Red watercress plant named ‘RW1’

Abstract

The present invention relates to a new and distinct variety of watercress plant, and its plant parts, including the mutation of an allele of watercress designated “BWRW”, which results in watercress plants with red-pigmented leaves and/or stems. The red-green variety is distinguished from green watercress varieties, in particular with its red pigmentation ranging from dark purple to purple-grey to dark red to pink leaves and stems; intermediate-sized stem diameter ranging from 3.5 mm to 5.5 mm, which is commercially acceptable for both fresh and cooked consumption; a higher than average nutritional antioxidant capacity as measured by Ferric Reducing Ability of Plasma (FRAP) assays; as well as expanded harvesting seasons, with suitability to be grown in the United States year-round.

Claims

1. A new and distinct variety of watercress plant having the characteristics as illustrated and described herein.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The accompanying photographs labeled FIGS. 1 through 8 show two typical specimens of the leaves and stems of the new variety demonstrating the pigmentation variation produced by the mutant allele designated BWRW. The photographs were taken of four-week-old harvested plants from different locations in the same bed and photographed indoors under fluorescent lighting in the Fall of 2015. The different specimens demonstrate the variation in pigment distribution as occurs with variations in environmental conditions, such as exposure to day length or photoperiod. FIGS. 9 through 16 demonstrate the typical reproductive characteristics of flowers, siliques, and seeds. Photographs were taken indoors under fluorescent lighting in the Summer of 2016. The 8-10-week-old plants were grown in a field bed in Martinsburg, W. Va.

(2) FIG. 1 shows the first plant specimen, demonstrating dominant dark-purple pigmented leaves and dark reddish-green stems. The more uniform pigmentation occurrence on plant structures is more typical of fall and winter months, or in areas with a shortened photoperiod.

(3) FIG. 2 shows a section of the stem of the first plant specimen, demonstrating dark-purple to deep-reddish-green pigmentation and leaves with significant red pigmentation and green veins.

(4) FIG. 3 shows a closely cropped image of the first plant specimen with red and green coloration of a section of the stem and leaves with significant red pigmentation, and green veins.

(5) FIG. 4 shows a plant leaf from the first plant specimen, demonstrating dominant red pigmentation on the blade with distinctly green veins.

(6) FIG. 5 shows the second plant specimen, demonstrating green colored stems and mostly green leaves with red pigmentation mainly distributed on leaf borders. The broadened green coloration on plant structures is more typical of summer months, or in areas with a lengthened photoperiod.

(7) FIG. 6 shows the second plant specimen with green stem and green leaves with scarce red pigmentation mainly distributed on leaf borders.

(8) FIG. 7 shows a closely cropped image of the second plant specimen with green stem and green leaves with scarce red pigmentation mainly distributed on leaf borders.

(9) FIG. 8 shows an image of a leaf from the second plant specimen, demonstrating significant green coloration on the blade with scarce red pigmentation mainly distributed on leaf borders.

(10) FIG. 9 is a representation of a silique illustrating the characteristics detailed in the specification.

(11) FIG. 10 is a representation of a seed illustrating the characteristics detailed in the specification.

(12) FIG. 11 is a representation of a raceme illustrating the characteristics detailed in the specification.

(13) FIG. 12 is a representation of a flower illustrating the characteristics detailed in the specification.

(14) FIG. 13 is a representation of a flower petal illustrating the characteristics detailed in the specification.

(15) FIG. 14 is a representation of the calyx illustrating the characteristics detailed in the specification.

(16) FIG. 15 is a representation of the gynoecium illustrating the characteristics detailed in the specification.

(17) FIG. 16 is a representation of the androecium illustrating the characteristics detailed in the specification.

DEFINITIONS

(18) In the description and tables that follow, a number of terms are used. In order to provide a clear and consistent understanding of the specification and claim, the following definitions are provided:

(19) Allele. An “allele” is any of one or more alternative form of a gene (dominant or recessive), all of which alleles relates to one trait or characteristic gene.

(20) BWRW. “BWRW” refers to the mutant allele or alleles of the present invention that results in red-pigmented leaves in the watercress plant named ‘RW1’.

(21) Essentially all the physiological and morphological characteristics. A plant having “essentially all the physiological and morphological characteristics” means a plant having the physiological and morphological characteristics, except for the characteristics derived from the converted gene or genes.

(22) Regeneration. “Regeneration” refers to the development of a plant from tissue culture.

