METHODS FOR PLANT SEED PRODUCTION

Abstract

The invention provides methods for producing seeds in watermelon. In one embodiment methods are provided comprising grafting of a seed parent onto a stress tolerant rootstock, pollinating the seed parent with pollen from a pollen donor, and cultivating the seed parent until seed is formed. In specific embodiments, triploid seeds produced by a method of the invention are rendered conspicuously distinguishable from tetraploid seeds, and thus readily selected manually or by an automated machine. Methods for increasing seed yield and/or quality are also provided.

Description

FIELD OF THE INVENTION

The present invention relates to the field of seed production and, more specifically, to methods of producing seeds of watermelon and other species.

BACKGROUND OF THE INVENTION

Watermelons are natural diploids, referred to as 2N (N=11). Many plants, including watermelons, can undergo a duplication of their entire set of chromosomes and exist as tetraploids 4N (4N=44). Watermelon tetraploids can be produced routinely in the laboratory using cell biology techniques.

A tetraploid parent can be crossed with a diploid parent to produce triploid seeds (3N=33). A hybrid triploid plant produces watermelon fruit which is “seedless,” meaning that it very rarely produces mature seeds, and only rarely produces immature seeds with hard seed coats, but no embryo. To obtain triploid watermelon seed, a cross between a tetraploid and diploid line is made. The tetraploid female flower is used as the ‘seed parent’ and the diploid male flower is used as the pollen donor. Seeds obtained from this cross bear triploid embryos. A tetraploid seed parent typically produces only 5 to 10% as many seeds as a typical diploid plant. If female diploid flowers are pollinated with pollen coming from tetraploid flowers the result is empty seeds.

When production of triploid hybrids is done by open pollination, there is no control on the source of pollen that reaches the stigma of the tetraploid flower, and thus both tetraploid and triploid seeds may be found in the same fruit. In the absence of selection methods, hybrid seeds produced in this manner may therefore be contaminated with seeds resulting from self-pollination.

SUMMARY OF THE INVENTION

In one aspect, the invention provides a method of producing hybrid watermelon seed comprising: (a) obtaining a first watermelon plant, wherein the plant has been grafted onto a rootstock that exhibits resistance to at least one biotic and/or abiotic stress when under stress conditions; (b) allowing the grafted first watermelon plant to be pollinated by a second watermelon plant to produce a hybrid watermelon seed; and (c) allowing hybrid watermelon seed to form. In one embodiment, the first watermelon plant is a tetraploid watermelon plant that produces triploid (3N) hybrid seeds after being pollinated by a second watermelon plant that is diploid. In another embodiment, the first watermelon plant is a diploid watermelon plant that produces a diploid (2N) hybrid seed after being pollinated by a second diploid watermelon plant. In some embodiments, the second diploid watermelon is grafted onto a rootstock that exhibits a selected desirable phenotype.

A rootstock used in accordance with the invention may exhibit any type of stress resistance. In one embodiment, the rootstock exhibits tolerance to an abiotic stress selected from the group consisting of cold tolerance, heat tolerance, drought tolerance, and salt tolerance. In another embodiment, the rootstock exhibits biotic stress tolerance selected from the group consisting of disease resistance, insect resistance, and nematode resistance. Disease resistance includes resistance to bacterial, fungal, and viral diseases. In specific embodiments, the rootstock may be obtained from a plant selected from the group consisting of watermelon, squash, pumpkin, wax gourd, and bottle gourd. In further embodiments, the seed parent may or may not be grown under stress conditions.

Grafting carried out in accordance with the invention may be performed by any method known to one of skill in art. In one embodiment, grafting is performed by a method selected from the group consisting of splice grafting, bud grafting, cleft grafting, side grafting, approach grafting, and hole insertion grafting. Pollination may be carried out in accordance with standard methods, including pollination by insects and hand-pollination.

In another aspect of the invention, methods are provided for producing triploid seed, wherein the triploid seeds are rendered conspicuously distinguishable from the seeds of the tetraploid parent, such as based on size and/or shape, particularly when seed parent is exposed to stress conditions during cultivation. Thereby, the invention allows selecting the seeds of one ploidy category from the seeds of other ploidy categories based on size and/or shape. In one embodiment, the selection may be performed manually. In another embodiment, the selection may be performed mechanically by an automated machine.

The invention further permits producing increased number of fruits, increased number of seeds per fruit, and increased total seed weight per fruit in a grafted seed parent relative to a non-grafted seed parent. In specific embodiments, the seed yield per fruit, including diploid and tetraploid plants, may be defined as, for example, at least about 5, 10, 25, 50, at least about 75, at least about 100, at least about 125, at least about 150, at least about 175, at least about 200, at least about 225 or at least about 250 seeds per fruit, including from about 5 to about 150, from about 34 to about 100, from about 60 to about 120, from about 50 to about 150, from about 100 to about 200, from about 125 to about 250, and from about 150 to about 200, seeds per fruit produced by using a grafted seed parent with a diploid pollen donor plant. In the case of diploid watermelon plants, the seed yield per fruit may be defined in specific embodiments as at least about 150, 200, 250, 300, 350 or at least about 400.

