Seed Breaking Dormancy Technique and Growth of Screw Tree (Helicteres isora Linn.) Seedlings

Screw tree is a shrub from family Malvaceae that has many benefits in pharmacy. Screw tree seed has very hard seed coat, so the seed must be treated before germination. The aim of this research was to assess the characteristic of fruit and seeds, effect of seed breaking dormancy, and effect of NPK fertilizer dosage on the growth of screw tree (Helicteres isora) seedlings. The results indicated that screw tree fruits belong to dry fruits with capsule form and has 5 follicles that has different direction. Screw tree seed is orthodox type that has 9 ̶ 36 seeds in one follicle with triangle and square shape. Germination technique in laboratory with soaking the seeds in hot water 100oC until the water cool for 48 hours treatment produced the best germination amounting to 65.0%. Germination technique in green house with soaking the seeds in hot water 100oC until the water cool for 24 hours treatment was the best germination amounting to 77.0%. Seedlings fertilized with 1 g NPK doses increased screw tree growth in diameter parameter of 6.35 mm and shoot-root ratio parameter of 3.9 compared to control.

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Pematahan Dormansi Benih Kebiul (Caesalphinia bonduc L.) dengan Berbagai Metode

Akta Agrosia ◽

10.31186/aa.19.2.147-156 ◽

2016 ◽

Vol 19 (2) ◽

pp. 147-156

Author(s):

Yesi Uyatmi ◽

Entang Inoriah ◽

Marwanto Marwanto

Keyword(s):

Plant Height ◽

Root Length ◽

Germination Rate ◽

Hot Water ◽

Germination Capacity ◽

Hard Seed ◽

Randomized Design ◽

Breaking Dormancy ◽

Different Temperatures ◽

Hard Seed Coat

Seed of Caesalpinia bonduc L. is difficult to germinate due to the thick and hard seed coat. The research aims to evaluate various methods for breaking dormancy of C. bonduc seed. This study was conducted from December to January 2016 The way to break the dormancy were arranged in Completely Randomized Design. Eleven methods to solve the seed dormancy of C. bonduc were compared. The ways to break the dormancy were soaking in water with different temperatures. The temperatures were 30C for 0 hours, 5 hours, 10 hours, and 15 hours. Other techniques to break the dormancy were soaking in hot water at 10000C for 5 hours, 10 hours, and 15 hours. Warm stratification with 100% air humidity (RH) at 40C for five days, ten days and 15 days also included as treatments. The last method was seed piercing with a needle. The variables observed in this study were germination capacity, germination rate, epicotyl length, plant height, and root length. The results of this study showed that the 11 methods of breaking seed dorman cy significantly affected germination capacity, germination rate, emerging epicotyl, and plant height. Seed piercing classified as the most efficient method as indicated by the value of 100% in germination capacity, 1.43 in germination rate, 13.64 cm in plant height, and 6.16 cm in root length.0

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A comparative study of seed dormancy and germination in an annual and a perennial species of Senna (Fabaceae)

Seed Science Research ◽

10.1017/s0960258500004475 ◽

1998 ◽

Vol 8 (4) ◽

pp. 501-512 ◽

Cited By ~ 43

Author(s):

Jerry M. Baskin ◽

Xiaoying Nan ◽

Carol C. Baskin

Keyword(s):

