The influence of micrografting in vitro on tissue culture behavior and vegetative propagation of old European larch trees

The influence of a new micrografting method in vitro was tested by using long shoot meristems of adult 140 year old European larch trees grafted onto larch seedling rootstocks in sterile peat pellets. Five months after grafting and transfer of grafts to ex vitro conditions, new shoots from sprouting scions were re-established into tissue culture. The propagation behavior of shoots derived from these explants was compared with shoots established via bud culture from the same donor trees. Shoot explants from micrografts multiplied more rapidly than shoots explants from the original adult donor trees. Rooting experiments with cuttings from six micrografted clones resulted in 49.9 ± 11.9% rooting. Cuttings from donor trees invariably showed no root formation. The results confirm a rejuvenating influence of micrografting in larch.     

Micrografting of ASBVd-infected Avocado (<Emphasis Type="Italic">Persea americana</Emphasis>) plants

Shoot tips (meristem plus 2–3 leaf primordia) from in vitro-germinated avocado seedlings of 2 ASBVd-infected cultivars were micrografted in vitro onto decapitated seedlings from 2 ASBVd-free cultivars, and plants were recovered. Shoot tips consisted of two different sizes, i.e., <0.5 mm long and >0.5 mm but <1 mm long. The recovered plants were indexed for ASBVd using RT-PCR. More plants (58.8%) were recovered from scions >0.5 mm than from those that were <0.5 mm (10.3%). RT-PCR demonstrated that ASBVd replicated in all micrografts from infected sources irrespective of the scion size, while no ASBVd was detected in micrografts from plants that tested negative. ASBVd therefore cannot be eliminated by in vitro micrografting.     

Development,histological observations and Grapevine leafroll‐associated virus‐3 localisation in in vitro grapevine micrografts

Development, histological process and Grapevine leafroll‐associated virus‐3 localisation were studied in micrografts of three scion/rootstock combinations: healthy/healthy, healthy/infected and infected/healthy. Earlier bud break and faster growth in scions of micrografts were obtained when the healthy shoot segments were used as scions, while earlier bud break in rootstocks and greater fresh weight of roots in micrografts were produced when the healthy shoot segments were used as rootstocks. All histological processes including callus initiation and formation in micrografting conjunctions, and initiation of new cambial cells followed by vascular bundle development connecting scions and rootstocks were similar in micrografts, regardless of the sanitary status of the scions and rootstocks used for micrografting. Virus infection in micrografting conjunctions and systematic infection in micrografts were much more efficient and faster in micrografting combination of the infected scions/healthy rootstocks than in the healthy scions/infected rootstocks. To the best of our knowledge, this is the first report addressing histological process of micrograft development and virus localisation in micrografts. In vitro culture system established in this study facilitates studies on the ‘pure’ impact of the viral infection on micrografting.     

Regeneration and micrografting of lentil shoots

Summary A protocol for regeneration and micrografting of shoots of lentil (Lens culinaris Medik) was developed. Multiple shoots (4–5) were regenerated from cotyledonary node explants on Murashige and Skoog (MS) medium containing 8.8 μM 6-benzylaminopurine. In vitro regenerated shoots were micrografted on rootstocks with 96% efficiency. The successful grafts were transplanted to pots in Redi-earth^TM, hardened off and were grown to maturity with 100% success. The success of the micrografting was independent of the nature and concentration of growth regulator used in shoot initiation medium and the time period for induction of shoots. The protocol was successful with several cultivars of lentil. The advantages of micrografting over in vitro rooting are discussed.     

Cryopreservation for eradication of Jujube witches' broom phytoplasma from Chinese jujube (Ziziphus jujuba)

Here, we report efficient eradication of Jujube witches' broom phytoplasma (Candidatus Phytoplasma ziziphi) from Chinese jujube (Ziziphus jujuba) by cryopreservation. Shoot tips (1.0 mm in size) with 5–6 leaf primordia (LPs) excised from diseased in vitro stock shoots were subject to droplet‐vitrification cryopreservation. Shoot tips following cryopreservation were post‐cultured on a recovery medium for survival. Plantlet regeneration was obtained by micrografting of surviving shoot tips upon in vitro rootstocks. With this protocol, 85% of shoot tips survived following cryopreservation, among which 75% regenerated into whole plantlets and all of them were free of phytoplasma, regardless of the sizes used for cryopreservation. Ultrastructural studies demonstrated that phytoplasma was absent in the apical dome, and leaf primordia (LPs) 1 and 2, while abundance of phytoplasma was present in the lower parts of shoot tips, leaf primordium 3 and older tissues. Histological observations showed that much more damage was found in cells located in the lower part of apical dome, leaf primordium 3 and older tissues than in those at the upper part of apical dome and in the LPs 1 and 2. These cells were most likely to survive and regenerate into phytoplasma‐free plantlets following cryopreservation and micrografting. Ploidy levels analyzed by flow cytometry (FCM) were maintained in plantlets regenerated from cryopreservation followed by micrografting. Results reported here would provide technical support for production of phytoplasma‐free plants and for long‐term storage of germplasm of Chinese jujube.     

