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Production of Grafted Plants of Mature Quercus Robur L. 'Fastigiata'

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Production of Grafted Plants of Mature Quercus Robur L. 'Fastigiata' Propagation of Ornamental Plants Vol. 16, № 2, 2016: 47-55 PRODUCTION OF GRAFTED PLANTS OF MATURE QUERCUS ROBUR L. ‘FASTIGIATA’ THROUGH SERIAL GRAFTING ON JUVENILE ROOTSTOCKS AND EFFECT ON MICROPROPAGATION Santiago Crecente-Campo and Juan Luis Fernández-Lorenzo* Santiago de Compostela University, Higher Polytechnic School of Lugo, Department of Crop Production, Benigno Ledo str., 27002 Lugo, Spain, *Fax: + 34-982823001, *E-mail: [email protected] REFERENCES BALLESTER A., MEIER-DINKEL A. (1990). Micropropagation of Quercus species. In: Riordain F. O. (Ed.). COST 87 Micropropagation of Betula and Quercus. Initial reports of the woody plant working group: 39-75. BON M. (1988). J 16: An apex protein associated with juvenility of Sequoiadendron giganteum. Tree Physiology, 4: 381-387. BORZAN ž. (1993). Grafting of oaks with variegated leaves. Annales des Sciences. Forestières, 50: 351-355. BROSNAN C. A., MITTER N., CHRISTIE M., SMITH N. A., WATERHOUSE P. M., CARROLL B. J. (2007). Nuclear gene silencing directs reception of long-distance mRNA silencing in Arabidopsis. Proceedings of the Natural Academy of Sciences of USA, 104: 14741-14746. CHABUKSWAR M. M., DEODHAR M. A. (2006). Restoration of rooting competence in a mature plant of Garcinia indica through serial shoot tip grafting in vitro. Scientia Horticulturae, 108: 194-199. CHALUPA V. (1993). Vegetative propagation of oak (Quercus robur and Q. petraea) by cutting and tissue culture. Annales des Sci- ences Forestières, 50: 295-307. CHANG I. F., CHEN P. J., SHEN C. H., HSIEH T. J., HSU Y. W., HUANG B. L., KUO C. I., CHEN Y. T., CHU H. A., YEH K. W., HUANG L. C. (2010). Proteomic profiling of proteins associated with the rejuvenation of Sequoia sempervirens (D. Don). Endl. Protein Sci- ence, 8: 64. CHIMOT-SCHALL F., VILLEMUR P., JONARD R. (1986). Essays of rectification of a precocious diagnostic of incompatibilities for the graft- ing with three techniques in vitro: The micrografting, the associations of inter nodes and the fusions of callus. Comptes rendus de l’Académie des Sciences, Paris, 303, Série III: 591-594. CRECENTE-CAMPO S. (2013). Microenxerto e recultivo do calo basal na micropropagaciόn de material adulto de carballo e castieiro. PhD Thesis. University of Santiago de Compostela, 227 pp. DANTHU P., HANE B., SAGNA P., GASSAMA Y. K. (2002). Restoration of rooting competence in mature Faidherbia albida, a Sahelian leguminous tree, through serial root sucker micrografting. New Forests, 24: 239-244. DANTHU P., TOURÉ M. A., SOLOVIEV P., SAGNA P. (2004). Vegetative propagation of Ziziphus mauritiana var. Gola by micrografting and its potential for dissemination in the Sahelian Zone. Agroforestry Systems, 60: 247-253. DUCOUSSO A., BORDACS S. (2004). EUFORGEN Technical Guidelines for genetic conservation and use for pedunculate and sessile oaks (Quercus robur and Q. petraea). International Plant Genetic Resources Institute, Rome, Italy, 6 pp. DUNOYER P., BROSNAN C. A., SCHOTT G., WANG Y., JAY F., ALIOUA A., HIMBER C., VOINET O. (2010). An endogenous, systemic RNAi pathway in plants. EMBO Journal, 29: 1699-1712. ERMEL F. F., POESSEL J. L., FAUROBERT M., CATESSON A. M. (1997). Early scion/stock junction in compatible and incompatible pear/ pear and pear/quince grafts: A histo-cytological study. Annals of Botany, 79: 505-515. ERREA P., GARAY L., MARIN J. A. (2001). Early detection of graft incompatibility in apricot (Prunus armeniaca) using in vitro tech- niques. Physiologia Plantarum, 112: 135-141. EVERS P., VERMEER E., VAN EEDEN S. (1993). Rejuvenation of Quercus robur. Annals of Forest Science, 50: 330-335. EWALD D., KRETZSCHMAR U. (1996). The influence of micrografting in vitro on tissue culture behaviour and vegetative propagation of old European larch trees. Plant Cell, Tissue and Organ Culture, 44: 249-252. EWALD D., NAUJOKS G. (1997). Sustainability of rejuvenation in larch and oak clones. In: Welander M. (Ed.). Identification and Control of Phase Changes in Rejuvenation. COST 822, 4th Meeting Working Group 3. Nitra, Slovakia: 7-11. FERNÁNDEZ-LORENZO J. L., FERNÁNDEZ-LÓPEZ M. J. (2005). Reinvigoration of mature Castanea sativa by micrografting onto a juvenile clone. Acta Horticultura, 693: 293-298. Fraga M. F., Caсal M. J., aragonйs a., rodrнguez R. (2002). Factors involved in Pinus radiata D. Don. micrografting. Annals of Forest Science, 59: 155-161. FREITAS M. I. (2002). Propagacão Vegetativa de Sobreiros Seleccionados. Silva Lusitanica, 10: 17-52. GIOVANNELLI A., GIANNINI R. (2000). Reinvigoration of mature chestnut (Castanea sativa) by repeated graftings and micropropaga- tion. Tree Physiology, 20: 1243-1248. GREENWOOD M. S., HOPPER C. A., HUTCHISON