Micropropagation and medium-term conservation of Rosa pulverulenta

Kavand, Somayeh; Kermani, Maryam Jafarkhani; Haghnazari, Ali; Khosravi, Pegah; Azimi, Mohamad Reza

doi:10.4025/actasciagron.v33i2.10279

Abstracts

In Iran, a large number of Rosa species have been exposed to extinction and therefore preservation techniques are necessary to safeguard their future. In the present investigation, the objectives were to optimize the micropropagation and medium-term conservation of one of these wild species, Rosa pulverulenta. At proliferation stage, the maximum number of new leaves (9.6) were produced on the medium containing 4 μM BAP + 0 μM GA3, whereas the maximum number of axillary shoots (4.1) were observed in the medium containing 4 μM BAP + 3 μM GA3. The results for rooting experiments suggested that the highest increase in stem height (49.5 mm) at the acclimatization stage was observed in plantlets treated with 1 μM IBA + 0.5 μM NAA during the rooting stage. Comparing the refrigerator and phytotron conditions for medium-term conservation of in vitro plantlets indicated that although the refrigerator conditions resulted in lower growth rate compared with the phytotron, the survival rate in refrigerator (100%) was significantly higher than phytotron (87.5%). Furthermore, the growth rate of the plantlets from the refrigerator was accelerated during the recovery period and verged on to the ones stored in the phytotron.

in vitro conservation; micropropagation; proliferation; recovery; rooting; Rosa pulverulenta

No Irã, um número grande de espécies de Rosa são expostas à extinção. Por causa disto, as técnicas de preservação são necessárias para garantir o futuro destas mesmas espécies. Nesta investigação, os objetivos foram aperfeiçoar a micropropagação e preservar durante médio prazo uma destas espécies, Rosa pulverulenta. No estádio de proliferação, o número máximo de novas folhas (9,60) foi produzido no meio contendo 4 μM BAP + 0 μM GA3, mas o número máximo de gemas axilares foi observado no meio com 4 μM BAP + 3 μM GA3. Os resultados obtidos permitiram inferir que o maior aumento na altura de haste (49,5 mm) durante o estádio de climatização foi observado nos explantes tratados com 1 μM IBA + 0,5 μM NAA durante o enraizamento. Observa-se que embora a geladeira tenha proporcionado uma menor taxa de crescimento, a sobrevivência em médio prazo foi maior (100,00%) do que no phytotron (87,50%). Além disto, a taxa de crescimento dos explantes que foram mantidos na geladeira foi acelerada durante o periodo de recuperação e ficaram próximas daquelas mantidas no phytotron.

preservação in vitro; micropropagação; proliferação; recuperação; enraizamento; Rosa pulverulenta

CROP PRODUCTION

Micropropagation and medium-term conservation of Rosa pulverulenta

Micropropagação e conservação durante médio prazo de Rosa pulverulenta

Somayeh Kavand; Maryam Jafarkhani Kermani^* * Author for conrrespondence. E-mail: maryam.j.kermani@gmail.com ; Ali Haghnazari; Pegah Khosravi; Mohamad Reza Azimi

Tissue Culture and Gene Transformation Department, Agricultural Biotechnology Research Institute of Iran,Islamic Republic of Iran

ABSTRACT

In Iran, a large number of Rosa species have been exposed to extinction and therefore preservation techniques are necessary to safeguard their future. In the present investigation, the objectives were to optimize the micropropagation and medium-term conservation of one of these wild species, Rosa pulverulenta. At proliferation stage, the maximum number of new leaves (9.6) were produced on the medium containing 4 μM BAP + 0 μM GA₃, whereas the maximum number of axillary shoots (4.1) were observed in the medium containing 4 μM BAP + 3 μM GA₃. The results for rooting experiments suggested that the highest increase in stem height (49.5 mm) at the acclimatization stage was observed in plantlets treated with 1 μM IBA + 0.5 μM NAA during the rooting stage. Comparing the refrigerator and phytotron conditions for medium-term conservation of in vitro plantlets indicated that although the refrigerator conditions resulted in lower growth rate compared with the phytotron, the survival rate in refrigerator (100%) was significantly higher than phytotron (87.5%). Furthermore, the growth rate of the plantlets from the refrigerator was accelerated during the recovery period and verged on to the ones stored in the phytotron.

