USPP18415P3 - Zoysiagrass plant named ‘BA-305’ - Google Patents

Abstract

A newly discovered, and asexually reproduced genotype of Zoysiagrass with a distinct set of foliar, inflorescent and agronomic traits.

Description

GENUS AND SPECIES NAME

This invention relates to a new and distinct genotype of Zoysiagrass derived as the progeny from the F₁ variety named ‘Emerald’, which is an interspecific hybrid between Zoysia japonica Stued.×Zoysia tenuifolia (L.) Merr. It is described herein as ‘BA-305’. As used herein ‘BA-305’ has the identical meaning as “Pristine Zoysia”.

BACKGROUND OF THE INVENTION

This invention was discovered and identified in Palm Beach County, Fla. It was a unique and distinctly different vegetative inclusion growing in a planting of the unpatented Zoysiagrass variety known as ‘Emerald’. ‘BA-305’ is postulated to be either a spontaneous mutation that originated from ‘Emerald’, or derived as the progeny from an outcross to an unknown pollen parent.

‘BA-305’ was initially propagated asexually from a single 1.5 inch plug taken from the off type inclusion noted above. Over a five-year period there have been multiple vegetative increases at various research sites throughout Florida, and ‘BA-305’ has remained uniform and genetically consistent. The denomination of this new invention is ‘BA-305’, but in commerce ‘BA-305’ has been tested under the synonym “Pristine Zoysia”, which will be its commercial designation in the United States.

The distinctness of ‘BA-305’ from ‘Emerald’, its putative progenitor, is based on four sets of traits including:

• • 1) floral morphology;
  • 2) leaf and stem morphology;
  • 3) color and pigmentation; and
  • 4) rate of growth and cover.

Measures of disease and insect resistance yielded no significant statistical differences.

For the purpose of registration under the “International Convention for the Protection of New Varieties of Plants” (generally known by its French acronym UPOV Convention) and noting Sections 1612 of the Manual of Patent Examination Procedures the new variety of Zoysiagrass of the present invention is named ‘BA-305’.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1: A comparative photograph of ‘BA-305’ (left) and ‘Emerald’ (right). Both pots were allowed to grow side-by-side, uncut and under identical cultural practices. This photograph illustrates the higher biomass production of ‘BA-305’ compared to ‘Emerald’

FIG. 2: A aerial photograph of ‘Emerald’ (left) and ‘BA-305’ (right) illustrates the volume of leaf area produced by ‘BA-305’.

Both pots were grown side-by-side, uncut and under the same cultural practices.

FIG. 3: A comparative photograph of ‘Emerald’ (left) and ‘BA-305’ (right) grown in trays in Belle Glade, Fla. This photograph illustrates the difference in texture and color between the two genotypes. Both sets of trays were grown side-by-side, uncut, and under identical cultural practices.

FIG. 4: Breeders Block of ‘BA-305’ growing in Avon Park, Fla.

FIG. 5: A close-up photograph of the freshly cut Breeders Block of ‘BA-305’.

FIG. 6: A side profile photograph of ‘BA-305’ after a recent cutting.

DETAILED DESCRIPTION OF THE VARIETY

This new variety of Zoysiagrass is a perennial plant propagated asexually from either rhizomes, stolons, sprigs, or plugs. It is best adapted to the subtropical climates of Florida. ‘BA-305’ was tested and described under field conditions at four research sites in Florida, including Arcadia, Belle Glade, Gainesville, and Milton. Phenotypically, ‘BA-305’ is most similar to ‘Emerald’ but it has a more refined morphology.

The floral morphology of ‘BA-305’ is typical of the interspecific hybrid Zoysia japonica Stued. by Zoysia terruifloia (L.) Merr. as represented by the variety ‘Emerald’. ‘BA-305’ and ‘Emerald’ were compared to eight inflorescences traits (Table 1) and the two genotypes were significantly different from seven of the eight traits. In each case ‘BA-305’ had a smaller and more refined morphology. ‘BA-305’ had a significantly shorter overall shoot length, seed head length, peduncle length and the exposed peduncle length, although shorter, was not statistically significant (Table 1). Seed head width and the average number of seeds per raceme (Seed Count/Seed Head) were also significantly smaller. Additionally, ‘Emerald’ had a higher seed density on the raceme than ‘BA-305’ (0.727 seed/mm vs 0.880 seed/mm), but this trait was not visually discernable. Glume length and glume width were also smaller. Essentially, ‘BA-305’ had smaller and fewer seeds distributed at a lower density on shorter seed heads with smaller peduncles.

