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Biocell

Print version ISSN 0327-9545

Biocell vol.26 no.3 Mendoza Aug./Dec. 2002

 

In vitro propagation of Opuntia ellisiana Griff. and acclimatization to field conditions

María Cecilia Juárez1 , Carlos Bernardo Passera 1-2

1. Centro Regional de Investigaciones Científicas y Tecnológicas (CRICYT), Instituto Argentino de Investigaciones de las Zonas Áridas (IADIZA). C.C. 507, 5500 Mendoza, Argentina. E-mail: mcjuarez@lab.cricyt.edu.ar
2. Facultad de Ciencias Agrarias, Universidad Nacional de Cuyo. C.C. 7, 5505 Chacras de Coria, Mendoza, Argentina. E-mail: cpassera@lab.cricyt.edu.ar; cpassera@fca.uncu.edu.ar

Address correspondence to: Lic. M. Cecilia Ju‡rez. IADIZA, CRICYT, Casilla de Correo 507, (5500) Mendoza,
ARGENTINA. Fax: (+54 261) 428 0080. E-mail: mcjuarez@lab.cricyt.edu.ar

Key words: Micropropagation. Areole culture. Cold hardy forage. Arid forage resources.

Abstract: The genus Opuntia is a valuable forage resource in arid and semiarid lands during periods of drought and shortage of herbaceous plants. However, absolute minimum temperatures in the plains of Mendoza represent a limiting factor to cultivate several species.Opuntia ellisiana is a cold hardy species, so the goals of this study were to massively propagate it using in vitro culture techniques, and then to acclimatize plantlets obtained to field conditions. Different sterilization protocols were tested. Areoles were isolated in laminar airflow cabinet, and cultured on Murashige-Skoog medium, supplemented with sucrose and different BAP and IBA combinations. Explants were grown at 27±2ºC, under a 16-h photoperiod. The shoots produced were used in the rooting assay using different auxin combinations. In the most eff icient growth treatment, plantlets reached 100% shooting after 35 days of culture, and a mean length of 10.2 mm after 49 days of culture. A 100% rooted plantlets was obtained on a medium containing 5 mg L -1 IBA, after 12 days of culture. Acclimatization was achieved under greenhouse conditions, showing 100% plantlet survival.This study suggests that O. ellisiana can be successfully micropropagated by areoles, and easily acclimatizated to field conditions.

Abbreviations: benzylaminopurine (BAP); indole-3-butyric acid (IBA); basal medium (BM).