Micrografting of <Emphasis Type="Italic">Protea cynaroides</Emphasis>

The inability to induce rooting of in vitro-established Protea cynaroides microshoots has prevented the production of complete plantlets. A successful shoot-tip micrografting technique was developed using in vitro-germinated P. cynaroides seedlings as rootstocks and axenic microshoots established from pot plants as microscions. Thirty-day old seedlings, germinated on growth-regulator-free, half-strength Murashige and Skoog medium, were decapitated and a vertical incision made from the top end. The bottom ends of microshoots established on modified Murashige and Skoog medium were cut into a wedge (‘V’) shape, and placed into the incision. The micrografted explants were cultured in a growth chamber with the temperature adjusted to 25 ± 2°C, with a 12-h photoperiod. Best results were obtained by placing the microscions directly onto the rootstock without any pre-treatments. Dipping the explants in anti-oxidant solution or placing a layer of medium around the graft area led to the blackening of the microscion.     

Early detection of grapevine leafroll virus in <Emphasis Type="Italic">Vitis vinifera</Emphasis> using <Emphasis Type="Italic">in vitro</Emphasis> micrografting

Micrografting of grapevine was investigated for its use as a tool in virus indexing of grapevine stock. Cabernet franc and Cabernet sauvignon scions infected with grapevine leafroll-associated closterovirus III (GLRaVIII) were grafted on to virus-free indicator rootstocks of LN 33 and Cabernet sauvignon growing in tissue culture. The two rootstocks and two scions were grafted in all four possible combinations along with two control grafts (virus-free scion on virus-free rootstock). A modified MS Murashige and Skoog (1962) tissue culture medium supplemented with 0.5 mg l^–1 6-benzylaminopurine was sufficient to induce multiple shoots. Shoots and micrografts readily produced roots in the basal medium. Micrografting gave an overall success rate of 77.8%, with no significant difference between LN 33 rootstock and Cabernet sauvignon. When leafroll infected scion material was micrografted on to virus-free rootstock, the rootstock leaf turned red (23.5% in LN 33 and 63.9% in Cabernet sauvignon) or it showed leafrolling (28.5%, no significant difference between LN 33 and Cabernet sauvignon) within 2–3 weeks. After 12 weeks in culture, the extent of viral symptoms in the micrografted material was high (81.3%), with no significant difference between LN 33 and Cabernet sauvignon; however, the expression of symptoms was more severe on Cabernet sauvignon than on LN 33 rootstock. Double antibody sandwich-enzyme linked immunosorbent assay (DAS-ELISA) was used to validate the visual symptoms and the presence of virus was confirmed in 80% of the rootstock with visual symptoms of infection. Results indicate that micrografting is an effective method for viral indexing of grapevines. The method can be used in conjunction with wood indexing for post-entry quarantine to identify infected material and reject it much earlier than is currently possible.     

In vitro micrografting for production of Indian citrus ringspot virus (ICRSV)-free plants of kinnow mandarin (Citrus nobilis Lour × C. deliciosa Tenora)

Production of Indian citrus ringspot virus (ICRSV)-free plants from an infected plant of kinnow mandarin (Citrus nobilis Lour × C. deliciosa Tenora) is reported. The shoot apices of different sizes (0.2–1.0 mm) excised from the ICRSV-infected plant were micrografted onto decapitated rootstock seedlings of rough lemon (C. jambhiri). Micrograft survival depended on the size of shoot apex and the sucrose concentration of the culture medium. Increase in scion size from 0.2 to 0.7 mm resulted in an increase in micrografting success rate from 30.55 to 51.88%. Further, micrograft survival obtained with 0.2 mm was improved from 30.55 to 38.88% by increasing sucrose concentration in the culture media from 5 to 7.5%. The micrografted plants were tested for ICRSV using ELISA and RT-PCR. All plants raised from 0.2-mm scion were found negative with both ELISA and RT-PCR whereas only 20% of the ELISA negative plants raised from 0.3-mm scion were found negative for ICRSV with RT-PCR. The outcome of this research is the successful establishment, acclimatization and virus testing of micrografted plants.     