Seed Dormancy ◽

Seed Coat ◽

Seasonal Temperature ◽

Hard Seed ◽

Breaking Dormancy ◽

Wide Range ◽

Natural Temperature ◽

Colour Morphs ◽

Hard Seed Coat ◽

Seed Dormancy And Germination

AbstractSeed dormancy and germination ofSenna marilandicaandS. obtusifoliawere compared in greenhouse and laboratory studies. About 90% of theS. obtusifoliaseeds were green and had hard seed coat dormancy, whereas the other 10% were brown and nondormant. Seed-colour morphs did not occur inS. marilandica, and nearly 100% of the seeds had hard seed coat dormancy. Seeds ofS. obtusifoliawere significantly heavier than those ofS. marilandica. Mechanical scarification was very effective in overcoming dormancy in seeds of both species. However, concentrated sulfuric acid, absolute ethanol and boiling water were less effective in breaking dormancy in seeds ofS. marilandicathan in those ofS. obtusifolia. Further, incubating seeds at 30/15 to 40/25°C and dry-heat treatments at 80–100°C were ineffective in breaking dormancy inS. marilandica, but significantly increased germination percentages inS. obtusifolia. In neither species were simulated daily/seasonal temperature shifts effective in breaking dormancy. Scarified seeds of both species germinated over a wide range of temperatures in both light and darkness. Under near-natural temperature conditions, seeds ofS. marilandicagerminated in spring only, whereas those ofS. obtusifoliaemerged in late spring and throughout summer. Both species can form a long-lived seed bank. Dormancy break by high field temperatures in seeds ofS. obtusifoliaallows this species to germinate throughout the warm growing season and thus contributes to its success as a weed in arable crops.

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Seed anatomical studies on dormancy and germination in Chamaecrista absus

Journal of Applied and Natural Science ◽

10.31018/jans.v8i2.888 ◽

2016 ◽

Vol 8 (2) ◽

pp. 868-873

Author(s):

H. M. Pallavi ◽

K. Vishwanath ◽

Bapurayagouda Patil ◽

N. Naveen ◽

Manjunath Thattimani

Keyword(s):

Seed Coat ◽

Hot Water ◽

Boiling Water ◽

Physical Dormancy ◽

Anatomical Studies ◽

Hard Seed ◽

Artificial Seed ◽

Germination Behaviour ◽

Hilar Region ◽

Hard Seed Coat

Present study was conducted to analyze the anatomical structure of seed to study the dormancy behaviour in Chamaecrista absus. Seed germination behaviour was also studied after breaking the seed dormancy by artificial seed treatments. The anotamical studies revealed that seed has apical hilar region and seed coat has four layers consisting of outer cuticle, sub cuticle, palisade layer and inner tegma leading to physical dormancy. Outer cuticle and sub cuticle layers are very hard to break naturally and hence seeds possess hard seed coat dormancy. This physically hard seed coat should be made soft to enhance germination. Studies to break dormancy were conducted involving treatments like hot water, hormones and in combinations of both. The results revealed that seeds dipped in boiling water made inner layers permeable for water absorption in hilar region and thus germination enhanced. In specific seeds treated with boiling water for 5 minutes recorded higher germination (82 %) over untreated control (26 %). . Other artificial treatments with hormones gibberellic acid (33 % ) and ethrel (34 % ) did not enhanced the germination significantly over control. C. absus has hard coat dormancy and can be overcame by treating seeds with boiling water treatment.

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Effect of pre-sowing treatments and growing media on seed germination and seedling growth of Albizia lebbeck (L.) Benth

Journal of Applied and Natural Science ◽

10.31018/jans.v10i3.1750 ◽

2018 ◽

Vol 10 (3) ◽

pp. 860-863

Author(s):

Naresh Kumar ◽

A. K. Handa ◽

Inder Dev ◽

Asha Ram ◽

A. R. Uthappa ◽

...

Keyword(s):

Seedling Growth ◽

Room Temperature ◽

Cold Water ◽

Hot Water ◽

Albizia Lebbeck ◽

Physical Dormancy ◽

Growing Media ◽

Hard Seed ◽

Collar Diameter ◽

Hard Seed Coat

The seeds of Albizia lebbeck have been observed to exhibit physical dormancy due to presence of hard seed-coat. To overcome this problem, the seeds were subjected to seven pre-sowing treatments viz., T1-immersion of seeds in cold water for 12 h; T2-immersion of seeds in cold water for 24 h; T3-immersion of seeds in hot water (100 Â°C) and subsequent cooling at room temperature for 12 h; T4-immersion of seeds in hot water (100 Â°C) and subsequent cooling at room temperature for 24 h; T5-immersion of seeds in cold water for 12 h followed by immersion in hot water (100 Â°C) and allowed to cool for 1 h; T6-immersion of seeds in cold water for 24 h followed by immersion in hot water (100 Â°C) and allowed to cool for 1 h. Untreated seeds served as control (T0). Treatment T3 gave highest germination (96%) which was comparable with T5 (95 %), T4 (94 %) and T6 (93%). Nine growing media viz., T1: soil, T2: soil+sand (2:1), T3: soil+perlite (2:1), T4: soil+Farm Yard Manure (FYM) (2:1), T5: soil+vermicompost (2:1), T6: soil+sand+FYM (1:1:1), T7: soil+sand+vermicompost (1:1:1), T8: soil+perlite+FYM (1:1:1) and T9: soil+perlite+ vermicompost (1:1:1) were, also, studied for their effect on seedling growth of A. lebbeck. Among these media, maximum values of shoot length (23.82 cm), root length (21.14 cm), collar diameter (3.59 mm) and seedling quality index (0.350) were observed in T7.

