Effective Protocol for in Vitro Shoot Production Through Nodal Explants of Simmondsia Chinensis

Nodal explants excised from 18 to 20-year-old female plants of Simmondsia chinensis if cultured on Murashige and Skoog's medium supplemented with 20 M N⁶-benzyladenine (BA) differentiated an average of 2.7 ± 0.4 shoots in 11.5% explants. The percentage of nodal explants inducing multiple shoots enhanced significantly if in vitro raised shoots were used as source of explants. Nearly 100% cultures differentiated an average of 4.7 ± 2.0 shoots per explant on the same medium. Nearly 85% of the shoots induced roots when a pulse treatment of 50 M indole-3-butyric acid (IBA) was given prior to their transfer to semi-solid MS medium containing 10 M IBA + 0.5% activated charcoal + 1 M BA. Plantlets were gradually hardened in Soilrite and acclimatized to soil.     

巴西橡胶成龄无性系茎段的试管微繁技术研究

巴西橡胶成龄无性系茎段组织培养在生产中有很大的潜在应用价值,但一直是橡胶树组织培养的难点,至今国内外鲜有成功的报道.本研究以在中国热带地区大面积推广种植的巴西橡胶树优良品种热研7-33-97不同生长时期成龄树茎段为外植体,进行无性系试管微繁技术研究.研究结果表明不同生长时期的茎段在自然条件中受污染程度不同,茎段真菌污染率为稳定期＞淡绿期＞古铜期,细菌污染率为淡绿期＞稳定期＞古铜期.不同生长时期的成龄树茎段需要通过不同的灭菌方法才能显著提高外植体的利用率,外植体灭菌方法显著影响橡胶成龄树茎段的组织培养效率;与稳定期相比,古铜期和淡绿期茎段在组织培养过程中诱导丛生芽萌芽快、萌芽多,是较优的外植体材料;古铜期和淡绿期茎段在激素配比为4.0～5.0 mg/L6-BA+0.5 mg/L GA3的条件下能很好的诱导抽出丛生芽;丛生芽在激素配比为2.0 mg/L 6-BA+0.5 mg/LNAA,1.0 mg/t 6-BA+1.0 mg/L KT+0.5 mg/L NAA或0.5 mg/L 6-BA+1.5 mg/L KT+0.5 mg/L NAA的条件下能很好的诱导丛生芽抽出健壮的芽条;丛生芽抽出的健壮芽条在激素配比为0.5 mg/L IBA+0.5 mg/L IAA的条件下能较好的抽根成苗.外植体生长时期、激素种类和浓度配比都是影响巴西橡胶成龄无性系茎段的试管微繁的重要因素.     

Micropropagation of Sesbania sesban from the Mature Tree-Derived Explants

The nodal and internodal explants excised from the orthotropic shoots of Sesbania sesban var. bicolor elicited the development of shoots directly from the explants as well as via an intervening callus phase on Nitsch (N) medium. On benzyladenine (BA) supplemented media, the adventitious shoot buds developed involving a callus phase. An average of 8.9 ± 4.1 shoots developed per nodal explant on N medium containing 0.5 mg dm⁻³ BA in 95 % cultures, whereas 65 % cultures of internodal explants developed shoots with an average of 5.9 ± 3.6 shoots per explant on N medium supplemented with 1.0 mg dm⁻³ BA. On kinetin (Kn) supplemented medium shoots developed directly from the surface of both the explants at all the concentrations tried. Nodal explants on N medium supplemented with 1.5 mg dm⁻³ Kn developed an average of 12.5 ± 7.9 shoots per explant in 100 % cultures, while internodal explants induced an average of 11.6 ± 7.4 shoots per explant in 75 % explants at 0.5 mg dm⁻³ Kn. The in vitro regenerated shoots developed roots when implanted on N medium supplemented with 2 mg dm⁻³ indole-3-butyric acid (IBA), after 30 d of inoculation. The in vitro developed plantlets were initially acclimatized under controlled conditions for four months, prior to their transfer to the field. This revised version was published online in July 2006 with corrections to the Cover Date.     