Endogenous cytokinins as biochemical markers of rubber-tree (Hevea brasiliensis) clone rejuvenation

The endogenous levels of isopentenyladenine, isopentenyladenosine, zeatin and zeatin riboside and the ability forin vitro axillary shoot organogenesis and rhizogenesis were compared between mature and rejuvenated clones ofHevea brasiliensis (Müll. Arg.). Enhancement of thein vitro organogenesis ability of rubber-tree clones following somatic embryogenesis or repeated grafting onto juvenile rootstocks was accompanied by an increase of zeatin riboside levels in shoots used as starting material forin vitro micropropagation. Furthermore, the zeatin level, inin vitro shoots of clones treated byin vitro micrografting, and consequently capable of axillary shoot and root organogenesis, was higher than inin vitro shoots of non treated mature material incapable of in vitro organogenesis. We conclude that the endogenous zeatin-like cytokinin level (free and ribosylated forms) can be considered as a reliable marker for the recovery ofin vitro shoot and root organogenesis after rejuvenating treatments in rubber-tree clones.     

In vitro micrografting of cashew

Shoot tips excised from glasshouse-raised seedlings and field-grown plants of cashew (Anacardium occidentale L.) were micrografted by a modified side-grafting procedure using in vitro-raised seedling rootstocks. Factors affecting graft-take were optimised. The micro-scion take obtained was in the range 60–80%. The best growth of micro-scions was obtained with hypocotyls rather than with epicotyls as stock tissue. Rooting of micrografted shoots of mature tree origin was poor (13.3%) because the shoots were only partially rejuvenated. This revised version was published online in June 2006 with corrections to the Cover Date.     

A Study of the graft union in in vitro micrografted apple

Light microscopy was used to study graft union formation in in vitro micrografts of tissue cultured apple (Malus domestica. Borkh). Micrografts were constructed using horizontal incisions to form the grafting surface, and placing the cut ends of rootstock and scion into sterile silicon tubing to permit graft formation to occur.The outer morphological and histological development was similar for different stock-scion micrograft combinations but graft union formation was slower in heterografts than in autografts. Initial leaf expansion at the scion shoot apex occurred in all micrografted plantlets within 1–4 days and was not indicative of graft success. Progressive scion growth and development could be used as an indication of graft success by ten to fourteen days after grafting and probably was related to establisment of cell to cell contact at the graft interface. Microscopy showed initiation of callus proliferation in the vascular cumbium and the pith ten days after grafting. Differentiation was observed subsequently and this was reflected in scion development. Longitudinally orientated cambial cells began to differentiate between twenty and forty days after grafting, and formed a bridge between the vascular cylinders of scion and rootstock. The scions at this stage had as many as eight newly expanded leaves and micrografts were strong enough to permit silicon sleeve removal without damage. Continuity of new vascular elements in rootstock and scion was established around forty days. New vascular elements curved slightly in towards the pith to form a c shaped bridge across the graft union. Vascular development continued until it reached completion after six months.     

In vitro micropropagation of a Cucurbita interspecific hybrid cultivar – a root stock plant

An efficient in vitro micropropagation protocol was developed for direct shoot growth of interspecific Cucurbita hybrid variety using shoot–tips of 5-day-old explants. The excised shoot–tips were cultured on Murashige and Skoog (MS) medium containing two plant growth regulators (6-benzyladenine and naphthaleneacetic acid) with various combinations and concentrations for the study of shoot induction. The best condition for shoot growth was with 3 mg l^–1 6-benzyladenine (BA) in MS medium. The shooting frequency was 84% and five shoots were obtained from each explant after 30 days of culture. Shoots (11.5 cm length) were rooted most effectively in 1 mg l^–1 indole-3 butyric acid (IBA)-supplemented MS medium. The highest root formation rate was 93% and all rooted shoots were transplanted into soil.     