(23) Yield. The term “Yield” is typically defined when used. Yield can mean the number of bunches of watercress per acre where, on average, 4 bunches equal approximately a pound. Alternatively, if watercress is harvested loose, yield may be measured in pounds (lbs) or kilograms (Kg) per acre.

DETAILED BOTANICAL DESCRIPTION

(24) The present invention relates to a new and distinct variety of red watercress plant and its plant parts, including the mutation of allele designated “BWRW” in the genus Nasturtium that is phenotypically described in the present invention via a watercress plant having red-pigmented leaves and/or stems.

(25) Watercress is a perennial plant and is generally produced for human consumption. Watercress is typically grown in rectilinear beds with flowing water and the beds are tested frequently for the presence of harmful pathogens. The flowing water may flow through the bed and exit or it may be re-circulated to flow through multiple times. Companies may also add a proprietary blend of fertilizer elements to the irrigation water in the flow-through system. Each bed will have a base to support watercress root growth. The base composition may be natural soil, which is commonly used in the United States, soil overlaid with pebbles, which is commonly used in England, or various plastic compounds overlaid with a more porous material that roots can hook on to.

(26) Watercress is often used to make tea or to make a stock base for cooking. It is also frequently used in place of lettuce on sandwiches. More recently chefs have begun offering watercress in salads and the red-pigmented watercress provides chefs and other food preparers with a striking color option when adding watercress to typically green salads. In addition, members of medical research communities in the U.S. and U.K. have begun detailing the varied anticancer properties of watercress.

(27) The present invention provides a mutant allele designated “BWRW” which results in watercress plants having red-pigmented leaves and/or stems. The red pigmentation of the leaves can range in appearance from dark purple and dark red to pink depending on the environmental conditions and whether one is looking at the upper or lower surface of the leaf.

(28) In addition to conferring the red pigment to the leaves and/or stems, the BWRW allele also affects the distribution of the pigment in the leaves depending on the maturity of the crop and variation in the environmental conditions such as with fluctuations of photoperiod during different times of the year. The red color is distributed mainly in the leaf blade while the veins remain bright green under a short photoperiod (less than 10 h), and for example, when grown in Florida where temperatures fluctuate between 30° and 50° F. during cooler months. In growing conditions under a long photoperiod (longer than 10 h), for example in northern latitudinal areas where temperatures range between 89° and 105° F., the red color is distributed largely at the leaf margins while the veins and the leaf blades are bright green.

(29) Discovery and Propagation of ‘RW1’

(30) The mutant allele of the embodiments of the present invention, BWRW, unexpectedly arose as a spontaneous mutation in a population of triploid green watercress grown in New Market, Ala. during the Summer of 2006. The Alabama farm located at 34°55′0.51″N 86°25′2.63″W, 230 m elevation above the sea level has a production area of 26 acres. In the 1940s, there were many small watercress farms in New Market and in nearby towns, but today the farm where the present invention was discovered, is the only remaining farm. The green watercress varieties, such as Green Watercress U.S. Standard (referenced in Tables 2 and 3) were cultivated in the same location and are still in production today. During 2006, a small area of the farm was designated for the yield evaluation of potential watercress crosses. The red watercress was also cultivated with arugula (30% of the land area) but arugula is no longer cultivated at the New Market farm.

(31) Prior to the present invention, a red-pigmented leaf mutation of this type in watercress was unknown. The single, large, mutant plant was moved from Alabama to Fellsmere, Fla. and placed in a research bed during the Winter-Spring season of 2006-2007. The line was expanded in 8′×40′ beds for five generations through asexual reproduction via stem cuttings under the direction of the inventor.

(32) The line was then uprooted and transferred between Alabama and Florida for further reproduction during growing seasons lasting for periods of 6 months each. The line was expanded via stem cuttings for five generations in the Summer season (2007), for five generations in the Winter-Spring season (2007-2008), for four generations in the Summer season (2008), and for one generation in the Winter-Spring season (2008-2009). In total, twenty generations of the invention were employed by Spring 2009. Additionally, the ‘RW1’ line is maintained through a tissue culture program to maintain healthy plants free of pests and pathogens. Tissue culture is now the preferred method of asexual propagation.

