Biotechnological advances in pomegranate (Punica granatum L.)

Pomegranate (Punica granatum L.) is known for its nutritional, medicinal, and ornamental importance. It is conventionally propagated by hardwood and softwood cuttings, but about 1 yr is needed before the rooted cuttings can be transplanted to the field. Propagation by seed is undesirable as populations are heterozygous and seed propagation leads to wide variations in tree and fruit characteristics. Several studies have been conducted on in vitro culture of pomegranate, and protocols have been developed for plant regeneration through organogenesis and embryogenesis from various types of explants. Tissue culture has enabled mass propagation of superior genotypes of both wild and cultivated varieties. However, successful application of tissue culture systems for genetic engineering of pomegranate is still limited. Molecular markers are essential for identification and discrimination of genotypes for genetic conservation, crop improvement, breeding programs, and commercialization of superior genotypes. These techniques may also be applicable to rapid identification and indexing of disease-free planting material. This review focuses on the biotechnological approaches that are being used for pomegranate improvement.     

Picrorhiza kurrooa: current status and tissue culture mediated biotechnological interventions

Picrorhiza kurrooa, one of the important plant species among the various medicinal plants, is endemic to Himalaya. As the plant is useful in the treatment of various diseases, e.g., hepatic disorders, gastric troubles, anemia, asthma, etc., illegal collection from the wild is increasing and now this plant is banned for export in any form and listed as ‘endangered’. Ecological studies carried out on this species in last few decades suggested that the availability of this species in its specific habitats is comparatively lower than other associate species. Possible factors responsible for this depletion are increasing demand in the pharmaceutical industries, habitat specificity, heavy exploitation from the wild, unorganized cultivation practices etc. Biotechnology is playing a crucial role to conserve this important plant species. The past 23 years have witnessed a progressive biotechnological advances made in P. kurrooa. People have published various reports on establishments of in vitro culture techniques including micropropagation, synthetic seed production, plant regeneration via callus-mediated shoot organogenesis, adventitious shoot regeneration, genetic transformation through Agrobacterium rhizogenes, secondary metabolite analysis etc. This review attempts to focus on present ecological status and provide a comprehensive account on the tissue culture-mediated biotechnological interventions made in P. kurrooa for improvement and conservation of this medicinally important plant.     

Combination of thidiazuron and 2-isopentenyladenine promotes highly efficient adventitious shoot regeneration from cotyledons of mature sunflower (Helianthus annuus L.) seeds

Genetic improvement of sunflower (Helianthus annuus L.) through the use of biotechnological tools requires a reliable in vitro shoot regeneration system. Tissue culture protocols reported to date for sunflower suffer from low efficiency, poor reproducibility, genotype dependence and a tendency for flowering in vitro. The present study describes an efficient protocol system for shoot regeneration via direct adventitious shoot organogenesis from cotyledons of mature seeds of sunflower. About 169 media combinations comprising 12 different growth regulator combinations in various concentrations were assessed for induction of shoots from cotyledons derived from mature seeds and also from seedling tissues of 2?C20-day-old seedlings. Appearance of shoots from seedling tissues was sporadic and the frequency of shoot regeneration was low. Cotyledon explants from mature seeds were consistent with regard to frequency of adventitious shoot regeneration and number of shoots per explant. A high frequency (93.86?%) of adventitious shoot regeneration was obtained within 2?weeks of culture initiation on Murashige and Skoog (MS) medium supplemented with 9.84???M 2-isopentenyladenine (2-iP), 2.85???M indole-3-acetic acid (IAA) and 0.45???M thidiazuron (TDZ). Use of 2-iP in the shoot induction and elongation media prevented precocious flowering. Statistical analysis revealed significant effects of explant orientation, age of seedlings, and genotype on adventitious organogenesis. Maximum shoot regeneration was obtained when cotyledons from 0 and 1-day-old seedlings were placed with their adaxial surface in contact with the medium surface. The protocol developed was tested on 42 genotypes and found to be applicable to a wide range of genotypes. Histological studies indicated that the shoots originated predominantly through adventive organogenesis from the sub-epidermal and cortical regions.     