Keywords:in vitro conservation, micropropagation, proliferation, recovery, rooting, Rosa pulverulenta.

RESUMO

No Irã, um número grande de espécies de Rosa são expostas à extinção. Por causa disto, as técnicas de preservação são necessárias para garantir o futuro destas mesmas espécies. Nesta investigação, os objetivos foram aperfeiçoar a micropropagação e preservar durante médio prazo uma destas espécies, Rosa pulverulenta. No estádio de proliferação, o número máximo de novas folhas (9,60) foi produzido no meio contendo 4 μM BAP + 0 μM GA3, mas o número máximo de gemas axilares foi observado no meio com 4 μM BAP + 3 μM GA3. Os resultados obtidos permitiram inferir que o maior aumento na altura de haste (49,5 mm) durante o estádio de climatização foi observado nos explantes tratados com 1 μM IBA + 0,5 μM NAA durante o enraizamento. Observa-se que embora a geladeira tenha proporcionado uma menor taxa de crescimento, a sobrevivência em médio prazo foi maior (100,00%) do que no phytotron (87,50%). Além disto, a taxa de crescimento dos explantes que foram mantidos na geladeira foi acelerada durante o periodo de recuperação e ficaram próximas daquelas mantidas no phytotron.

Palavras-chaves: preservação in vitro, micropropagação, proliferação, recuperação, enraizamento, Rosa pulverulenta.

Introduction

Micropropagation has five major advantages compared to the conventional methods of plant propagation: (i) it is an invaluable aid in the multiplication of elite clones of intractable/ recalcitrant species; (ii) it is important in terms of multiplying plants throughout the year, with control over most facets of production; (iii) it is possible to generate pathogen-free plants even from explants of infected mother plants; (iv) plant materials such as male sterile, fertility maintainer and restorer lines can be cloned; and (v) it enables the production of a large number of plants in a short time from a selected number of genotypes (RANI; RAINA, 2000).

Micropropagated explants require less space and labor inputs for the maintenance of germplasm collections (RAJASEKHARAN, 2006). The in vitro conservation methods are considered particularly interesting for those horticultural species that are propagated by vegetative methods as well as those with recalcitrant seeds (SHIKHAMANY, 2006).

A variety of approaches have been used separately or in combination to reduce the growth rate of in vitro plant tissues. Probably, the most successful strategies have involved temperature reductions, but the responses vary significantly between and within species. Slow growth is used as a short-term to medium-term conservation in many laboratories, including the Centro Internacional de la Papa (CIP) and Centro Internacional de Agricultura Tropical (CIAT) (ENGELMANN, 1991).

More than 200 species are present in the genus Rosa (WISSEMANN, 2003) from which 14 wild species are present in Iran. Rosa pulverulenta is a small bush (50 to 100 cm) with small pink (and rarely white) solitary flowers (10-25 mm in diameter) or clusters with 2-4 flowers.R. pulverulenta usually grows in Asia, south east Europe including west Syria, Caucasus, Azerbaijan, Armenia, Iran and Afghanistan (ERCISLI, 2005). Traditionally, most roses are heterozygous and do not breed true to type. Therefore, they are propagated by vegetative methods. Since most rose species are difficult to root, conventional propagating methods are very slow, time consuming, and tiring. Tissue culture on the other hand is becoming increasingly popular as an alternative to the conventional plant propagation methods (ROBERTS; SCHUM, 2003).

In Iran, a large number of Rosa species have been exposed to extinction and therefore preservation techniques are necessary to safeguard their future. The present investigation is the first report on in vitro propagation and medium-term conservation of one of these species, R. pulverulenta.

