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International Journal of Food Properties Volume 19, 2016 - Issue 11
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Original Articles

Glycine Betaine-Mediated Protection of Peas (Pisum sativum L.) During Blanching and Frozen Storage

Jayaranjan R. KarDepartment of Food Engineering and Technology, Institute of Chemical Technology, Nathalal Parekh Marg, Matunga, IndiaView further author information
,
John E. HallsworthInstitute for Global Food Security, School of Biological Sciences, MBC, Queen’s University Belfast, UKView further author information
&
Rekha S. SinghalDepartment of Food Engineering and Technology, Institute of Chemical Technology, Nathalal Parekh Marg, Matunga, IndiaCorrespondence[email protected]
View further author information
Pages 2510-2521 | Received 02 Jul 2015, Accepted 19 Sep 2015, Published online: 18 Jul 2016

REFERENCES

  • Scheibler, C. Ueber das Betain, Eine im Safte der Zuckerru¨Ben (Beta Vulgaris) Vorkommende Pflanzenbase [About the Betaine, One in Said the Zuckerrübe¨Ben (Beta vulgaris) Occurring plant base]. Berichte der Deutschen Chemischen Gesellschaft [Reports of the German Chemical Society] 1869, 2, 292–295.
  • Giri, J. Glycinebetaine and Abiotic Stress Tolerance in Plants. Plant Signaling & Behavior 2011, 6, 1746–1751.
  • Severin, J.; Wohlfarth, A.; Galinski, E.A. The Predominant Role of Recently Discovered Tetrahydropyrimidines for the Osmoadaptation of Halophilic Eubacteria. Journal of General Microbiology 1992, 138, 1629–1638.
  • Cleland, D.; Krader, P.; McCree, C.; Tang, J.; Emerson, D. Glycine Betaine As a Cryoprotectant for Prokaryotes. Journal of Microbiological Methods 2004, 58, 31–38.
  • Park, E.J.; Jeknic, Z.; Chen, T.H.H. Exogenous Application of Glycinebetaine Increases Chilling Tolerance in Tomato Plants. Plant and Cell Physiology 2006, 47, 706–714.
  • Holtmann, G.; Bremer, E. Thermoprotection of Bacillus Subtilis by Exogenously Provided Glycine Betaine and Structurally Related Compatible Solutes: Involvement of OPU Transporters. Journal of Bacteriology 2004, 186, 1683–1693.
  • Bhaganna, P.; Volkers, R.J.M.; Bell, A.N.W.; Kluge, K.; Timson, D.J.; McGrath, J.W.; Ruijssenaars, H.J.; Hallsworth, J.E. Hydrophobic Substances Induce Water Stress in Microbial Cells. Microbial Biotechnology 2010, 3, 701–716.
  • Cray, J.A.; Russell, J.T.; Timson, D.J.; Singhal, R.S.; Hallsworth, J.E. A Universal Measure of Chaotropicity and Kosmotropicity. Environmental Microbiology 2013, 15, 287–296.
  • Cray, J.A.; Stevenson, A.; Ball, P.; Bankar, S.B.; Eleutherio, E.C.; Ezeji, T.C.; Singhal, R.S.; Thevelein, J.M.; Timson, D.J.; Hallsworth, J.E. Chaotropicity: A Key Factor in Product Tolerance of Biofuel-Producing Microorganisms. Current Opinion in Biotechnology 2015, 33, 228–259.
  • Hallsworth, J.E.; Magan, N. Manipulation of Intracellular Glycerol and Erythritol Enhances Germination of Conidia at Low Water Availability. Microbiology 1995, 141, 1109–1115.
  • Kar, J.R.; Singhal, R.S. Investigations on Ideal Mode of Cell Disruption in Extremely Halophilic Actinopolyspora halophila (MTCC 263) for Efficient Release of Glycine Betaine and Trehalose. Biotechnology Reports 2015, 5, 89–97.
  • Heikkila, H.O.; Melaja, J.A.; Millner, D.E.D.; Virtanen, J.J. Betaine Recovery Process. US Patent 4359430, 1982.
  • Whapham, C.A.; Blunden, G.; Jenkins, T.; Hankins, S.D. Significance of Betaines in the Increased Chlorophyll Content of Plants Treated with Seaweed Extract. Journal of Applied Phycology 1993, 5, 231–234.
  • Kar, J.R.; Hallsworth, J.E.; Singhal, R.S. Fermentative Production of Glycine Betaine and Trehalose from Acid Whey Using Actinopolyspora halophila (MTCC 263). Environmental Technology & Innovation 2015, 3, 68–76.