Introduction

The genus Opuntia (Cactaceae) has a specialized photosynthetic mechanism known as Crassulacean Acid Metabolism (CAM), whereby these plants open their stomates and take up CO 2 at night, when temperatures are lower and humidity higher than during the daytime. This invariably results in reduced water loss (Nobel, 1995; Taiz and Zeiger, 1998).
Owing to its high water-use efficiency (even in areas with annual rainfall values as low as 120-150 mm), and its high drought-tolerance (Le Houérou, 1994), this cactus is a valuable forage resource in arid and semiarid lands during periods of drought and shortage of herbaceous plants.
Previous studies have addressed the economic feasibility of producing Opuntia ficus-indica Mill. cactus pear fruit (Guevara and Pizzi, 1998) and forage (Guevara et al., 1999) in the Mendoza plains, where soil features and rainfall values suggest that O. ficus-indica could be successfully grown.
However, extremely low temperatures restrict the areas where O. ficus-indica and other Opuntia species can be grown. Sensitivity to low temperatures varies greatly among species of Opuntia. Various commercial species, such as O. ficus-indica and O. streptacantha Lem., are killed at –5º to –8ºC (Nobel, 1995).
Observations of several species established in the Mendoza plains have suggested that very low winter temperatures lasting 11 to 13 h are the major limiting factor affecting cultivation in this area. Some field assays showed that when night temperatures dropped to –17ºC, young cladodes from 9-month-old plants of O. ficus-indica were almost totally destroyed, whereas 3-year-old plants of O. ficus-indica, O. spinulifera Salm-Dyck f. nacunniana Le Houér., f. nov. and O. robusta Wend. had mean frost damages of 25%, 5%, and 2%, respectively (Guevara and Estevez, 2001; Guevara et al., 2000).
In contrast, some species show high tolerance to low temperatures, such as the spineless Opuntia ellisiana that experienced no damage from temperatures of -20ºC (Wang et al., 1997).
Despite being the slowest growing of all spineless Opuntia species, O. ellisiana exhibits high water-use efficiency (162 kg H 2 O kg -1 dry matter). In fact its water-use efficiency is higher than that of any other plant species (including C 3 and C 4 ) measured under long-term field conditions (Han and Felker, 1997).
On this account, O. ellisiana could be a useful forage variety in locations that prove too cold for O. robusta Wend. or O. ficus-indica (Han and Felker, 1997). O. ellisiana’s cold hardiness, its economic potential for forage production, and the low availability of material for propagation justified the application of in vitro propagation techniques. An efficient massive multiplication in reduced space and time (Escobar et al., 1986; Pimienta-Barrios, 1990; Rubluo et al., 1996) characterizes micropropagation, while genetic stability is maintained, and plant health and vigor increase (Rice et al., 1992).
The main goal of this study was to achieve massive propagation of O. ellisiana by in vitro culture of areoles, and to succeed in attaining plantlet acclimatization to field conditions.
The specific goals were a) to elaborate successful protocols for cladode sterilization; b) to find the optimal growth regulators combination able to induce shooting from areoles of sterilized cladodes; c) to determine auxin concentrations able to induce rooting; and d) to acclimatize propagated material to field conditions.

Materials and Methods

Owing to low availability of O. ellisiana cladodes, the preliminary sterilization trials were performed with O. ficus-indica.
The following sterilization procedures were tested:
I. Entire cladodes washed with water and sterilized by immersion in 20% sodium hypochlorite plus 2% Tween 80 for 10 min (Mohamed-Yassen et al., 1995), followed by immersion in 1% benzalkonium chloride for 30 min. Subsequently, cladodes were rinsed four times with sterile distilled water.
II. Areoles were isolated using a hollow punch (1cm in diameter), then sterilized by immersion in 96º ethanol for 1 min, followed by immersion in 20% sodium hypochlorite for 7 min, and finally rinsed three times with sterile distilled water (Clayton et al., 1990).


FIGURE 1. (A) Percentage of areole shooting on four different nutritive media for 49 days; (B) shoot length (mm) produced by areoles cultured on different nutritive media.
For each graph, means recorded on the same date, followed by the same letter, are not significantly different (p<0.05).

