Browse > Article
http://dx.doi.org/10.5010/JPB.2010.37.4.494

The effect of medium change after pretreating microspores, medium addition, and volume of under solid medium in double layer culture on the production of embryos in isolated microspore culture of hot pepper (Capsicum annuum L.)  

Park, Eun-Joon (Department of Life Sciences, Mokwon University)
Lee, Jong-Suk (Department of Life Sciences, Mokwon University)
An, Dong-Joo (Department of Life Sciences, Mokwon University)
Kim, Moon-Za (Department of Life Sciences, Mokwon University)
Publication Information
Journal of Plant Biotechnology / v.37, no.4, 2010 , pp. 494-504 More about this Journal
Abstract
The effect of the addition of the fresh medium, volume of under solid medium in double layer culture as well as the medium change after pretreating microspores on the production of embryos in microspore culture of hot pepper (Capsicum annuum L.) has been studied. When cultured after heat pre-treatment, changing pretreatment media with fresh culture media proved to be more effective for embryo production rather than supplementing additional culture media. Heat-pretreating for 3 days turned out more effective for embryo production than pretreating for 1 or 2 days. In the case of anther pretreatment, the addition of fresh medium after culture was not effective for embryo production. In pretreating microspores, however, supplementing additional fresh culture media greatly improved embryo yield and quality. The best time point of media addition was 4 days after culture commenced, and the most effective number of times of media addition was one time addition. Moreover, the effective volume of added medium in double layer culture for embryo production was 1.5 ml. The addition of media more than 1.5 ml reduced both embryo yield and quality. Double layer medium was more effective for embryo development than liquid medium. When the volume of under solid medium increased ranging from 3 ml to 7 ml, more cotyledonary embryos were produced in either 5 ml or 7 ml compared to 3 ml, even though the total number of embryos were highest in 3 ml. These results can be used as an important data for establishing an efficient microspore culture system for producing high frequency of normal embryos in hot pepper.
Keywords
Haploid; Microspore culture; Capsicum annuum L;
Citations & Related Records
Times Cited By KSCI : 1  (Citation Analysis)
연도 인용수 순위
1 Zhou H, Zheng Y, and Konzak C.F, (1991) Osmotic potential of media affecting green plant percentage in wheat anther culture. Plant Cell Rep 10:63-66
2 Supena EDJ, Muswita W, Suharsono S, Custers JBM (2006a) Evaluation of crucial factors for implementing shedmicrospore culture of Indonesian hot pepper (Capsicum annuum L.) cultivars. Scientia Horticulturae 107:226-232   DOI
3 Supena EDJ, Suharsono S, Jacobsen E, Custers JBM (2006b) Successful development of a shed-microspore culture protocol for doubled haploid production in Indonesian hot pepper (Capsicum annuum L.). Plant Cell Rep 25:1-10   DOI
4 Swanson EB, Coumans MP, Wu SC, Barsby TL, Beversdorf WD (1987) Efficient isolation of microspores and the production of microspore-derived embryos from Brassica napus. Plant Cell Rep 6:94-97
5 Swanson EB, Herrgesell MJ, Arnoldo M, Sippell DW, Wong RSC (1989) Microspore mutagenesis and selection: Canola plants with field tolerance to the imidazolinones. Theor Appl Genet 78:525-530   DOI
6 Swanson EB (1990) Microspore culture in Brassica : In JW Pollard and JM Walker, eds, Methods in molecular biology, Vol. 6, Plant cell and tissue culture. Humana Press, New Jersey: 159-170
7 Testillano P, Georgiev S, Mogensen HL, Coronado MJ, Dumas C, Risueno MC, Matthys-Rochon E (2004) Spontaneous chromosome doubling results from nuclear fusion during in vitro maize induced microspore embryogenesis. Chromosoma 112:342-349   DOI
8 Zhao J, Simmonds D, Newcomb W (1996) Induction of embryogenesis with colchicine instead of heat in microspores of Brassica napus L. cv. Topas. Planta 198:433-439   DOI
9 Zheng MY, Liu W, Weng Y, Polle E (2001) Culture of freshly isolated wheat (Triticum aestivum L.) microspores treated with inducer chemicals. Plant Cell Rep 20:685-690   DOI
10 Zhou H, Konzak (1989) Improvement of anther culture methods for haploid production in wheat. Published in Crop Sci 29:817-821   DOI
11 Li H, Devaux P (2003) High frequency regeneration of barley doubled haploid plants from isolated microspore culture. Plant Sci 164:379-386   DOI
12 Liu W, Zheng MY, Polle EA, Konzak CF (2002) Highly efficient doubled-haploid production in wheat (Triticum aestivum L.) via induced microspore embryogenesis. Crop Sci 42:686-692   DOI
13 Park EJ, Kim JA, Lee JS, J IC, Yoon MC, Chumg SH, Kim M (2005) The influence of pretreatment period, 2-hydroxynicotinic acid, and anther co-pretreatment on embryo induction in isolated microspore culture of Capsicum annuum L. Kor J Plant Biotech 32:37-44   과학기술학회마을