In yet another aspect, the invention provides seeds and plants produced by a process that comprises crossing a first parent plant with a second parent plant, wherein at least one of the first or second parent plants is a plant grafted on a rootstock. In one embodiment of the invention, seed and plants produced by the process are first generation (F₁) hybrid seeds and plants produced by crossing a plant in accordance with the invention with another, distinct plant. Therefore, certain exemplary embodiments of the invention provide an F₁ hybrid seed and plant thereof. In specific embodiments of the invention, a diploid watermelon variety is used as the seed parent and the pollen donor is a second diploid watermelon plant. In other embodiments, the seed and pollen parents are a plant species selected from the group consisting of hot pepper, sweet pepper, tomato, squash, cucumber, pumpkin, gourd, melon, eggplant, and okra.

In still yet another aspect, the invention provides a population of seed parent and pollen donor parent plants in accordance with the invention. In one embodiment, a population of plants is provided planted in pollinating proximity in a field comprising a) tetraploid watermelon seed parent plants, wherein the plants have been grafted onto a rootstock that exhibits stress tolerance when under stress conditions; and b) diploid watermelon pollen donor plants. In specific embodiments, the tetraploid watermelon seed parent plants and diploid watermelon pollen donor plants are planted in alternating rows, and may be planted in a ratio of rows of tetraploid watermelon seed parent plants to diploid watermelon pollen donor plants of, for example, 1:1, 2:1, 3:1, 4:1 or 5:1.

These and other features and advantages of this invention are described in, or are apparent from, the following detailed description of various exemplary embodiments of the devices and methods according to this invention.

DETAILED DESCRIPTION OF THE INVENTION

The invention overcomes limitations in the art by providing improved methods for producing watermelon seeds. In one embodiment of the invention, the inventors surprisingly found that production of triploid seeds can be substantially improved by crossing a diploid pollen donor line with a tetraploid seed parent that has been grafted to a rootstock exhibiting resistance to biotic or abiotic stress when under stress conditions, and that these benefits are observed even in the absence of exposure of the seed parent to stress to which the rootstock confers resistance. For example, use of a disease resistant rootstock was found to confer improved seed production even in the absence of disease pressure. Significantly, the inventors also found that triploid seeds produced by the grafted seed parents exhibited a morphology that was more distinct from tetraploid seeds relative to ungrafted plants. The improved distinctions in seed morphological characteristics is of great importance due to the difficulty that can occur in distinguishing the tetraploid seeds also found in fruits of the seed parent from triploid seeds. By improving the distinctions between triploid and tetraploid seeds, such as in thickness and weight, the invention allows easy separation of the triploid seeds by manual or automated screening. Seed quality and the efficiency of seed production is thereby increased, benefiting seed producers and farmers alike.

In accordance with the invention, grafted seed parents may also be used to improve seed yield and quality. The inventors surprisingly found that increased numbers of seeds per fruit could be obtained in grafted seed parents relative to non-grafted seed parents, and even more surprisingly the effect was found even in the absence of stress to which the rootstock confers resistance. One embodiment of the invention therefore comprises crossing a grafted seed parent, which may be a diploid or tetraploid watermelon plant, with a grafted or ungrafted pollen donor plant. Examples of diploid seed lines that may be used as seed parents or pollen donors in accordance with the invention are well known in the art and include, but are not limited to, Allsweet, Crimson Sweet, Jubilee, Dixie Lee, Sugar Baby, Calsweet, Charleston Grey, and Minilee.

The techniques of the invention are also applicable to other species which are amenable to grafting. Therefore the invention provides, in one embodiment, a method of producing plant seed comprising: crossing a first plant that has been grafted onto a rootstock that exhibits stress tolerance when under stress conditions, allowing the first plant to be pollinated by a second plant of the same species, and allowing seed to form on the first plant, wherein the first plant is grown in the absence of said stress conditions. Examples of species applicable to the method include hot pepper, sweet pepper, tomato, squash, cucumber, pumpkin, gourd, melon, eggplant, and okra. In one embodiment, the rootstock confers resistance to bacterial, fungal and/or viral disease.

In another embodiment, a seed parent used in accordance with the invention is a tetraploid plant that is crossed to a diploid pollen donor to produce triploid hybrid seed. Examples of tetraploid seed parents that may be used are known in the art. Methods for producing tetraploid watermelon plants are also known in the art and are described in, for example, see Kihara, 1951 and Eigsti, 1971. To develop a tetraploid, chemicals that alter mitosis of a diploid inbred line may be used so that unusual numbers of chromosomes are obtained. For example, colchicine is a chemical that alters the mitotic spindle fibers of diploid cells resulting in a number of cells that are tetraploid. The diploid line used to create a tetraploid may be selected based on the traits desired for the tetraploid line. Traits that are desired for a tetraploid line may therefore first be introgressed into the diploid inbred lines that will be used to develop the tetraploid lines by breeding methods well known to one of skill in the art. Thus, the diploid and tetraploid parent lines may be bred separately for the desired traits.