  • C azzato, E.; Laudadio, V.; Ceci, E.; Tufarelli, V. Effect of Sulphur Fertilization on Fatty Acid Composition of Faba Bean (Vicia faba L.), White Lupin (Lupinus albus L.), and Pea (Pisum sativum L.) Grains. Journal of Food, Agriculture, and Environment 2014, 12, 136–138.
  • Mahajan, R.; Garg, S.; Sharma, P.B. Indian Frozen Peas Market: A Case Study on FPIL. International Journal of Globalisation and Small Business 2011, 4, 154–169.
  • Lin, S.; Brewer, M.S. Effects of Blanching Method on the Quality Characteristics of Frozen Peas. Journal of Food Quality 2005, 28, 350–360.
  • Collins, M.A.; Buick, R.K. Effect of Temperature on the Spoilage of Stored Peas by Rhodotorula glutinis. Food Microbiology 1989, 6, 135–141.
  • Giannakourou, M.C.; Taoukis, P.S. Stability of Dehydrofrozen Green Peas Pretreated with Nonconventional Osmotic Agents. Journal of Food Science 2003, 68, 2002–2010.
  • Green, K.; Foster, C. Transformations in Food Consumption and Production Systems: The Case of the Frozen Pea. In Industrial Ecology and Spaces of Innovation; Green, K.; Randles, S.; Eds.; Edward Elgar Publishing: Northhampton, MA, 2006; pp. 131–152.
  • Sun, D.W. Handbook of Frozen Food Processing and Packaging, Contemporary Food Engineering; Taylor & Francis: Boca Raton, FL, 2012.
  • De Zwart, F.J.; Slow, S.; Payne, R.J.; Lever, M.; George, P.M.; Gerrard, J.A.; Chambers, S.T. Glycine Betaine and Glycine Betaine Analogues in Common Foods. Food Chemistry 2003, 83, 197–204.
  • Schwab, U.; Törrönen, A.; Toppinen, L.; Alfthan, G.; Saarinen, M.; Aro, A.; Uusitupa, M. Betaine Supplementation Decreases Plasma Homocysteine Concentrations But Does Not Affect Body Weight, Body Composition, Or Resting Energy Expenditure in Human Subjects. The American Journal of Clinical Nutrition 2002, 76, 961–967.
  • Barak, A.J.; Beckenhauer, H.C.; Tuma, D.J. Betaine, Ethanol, and the Liver: A Review. Alcohol 1996, 13, 395–398.
  • Kanbak, G.; Arslan, O.C.; Dokumacioglu, A.; Kartkaya, K.; Inal, M.E. Effects of Chronic Ethanol Consumption on Brain Synaptosomes and Protective Role of Betaine. Neurochemical Research 2008, 33, 539–544.
  • Kim, Y.C. Liver Regeneration Accelerator Comprising Betaine. US Patent 20120172436, 2012.
  • Lever, M.; Slow, S. The Clinical Significance of Betaine, An Osmolyte with a Key Role in Methyl Group Metabolism. Clinical Biochemistry 2010, 43, 732–744.
  • Jutila, K. Use of Betaine. US Patent 20110196036, 2011.
  • Messadek, J. Therapeutic Treatment. US Patent 20100210608, 2010.
  • Peters, J.A.C.; van Norren, K.; Gorselink, M.; Hageman, R.J.J. Nutrition Comprising Betaine Against Muscle Wasting. US Patent WO2007043857, 2008.
  • Silva, C.R.; Simoni, J.A.; Collins, C.H.; Volpe, P.L.O. Ascorbic Acid As a Standard for Iodometric Titrations. An Analytical Experiment for General Chemistry. Journal of Chemical Education 1999, 76, 1421.
  • Nleya, K.M.; Minnaar, A.; de Kock, H.L. Relating Physico-Chemical Properties of Frozen Green Peas (Pisum sativum L.) to Sensory Quality: Sensory and Physico-Chemical Properties of Frozen Green Peas. Journal of the Science of Food and Agriculture 2014, 94, 857–865.
  • Bradford, M.M. A Rapid and Sensitive Method for the Quantitation of Microgram Quantities of Protein Utilizing the Principle of Protein-Dye Binding. Analytical Biochemistry 1976, 72, 248–254.
  • Gökmen, V.; Savaş Bahçeci, K.; Serpen, A.; Acar, J. Study of Lipoxygenase and Peroxidase As Blanching Indicator Enzymes in Peas: Change of Enzyme Activity, Ascorbic Acid, and Chlorophylls During Frozen Storage. LWT–Food Science and Technology 2005, 38, 903–908.