The number of seeds heads produced on a monthly basis varied with season. ‘BA-305’ produced statistically fewer seed heads then ‘Emerald’ in June, July, December, January, February, and March. Conversely, ‘BA-305’ produced statistically more seed heads than ‘Emerald’ in the months of August, September, and October (Table 4). No statistical differences existed between the two genotypes for seed head production in the months of April, May, or November. ‘BA-305’ produced fewer seed heads than ‘Emerald’ in the winter and summer, while ‘Emerald’ produced fewer seed heads in the fall. This phase change generally occurred in the mid-fall and mid-spring.

The morphology of the flag leaf is described by flag leaf length, width, and sheath length. ‘BA-305’ differed statistically from ‘Emerald’ for flag leaf length and sheath length. As with the floral morphology these flag leaf traits were finer for ‘BA-305’ then ‘Emerald’ (Table 2). No difference existed in flag leaf width. Stolon and leaf morphology of the vegetative tissue was measured on fully expanded leaves at the fifth node below the stolon meristem. Again, ‘BA-305’ had a more refined texture then ‘Emerald’. Leaf length of ‘BA-305’ was on average 21% shorter and 19% narrower than ‘Emerald’ (Table 3). This difference is visually represented in FIGS. 1, 2, and 3. The internode morphology of ‘BA-305’ was larger than ‘Emerald’ (Table 3). The average internode length of ‘BA-305’ was measured at 20.92 mm vs 11.37 mm for ‘Emerald’. ‘BA-305’ produced internodes about 85% longer than ‘Emerald’, however no meaningful difference existed on internode widths (Table 3).

Leaf color and stolon/rhizome pigment also varied between the two genotypes, and was determined by a comparison of fresh leaf and stolon tissue to color panels in the Munsell Color Chart. The adaxial surface of the leaves of ‘BA-305’ ranged from 7.5GY (4/6 to 5/6) in color. ‘Emerald’ produced leaves of less intense color and ranged from 5GY (4/6) to 7.5 GY (4/6). The stolons of ‘BA-305’ produced a pigment that ranged 5RP (3/2), while ‘Emerald’ produced a lighter pigment which measured 5RP (4/2) on the Munsell Color Chart.

From the initiation of the growth rate experiment, ‘BA-305’ covered the plots faster and had significantly more cover in each month of the year. ‘BA-305’ attained 50% coverage in 5.2 months, while it took ‘Emerald’ 8.0 months; 100% cover was attained in 11.0 months from ‘BA-305’ and over 13 months for ‘Emerald’ (Table 5). This significantly faster rate of coverage gave ‘BA-305’ an important agronomic advantage relative to harvest interval and crop maintenance. The number of stolons and the stolon length were significantly more and longer for ‘BA-305’ compared to ‘Emerald’ (Table 5).

TABLE 1
Comparison of floral traits between
‘Emerald’ and ‘BA-305’.

‘Emerald’

‘BA-305’

Trait (in mm)	Mean	± s.e.	Mean	± s.e.	LSD α = 0.05

Overall Shoot lengthz	35.80	1.17	26.05	0.82	5.565
Seed Head Lengthy	11.76	0.55	9.65	0.40	1.908
Seed Head Widthx	1.53	0.07	1.21	0.06	0.187
Seed Count/Seed Head	16.10	0.87	10.90	0.48	3.10
Exposed Peduncle	12.40	0.91	7.95	0.80	4.95
					(ns)
Peduncle Lengthu	23.35	1.36	15.18	0.51	5.33
Glume Lengtht	2.66	0.06	2.43	0.08	0.19
Glume Widths	0.89	0.02	0.81	0.04	0.06
zOverall shoot length is a measure of the total inflorescence length from the apex of the seed head to the first node on the peduncle subtending the raceme
ySeed Head Length is measured from the apex of the seed head to the top of the peduncle on the base of the raceme.
xSeed Head Width is measured at the broadest part of the seed head.
wSeed Count/Seed Head is the average number of seeds per head or raceme.
vExposure Peduncle Length is the average length of the peduncle not covered by the flag leaf sheath.
uPeduncle Length is the average pinnacle length measured from the base of the seedhead to the top of the node.
tGlume Length is a measure of the average glume length on the seed located at the mid point along the seedhead.
sGlume Width is measured at the widest part of the glume.

TABLE 2
Comparison of flag leaf traits between
‘BA-305’ and ‘Emerald’

‘Emerald’

‘BA-305’

Trait (in mm)	Mean	± s.e.	Mean	± s.e.	LSD α ≦ 0.05

Flag Leaf Lengthz	9.20	0.99	4.65	0.44	1.97
Flag Leaf Widthy	0.79	0.25	0.81	0.03	0.08
					(ns)
Flag Leaf Sheathx	11.45	0.77	8.50	0.65	2.35
zFlag Leaf Length is measured from the apex of the leaf to the top of the leaf sheath.
yFlag Length Width is measeured at the widest part of the flag leaf.
xFlag Leaf Sheath is measured from the top node to the base of the flag leaf.

