Review Uncovering the Challenges and Advancements in the In Vitro Propagation of Eucalyptus Plantations
Abstract
:1. Introduction
1.1. Challenges with Conventional Breeding
1.2. A Crop with Potential Biomass Production
2. Micropropagation and Its Applications
2.1. Establishing Axenic Culture
2.2. In Vitro Proliferation of Shoot
2.2.1. Organogenesis
2.2.2. Somatic Embryogenesis
2.3. Adventitious Root Formation and Root Hardening
3. Factors Affecting the Efficiency of Micropropagation
3.1. Role of Plant Growth Regulators
3.2. Effect of Culture Media
3.3. Importance of Organic and Inorganic Elements
3.4. The Role of Carbohydrates
3.5. Effects of Radiation and Light Exposure
4. In Vitro Germplasm Preservation
5. Limitations, Challenges, and Future Directions
6. Conclusions
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Explant-Source/Type | Culture Media/PGRs/Additives | Experimental Outcomes/Remarks/Productivity/Root Hardening, etc. | References |
---|---|---|---|
Nodal segments | MS media, WPM, 0.5 mg L−1 IBA, 1.0 mg L−1 BAP, B5, NAA, Kinetin | Full-strength MS media supplemented with 1.0 mg L−1 BAP showed the best shoot elongation; ½ MS media supplemented with 0.5 mg L−1 IBA showed the best rooting; the resulting hybrid produced yielded 3–5 times more wood than parental species. | [5] |
Nodal segments (30–32-year trees) | MS media, WPM, B5 medium, SH medium, IBA, BAP, NAA, | Best in vitro studies were obtained from the explants collected during the period of January to February and August to September; ½ MS media + BAP resulted in best rooting (92%); up to 98% of plants survived acclimatization. | [6] |
Stem cuttings and axillary buds | MS Media, 2.22 µm BA, 1.16 µm Kinetin, 0.029 µm gibberellic acid, 400 mg L−1 PVP, 30 g L−1 sucrose | Micropropagation and microcuttings showed higher adventitious rooting (24.8–100% and 43–95%, respectively) than stem cuttings (9.3–75.5%). | [12] |
Maintained Elite clones (KE8, CE2, T1, and Y8) | Basal MS media, 2.5 µM BA, 0.5 µM NAA, D-mannitol (0, 250, 500, 750, and 1000 mM) | The culture growth index of all clones was reduced significantly because of drought stress. | [17] |
Cuttings from plants grown in vitro | Full and ½ strength MS media | Concentrations of IAA, IBA, and stem anatomy had no effect on the rooting potential of shoots. | [22] |
Nodal cuttings | IAA, IBA (0, 1, 3, 8 g Kg−1) | The position from which the explant is harvested can affect the rooting potential and seed vigor. Explants obtained from 7/8 and 9/10 apical positions showed enhanced rooting and shooting. | [25] |
Cuttings from 6-month-old parental plants | MS media, IAA, meta-topolin, kinetin, BAP, vit. B5, biotin, sucrose | 0.5 mg L−1 meta-topolin and 1 mg L−1 IAA enhanced shoot elongation as well as bud proliferation, while 0.5 mg L−1 IAA resulted in the most consistent rooting percentages. Moreover, equal expression of AUX1 and PIN1 transporter genes increased responsiveness toward PGRs. | [29] |
Nodal segments | MS media, 58 mM sucrose, 0.5 μM NAA, 2.5 μM BA, | Media supplemented with 1.0 μM 2,4-D, 5.0 μM BA and 500 mg L−1 cefotaxime showed maximum (44.6%) shoot bud organogenesis. | [33] |
Nodal segments | MS media, 2 mg L−1 BAP, 0.1 mg L−1 NAA | Media supplemented with 0.5 mg L−1 showed the best shoot elongation, ½ MS + 1 mg L−1 IAA showed the best root induction and elongation, and direct regeneration was observed in MS + 20:1 BAP: NAA. | [34] |
Young shoot segments | WPM, MS media, 2iP, NAA, BAP, sucrose | Media supplemented with BA resulted in 99% shoot proliferation, media supplemented with 2iP resulted in 93% shoot regeneration, and IBA promoted rooting in 60% of the clones. | [35] |