  • Sanford, K.A.; Gullett, E.A.; Roth, V.J. Optimization of the Sensory Properties of Frozen Peas by Principal Components Analysis and Multiple Regression. Canadian Institute of Food Science and Technology Journal 1988, 21, 174–181.
  • Gökmen, V.; Savaş Bahçeci, K.; Acar, J. Characterization of Crude Lipoxygenase Extract from Green Pea Using a Modified Spectrophotometric Method. European Food Research and Technology 2002, 215, 42–45.
  • Martinez, C.; Ros, G.; Periago, M.J.; Lopez, G.; Ortuno, J.; Rincon, F. Physico-Chemical and Sensory Quality Criteria of Green Beans (Phaseolus vulgaris, L.). Lebensmittel-Wissenschaft und-Technologie 1995, 28, 515–520.
  • Pont Lezica, R.; Romero, P.A.; Hopp, H.E. Glucosylation of Membrane-Bound Proteins by Lipid-Linked Glucose. Planta 1978, 140, 177–183.
  • Staneloni, R.J.; Tolmasky, M.E.; Petriella, C.; Leloir, L.F. Transfer of Oligosaccharide to Protein from a Lipid Intermediate in Plants. Plant Physiology 1981, 68, 1175–1179.
  • Rummel, J.D.; Beaty, D.W.; Jones, M.A.; Bakermans, C.; Barlow, N.G.; Boston, P.J.; Chevrier, V.F.; Clark, B.C.; de Vera, J.P.P.; Gough, R.V.; Hallsworth, J.E.; Head, J.W.; Hipkin, V.J.; Kieft, T.L.; McEwen, A.S.; Mellon, M.T.; Mikucki, J.A.; Nicholson, W.L.; Omelon, C.R.; Peterson, R.; Roden, E.E.; Sherwood, L.B.; Tanaka, K.L.; Viola, D.; Wray, J.J. A New Analysis of Mars “Special Regions:” Findings of the Second MEPAG Special Regions Science Analysis Group (SR-SAG2). Astrobiology 2014, 14, 887–968.
  • Ball, P.; Hallsworth, J.E. Water Structure and Chaotropicity: Their Uses, Abuses, and Biological Implications. Physical Chemistry Chemical Physics 2015, 17, 8297–8305.
  • Chin, J.P.; Megaw, J.; Magill, C.L.; Nowotarski, K.; Williams, J.P.; Bhaganna, P.; Linton, M.; Patterson, M.F.; Underwood, G.J.C.; Mswaka, A.Y.; Hallsworth, J.E. Solutes Determine the Temperature Windows for Microbial Survival and Growth. Proceedings of the National Academy of Sciences 2010, 107, 7835–7840.
  • Williams, J.P.; Hallsworth, J.E. Limits of Life in Hostile Environments: No Barriers to Biosphere Function? Environmental Microbiology 2009, 11, 3292–3308.
  • Lievens, B.; Hallsworth, J.E.; Pozo, M.I.; Belgacem, Z.B.; Stevenson, A.; Willems, K.A.; Jacquemyn, H. Microbiology of Sugar-Rich Environments: Diversity, Ecology, and System Constraints: Microbiology of Sugar-Rich Environments. Environmental Microbiology 2015, 17, 278–298.
  • Hallsworth, J.E.; Magan, N. Improved Biological Control by Changing Polyols/Trehalose in Conidia of Entomopathogens. Brighton Crop Protection Conference—Pests and Diseases 1994, 3, 1091–1096.
  • Alves, F.L.; Stevenson, A.; Baxter, E.; Gillion, J.L.M.; Hejazi, F.; Morrison, I.E.; Prior, B.A.; McGenity, T.J.; Rangel, D.E.N.; Magan, N.; Timmis, K.N.; Hallsworth, J.E. Concomitant Osmotic and Chaotropicity-Induced Stresses in Aspergillus wentii: Compatible Solutes Determine the Biotic Window. Current Genetics 2015, 61, 457–477.
  • Hohmann, S. Osmotic Stress Signaling and Osmoadaptation in Yeasts. Microbiology and Molecular Biology Reviews 2002, 66, 300–372.
  • Stevenson, A.; Cray, J.A.; Williams, J.P.; Santos, R.; Sahay, R.; Neuenkirchen, N.; McClure, C.D.; Grant, I.R.; Houghton, J.D.; Quinn, J.P.; Timson, D.J.; Patil, S.V.; Singhal, R.S.; Antón, J.; Dijksterhuis, J.; Hocking, A.D.; Lievens, B.; Rangel, D.E.N.; Voytek, M.A.; Gunde-Cimerman, N.; Oren, A.; Timmis, K.N.; McGenity, T.J.; Hallsworth, J.E. Is There a Common Water-Activity Limit for the Three Domains of Life? The International Society for Microbial Ecology Journal 2015, 9, 1333–1351.

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