Figure 1. JSOL Micro-Tom Mutant Line
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か Hiroshi Ezura a , Tsuyoshi Mizoguchi a , Shin Watanabe a , Sayaka Uchii a , Sun Hyon Jin a , Yasutaka Kubo b , Hitoshi Mori c , Shunsuke Imanishi d , Daisuke Shibata e a Gene Research Center, University of Tsukuba, 1-1-1 Tennodai, Tsukuba-shi, Ibaraki-ken, 305-8577, Japan, b Guraduate School of National Science, Okayama University, 1-1-1 Tsushima-naka, Okayama-shi, Okayama-ken, 700- 8530 c Guraduate School of Bioagricultural Sciences, Nagoya University, Furo-cho ChiFull Address,Japan d National Institute of Vegetable and Tea Science, NARO, 360 Kusawa, Ano, Mie-ken, 514-2392, Japan e Kazusa DNA Research Institute, Kazusa-Kamatari 2-6-7, Kisarazu-shi, Chiba 292-0818, Japan Email: [email protected] Figure 1. JSOL Micro-Tom Mutan t Line QuickTime˛ Ç∆ TIFFÅià≥èkǻǵÅj êLí£ÉvÉçÉOÉâÉÄ Ç™Ç±ÇÃÉsÉNÉ`ÉÉÇかå©ÇÈÇΩÇ Ç…ÇÕïKóvÇ≈Çか ÅB fl ∑ QuickTime˛ Ç∆ TIFFÅià≥èkǻǵÅj êLí£ÉvÉçÉOÉâÉÄ Ç™Ç±ÇÃÉsÉNÉ`ÉÉÇかå©ÇÈÇΩÇ Ç…ÇÕïKóvÇ≈Çか ÅB fl ∑ QuickTime˛ Ç∆ TIFFÅià≥èkǻǵÅj êLí£ÉvÉçÉOÉâÉÄ Ç™Ç±ÇÃÉsÉNÉ`ÉÉÇかå©ÇÈÇΩÇ Ç…ÇÕïKóvÇ≈Çか ÅB fl ∑ QuickTime˛ Ç∆ TIFFÅià≥èkǻǵÅj êLí£ÉvÉçÉOÉâÉÄ Ç™Ç±ÇÃÉsÉNÉ`ÉÉÇかå©ÇÈÇΩÇ Ç…ÇÕïKóvÇ≈Çか ÅB fl ∑ QuickTime˛ Ç∆ TIFFÅiLZWÅj êLí£ÉvÉçÉOÉâÉÄ Ç™Ç±ÇÃÉsÉNÉ`ÉÉÇかå©ÇÈÇΩÇ Ç…ÇÕïKóvÇ≈Çか ÅB fl ∑ QuickTime˛ Ç∆ TIFFÅià≥èkǻǵÅj êLí£ÉvÉçÉOÉâÉÄ Ç™Ç±ÇÃÉsÉNÉ`ÉÉÇかå©ÇÈÇΩÇ Ç…ÇÕïKóvÇ≈Çか ÅB fl ∑ QuickTime˛ Ç∆ TIFFÅià≥èkǻǵÅj êLí£ÉvÉçÉOÉâÉÄ Ç™Ç±ÇÃÉsÉNÉ`ÉÉÇかå©ÇÈÇΩÇ Ç…ÇÕïKóvÇ≈Çか ÅB fl ∑ QuickTime˛ Ç∆ TIFFÅiLZWÅj êLí£ÉvÉçÉOÉâÉÄ Ç™Ç±ÇÃÉsÉNÉ`ÉÉÇかå©ÇÈÇΩÇ Ç…ÇÕïKóvÇ≈Çか ÅB fl ∑ QuickTime˛ Ç∆ TIFFÅiLZWÅj êLí£ÉvÉçÉOÉâÉÄ Ç™Ç±ÇÃÉsÉNÉ`ÉÉÇかå©ÇÈÇΩÇ Ç…ÇÕïKóvÇ≈Çか ÅB fl ∑ QuickTime˛ Ç∆ TIFFÅiLZWÅj êLí£ÉvÉçÉOÉâÉÄ Ç™Ç±ÇÃÉsÉNÉ`ÉÉÇかå©ÇÈÇΩÇ Ç…ÇÕïKóvÇ≈Çか ÅB fl ∑ Figure 3. M2 Pl ants Introduction The spotlight for most plant scientists must be post- genomic studies such as transcriptome, proteome, and meta bolome. In addition, advance in bioinfomatics pioneer new category of studies like system biology. Tomato is a mode l plant that gives information on fruit storage, product translocation and novel metabolites. It is highly expecte d that other solanaceae plant will have constructive feed back from the genetic and molecular study of tomato. More over, the development of L. esculentum var. Micro-Tom gave u s a great advantage to examine tomato plantlet in narrow room space. Our main objective is to construct an infrast ructure for Micro-Tom study. Mutanegenesis has been highl y effective strategy for studying the genetic bases of tr aits. One of the mutational approach is a chemical mutage nesis by ehylmetane sulphate (EMS) treatment which gives rise to a high mutation frequency without apparent prefer ences for specific genomic regions. It can also generate many alleles that enable one to get null phenotypes. At p resent, we are establishing Micro-Tom mutant lines by EMS treatment and a construction of the database in silico wi th aim to supply the experimental resource and the inform ation for worldwide use. Focusing on both "Floral and cir cadian rhythm in neuter plant" and " plant hormone and fr uit development", we have already set up a system for scr eening mutants. In addition, we have established an effic ient transformation protocol for developing T-DNA tag lin es in Micro-Tom. Here we report the latest progress in ou r work conducted by Japanese Solanaceae consortium (JSO L). Figure 4. Micro-Tom Mutant Database Organization: 001 Ç©Ç Ç≥ ∏ Mutant