Micropropagation of Three Varieties of Caralluma adscendens via Nodal Explants

A procedure for in vitro propagation of pharmaceutically valuable varieties of Caralluma adscendens from nodal explant, is described. The highest shoot multiplication with 80% frequency was achieved within one month on Murashige and Skoog’s medium supplemented with 8.87 μM BA. Shoot multiplication occurred in subsequent subcultures in culture bottles on MS medium. Regenerated shoots were rooted on half strength MS medium supplemented with NAA (0.54 μM) in all the three varieties. The rooted plants were hardened for establishment in soil.     

Micropropagation of Anethum graveolens L Through Axillary Shoot Proliferation

A protocol is described for rapid and large-scale in vitro propagation of Anethum graveolens by enhanced axillary shoot induction that was dependent on BAP supply. The synergistic combination of 0.5 mg l^?1 BAP and 0.1 mg l^?1 IBA induced 100% shoot formation as well as shoot number (6.6 ± 0.48 per explant). Subculturing of shoot tips of in vitro plants on multiplication medium enabled continuous production of healthy shoots with similar frequency. Rooting of shoots was achieved on a medium with 1mg l^?1 IBA and 0.5 mg l^?1 Kn. Micropropagated plants established in garden were uniform and identical to the donor plant with respect to morphological and cytological characteristics.     

越橘属植物克隆的体外繁殖

以美国引进的越橘属植物为材料,取其成龄植株的茎段或茎尖为外植体,培养在添加各种激素配比的改良WPM的培养基上,研究了影响克隆体外繁殖的因素,筛选离体最佳增殖和生根培养基及培养条件.结果表明:在改良WPM添加Zt 1.0 mg/L的增殖培养基上,增殖系数最大达50,在1/2WPM IBA 0.3 mg/L的生根培养基上生根率因外植体的基因型不同而有差异,可达到30%～70%.通过实验室的半无菌炼苗后,试管苗移栽到温室的成活率达60%.     

Multiplication of Eucalyptus citriodora (L) Hook Through Shoot Bud Induction on the Internodal Portions of Mature Tree Explants

Nodal explants of Eucalyptus citriodora responded better for high frequency bud break and fast growth in liquid agitated cultures with 4.4 μM benzyladenine (BA) and 5.37 μM α-naphthalene acetic acid (NAA) rather than on semisolid medium. On transfer to MS medium with 1.11 μM BA and 5.37 μM NAA the sprouted axillary buds showed further elongation growth alongwith a slight callus and formation of globular structures on the internodal regions. The anatomy of these globular structures revealed that they are shoot buds. These buds elongated into shoots on MS medium with low levels of BA.     

In Vitro Clonal Propogation of Coleus forskohlii via Direct Shoot Organogenesis from Selected Leaf Explants

Present study provides an easy and efficient protocol for large scale clonal propagation of Coleus forskohlii, a threatened medicinal plant of commercial importance. Basal leaf lamina excised from upper three nodes of shoot was used as explant and its size, position, orientation and season of collection were initially optimized to select the most responsive explant condition. Enhanced shoot production and proliferation has been achieved on medium containing 2 μM BA + 0.1 μM NAA wherein, a highest number of 35 shoots/explant were produced. The regenerated shoots of varied length (3–5 cm) were transferred to root induction medium comprising of IBA, NAA and IAA (1–5 μM) in half-strength MS medium to determine the most suitable shoot length for proper root induction. Rooted plantlets were acclimatized in field conditions after proper hardening. Histological analysis was also carried out to confirm the nature of origin of shoot buds from leaf explants.     

In Vitro Micropropagation and Flowering in Artemisia annua

A protocol for quick regeneration of a large number of plantlets of Artemisia annua (source of a potent antimalarial drug) is being reported. Multiple shoots were obtained in large numbers from juvenile as well as vegetative parts of mature plant on Murashige and Skoog’s medium (MS) having 3% sucrose and 800 μM myoinositol and supplemented with NAA (0.5 μM) + BAP (13.0 μM) + GA₃ (0.3 μM) + Asp (300.0 μM) + Glu (700.0 μM) + Arg (300.0 μM) + Cys - HCl (30.0 μM). Reversal of reproductive to vegetative phase and back to reproductive phase could be achieved in the cultured flower buds. The shoots obtained on the above medium could be induced to flower. In addition, new shoots that differentiated from vegetative parts of juvenile and mature explants also produced flowers when cultured on MS with GA₃ (0.3 μM). Since artemisinin estimation is correlative to flowering, our results would facilitate better understanding of biosynthesis of this drug in vitro.     