Material and methods

Plant material and culture conditions

Nodal segments (1-1.5 cm) of R. pulverulenta were collected from the Rose Germplasm Collection at the Agricultural Biotechnology Research Institute of Iran (ABRII). They were sterilized (KHOSRAVI et al., 2007) and transferred to induction medium containing full strength VS (VAN der SALM, 1994) mineral salts and vitamins, 2.7 g L^-1 calcium gluconate and 2 μM 6-benzylaminopurine (BAP). The pathogen-free explants were then used in the proliferation and rooting stages of micropropagation.

The pH of all media was adjusted to 5.8 using 1.0 N potassium hydroxide (KOH) or 1.0 N hydrochloric acid (HCl), before adding 7 g L^-1 plant agar. Media were autoclaved for 15 min. at 121ºC and 1.2 kgf cm^-1 pressure. All the in vitro cultures were placed under high pressure metal halide lamps (PPFD 60 μmol m^-2 s^-1 at the plant surface) on a 16/8 hour light/dark cycle in a culture room maintained at 20 ± 2ºC.

In vitro propagation stages

Proliferation stage: Proliferation media contained full strength VS medium, 2.7 g L^-1 calcium gluconate with various concentrations of BAP (0, 2, 4, 8 and 16 μM) in combination with giberellic acid (0 and 3 μM GA₃).

Elongation stage: In vitro, shoots were cultured on shoot elongation medium containing full strength VS mineral salt and vitamins, devoid of hormones, for 21 days before induction to rooting stage.

Rooting stage: Different levels of 3-Indolebutyric acid (IBA) (0, 0.25, 0.5 and 1 μM) in combination with 1-Naphtalene acetic acid (NAA) (0, 0.5 μM) were used in liquid media containing half strength VS salts, full amounts of vitamins, half levels of sucrose and 2.7 g L^-1 calcium gluconate. The shoots were supported by the cellulose plugs called sorbarods (sorbarod, Ilacon, UK).

Acclimatization stage: Plantlets were acclimatized according to our previous report (KHOSRAVI et al., 2007).

In vitro conservation and recovery of shoots

Preservation of in vitro shoots encompassing 3 leaves was carried out in two conditions: refrigerator (4-6ÚC) in complete darkness and phytotron (20 ± 2ÚC) with 16/8 hour light/dark cycle (as control). All the shoots were cultured in the optimized proliferation medium (containing 4 mM of BAP and 3 mM of GA₃). The survived shoots were also transferred to optimized proliferation medium during the recovery phase.

Experimental design and statistical analysis

The shoot proliferation experiment was performed in a factorial based completely random design with 2 observations and 5 replications. Number of new leaves, ratio of green leaves to total number of leaves, plant height and number of axillary shoots were recorded after four weeks.

Rooting experiment, in vitro conservation and recovery of shoots were carried out in a factorial based completely random design with 3 observations and 5 replications. In the rooting stage, the percentage of rooting, number of roots per plantlet and total root length per plantlet were recorded after four weeks. In the acclimatization stage, the percentage of survival and stem height were compared in plants obtained from different rooting treatments after two weeks. Morphological parameters such as percentage of survival, number of new leaves, plant height, number of axillary shoots, and ratio of green leaves to total number of leaves were recorded after six months and four weeks for the conservation experiments and recovery phase, respectively. Analysis of variance was performed and comparisons of means were conducted using DuncanMs Multiple Range test. All analyses were regarded as significant if p value was less than 0.05.

Results and discussion

Shoot proliferation

Maximum number of new leaves (9.6) was produced on the medium containing 4 μM BAP + 0 μM GA₃ (Figure 1A), whereas the ratios of green leaves to total number of leaves were not significantly different between most of the treatments (Figure 1B). The maximum number of axillary shoots (4.1) was observed in the medium containing 4 μM BAP + 3 μM GA₃ (Figure 1C) and the highest increase in plant height (0.71 cm) was observed in the medium containing 2 μM BAP + 3 μM GA₃ (Figure 1D).

