DD280030A1 - MEDIUM FOR THE PROTECTION OF CULTURAL AND USE PLANTS AGAINST VIRUSES - Google Patents

Abstract

The invention relates to agents for the protection of crops and crops against viruses. According to the invention, they contain as active ingredient one or more compounds of the general formula in which R denotes NO 2 or NH 2, XNa, K, NH 4 or aliphatic amine andn 0 or 1. formula

Description

Field of application of the invention

The invention relates to agents for increasing the resistance of crops and crops to viruses.

The funds are used in the laboratory and greenhouse sector as well as in the field - under practical growing conditions - against various infectious diseases, such as

in the case of the bean (Phaseolus vulgaris L.), the common bean mosaic virus (Bean common mosaic virus) against the bean yellow mosaic virus (bean yellow mosaic virus)

- barley (Hordeum vulgare L.) against the barley stripe mosaic virus against the barley yellow dwarf virus

- with the cucumber (Cucumisstativus L)

against the cucumber green mottle mosaic virus against the cucumber mosaic virus

in the potato (Solanum tuberosum L.), the potato virus X (potato virus X)

against the potato Y virus (potato virus Y)

- in the turnip (Beta vulgaris L) against the Virösa root activity (beet necrotic yellow vein virus) against the mild beet yellowing virus (beet mild yellowing virus)

- Tobacco (Nicotiana tabacum L.) against tobacco mosaic virus (Tobacco mosaic virus) against tobacco necrosis virus (Tabacco necrosis virus)

Characteristic of the known state of the art

1. Direct control of pests The development of virucidal agents for the direct control of viruses has, until now, provided insignificant results compared to the product range of fungicides or insecticides (RF WHITHE and JF ANTONIW: Crop Protection 2 (1983 ), 259-271).

The main cause is dari, justified that the metabolic rate of viruses in contrast to that of the fungi or bacteria is not autonomous, but is inseparably coupled with the metabolism of the plant. Chemotherapeutic interventions in the virus metabolism therefore always influence the host metabolism. The currently most promising agents from the class of base analogues, ribavirin (Synonym: Virazoi; G. SCHUSTER: Effect of virazole on the multiplication of systemic viruses in N.tabacum "Samsun") Report of the Institute for Tobacco Research, Dresden 23 [1976], 21 to 36) and dioxohexahydrotriazine (abbreviation: DHT; G. SCHUSTER et al .: Antiphytoviral activity of 2.4-dioxohexahydrotriazine Acta Virologica 23 (1979), 412 to 420), despite proven effect on the experimental stage have not yet come out As already mentioned, processes for the direct control of pests are not always problem-free in ecological, toxicological and in part also economic terms, and the increasing selection of pathogenic strains that have become resistant to pesticides is difficult, and not all important infectious diseases can be treated with these methods be controlled Alternatives b The methods used to increase the resistance of the plants. These methods mainly include the breeding of resistant varieties. The use of such varieties is burdened with the problem of overcoming resistance by virulent pathotypes whose selection may be favored under modern growing conditions.

2. Increase the resistance of the plants

Increasing the resistance of plants is a crucial alternative to direct control of pathogens. In this case, one uses the genetically fixed defense potential of the plants, which is either constantly effective (and manifests itself as a specific degree of resistance that can be influenced by the breed) or requires activation (resistance induction).

2.1. Breeding resistant varieties

The great successes of resistance breeding are also accompanied by an increasing selection of virulent virus strains that can break through the resistance of new plant forms and suddenly make them susceptible to resistant varieties. Furthermore, in some areas of plant breeding, it is becoming increasingly difficult to combine the demands for high yields and good quality in breeding with high resistance properties at the same time.

2.2. Activation of plant's own defense mechanisms

The exploitation of the possibilities inherent in this principle represents a great potential in the fight against viruses. For today's crop protection, therefore, there is the need to develop practicable methods for using this principle.

At present, there are essentially two methods based on the activation of natural defense systems against plant viruses: virus interference (cross protection) and the acquired or induced resistance.

Vi.usiniferosis is a phenomenon in which the systemic spread of a weak virus strain in the plant gives it increased resistance to a strong strain of the same virus. Although used in practice in field crops or plants under glass and plastic, the Prununisierung remains a highly critical process because of the biological instability of the plant and virus material.

Induced resistance is understood to mean the "selectively alterable disease disposition of the plants in the direction of an increased resistance (= resistance)" (W. BEICHT: How to "immunize" plants? Natural History 37 [1984J, 3G9 to 312]). Its essence is the activation of genetically preformed resistance mechanisms; In contrast to classical chemotherapy, the applied agents do not counteract the virus itself, but initiate reactions that interfere with the process of virus replication or spread.

Currently the most advanced is the induction of resistance by application of plant extracts (H.N. VERMA et al.

M.M.A.A. KHAN: Management of plant virus diseases by Pseudoranthemum bicolor leaf extract. Journal of Plant Diseases and Plant Protection 91 [1984], 266 to 272).

However, the need to produce extracts places significant limits on spreading on large areas. Since the previously known active components are characterized as high molecular weight substances with polysaccharide or Polypeptidnatur, a synthetic approach is currently not possible.

Object of the invention

The object of the invention are novel means for protection against pathogenic viruses in crops and crops, which should be the pathogenesis of the development or propagation of pests - the spread of virus-related plant diseases in agricultural and horticultural crops - effectively met.