Results obtained (see below) led us to utilize procedure I.
A Murashige-Skoog (MS) basal medium (BM) (Murashige and Skoog, 1962) with 30 g L -1 sucrose and 0.8% agar was used.
Benzylaminopurine (BAP) at 10 mM, and indole-3-butyric acid (IBA) at variable concentrations were used as growth regulators.
Media were adjusted to pH 5.7 with 0.1N KOH, and autoclaved at 0.1 MPa (121ºC) for 30 min. Explants were dispensed into 20 x 150 mm glass tubes containing 10 ml of media (Mohamed-Yassen et al., 1995), and cultured in growth chambers at 27±2ºC, 100% relative humidity. Light had an intensity of 100 mmoles m -2 s -1 at tube level.
The following experiments were designed:
1) Areole culture (n=10) for 49 days, which included the following treatments:
a) BM + BAP, under 1-week darkness, followed by a 16-h photoperiod.
b) BM + BAP, under a 16 h-photoperiod.
c) BM + BAP + 10 mM IBA, under 1-week darkness, followed by a 16-h photoperiod.
d) BM + BAP + 10 mM IBA, under a 16-h photoperiod.
In each treatment infected and non-infected areoles were determined, as well as number and length of shooting areoles.
2) Shooting areole culture (n=10) obtained in the above assay, under a 16-h photoperiod for 48 days, which included the following treatments:
a) Entire shoot in BM + 25 mM IBA.
b) Transversally sectioned shoot in BM + 25 mM IBA.
c) Entire shoot in BM + 50 mM IBA.
d) Transversally sectioned shoot in BM + 50 mM IBA.
Both the number of rooted shoots and the number of roots per shoots were determined.
O. ellisiana shoots developed and rooted in vitro were transferred to the greenhouse, where they were acclimatized so as to endure environmental conditions. Plantlets were grown in speedlings filled with sterilized substrate (organic matter: sand: soil, 6:3:1 v/v). All plantlets were watered as required and grown in the shade (80% solar radiation intercepted) for 48 h, under high relative humidity (80-90%). Subsequently some of them were taken to the field where very low relative humidity prevails, and the others were subjected to decreasing relative humidity for 72 h. Plantlet survival was determined.
Data were subjected to an analysis of variance (ANOVA). Mean comparisons were tested using Duncan´s test. Angular transformations were made for the analysis of percentage data.


FIGURE 2. (Left) Areoles isolated from cladodes of O. ellisiana, and shoots regenerated from meristematic tissue, after 49 days of in vitro culture. (Right) Rooted shoot of O. ellisiana on MS basal medium plus 30g.L -1 sucrose, 0.8% agar and 25 mM IBA after 48 days of in vitro culture.

Results

Sterilization procedure I, in which entire cladodes were immersed in Tween 80, sodium hypochlorite and benzalkonium chloride solution, proved to be the most efficient, with only 12% areoles infected. This infection percentage was remarkably lower than that of sterilization procedure II, wherein 80% areoles were infected.
A 100% areole shooting was obtained on BM + BAP + 10 mM IBA, under a 16-h photoperiod on the 35 th day of culture. The areoles cultured in BM + BAP, under a 16-h photoperiod presented 60% shooting after 35 days in culture. Areoles which were subjected to BM + BAP, under 1-week darkness, followed by a 16-h photoperiod; and BM + BAP + 10 mM IBA, under 1-week darkness, followed by a 16-h photoperiod, showed at the end of the assay a shooting percentage close to 40% (Figs. 1-A and 2). It is worth noticing that only one shoot was obtained for each areole.
The greater shoot length (13 mm) was obtained by culturing areoles on BM + BAP + 10 mM IBA, under 1-week darkness, followed by a 16-h photoperiod, on the 49 th day. This shoot length was significantly higher than that registered in BM + BAP under conditions of 1-week darkness, followed by a 16-h photoperiod (Fig. 1-B).
The highest rooting percentage of shoots was 100% for the following treatments: entire shoots in 25 mM IBA; sectioned shoots in 25 mM IBA; and entire shoots in 50 mM IBA, after 19 days in culture (Figs. 2 and 3-A).
A high number of roots per rooted plantlet was obtained by culturing entire shoots on BM+25 mM IBA, after 19 days in culture. However, the greatest number of roots per rooted plantlet was obtained with entire shoots cultured on BM+25 mM IBA and BM+50 mM IBA, and was achieved after 33 days of culture. Growing entire shoots on a BM supplemented with any of the IBA concentrations used produced 16 roots per rooted plantlet on the 33 rd day. This was significantly higher than the number reached using the treatment including sectioned shoots in 25 mM IBA; and the latter was in turn higher than that obtained from the treatment using sectioned shoots in 50 mM IBA (Fig. 3-B). The same results were observed after 48 days in culture, at the end of the assay.
Both acclimatization procedures applied to in vitro regenerated plantlets were successful, plantlets showing a 100% survival when transferred to soil.

