$\require{mediawiki-texvc}$
  • 검색어에 아래의 연산자를 사용하시면 더 정확한 검색결과를 얻을 수 있습니다.
  • 검색연산자
검색연산자 기능 검색시 예
() 우선순위가 가장 높은 연산자 예1) (나노 (기계 | machine))
공백 두 개의 검색어(식)을 모두 포함하고 있는 문서 검색 예1) (나노 기계)
예2) 나노 장영실
| 두 개의 검색어(식) 중 하나 이상 포함하고 있는 문서 검색 예1) (줄기세포 | 면역)
예2) 줄기세포 | 장영실
! NOT 이후에 있는 검색어가 포함된 문서는 제외 예1) (황금 !백금)
예2) !image
* 검색어의 *란에 0개 이상의 임의의 문자가 포함된 문서 검색 예) semi*
"" 따옴표 내의 구문과 완전히 일치하는 문서만 검색 예) "Transform and Quantization"
쳇봇 이모티콘
안녕하세요!
ScienceON 챗봇입니다.
궁금한 것은 저에게 물어봐주세요.

논문 상세정보

Hormonal Requirements Induced Different Regeneration Pathways in Alhagi graecorum

Journal of plant biotechnology v.6 no.3 , 2004년, pp.171 - 179  
Abstract

Hormonal requirements inducing different regeneration pathways with particular emphasis on somatic embryo-genesis in Alhagi graecorum were studied. While combination of 0.5 $\mu{M}$ 2,4-dichlorophenoxyacetic acid (2,4-D), 2.5 $\mu{M}$ 6-benzylaminopurine (BAP) and 5 $\mu{M}$ 1-naphthaleneacetic acid (NAA) in MS medium induced callus formation and callus maintenance from internodal explants, each alone or in combination with other induced distinct regeneration pathway. Adventitious bud formation was induced on MS medium supplemented with 2.5 $\mu{M}$ BAP. It was improved when 2.5 $\mu{M}$ BAP was used in combination with 5 $\mu{M}$ NAA. MS medium containing 0.5 $\mu{M}$ 2,4-D or 5 $\mu{M}$ NAA induced the formation of abnormal direct somatic embryos. While increase of 2,4-D concentration (1.125-9) resulted in the formation of viable embryogenic mass, increase of NAA did not change its effect. NAA should be used in combination with 2,4-D even at low concentration (0.5 $\mu{M}$) to form embryogenic mass. In A. gaecorum, the role of 2,4-D as trigger of somatic embryogenesis and BAP as trigger of adventitious bud formation was deduced, but for maximum yield certain auxin-cytokinin ratio should be applied. Embryogenic masses characterized by high water content, low peroxidase activity, and low number of peroxidase and glutamate oxaloacetate transaminase bands in comparison with calli obtained under conditions stimulating adventitious bud formation. The resulted differential gene expression, which could be detected by native-PAGE patterns, could be used as marker for organogenic pathway in A. graecorum.

참고문헌 (42)