In vitro propagation of rose--a review

In vitro propagation of rose has played a very important role in rapid multiplication of cultivars with desirable traits and production of healthy and disease-free plants. During the last several years, different approaches have been made for in vitro propagation of rose. Micropropagation using apical buds or nodal segments and understanding the specific requirements at different stages has been comprehensively covered in literature. New challenges for refinements of protocols for high rate of shoot multiplication and development of cost effective methods has gained importance in the recent past. Importance of liquid static culture for shoot proliferation and root induction for rose is also discussed in the present review. Further, the development of protocol for in vitro plant regeneration which is considered as most important step for successful implementation of various biotechnological techniques used for plant improvement programmes has been adequately addressed in literature. In rose, there are several reports which indicate rapid regeneration and multiplication through organogenesis or somatic embryogenesis. On the whole, the present review gives a consolidated account of in vitro propagation in rose.     

Regeneration capacity of selected genotypes of white mustard (Sinapis alba L.)

Traditional breeding methods based on inbreeding are difficult to implement in the case of Sinapis alba (white mustard) because this plant displays high levels of self-incompatibility. More rapid progress in breeding could be possible if biotechnological methods and in vitro cultures were used. However, white mustard is not readily amenable to biotechnological treatment. Seeds of traditional S. alba cultivars (e.g., Nakielska) are characterized by high levels of glucosinolates and erucic acid. However, a new Polish variety of white mustard (Bamberka) possesses low erucic acid content in the oil. The main goal of the study was elaboration of a plant regeneration system via in vitro culture of hypocotyl and cotyledon explants from low and high erucic acid-containing white mustard cultivars. In these experiments, a simple system for in vitro regeneration of white mustard was developed, with the aim to promote maximum formation of shoots within a short period of time. Traditional and improved cultivars of S. alba showed comparable capacity for shoot development from hypocotyl-derived and cotyledon-derived explants. The two types of cultivars were characterized by essentially equivalent shoot regeneration responses, being slightly higher in hypocotyl than the cotyledonary explants. A greater influence on shoot regeneration from hypocotyl explants was observed on medium supplemented with 4.4 μmol 6-benzylaminopurine, 0.57 μmol indole-3-acetic acid, and a low concentration of kinetin (4.6 μmol). This technique will allow for rapid generation of sufficient plant material for further use in a variety of white mustard breeding projects.     

Biotechnological advances in jojoba [Simmondsia chinensis (Link) Schneider]: recent developments and prospects for further research

Jojoba (Simmondsia chinensis), is a medicinal and oil-yielding, multi-purpose species of the family Simmondsiaceae. The most valuable product of jojoba seed is the liquid wax or jojoba oil which is used extensively in the cosmetic and bio-fuel industry. Propagation of jojoba is possible using conventional methods, but it is time consuming and cumbersome owing to long rotation periods, male-biased population, and long flowering and seed set time. The development of an efficient regeneration system is a prerequisite for a number of biotechnological interventions for the improvement of jojoba, such as genetic transformation, production of useful metabolites in vitro, etc. During the past decade, therefore, several attempts have been made for in vitro propagation of jojoba. Organogenesis has been achieved in this species from mature as well as juvenile explants. Present communication reports an overview of the in vitro regeneration of jojoba via organogenesis and somatic embryogenesis. Factors affecting organogenesis as well as production of synthetic seeds using shoot tips and axillary buds have also been discussed; however, efforts need to be made to develop an efficient genetic transformation system in jojoba. The purpose of this review is to focus upon the current information on in vitro propagation and biotechnological advances made in jojoba.     