Discussion

Sterilization treatment of entire cladodes and sub-sequent explant excision in laminar airflow cabinet proved to be the most successful procedure. Using benzalkonium chloride in sterilizing entire cladodes resulted in reduced infection levels, as was also found for other plant materials (Flachsland et al., 1997).


FIGURE 3. (A) Percentage of rooted entire and sectioned shoots, on a culture medium with different concentrations of IBA, for 48 days; (B) number of roots from entire and sectioned shoots cultured on nutritive media.For each graph, means recorded on the same date, followed by the same letter, are not significantly different (p<0.05).

The culture medium with BAP and IBA, under a 16-h photoperiod, showed the highest percentage of areole shooting (100%) along with a high shoot growth rate, thus being the most efficient culture medium for the optimal multiplication of this plant material. Previous studies have pointed out that the optimal hormone combination may be unique for each cactus species (Johnson and Emino, 1977, 1979). However, recent articles emphasize that low levels of auxin with cytokinin increased axillary shoot production in some cactus species (Clayton et al., 1990). Cytokinin is considered to be essential for the development of cactus axillary shoots (Mauseth, 1977). Opuntia amyclea buds developed in response to the exogenous stimulus of cytokinin (BAP) (Escobar et al., 1986). The lateral buds of tobacco plants can also be stimulated to grow when exposed to a nutritive medium high in cytokinin (Murashige and Skoog, 1962).
Shoot and root differentiation is the result of the interaction between cytokinin and auxin hormones (BAP/IBA). This interaction cannot always be controlled because endogenous hormones (synthesized by the tissues in culture) are influenced by exogenous growth regulators (Rubluo et al., 1996). These endogenous hormones are also affected by light availability (Taiz and Zeiger, 1998). The lengthening of shoots recorded in the treatment using 10 mM IBA under 1-week darkness was probably the result of the absence of light. Rooting is favored by auxin availability. Apical meristems produce auxins, so treatments with entire shoots yielded the greater number of roots and the higher rooting percentage.
After transplant, plantlet survival was 100%, similar to that reported by other authors (Ault and Blackmon, 1987; Clayton et al., 1990; Johnson and Emino, 1979; Mohamed-Yassen et al., 1995; Vyskot and Jára, 1984). Moisture requirements of plantlets were minimal during acclimatization. They can be directly placed in the open, under environmental moisture conditions, to avoid fungal infection (Smith et al., 1991). Plantlets obtained showed the typical cladode shape (Fig. 4), which is a major trait of in vitro regenerated plants. It is to be noted that plants grown from seeds in an irrigated field maintained the juvenile cylindrical form for a longer time and grew very slowly, even after four years (Escobar et al., 1986).
After 7 months of culture a total 1,200 plantlets were obtained. By early autumn the propagated and acclimatized plantlets of O. ellisiana were sent to the Jardín Botánico in Puerto Madryn (Chubut); to the Dirección de Recursos Naturales Renovables, Malargüe (Mendoza); and to the Estación Experimental de Ganado y Pasturas Naturales El Divisadero, Santa Rosa (Mendoza), where the plants were grown in the field. Plants survived the freezing winter temperatures in all three places (-9ºC, -14ºC, and -14.8ºC respectively, for several hours); however O. ficus-indica plants, forming the control group, were killed.
The results of this study suggest that O. ellisiana can be successfully micropropagated by areoles, and easily acclimatized to field conditions.


FIGURE 4. O. ellisiana acclimatized under greenhouse conditions after 15 months.

Acknowledgements

The authors thank N. Horák for reviewing the English version of the manuscript, Ing. S. Trione for his critical reading, and Ing. M. Cirrincioni for his assistance in the greenhouse and laboratory.
This work was supported by the Secretaría de Ciencia y Técnica de la Universidad Nacional de Cuyo (SeCyT), Project Nº 06/A 138.

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Received on February 14, 2002.
Accepted on July 5, 2002.

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