Proline: A Novel Cryoprotectant for the Freeze Preservation of Cultured Cells of <i>Zea mays</i> L

Withers, Lyndsey A.; King, Patrick J.

doi:10.1104/pp.64.5.675

Cited by 152 publications

(69 citation statements)

References 18 publications

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“…Successful recovery of viable tissues usually requires the use of a cryoprotectant like DMSO which itself can be very toxic. The use of naturally occurring compounds like proline (12) or trehalose which may not be toxic would be advantageous.…”

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confidence: 99%

Trehalose as Cryoprotectant for the Freeze Preservation of Carrot and Tobacco Cells

Bhandal¹,

Hauptmann²,

Widholm³

1985

Plant Physiol.

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Suspension cultures of carrot (Daucus carota, line Cl), tobacco (Nicotiana tabacum, line TXI), and Nicotiana plumbaginifolia (line NP) were frozen under controled conditions with trehalose as the sole cryoprotectant. Maximal post-thaw viability (71-74%), measured by phenofni"n dye exclusion, was obtained with the Cl cells following a 24-hour pretreatment with 5 or 10% trehalose and with 40% trehalose as the cryoprotectant during freezing. TXl nisms accumulate during dehydration high concentrations of trehalose, an a-a-linked glucose disaccharide, which is utilized during and after rehydration. In studies with artificial membranes, it appears that trehalose substitutes for water molecules in the membrane during dehydration and thus helps to maintain membrane integrity (5). Because of these observations, and because structural water is an important component of freezeinjury, we tried trehalose as a cryoprotectant. MATERIALS AND METHODSCarrot (Daucus carota L. var sativa, cv Danvers, root-derived, Trehalose (40% in culture medium) and DMSO (both purchased from Sigma Chemical Co.) were filter sterilized and added to the culture medium to final concentrations of 5 or 10%. Pretreatments began on day 4 for the Cl and TX 1 cells and day 2 for NP cells after subculture.The freezing and thawing protocol was as described earlier (7). Cells were collected from 10 ml medium by centrifugation at lOOg for 10 min. The supernatant was removed and the cells were resuspended in 5 ml of the cryoprotectant solution. Twoml aliquots of this suspension were then placed in Cryotubes (Neslab) which were placed in ice for 1 h prior to cooling at 1°C min-' to -40C. The tubes were then placed in liquid N2 for 2 d before thawing in a 40°C water bath.Cell viability was measured by counting cells which had excluded phenosafranin (9) (about 150 cells were observed for each treatment). The remaining cells were plated on 20 ml of the culture medium solidified with 0.8% Bacto agar in 10-cm plastic Petri dishes which were then incubated at 27 to 28C. RESULTS AND DISCUSSIONInitial experiments using trehalose as the sole cryoprotectant during the freezing period without pretreatment did not allow the recovery of any viable cells following thawing with lines C1, TX 1, and NP. However, the pretreatment of Cl cells with 5 or 10% trehalose for 24 h prior to freezing in 20 or 40% trehalose gave more than 50% viability (Table I; Fig. IA). The cells were capable of continued growth when plated on agar-solidified medium (Fig. IA). The use of 5% DMSO plus 10 or 20% trehalose did not increase the post-thaw viability and did prevent further cell growth in the case of 5% DMSO plus 20% trehalose (Table I).

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confidence: 99%

Trehalose as Cryoprotectant for the Freeze Preservation of Carrot and Tobacco Cells

Bhandal¹,

Hauptmann²,

Widholm³

1985

Plant Physiol.

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“…1977). Carpenter and Crowe (1988, cited by Kurt and Hanson, 1997) indicate that this amino acid is essential for stabilizing cell structures, presenting an osmoprotector and cryoprotector activity in fruits tissues, as well as cell protection against oxygen reactives and free radicals (Withers and King, 1979;Alia and Mohanty, 1997). This is important if we consider that damage by "peteca" has been associated to the action of oxygen reactives and a lack of oxygen diffusion in the cells (Nobel, 1999, cited by Storey andTreeby, 2002).…”

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Peteca rind pitting as influenced by proline content in winter lemon albedo

Fichet

Chamorro²,

Riquelme

2012

Cienc. Inv. Agr.

