RU2197804C2 - Method of increasing rice salt-resistance - Google Patents

Abstract

FIELD: agriculture. SUBSTANCE: method involves presowing treatment of seeds with salt protector solution based on double copolymer of acrylic acid amide and triacryloyl hexahydro-1,3,5-triazine (CPAA). Said components are used in the following amounts, wt.%: CPAA, 0.0001-0.005; water, the balance. EFFECT: increased efficiency and improved productivity of plants growing in chloride salinated soil. 2 tbl

Description

 The invention relates to the field of agriculture, specifically to a method for increasing the salt tolerance of rice.

 A hetero-chain double copolymer of acrylic acid amide and triacryloylhexahydro-1,3,5-triazine (SPAA) is known as a film former for presowing treatment of corn seeds (see N.V. Stukalova, V.N. Zapliny, G.M. Pogosyan. Processing corn seeds with a film-forming agent based on a heterochained water-soluble copolymer. - Transactions of Kub.SKhI, 1990, issue 307 (335), s, 10-13). The use of this copolymer as a salt protector to increase the salt tolerance of rice plants is not known.

There is also a method of producing salt-resistant forms of sunflower using pre-soaking of sunflower seeds in water for 16-20 hours, followed by seed treatment with a solution of N-nitrosomethylurea at a concentration of 0.008-0.12% at 20-25 ^o C for 6-12 hours (cm Yu.D. Beletsky, EK Razoriteleva, LI Sizova, Method for the production of salt-tolerant forms of sunflower - A.S. 1576063 (USSR); M.cl. 5 A 01 H 1/06, Bull. 1988, 25 - prototype). The disadvantages of using this method are the need for prolonged preliminary soaking of seeds, the use of toxic, mutagenic and carcinogenic N-nitrosomethylurea for seed treatment, as well as a very slight increase in the salt resistance of other crops, such as rice, and the inability to increase photosynthesis activity, length and mass of roots and seedlings, panicle mass and rice yield when growing it in soil salted with sodium chloride (according to the authors).

 The technical solution to the problem of increasing seedling length, root length and mass, photosynthesis productivity, panicle mass, 1000 grain mass and rice yield when grown against a background of chloride salinity is to use a tool that eliminates the need for prolonged preliminary soaking of seeds in water, non-toxic, not mutagenic and a carcinogenic effect with a more active salt protective effect and capable of increasing the activity of photosynthesis.

 The objective is achieved by the fact that in the method of increasing the salt resistance of rice to increase the length of seedlings, the length and mass of roots, the mass of grain in a panicle, the mass of 1000 grains, grain productivity, as well as to increase the activity of photosynthesis when growing rice plants against the background of chloride salinity, a method based on pre-sowing treatment of rice seeds with a tool based on a double copolymer of amide of acrylic acid and triacryloylhexahydro-1,3,5-triazine (SPAA) at a concentration of 0.0001-0.005 wt.% at a rate of consumption of funds for presowing abotku 10 l / ton of seed.

 The novelty of the proposed proposal is seen in the fact that the use of SPAA allows to increase the length of seedlings, the length and mass of roots, the mass of grain in a panicle, the mass of 1000 grains and grain productivity, as well as to increase the activity of photosynthesis of rice plants when growing them against the background of chloride salinity; excluding prolonged preliminary soaking of seeds in water, which does not have toxicity, mutagenic and carcinogenic effects and with a stronger salt-protective effect.

 In this case, SPAA is prepared and purified by radical chain copolymerization in solution of amide of acrylic acid and triacryloylhexahydro-1,3,5-triazine in water at a concentration of the latter below the crosslinking threshold by the known method (see N.V. Stukalova, V.N. Zaplichny, G. M. Poghosyan, Processing of Corn Seeds with a Film-Forming Agent Based on a Heterochain Water-Soluble Copolymer, Proceedings of the Cuban Agricultural Institute, 1990, issue 307 (335), pp. 10-13). For comparison, use the commercial drug N-nitrosomethylurea brand "hch" in a known concentration of 0.12 wt.%. Based on SPAA and N-nitrosomethylurea, aqueous solutions of presowing seed preparations are prepared. Moreover, in the case of the known method and preparation of N-nitrosomethylurea (prototype), the test seeds are subjected to preliminary swelling in water for 16 hours, while in the case of the proposed method and SPAA, this operation is excluded.

 As the object of study, we chose a grain crop grown under flooding conditions - rice of the "Spalchik" variety. For control, seeds soaked in water were used. Specific examples of execution are presented below.

Example 1. Prepared for the experiment, rice seeds in an amount of 240 pcs. placed in a Petri dish, pour 62.8 μl (10 l / t of seeds) of water, mix thoroughly until completely wetted and dried at 20-25 ^o C for 0.5 h. Then, for a laboratory experiment, the seeds are sown in standard size soil-filled soil germination (60 seeds / germination in triplicate) and grown according to the generally accepted method. For the vegetation experiment, seeds are sown in vegetation vessels filled with soil of standard sizes (20 seeds / vessel in triplicate) and grown according to the generally accepted method.