Rapid In Vitro Propagation of East Indian Rosewood (Dalbergia latifolia Roxb.) through High Frequency Shoot Proliferation from Cotyledonary Nodes

An efficient protocol is described for large scale in vitro propagation of east Indian rosewood (Dalbergia latifolia Roxb.) using cotyledonary nodes derived from axenic seedlings. Of the four different cytokinins tested, BA was most effective in inducing multiple shoot buds in the explants. High frequency shoot proliferation (93%) coupled with maximum number of shoot formation (10-12 shoots/explant) was recorded on Murashige and Skoog’s medium supplemented with 2.0 mg/l BA. The frequency of shoot proliferation declined at higher levels of cytokinins. Shoot culture was multiplied by subculturing the original cotyledonary node on a fresh shoot multiplication medium each time aHer excising the newly formed shoots. Shoots obtained from each passage were multiplied further as nodal explants and each node produced 3-4 shoots. In two months from a single cotyledonary node, about 90 shoots were obtained. Rooting was induced in 72% of the regenerated shoots on half-strength MS containing IAA, IBA and IPA each at 1.0 mg/l. Rooted plantlets were hardened off and eventually established in soil.     

Effect of Carbon Source on the Shoot Proliferation Potential of Epicotyl Explants of Syzygium cuminii

Black plum (Syzygium cuminii) explants were grown in vitro on Murashige and Skoog medium. Among the various saccharides tested, the best caulogenic response was afforded by sucrose both in terms of explant response and shoot developing potential. Within monosaccharides, mannose was totally inhibitory as on the medium supplemented with this the shoot buds failed to develop, while, fructose and xylose completely inhibited the opening as well as the elongation of shoot buds. Glucose and galactose did not completely inhibit the caulogenic response. Among disaccharides, other than sucrose, maltose totally inhibited the elongation of the developed shoot buds while lactose supported it to a limited extent. Sugar alcohols, though not as good as sucrose, proved better sources of carbon and energy than the other tested sugars. Sucrose at concentration 4 % proved to be the best in developing 4.2 shoots per explant. This revised version was published online in July 2006 with corrections to the Cover Date.     

In Vitro Propagation of Endangered Temperate Himalayan Medicinal Herb Picrorhiza kurroa Royle ex Benth using Leaf Explants and Nodal Segments

The present study describes the micropropagation of Picrorhiza kurroa, (commonly known as kutki) an endangered medicinal herb of the temperate Himalayas and a source of hepatoprotective picrosides. In vitro shoot multiplication was achieved through sprouting of axillary buds using nodal segments and leaf tissue. For shoot regeneration, the hormone combinations kinetin (2.0 mg l^?1) and Kinetin + Indole-3-butyric acid (IBA) (2.0 mg l^?1 + 0.50 mg l^?1) with leaf explant was found superior. Interestingly, the basal MS medium gave 99.94 % response (direct proliferation) with nodal explant. The medium supplemented with IBA (1.0 mg ^?1) was found best for rooting of regenerated shoots. Nodal segments plated on the medium supplemented with TDZ + IBA (0.11 mg ^?1 + 0.50 mg ^?1) formed somatic embryos, however further regeneration could not be achieved. The in vitro raised plantlets were hardened and successfully established in the glass house conditions.     