Micropropagation of the pistachio and its rootstocks by temporary immersion system

Although several studies have been reported on the micropropagation of the pistachio and its rootstocks, to date none of them had been efficient on the mass production of these plants in bioreactor systems. Thus, the micropropagation of juvenile pistachio shoot tips and nodal buds was investigated in a temporary immersion bioreactor system (RITA^®) and on a conventional semi-solid medium. Among the tested immersion conditions, immersion for 24 min every 16 h reduced vitrification and improved proliferation in the pistachio. Interactions were evident in immersion time and frequency in nodal segments. Nodal buds were better than shoot tips as the highest multiple shoot formation was recorded in MS medium containing 4 mg L^?1 BA and 0.1 mg L^?1 GA₃ in RITA^®. Although shoot tip necrosis (STN) was observed in shoots proliferated on semi-solid MS medium, such a symptom did not occur in shoots sprouted in the RITA^®. Additionally, these optimized conditions were applied to nodal buds of mature male pistachio ‘Atl?’ and Pistacia rootstocks (P. khinjuk Stocks and P. atlantica Desf.), and the micropropagation in the bioreactor system, in comparison to the semi-solid medium, was also improved. Furthermore, in vitro rooting of pistachio plantlets, despite the lower range (27.5 %), was also achieved in RITA^®. However, rooting was better on semi-solid medium for all tested species (ranged between 50 and 70 %). The results of this study showed that RITA^® could be used for the mass propagation of pistachio and its rootstocks, as well as for other woody plant species.     

Cryopreservation of in vitro-grown shoot tips of apple and pear by vitrification

In vitro-grown shoot tips of apples (Malus domestica Borkh. cv. Fuji) were successfully cryopreserved by vitrification. Three-week-old in vitro apple plantlets were cold-hardened at 5°C for 3 weeks. Excised shoot tips from hardened plantlets were precultured on a solidified Murashige & Skoog agar medium (MS) supplemented with 0.7 M sucrose for 1 day at 5°C. Following preculture shoot tips were transferred to a 2 ml plastic cryotube and a highly concentrated cryoprotective solution (designated PVS2) was then added at 25°C. The PVS2 contains (W/V) 30% glycerol, 15% ethylene glycol and 15% dimethylsulfoxide in medium containing 0.4 M sucrose. After dehydration at 25°C for 80 min, the shoot tips were directly plunged into liquid nitrogen. After rapid warming, the shoot tips were expelled into 2 ml of MS medium containing 1.2 M sucrose and then plated on agar MS medium. Direct shoot elongation was observed in approximately 3 weeks. The average rate of shoot formation was about 80%. This vitrification method was successfully applied to five apple species or cultivars and eight pear cultivars. This method appears to be a promising technique for cryopreserving shoot tips from in vitro-grown plantlets of fruit trees.Abbreviations DMSO dimethylsulfoxide - EG ethylene glycol - PVS2 vitrification solution - LN liquid nitrogen - BA 6-benzylaminopurine - NAA -naphthaleneacetic acid - SE standard error - ABA abscisic acid     

Micrografting of pistachio (Pistacia vera L. cv. Mateur)

A successful micrografting technique was developed for Pistacia vera. High levels of graft union were achieved when shoots from Stage II cultures of four-year-old P. vera. cv. Mateur were grafted onto in vitro-raised seedling rootstocks. Light and fluorescence microscopy investigations revealed that vascular continuity was established across grafts by three weeks.     

Micropropagation of wild beet (Beta maritima) from inflorescence pieces

In order to investigate the regeneration of wild beet (Beta maritima) from inflorescence pieces, the effects of growth regulator, genotype, explant source and stage of plant development on adventitious shoot formation and rooting in vitro and subsequent transplanting in the glasshouse were tested. Inflorescence tips produced more adventitious shoots than sub-apical segments and the best micropropagation was achieved on a Murashige and Skoog (MS) medium supplemented with 1.0 mg l^–1 BAP. Addition of auxin was not beneficial. The induction rate of adventitious shoots was genotype-dependent and influenced by the stage of plant development. Adventitious shoots were produced from the base of the flower buds, i.e. from the receptacle, not from axils or stalks and only a few buds on inflorescence tip explants produced adventitious shoots. Rooting was increased by using a MS medium with 3% sucrose supplemented with 1.0 mg l^–1 NAA. There was no variation in leaf morphology of the transplants. This work shows that inflorescence tips can be used successfully as explants for in vitro multiplication of sugar beet and wild beet.Abbreviations BAP benzylaminopurine - IBA indole-3-butyric acid - GA₃ gibberellic acid - MS Murashige and Skoog medium - NAA naphthaleneacetic acid Author for correspondence     