no. Å@Å@Å@Å@Å@Å@Å@ Mutant name: 1. Seed 1-1.Germination 1-2.Seedling lethality 1-3.Slow germination 2. Plant size 2-1. Extremely small 2-2.Small plant 2-3. Large plant 3. Plant habit 3-1.Internode length 3-2. Branching 3-3. Aborted growth 4. Leaf morphology 4-1. Leaf width 4-2. Leaf size 4-3. Leaf texture 5. Leaf color 5-1. Purple leaf 5-2. Yellow leaf 5-3. Yellow-green leaf 5-4. Dull green/gray leaf 5-5. Variegation 6. Flowering timing 7. Inflorescence structure 8. Flower morphology 8-1. Flower homeoticmutation 8-2. Flower organ size 8-3. Flower organ width 9. Flower color 9-1. White flower 9-2. Pale yellow flower 9-3. Strong yellow flower 10. Fruit size 10-1. Small fruit 10- 2. Large fruit 11. Fruit morphology 11-1. Long fruit 11-2. Rounded fruit 11-3. Other fruit morphology 12. Fruit color 12-1. yellow fruit 12-2. orange fruit 12-3. dark red fruit 12-4. Epidermis 12-5. Green fruit 13. Fruit ripening 13-1. Early ripening 13-2. Late ripening 14. Sterility 14-1. Partial sterility 14-2. Full sterility 15. Disease and stress response 15-1. Necrosis 15-2. Wilting 15-3. other disease response Åú Å@phenotype ņ Å@ 0:germination ņ Å@ 1:leaf production ņ Å@ 2:side shoot ņ Å@ 3:inflorescence ņ Å@ 4:flowering ņ Å@ 5:fruit ņ Å@ 6 ripening Åú Å@growth stage Comments (free text format) IMG Image upload x x Generation of Micro-Tom Based Mutant Lines for Tomato Genomics by apanese Solanaceae Genomics Consortium (JSOL QuickTime˛ Ç∆ TIFFÅiLZWÅj êLí£ÉvÉçÉOÉâÉÄ Ç™Ç±ÇÃÉsÉNÉ`ÉÉÇかå©ÇÈÇΩÇ Ç…ÇÕïKóvÇ≈Çか ÅB fl ∑ Figure 2. JSOL Micro-Tom Mutant Line Te am QuickTime˛ Ç∆ TIFFÅiLZWÅj êLí£ÉvÉçÉOÉâÉÄ Ç™Ç±ÇÃÉsÉNÉ`ÉÉÇかå©ÇÈÇΩÇ Ç…ÇÕïKóvÇ≈Çか ÅB fl ∑ 1. Micro-Tom Mutant Line After organizing Japanese Solanaceae consortium (JSOL) i n 2004, we immediately decided to establish Micro-Tom mutant line and to set up a system for screening mutants. We starte d to cultivate M1 plants at the end of 2004 (Figure 1) and w e had harvested 4000 M1 Plants by this spring and obtained 2 500 M2 families (Table 1). These M2 Plants have already cult ivated and been ready for screening. 2. Micro-Tom Mutant Database 3. Establish Micro-Tom Transformation System for T-DNA Tag 3. Conclusion JSOL Micro-Tom Mutant Line project is a collaborate work with 5 Japanese institutes. Now M2 Plant seeds are distribut ed to each institutes and cultivated (Figure 2). JSOL Micro-Tom Mutan t Line project is a colla borate work with 5 Japane se institutes. Now M2 Pla nt seeds are distributed to each institutes and cu ltivated (Figure 2). At the same time, we are establishing TILLING SYST EM for screening mutants. Some interesting phenotyp es in M2 Plants are discr ibed in Figure 3. 1st 2nd EMS Concentration 0.3 or 0.5% 1.0% Treated Seeds Number 4000 3000 M2 Families 2500 now harvestin Table 1. Number of EMS treated seeds and harv To integrate various and enormous mutant infor mation from each institut es, Micro-Tom Mutant Data base are under constructi on in silico. This is a c ollaboration work with Na tional Institute of Genet ics in Japan. final objec t of the database is offc orse to supply the experi mental resource and the i nformation for worldwide use. Start of test operat ion is scheduled for duri ng next spring. Figure 5. Micro-Tom Transformation System Figure 7. Key Point for high transformation ratio After establishi ng mutant lin, it is necessary to develop T-DNA tag lines for m utant analysis. Howev er, largest trouble d elaying the study