(33) To successfully propagate via stem cuttings, a land area (or bed) is prepared prior to planting. The land is tilled, leveled, and then water added to flow from one side to the other. The cuttings are then placed on beds with the thin water layer. Watercress cuttings are taken from long stems averaging 40 to 75 cm length and are never blooming at this growth stage. Vegetative cuttings produce more plants when the cuttings are placed horizontally onto the beds. Buds located in nodes start growing after the cutting is planted on beds. Rooting from nodes produces successful plant establishment. Some of the roots are submerged in water but others grown under the soil layer and the base of shoot are submerged in water but the major shoot is above water.

(34) Typically the first crop reaches a harvestable stage in about 7 weeks with subsequent harvests occurring at 4 to 5 week intervals depending on environmental conditions. Harvest can occur by hand making a bunch in the field and placing a rubber band around the bunch and trimming the end to the desired length.

(35) Morphological Description

(36) The red-pigmented watercress of the present invention has shown uniformity and stability for red-pigmented leaves and/or stems and other traits substantially as shown and described herein, within the limits of environmental influence for pigmentation. The line has been increased through at least 20 crop cycles since 2006 with continued observation for uniformity. Presently, plants of the invention encompass 10 to 15% of the 26 acre cultivated area. No variant traits have been observed or are expected in the present invention. The color determinations are in accordance with the Fifth Edition (2007) of The Royal Horticultural Society Colour Chart published by The Royal Horticultural Society (London, England), except where general color terms of ordinary dictionary significance are used. The following characteristics were taken of four-week-old plants, with the exception of the flowers, siliques, and seeds, which were collected from eight-to-ten-week old plants. The red-pigmented watercress of the present invention has the following morphologic and other characteristics.

(37) TABLE-US-00001 TABLE 1 VARIETY DESCRIPTION Plant: A perennial succulent temperate herb Stems: Appearance: Floating and semi-erect stems, typically stays under water while 17.78 cm (7.0 in) turns upward when ready for harvest Diameter: 3.5 to 5.5 mm diameter at 17.145 cm (6.75 in) from apical meristem Internode length: 1.27 cm (0.5 in) Surface texture: Cylindrical and succulent with a brilliant cuticle and smooth surface Color: TABLE 1A Table Description: Stem color determined for contrasting red watercress types defined generally as “purple” type and “green- red” type show slight differences in color pattern due to photo- periods of different growing seasons. Plant Stem section Purple (Winter) Green-Red (Summer) Immature Yellow green 144A Yellow green 144B Mature Yellow green 144A Yellow green 144B (6 inches from tip) Leaves: Arrangement: A compound leaf with two opposite pair of oval leaflets and a pentagon shaped terminal leaflet Apex: Moderately apiculate Base: Inequilateral truncate to round Margin: Crenate to sinuate Size of terminal leaflet (the largest leaf from an average derived from 20 plants):  Green-red leaves: Length: 41.0 mm: Width: 37.0 mm  Purple leaves: Length: 35.0 mm: Width: 28.0 mm Size of leaflet (average derived from 20 plants):  Green-red leaves: Length: 19.0 mm: Width: 14.0 mm  Purple leaves: Length: 16.0 mm: Width: 12.0 mm Number of leaflet per leaf (average): Two opposed leaflet pairs or three pairs in rare occurrence Leaflet surface texture:  Upper Surface: Glabrous  Lower Surface: Rugose Color:

