Plant husbandry – Water culture – apparatus or method
Reexamination Certificate
2001-10-16
2003-07-29
Carone, Michael J. (Department: 3643)
Plant husbandry
Water culture, apparatus or method
C047S082000
Reexamination Certificate
active
06598339
ABSTRACT:
BACKGROUND OF THE INVENTION
Strawberries are an important crop throughout the world. Due to genetic heterozygosity, adaptability, and plasticity of the plant, this species can grow in varied environments throughout the world, from Alaska to South Africa (Martinelli, A. [1992] “Micropropagation of strawberry (Fragaria spp.)”
Biotechnology in Agriculture and Forestry
18:354-370, Springer Verlag, Berlin, W. Germany). The high value of the fruit allows for intensive production methods in many regions.
An estimated 1.8 billion strawberry plants are vegetatively propagated throughout the world each year (Boxus, P. [1989] “Review of in vitro strawberry mass production” Acta Horticulture. Inter. Strawberry Symp., Cesena, Italy 265:309-320). Greater than 700 million of these plants are propagated in the United States. Commercial strawberry cultivars must be propagated vegetatively because seeds are not true to type. Strawberry transplants are produced conventionally by planting a field nursery in early summer, the nursery plants produce daughter plants on stolons in response to long day lengths and high temperatures. In late summer and early fall the daughter plants from the nursery field are dug, soil is removed from the roots, and then the plants may be cold stored for several months before planting, or planted immediately. These plants may become extremely stressed during this process. Additionally, inconsistency in strawberry transplant production and handling, coupled with post transplant conditions can contribute to delayed flowering and subsequent fruiting irregularity, and disease and spider mite epidemics due to pathogen infestation and plant stress. The percentage of marketable fruit may therefore be reduced. Mechanical digging and shaking (to remove soil from roots) often damages roots and breaks petioles, reducing the number of ftmctional leaves for use by the transplant during establishment and creating possible sites for pathogen infection. Bare-root transplants often require large quantities of water at planting, especially in warm climates. This further exacerbates plant pest problems and can leach nutrients.
One of the greatest challenges facing the current strawberry plant propagation system may be the elimination, by the year 2001, of the fumigant methyl bromide (Courter, J. W. [1993] “Accord reached on production cuts from methyl bromide” N. Amer. Strawberry Growers Assoc. Newsletter 18:6). Methyl bromide has been used on the majority of commercial acreage for disease control and effective alternatives have not been developed. Additionally, there have been years when nurseries have had difficulty digging plants because of adverse weather conditions during the digging period. Varying weather conditions during the transplant production season can cause variability in transplant performance from year to year.
Through micropropagation, large quantities of uniform, vigorous, pathogen-free plants can be produced (Boxus, P., C. Damiano, and E. Brasseur [1984] “Strawberry” In: Handbook of Plant Cell Culture, Vol. 3, p. 453-486, Macmillan Publishing Co., New York, N.Y.). Micropropagated plants are more expensive than standard plants, but the increased runner production of micropropagated plants (Swartz, H. H., C. J. Galletta, and R. H. Zimmerman [1981] “Field Performance and Phenotypic Stability of Tissue Culture-propagated Strawberries” J. Am. Soc. Hortic. Sci. 106:667-673) has justified the increased expense for some nursery growers. Micropropagated plants often produce smaller fruit and therefore have not been directly used for fruit production. In some cultivars, bare-root daughter plants of micropropagated mother plants had increased fruit production compared to conventional bare-root plants which were not micropropagated. The daughter plants from micropropagation, however, are produced in field nurseries and therefore can develop the same inconsistencies as conventional plants due to temperature fluctuations and exposure to pathogens.
The above problems of transplant variability could be avoided by the use of micropropagation derived plug transplants which can be mechanically transplanted into the field similar to other vegetable transplants. Plug (tray) transplants have been used successfully in Europe since the late 1980's (Hennion, B., J. Schupp, and J. Longuesserre [1996] Fraisimotte: a strawberry-plug plant developed by CIREF. p. 87 Abstract; 3
rd
Inter. Strawberry Symp., Veldhoven, The Netherlands) and have been the subject of research in North America. In North Carolina, plugs have been reported to have several distinct advantages over bare-root transplants: plugs required only 10% of the water needed for bare-root establishment in spring production systems; a mechanical multiple-row plug transplanter could be used for planting; minimal root damage during transplanting which provided for quick root establishment; and plant survival was greater (Poling, E. S. and K. Parker [1990] “Plug production of strawberry transplants” Adv. in Strawberry Prod. 9:37-39). ‘Chandler’ plug transplants grown in New Jersey had three times the fruit production of dormant crowns, but primary fruit size was lower with the plug transplant (Fiola, J. and R. Lengyen [1995] “Plug transplants are superior to dormant transplants for productivity in strawberry plasticulture” pg. 289-291, In: Proc. of the IV N. Amer. Strawberry Conf., University of Florida Horticultural Sciences Department, Gainesville, Fla.).
BRIEF SUMMARY OF THE INVENTION
The subject invention provides inexpensive materials and methods for growing strawberry plants. In a preferred embodiment the methods use tissue cultured mother plants in elevated troughs
12
to produce strawberry daughter plant tips. The daughter plant tips hang from the troughs
12
and continue to grow down towards the ground. The same mother plants can be used for extended periods and continue to produce large amounts of high quality daughter plant tips. The runners are harvested as long chains of daughter plant tips. When this system is used in a protective structure such as a greenhouse, the plants remain dry. This reduces pathogen dissemination and infection.
In a preferred embodiment, the subject invention further provides a system
14
for rooting the daughter plants
16
. In a specific embodiment, this system
14
uses hanging trays
18
. As the daughter plants grow they are placed in these hanging trays for immediate rooting. The trays
18
can either be watered from above by a mist or from below with a mist or capillary mat. In a specific embodiment, Rock wool or OASIS trays are used because they have preformed holes for placing daughter plants
16
and have high water holding capacity. There is no need for fertilizer for the daughter plant trays
18
because the daughter plants receive nutrients from the mother plant.
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Boxus, P., C. Damiano, E. Brasseur, “Strawberry” In: Handbook of Plant Cell Culture, vol. 3, pp. 453-486, 1984, Macmillan Publishing Co., New York, NY.
B
Bish Eric Bryan
Cantliffe Daniel James
Chandler Craig Kellman
Nguyen Son T.
Saliwanchik Lloyd & Saliwanchik
University of Florida
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