[1] Perl A, Lotan O , Abu- Abied M, et al. Establishment of an Agrobacterium- mediated transformation system for grape (Vitis vinifera L): The role of antioxidants during grape- Agrobacterium interactions[J]. Nature Biotechnology,1996,14:624-628.
[2] Jaillon O, Aury J M, Noel B, et al. The grapevine genome sequence suggest ancestral hexaploidization in major angiosperm phyla[J]. Nature,2007,449:463-465.
[3] Martinelli L, Gribaudo I. Somatic embryogenesis in grapevine.// In: Roubelakis- Angelakis K A. Grapevine molecular biology and biotechnology( 2nd Edn) [M]. Springer Science & Business Media B V: Netherlands,2009,277-284.
[4] 姜建福,孙海生,刘崇怀,等.2000年以来中国葡萄育种研究进展[J].中外葡萄与葡萄酒,2010,3:60-65.
[5] 郝燕,王发林,李红旭,等.提高葡萄杂交育种效率的研究[J].北方园艺,2007,7:23-24.
[6] 侯文胜,郭三堆,路明.利用转基因技术进行植物的遗传改良[J].生物技术通报,2002,1:12-15.
[7] Wang, Q C, Li P, Hanania U, et al. Improvement of Agrobacteriummediated transformation efficiency and transgenic plant regeneration of Vitis vinifera L. by optimizing selection regimes and utilizing cryopreserved cell suspensions[J]. Plant Science,2005,168 (2):565-571.
[8] Feechan A, Jermakow A, Torregrosa L, et al. Identification of grapevine MLO gene candidates involved in susceptibility to powdery mildew[J]. Functional Plant Biology, 2008, 35: 1255-1266.
[9] Mullins M G, Archie Tang F C, Facciotti D. Agrobacteriummediated genetic transformation of grapevines: transgenic plants of Vitis rupestris Scheele and buds of Vitis vinifera L.[J]. Bio/Technol, 1990,8:1041-1045.
[10] Franks T, He D G, Thomas M. Regeneration of transgenic vinifera Sultana plants: genotypic and phenotypic analysis[J]. Molecular Breeding,1998,4:321-333.
[11] Yamamoto T, Iketani H, Nishizawa Y, et al. Transgenic grapevine plants expressing a rice chitinase with enhanced resistance to fungal pathogens[J]. Plant Cell Reports,2000,19:639-646.
[12] Bornhoff B A, Harst M, Zyprian E, et al. Transgenic plants of Vitis vinifera cv. Seyval Blanc[J]. Plant Cell Reports,2005,24:433-438.
[13] Marsoni M, Bracale M, Espen L, et al. Proteomic analysis of somatic embryogenesis in Vitis vinifera[J]. Plant Cell Reports,2008, 27(2):347-356.
[14] Zhang J W, Ma H Q, Chen S, et al. Stress response proteins' differential expression in embryogenic and non-embryogenic callus of Vitis vinifera L. cv. Cabernet Sauvignon-A proteomic approach [J]. Plant Science,2009,177(2):103-113.
[15] Li Z T, Dhekney S, Dutt M, et al. Optimizing Agrobacteriummediated transformation of grapevine[J]. In Vitro Cell Dev BiolPlant,2006,42:220-227.
[16] Bouamama B, Mliki A, Ghorbel A. Efficiency of coupling biolistic and Agrobacterium in genetic transformation of Tunisian autochthonous garpes[J]. Agricoltura Mediterranea,2000,130(3- 4): 223-227.
[17] Scorza R, Cordts J M, Ramming D W, et al. Transformation of grape (Vitis vinifera L.) zygotic derived somatic and regeneration of transgenic plants[J]. Plant Cell Reports,1995,14(9):589-592.
[18] Vidal J R, Kikkert J R, Wallace P G, et al. High-efficiency biolistic co-transformation and regeneration of Chardonnay(Vitis vinifera L.) containing npt- Ⅱ and antimicrobial peptide genes[J]. Plant Cell Rep,2003,22:252-260.
[19] Colby S M, Meredith C P. Kanamyein sensitivity of cultured tissues of Vitis[J]. Plant Cell Reports,1990,9:237-240.
[20] Lopez-Perez A J, Velasco L, Pazos-Navarro M, et al. Development of highly efficient genetic transformation protocols for table grape Sugraone and Crimson Seedless at low Agrobacterium density[J]. Plant Cell Tiss Org,2008,94(2):189-199.
[21] Li Z T, Dhekney S A, Dutt M, et al. An improved protocol for Agrobacterium-mediated transformation of grapevine (Vitis vinifera L.) [J]. Plant Cell, Tissue and Organ Culture,2008,93(3):311-321.
[22] Guan X, Zhao H, Xu Y, et al. Transient expression of glyoxal oxidase from the Chinese wild grape Vitis pseudoreticulata can suppress powdery mildew in a susceptible genotype[J]. Protoplasma, 2010.
[23] Aguero C B, Uratsu S L, Greve C, et al. Evaluation of tolerance to Pierce’ s disease and botrytis intransgenicplants of Vitis vinifera L. Expressing the pear PGIP gene[J]. Molecular Plant Pathology,2005, 6:43-51.
[24] Becker J V. Functional analysis of poly galacturonase- inhibiting proteins (PGIPs)from Vitis species: identi fi cation of anadditional rolein plant defence. 8th International Symposium of Grapevine Physiology and Biotechnology[C]. Adelaide, Australia. 2008.
[25] Zok A, Olah R, Hideg E, et al. Effect of Medicago sativa ferritin gene on stress tolerance in transgenic grapevine[J]. Plant Cell, Tissue and Organ Culture,2010,100:339-344.
[26] Costantini E, Landi L, Silvestroni O, et al. Auxin synthesisencoding transgene enhances grapefecundity[J]. Plant Physiology, 2007,143:1689-1694.
[27] Fan C H, Pu N, Wang X P, et al. Agrobacterium-mediated genetic transformation of grapevine (Vitis vinifera L.) with a novel stilbene synthase gene from Chinese wild Vitis pseudoreticulata[J]. Plant Cell, Tissue and Organ Culture,2008,92(2):197-206.
[28] Xu W R, Yu Y H, Ding J H, et al. Characterization of a novel stilbene synthase promoter involved in pathogen- and stressinducible expression from Chinese wild Vitis pseudoreticulata[J]. Planta,2010,231:475-487.
[29] Torregrosa L, Pradal M, Souquet J M, et al. Manipulation of VvAdh to investigate its function in grapevine berry development[J]. Plant Science,2008,174:149-155.
[30] Carmona M J, Chaib J. A molecular genetic perspective of reproductive developmentin grapevine[J]. Journal of Experimental Botany,2008,59:2579-2596.
[31] Poupin M J, Federici F, Medina C, et al. Isolation of the three grape sub- lineages of B- class MADS- box TM6, PISTILLATA and APETALA3 genes which are differentially expressed during flower and fruit development[J]. Gene,2007,404:10-24.
[32] 王关林,方宏筠.果树基因工程研究进展及展望[J].中国果树,2002 (3):43-47.
[33] Dhekney S A, Li Z T, Dutt M, et al. Agrobacterium- mediated transformation of embryogenic cultures and plant regeneration in Vitis rotundifolia Michx. (muscadine grape) [J]. Plant Cell Rep, 2008,27(5):865-872.
|