K. W. (1989). Effect of age on shoot growth, foliar characteristics, and DNA methyla- tion. Plant Physiology, 90: 406-412. GRESSHOff P. M., DOY C. H. (1972). Development and differentiation of haploid Lycopersicum esculentum. Planta, 197: 161-170. HAQUE A. K., YAMAOKA N., NISHIGUCHI M. (2007). Cytosine methylation is associated with RNA silencing in silenced plants but not with systemic and transitive RNA silencing through grafting. Gene, 396: 21-31. HARADA T. (2010). Grafting and RNA transport via phloem tissue in horticultural plants. Scientia Horticulturae, 125: 545-550. HARTMANN H. T., KESTER D. E., DAVIES F. T., GENEVE R. L. (2002). Plant Propagation. Principles and Practices (7th Edition). Prentice- Hall. New Jersey, 888 pp. HAYWOOD V., YU T. S., HUANG N. C., LUCAS W. J. (2005). Phloem long-distance trafficking of gibberellic acid-insensitive RNA regu- lates leaf development. Plant Journal, 42: 49-68. HUANG L. C., HSIAO C. K., LEE S. H., HUANG B. L., MURASHIGE T. (1992a). Restoration of vigor rooting competence in stem tissues of mature Citrus by repeated grafting of their shoot apices onto freshly germinated seedlings in vitro. In Vitro Cellular & De- velopmental Biology-Plant, 28: 30-32. Huang L. C., Lius S., Huang B. L., Murashige T., Mahdi E. F. M., Van-Gundy R. (1992b). Rejuvenation of Sequoia sempervirens by repeated grafting of shoot tips onto juvenile rootstocks in vitro. Plant Physiology, 98: 166-173. Kasai A., Bai S., Li T., Harada T. (2011). Graft-transmitted siRNA signal from the root induces visual manifestation of endogenous post-transcriptional gene silencing in the scion. PloS One, 6 (2): e16895. doi:10.1371/journal.pone.0016895. Kim M., Canio W., Kessler S., Sinha N. (2001). Developmental changes due to long-distance movement of a homeobox fusion transcript in tomato. Science, 293: 287-289. Kleinschmit J., Witte R., Sauer A. (1975). Möglichkeiten der Zuchterischen Verbesserung von Stiel und Traubeneichen (Quercus robur und Quercus petraea). II. Versuche zur Stecklingsvermehrung von Eiche. Allgemeine Forst und Jagdzeitung, 146: 179-185. Kothencz Z., Lantos A., Vegvari G. (2001). Bench grafting of Quercus robur ‘Fastigiata’, Quercus pontica and Quercus × turneri ‘Pseudoturneri’. Propagation of Ornamental Plants, 1: 28-30. Kudo H., Harada T. (2007). A graft-transmissible RNA from tomato rootstock changes leaf morphology of potato scion. HortScience, 42: 225-226. Lloyd G., McCown B. (1981). Commercially-feasible micropropagation of mountain laurel, Kalmia latifolia, by use of shoot-tip culture. Combined Proceedings, International Plant Propagators Society, 30: 421-427. MARKS T. R., SIMPSON S. E. (2000). Interaction of explant type and indole-3-butyric acid during rooting in vitro in a range of difficult and easy-to-root woody plants. Plant Cell, Tissue and Organ Culture, 62: 65-74 Mneney E., Mantell S. (2001). In vitro micrografting of cashew. Plant Cell, Tissue and Organ Culture, 66: 49-58. Molnar A., Meinyk C. W., Bassett A., Hardcastle T. J., Dunn R., Baulcombe D. C. (2010). Small silencing RNAs in plants are mobile and direct epigenetic modification in recipient cells. Science, 328: 872-875. Monteuuis O. (1995a). In vivo grafting and in vitro micrografting of Acacia mangium: impact of ortet age. Silvae Genetica, 44: 190-193. Monteuuis O. (1995b). Influence of the grafting technique on meristem micrografting of Douglas-fir. New Forest, 10: 267-273. Monteuuis O. (2012). In vitro grafting of woody species. Propagation of Ornamental Plants, 12: 11-24. Moon H. K., Yi J. S. (1993). Cutting propagation of Quercus acutissima clones after rejuvenation through serial grafting. Annales des Sciences Forestiéres, 50: 314-318. Nelson S. C. (2006). Grafting of Acacia koa Gray onto young Acacia seedlings. Nature Plants Journal, 7: 137-140. Obdržálek J., Jílková J. (2006). Winter grafting of oaks, Quercus L. Horticultural Science, 33: 61-69. Padilla I. N. G., Encina C. L. (2011). The use of consecutive micrografting improves micropropagation of cherimoya (Annona cher- imola Mill.) cultivars. Scientia Horticulturae, 129: 167-169. Palauqui J. C., Vaucheret H. (1998). Transgenes are dispensable for the RNA degradation step of cosuppression. Proceedings of the National Academy of Sciences of USA, 95: 9675-9680. Palauqui J. C., Elmayan T., Pollien J. M., Vaucheret H. (1997). Systemic acquired silencing: Transgene-specific post-transcriptional silencing is transmitted by grafting from silenced stocks to non-silenced scions. EMBO Journal, 16: 4738-4745. Pliego-Alfaro F., Murashige T. (1987). Possible rejuvenation of adult avocado by graftage onto juvenile rootstocks in vitro. Hort- Science, 22: 1321-1324. Revilla M. A., Pacheco J., Casares A., Rodríguez R. (1996). In vitro reinvigoration of mature olive trees (Olea europaea L.) through micrografting. In vitro Cellular & Developmental Biology-Plant, 32: 257-261.
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