(38) TABLE-US-00002 TABLE 1B Leaf color determined for contrasting red watercress types defined generally as “purple” type and “green-red” type show differences in color pattern due to photoperiods of different growing seasons. Leaf Green- Purple Red (Winter) (Summer) (30° to (89° to 50° F., 105° F., or 10 hour or long Plant photoperiod photo- section or less) period) Im- Upper side Main Greyed Main Green mature (blade) purple 186A 143A Veins Green 143A Edges Greyed purple 186B Lower side Main Purple 77A Main Green (opposite) 143A Veins Green 143A Edges Purple 77A Mature Upper side Main Greyed Main Green (6 inches (blade) purple 186A 143A from tip) Veins Green 143A Edges Greyed purple 186B Lower side Main Purple 77A Main Green (opposite) 143A Veins Green 143B Edges Purple 77A Petiole Length (average distance from the stem to the first leaflet pairs): Green-red. Length: 41.0 mm; Width: 37.0 mm Purple: Length: 35 mm; Width: 28 mm Surface texture: Upper surface: Semi cylindrical shape (cross section) and succulent with a brilliant cuticle and smoothly surface Lower surface: None as petiole is semi cylindrical Color: Green-red. RHS 144B (yellow green) Purple: RHS 144A (yellow green) Inflorescence: Plant is typically harvested prior to flowering Appearance: Raceme Raceme Size (average): Up to 200.0 mm Number of flowers per raceme (average): 3 to 7 well opened flowers and15 to 24 unopened flowers Floral cycle: One flower/seed production cycle during summer and winter per floral induction treatment Flower: Size (average): Radial diameter of 4.0 to 6.0 mm Type or form (of flower): Dissymmetric or slightly zygomorphic (cross-like arrange- ment) Number of petals per individual flower: 4 Petal shape: Clawed free petals Petal apex type: Rounded Petal margin: Entire Flower Color: White RHS 155B and purple RHS 77A Calyx: Size (average in mm): 2.0 to 3.5 mm Sepal shape: Saccate sepals, oblong shaped and tip obtuse Color: Yellow-green, RHS 146C Pedicel: Length (average): 5.0 to 7.0 mm Surface texture: Pedicel is semi-circular. The convex side is glabrous and flat side has dense hair Color: Green RHS 146A Peduncle: Length (average): 10.0 to 15.0 mm Surface texture: Smooth between nodes, plain hairs around nodes Color: Green RHS 143A Reproductive Organs: Gynoecium: Size (average): 2.0 to 4.5 mm Number per flower (average): 1 Color: Yellow-green RHS 146A and yellow- green RHS 153B Androecium: Size (average): 2.6 to 4.5 mm Number per flower (average): 6 Color: Yellow-green RHS 144D and yellow- green RHS 152D Fruit (silique):   Shape: Linear cylindrical silique   Size (average, mm): 6.0 to 10. 0 mm   Color: Yellow-green RHS 144A Seed:   Quantity: 42 to 60 seeds per silique but only 6 to 10   develop fully   Shape: Obovate   Texture: Reticulated   Color: Greyed-orange, RHS 175A and RHS165B

COMPARISON TO SIMILAR VARIETIES

Tables

(39) Watercress plants grow as long indeterminate stems which may elongate in a prostrate or upright orientation. Prostrate forms usually root into support media at the axils while simultaneously producing a lateral stem which orients upright for harvest. Upright forms bend upright forming an L shape without long prostrate runs. Unexpectedly, the red watercress plant named ‘RW1’, containing the BWRW mutant allele of the present invention presents an intermediate form, grows more slowly than standard green watercress, and produces 36% fewer marketable stem bunches than standard 3n or 2n green watercress lines. Table 2 shows the yield of the red watercress plant named ‘RW1’, containing the BWRW mutant allele of the present invention as compared to the yield of standard green watercress plants. In Table 2, column 1 shows the type of watercress, column 2 shows the ploidy, column 3 shows the year, columns 4 through 12 show the yield in bunches per acre and column 13 shows the mean yield for each year.

(40) TABLE-US-00003 TABLE 2 Comparison of Red Watercress Plant Named ‘RW1’ Containing the BWRW Mutant Allele with Standard Green Watercress Lacking the BWRW Mutant Allele for Yield over Two Years Four Week Periods Beginning January 1 Watercress Line Ploidy Year 1 2 3 4 Red 3n 2008 18,800 12,770 16,529 7,336 Water- 2009 15,750 13,730 19,226 15,270 cress Plant Named ‘RW1’ Green 3n 2008 21,732 23,823 25,354 22,850 Water- 2009 16,151 25,353 22,588 23,979 cress USA Standard Green 2n 2008 18,257 18,782 20,862 21,674 Watercress 2009 27,433 26,269 18,401 20,982 UK Standard Water- cress Line Year 5 6 11 12 13 Mean Red 2008 16,592 15,771 15,520 11,919 14,405 Water- 2009 8,996 14,594 cress Plant Named ‘RW1’ Green 2008 27,303 22,900 21,495 21,223 18,795 22,841 Water- 2009 25,228 23,196 22,749 cress USA Stan- dard Green 2008 26,828 21,234 15,808 17,800 20,156 Water- 2009 23,271 cress UK

(41) As shown in Table 2, the red watercress plant named ‘RW1’, containing the mutant allele BWRW of the present invention unexpectedly yielded significantly fewer bunches per acre than either the standard U.S. or U.K. green watercresses which lack the BWRW mutant allele. Importantly, while slower growth reduces the total number of bunches and crops per season, slower growth allows the crop to hold longer in the field before going out of market specifications. An additional benefit is that individual stems do not develop as large an undesirable central hole as faster growing lines do.