mih gt be absence of high l efficent transforma tion procedure for to mato species. Therefo re, We have establish ed highly efficient t ransformation protoco l for developing T-DN A tag lines in Micro- Tom (Figure 5). We su cceeded to achieve hi ghly efficient transf ormation ratio (appro ximately 40%) by addi tion of acetoshringon e two times during cu ltivation period and operation of careful rooting selection to pick up transformed c ells thoroughly (Figu re 7). Especially, it is effective for high ly efficient transfor mation to repeat sepa rate operation at roo ting selection step b ecause organs undergo ing redifferentiation to form multiple shoo ts included both tran sformed and untransfo rmed cells (Figure 6). Figure 6. Chimer a both transform ed and untransfo rmed cells
description
Figure 4. Micro-Tom Mutant Database. Generation of Micro-Tom Based Mutant Lines for Tomato Genomics by Japanese Solanaceae Genomics Consortium (JSOL). - PowerPoint PPT Presentation
Transcript of Figure 1. JSOL Micro-Tom Mutant Line
か
Hiroshi Ezuraa , Tsuyoshi Mizoguchia, Shin Watanabea, Sayaka Uchiia, Sun Hyon Jina, Yasutaka Kubob, Hitoshi Moric, Shunsuke Imanishid, Daisuke Shibatae
aGene Research Center, University of Tsukuba, 1-1-1 Tennodai, Tsukuba-shi, Ibaraki-ken, 305-8577, Japan,bGuraduate School of National Science, Okayama University, 1-1-1 Tsushima-naka, Okayama-shi, Okayama-ken, 700-8530cGuraduate School of Bioagricultural Sciences, Nagoya University, Furo-cho ChiFull Address,JapandNational Institute of Vegetable and Tea Science, NARO, 360 Kusawa, Ano, Mie-ken, 514-2392, JapaneKazusa DNA Research Institute, Kazusa-Kamatari 2-6-7, Kisarazu-shi, Chiba 292-0818, JapanEmail: [email protected]
Figure 1. JSOL Micro-Tom Mutant Line
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Figure 3. M2 Plants
IntroductionThe spotlight for most plant scientists must be post-genomic studies suc
h as transcriptome, proteome, and metabolome. In addition, advance in bioinfomatics pioneer new category of studies like system biology. Tomato is a model plant that gives information on fruit storage, product translocation and novel metabolites. It is highly expected that other solanaceae plant will have constructive feedback from the genetic and molecular study of tomato. Moreover, the development of L. esculentum var. Micro-Tom gave us a great advantage to examine tomato plantlet in narrow room space. Our main objective is to construct an infrastructure for Micro-Tom study. Mutanegenesis has been highly effective strategy for studying the genetic bases of traits. One of the mutational approach is a chemical mutagenesis by ehylmetane sulphate (EMS) treatment which gives rise to a high mutation frequency without apparent preferences for specific genomic regions. It can also generate many alleles that enable one to get null phenotypes. At present, we are establishing Micro-Tom mutant lines by EMS treatment and a construction of the database in silico with aim to supply the experimental resource and the information for worldwide use. Focusing on both "Floral and circadian rhythm in neuter plant" and " plant hormone and fruit development", we have already set up a system for screening mutants. In addition, we have established an efficient transformation protocol for developing T-DNA tag lines in Micro-Tom. Here we report the latest progress in our work conducted by Japanese Solanaceae consortium (JSOL).