Two generations of self-pollination and selection may be needed to “fix” the 4N condition because, after the colchicine treatment, chromosomal aberrations are often encountered that affect seed fertility, and must be eliminated. Once the stable tetraploid containing the desired characteristics is verified, it then can be used as a stable female parent for the production of the triploid hybrid.

Crossing two different tetraploids followed by recombination breeding can also result in new tetraploid lines. A longer breeding period is required to develop a stable tetraploid line using this approach. This is due to the larger number of genetic combinations and the fewer seed that tetraploids produce.

Seed parents may also be propagated by tissue culture. The use of tissue culture to propagate watermelon plants is exemplified in Zhang et al., 1994a.

Selection and Use Rootstock

In another aspect, the invention provides methods involving selecting and using a rootstock having a desired phenotype comprising tolerance to stress when under stress conditions. In one embodiment it may be desirable to select rootstock exhibiting desirable traits lacking in the seed parent. For instance, if a tetraploid seed parent is susceptible to a soil borne disease, a rootstock that is resistant to the soil borne disease may be selected for grafting.

Examples of abiotic stress that rootstock may confer resistance to include, but are not limited to, cold, high temperature, salt, drought, and flood. Examples of biotic stress include, but are not limited to, plant pathogens, insects, and nematodes. Rootstocks may be from plants of any ploidy level, including diploid and tetraploid plants. Examples of known rootstocks include, but are not limited to, RS-841, Shintoza, Shogun, Charmtoza, FR Couple, and FR Strong.

It is not necessary that the rootstock be from the same species from which the scion is derived. Rootstocks of other plants that are compatible with the scion may also be used. Examples of such compatible rootstocks for use with watermelon and other species include, but are not limited to, bottle gourd (Lagenaria Siceraria var. hispida), wax gourd (Benincasa hispida), pumpkin (Cucurbita pepo), squash (Cucurbita moschata), African horned cucumber (Cucumis metuliferus), Cucurbita maxima, interspecific Cucurbita maxima×Cucurbita moschata and bur-cucumber Sicyos angulatus. (See e.g., Zhang et al., 1994a).

Rootstock may also be a progeny of an interspecific cross. In a particular embodiment, the rootstock is a progeny of interspecific cross between Cucurbita maxima and Cucurbita moschata. An example of such progeny is Shintoza.

Grafting methods for watermelon and other species are known in the art. Examples of grafting methods include, but are not limited to, splice grafting, side grafting, approach grafting, hole insertion grafting, bud grafting, and cleft grafting. (See e.g., Cushman 2006). The grafting may be performed manually or by an automated machine.

Selecting Diploid Pollen Donors and Crossing with Seed Parents

In particular embodiments of the invention, diploid pollen donor plants are selected for use as a male parent in a cross with a grafted tetraploid or diploid plant. A stable diploid inbred may be selected. Adequate viable pollen supply from the diploid pollen donor may be needed for the female flowers to set and develop into regular fruit. In some embodiments, a diploid pollen donor is grafted onto a selected rootstock. In other embodiments, the diploid pollen donor is a non-grafted plant. In one non-limiting embodiment, the diploid pollen donor plant may be a publicly available line such as, for example, Crimson Sweet, Jubilee, Sugar Baby, Dixie Lee, Allsweet, Calsweet, Charleston Grey, and Minilee. Generally pollen donors will be selected that produce progeny with desirable phenotypes when crossed with the corresponding seed parent.

In accordance with the invention, processes are provided for crossing a seed parent with a pollen donor. These processes may, in specific embodiments, be further exemplified as processes for preparing hybrid watermelon seed or plants, wherein a seed parent is crossed with a pollen donor watermelon plant of a different, distinct line to provide a hybrid that has a grafted watermelon plant as one of its parents. In these processes, crossing will result in the production of seed. The seed production occurs regardless of whether the seed is collected.

In one embodiment of the invention, the first step in “crossing” comprises planting of seed parents and pollen donors in proximity so that pollination will occur, for example, mediated by insect vectors. In some embodiments, pollen may be transferred manually. The desired ratio of seed parents and pollen donors for watermelon hybrid seed production is well known to one of skill in the art. In one example, the seed parents and pollen donors are planted at a ratio of 2:1. Examples of other ratios of seed parents and pollen donors include, but are not limited to, 1:1, 3:1, 4:1, and 5:1. In a particular embodiment, seed production fields may be planted at the ratio of 2 rows of female line and 1 row of diploid male line.

A second step may comprise cultivating or growing the seeds of seed parent and pollen donor watermelon plants into plants that bear flowers. A third step may comprise preventing self-pollination of the plants, such as by emasculating the male portions of flowers, (i.e., treating or manipulating the flowers to produce an emasculated parent watermelon plant). Self-incompatibility systems may also be used in some hybrid crops for the same purpose. Self-incompatible plants still shed viable pollen and can pollinate plants of other varieties but are incapable of pollinating themselves or other plants of the same line. In some embodiments, all the male flower portions may be manually removed from the female plants. This process is known as de-budding or emasculation. In other embodiments, a male-sterile seed parent line may be used that may not require the de-budding process.