Effect of thidiazuron in germinating tamarind seedlings

Summary Tamarind, a multipurpose tropical tree species, is economically important for sustainable development of wasteland due to its hardy nature and adaptability to various agroclimatic ocnditions. Reports on in vitro morphogenesis in this species are limited, due to its recalcitrant and callogenic nature. To overcome these limitations, an attempt was made to induce meristematic activity in seedling explants. Seedlings were germinated in medium with or without thidiazuron (4.54, 9.08, 13.12, 18.16 μM). This growth regulator restricted the differentiation of the apical meristem to form shoots. It triggered proliferation of the meristematic tissue at the cotyledonary node and a large number of meristematic buds appeared in a ridial pattern around the node. The meristematic activity extended to the junction of the epicotyl and hypocotyl, giving rise to buds in the form of protuberances in all sides of the junction. These buds differentiated to form shoot primordia and subsequently to shoots in medium devoid of growth regulators. Plants developed by micrografting of these shoots on seedling-derived rootstocks survived in soil.     

In vitro propagation of cashew from young trees

Summary Regeneration of cashew (Anacardium occidentale L.) from shoot explants of young grafts of mature tree origin is described. Establishment of shoot cultures was affected by season of collection, source, and type of explant. Explants from young grafts established better than those collected from field trees, and nodal cuttings regenerated better than shoot tips. Maximum percentage bud break and minimum contamination was noticed when shoots were collected in dry months (January to May). Pre-conditioning of stock plants by hormonal spray with 6-benzyladenine (BA) and gibberellic acid (GA₃) and brief presoaking of shoots in BA had no significant effect on culture establishment. MS (Murashige and Skoog, 1962) medium with half-strength major nutrients, 2.74 mM l-glutamine, 87.6 mM sucrose, and 2.25 gl⁻¹ phytagel was ideal for culture initiation. Inclusion of 0.1% polyvinylpyrrolidone (PVP-360) in the media reduced phenolic exudation. Solidified media was superior to liquid medium. Sucrose/glucose as energy source was found essential in the medium and had significant effect on percentage bud break and shoot development. A repeatable axillary shoot-bud induction was obtained on the above basal medium containing thidiazuron (TDZ) alone and in combination with BA. TDZ at 0.45 μM was best for axillary shoot-bud proliferation (4.5 buds per shoot) with maximum response (100%). Bud elongation could be stimulated in multiple shoots on medium containing 116.8 mM sucrose. In vitro rooting on auxin media and pulsing microshoots in 10 mM naphthalenaacetic acid (NAA) was ineffective. Rooting inability was, however, overcome by a micrografting procedure.     

Cryopreservation of in vitro-grown shoot tips of grapevine by encapsulation-dehydration

In vitro-grown shoot tips of the LN33 hybrid (Vitis L.) and cv. Superior (Vitis vinifera L.) were successfully cryopreserved by encapsulation-dehydration. Encapsulated shoot tips were precultured stepwise on half-strength MS medium supplemented with increasing sucrose concentrations of 0.25, 0.5, 0.75 and 1.0 M for 4 days, with one day for each step. Following preculture, encapsulated shoot tips were dehydrated prior to direct immersion in liquid nitrogen for 1 h. After thawing, cryopreserved shoot tips were post-cultured on a post-culture medium for survival. An optimal survival of cryopreserved shoot tips was achieved when encapsulated shoot tips were dehydrated to 15.6 and 17.6% water content for the LN33 hybrid and cv. Superior, respectively. Comparison between the effects of dehydration with silica gel and by air drying on cryopreserved shoot tips, showed that survival was dependent on water content, not on dehydration method. The thawing method markedly affected survival of cryopreserved shoot tips, and thawing at 40 °C for 3 min was found best. No callus formation and fastest shoot elongation were obtained when cryopreserved shoot tips were post-cultured on the post-culture medium composed of half-strength MS supplemented with 1 mg l⁻¹ BA and 0.1 mg l⁻¹ NAA. With these optimized parameters, 60 and 40% survival of cryopreserved shoot tips were obtained for the LN33 hybrid and cv. Superior, respectively. This revised version was published online in June 2006 with corrections to the Cover Date.