In vitro propagation of Allium stamineum: an endangered medicinal plant
Subject Areas : Plant PhysiologyNajmeh Ghahtan 1 , Mohammad Hedayat 2 , Mohammad Amin Kohanmoo 3 , Gholamreza Abdi 4 , Rashid Jamei 5
1 - 1Department of Horticulture, College of Agriculture, Persian Gulf University, Bushehr, 7516913817, Iran
2 - 1Department of Horticulture, College of Agriculture, Persian Gulf University, Bushehr, 7516913817, Iran
3 - 1Department of Horticulture, College of Agriculture, Persian Gulf University, Bushehr, 7516913817, Iran
4 - Department of Biotechnology, Persian Gulf Research Institute, Persian Gulf University, Bushehr, 7516913817, Iran
5 - Department of Biology, Faculty of Sciences, Urmia University, Urmia, Iran
Keywords: Bulblets, Explant, Regeneration, IBA, Rooting,
Abstract :
Allium stamineum, an endangered medicinal plant in Iran, requires conservation efforts through in vitro culture techniques. This study established an effective protocol for callus induction and bulblet regeneration in A. stamineum using various explant types (radicle, basal plate, and cotyledon) and growth regulators. The results indicated that the best callus formation from cotyledon explants occurred in media containing 1 mg/L 2,4-D, 1 mg/L 2,4-D with 0.5 mg/L BA, 2 mg/L 2,4-D with 0.5 mg/L kinetin, and 1 or 2 mg/L 2,4-D with 1 mg/L kinetin. In terms of regeneration, cotyledon explants showed the highest regeneration rate compared to radicle and basal plate explants, with 3.33 regenerations per explant in MS medium supplemented with 1 mg/L kinetin and 1 mg/L NAA. Additionally, the highest bulblet regeneration rate (11 per explant) was obtained from callus on PGR-free medium. The maximum number of roots (7.90) and root length (10.9 mm) were observed on MS medium containing 3 mg/L IBA. Rooted bulblets were successfully acclimatized in pots filled with a cockpit mixture (3:1 v/v) with a 100% survival rate. This study not only provides a successful in vitro propagation technique for A. stamineum but also facilitates its breeding program.
Ayabe, M. and S. Sumi. 1998. Establishment of a novel tissue culture method, stem-disc culture, and its practical application to micro propagation of garlic (Allium sativum L.). Plant Cell Reports. 17(10): 773-779.
Ayed, C., C. Bayoudh, A. Rhimi, N. Mezghani, F. Haouala and B. AL Mohandes Dridi. 2018. In vitro propagation of Tunisian local garlic (Allium sativum L.) from shoot tip culture. Journal of Horticulture and Postharvest Research 1(2): 75-86.
Bikis, D. 2018. Review on the application of biotechnology in garlic (Allium sativum) improvement. International Journal of Research Studies in Agricultural Sciences 4(11): 23-33.
Ebrahimi, R., Z. Zamani and A. Kashi. 2009. Genetic diversity evaluation of wild Persian shallot (Allium hirtifolium Boiss.) using morphological and RAPD markers. Scientia Horticulturae 119(4): 345-351.
Farhadi, N., J. Panahandeh, A. M. Azar and S. A. Salte. 2017. Effects of explant type, growth regulators and light intensity on callus induction and plant regeneration in four ecotypes of Persian shallot (Allium hirtifolium). Scientia Horticulturae 218: 80-86.
Frebort, I., M. Kowalska, T. Hluska, J. Frébortová and P. Galuszka. 2011. Evolution of cytokinin biosynthesis and degradation. Journal of Experimental Botany 62(8): 2431-2452.
Haque, M. S., T. Wada and K. Hattori. 2003. Shoot regeneration and bulblet formation from shoot and root meristem of garlic cv Bangladesh local. Asian Journal of Plant Science 2(1): 23-27.
Jeong, M. J. and S. H. Yong. 2022. Rapid micropropagation of wild garlic (Allium victorialis var. platyphyllum) by the scooping method. Journal of Plant Biotechnology 49(3): 213-221.