TABLE 3
Comparison of leaf morphology between
‘BA-305’ and ‘Emerald’.

‘Emerald’

‘BA-305’

Trait (in mm)	Mean	± s.e.	Mean	± s.e.	LSD α ≦ 0.05

Leaf Length	60.80	2.16	68.07	2.66	8.34
Leaf Widthz	1.96	0.08	1.59	0.07	0.25
Internode Length	11.37	0.58	20.92	0.45	2.29
Internode Widthy	1.33	0.06	1.35	0.06	0.18
					(ns)
zLeaf Width is measured at the widest part of the leaf.
yInternode Width is measured at the widest part of the internode.

TABLE 4
Comparison of the average seed head production between
‘BA-305’ and ‘Emerald’ measured on a monthly basis.

Seed Heady	MONTH

	APRIL	MAY	JUNE	JULY
‘BA-305’	0	0	5.00 ± 2.20	7.00 ± 3.76
‘Emerald’	0	0	29.00 ± 4.14	21.75 ± 3.97

	AUGUST	SEPTEMBER	OCTOBER
‘BA-305’	27.50 ± 5.62	57.75 ± 8.74	63.75 ± 10.18
‘Emerald’	10.50 ± 2.90	12.75 ± 9.86	4.750 ± 2.43

	NOVEMBER	DECEMBER	JANUARY
‘BA-305’	49.00 ± 9.03	25.25 ± 8.35	15.50 ± 6.20
‘Emerald’	47.75 ± 11.41	112.50 ± 15.76	120.75 ± 13.98
	FEBRUARY	MARCH	APRIL
‘BA-305’	5.50 ± 4.52	42.25 ± 29.94	60.00 ± 17.25
‘Emerald’	128.0 ± 14.43	103.75 ± 16.9	76.25 ± 12.89
ySeed head count is measured as mean ± standard error on a 8.0 cm2 plot basis.

TABLE 5
Comparison of average cover, stolon/rhizome number,
and stolon/rhizome length between ‘BA-305’ and
‘Emerald’ measured on a monthly basis.

	MONTH

	APRIL	MAY	JUNE	JULY
Coveredz
‘BA-305’	0	1.25 ± 1.25	10.75 ± 2.39	35.00 ± 6.12
‘Emerald’	0 0	11.25 ± 1.25	18.75 ± 3.75
Stolon Numberx
‘BA-305’	0	0	2.25 ± 1.03	7.75 ± 0.63
‘Emerald’	0	0	0.25 ± 0.25	5.25 ± 1.93
Stolon Lengthz
‘BA-305’	0	0	1.75 ± 0.63	3.25 ± 0.75
‘Emerald’	0	0	0.25 ± 0.25	1.75 ± 0.48

	AUGUST	SEPTEMBER	OCTOBER
Coveredz
‘BA-305’	42.50 ± 3.23	48.75 ± 5.54	56.25 ± 5.15
‘Emerald’	28.75 ± 3.15	33.75 ± 3.75	42.50 ± 1.44
Stolon Numberx
‘BA-305’	11.50 ± 0.87	11.50 ± 0.87	11.25 ± 0.63
‘Emerald’	5.25 ± 1.60	5.25 ± 1.60	7.50 ± 0.87
Stolon Lengthz
‘BA-305’	3.50 ± 0.65	4.75 ± 0.85	6.25 ± 0.63
‘Emerald’	2.25 ± 0.48	3.50 ± 1.19	4.00 ± 0.0
	NOVEMBER	DECEMBER	JANUARY
Coveredz
‘BA-305’	60.00 ± 5.77	72.50 ± 3.23	77.50 ± 4.79
‘Emerald’	45.0 ± 0.0	50.0 ± 7.04	52.5 ± 1.44
Stolon Lengthz
‘BA-305’	6.00 ± 0.71	—	—
‘Emerald’	4.00 ± 0.0	—	—
Stolon Numberx
‘BA-305’	11.25 ± 0.83	—	—
‘Emerald’	7.50 ± 0.87	—	—

	FEBRUARY	MARCH	APRIL
Coveredz
‘BA-305’	83.75 ± 5.91	100.00 ± 0	100.00 ± 0
‘Emerald’	57.55 ± 1.44	78.75 ± 2.39	87.5 ± 6.02
Stolon Numberx
‘BA-305’	—	—	—
‘Emerald’	—	—	—
Stolon Lengthz
‘BA-305’	—	—	—
‘Emerald’	—	—	—
xCover is measured as the cumulative percentage of cover over a prescribed plot area.
yStolon Number is a count of stolon/rhizomes radiating from a central plug over a prescribed plot area.
zStolon Length is a number of the average length in cm of the stolons/rhizomes.

Claims (1)

1. A new and distinct genotype of zoysiagrass plant substantially described and illustrated herein.

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