Nodal segments | EDM basal media (a novel basal media for E. dunnii) supplemented with 20 g L−1 sucrose and without PGRs | Higher Fe, Cu, Zn, and Mn concentrations in EDMm media increased rooting. Moreover, high S and K concentrations in EDMm increased growth rate and multiplication. Also, no Fe chlorosis/oxidation was observed in shoots cultured on EDMm. | [37] |
Zygotic embryo | One of the following media and growth regulators: ½ or full-strength MS media/WPM/B5/DKW/JADS media/3 mg L−1 NAA/10 mL−1 silver nitrate/0.5 mg L−1 DTT/100 mg L−1 ascorbic acid/0.5 mg L−1 DTE/1% m/v PVP/1% m/v PVPP/0.01% w/v activated charcoal | The best media for somatic embryogenesis were B5 and MS. Moreover, Silver nitrate, activated charcoal, and DTE reduced the browning of explants. | [41] |
Somatic embryos | MS media supplemented with 3 mg L−1 NAA | MS medium without PGRs is highly efficient for promoting cotyledonary embryo proliferation and germination. | [42] |
Zygotic embryo cotyledons | Hormone-free MS media | The reserve accumulation of mature zygotic embryos was analyzed. Cotyledonary somatic embryos possess a low density of starch and no lipids/proteins. | [43] |
Axillary shoots | ½ MS, 4.4 μM, 1 μM NAA, 1 g L−1 sucrose | WPM and QL media supplemented with Gibberellic acids showed enhanced shoot proliferation, ½ WPM supplemented with 20 μM IBA showed enhanced rooting, and 67% Plantlet hardening was achieved. | [44] |
Shoot segments | MS media, 0.02 mg L−1 IBA | Vitron vessel placed in Low Photon Flux density at 3000 ppm CO2 for 24 h/day yielded the best growth and quality of plantlets. | [45] |
Seedlings grown from seeds | Variable potting mixture | Low temperatures of 18 °C/13 °C to 23 °C/18 °C (day/night) reduced the number of harvested cuttings; however, they did not affect the percentage of roots proliferated from cuttings. By contrast, increasing the temperature to 33 °C/28 °C resulted in an increased number of cutting per stock plant. | [46] |
Hypocotyl segments and cotyledonary leaves | MS media supplemented with different concentrations of NAA and TDZ, 0.8 g L−1 PVP, 0.1 g L−1 biotin, 0.1 g L−1 calcium pantothenate, 30 g L−1 sucrose | 0.44 µM BAP increased the regeneration of adventitious buds. | [47] |
Zygotic embryos and cotyledons | MS media supplemented with 3 g L−1 sucrose and different concentrations of NAA, 2,4-D, BA, ABA | 1 mg L−1 NAA resulted in maximum callus induction, the frequency of callus proliferation depends on the age of the explant, with 10-year-old explants showing maximum proliferation, the highest frequency of somatic embryogenesis was observed in callus from mature zygotic embryos, low ABA concentrations increased number of somatic embryos. | [48] |
Nodal segments | 1/2 MS supplemented with different concentrations of BAP, NAA, and GA3 | 0.050 mg L−1 BAP achieved optimal bud proliferation + 0.50 mg L−1 NAA, while ½ MS media supplemented with 0.2−1 and 0.10 mg L−1 GA3 + 0.10 mg L−1 BAP showed highest shoot elongation. | [49] |
Nodal segments | MS media without PGRs | Media free from GA3 + BAP resulted in best shoot elongation, and WPM + 0.05 mg L−1 NAA + 0.5 mg L−1 BAP resulted in maximum axillary bud proliferation. | [50] |
Nodal segments | ½ MS media, De-Fossard Medium, 0.9 µg L−1 BA, 0.5 µM NAA | The best multiplication rate (2.25) was achieved, and 93% of the plants survived acclimatization. | [51] |
Nodal segments | MS media supplemented with 0.05 μM NAA, 0.4 μM BA, 1 mg L−1 nicotinic acid, 1 mg L−1 pyridoxine-HCl, 1 mg L−1 thiamine, 2 mg L−1 glycine, 50 mg L−1 myo-inositol, and 30 g L−1 sucrose | Endogenous rhythms cause time-related fluctuations, resulting in rooting variations among closely related genotypes. | [52] |
Epicotyl segments | ½ MS supplemented with 1/6× CaCl2, 2% (w/v) sucrose | Auxin reduced mean rooting time, and light conditions did not affect the rooting efficiency; with increased age, decreased rooting capability was observed. | [53] |