Review: Seaweed tissue culture as applied to biotechnology: Problems,achievements and prospects

Advances have been made in cell and tissue culture of seaweeds to define a unique branch of in vitro techniques; however, they are lagging far behind those of land plants and have limited applications. Explants can be cultivated axenically in enriched or artificial seawater culture media, and regeneration and even callus formation are achieved. In this state of the art technique, seaweed tissue culture may be already useful for certain biotechnological applications, such as clonal propagation of seed material for mariculture. Nevertheless, the absolute control of growth and development as it is exerted in higher plant tissue culture is lacking, and it is required for more complex biotechnological applications in seaweeds. Definitively, we need appropriate cells (competent cells) to induce growth with the most effective chemical regulators in culture medium adjusted towards the addition of carbon sources. Still, free cells and protoplast isolation and regeneration in marine seaweeds constitute the most developed topic in seaweed tissue culture. The regulation of growth and development of seaweed free cell and protoplast cultures may sustain a purposeful use of techniques in the era of genomic applications.     

In vitro biotechnological approaches on <Emphasis Type="Italic">Vanilla planifolia</Emphasis> Andrews: advancements and opportunities

In vitro biotechnological advancement of Vanilla plays a major role in germplasm conservation, genetic engineering, accelerated clonal multiplication and production of disease-free plants with enviable aromatic properties. Several attempts have been taken place for the establishment of efficient in vitro protocol for Vanilla in the past few decades. Optimization of various conditions during different phases of micropropagation, for instance development of in vitro aseptic cultures, multiple shoot regeneration, rooting and acclimatization of the plantlets are discussed in this review. In addition to basic micropropagation techniques, various other in vitro biotechnological applications such as clonal fidelity assessment, genetic transformation, synthetic seed technology and cryopreservation are also highlighted. Apart from the existing data, applied aspects like embryo rescue, mutation breeding, genetic engineering, protoplast fusion, somaclonal variation, in vitro enhancement of vanillin production through cell suspension culture, hairy root culture or bioreactors and cryopreservation need to be investigated further. Overall, the current review gives a synopsis on progress and prospect of in vitro culture of Vanilla.     

Silver nitrate and aminoethoxyvinylglycine promote in vitro adventitious shoot regeneration of pomegranate (Punica granatum L.)

A protocol is presented for direct adventitous shoot organogenesis and complete plant regeneration from seedling-derived explants of pomegranate (Punica granatum L.), a tropical fruit tree. Murashige and Skoog (1962) (MS) medium enriched with 8.9 mumol/L benzyladenine (BA), 5.4 mumol/L naphthaleneacetic acid (NAA) and 10% coconut water (CW) induced adventitious shoot bud differentiation in axenic seedling-derived cotyledons as well as hypocotyl segments. The cotyledons were more responsive than the hypocotyls. Addition of ethylene inhibitors such as AgNO3 (10-40 mumol/L) and aminoethoxyvinylglycine (AVG) (5-15 mumol/L) to the medium markedly enhanced regeneration frequency as well as number of shoots obtained per explant. The promotive effect of AVG and AgNO3 on shoot organogenesis was observed only in cotyledon explants. The regeneration medium containing AgNO3 (20 mumol/L) or AVG (10 mumol/L) induced adventitious shoot buds from 57% or 53% of the cotyledon explants respectively. These shoot buds developed into shoots upon transfer to a regeneration medium without AgNO3 and AVG. The promotive effect of AVG on shoot regeneration was reversed by exogenous application of 20 mumol/L 2-chloroethylphosphonic acid (CEPA), an ethylene releasing compound. On the other hand, shoot regeneration stimulated by AgNO3 was relatively less affected by CEPA. Regenerated shoots were rooted in half-strength MS medium (1/2 MS) containing 0.54 mumol/L NAA. The well rooted plantlets were acclimatized and eventually established in soil.     

Shoot regeneration from cultured leaves of Japanese pear (Pyrus pyrifolia)

Several experiments were conducted to investigate in vitro regeneration of adventious shoots from cultured leaves of Japanese pear (Pyrus pyrifolia). A protocol was developed and regeneration achieved from six cultivars. Leaves harvested from shoot cultures which had been preconditioned on B5 medium with 5 μM thidiazuron plus 0.25 μM gibberellic acid were placed on regeneration medium of the same composition. Frequency of regeneration per leaf was as high as 23% but cultivar and environmental factors influenced the result. More mature (basal) leaves regenerated more frequently than younger ones from the shoot tip. Leaf orientation during regeneration and photoperiod was not a strong influence but regeneration from leaf pieces was less than from uncut leaves. An alternative regeneration procedure was developed in which first, shoot cultures were grown on the preconditioning medium. Leaves of the intact shoot cultures were then induced to regenerate directly when adventitious shoots formed on leaves of the intact shoot culture leaves without excision. Adventitious shoots from both procedures developed into typical shoot cultures when transferred to shoot culture maintenance medium. This revised version was published online in June 2006 with corrections to the Cover Date.     