Khan, N., M. Alam and U. Nath. 2004. In vitro regeneration of garlic through callus culture." Journal of Biological Sciences 4(2): 189-191.
Luciani, G. F., A. K. Mary, C. Pellegrini and N. R. Curvetto. 2006. Effects of explants and growth regulators in garlic callus formation and plant regeneration. Plant cell, tissue and organ culture 87: 139-143.
Marrelli, M., V. Amodeo, G. Statti and F. Conforti. 2018. "Biological properties and bioactive components of Allium cepa L.: Focus on potential benefits in the treatment of obesity and related comorbidities. Molecules 24(1): 119.
Mehta, J., A. Sharma, N. Sharma, S. Meghwal, G. Sharma, P. Gehlot and R. Naruka. 2013. An Improved Method for Callus Culture and, Vitro. International Journal of Pure Applied Bioscience 1 (1): 1-6
Murashige, T. and F. Skoog. 1962. A revised medium for rapid growth and bio assays with tobacco tissue cultures. Physiologia plantarum 15(3): 473-497.
Nabavi, S. M., M. Saeedi, S. F. Nabavi and A. S. Silva 2020. Recent advances in natural products analysis. Elsevier, Amsterdam, XXIII-XXIII. ISBN 978-0-12-817519-4; 978-0-12-816455-6
Pop, T. I., D. Pamfil and C. Bellini 2011. "Auxin control in the formation of adventitious roots. Notulae Botanicae Horti Agrobotanici Cluj-Napoca 39(1): 307-316.
Razyfard, H., S. Zarre, R. M. Fritsch and H. Maroofi. 2011. Four new species of Allium (Alliaceae) from Iran. Annales Botanici Fennici 48(4), 352-360
Scotton, D. C., V. A. Benedito, J. B. de Molfetta, B. I. F. Rodrigues, A. Tulmann-Neto and A. Figueira , 2013. Response of root explants to in vitro cultivation of marketable garlic cultivars. Horticultura Brasileira 31: 80-85.
Sharifi-Rad, J., D. Mnayer, G. Tabanelli, Z. Stojanović-Radić, M. Sharifi-Rad, Z. Yousaf, L. Vallone, W. Setzer and M. Iriti. 2016. Plants of the genus Allium as antibacterial agents: From tradition to pharmacy. Cellular and Molecular Biology 62(9): 57-68.
Tubić, L., J. Savić, N. Mitić, J. Milojević, D. Janošević, S. Budimir and S. Zdravković-Korać. 2016. Cytokinins differentially affect regeneration, plant growth and antioxidative enzymes activity in chive (Allium schoenoprasum L.). Plant Cell, Tissue and Organ Culture 124: 1-14.
Xu, Z., Y.-C. Um, C.-H. Kim, G. Lu, D.-P. Guo, H.-L. Liu, A. A. Bah and A. Mao. 2008. Effect of plant growth regulators, temperature and sucrose on shoot proliferation from the stem disc of Chinese jiaotou (Allium chinense) and in vitro bulblet formation. Acta Physiologiae Plantarum 30: 521-528.
Zheng, S., B. Henken, E. Sofiari, P. Keizer, E. Jacobsen, C. Kik and F. Krens 1999. Effect of cytokinins and lines on plant regeneration from long-term callus and suspension cultures of Allium cepa L. Euphytica 108: 83-90.
.
1405
In vitro propagation of Allium stamineum: an endangered medicinal plant
Najmeh Ghahtan1 , Mohammad Hedayat1 , Mohammad Amin Kohanmoo1 , Gholamreza Abdi2* and Rashid Jamei3
1.Department of Horticulture, College of Agriculture, Persian Gulf University, Bushehr, 7516913817, Iran.
2.Department of Biotechnology, Persian Gulf Research Institute, Persian Gulf University, Bushehr, 7516913817, Iran.
3.Department of Biology, Faculty of Sciences, Urmia University, Urmia, Iran.