A fourth step for a hybrid cross may comprise cross-pollination between the seed parent and pollen donor watermelon plants. In one embodiment, the pollen of the diploid pollen donor parent is transferred to a female diploid or tetraploid seed parent flower by manual methods well known to one of in the art. In another embodiment, the pollen is transferred by insect vectors. In a particular embodiment, the crossing of seed parents may involve self-pollination, which may occur manually or without any human intervention.

Yet another step comprises harvesting seeds from the seed parent. All or a portion of the fruit set on the seed parent can be harvested, and seeds are isolated. (U.S. Pat. No. 6,018,101). The harvested seed can be used for any desired purpose, including grown to produce watermelon plants and sold to farmers.

Recovery of Seeds

Seeds may be recovered from matured fruits using methods known to one of skill in the art. In some embodiments, an open pollinated tetraploid seed parent may produce tetraploid seeds in addition to triploid seeds. For example, in order to reduce the cost and labor involved in hand pollination, the transport of the pollen may be left to bees in the field of open pollinated seed parents. Under these conditions, since there is no control on the source of pollen that reaches the stigma of the tetraploid flower, tetraploid and triploid seeds may be found in the same fruit.

In one example, a grafted tetraploid seed parent of the invention produces triploid seeds that are conspicuously distinguishable from tetraploid seeds based on size and/or shape. In specific embodiments, the grafted seed parent yields seeds with improved distinctions in seed thickness and/or seed weight between triploid and tetraploid seeds relative to a non-grafted seed parent. The grafted seed parent, even if raised under a stress condition, yields triploid seeds that are distinguishable from tetraploid seed and can be selected, for example, as being thinner than tetraploid seeds, weighing less than tetraploid seeds, and/or otherwise exhibiting morphological distinctions.

The triploid seeds may therefore be separated from the tetraploid seeds based on differences in morphological characteristics. In one embodiment, the seeds are manually separated. In another embodiment, the seeds are mechanically separated using an automated machine. The automated machine may separate the seeds in accordance with their thickness and/or weight.

In a further embodiment, the invention provides a plant of a grafted and hybridized seed parent that exhibits an average seed number of at least 50 seeds per fruit. In specific embodiments, the seed number may be further defined as, for example, at least about 50, at least about 75, at least about 100, at least about 125 or at least about 150 seeds per fruit, including from about 50 to about 150, from about 34 to about 100, and from about 60 to about 120 seeds per fruit produced by using a grafted seed parent with a diploid pollen donor plant.

In another embodiment, the invention provides a plant of a grafted and hybridized seed parent that exhibits an average seed weight of at least 8 grams (gms) per fruit. In specific embodiments, the seed weight may be further defined as, for example, at least about 0.5 gms, at least about 2 gms, at least about 5 gms, at least about 8 gms, at least about 10 gms, at least about 20 gms or at least about 50 gms per fruit, including from about 5 to about 50, from about 8 to about 40, and from about 8 to about 15 gms per fruit produced by using a grafted seed parent with a diploid pollen donor plant.

Male Sterility

In certain aspects, a seed parent plant may be a male sterile (i.e., comprise a male sterile scion). For example, a grafted tetraploid watermelon scion as described herein maybe male sterile. In certain aspects, a seed parent may be rendered male sterile by physical removal of male plant tissues such as removal of pollen producing flowers. In some aspects, a seed parent may be rendered male sterile by application of a gametocide, for example as described in U.S. Pat. No. 4,936,904. In still further aspects, a seed parent may comprises a male sterility trait such as genetic or cytoplasmic male sterility. For example, tetraploid watermelon plants comprising a recessive gene for male sterility were described by Love et al., 1986. A stable male recessive watermelon line, G17AB, has also been described (Zheng et al., 1994b; Zheng et al., 1996). Watermelon plants comprising a male sterility gene, such as the G17AB line, or progeny of such a plant or line of plants may also be used according to the methods described herein.

EXAMPLES

Example 1

Effect of Grafting of Seed Parent on Seed Numbers and Hybridity

Scions were obtained from the tetraploid watermelon hybrid variety TML 110-1440 and grafted onto the rootstocks Charmtoza, Shintoza, and Shogun. Grafting was carried out by side grafting. The grafted tetraploid was planted in a field together with non-grafted tetraploid plants and the diploid variety 110-6433 to serve as a male parent plant. The plants were grown under conditions in which the plants were not subject to disease pressure or other stress of note.

Insect-mediated pollination was allowed to occur between the diploid and grafted tetraploid plants and seeds were allowed to form. Seeds were then harvested from the tetraploid parent and measurements taken of seed weight, seed number, and hybridity (% hybridity represent the % of triploid seed in the fruit of the tetraploid parent). The results are presented in Table 1

TABLE 1
Increased seed weight per fruit, seed number per fruit
and hybridity resulted from grafting of seed Parents.
	Total	Total	Clean/			Number
	Number	Seed	sized	Total	Grams	of seeds
	of	Weight	Wt.	Number	per	per	Hybridity
	Fruits	(Gms.)	(Gms.)	of seeds	fruit	fruit	(%)
Non Grafted	35	348.53	347.80	5,015	9.96	143	65.40
Grafted (all)	60	689.90	691.20	9,753	11.50	163	81.83
Grafted	15	166.30	166.50	2,488	11.09	166	78.70
Charmtoza
Grafted	32	372.34	373.10	5,359	11.64	167	87.20
Shintoza
Grafted	13	151.26	151.60	1,906	11.64	147	79.60
Shogun

As shown, in Table 1, the grafted plants yielded the total seed weight per fruit of 11.50 gms, but the non-grafted plants yielded the total seed weight per fruit of only 9.96 gms. Also, the grafted plants yielded an average of 163 seeds per fruit, but the non-grafted plants yielded an average of only 143 seeds. The grafted plants yielded the hybridity of 81.83%, but the non-grafted plants yielded the hybridity of only 65.40%.

