Doubled-haploid production in chickpea (Cicer arietinum L.): role of stress treatments

This is the first report on the production of double-haploid chickpea embryos and regenerated plants through anther culture using Canadian cultivar CDC Xena (kabuli) and Australian cultivar Sonali (desi). Maximum anther induction rates were 69% for Sonali and 63% for CDC Xena. Under optimal conditio...

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Veröffentlicht in:	Plant cell reports 2009-08, Vol.28 (8), p.1289-1299
Hauptverfasser:	Grewal, Ravinder Kaur, Lulsdorf, Monika, Croser, Janine, Ochatt, Sergio, Vandenberg, Albert, Warkentin, Thomas D
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Schlagworte:	Biological and medical sciences Biomedical and Life Sciences Biotechnology Cell Biology Cell Culture Techniques Cells, Cultured Centrifugation Chromosomes Chromosomes, Plant Cicer - embryology Cicer - genetics Cicer arietinum Cold Temperature Cultivars Culture Media Electroporation Embryos Flowers - embryology Flowers - genetics Fundamental and applied biological sciences. Psychology Genetics Haploidy Life Sciences Original Paper Osmotic Pressure Plant Biochemistry Plant Sciences Plants genetics Regeneration Stress, Physiological
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description	This is the first report on the production of double-haploid chickpea embryos and regenerated plants through anther culture using Canadian cultivar CDC Xena (kabuli) and Australian cultivar Sonali (desi). Maximum anther induction rates were 69% for Sonali and 63% for CDC Xena. Under optimal conditions, embryo formation occurred within 15-20 days of culture initiation with 2.3 embryos produced per anther for CDC Xena and 2.0 embryos per anther for Sonali. For anther induction, the following stress treatments were used: (1) flower clusters were treated at 4°C for 4 days, (2) anthers were subjected to electric shock treatment of three exponentially decaying pulses of 50-400 V with 25 μF capacitance and 25 Ω resistance, (3) anthers were centrifuged at 168-1,509g for 2-15 min, and finally (4) anthers were cultured for 4 days in high-osmotic pressure (563 mmol) liquid medium. Anthers were then transferred to a solid embryo development medium and, 15-20 days later, embryo development was observed concomitant with a small amount of callus growth of 0.1-3 mm. Anther-derived embryos were regenerated on plant regeneration medium. Electroporation treatment of anthers enhanced root formation, which is often a major hurdle in legume regeneration protocols. Cytological studies using DAPI staining showed a wide range of ploidy levels from haploid to tetraploid in 10-30-day-old calli. Flow cytometric analysis of calli, embryos and regenerated plants showed haploid profiles and/or spontaneous doubling of the chromosomes during early regeneration stages.
doi_str_mv	10.1007/s00299-009-0731-1
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Electroporation treatment of anthers enhanced root formation, which is often a major hurdle in legume regeneration protocols. Cytological studies using DAPI staining showed a wide range of ploidy levels from haploid to tetraploid in 10-30-day-old calli. 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Maximum anther induction rates were 69% for Sonali and 63% for CDC Xena. Under optimal conditions, embryo formation occurred within 15-20 days of culture initiation with 2.3 embryos produced per anther for CDC Xena and 2.0 embryos per anther for Sonali. For anther induction, the following stress treatments were used: (1) flower clusters were treated at 4°C for 4 days, (2) anthers were subjected to electric shock treatment of three exponentially decaying pulses of 50-400 V with 25 μF capacitance and 25 Ω resistance, (3) anthers were centrifuged at 168-1,509g for 2-15 min, and finally (4) anthers were cultured for 4 days in high-osmotic pressure (563 mmol) liquid medium. Anthers were then transferred to a solid embryo development medium and, 15-20 days later, embryo development was observed concomitant with a small amount of callus growth of 0.1-3 mm. Anther-derived embryos were regenerated on plant regeneration medium. Electroporation treatment of anthers enhanced root formation, which is often a major hurdle in legume regeneration protocols. Cytological studies using DAPI staining showed a wide range of ploidy levels from haploid to tetraploid in 10-30-day-old calli. 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Maximum anther induction rates were 69% for Sonali and 63% for CDC Xena. Under optimal conditions, embryo formation occurred within 15-20 days of culture initiation with 2.3 embryos produced per anther for CDC Xena and 2.0 embryos per anther for Sonali. For anther induction, the following stress treatments were used: (1) flower clusters were treated at 4°C for 4 days, (2) anthers were subjected to electric shock treatment of three exponentially decaying pulses of 50-400 V with 25 μF capacitance and 25 Ω resistance, (3) anthers were centrifuged at 168-1,509g for 2-15 min, and finally (4) anthers were cultured for 4 days in high-osmotic pressure (563 mmol) liquid medium. Anthers were then transferred to a solid embryo development medium and, 15-20 days later, embryo development was observed concomitant with a small amount of callus growth of 0.1-3 mm. Anther-derived embryos were regenerated on plant regeneration medium. Electroporation treatment of anthers enhanced root formation, which is often a major hurdle in legume regeneration protocols. Cytological studies using DAPI staining showed a wide range of ploidy levels from haploid to tetraploid in 10-30-day-old calli. Flow cytometric analysis of calli, embryos and regenerated plants showed haploid profiles and/or spontaneous doubling of the chromosomes during early regeneration stages.</abstract><cop>Berlin/Heidelberg</cop><pub>Berlin/Heidelberg : Springer-Verlag</pub><pmid>19543732</pmid><doi>10.1007/s00299-009-0731-1</doi><tpages>11</tpages></addata></record>
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subjects	Biological and medical sciences Biomedical and Life Sciences Biotechnology Cell Biology Cell Culture Techniques Cells, Cultured Centrifugation Chromosomes Chromosomes, Plant Cicer - embryology Cicer - genetics Cicer arietinum Cold Temperature Cultivars Culture Media Electroporation Embryos Flowers - embryology Flowers - genetics Fundamental and applied biological sciences. Psychology Genetics Haploidy Life Sciences Original Paper Osmotic Pressure Plant Biochemistry Plant Sciences Plants genetics Regeneration Stress, Physiological
title	Doubled-haploid production in chickpea (Cicer arietinum L.): role of stress treatments
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