Explanation of the essence <t invention

It was therefore an object, by physiologically harmless usable, synthetically generated, chemical means for resistance activation effective control of viral infectious diseases in crops and crops to allow with ecological benefits and high benefits in increasing and stabilizing yields - without genetic intervention) and without the use of toxic pesticides.

This object is achieved in that the means for protecting crops and crops against viruses in addition to conventional adjuvants and additives as an effective ingredient one or more compounds of the general formula

in the

R = NO ₂ or NH ₂

X - Na, K, NH ₄ or aliphatic amine and

η = 0 or 1,

contain.

The ready-to-use agents contain one or more biologically active compounds of the abovementioned type together with carriers and / or surface-active substances.

The present invention overcomes the stated shortcomings of the hitherto known technical solutions. The agents according to the invention produce - they are applied - resistance to viral pests by activation of plant-own defense systems (indirect pest control); They are physiologically harmless in all application variants. Phytotoxic effects have not been detected in any case. Special examinations also showed no toxic effects in humans and animals.

Plants are known to have a natural resistance potential, which is characterized by a high degree of elasticity and can be activated by non-genetic type interventions.

The active compounds of the presented agents are readily accessible by chemical synthesis. The industrial production of the funds is very economical, just as much as in the agricultural and horticultural practice their application (application rate) is extremely economical. Compared to the conventional methods of pest control, there are no toxicological and ecological problems when using the funds; the economy in production and application of the compositions according to the invention is highly favorable compared to, for example, conventional pesticides.

embodiments

The exemplary embodiments are intended to explain the advantages of the agents according to the invention in more detail.

example 1

Reinforcement of the defense reaction against the tobacco mosaic virus in tobacco plants (Nicotiana tabacum var. Samsun) by the agents according to the invention

The tobacco plants are sprayed to drip point in the 5-6-sheet stage 48h and 24 h prior to virus inoculation with a 0.05% aqueous solution of the active compounds with the addition of 0.01% of a surfactant (Tween 20: polyoxyethylene sorbitan monolaurate) , The infection is carried out by manually rubbing a diluted aqueous suspension of the purified virus (TMV) after previous carborundum pollination of the leaves. The virus spreads systemically in the plants.

14 days after the inoculation is harvested. The virus concentration in the pressed juices obtained from the leaves by means of a roller press is determined by means of a simplified spectrophotometric determination method and compared with the virus concentration in the pressed juice from untreated leaves.

Name of virus concentration

4,4'-dinitro-tolane-2,2'-disulfonic acid 78.4

4,4'-diamino-stilbene-2,2'-disulfonic acid 87.3

4,4'-dinitro-stilbene-2,2'-disulfonic acid 89.4

It turns out that the virus concentration is reduced by the treatment according to the invention with said agents to 80 to 90% compared to the untreated control.

Example 2

Enhancement of the defense reactant against the tobacco mosquito virus in Tabakpfianzcn (Nicotiane tabacum var. Samsun NN or Xanthi-nc) by the agents according to the invention

The tobacco plants are sprayed dripping wet in the 8-leaf stage 48 h and 24 h before virus inoculation with a 0.05% aqueous solution of the active compounds with the addition of 0.01% of a surfactant (Tween 20: polyoxyethylene sorbitan monolaurate). The Infekiion is carried out as in Example 1 by manually rubbing a dilute aqueous suspension of the purified virus (TWV) after previous Carborundpäubung the leaves. The virus is localized at the site of its entry into the leaf, where it forms visible lesions. Their number is determined 4-6 days after inoculation; their reduction compared to the untreated control is a measure of the antiviral effect.

Name of lesion number

4,4'-dinitro-tolane-2,2'-disulfonic acid 34.9

4,4'-Diamino-2,2'-disulfonic acid 32,6

4,4'-dinitro-stilbene-2,2'-disulfonic acid 41,8

The number of lesions is reduced by the inventive treatment with said agents to 30 to 40% compared to the untreated control.

Example 3

Reinforcement of the defense reaction against the barley-striped mosaic virus in barley planters (Hordeum vulgare L.) by means of the invention

The barley plants are sprayed to drip point in the 3-leaf stage 48 h and 24 h prior to virus inoculation with a 0.05% aqueous solution of the active compound with the addition of 0.01% of a surfactant (Tween 20: polyethylene sorbitan monolaurate) , After application, the plants are rinsed thoroughly under tap water. Infection is by manual rubbing with a diluted extract of infected plants after previous carborundum pollination.

The virus spreads systemically in the plants. 14 days after the inoculation is harvested. The virus concentration in the buffer extracts obtained from the leaves is determined by means of a spectrophotometric or serological determination method and compared with the virus concentration in the buffer extract from untreated leaves.

Name of virus concentration

4,4'-dinitro-tolane-2,2'-disulphonic acid 76,8

4,4'-diamino-stilbene-2,2'-disulphonic acid 50,8

4,4'-dinitro-stilbene-2,2'-disulphonic acid 62,4

The treatment according to the invention with the said agents leads to a lowering of the virus concentration to 50 to 75% compared to the untreated control.

Claims (1)

Agent for the protection of crops and crops against viruses, characterized in that they contain, in addition to customary auxiliaries and additives as an active ingredient one or more compounds of the general formula C (H) _n - in the R = NO ₂ or NH ₂ X == Na, K, NH ₄ or aliphatic amine and η = 0 or 1 mean.