Example 2

Effect of Grafting of Seed Parent on Fruit Yield, Seed Weight and Hybridity

The tetraploid seed parent TML 110-1440 was grafted on the rootstocks, Shintoza, Shogun, Charmtoza, FR Couple, and FR Strong by side grafting. The grafted tetraploid plants, non-grafted tetraploid and the diploid pollen donor line 110-6433 were planted in a field and cultivated to maturity. Diploid pollen donors were planted along with the grafted tetraploid seed parents, with spacings of 16″×16″, 32″×32″, 48″×48″, and 24″×24″.

The tetraploid seed parents were open-pollinated by insects and seeds were allowed to form. Seeds were harvested and the seed weight, seed number, and hybridity measured. The results are provided in Table 2.

TABLE 2
Increased seed weight per fruit, and hybridity resulted from grafting of seed parents.
				TSW
Female parent,				(Thousand		Extended
TML 110-1440	Spacing		# of	Seed Weight)		Yield
plus Rootstock	(inches)	Gr./plant	fruit/plant	gms	Hybridity	Kg/Ac
TML 110-1440	16	9.2	1.15	70	87.2	60
w/o rootstock	32	15.1	1.69	71	85	49
	48	18.5	1.57	70	89	40
	24	13	1.35	70	83.7	56
	Manually	4.2		85
	self-
	pollinated
	Manually	7.6		72
	cross-
	pollinated.
Shintoza	16	14.5	1.45		83	94
	32	30	2.5	67.95	88	98
	48	43	3.83	67.7	88	93
	24	15.9	2.32		95.7	69
	Manually	N/A
	self-
	pollinated
	Manually	6.4, 8.2
	cross-
	pollinated
Shogun	16	12.8	1.4	74	84	83
	32	20.6	2.3	72	86	67
	48	N/A	N/A
	24	N/A	N/A
	Manually	4.3, 7.8		76 & 80
	self-
	pollinated
	Manually	20.9		72
	cross-
	pollinated
Charmtoza	16	16	1.7	72.05	83	104
	32	28.9	2.4	68	89	94
	48	29.3	3.2	72.1	87	63
	24	19.6	2.25	65.55	83.5	85
	Manually	N/A
	self-
	pollinated
	Manually	8.4, 8.0
	cross-
	pollinated
FR Couple	16	17.6	1.75		70.7	114
(TW 1)	32	23.2	2.53	73.5	85	75
	48	32.6	3.3	73.2	82	71
	24	20.6	2.1	68.7	88.9	89
	Manually	3.5
	self-
	pollinated
	Manually	10.7, 8.8
	cross-
	pollinated
FR Strong	16	15.7	1.6	73.1	83.9	102
(TW 2)	32	25	2.3	74.15	80	81
	48	41.4	3.29	72.6	86	90
	24	21.5	2.38	67.75	83.3	93
	Manually	N/A
	self-
	pollinated
	Manually	12.8, 9.1
	cross-
	pollinated

As shown in Table 2, the seed parents grafted on the rootstocks Shintoza, Shogun, Charmtoza, FR Couple, and FR Strong yielded increased number of fruits, seed yield, total seed weight, and hybridity.

Example 3

The Effect of Grafting on Seed Numbers and Seed Yield

Tetraploid watermelon lines TML110-1440, TML110-0064, TCS110-1009, and TCS110-1018 were crossed as seed parent lines with a diploid pollen donor line. Prior to crossing tetraploid seed parents were grafted onto the interspecific rootstock Cucurbita maxima×Cucurbita moschata (Shintoza) by side grafting. The diploid pollen donor plants were ungrafted.

Grafted and non-grafted tetraploid seed parent plants were transplanted on the same day into a field that was subject to normal (no stress noted) conditions during cultivation. The diploid pollen donor WAS110-6433 was planted with the tetraploid seed parent plants. The plants were grown to maturity with bee-mediated pollination of the tetraploid plants taking place. Fruits were harvested in different days considering the relative maturity to allow full development of seed parts. Seeds were extracted and the number of fruits, total seed weight, average seed weight per fruit, total seed numbers, and average seed number per fruit determined. The results are presented in Table 3.