________________________________________________________________________________
Abstract
Allium stamineum, an endangered medicinal plant in Iran, requires conservation efforts through in vitro culture techniques. This study established an effective protocol for callus induction and bulblet regeneration in A. stamineum using various explant types (radicle, basal plate, and cotyledon) and growth regulators. The results indicated that the best callus formation from cotyledon explants occurred in media containing 1 mg/L 2,4-D, 1 mg/L 2,4-D with 0.5 mg/L BA, 2 mg/L 2,4-D with 0.5 mg/L kinetin, and 1 or 2 mg/L 2,4-D with 1 mg/L kinetin. In terms of regeneration, cotyledon explants showed the highest regeneration rate compared to radicle and basal plate explants, with 3.33 regenerations per explant in MS medium supplemented with 1 mg/L kinetin and 1 mg/L NAA. Additionally, the highest bulblet regeneration rate (11 per explant) was obtained from callus on PGR-free medium. The maximum number of roots (7.90) and root length (10.9 mm) were observed on MS medium containing 3 mg/L IBA. Rooted bulblets were successfully acclimatized in pots filled with a cockpit mixture (3:1 v/v) with a 100% survival rate. This study not only provides a successful in vitro propagation technique for A. stamineum but also facilitates its breeding program.
Keywords: Bulblets, Explant, Regeneration, IBA, Rooting
Ghahtan, N. , M. Hedayat , M. A. Kohanmoo , Gh.R. Abdi and R. Jamei, 2024. In vitro propagation of Allium stamineum: an endangered medicinal plant. Iranian Journal of Plant Physiology 14 (2), 5023-5033.
|
____________________________________ * Corresponding Author E-mail Address: abdi@pgu.ac.ir Received: November, 2023 Accepted: March, 2024
|
Materials and Methods
Plant Material
Seedlings of Allium stamineum were used as the initial explants. Seeds were collected from plants growing on clay-loam soil in an open plain in southeastern Borazjan County, Bushehr, in April 2018. After initial washing, the collected seeds were surface sterilized by treating with 2% (v/v) carbendazim for 30 minutes, followed by 75% ethanol for 60 seconds. The seeds were then immersed in a 20% (m/v) sodium hypochlorite (NaClO) solution for 10 minutes and rinsed three times with sterile double-distilled water. All sterilization procedures were carried out in a laminar airflow cabinet (Miao-miao Yan et al., 2009).
Basal Medium and Culture Conditions
Murashige and Skoog (MS) medium (1962) supplemented with different combinations of plant growth regulators (PGRs) [2,4-Dichlorophenoxyacetic acid (2,4-D), 6-Benzylaminopurine (BAP), Naphthalene acetic acid (NAA), and kinetin (Kin)], 3% (w/v) sucrose, and 0.8% agar was used. The pH of the medium was adjusted to 5.7±0.1 before autoclaving at 121°C for 15 minutes (Murashige and Skoog 1962; Farhadi, Panahandeh et al., 2017). Cultures were maintained at 22±2°C in a growth chamber with a 16/8-hour light/dark cycle, with light provided by Philips Luxeon LEDs made in China.
Effect of 2,4-D, Kinetin, and BAP on Callus Induction
The influence of explant type on callus induction in A. stamineum was assessed using three different explant types: radicle, basal plate, and cotyledon. Each explant, measuring around 5–7 mm in length, was placed on MS medium supplemented with various concentrations of growth regulators: 0 and 1 mg/L BAP, 0, 0.5, and 1 mg/L kinetin, and 1 and 2 mg/L 2,4-D.
Effect of Growth Regulators on Bud Proliferation
To assess the impact of explant type on bulblet and shoot regeneration in A. stamineum, three explant types—radicle, basal plate, and cotyledon—were used. Explants, measuring approximately 5 to 7 mm in length, were placed on MS medium supplemented with various concentrations of kinetin (0, 1, 2, and 4 mg/L) and NAA (1 and 2 mg/L). This experiment was conducted as a factorial design based on a completely randomized design.