Figure 4. Micro-Tom Mutant Database
Organization: 001 Ç©Ç∏Ç≥ Mutant no. Å@Å@Å@Å@Å@Å@Å@Mutant name:
1. Seed1-1.Germination1-2.Seedling lethality1-3.Slow germination2. Plant size2-1. Extremely small2-2.Small plant2-3. Large plant3. Plant habit3-1. Internode length3-2. Branching3-3. Aborted growth4. Leaf morphology4-1. Leaf width4-2. Leaf size4-3. Leaf texture5. Leaf color5-1. Purple leaf5-2. Yellow leaf5-3. Yellow-green leaf5-4. Dull green/gray leaf5-5. Variegation6. Flowering timing7. Inflorescence structure8. Flower morphology8-1. Flower homeotic mutation8-2. Flower organ size8-3. Flower organ width
9. Flower color9-1. White flower9-2. Pale yellow flower9-3. Strong yellow flower10. Fruit size10-1. Small fruit10- 2. Large fruit11. Fruit morphology11-1. Long fruit11-2. Rounded fruit11-3. Other fruit morphology12. Fruit color12-1. yellow fruit12-2. orange fruit12-3. dark red fruit12-4. Epidermis12-5. Green fruit13. Fruit ripening13-1. Early ripening13-2. Late ripening14. Sterility14-1. Partial sterility14-2. Full sterility15. Disease and stress response15-1. Necrosis15-2. Wilting15-3. other disease response
ÅúÅ@phenotype
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ņÅ@1:leaf production
ņÅ@2:side shoot
ņÅ@3:inflorescence
ņÅ@4:flowering
ņÅ@5:fruit
ņÅ@6 ripening
ÅúÅ@growth stage
Comments(free text format)
IMG
Image upload
x
x
Generation of Micro-Tom Based Mutant Lines for Tomato Genomics by
Japanese Solanaceae Genomics Consortium (JSOL)
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Figure 2. JSOL Micro-Tom Mutant Line Team
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1. Micro-Tom Mutant LineAfter organizing Japanese Solanaceae consortium (JSOL) in 2004, we immed
iately decided to establish Micro-Tom mutant line and to set up a system for screening mutants. We started to cultivate M1 plants at the end of 2004 (Figure 1) and we had harvested 4000 M1 Plants by this spring and obtained 2500 M2 families (Table 1). These M2 Plants have already cultivated and been ready for screening.
2. Micro-Tom Mutant Database
3. Establish Micro-Tom Transformation System for T-DNA Tag Line
3. ConclusionJSOL Micro-Tom Mutant Line project is a collaborate work with 5 Japanese in
stitutes. Now M2 Plant seeds are distributed to each institutes and cultivated (Figure 2).
JSOL Micro-Tom Mutant Line project is a collaborate work with 5 Japanese institutes. Now M2 Plant seeds are distributed to each institutes and cultivated (Figure 2). At the same time, we are establishing TILLING SYSTEM for screening mutants. Some interesting phenotypes in M2 Plants are discribed in Figure 3.
1st 2nd
EMS Concentration 0.3 or 0.5% 1.0%
Treated Seeds Number 4000 3000
M2 Families 2500 now harvesting
Table 1. Number of EMS treated seeds and harvested plants
To integrate various and enormous mutant information from each institutes, Micro-Tom Mutant Database are under construction in silico. This is a collaboration work with National Institute of Genetics in Japan. final object of the database is offcorse to supply the experimental resource and the information for worldwide use. Start of test operation is scheduled for during next spring.
Figure 5. Micro-Tom Transformation System
Figure 7. Key Point for high transformation ratio
After establishing mutant lin, it is necessary to develop T-DNA tag lines for mutant analysis. However, largest trouble delaying the study mihgt be absence of highl efficent transformation procedure for tomato species. Therefore, We have established highly efficient transformation protocol for developing T-DNA tag lines in Micro-Tom (Figure 5). We succeeded to achieve highly efficient transformation ratio (approximately 40%) by addition of acetoshringone two times during cultivation period and operation of careful rooting selection to pick up transformed cells thoroughly (Figure 7). Especially, it is effective for highly efficient transformation to repeat separate operation at rooting selection step because organs undergoing redifferentiation to form multiple shoots included both transformed and untransformed cells (Figure 6).
Figure 6. Chimera both transformed and unt
ransformed cells
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