TABLE 3
Increased seed weight and seed numbers per fruit
resulting from grafting of seed parents
		Total	Avg. seed
		Seed	Wt. Per	Total	Average Seed
Experimental	Number	Weight	fruit	Seed	Number per
Material	of Fruits	(Gms)	(Gms)	Count	fruit
B64 NG	20	172.86	8.64	2,432	121
B64 G	19	182.59	9.61	2,825	148
1440 NG	27	324.17	12	4,078	151
1440 G	20	267.63	13.38	3,677	184
1009 NG	19	176.82	9.3	2,297	121
1009 G	15	121.02	8.07	1,854	124
1018 NG	24	191.32	7.97	2,521	105
1018 G	15	130.67	8.71	1,807	120
NG—Non-grafted;
G—Grafted

As shown in Table 3, grafted seed parents yielded greater weight and seed number per fruit relative to non-grafted seed parents. For example, the grafted B64 seed parent yielded 9.61 gms of seed per fruit, but the non-grafted B64 yielded only 8.64 gms of seed per fruit. Likewise, the grafted 1440 and 1018 plants yielded more seed weight per fruit relative to their non-grafted plants. The seed weight for grafted 1009 plants was lower than non-grafted plants, possibly because the trait controlling seed number per plant was segregating in this line and was unevenly represented between those plants selected for grafting relative to nongrafting. In addition, the grafted B64 seed parent yielded 148 seeds per fruit, while the non-grafted B64 yielded only 121 seeds per fruit, and each of the grafted 1440, 1009, 1018 plants yielded more seeds per fruit relative to their non-grafted plants.

Example 4

Seed Production in Melon and Watermelon Using Grafting

An analysis was also carried out on the effect on seed production (in grams per plant) using grafting with melon and watermelon varieties and varying rootstocks relative to nongrafted checks. The results of the analysis are presented below.

	Grafted Scion		FPO
	145-22182		863991		Number	Seed
Rootstock/	Trial	Hectares	Planned	Hectares	plants that	production	Grams seed	%
Chilsung Shintoza	Identification	planned	plants	planted	worked	in kilograms	per plant	germination
	Melon Grafting
Graft	S6V1	0.34	5440	0.3	4790	92.72	19.3	94-97
Non-graft check	S7V5,6			0.3	4790	77.82	16.25	94-98
Gourd/	145-23190		FPO
			895010
Graft	S5V1	0.46	7360	0.06	1000	3.68	3.68	87-96
Non-graft check	L2V4			0.28	4602	42.07	9.14	95-100
Chilsung Shintoza	145-23269		FPO
			884417
Graft	S6V1	0.59	9440	0.38	6043	7.24	1.2	42-84
Non-graft check	S3V5,6			0.38	6043	73.61	12.18	71-94
Shintoza	145-23206		FPO
			897683
Graft	L6V3	0.33	5280	0.1	1628	22.03	13.53	1628
Non-graft check	S9V4,5			0.1	1628	18.66	11.46	1628
Shintoza	145-23304		FRO
			880342
Graft	S5V1	0.16	2560	0.13	2136	31.1	14.56	73-93
Non-graft check	L5V3,4			0.13	2136	36.5	17.08	96-99
Shintoza	145-23249		FRO
			872648
Graft	S5V1 L6V3	0.33	5280	0.11	1829	18.26	9.98	84-86
Non-graft check	L2V2			0.11	1829	28.85	15.77	84-98
Shintoza	145-22189		FRO	Etapa 14
			909292
Graft	L6V4	0.59	9440	0.25	4053	67.95	16.76	90-93
Non-graft check	LB,CV			0.25	1750	16.7	9.5	82-94
	18;18,19
Shintoza	145-22189		FRO	Etapa 15
			909292
Graft	DV19;S11V4,5	0.2	3200	0.11	1697	20.3	11.96	8445
Non-graft check	CV20,21,22			0.11	1697	20.4	12.02	6340
	Gal
Graft	L6V4	0.19
Shintoza	145-23377		FPO
			897686
Graft	L6V3,4	0.44	7040	0.18	2873	25.68	8.94	8841
Non-gaft check	S 10V4,5			0.18	2873	18.09	6.3	4845
Shirrtoza	145-23269		FPO
			897686
Graft	S2V2,3;DV19	0.14	2240	0.09	1411	15.7	11.12	8844
	Gal
Non-graft check	CV27 Gal			0.09	1411	22.53	15.96	6844
Shintoza	145-311134		FPO
			909289
Graft	DV19 Gal	0.1	1600	0.08	1267	15.25	12	9345
Non-graft check	CV27 Gal			0.08	1267	24.51	19.34	9445
Shintoza	145-297888		FPO
			917028
Graft	S2V2,3;DV18	0.36	5760	0.27	4103	49.29	12	96-95
	Gal
Non-graft check	Galmo DV18			0.27	4103	60.78	14.81	85-93
Rootstock/	145-23269		FPO
			925514
Charmtoza	S11V4,5	0.07	288	0.007	111	0.67	6
Chilsung Shimtoza	S11V4,5		480	0.012	205	0.54	2.63
Shimtoza	S11V4,5		460	0.01	169	0.09	0.53
Non-graft check	S11V4,5				34023	494.32	14.53
Rootstock/	145-23269		FPO
			925514
Hwangtoza	S10V2,3	0.59		0.05	726	5.32	7.32
Shimtoza (0)	S10V2,3			0.02	311	1.77	5.69
Shimtoza (1)	S10V2,3			0.008	138	1.55	11.23
145-22182 (IMPAC)	S10V2,3			0.11	1717	23.2	13.5
Non-graft check	S10V2,3				34023	494.32	14.53
Watermelon Grafting
Chilsung Shintoza/	177-21153		FPO
			880345
Graft	S4V1	0.58	9280	0.33	5284	201.83	38	98-99
Non-graft check	L9V14 Gal			0.33	5284	50.4	9.5	95-98
Chilsung Shintoza/	177-25423		FRO
			892024
Graft	S4,3V1;1	0.24	3840	0.15	2367	41.29	17.4	99-100
Non-graft check	L12V4 Gal			0.15	2367	19.26	8.1	99-100
Shintoza/	177-152185		FRO
			897682
Graft	S3V1	0.08	1280	0.05	863	3.45	3.99	96-99
Non-graft check	L9V8,9 Gal			0.05	863	6.12	7.09	97-99
Shintoza/	177-268382		FRO
			926134
Graft	L8V7 Gal	0.1	1600	0.05	810	8.63	10.65	99-99
Non-graft check	L8V7,8 Gal			0.05	810	4.07	5.02	99-99
Shintoza	177-261691		FRO
			909287
Graft	L8V9 Gal	0.1	1600	0.06	981	8.53	8.69	98-99
Non-graft check	L8V9,10 Gal	0.5	8000	0.06	981	1.16	1.18	99-99
Shintoza	178-295191		FRO
			909287
Graft	L8V5 Gal.	0.01	166	0.01	166	0.29	1.75
Non-graft check	L8V5,6 Gal.			0.01	166	0.29	1.75
Shintoza	178-213828		FRO
			926141
Graft	L8V2,3 Gal.	0.17	2720	0.06	998	0.41	0.41
Non-graft check	L8V4,5 Gal.			0.06	998	0.38	0.38