Effect of Growth Regulators on Callus Proliferation
Fig. I. Effects of different growth regulator combinations on callus induction from various explants of A. stamineum. A) Comparisons of different explant types with the same growth regulators. B) Comparisons of different growth regulators on radicle induction. C) Comparisons of different growth regulators on basal plate induction. D) Comparisons of different growth regulators on cotyledon induction. The a-c above the columns indicate significant differences between each group.
Fig. III. Comparison of (A) vitamin C (B) vitamin E contents in different treatments on Portulaca oleracea L. The data is an average of three replicates ± SD. Non similar letters indicate significant differences between different treated groups.
|
B |
C |
A |
Root Induction
Excised single bulblets from the multiple bulblet clusters (proliferated on MS medium supplemented with kinetin, NAA, and IBA) were transferred to MS medium supplemented with different concentrations of IBA (1, 2, and 3 mg/L) for root induction. The number of roots per explant, the percentage of bulblets producing roots, and root length were recorded after 3 weeks.
D |
Three-week-old in vitro bulblets were gently washed under running tap water and transferred to pots filled with a cocopeat (75:25%) mixture. They were covered with plastic in the culture room. The plantlets were then acclimatized to the natural environment in the greenhouse.
Statistical Analysis
Fig. II. Effects of different growth regulator combinations on bulblet regeneration from various explants of A. stamineum. A) Comparisons of different explant types with the same growth regulators. B) Comparisons of different growth regulators on radicle regeneration. C) Comparisons of different growth regulators on basal plate regeneration. D) Comparisons of different growth regulators on cotyledon regeneration. The a-c above the columns indicate significant differences between groups (P < 0.05).
|
D |
C |
A |
Results
Effect of 2,4-D, Kinetin, and BAP on Callus Induction
The results demonstrated that the composition of growth regulators in the MS medium significantly influenced callus formation in Allium stamineum. The best callus formation from cotyledon explants was observed in media containing 1 mg/L 2,4-D, as well as in media supplemented with combinations of 1 mg/L 2,4-D and 0.5 mg/L BAP, 2 mg/L 2,4-D with 0.5 mg/L kinetin, and both 1 mg/L and 2 mg/L 2,4-D with 1 mg/L kinetin. These combinations resulted in dense, friable callus, which is considered optimal for subsequent regeneration experiments. The ability of 2,4-D in combination with cytokinins like BAP and kinetin to induce callus formation highlights the synergistic effects of auxins and cytokinins in promoting cell division and callus proliferation (Fig.I). This observation suggests that cotyledon explants are highly responsive to these specific combinations of growth regulators, making them a suitable explant choice for further tissue culture studies in A. stamineum.
Effect of Growth Regulators on Bud Proliferation
Fig. III. Effects of different growth regulator combinations on bulblet diameter from various explants of A. stamineum. A) Comparisons of different explant types with the same growth regulators. B) Comparisons of different growth regulators on radicle diameter. C) Comparisons of different growth regulators on basal plate diameter. D) Comparisons of different growth regulators on cotyledon diameter. The a-d above the columns indicate significant differences between groups (P < 0.05).
|
D |
C |
B |
Effect of Growth Regulators on Callus Proliferation
The study found that the presence of growth regulators in the media significantly influenced bulblet regeneration from A. stamineum callus. Specifically, media devoid of growth regulators (growth regulator-free) resulted in significantly lower rates of bulblet regeneration compared to media supplemented with kinetin and NAA (P < 0.05) (Fig. 4). This suggests that the presence of growth regulators is essential for the successful transition of callus into bulblets. The optimal regeneration was observed in calli that were cultured on MS medium containing 2 mg/L kinetin and 1 mg/L NAA, where robust bulblet formation occurred. The findings highlight the critical role of a carefully balanced hormonal environment in promoting not just callus proliferation, but also its subsequent differentiation into organogenic structures.
