INTRODUCTION
Arrow cane (Gynerium sagitatum Aubl.) is a Poaceae species native to West India and distributed from México through Paraguay in the American continent. The plant is well adapted to inter tropical zone conditions with a better growth rate in wet low lands, organic soils and altitude up to 1600 m above sea level (GRIN, 2013). Cultivation and processing of arrow cane have been the main income source for communities of the Zenú Indian group, most of them dedicated to make craftsmanship products from the plant´s central nerve becoming the most famous handmade Colombian products (DANE, 2005). Recent studies evidenced the potential for landfill phytoremediation using arrow cane alone or in association with other plant species (Madera-Parra, 2015 a, Madera-Parra, 2015b).
Arrow cane propagates by sexual and clonal methods; plants are dioceaus and flowers can be wind pollinated, seeds index is around 1.7 million Kg-1 and, when viable, seeds can germinate from three to seven days after imbibition at 20-30°C. Flowering usually occurs at the stem terminal in 18-20 months old stem; however, under Humid Caribbean conditions sexual propagation does not occur because seeds are unviable. Clonal propagation is the current way for plant multiplication and dissemination; the new shoots emerge from underground rhizomes that expand radially up to 20m from the main stem. The newly grown stems eventually mature and flower becoming a new source for basal growing shoots. This growth and propagation habit is not only very efficient for colonization new territories but also an effective way to preserve wetlands and shores from erosion and degradation (Kalliola et al., 1992; Araméndiz et al., 2005).
Arrow cane plant extraction from wild populations to make craftsmanship (hats, rings, shoes, etc.), homes, musical instruments and ornamental products happens at a very high rate since commercially crops are not available. It is estimated that more than 50% of arrow cane natural populations in the Colombian Northern Coast have been eliminated in the past 10 years becoming a cultural, economic and environmental issue. Several studies have been conducted aimed at developing an efficient propagation method for natural restoration and commercial crops for fiber production (Araméndiz et al., 2005, Suarez et al., 2013).
Micropropagation is a clonal propagation technique that allows massive plant multiplication in short periods of time, reduced space and under aseptic conditions (Sinhg et al., 2013; Waikhom & Louis, 2014). Micropropagated plants are cultured from explants, established in closed containers with nutrient media and hormone supply that result in high levels of genetic and phenotypic uniformity. Usually, micropropagation requires fully equipped labs, relatively high amount of reagents, well trained people and many labor hours which results in high plant costs (Shinde et al., 2016). Several studies related to developing micropropagation strategies for arrow cane in order to produce massive plant material for planting commercial crops have been reported (Pastrana and Suarez, 2009, Suarez et al., 2009; Rivera et al., 2009; Suarez et al., 2017); however, micropropagated plants results in higher costs than planting material from natural populations. Double phase medium system have been implemented to reduce costs of Vitis vinifera (Couselo et al., 2006), Ananas comosus (Scherwinski-Pereira et al., 2012) and Whitania somnifera (Singh et al., 2016) micropropagated plants by means of reduced gelling agents, subculture, reagents and labor hours in the process. In the present research, double phase medium with continuous shoot growth in the same recipient was compared to conventional semisolid medium system for Gynerium sagitatum micropropagation with respect to multiplication rate and costs variables.
MATERIALS AND METHODS
Plant material. Plant material consisted of in vitro established arrow cane plants cultivar “Criolla” cultivated for 12 months with monthly subcultures. The culture medium was MS (Murashige and Skoog, 1962) supplied with (in mg L-1) myo inositol (100), sucrose (30.000), thiamine HCl (0.4) and Phytagel® (3.000) (Sigma Co®.). The explants consisted of clusters with three 3-4 cm long shoots obtained from established plants after four weeks of subculture. The cultures were stored at 25°C with 12 h photoperiod provided by cool white fluorescent tubes (40-50 µmol m-2 s-2).