Efficient in vitro plant regeneration from seedling-derived explants and genetic stability analysis of regenerated plants of <Emphasis Type="Italic">Simarouba glauca</Emphasis> DC. by RAPD and ISSR markers

Simarouba glauca DC. is a multipurpose tree species known for oil, timber, and medicinal properties. The application of biotechnological methods for genetic improvement of this species depends on the availability of an efficient plant regeneration system. In this study, the shoot regeneration potential of various seedling-derived explants was assessed after culturing on Murashige and Skoog (MS) and woody plant (WP) medium containing different growth regulators. The explants differed in their capacity for shoot bud formation and subsequent shoot elongation on the media tested. Shoot bud induction was achieved at a high frequency (44.8–76.2%) from different explants on MS medium with 2 mg L^?1 6-benzylaminopurine (BAP) as compared to other media tested. Cotyledons exhibited the highest capacity for shoot bud induction (76.2%) and shoot elongation (9.1 elongated shoots per explant). The in vitro-regenerated shoots rooted at a frequency of 66.7% after pulse treatment in 10 mg mL^?1 indole-3-butyric acid (IBA) solution for 5 min followed by culture on half-strength WP medium with 0.2 mg L^?1 IBA. The regenerated plants were acclimatized and established in the glasshouse with a survival rate of 80%. Molecular characterization of regenerated plants using 14 random amplified polymorphic DNA (RAPD) and 15 intersimple sequence repeat (ISSR) primers revealed a high number of monomorphic bands, with only 1.6–2.6% of the bands being polymorphic. The regeneration system established in the study has the potential to be used for rapid multiplication, conservation, and genetic transformation of this species.     

Regeneration from Isolated Portions of the Shoot Apex of Trachymene coerulea R. C. Grah

To test the morphogenettc capacity of parts of the shoot apexof Trachymene coerulea after explanting from the subjacent tissues,explants of decreasing sizes, comprising different regions ofthe menstem, were made. Growth was on culture medium withoutexogenous growth regulators. The centre of the shoot apex producedfewer mature leaves and fewer embryos from the basal tissuesthan did the flanks when separated from any continuing influencefrom the subjacent tissues. This result is interpreted as dueto physiological differences between the regions of the shootapex. While regeneration from the flanks was greater than thatfrom the centres, the latter can be regarded as morphogeneticallycompetent and physiologically active. The lesser regenerationfrom the centres is regarded as the result of greater dominanceover the basal tissues than that exerted by the flanks. Trachymene coerulea R. C. Grah, blue lace flower, shoot apex culture, regeneration of portions of shoot apex, morphogenesis     

Current trends and future prospects of biotechnological interventions through tissue culture in apple

Apple (Malus domestica Borkh.), which is a widely cultivated, important economic fruit crop with nutritive and medicinal importance, has emerged as a model horticultural crop in this post-genomic era. Apple cultivation is heavily dependent on climatic condition and is susceptible to several diseases caused by fungi, bacteria, viruses, insects, etc. Extensive research work has been carried out to standardize tissue culture protocols and utilize them in apple improvement. We review the in vitro shoot multiplication, rooting, transformation and regeneration methodologies in apple and tabulate various such protocols for easy reference. The utility and limitation of transgenesis in apple improvement have also been summarized. The concepts of marker-free plants, use of non-antibiotic resistance selectable markers, and cisgenic and intragenic approaches are highlighted. Furthermore, the limitations, current trends and future prospects of tissue culture-mediated biotechnological interventions in apple improvement are discussed.     