Example 5

Further Analysis of the Effect of Grafting on Seed Production

Grafted diploid watermelon varieties Starbrite and Susanita were grafted on rootstock varieties Charmtoza, Chilsung Shintoza, FR-Couple, and Hwangtoza. Seed yield per plant was measured in grams and indicated an increase in the seed yield per plant for most grafted combinations in comparison with the ungrafted check.

		FRUIT		YIELD/
VARIETY	ROOTSTOCK	COUNT	YIELD	PLANT
STARBRITE	CHARMTOZA	7	451	64.43
	CHECK	57	2145	37.63
	CHILSUNG SHINTOZA	28	1643	58.68
	FR-COUPLE	56	2118	37.82
	HWANGTOZA	47	2407	51.21
SUSANITA	CHARMTOZA	60	1314	21.90
	CHECK	69	1170	16.96
	CHILSUNG SHINTOZA	67	1584	23.64
	FR-COUPLE	64	1376	21.50
	HWANGTOZA	55	1409	25.62

Although the foregoing invention has been described in some detail by way of illustration and example for purposes of clarity and understanding, it will be obvious that certain changes and modifications may be practiced within the scope of the invention, as limited only by the scope of the appended claims.

All references cited herein are hereby expressly incorporated herein by reference.

REFERENCES

The following references, to the extent that they provide exemplary procedural or other details supplementary to those set forth herein, are specifically incorporated herein by reference:

• U.S. Pat. Nos. 4,936,904; 6,018,101
• Cushman, Univ. of Florida, Extension Publication, HS1075, 1-5, 2006.
• Eigsti, HortScience, 6:1-2, 1971.
• Kihara, Proceedings of American Society for Horticultural Science, 58:217-230, 1951.
• Kurata, HortScience 29(4):235-239, 1994.
• Love et al., Euphytica, 35:633-638, 1986.
• Zhang et al., Cucurbit Genetics Coop., 17:111-115, 1994a.
• Zheng et al., J. Heredity, 85(4):279-285, 1994b.
• Zheng et al., HortScience, 31(1):29-57, 123-126, 1996.

Claims

1. A method of producing triploid watermelon seed comprising: (a) obtaining a tetraploid watermelon plant, wherein the plant has been grafted onto a rootstock that exhibits stress tolerance when under stress conditions;(b) allowing the tetraploid watermelon plant to be pollinated by a diploid watermelon plant; and(c) allowing triploid seed to form on the tetraploid watermelon plant.

2. The method of claim 1, wherein the stress tolerance comprises an abiotic stress tolerance selected from the group consisting of cold tolerance, high temperature tolerance, drought tolerance, and salt tolerance.

3. The method of claim 1, wherein the stress tolerance comprises a biotic stress tolerance selected from the group consisting of a disease resistance, an insect resistance, and a nematode resistance.

4. The method of claim 1, wherein the rootstock is from a plant selected from the group consisting of watermelon, squash, pumpkin, wax gourd, and bottle gourd.

5. The method of claim 1, wherein the diploid watermelon plant is grafted onto a rootstock that exhibits stress tolerance when under stress conditions.

6. The method of claim 1, wherein the diploid watermelon plant has not been grafted.

7. The method of claim 1, further comprising the step of: (d) selecting the triploid seed from a population of seed resulting from step (c) based on the thickness and/or weight of the triploid seed.