  1. Ammirato PV (1983) Embryogenesis. In: Evans DA, Sharp WR, Ammirato PV, Yamada Y (ed), Handbook of Plant Cell Culture, Vol 1, pp 82-123. Mac Millan, New York 
  2. Bertozo MR, Valls JFM (2001) Seed storage protein electophoresis in Arachis pintoi and A. repens (Leguminosae) for evaluating genetic diversity. Genetic Resour Crop Evol 48: 121-130 
  3. Brewer GJ (1970) Introduction to isoenzyme techniques. Academic Press, New York, San Frandsco, London 
  4. De Klerk GJ, Arnholdt-Schmitt B, Lieberei R (1997) Regeneration of roots, shoots and embryos: physiological biochemical and molecular aspects. Biol Plant 39: 53-66 
  5. Etienne H, Berger A, Carron MP (1991) Water status of callus from Hevea brasiliensis during induction of somatic embryogenesis. Physiol Plant 82: 213-218 
  6. Hassanein AM, Mazen AMA (2001) Adventitious bud formation in Alhagi graecorum. Plant Cell, Tiss Org Cult 65: 31-35 
  7. Hassanein AM, Galal M, Azooz MM (2003) Interaction between time of nodal explant collection and growth regulators determines the efficiency of Morus alba microprobagation. J Plant Biotech 5: 255-231 
  8. Legrand B, Bouazza A (1991) Changes in peroxidase and lAA-oxidase activities during adventitious buds formation from small root explant of Cichorium intybus L: Influence of glucose. J Plant Physiol 138: 102-106 
  9. Harms CT (1983) Somatic incompatibility in the development of higher plant somatic hybrids. The Quarterly Review of Biology 58: 325-353 
  10. Hassanein AM, Ahmed AM, AbdeI-Hafez AII, Soltan DM (1999a) Phenol-oxidizing isoenzymes, malate dehyderogenase patterns and organogenesis of Solanum nigrum as affected by light treatments. Acta Agrono Hungar 47: 127-136 
  11. Gepts P (1990) Genetic diversity of seed storage proteins in plants. In: Brown HD, Glegg MT, Kahler AL and Weir BS (eds), Plant Population, Genetics, Breeding and Genetic Recourses, pp 64-82. Sunderland, Massachusetts 
  12. Hare PD, du Plessis S, Cress WA, Van Staden J (1996) Stress induced changes in plant gene expression. South African J Sci 92: 431-439 
  13. Kim SH, Kim SK (2002) Effects of auxins and cytokinins on callus induction from leaf blade, Petiole, and stem segments of in vitro-grown 'Sheridan' grape shoots. J Plant Biotech 4: 17-21 
  14. Wakamatsu K, Takahama U (1993) Changes in peroxidase activity and in peroxidase isoenzyme in carrot callus. Physiol Plant 88: 167-171 
  15. Vasil IK (1982) Plant Cell culture and somatic cell genetics of cereals and grasses. Vasil IK, Scowcroft W, Frew KJ (ed.s), Plant Improvement and Somatic Cell Genetics, PP 179-203. Academic Press. New York 
  16. Schween G, Schwenkel H (2003) Effect of genotype on callus induction, shoot organogenesis, and phenotypic stability of regenerated plants in the greenhouse of Primula ssp. Plant Cell Tiss Org Cult 72: 53-61 
  17. Siegel BZ, Galston AW (1967) The isoperoxidase of Pisum sativum. Plant Physiol 42: 221-226 
  18. Kim KH, Park HK, Yeo UD (2001) Effect of auxins and cytokinins on organogenesis of soybean Gtycine max L. J Plant Biotech 3: 95-100 
  19. Rose RJ, Thomas MR, Fitter JT (1990) The transfer of cytoplasmic and molecular genomes by somatic hybridi-zation. Aust J Plant Physiol 17: 303-321 
  20. Carman JG (1990) Embryogenic cells in plant tissue cultures occurrence and behavior. In vitro Cell Dev Biol 26: 746-753 
  21. Cuenca B, San-Jose MC, Martinez MT, Ballester A, Vieitez AM (1999) Somatic embryogenesis from stem and leaf explants of Quercus robur L. Plant Cell Rep 18: 538-543 
  22. Ozawa S, Yasutani I, Fukuda H, Komamine A, Sugiyama M (1998) Organogenic Reponses in tissue culture of mutants of Arabidopsis thaliana. Development 125: 135-142 