Rooting and Acclimatization
Fig. V. The effect of different combinations of growth regulators on bulblets regeneration of A. stamineum callus. The a-e above the columns show significant differences between each group (P<0.05).
|
Fig. IV. Effects of different growth regulator combinations on shoot regeneration from various explants of A. stamineum. A) Comparisons of different explant types with the same growth regulators. B) Comparisons of different growth regulators on radicle regeneration. C) Comparisons of different growth regulators on basal plate regeneration. D) Comparisons of different growth regulators on cotyledon regeneration. The a-e above the columns indicate significant differences between groups (P < 0.05).
|
B |
C |
D |
A |
Fig. VI. Effect of IBA on the in vitro rooting of bulblets of A. stamineum. The a-c above the columns show significant differences between each group (P<0.05).
|
Discussion
|
Methyl jasmonate-treated adventitious roots in Artemisia amygdalina L. have demonstrated a high level of antioxidant activity, up to 89%. Also, a high antioxidant activity (87%) has been recorded in the methyl jasmonate-treated adventitious root suspension cultures of Artemisia scoparia (Taj et al., 2019). When JA is added to the culture medium, Lavandula angustifolia tissues develop strong antioxidant capacities (Andrys et al., 2018). SA and JA showed elevated antioxidant activity in elicited cells of Panax ginseng L. (Ali et al., 2007), Artemisia absinthium (Ali and Abbasi, 2014), and Momordica dioica (Chung et al., 2017) compared to the non-elicited cells. Treatment of Hypericum perforatum cell suspensions with JA increased phenylalanine ammonium lyase (PAL) and chalcone isomerase (CHI) activity (Gadzovska et al., 2007).
One of the key enzymes in the phenylpropanoid biosynthesis pathway, which is crucial for the synthesis of flavonoids, lignin, phenols, and many other related compounds, is PAL (Zhang et al., 2015). Treating cell cultures with methyl jasmonate was shown to increase the production of PAL enzymes, leading to an increase in secondary metabolite production.
The phenolic content and taxol biosynthesis of cells also increased under SA treatment; therefore, increasing the concentration of SA induced the production of taxol (Caarls et al., 2015). In methyl jasmonate-treated cell suspension cultures with reduced anthocyanin content, the biosynthetic pathways from anthocyanins to phenolic compounds may have changed (Açikgöz et al., 2019). When JA was added to the Lavandula angustifolia Mill culture medium, the polyphenol content rose in comparison to the control (Andrys et al., 2018). In line with our findings, applying JA and SA raised the level of total phenols and flavonoids in cell suspension cultures of Panax ginseng L. (Ali and Abbasi, 2014) and Artemisia absinthium L. (Ali et al., 2015). Optimal concentrations (100 and 200 μM) of methyl jasmonate and SA as well as optimal exposure period resulted in increased total isoflavone in the cell suspension culture compared to the control (Halder et al., 2019). It has been recorded that the phytoecdysteroid levels increased following 14 days of treatment of Ajuga bracteosa with methyl jasmonate. Methyl jasmonate and phenylacetic acid (PAA) also increased the total phenolic and flavonoid contents in A. bracteosa root suspension (Saeed et al., 2017). PAL activity has been stimulated by the use of JA and methyl jasmonate in the production of high levels of flavonoids (Park et al., 2019).
Panax ginseng cultures were also treated with 500 μM methyl jasmonate and produced 28-fold more saponin than the control (Lu et al., 2001). A threefold increase in saponin production was observed when 0.2 mM SA was applied to adventitious roots of Panax ginseng L. (Lu et al., 2001). JA increased the production of ginsenosides in cell suspension leading to an increase in total saponin content by synthesizing ginsenosides (Lu et al., 2001). In Glycyrrhiza glabra var. violacea (Boiss.), treatment with 2 mM methyl jasmonate and 1 mM SA led to increased saponin production by 3.8 and 4.5 times (Shabani et al., 2009). β-AS, SS, and SE transcript levels in Medicago cell culture were unaffected by the inclusion of SA in the culture medium; however, 24 hours after the cultured cells were exposed to 500 μM methyl jasmonate, β-AS transcription increased by about 50 times (Suzuki et al., 2005).