8. The method of claim 1, wherein the tetraploid watermelon plant is grown in the absence of said stress conditions.

9. The method of claim 1, wherein the tetraploid watermelon plant is grown in the presence of said stress conditions.

10. The method of claim, wherein the stress tolerance comprises a biotic stress tolerance selected from the group consisting of viral disease resistance, bacterial disease resistance, and fungal disease resistance.

11. The method of claim 7, wherein the step of selecting is performed manually.

12. The method of claim 7, wherein the step of selecting is automated.

13. The method of claim 1, wherein the tetraploid watermelon plant is pollinated by an insect.

14. The method of claim 1, wherein the tetraploid watermelon plant is hand-pollinated.

15. The method of claim 1, wherein the grafting is performed by a method selected from the group consisting of splice grafting, bud grafting, cleft grafting, side grafting, approach grafting, and hole insertion grafting.

16. The method of claim 1, wherein the triploid watermelon seed formed in step (c) exhibits a morphology that is distinguishable from tetraploid seed produced by the seed parent.

17. The method of claim 1, wherein the tetraploid watermelon plant produces a greater number of seed per fruit and/or with a higher degree of hybridity relative to a watermelon plant of the same genotype as said tetraploid watermelon plant that has not been grafted and is grown under the same conditions as the tetraploid watermelon plant.

18. The method of claim 1, wherein the tetraploid watermelon plant is exposed to at least a first biotic and/or abiotic stress prior to triploid seed forming.

19. A method of producing diploid watermelon seed comprising: (a) obtaining a first diploid watermelon plant, wherein the plant has been grafted onto a rootstock that exhibits stress tolerance when under stress conditions;(b) allowing the first diploid watermelon plant to be pollinated by a second diploid watermelon plant; and(c) allowing diploid watermelon seed to form on the first diploid watermelon plant.

20. The method of claim 19, wherein the stress tolerance comprises an abiotic stress tolerance selected from the group consisting of cold tolerance, high temperature tolerance, drought tolerance, and salt tolerance.

21. The method of claim 19, wherein the stress tolerance comprises a biotic stress tolerance selected from the group consisting of a disease resistance, an insect resistance, and a nematode resistance.

22. The method of claim 19, wherein the first diploid watermelon plant and the second diploid watermelon plant are of a different genotype.

23. The method of claim 19, wherein the rootstock is from a plant selected from the group consisting of watermelon, squash, pumpkin, wax gourd, and bottle gourd.

24. The method of claim 19, wherein the first diploid watermelon plant is grown in the absence of said stress conditions.

25. The method of claim 19, wherein the first diploid watermelon plant is grown in the presence of said stress conditions.

26. The method of claim 19, wherein the first diploid watermelon plant produces a greater number of seed per fruit and/or higher degree of hybridity relative to a watermelon plant of the same genotype as said first diploid watermelon plant that has not been grafted and is grown under the same conditions as the first diploid watermelon plant.

27. The method of claim 19, wherein the second diploid watermelon plant is grafted onto a rootstock that exhibits stress tolerance when under stress conditions.

28. The method of claim 19, wherein the second diploid watermelon plant is not grafted.

29. The method of claim 19, wherein the first tetraploid watermelon plant is pollinated by an insect.

30. The method of claim 19, wherein the first tetraploid watermelon is hand-pollinated.

31. The method of claim 19, wherein the grafting is performed by a method selected from the group consisting of splice grafting, bud grafting, cleft grafting, side grafting, approach grafting, and hole insertion grafting.

32. The method of claim 19, wherein the first diploid watermelon plant is exposed to at least a first biotic and/or abiotic stress prior to seed forming.

33. A method of producing plant seed comprising: (a) obtaining a first plant, wherein the plant has been grafted onto a rootstock that exhibits stress tolerance when under stress conditions;(b) allowing the first plant to be pollinated by a second plant of the same species; and(c) allowing seed to form on the first plant, wherein the first plant is grown in the absence of said stress conditions.

34. The method of claim 28, wherein the first and second plants are of a species selected from the group consisting of hot pepper, sweet pepper, tomato, squash, cucumber, pumpkin, gourd, melon, eggplant, and okra.

35. The method of claim 28 wherein the stress conditions comprise bacterial, fungal and/or viral disease.

36. The method of claim 28, wherein the first plant produces a greater number of seed per fruit and/or higher degree of hybridity relative to a plant of the same genotype as said first plant that has not been grafted and is grown under the same conditions as the first plant.

37. A population of plants planted in pollinating proximity in a field comprising: (a) tetraploid watermelon seed parent plants, wherein the plants have been grafted onto a rootstock that exhibits stress tolerance when under stress conditions; and(b) diploid watermelon pollen donor plants.

38. The population of claim 37, wherein the tetraploid watermelon seed parent plants and diploid watermelon pollen donor plants are planted in alternating rows.

39. The population of claim 38, wherein the rows are planted in a ratio of rows comprising tetraploid watermelon seed parent plants to diploid watermelon pollen donor plants of 1:1, 2:1, 3:1, 4:1 or 5:1.