(42) Watercress stem diameters affect how watercress is used by consumers. Watercress can be consumed fresh as a lettuce substitute or in a mix of fresh greens; it can be boiled, sautéed or stir-fried. Watercress lines marketed for fresh consumption typically possess a smaller stem diameter, for example in the U.K. where watercress is most often consumed fresh, the standard stem diameter is 2.33 mm. Watercress lines marketed for stir fry, boiling, or sautéing possess larger stem diameters of 3.5 to 5.5 mm. Unexpectedly, the red watercress plant named ‘RW1’, containing the BWRW mutant allele of the present invention had a mean stem diameter that was intermediate between the green standard U.S. watercress line and the green standard U.K. watercress line.

(43) Table 3 shows the mean stem number per bunch, the mean weight per stem, and the mean stem diameter for red watercress plant named ‘RW1’, which contains the BWRW mutant allele of the present invention as compared to standard U.S. and U.K. green watercresses which lack the BWRW mutant allele. Also included are two experimental green watercresses, 47-8 and 96-1, which lack the BWRW mutant allele of the present invention. In Table 3 column 1 shows the watercress line, column 2 shows the ploidy of each line, column 3 shows the growing location, column 4 shows the date the watercress was cut and the measurements taken, column 5 shows the mean stem number per bunch, column 6 shows the mean weight in grams per stem, column 7 shows the mean stem diameter in millimeters, and column 8 shows the standard deviation of the stem diameter in millimeters.

(44) TABLE-US-00004 TABLE 3 Comparison of Various Stem Characteristics between Red Watercress Plant Named ‘RW1’, Containing the BWRW Mutant Allele and Standard Green Watercress and Two Experimental Watercress Lines Mean Stem # Watercress Line Ploidy Location Cut Date per Bunch Red Watercress 3n Florida Jan. 12, 2009 34 Plant Named ‘RW1’ Red Watercress 3n Tennessee Jun. 5, 2009 49 Plant Named ‘RW1’ Green Watercress 3n Florida Jan. 12, 2009 42 US Standard Green Watercress 3n Tennessee Jun. 5, 2009 45 US Standard Green Watercress 2n Florida Jan. 14, 2009 91 UK Standard 47-8 6n Florida Jan. 12, 2009 44 47-8 6n Tennessee Jun. 5, 2009 32 96-1 6n Florida Jan. 12, 2009 28 96-1 6n Tennessee Jun. 5, 2009 48 Mean Mean Stem Stem Wt per Diameter Diameter, Std Watercress Line Stem (g) (mm) Dev (mm) Red Watercress 4.68 4.39 1.11 Plant Named ‘RW1’ Red Watercress 4.14 3.58 1.26 Plant Named ‘RW1’ Green Watercress 3.59 3.60 1.09 US Standard Green Watercress 4.63 4.06 1.22 US Standard Green Watercress 1.57 2.33 0.76 UK Standard 47-8 3.48 3.39 1.02 47-8 6.64 5.37 1.27 96-1 5.99 4.46 1.11 96-1 4.86 3.86 1.10

(45) As shown in Table 3, the red watercress stem diameter, 3.58 to 4.39 mm, compares favorably with the U.S. standard 3n line, 3.6 to 4.06 mm, and with two new experimental hexaploid lines.

(46) The red watercress plant named ‘RW1’, containing the BWRW mutant allele of the present invention unexpectedly can be grown in the U.S. in summer because its stem diameter range of 3.5 to 5.5 mm is commercially acceptable for a variety of uses by consumers. The stem diameter of the red watercress containing the BWRW mutant allele of the present invention is such that it is not too small to be used for stir-fry, boiling and sautéing nor is it too big to be used for fresh consumption. As shown in Table 3, the BWRW allele allows watercress to be grown year-round unlike the standard green U.K. watercress.

(47) The assay Ferric Reducing Ability of Plasma (FRAP) is considered an assay of antioxidant power. In tests at the University of South Hampton, U.K., watercress FRAP values of a number of watercress lines were tested and ranged from 1.61 to 5.65 nmol Fe 2+ equivalents per gram fresh weight. In these tests red watercress plant named ‘RW1’, containing the BWRW mutant allele of the present invention had an unexpected FRAP value of 5.65 nmol which is at least 2.27 times greater than the mean of 2.27 nmol Fe 2+ equivalents per gram fresh weight generated for green watercress lines which lack the BWRW mutant allele. This means the red watercress plant named ‘RW1’ has greater antioxidant power than standard green watercress lines.