Inheritance of plant regeneration from maize (Zea mays L.) shoot meristem cultures derived from germinated seeds and the identification of associated RAPD and SSR markers

The inheritance of shoot regeneration through shoot-tip meristem culture derived from maize seedling was evaluated, and the markers (RAPD and SSR) associated with this regeneration character were identified both in a group of North American maize inbreds and a crossing population. A discrete distribution of percent regeneration and no. of shoots per explant was observed in the inbred group and the F₂ population. The results suggested that this regenerable trait was controlled by several major genes. Five RAPD markers were identified to be relevant to percent regeneration in maize shoot-tip culture system. One RAPD marker and three SSR markers were associated with no. of shoot per explant and its relevant traits. Of them marker BC603-1600 explained 18% of the variation for no. of shoot per explant and 16% of the variation for callus size. The BC603-1600 was sequenced and assigned in linkage group 7 based on a NCBI blast search. The information provided here should benefit to determine the genetic mechanisms involved in the maize regeneration response related to shoot meristem culture pathway and benefit to select high regenerable germplasm by using marker assisted selection.Communicated by H.F. Linskens     

Regeneration of androgenic embryos in apple (<Emphasis Type="Italic">Malus x domestica</Emphasis> Brokh.) <Emphasis Type="Italic">via</Emphasis> anther and microspore culture

Based on optimized protocols for anther and microspore culture in apple (Malus x domestica Borkh.), the regeneration phase and the efficiency of the processes in general were compared by using the same androgenic material of two experimental years. Microspore culture resulted in an increase in embryo induction depending on the genotype (Höfer 2004), however anther culture was superior to microspore culture in the total number of regenerated plants. The regeneration process in anther and microspore culture is similar. Two developmental pathways were observed: 1) secondary embryogenesis followed by adventitious shoot formation and 2) direct adventitious shoot formation from primary embryos. Induction and regeneration processes are delayed in microspore culture as compared with anther culture. The reasons for the reduced regeneration efficiency in microspore culture are discussed.     

Thidiazuron-induced high-frequency plant regeneration from leaf explants of Paulownia tomentosa mature trees

Attempts were made to study the effect of thidiazuron (TDZ) on adventitious shoot induction and plant development in Paulownia tomentosa explants derived from mature trees. Media with different concentrations of TDZ in combination with an auxin were used to induce adventitious shoot-buds in two explant types: basal leaf halves with the petiole attached (leaf explant) and intact petioles. Optimal shoot regeneration was obtained in leaf explants cultured on induction medium containing TDZ (22.7 or 27.3 μM) in combination with 2.9 μM indole-3-acetic acid (IAA) for 2 weeks, and subsequent culture in TDZ-free shoot development medium including 0.44 μM BA for a further 4-week period. The addition of IAA to the TDZ induction medium enhanced the shoot-forming capacity of explants. The caulogenic response varied significantly with the position of the explant along the shoot axis. The highest regeneration potential (85–87%) and shoot number (up to 17.6 shoots/explant) were obtained in leaf explants harvested from the most apical node exhibiting unfolded leaves (node 1). An analogous trend was also observed in intact petiole explants, although shoot regeneration ability was considerably lower, with values ranging from 15% for petioles isolated from node 1 to 5% for those of nodes 2 and 3. Shoot formation capacity was influenced by the genotype, with regeneration frequencies ranging from 50% to 70%. It was possible to root elongated shoots (20 mm) in basal medium without growth regulators; however, rooting frequency was significantly increased up to 90% by a 7-day treatment with 0.5 μM indole-3-butyric acid, regardless of the previous culture period in shoot development medium (4 or 8 weeks). Shoot quality of rooted plantlets was improved not only by IBA treatment but also by using material derived from the 4-week culture period. Regenerated plantlets were successfully acclimatized in the greenhouse 8 weeks after transplanting.     