Shoot multiplication. Clusters with three stems were established into 750cm3 polycarbonate flasks containing double phase medium consisting of 100cm3 MS semisolid bottom medium added with 30cm3 liquid MS medium on top of the semisolid phase; four explants were established in each container and the liquid phase was re-plenished every two weeks inside of a laminar flow hood to avoid contamination. For conventional semisolid system, similarly processed explants were cultivated in 30cm3 MS semisolid medium contained in 125cm3 polycarbonate flasks; a single explant was established in each container and total explants were transferred to fresh medium of the same formulation every four weeks.
The medium formulation for both treatments was MS (Murashige and Skoog, 1962) supplied with (in mg L-1) mio inositol (100), sucrose (30.000), thiamine HCl (0.4) and BAP (0.5); the semisolid phase was added with Phytagel® (3.000) (Sigma Co.). All flasks were covered with heavy duty aluminum foil and sealed with Nescofilm®. The cultures were stored at 25°C with 12 h photoperiod provided by cool white fluorescent tubes (40-50 µmol m-2 s-2) during 120 days.
Treatments, consisting of double phase medium dispensed in 750 cm3 containers and semisolid medium dispensed in 250 cm3, each treatment was replicated 10 times for a total of 20 experimental units distributed with a complete randomized design. After 120 days in culture, the total number of shoots, shoots per flask, newly formed shoots per explant and shoot length were registered. Data were analyzed using T test based on the here µ was the overall mean, β was the effect of medium consistency and container and Ɛ was the experimental error. Costs of shoot production were quantified based on the multiplication rate and cost of elements used for each system.
Medium sterilization. The pH of all media was adjusted to 5.7-5.8 prior to addition of gelling agent when indicated. Media were sterilized by autoclaving at 120 °C and 1.2 kg cm-2 for 15 min.
Transfer to ex vitro conditions. Micropropagated shoots were washed with sterile distilled water to remove medium residues and transplanted into 72-plug containers filled with peat as substrate. The containers were placed in a shade house with 20% light coverage with Saram® and irrigation provided by a fog system every 20 min for 30 seconds during the first two weeks. After two weeks, plants were transferred to 50% light coverage with Saram® and irrigated three times a day two minutes each. Seven weeks after transferring to ex vitro conditions, the number of plants that survived and adapted to normal conditions was recorded and survival rate calculated.
RESULTS AND DISCUSSION
New shoots formed from established explants were visible after two weeks in culture from both double phase and semisolid medium cultures. New shoots showed a healthy growth pattern with no phenol emission or contamination symptoms; no callus tissue or adventitious shoot growth was observed. This growth performance is typical of in vitro established cultures when transferred to BAP supplied medium. Cultures adapted to in vitro conditions respond accordingly to PGR supply in contrast non-in vitro adapted cultures usually show a non-synchronic growth with large asymmetric organs, phenol emission and necrotic tissues (Suárez et al., 2009; Pastrana and Suárez, 2009).
The results of the T student test applied to the data allowed to detect statistical differences for total number of shoots (Pr= 0.0001), number of shoots per flask (Pr= 0.0011), mean number of newly formed shoots per explant (Pr= 0.0148) and shoot length (Pr= 0.0001) as a result of the applied treatments (Table 1). The analysis showed that continuous culture of arrow cane explants in double phase medium significantly increases the total number of shoots, the number of new shoots per explant, the number of shoots in each individual flask and the length of shoots compared to the conventional semisolid medium system in the same time frame (90 days) (Table 1, Figure 1).
The cost analysis of micropropagated shoots at a rate of 6.8 new shoots per explant using a conventional semisolid medium system with four week transfer to fresh medium estimates a cost of US$0.18 per shoot (López, 2016). The results of the present research showed that multiplication rate in double phase medium can be about two folds (13) compared to semisolid medium system. Considering the medium quantity needed for each system, gelling agent amount, labor related to subculture and washing glassware; it is estimated that double phase medium system can lower the total cost of plants by 20% compared to semisolid medium cultures system (Table 1).