  23. Peeters AJM, Gerads W, Barendse GWM (1991) In vitro flower bud formation in tobacco: interaction of hormones. Plant Physiol 97: 402-408 
  24. Visedo G, Fernandez-Piqueras J, Garcia JA (1990) Isoenzyme profiles associated with the hypersensitive response of Chenopodium foetidum to plum pox virus infection. Physiol Plant 78: 218-224 
  25. Blanc G, Michaux-Ferriere N, Teisson C, Lardet L, Carron MP (1999) Effect of carbohydrate addition on the induction of somatic embryogenesis in Hevea brasliensis. Plant Cell Tiss Org Cult 59: 103-112 
  26. Kaeppler HF, Pedersen JF (1996) Media effects on phenotype of callus cultures initiated from photoperiod-insensitive, elite inbred sorghum lines. Maydica 41: 83-89 
  27. Li T, Neumann KH (1985) Embryogenesis and endogenous hormone of cell culture of some carrot varieties (Daucus carota L). Berl Deut Bot Ges 98: 227-235 
  28. Arezki A, Boxus P, Kevers C, Caspar T (2001) Changes in peroxidase activity, and level of phenolic compounds during light-induced plantlet regeneration from Eucalyptus camaladulensis Dehn. Nodes in vitro. Plant growth Regul 33: 215-219 
  29. El-Khatib AA, Fayez KA, Hassanein AM (1999) Adaptive responses of Alhagi graecorum under different habitat conditions. Acta Agronomica Hungarica 47: 171-180 
  30. Endress R (1994) Plant Cell Biotechnology. Springer Verlag, Hiedelberg 
  31. Chawla HS (1991) Plant regeneration potential and isoenzyme variation during morphogenesis of barley callus. Biol Plant 33: 175-180 
  32. Hassanein AM (1998) Isoezyme patterns of Solanum nigrum and the cybrid plant containing Solanum nigrum genome and Solanum tuberosum plastome. Biol Plant 40: 617- 621 
  33. Hassanein AM, Ahmed AM, AbdeI-Hafez AII, Soltan DM (1999b) Isoenzymes expression during root and shoot organogenesis of Solanum nigrum. Biol Plant 42: 341-347 
  34. Mezzetti B, Savini G, Carnevali F, Mott D (1997) Plant genotype and growth regulators interaction affecting in vitro morphogenesis of blackberry and raspberry. Biol Plant 39: 139-150 
  35. Stafford A, Warren G (1993) Plant Cell and Tissue, John Willy & Sons, Chichester, New York 
  36. Murashige T, Skoog F (1962) A revised medium for rapid growth and bioassays with tobacco tissue cultures. Physiol Plant 15: 473-497 
  37. Protopapadakis E, Papanikolaou X (1998) A study on gluta-mate oxaloacetate transaminase isozymes of citron cultivars. Genetic Resour Crop Evol 45: 561-564 
  38. Borkird C, Choi JH, Jin Z, Franz G, Hatzopolous P, Chorneau R, Bonas U, Pelegri F, Sung ZR (1988) Development regulation of embryonic genes in plants. Proc Natl Acad Sci USA 85: 6399-6403 
  39. Lindfors A, Kuusela H, Hohtola A, KupiIa-Ahvenniemi S (1990) Molecular correlates of tissue browning and deterioration in Scots pine calli. Biologia Plantarum 32: 171-180 
  40. Boulos L, El-Hadidi M (1984) The Weed Flora of Egypt. The American Univ., Cairo, Egypt 
  41. Fellers JP, Guenzi AC, Porter DR (1997) Marker proteins associated with somatic embryogenesis of wheat callus cultures. J Plant Physiol 151: 201-208 
  42. Carron MP, Etienne H, Michaux-Ferriere N, Montoro P (1995) Somatic embryogenesis in rubber tree (Hevea brasiliensis Mull. Arg.) In: Bajaj YPS (ed.) Biotechnology in Agriculture and Forestry. Vol 30. Somatic Embryogenesis and Synthetic Seed. pp 353-369. Springer Verlag Berlin 

이 논문을 인용한 문헌 (0)

  1. 이 논문을 인용한 문헌 없음

원문보기

원문 PDF 다운로드

  • ScienceON :

원문 URL 링크

원문 PDF 파일 및 링크정보가 존재하지 않을 경우 KISTI DDS 시스템에서 제공하는 원문복사서비스를 사용할 수 있습니다. (원문복사서비스 안내 바로 가기)

상세조회 0건 원문조회 0건

DOI 인용 스타일