Plant regeneration capacity of mesophyll protoplasts from Brassica napus and related species

Protoplasts from a total of thirty-six genotypes of Brassica species – B. napus, B. campestris (syn. B. rapa), B. juncea, and three distant relatives, Orychophragmus violaceus, Isatis indigotica and Xinjiang wild rape – were analysed for shoot regeneration using a feeder culture system. With the exception of B. campestris and Xinjiang wild rape, some genotypes of all the species could regenerate plants with high efficiency (above 20% of isolated calli initiating shoots). Several genotypes with high regeneration ability were elite breeding lines. Culture conditions as well as genotype had a significant impact on shoot regeneration frequency. In particular, silver nitrate added to the regeneration medium at doses of 6 and 30 μM improved shoot regeneration frequency to 25.4% and 52.2% of isolated calli, respectively, compared to 7.3% percent shoot regeneration without silver nitrate in seven responsive genotypes. Addition of silver nitrate to the regeneration medium also induced shoot regeneration in non-responsive genotypes. Intact plants could be obtained within three months from protoplast isolation in the regenerative genotypes using the current culture system. Advantages of mesophyll protoplasts as compared to protoplasts isolated from hypocotyls for genetic manipulation in Brassica species are discussed. This revised version was published online in June 2006 with corrections to the Cover Date.     

Evaluation of the effect of <Emphasis Type="Italic">in vitro</Emphasis> stress and competition on tissue culture response of flax

This study was carried out to investigate the in vitro competition in tissue culture of three flax (Linum usitatissimum L.) cultivars using different distances among hypocotyl explants cultured. Hypocotyl fresh and dry masses, shoot regeneration percentage, shoot number per hypocotyl, regenerated shoot length and total chlorophyll content were examined during shoot regeneration, while plantlet height, number of roots and length of roots were recorded during rooting. With decreasing distance among explants we observed increased shoot regeneration and rooting till a certain point from where stress initiated and significant decreases in all parameters observed. Explants cultured at distance 1.0 cm were found to be at their optimum.     

Callus induction and shoot regeneration of <Emphasis Type="Italic">Phaseolus lunatus</Emphasis> L. cv. Wonder Bush and cv. Pole Sieva

We report the first protocol for callus induction and shoot regeneration for Phaseolus lunatus L. cv. Wonder Bush and cv. Pole Sieva. We used different explants viz., epicotyls, cotyledons and hypocotyls. The medium used was MS basal medium with thidiazuron (0.5 mg l⁻¹) and IAA (0.05 mg l⁻¹) for the induction of callus followed by BAP (1.0 mg l⁻¹) for the induction of shoots. Epicotyl explants showed the fastest response and the highest percentage of shoot regeneration. This protocol opens new biotechnological strategies to transfer economically important genes to this important crop species.     

Efficient in vitro regeneration of fertile plants from corm explants of Hypoxis hemerocallidea landrace Gaza—The “African Potato”

We present efficient protocols for the regeneration of fertile plants from corm explants of Hypoxis hemerocallidea Fisch. & C. A. Mey. landrace Gaza, either by direct multiple shoot formation or via shoot organogenesis from corm-derived calluses. The regeneration efficiency depended on plant growth regulator concentrations and combinations. Multiple direct shoot formation with high frequency (100% with 5–8 shoots/explant) was obtained on a basal medium (BM) supplemented with 3 mg/l kinetin (BM1). However, efficient indirect regeneration occurred when corm explants were first plated on callus induction medium (BM2) with high kinetin (3 mg/l) and naphthalene acetic acid (NAA 1 mg/l), and then transferred to shoot inducing medium (BM3) containing BA (1.5 mg/l) and NAA (0.5 mg/l). Shoot regeneration frequency was 100% and 30–35 shoots per explant were obtained. The regenerated shoots were rooted on a root inducing medium (BM4) containing NAA (0.1 mg/l). Rooted plantlets were transferred to the greenhouse. The regenerants were morphologically normal and fertile. Flow cytometric analyses and chloroplast counts of guard cells suggested that the regenerants were diploid. Efficient cloning protocols described here, have the potential not only to substantially reduce the pressure on natural populations but also for wider biotechnological applications of Hypoxis hemerocallidea—an endangered medicinal plant.