The results of the present study demonstrated that inclusion of 3μM GA₃ to the culture media significantly increased the number of axillary shoots and stem height in all of the BAP concentrations. Kim et al. (2003) indicated that in vitro shoot proliferation and multiplication are largely based on media formulations containing cytokinins as major plant growth regenerators, although low concentrations of auxins or GA₃ are also essential. The results showed that in some of the parameters the differences between the treatments were not significant, however, the maximum number of axillary shoots were significantly higher in the medium containing 4 mM of BAP and 3 mM of GA₃. As the concentration of BAP was raised to more than 4 mM, a reduced growth rate was noted (Figure 2A) which is in accordance with our previous report on in vitro propagation of Rosa hybrida cv. Iceberg where high concentrations of BAP resulted in reduced rates of growth (KHOSRAVI et al., 2007).

Root initiation and acclimatization

The Table 1 illustrates the response of in vitro shoots treated with media containing different concentrations of IBA and NAA. Although there was no significant difference among all the treatments in the percentage of rooting and even in the hormone-free medium, 73.3% of seedlings produced roots.

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The highest percentage (93.3%) of rooting was obtained on the medium containing 0.25 μM IBA + 0.5 μM NAA. The longest root length per plantlet (64.7 mm) and the highest number of roots per plantlet (5) were recorded in the medium containing 1 μM IBA+ 0.5 μM NAA (Table 1). At acclimatization stage most of the plantlets from different rooting media had 100% survival rate, whereas the highest increase in stem height (49.5 mm) was observed in plantlets treated with 1 μM IBA + 0.5 μM NAA during the rooting stage (Table 2). According to Roberts and Schum (2003), roses are usually rooted in media containing different levels of salts and vitamins, often reduced to 1/4 or 1/2 strength, containing NAA, indole acetic acid (IAA), or both.

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The present investigation recommended a combination of IBA (1 μM) and NAA (0.5 μM) for in vitro rooting of R. pulverulenta. This is in agreement with Roy et al. (2004) who also found that a combination of auxins (1 mg L^-1 IBA and 0.5 mg L^-1 IAA) was needed for in vitro rooting of roses.

In vitro conservation and recovery of shoots

The stored plantlets had higher survival rates in the refrigerator but had considerable higher growth rate in the phytotron. Percentages of survived seedlings in phytotron and refrigerator were 87.5 and 100%, respectively. Average increase in stem height, average number of new leaves and average number of axillary shoots of the plantlets stored in phytotron and refrigerator were 19.5, 42.2 and 3.53 mm and 2.1, 2.47 and 0.87 mm, respectively (Figure 2A and B). Comparing the ratio of green leaves to total number of leaves between the plantlets maintained in the phytotron and refrigerator indicated that there was no significant difference between them (Figure 2B). At the recovery stage, the growth rate of the plantlets stored in the refrigerator verged on to the ones that were stored in the phytotron. There was not a significant difference in average number of new leaves, ratio of green leaves to total number of leaves and average number of axillary shoots between the two storage conditions (Figure 2C and D). However, during the recovery period, average increase in stem height was significantly higher in the plantlets maintained in the refrigerator (4.8 mm) compared to the ones stored in the phytotron (1.1 mm) (Figure 2C). These observations are in agreement with Williams et al. (1997) who investigated the storage of in vitro shoot cultures of eight clones or cultivars of Camellia japonica L. and Camellia reticulate Lindley at 2-4°C for up to 12 months. They obtained 100% survival frequencies during the first or second sub-cultures after cold storage of seven in the eight clones assayed.

A combination of cold treatment and complete darkness slows the biological processes and hence the growth rate of plants. In the present investigation refrigerator condition resulted in lower growth rate of the plantlets, but the survival rate of the plantlets was significantly higher than those plantlets stored in the phytotron. Moreover, the growth rate of the plantlets from the refrigerator was accelerated during the recovery period. Therefore, storage in the refrigerator is considered an effective method for medium-term conservation of R. pulverulenta. Holobiuc et al. (2009) suggested that in vitro preserved material could be used as ex situ conservation source, and the effective propagation and medium-term conservation methods developed in the present study could be used as the basis for development of long-term conservation of R. pulverulenta.