Medium | Total shoots produced | Shoots per flask | Shoots per explant | Shoot length (cm) | Shoot cost (US$) |
---|---|---|---|---|---|
Double phase | 855 A | 47.50 A | 13.00 A | 7.6 A | 0.15 |
Semisolid | 516 B | 6.88 B | 6.88 B | 5.2 B | 0.18 |
Values with the same letter are not different according to T test (α = 0.05) |
Culture media for in vitro tissue culture can be formulated as semisolid, liquid or double phase (liquid on top of semisolid) (Akhtar, 2013; Mehta et al., 2014; Litwińczuk, 2013). Semisolid media favor explant stability and allow to expand the time for subculture because slow nutrient and water release to the tissues; in contrast, they are usually more expensive because of gelling agents costs and nutrient absorption by tissues is slower; in contrast, liquid media are less expensive for absence of gelling agents, nutrient and plant regulators absorption by explants is faster, especially in cell suspension systems; (El-Hawaz et al., 2015; Perera et al., 2015). For liquid cultured tissues subcultures are more frequent because of nutrient depletion, tissue vitrification and phenol leakage in the medium that negatively affects growth and survival (Dong et al., 2016; Jones and Saxena, 2013). Double phase medium formulation combines the benefits of semisolid and liquid media: explant stability is provided by semisolid phase; rapid nutrient uptake is favored by liquid phase, the subcultures are eliminated by periodical addition of liquid medium which reduces cost from gelling agents, labor and support elements such as sealing material (Litwińczuk, 2013; López, 2013).
In semisolid medium system, subculture of plant tissue to fresh medium is necessary in order to provide constant adequate nutrient levels, to avoid tissue decay and to maintain high multiplication rates. During subculture, stems and leaves are cut back to maintain the shoot/container size ratio accordingly; additionally, shoot clusters are separated to scale up propagule number to keep high multiplication rates. The data collected in this research showed that cultures grown continuously with no transfers to fresh medium and absence of shoot cutting resulted in shoots >40% larger than those sequentially severed, separated and transferred to fresh medium periodically during the 120 days of the research; this may indicate that subculture induces some stress levels by structure severing and high nutrient saturation on fresh medium that negatively affect shoot growth (Shin et al., 2013). Plant size is especially important for plant survival during transfer to ex vitro conditions; in vitro propagated plants grow under very low light intensities (<60 µmol m-2 s-1) that prevents photosynthesis activation and therefore, energetic compound supply, usually sucrose, in needed, creating a heterotrophic (photomixotrophic) model for in vitro plant growth and development (Kapchina et al., 2014; Nunes et al., 2016; Chavan et al., 2014). Because of this external energetic support, when transferred to ex vitro conditions, plants must have plenty of carbohydrate reserves in organs, such as leaves and stems, that serve as “life boat” effect before newly photosynthetic active leaves are formed. Therefore, micropropagated plants with larger organs will store more nutritional reserves and will have more opportunities to successfully withstand adaptation when transferring to natural environment (Kane, 1996; Resende et al., 2016; Zakavi et al., 2016).
Plants cultured in both systems had a complete survival percentage (100%) seven weeks after transfer to ex vitro conditions; however, plants cultured in larger containers/double phase/no transfer were in average larger (13cm) than those cultured in semisolid media with monthly transfers to fresh medium (5cm)(Figure 2); difference that may be the result of the higher reserve accumulation and rapid allocation for new organ formation in the first; however, more studies are recommended to deep into this topic.
CONCLUSSION
The present study has shown that micropropagation of arrow cane shoots using double phase medium resulted in higher multiplication rates that may decrease micropropagated plant costs at least 20% compared to those micropropagated using semisolid medium system. Likewise, double phase cultured shoots were 40% larger which may have a beneficial impact on plant adaptation to ex vitro and growth when transferred to field conditions.