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Dormancy in Pinusmonticola seed related to stratification time, seed coat, and genetics

Canadian Journal of Forest Research ◽

10.1139/x87-049 ◽

1987 ◽

Vol 17 (4) ◽

pp. 294-298 ◽

Cited By ~ 19

Author(s):

R. J. Hoff

Keyword(s):

Seed Coat ◽

White Pine ◽

Hard Seed ◽

Physiological Conditions ◽

Western White Pine ◽

Minor Site ◽

Coat Layer ◽

A Minor ◽

Hard Seed Coat

The inner layer of the seed coat, a papery membrane, and physiological conditions of the gametophyte–embryo were shown to be major sites of dormancy in seed of western white pine. The hard seed coat layer was a minor site. With no stratification, 7% of the seeds were not dormant, 9% were dormant because of the hard seed coat, 34% were dormant because of the inner seed coat, and 50% were dormant because of physiological conditions of the gametophyte–embryo. These values varied with stratification times and seed lots (families).

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Emergence of `Genesis' Triploid Watermelon following Mechanical Scarification

Journal of the American Society for Horticultural Science ◽

10.21273/jashs.124.4.430 ◽

1999 ◽

Vol 124 (4) ◽

pp. 430-432 ◽

Cited By ~ 2

Author(s):

John R. Duval ◽

D. Scott NeSmith

Keyword(s):

Seed Coat ◽

Citrullus Lanatus ◽

Crop Improvement ◽

Coarse Sand ◽

Financial Risks ◽

Hard Seed ◽

Series Of Experiments ◽

Triploid Watermelon ◽

Slow Growing ◽

Hard Seed Coat

Production of triploid watermelon [Citrullus lanatus (Thunb.) Matsum & Nakai] transplants is hindered by poor, inconsistent emergence, and frequent seed coat adherence to cotyledons. Seed coat adherence leads to weakened and slow growing plants. High seed costs, coupled with stand establishment problems, discourages transplant producers from growing this crop. Improvement of triploid watermelon emergence will lessen financial risks to growers and transplant producers and will provide a more reliable production system. Mechanical scarification was evaluated as a means to overcome inconsistent emergence and seed coat adherence. Seeds of `Genesis' triploid watermelon were placed in a cylinder with 100 g of very coarse sand (1.0 to 2.0 mm diameter) and rotated at 60 rpm for 0, 6, 12, 24, and 48 hours in a series of experiments. Number of emerged seed was recorded daily, to obtain emergence dynamics. No significant differences were observed in seed coat adherence among treatments. The longest duration of scarification However, enhanced emergence as compared to the control in three of four experiments. These data support earlier suggestions that a thick or hard seed coat is a factor contributing to poor germination and emergence of triploid watermelons.

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Subsidies for propagation of native species in Brazil with medicinal potential: Calophyllum brasiliense Cambess

Journal of Seed Science ◽

10.1590/2317-1545v41n3214007 ◽

2019 ◽

Vol 41 (3) ◽

pp. 318-327

Author(s):

Rosemeire Carvalho da Silva ◽

Andreza Cerioni Belniaki ◽

Elisa Serra Negra Vieira ◽

Francine Lorena Cuquel ◽

Maristela Panobianco

Keyword(s):