Conclusion

In conclusion, the present investigation recommended a practicable, in vitro propagation and medium-term conservation protocol for R. pulverulenta. At the proliferation stage, maximum number of axillary shoots was achieved in the medium containing 4 mM of BAP and 3 mM of GA₃. At the rooting stage, a combination of IBA (1 μM) and NAA (0.5 μM) was eefective. The plantlets stored in the refrigerated had a low growth rate, but at the recovery stage, their growth rate verged on to the ones that were stored in the phytotron, therefore, storage in the refrigerator was considered an effective method for medium-term conservation and possibly for development of long-term conservation of R. pulverulenta.

Acknowledgements

This work was a part of MSc thesis on Plant Breeding, University of Zanjan, funded by the Agricultural Biotechnology Research Institute of Iran (ABRII) (Project number: 2-05-05-01-86004).

Received on May 28, 2010.

Accepted on September 14, 2010.

License information: This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

ENGELMANN, F. In vitro conservation of tropical plant germplasm- review. Euphytica, v. 57, n. 3, p. 227-243, 1991.
ERCISLI, S. R. (Rosa spp.) germplasm resources of Turckey. Genetic Research and Crop Evolution, v. 52, n. 6, p. 787-795, 2005.
HOLOBIUC, I.; BLINDU, R.; CRISTIA, V. Researches concerning in vitro conservation of the rare plant species Dianthus nardiformis Janka. Biotechnology and Biotechnological Equipment, Special Edition on Line, 2009.
KHOSRAVI, P.; JAFARKHANI KERMANI, M.; NEMATZADEH, G. A.; BIHAMTA, M. R. A protocol for mass production of Rosa hybrida cv. Iceberg through in vitro propagation. Iranian Journal of Biotechnology, v. 5, n. 1, p. 100-104, 2007.
KIM, C. H.; CHUNG, J. D.; JEE, S. O.; OH, J. Y. Somatic embryogenesis from in vitro grown leaf explants of Rosa hybrida L. Journal of Plant Biotechnology, v. 5, n. 3, p. 169-172, 2003.
RAJASEKHARAN, P. E. In vitro conservation of horticultural crops. In: ICAR short course on in vitro conservation and cryopreservation new options to conserve horticultural genetic resources Hessaraghatta Lake: Indian Institute of Horticultural Research, 2006. p. 66-73.
RANI, V.; RAINA, S. N. Genetic fidelity of organized meristem-derived micropropagated plants: A critical reappraisal. In vitro cellular and developmental biology-plant, v. 36, n. 5, p. 319-330, 2000.
ROBERTS, A. V.; SCHUM, A. Cell tissue and organ culture. In: ROBERTS, A. V.; DEBENER, T.; GUDIN, S. (Ed.). Encyclopedia of rose science Oxford: Elsevier Academic Press, 2003. p. 57-110.
ROY, P. K.; MAMUN, A. N. K.; AHMED, G. In vitro plantlet regeneration of rose. Plant Tissue Culture, v. 14, n. 2, p. 149-154, 2004.
SHIKHAMANY, S. D. Horticultural genetic resources: role of ex situ conservation. In: ICAR short course on in vitro conservation and cryopreservation new options to conserve horticultural genetic resources Hessaraghatta Lake: Indian Institute of Horticultural Research, 2006. p. 6-15.
VAN der SALM, T. P. M.; VAN der TOORN, C. J. G.; HANISCH ten CATE, C. H.; DUBOIS, L. A. M.; DE VRIES, D. P.; DONS, H. J. M. Importance of the iron chelate formula for micropropagation of Rosa hybrida L. Money way T. Plant Cell Tissue and Organ Culture, v. 37, n. 1, p. 73-77, 1994.
WILLIAMS, J. C.; LOYACANO, A. F.; BROUSSARD, S. D.; COOMBS, D. F.; WALSTROM, D.; BALLESTER, A.; JANERIO, L. V.; VIEITEZ, A. M. Cold storage of shoot cultures and alginate encapsulation of shoot tips of Camellia japonica L. and Camellia reticulate Lindley. Scientia Horticulturae, v. 71, n. 1, p. 67-78, 1997.
WISSEMANN, V. Classification. In: ROBERTS, A. V.; DEBENER, T.; GUDIN, S. (Ed.). Encyclopedia of rose science Oxford: Elsevier Academic Press, 2003. p. 111-117.