14 Maraschin SF, Gaussand G, Pulido A, Olmedilla A, Lamers GEM, Korthout H, Spaink HP, Wang M (2005) Programmed cell death during the transition from multicellular structures to globular embryos in barley androgenesis. Planta 221: 459-470   DOI
15 Mityko J, Fari M (1997) Problems and results of doubled haploid plant production in pepper (Capsicum annuum L.) via anther- and microspre culture. Acta Hort 447:281-287
16 Obert B, Szabo L, Mityko J, Pretova A, Barnabas B (2005) Morphological events in cultures of mechanically isolated maize microspores. In Vitro Cell Dev Biol Plant 41:775-782   DOI
17 Pedroso MC, Pais MS (1994) Induction of microspore embryogenesis in Camellia japonica cv. Elegans. Plant Cell Tiss Org Cult 37:129-136   DOI
18 Polsoni L, Kott LS, Beversdorf WD (1988) Large-scale microspore culture technique for mutation selection studies in Brassica napus. Can J Bot 66:1681-1685   DOI
19 Regner F (1996) Anther and microspore culture in Capsicum, In: Jain SM, Sopory SK, Veilleux RE (eds) In vitro haploid production in higher plants, Vol. 3. Kluwer Academic Publ, Dordrecht the Netherlands: 77-89
20 Indrianto A, Barinova I, Touraev A, Heberle-Bors E. (2001) Tracking individual wheat microspores in vitro : identification of embryogenic microspores and body axis formation in the embryo. Planta 212:163-174   DOI
21 Jahne A, Lorz H (1995) Cereal microspore culture. Plant Sci 109:1-12   DOI
22 Kim M, Park EJ, Lee Y (2010) Increased embryo production by manipulation of pretreatment materials and media in isolated microspore culture of hot pepper (Capsicum annuum L.). In : Kumar A, Sopory S (eds) Applications of plant biotechnology ; In vitro propagation, plant transformation and secondary metabolite production. International Publishing House Pvt Ltd, NewDelhi: 89-105
23 Kim M (1999) The influence of temperature pretreatment on the production of microspore embryos in anther culture of Capsicum annuum L. Kor J Plant Tissue Cult 26:71-76   과학기술학회마을
24 Kim M, Kim J, Yoon M, Chio D, Lee KM (2004) Origin of multicellular pollen and pollen embryos in cultured anthers of pepper (Capsicum annuum) Plant Cell Tiss Org Cult 77:63-72   DOI
25 Kim M, Jang IC, Kim JA, Park EJ, Yoon M, Lee Y (2008) Embryogenesis and plant regeneration of hot pepper (Capsicum annuum L.) through isolated microspore culture. Plant Cell Rep 27:425-434   DOI
26 Kott LS, Polsoni L, Ellis B, Beversdorf WD (1988) Autotoxicity in isolated microspore cultures of Brassica napus. Can J Bot 66:1665-1670   DOI
27 Kyo M, Harada H (1985) Studies on conditions for cell division and embryogenesis in isolated pollen culture of Nicotiana rustica. Plant Physiol 79:90-94   DOI
28 Lantos C, Juhasz AG, Somogyi G, Otvos K, Vagi P, Mihaly R, Kristof Z, Somogyi N, Pauk J (2009) Improvement of isolated microspore culture of pepper (Capsicum annuum L.) via co-culture with ovary tissues of pepper or wheat. Plant Cell Tiss Org Cult 97:285-293   DOI
29 Dolcet-Sanjuan R, Claveria E, Huerta A (1997) Androgenesis in Capsicum annuum L.-Effects of carbohydrate and carbon dioxide enrichment. J Amer Spc Hort Sci 122: 468-475
30 Dumas de Vaulx R, Chambonnet D, Pochard E (1981) In vitro culture of pepper (Capsicum annuum L.) anthers: high rate plant production from different genotypes by ${+35^{\circ}C}$ treatments. Agronomie 1:859-864   DOI
31 Fukuoka H, Ogawa T, Matsuoka M, Ohkawa Y, Yano H (1998) Direct gene delivery into isolated microspores of rapeseed (Brassica napus L.) and the production of fertile transgenic plants. Plant Cell Rep 17:323-328   DOI
32 Gonzale-Melendi P, Testillano PS, Ahmadian P, Fadon B, Risueno MC (1996) New in situ approaches to study the induction of pollen embryogenesis in Capsicum annuum L. European Journal of Cell Biology 69:373-386
33 Harwood WA, Bean SJ, Chen DF, Mullineaus PM, Snape JW (1995) Transformation studies in Hordeum vulgare using a highly regenerable microspore system. Euphytica 85:113-118   DOI
34 Hansen M, Svinnset K (1993) Microspore culture of swede (Brassica napus ssp. rapifera) and the effects of fresh and conditioned media. Plant Cell Rep 12:496-500
35 Hoekstra, S, Van Zijderveld MH, Heidekamp F, Van der Mark F (1993) Microspore culture of Hordeum vulgare L.: the influence of density and osmolality. Plant Cell Rep. 12:661-665   DOI
36 Hu T, Kasha KJ (1997) Improvement of isolated microspore culture of wheat (Triticum aestivum L.) through ovary co-culture. Plant Cell Rep 16:520-525   DOI
37 Huang B, Brid S, Kemble R, Simmonds D, Keller W, Miki B (1990) Effects of culture density, conditioned medium and feeder cultures on microspore embryogenesis in Brassica napus L. cv. Topas. Plant Cell Rep 8:594-597   DOI
38 Immonen S, Anttila H (2000) Media composition and anther plating for production of androgenetic green plants from cultivated rye (Secale cereale L.). J Plant Physiol 156:204-210   DOI   ScienceOn
39 Dias JS, Correia MC (2002) Effect of medium renovation and incubation temperature regimes on tronchuda cabbage microspore culture embryogenesis. Sci Hortic 93:205-214   DOI