 Example 2. The preparation and cultivation of rice seeds is carried out under conditions similar to those in example 1, with the only difference that the seeds are sown in soil containing specially applied sodium chloride in an amount of 0.2 wt.% (2 g per 998 g of soil) .

Example 3. Prepared for the experiment, rice seeds in an amount of 240 pcs. placed in a Petri dish, pour 62.8 μl (10 l / t of seeds) of an aqueous solution of SPAA concentration of 0.01 wt.%, mix thoroughly until completely wetted and dried at 20-25 ^o C for 0.5 h. Next, the seeds are sown and grown in saline (0.2 wt.% Sodium chloride) soil under conditions similar to example 2.

Other examples (examples 4-9) and the results of the experiments are presented in table. 1-2. Moreover, in examples 4-9, rice seeds are grown in saline (0.2 wt.% NaCl) soil, and in example 9, the seeds are subjected to preliminary swelling in water (16 h at 20 ^o C) and pre-sowing treatment with an aqueous solution of N-nitrosomethylurea ( 0.12 wt.%).

 The length of the seedlings, the length and weight of the roots of rice plants is determined on the 10th day from the results of laboratory experiments according to the generally accepted method.

 The value of the second maximum (m) of the slow-fluorescence induction curve (IRF) as an indicator of the activity of the photosynthesis process is determined from the results of the growing experiment for the flag leaf in the flowering phase according to the well-known Tretyakov technique (see GI Tretyakov. Physiological studies of rice salt tolerance: Diss. Candidate of Biol Sciences, Tbilisi, 1983, 186 p.).

 The parameters of the crop structure (mass of grain in a panicle, mass of 1000 grains and productivity) are determined upon reaching full ripeness in the growing experiment.

 The data obtained as a result of calculation and averaging of three replicates in each example are mathematically reliable and are summarized in Tables 1 and 2.

 As can be seen from the data table. 1 and 2, the application of the proposed method for increasing the salt resistance of rice (examples 1-9) provides, in comparison with the control, a pronounced increase in the resistance of rice to salinity. Thus, a comparison of examples 1 and 2 shows that in the absence of presowing treatment of SPAA seeds, rice cultivation under conditions of chloride salinity leads to a sharp (17-30% in comparison with the control) decline in all vital indicators of the vegetation process and productivity. Pre-sowing treatment of rice seeds according to the proposed method with an aqueous solution of SPAA in the optimal concentration (0.0001-0.05 wt.%) Provides, in comparison with the control, an increase in the length of seedlings and roots by 3.5-10.5 and 48.1 - 62 , 2%, respectively (128.5-137.2 and 102.8-112.6 instead of 124.2 and 69.4 mm, respectively), while treatment with N-nitrosylmethylurea increases these indicators only by 0.4 and 8 , 6%, respectively.

 The increase in the mass of seedlings and roots during the treatment of SPAA seeds in comparison with the control occurred by 24.4-53.1 and 15.9-38.2%, respectively (40.3-49.6 and 40.1-47.8 mg instead 32.4-34.6 mg, respectively), while treatment with N-nitrosylmethylurea increases these parameters only by 4.3-4.6%, respectively.

The value of the second maximum (m) of IR ZF in examples 4-7 (treatment of SPAA seeds in optimal concentration) is 11.6-36.4% higher than that of the control (27.0-33.0 instead of 24.2 rel.ed, respectively ), while treatment with N-nitrosomethylurea (example 9) does not increase this indicator at all
The mass of grain in one panicle, the mass of 1000 grains and the grain yield in the proposed method when processing rice seeds SPAA in the optimal concentration (examples 4-7) increases in comparison with the control by 12.3-50.8; 0.8-3.5 and 3.5-22.3%, respectively (0.73-0.98; 27.4-28.15 and 6.49-7.67 g instead of 0.65; 27.19 and 6.27 g, respectively) while seed treatment with N-nitrosomethylurea only increases the grain mass in the panicle by 3.07% compared to the control, and the rest of the data are even negative compared to the control.

 Thus, the application of the proposed method for increasing the salt tolerance of rice seeds by pre-sowing treatment with their aqueous solutions of SPAA can increase the length and mass of seedlings and roots, intensify the photosynthesis process and increase the productivity of rice plants when growing them under chloride salinity, eliminating the need for pre-soaking the seeds in water and use for presowing seed treatment of mutagenic and carcinogenic N-nitrosomethylurea.

Claims (1)

A method of increasing the salt tolerance of rice, including pre-sowing treatment of seeds with a salt protector, characterized in that the agent is based on a double copolymer of acrylic acid amide and triacryloylhexahydro-1,3,5-triazite (SPAA) in the following ratio of ingredients, wt.%:
SPAA - 0.0001 - 0.005
Water - Else
and the seeds are treated by semi-dry dressing at the rate of 10 l / t of seeds.

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