In the 23-day-old hairy root culture of Rehmannia glutinosa, the addition of methyl jasmonate (50 μM) and SA (100 μM) in combination increased the production of iridoids (catalpol and harpagide) and phenylethanoids (verbascoside and isoverbascoside) compared to the control (Piatezak et al., 2016). By treating the hairy root culture of Rhinacanthus nasutus with methyl jasmonate and SA, biomass accumulation decreased, and the content of a group of naphthoquinone esters increased compared to the control (Cheruvathur and Thomas, 2014). When methyl jasmonate and/or SA are applied, the expression levels of important genes in the morphine biosynthesis pathway play an imperative role in the accumulation of these alkaloids at different times. Compared to the control, in methyl jasmonate treatment, the expression of key genes coding SalSyn, SalR, SalAT, and CODM increased and caused the accumulation of thebaine, morphine, and codeine in plants. SA treatment increases morphine accumulation by increasing the regulation of SalSyn, T6ODM, and CODM genes (Halder et al., 2019).
The effect of different concentrations of methyl jasmonate (100, 150, and 200 μM) and SA (125, 250, and 500 μM) was investigated on dopamine production in Portulaca oleracea root culture. Results showed that treatment with 100 μM methyl jasmonate increased dopamine in cells by 4.3-fold compared to the control. Treatment with SA did not affect dopamine levels (Moghadam et al., 2001).
In Tripterygium wilfordii hair root culture, treatment with methyl jasmonate (50 μM) dramatically stimulated the production of epitrophenidol (tryptolide) and wilfurine, although it resulted in a minor reduction in the concentration of a sesquiterpene pyridine alkaloid. On the other hand, treatment with the same concentration of salicylic acid (SA) had no significant effect on hair root growth and had very little effect on the production of this secondary metabolite (Zhu et al., 2014).
SA influences post-translational modifications of transcription factors and regulators, which in turn influence the activity and localization of transcriptional regulators. Through thioredoxin and glutaredoxin, SA alters the transcriptional regulators responsible for the inhibition of JA-dependent genes. SA affects the transcription stimulated by JA. In order to activate JA signaling, JA-responsive transcription factors must first be destroyed and detached from their target genes. SA can then bind to suppressive proteins in the nucleus or bind to the genes in the cytosol. At the DNA level, changes in histones by SA-dependent factors suppress JA-dependent genes (Halder et al., 2019).
Conclusion
Concomitant treatment of Portulaca oleracea with JA and SA increased the antioxidant capacity of the cell suspension by enhancing the levels of secondary metabolites such as phenols, flavonoids, alkaloids, and terpenoids.
References
Ayabe, M. and S. Sumi. 1998. Establishment of a novel tissue culture method, stem-disc culture, and its practical application to micro propagation of garlic (Allium sativum L.). Plant Cell Reports. 17(10): 773-779.
Ayed, C., C. Bayoudh, A. Rhimi, N. Mezghani, F. Haouala and B. AL Mohandes Dridi. 2018. In vitro propagation of Tunisian local garlic (Allium sativum L.) from shoot tip culture. Journal of Horticulture and Postharvest Research 1(2): 75-86.
Bikis, D. 2018. Review on the application of biotechnology in garlic (Allium sativum) improvement. International Journal of Research Studies in Agricultural Sciences 4(11): 23-33.
Ebrahimi, R., Z. Zamani and A. Kashi. 2009. Genetic diversity evaluation of wild Persian shallot (Allium hirtifolium Boiss.) using morphological and RAPD markers. Scientia Horticulturae 119(4): 345-351.
Farhadi, N., J. Panahandeh, A. M. Azar and S. A. Salte. 2017. Effects of explant type, growth regulators and light intensity on callus induction and plant regeneration in four ecotypes of Persian shallot (Allium hirtifolium). Scientia Horticulturae 218: 80-86.