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T. Fichet, J. Chamorro, and A. Riquelme. 2012. Peteca rind pitting as influenced by proline content in winter lemon albedo. Cien. Inv. Agr. 39(1): 201-209. One of the most important problems in lemon growing is the physiological disorder known as "peteca", which is characterized by causing cell dehydration and death in the albedo tissue with a subsequent necrosis of the surface zone of the fruit. This damage shows characteristics quite similar to those resulting from chilling injury in citrus fruit, where surface damage of fruit and dehydration of albedo cells also occur. Resistance to chilling injury shown by grapefruit would be related to increased proline content in the albedo (Purbis, 1981). In this study, proline content of lemons cv. "Fino" 49 from two groves, one in Curacaví (33°25.778 S -71°02.292 W, 196 m above sea level) and the other in Mallarauco (33°94.984 S -70°58.921 W, 269 m above sea level), was analyzed and determined. The Curacaví grove had a low incidence of peteca, whereas the Mallarauco grove exhibited a high incidence of this disorder. Significant differences in albedo proline content were found between both groves and content of this amino acid was highly associated to the degree of peteca incidence. Proline might be playing a role in the lower incidence of "peteca" in winter lemon fruit.

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“…a/ Traitement cryoprotecteur (conditionnement ou prétraitement) -Préculture : Des suspensions cellulaires en phase exponentielle de croissance ou en fin de phase de latence sont cultivées sur un milieu enrichi en mannitol (Withers et King, 1980 ;Maddox et coll., 1983), en proline (Withers et King, 1979) ou en sorbitol (Weber et coll., 198:J ;Maddox et coll., 1983 ;Chen et coll., 1984a), pendant des durées allant de quelques heures à quelques jours. Cette préculture n'est pas toujours né-cessaire (Sala et coll., 1979 ;Dougal!…”

Section: -La Cryoconservation Des Suspensions Cellulaires Et Des Calsunclassified

Problèmes posés par la conservation des souches cellulaires et des organes cultivésin vitro

Dereuddre

1985

Bulletin de la Société Botanique de France. Actualités Botaniqu

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Résumé.-L'instabilité des souches cellulaires et des cultures d'organes pose le problème de leur conservation. Plusieurs stratégies peuvent être développées selon les objectifs à atteindre ( conservation à moyen terme ou à long terme) ou selon le matériel à conserver (suspensions cellulaires et cals, d'une part, méristèmes, embryons somatiques ou polliniques, d'autre part). La conservation à moyen terme par l'utilisation de températures basses non gelantes, d'inhibiteurs de croissance ou de conditions d'hypoxie permet un contrôle continu du matériel. Elle ne peut cependant pas garantir une stabilité de la culture sur de longues périodes. La conservation à long terme dans l'azote liquide ( -196°C) doit permettre de préserver les souches conservées contre une modification progressive de leurs propriétés, mais elle nécessite encore une rnil!e au point minutieuse adaptée à chaque cas.Summary.-Instability of cell and organ cultures raises the question of their preservation. According to the aim to be attained (medium or long term storage) or according to the nature of the material to be preserved (ecU suspensions and callus on the one hand, meristems, soma tic or pollen embryos on the other hand), severa! strategies can be developed. If medium term preservation (low temperatures, growth inhibitors, hypoxia) allows a continuous checking of the culture, it does not warrant the culture stability for a long time. On the contrary, cryopreservation in liquid nitrogen (-196°C) allows strains to be preserved against a progreMive alteration of their properties ; but, it is a more complicated technir., nceding a sper.ific re~t~arch for each case.

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Proline: A Novel Cryoprotectant for the Freeze Preservation of Cultured Cells of Zea mays L

Cited by 152 publications

References 18 publications

Trehalose as Cryoprotectant for the Freeze Preservation of Carrot and Tobacco Cells

Trehalose as Cryoprotectant for the Freeze Preservation of Carrot and Tobacco Cells

Peteca rind pitting as influenced by proline content in winter lemon albedo

Problèmes posés par la conservation des souches cellulaires et des organes cultivésin vitro

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