Axillary buds | ½ MS supplemented with 1 g L−1 ABA | Encapsulation by calcium alginate and storing under low light intensities resulted in the preservation of cultures for up to 3 months without affecting their viability. | [54] |
Apical shoots | MS media supplemented with 0.04 mg L−1 BA, 1% sucrose, with/without charcoal | 38–85% survival was observed with plants exposed to PSV2 for 30 min in liquid nitrogen. | [55] |
Nodal segments | MS media supplemented with 30 g L−1 sucrose | The best in vitro establishment, multiplication, shooting, and rooting were achieved using red–blue LEDs and fluorescent lamps. | [56] |
Species | Explant | Sterilant | Media; PGR (If Any) | Area Studied and Scope of Work | References |
---|---|---|---|---|---|
E. camaldulensis × E. tereticornis and E. torelliana × E. citriodora | Nodal segments from mature trees (30–32 yrs) | 0.15% HgCl2 | MS media, WPM, SH medium, B5 medium; BAP, NAA | Hybridization of Eucalyptus species. The study reported that two hybrids developed that showed superior performance than parental genotypes. | [17] |
E. grandis × E. nitens | Axial buds | 10 g L−1 CaOCl | MS media; BAP, IAA, metatopolin, kinetin | Individual evaluation of each stage of micropropagation. The study reported that Auxins are principal components of media, and expression of different auxin transporters might be used as markers to identify Eucalyptus spp. amenable for micropropagation. | [29] |
E. erythronema × E. stricklandii | Seedlings germinated in vitro | 3% NaOCl | MS media supplemented with sucrose 30 g L−1; IBA, NAA, Gibberellic acids | First micropropagation report of ornamental Eucalyptus spp. The study reported that successful micropropagation from juvenile seedlings was achieved. | [44] |
E. benthamii × E. dunni | Nodal segments from 1-year-old plants | NaOCl | ½ strength MS media; PVP40, NAA, BAP | Optimization of chlorine concentration for explant sterilization and optimum ratio of PGRs for shoot elongation. The study reported that 0.5% NaOCl is suggested for nodal segments; 0.50 mg L−1 BAP + 0.05 mg L−1 NAA provides the highest number of bud proliferation. | [49] |
E. erythronema × E. stricklandii | Nodal segments | 1% NaOCl | MS media supplemented with sucrose 30 g L−1; 0.05 μM NAA and 2.22 μM BAP | Effect of different light intensities on micropropagation efficiency. The study reported that red–blue LEDs and fluorescent light result in higher vigor, high photosynthesis, and increased shoot and root proliferation. | [56] |
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Sharma, V.; Ankita; Karnwal, A.; Sharma, S.; Kamal, B.; Jadon, V.S.; Gupta, S.; Sivanasen, I. A Comprehensive Review Uncovering the Challenges and Advancements in the In Vitro Propagation of Eucalyptus Plantations. Plants 2023, 12, 3018. https://doi.org/10.3390/plants12173018
Sharma V, Ankita, Karnwal A, Sharma S, Kamal B, Jadon VS, Gupta S, Sivanasen I. A Comprehensive Review Uncovering the Challenges and Advancements in the In Vitro Propagation of Eucalyptus Plantations. Plants. 2023; 12(17):3018. https://doi.org/10.3390/plants12173018
Chicago/Turabian StyleSharma, Vikas, Ankita, Arun Karnwal, Shivika Sharma, Barkha Kamal, Vikash S. Jadon, Sanjay Gupta, and Iyyakkannu Sivanasen. 2023. "A Comprehensive Review Uncovering the Challenges and Advancements in the In Vitro Propagation of Eucalyptus Plantations" Plants 12, no. 17: 3018. https://doi.org/10.3390/plants12173018
APA StyleSharma, V., Ankita, Karnwal, A., Sharma, S., Kamal, B., Jadon, V. S., Gupta, S., & Sivanasen, I. (2023). A Comprehensive Review Uncovering the Challenges and Advancements in the In Vitro Propagation of Eucalyptus Plantations. Plants, 12(17), 3018. https://doi.org/10.3390/plants12173018