Frebort, I., M. Kowalska, T. Hluska, J. Frébortová and P. Galuszka. 2011. Evolution of cytokinin biosynthesis and degradation. Journal of Experimental Botany 62(8): 2431-2452.
Haque, M. S., T. Wada and K. Hattori. 2003. Shoot regeneration and bulblet formation from shoot and root meristem of garlic cv Bangladesh local. Asian Journal of Plant Science 2(1): 23-27.
Jeong, M. J. and S. H. Yong. 2022. Rapid micropropagation of wild garlic (Allium victorialis var. platyphyllum) by the scooping method. Journal of Plant Biotechnology 49(3): 213-221.
Khan, N., M. Alam and U. Nath. 2004. In vitro regeneration of garlic through callus culture." Journal of Biological Sciences 4(2): 189-191.
Luciani, G. F., A. K. Mary, C. Pellegrini and N. R. Curvetto. 2006. Effects of explants and growth regulators in garlic callus formation and plant regeneration. Plant cell, tissue and organ culture 87: 139-143.
Marrelli, M., V. Amodeo, G. Statti and F. Conforti. 2018. "Biological properties and bioactive components of Allium cepa L.: Focus on potential benefits in the treatment of obesity and related comorbidities. Molecules 24(1): 119.
Mehta, J., A. Sharma, N. Sharma, S. Meghwal, G. Sharma, P. Gehlot and R. Naruka. 2013. An Improved Method for Callus Culture and, Vitro. International Journal of Pure Applied Bioscience 1 (1): 1-6
Murashige, T. and F. Skoog. 1962. A revised medium for rapid growth and bio assays with tobacco tissue cultures. Physiologia plantarum 15(3): 473-497.
Nabavi, S. M., M. Saeedi, S. F. Nabavi and A. S. Silva 2020. Recent advances in natural products analysis. Elsevier, Amsterdam, XXIII-XXIII. ISBN 978-0-12-817519-4; 978-0-12-816455-6
Pop, T. I., D. Pamfil and C. Bellini 2011. "Auxin control in the formation of adventitious roots. Notulae Botanicae Horti Agrobotanici Cluj-Napoca 39(1): 307-316.
Razyfard, H., S. Zarre, R. M. Fritsch and H. Maroofi. 2011. Four new species of Allium (Alliaceae) from Iran. Annales Botanici Fennici 48(4), 352-360
Scotton, D. C., V. A. Benedito, J. B. de Molfetta, B. I. F. Rodrigues, A. Tulmann-Neto and A. Figueira , 2013. Response of root explants to in vitro cultivation of marketable garlic cultivars. Horticultura Brasileira 31: 80-85.
Sharifi-Rad, J., D. Mnayer, G. Tabanelli, Z. Stojanović-Radić, M. Sharifi-Rad, Z. Yousaf, L. Vallone, W. Setzer and M. Iriti. 2016. Plants of the genus Allium as antibacterial agents: From tradition to pharmacy. Cellular and Molecular Biology 62(9): 57-68.
Tubić, L., J. Savić, N. Mitić, J. Milojević, D. Janošević, S. Budimir and S. Zdravković-Korać. 2016. Cytokinins differentially affect regeneration, plant growth and antioxidative enzymes activity in chive (Allium schoenoprasum L.). Plant Cell, Tissue and Organ Culture 124: 1-14.
Xu, Z., Y.-C. Um, C.-H. Kim, G. Lu, D.-P. Guo, H.-L. Liu, A. A. Bah and A. Mao. 2008. Effect of plant growth regulators, temperature and sucrose on shoot proliferation from the stem disc of Chinese jiaotou (Allium chinense) and in vitro bulblet formation. Acta Physiologiae Plantarum 30: 521-528.
Zheng, S., B. Henken, E. Sofiari, P. Keizer, E. Jacobsen, C. Kik and F. Krens 1999. Effect of cytokinins and lines on plant regeneration from long-term callus and suspension cultures of Allium cepa L. Euphytica 108: 83-90.
.