ナショナルバイオリソースプロジェクト

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(27) Hirai T, Kim YW, Kato K, Hiwasa-Tanase K, Ezura H (2011) Uniform accumulation of recombinant miraculin protein in transgenic tomato fruit using a fruit- ripening-specific E8 promoter. Transgenic Research (In press).
(26) Covering chemical diversity of genetically-modified tomatoes using metabolomics for objective substantial equivalence assessment. Kusano et al. (2011) PloS ONE 6(2)e16989 [Journal site]
(25) TOMATOMA: A novel tomato mutant databse distributing Micro-Tom mutant collections. (2011) Saito et al., (2011) 52:283-296. Plant and Cell Physiology [Journal site]
(24) (Reivew article) Systematical development of tomato bioresources in Japan. Ariizumi et al., (2011) Interdisciplinary Bio Central 3:1-6. {Journal site}
(23) (和文総説論文) ナショナルバイオリソースプロジェクト・トマト(NBRPトマト)／研究を支えるバイオリソースの整備.　化学と生物 2月号　(2011) 有泉亨　江面浩　
(22) Genetic suppression analysis in novel vacuolar processing enzymes reveals their roles in controlling sugar accumulation in tomato fruits. Ariizumi T et al. (2011) Journal of Experimental Botany (In press) {Journal site}
(21) High-level accumulation of recombinant miraculin protein in transgenic tomatoes expressing a synthetic miraculin gene with optimized codon usage terminated by the native miraculin terminator. Hiwasa-Tanase K et al. (2011) Plant Cell Reports 30: 113-124. {Journal site}.
(20) The overexpression of spermidine synthase (MdSPDS1) leads to significant salt tolerance in tomato plant. Neily MH et al. (2011) Plant Biotechnology. 28; 33-42. {Journal site}
(19) Production of prenylated flavonoids in tomato fruits expressing a prenyltransferase gene from Streptomyces coelicolor. Koeduka et al. (2011) Plant Biology.13; 411-415 {Journal site}
(18) SNP discovery and linkage map construction in cultivated tomato. Shirasawa et al. (2010) DNA Res.17:381-391 [Journal site]

(17) Molecular breeding of tomato lines for mass production of miraculin in a plant factory.Kato et al., (2010) J. Agric. Food Chem. 58(17):9505-9510. {Journal site}
(16) Enhanced polyamine accumulation alters carotenoid metabolism at the transcriptional level in tomato fruit over-expressing spermidine synthase. Neily et al., (2010) J. Plant Physiol. {Journal site}
(15) Metabolic alterations in organic acids and γ-amino butyric acid in developing tomato (Solanum lycopersicum L.) fruits. Yin et al., Plant Cell Physiol. 51(8):1300-1314. {Journal site}.
(14) Gene dosage and genetic background affect miraculin accumulation in transgenic tomato fruits. Kim et al., (2010) Plant Biotech. 27(4): 333-338 {Journal site}.
(13) Lowering intercellular melatonin levels by transgenic analysis of indoleamine 2,3-dioxygenase from rice in tomato plants. Okazaki et al., (2010) J. Pineal Res. 49:239-247 {Journal site}
(12) Production of recombinant miraculin using transgenic tomato in a closed-cultivation system. Hirai T et al. J. Agric. Food Chem. 58:6096-6101. [Journal site]
(11) Large-scale analysis of full-length cDNAs from the tomato (Solanum lycopersicum). Aoki et al., (2010) BMC genomics, 11:210 [Journal site]
(10) Quantitative analysis of plant polyamines including thermospermine during growth and salinity stress. Naka et al., (2010) Plant Physiol. Biochem. 48:527-533. [Journal site]
(9) Tomato is a suitable material for producing recombinant miraculin protein in genetically stable manner. Yano et al., (2010) Plant Sci. 178:469-473. [Journal site]
(8) Coexpression analysis of tomato genes and experimental verification of coordinated expression of genes found in a functionally enriched coexpression module. Ozaki et al., (2010) DNA Res. 17:105-116. [Journal site]
(7) Spatial and Developmental Profiling of Miraculin Accumulation in Transgenic Tomato Fruits Expressing the Miraculin Gene Constitutively. Kim et al., (2010) J. Agric. Food Chem. 58: 282-286. [Journal site]
(6) Ripening-Associated ethylene biosynthesis in tomato fruit is autocatalytically and developmentally regulated. Yokotani et al., (2009) J. Exp. Bot. 60(12): :3433-3442. [Journal site]
(5) Cloning and characterization of a Chlamydomonas reinhardtii cDNA arylalkylamine N -acetyltransferase and its use in the genetic engineering of melatonin content in the Micro-Tom tomato. Okazaki M. et al. (2009) J. Pineal Res. 46(4): 373-382. [Journal site]
(4) Profiling of melatonin in the model tomato (Solanum lycopersicum L.) cultivar Micro-Tom. Okazaki M and Ezura H. (2009) J. Pineal Res. 46(3): 338-343. [Journal site]
(3) Mutant Resources for the miniature Tomato (Solanum lycopersicum L.) 'Micro-Tom'. Saito T. et al. (2009) J. Japan. Soc. Hort. Sci. 78(1): 6-13. [Journal site]
(2) Comprehensive Resources for Tomato Functional Genomics Based on the Miniature Model Tomato Micro-Tom. Matsukura C. et al. (2008) Current Genomics 9(7): 436-443. [Journal site]
(1) Biochemical mechanism on GABA accumulation during fruit development in tomato. Akihiro T. et al. (2008) Plant Cell Physiol. 49(9): 1378-1389. [PubMed]