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The Potential Impact of Ice-Minus Bacteria as a Frost Protectant in New York Tree Fruit Production

Published online by Cambridge University Press:  10 May 2017

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Abstract

Ice-nucleating bacteria, which are known to occur naturally on many crops and have been associated with frost damage, may be subject to control with genetically engineered bacteria, dubbed “ice-minus” bacteria. Ice-minus technology is designed to depress the critical temperature at which frost damage begins by displacing the natural population of ice-nucleating organisms. A trial product has been tested in the field with strawberries. Although tests with bacteriacidal compounds have suggested other mechanisms for controlling the critical temperature in deciduous fruit crops, ice-minus may prove to be effective. This analysis examines the possibility of ice-minus being adopted by New York tree-fruit growers and the likelihood of it causing a major economic impact on the state's fruit industry. Based on the climatology, phenology of fruit trees, and the record of actual frost damage in New York, the need for ice-minus is apparently not great enough to conclude that its adoption would cause a significant impact on New York fruit production.

Type
Research Article
Copyright
Copyright © 1989 Northeastern Agricultural and Resource Economics Association 

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Footnotes

Funds for this research were provided by the Niagara Mohawk Power Corporation under a contract with the Cornell University Departments of Agricultural Economics and Agricultural Engineering for studying the future of the New York agricultural sector and implications for electrical energy use. Any opinions or conclusions drawn are entirely the responsibility of the authors.

References

Ballard, J.K. and Proebsting, E.L., “Frost and Frost Control in Washington Orchards,” Washington State University Extension bulletin 634, 1972.Google Scholar
Blanpied, G.D., Personal communication, Department of Pomology, Cornell University, Ithaca, New York.Google Scholar
Castaldi, M., “The Economic Impacts of Utilizing Alternative Frost Protection Systems in the Hudson Valley of Eastern New York for Fresh Market Apple Production,” Cornell University Cooperative Extension Bulletin XB011. May, 1987.Google Scholar
Castaldi, M. and Forshey, C.G., “Survey of the Cost of Growing and Harvesting Apples in Eastern New York in 1986.” Cornell University Cooperative Extension Bulletin. February, 1987.Google Scholar
DeMarree, A., “Fruit Farm Business Survey, Lake Ontario Region, 1986,” Cornell University, A.E. Ext. 87–29. November 1987.Google Scholar
Forshey, C.G., Personal Communication, Hudson Valley Fruit Research Station. 1987.Google Scholar
Gross, D.C., Proebsting, E.L. Jr., and Andrews, P.K., “The Effects of Ice-Nucleation—Active Bacteria on Temperatures of Ice Nucleation and Freeze Injury of Prunes Flower Buds at Various Stages of Development,” Journal of American Society of Horticultural Science 10 (1984): 375380.Google Scholar
Hoffman, M.B., “Why Some Trees and Varieties Set Fruit and Others did not in 1945,” Proceedings of the New York State Horticultural Society for 1946, pp. 96101.Google Scholar
Lindow, S.E., “Frost Damage to Pear Reduced by Antagonistic Bacteria, Bactericides, and Ice-Nucleation Inhibitors,” Phytopathology 71(1981a): 237.Google Scholar
Lindow, S.E., “Three Methods Explored for Frost Control,” Southern Florist-Nurseryman 94(1981 b): 5657.Google Scholar
Lindow, S.E., “Role of Ice Nucleation Bacteria in Frost Injury to Plants,” Annual Review of Phytopathology 73 (1983): 363384.Google Scholar
Lindow, S.E. and Connell, J.H., “Reduction of Frost Injury to Almond by Control of Ice Nucleation Active Bacteria,” Journal of the American Society for Horticultural Science, 109 (1984): 4853.Google Scholar
Marx, Jean L., “Assessing the Risks of Microbial Release,” Science 237 (1987): 14131417.Google Scholar
New York State Department of Agriculture and Markets. Agricultural Statistics Service. Fruit Crop Report, various issues.Google Scholar
New York State Department of Agriculture and Markets. Agricultural Statistics Service. Orchard and Vineyard Survey (1980).Google Scholar
New York State Department of Agriculture and Markets. Agricultural Statistics Service. Orchard and Vineyard Survey (1985).Google Scholar
Proebsting, E.L. Jr. and Gross, D.C., “Field Evaluations of Frost Injury to Deciduous Fruit Trees as Influenced by Ice Nucleation-active Pseudomonas syringae,” Journal of the American Society for Horticultural Science. 113 (1988): 498506.Google Scholar
Schmidlin, T.W. A Temperature Climatology for New York State. Ph.D. thesis, Cornell University, 1984.Google Scholar
Stiles, W., Personal communication, Department of Pomology, Cornell University, Ithaca, New York.Google Scholar
United States Department of Agriculture. Noncitrus Fruits and Nuts, 1987 Annual Summary. January 1988.Google Scholar
United States Department of Commerce. Bureau of the Census. Agricultural Census. 1949 and 1982.Google Scholar
Yankofsky, S.A., Levin, Z., Moshe, A. Association with Citrus of Ice-Nucleating Bacteria and Their Possible Roles as Causative Agents of Frost Damage. Ceerr. Microbiol 5 (1981): 213217.Google Scholar