*

Author for conrrespondence. E-mail:

maryam.j.kermani@gmail.com

Publication Dates

Publication in this collection
24 May 2011
Date of issue
June 2011

History

Received
28 May 2010
Accepted
14 Sept 2010

This work is licensed under a Creative Commons Attribution 4.0 International License.

[1] ENGELMANN, F. In vitro conservation of tropical plant germplasm- review. Euphytica, v. 57, n. 3, p. 227-243, 1991.

[2] ERCISLI, S. R. (Rosa spp.) germplasm resources of Turckey. Genetic Research and Crop Evolution, v. 52, n. 6, p. 787-795, 2005.

[3] HOLOBIUC, I.; BLINDU, R.; CRISTIA, V. Researches concerning in vitro conservation of the rare plant species Dianthus nardiformis Janka. Biotechnology and Biotechnological Equipment, Special Edition on Line, 2009.

[4] KHOSRAVI, P.; JAFARKHANI KERMANI, M.; NEMATZADEH, G. A.; BIHAMTA, M. R. A protocol for mass production of Rosa hybrida cv. Iceberg through in vitro propagation. Iranian Journal of Biotechnology, v. 5, n. 1, p. 100-104, 2007.

[5] KIM, C. H.; CHUNG, J. D.; JEE, S. O.; OH, J. Y. Somatic embryogenesis from in vitro grown leaf explants of Rosa hybrida L. Journal of Plant Biotechnology, v. 5, n. 3, p. 169-172, 2003.

[6] RAJASEKHARAN, P. E. In vitro conservation of horticultural crops. In: ICAR short course on in vitro conservation and cryopreservation new options to conserve horticultural genetic resources Hessaraghatta Lake: Indian Institute of Horticultural Research, 2006. p. 66-73.

[7] RANI, V.; RAINA, S. N. Genetic fidelity of organized meristem-derived micropropagated plants: A critical reappraisal. In vitro cellular and developmental biology-plant, v. 36, n. 5, p. 319-330, 2000.

[8] ROBERTS, A. V.; SCHUM, A. Cell tissue and organ culture. In: ROBERTS, A. V.; DEBENER, T.; GUDIN, S. (Ed.). Encyclopedia of rose science Oxford: Elsevier Academic Press, 2003. p. 57-110.

[9] ROY, P. K.; MAMUN, A. N. K.; AHMED, G. In vitro plantlet regeneration of rose. Plant Tissue Culture, v. 14, n. 2, p. 149-154, 2004.

[10] SHIKHAMANY, S. D. Horticultural genetic resources: role of ex situ conservation. In: ICAR short course on in vitro conservation and cryopreservation new options to conserve horticultural genetic resources Hessaraghatta Lake: Indian Institute of Horticultural Research, 2006. p. 6-15.

[11] VAN der SALM, T. P. M.; VAN der TOORN, C. J. G.; HANISCH ten CATE, C. H.; DUBOIS, L. A. M.; DE VRIES, D. P.; DONS, H. J. M. Importance of the iron chelate formula for micropropagation of Rosa hybrida L. Money way T. Plant Cell Tissue and Organ Culture, v. 37, n. 1, p. 73-77, 1994.

[12] WILLIAMS, J. C.; LOYACANO, A. F.; BROUSSARD, S. D.; COOMBS, D. F.; WALSTROM, D.; BALLESTER, A.; JANERIO, L. V.; VIEITEZ, A. M. Cold storage of shoot cultures and alginate encapsulation of shoot tips of Camellia japonica L. and Camellia reticulate Lindley. Scientia Horticulturae, v. 71, n. 1, p. 67-78, 1997.

[13] WISSEMANN, V. Classification. In: ROBERTS, A. V.; DEBENER, T.; GUDIN, S. (Ed.). Encyclopedia of rose science Oxford: Elsevier Academic Press, 2003. p. 111-117.

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Micropropagation and medium-term conservation of Rosa pulverulenta

Micropropagação e conservação durante médio prazo de Rosa pulverulenta

Abstracts

Publication Dates

History