Molecular Analysis of In Vitro Shoot Organogenesis

Shoot organogenesis is one of the in vitro plant regeneration pathways. It has been widely employed in plant biotechnology for in vitro micropropagation and genetic transformation, as well as in study of plant development. Morphological and physiological aspects of in vitro shoot organogenesis have already been extensively studied in plant tissue culture for more than 50 years. Within the last ten years, given the research progress in plant genetics and molecular biology, our understanding of in vivo plant shoot meristem development, plant cell cycle, and cytokinin signal transduction has advanced significantly. These research advances have provided useful molecular tools and resources for the recent studies on the genetic and molecular aspects of in vitro shoot organogenesis. A few key molecular markers, genes, and probable pathways have been identified from these studies that are shown to be critically involved in in vitro shoot organogenesis. Furthermore, these studies have also indicated that in vitro shoot organogenesis, just as in in vivo shoot development, is a complex, well-coordinated developmental process, and induction of a single molecular event may not be sufficient to induce the occurrence of the entire process. Further study is needed to identify the early molecular event(s) that triggers dedifferentiation of somatic cells and serves as the developmental switch for de novo shoot development.     

Toward Molecular Understanding of In Vitro and In Planta Shoot Organogenesis

Shoot organogenesis, one of the in vitro plant regeneration processes that occur during in vitro micropropagation, is used in the study of plant development. Morphological, physiological, and molecular aspects of in vitro shoot organogenesis have been extensively studied for over 50 years. Because of the research progress in plant genetics and molecular biology, our understanding of in planta and in vitro shoot meristem development, the cell cycle and cytokinin signal transduction has advanced significantly. These research advances provide useful information as well as molecular tools to study further the genetic and molecular aspects of shoot organogenesis. A number of key molecular markers, genes, and pathways have been shown to play a critical role in the process of in vitro shoot organogenesis. Furthermore, these studies reveal that in vitro shoot organogenesis, as with in planta shoot development, is a complex, well-coordinated developmental process, given that the induction of a single molecular event is likely to be insufficient to induce the entire process. Continued study is required to identify additional molecular events that trigger dedifferentiation and act as developmental switches for de novo shoot development.     

In Vitro Micropropagation of Passiflora edulis (Purple Passionfruit)

A technique for the micropropagation of Passiflora edulis fromseedling explants is described. A multiplication rate of 4.5per month can be achieved in an Murashige and Skoog medium supplementedwith 2 % sucrose and 2 mg l^–1 BAP. Using this technique,no callus is produced. Problems of chlorosis and a method foravoiding subsequent death after prolonged culture are discussed. Passionfruit, Passiflora edulis, micropropagation, tissue culture, chlorosis     

Organogenesis of Lear Explants of Momordica grosvenori Swingle In Vitro

Leaves of Momordica grosvenori Swingle were used as experimatal material. Plantlets were obtained on MS medium supplemented with 6-BA 1 ppm and IBA 0.5 ppm. Histocytological observations on adventitious bud formation were carried out. After 1 week in culture, mesophyll cells obviously enlarged, cell divisions began in the mesophyll cells near the cut ends of explants, and meristemoids which consisted of small dark stained cells without chloroplasts were produced. Then meristemoids continued to proliferate and redifferentiated into many leaf-shaped bodies. Three weeks after cultivation, adiventitious buds were produced from meristemoids at surface layer of leaf-shaped body. The stem of plantlet was cut off when it reached 2 cm in height, and then was transferred onto MS basic medium supplemented with NAA 0.25–0.5 ppm for rooting. About 10 days after cultivation, vigorous root system was produced from the cut end of plantlets. It is possible that this technique of obtaining whole plants by leaf explant culture provides a method for the multiplication of the good individual plants of M. grosvenori.     

Vernalization in Lolium temulentum L.: Responses of In Vitro Cultures of Mature and Immature Embryos, Shoot Apices and Callus

Response of vernalization to low temperature (2C) was studiedin a winter-annual form of Lolium temulentum L., using imbibedseeds, excised mature and immature embryos, shoot apical meristemsand callus tissue. Excised embryos, as early as 5 days afteranthesis, and excised shoot apices could be vernalized as effectivelyas imbibed seeds. Cold treatment of developing embryos withinthe ear, however, appeared to have no vernalizing effect. Plantsderived from callus by somatic embryogenesis showed varyingdegrees of vernalization response. The vernalization response in L. temulentum, as in winter annualcereals, appears to be located in the shoot apical meristemand the vernalized condition can be transmitted to new axillarymeristems formed from it. Lolium temulentum L. darnel, vernalization, embryo culture, apical meristem culture, callus culture