Seed Coat ◽

Native Species ◽

Seedling Morphology ◽

Hard Seed ◽

Commercial Use ◽

Calophyllum Brasiliense ◽

Complete Extraction ◽

Long Stem ◽

Cotyledonary Petioles ◽

Hard Seed Coat

Abstract: Calophyllum brasiliense Cambess. (guanandi) is a native species with medicinal potential and also generates expectation for commercial use (wood) and for recovery of degraded areas. These seeds have physical and mechanical dormancy, requiring techniques for dormancy release; knowledge of seed and seedling morphology that assists laboratory analysis and propagation of the species is also necessary. The objective of this study was to describe the morphological structures of the seeds and normal and abnormal seedlings of guanandi, and also investigate if complete extraction of the endocarp and the seed coat to overcome dormancy will affect the morphology and initial plant development, and consequently production of transplants. Guanandi seeds are large (1000 seed weight of 1480.9 g) with a hard seed coat; cotyledons account for most of the embryo and serve as a reserve; the embryonic axis is small (1.0-2.0 mm) in relation to the seed, yet it is differentiated. The seedlings have hypogeal cryptocotylar germination, with cotyledonary petioles, taproot, and epicotyl developing into a long stem and a tip protected by cataphylls. The main abnormalities in seedlings are related to the root system. Extraction of the endocarp and seed coat does not alter the morphology of seedlings and promotes their greater development, which may be an advantageous strategy.

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Using endocarp-remains of seeds of wild apricot Prunus armeniaca to identify rodent seed predators

Current Zoology ◽

10.1093/czoolo/55.6.396 ◽

2009 ◽

Vol 55 (6) ◽

pp. 396-400

Author(s):

Hongmao Zhang ◽

Wei Wang

Keyword(s):

Seed Coat ◽

Prunus Armeniaca ◽

Linear Discriminant ◽

Hard Seed ◽

Seed Predators ◽

Quantitative Studies ◽

Chinese White ◽

Wild Apricot ◽

Field Mice ◽

Hard Seed Coat

Abstract Some rodent-dispersed seeds have a hard seed-coat (e.g.woody endocarp). Specific scrapes or dental marks on the hard seed-coat left by rodents when they eat these seeds can be used to identify seed predators. In this study we measured the morphological traits of endocarp-remains of seeds of wild apricot Prunus armeniaca used by Chinese white-bellied rats Niviventor confucianus and Korean field mice Apodemus peninsulae. We established their Fisher’s linear discriminant functions to separate endocarp-remains between the two predators. A total of 90.0% of the endocarp-remains left by Korean field mice and 88.0% of those left by Chinese white-bellied rats were correctly classified. The overall percentage of correct classification was 89.0%. One hundred and sixty endocarp-remains of unknown what species predated them were classified using the functions. The method may allow more reliable quantitative studies of the effects of Chinese white-bellied rats and Korean field mice on seed consumption and dispersal of wild apricot and this study might be used for reference in other studies of seed predators identification on hard seeds.

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Ecophysiology of Mimosa pudica L. at Biratnagar, Eastern Nepal

Our Nature ◽

10.3126/on.v7i1.2568 ◽

1970 ◽

Vol 7 (1) ◽

pp. 177-181 ◽

Cited By ~ 1

Author(s):

B. Niroula ◽

D. Parajuli ◽

S. Jha

Keyword(s):

Seed Coat ◽

Crude Protein ◽

Dry Weight ◽

Germination Percentage ◽

Mimosa Pudica ◽

Crude Fibre ◽

Hard Seed ◽

Total Plant ◽

Mature Seeds ◽

Hard Seed Coat

All the freshly collected mature seeds of M. pudica were greenish in colour, whereas 7 year old stored seeds were a mixture of greenish and brownish seeds. The greenish seeds had hard seed coat and acid treated as well as sand rubbing for 6-10 min greatly enhanced their germination percentage. The brownish seeds were simply the deteriorated form of greenish seeds. Leaves and pods had higher contribution to total plant dry weight in ungrazed field and in pot-cultured plants clipped a month before flowering. The young shoots of the plant had 18.9% crude protein, 0.46% phosphorus and 25.4% crude fibre on dry weight basis.Key words: Hard seed coat, Mimosa pudica, scarification, dry matter productionDOI: 10.3126/on.v7i1.2568Our Nature (2009) 7:177-181

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