DE2547696A1 - Antiviral ionic complex of linear polyarginine - and natural double-chain ribonucleic acid or its derivative - Google Patents

Abstract

Antiviral substance comprises a mainly ionic complex in which the cationic part is a linear polyarginine having at least 5 arginine units and the anionic part is (a) a double chain ribonucleic acid polyanion, the double chain ribonucleic acid being of natural origin or (b) a polyanion of a double chain deriv. of a natural double chain ribonucleic acid. The complexes are antivirals with a broad spectrum of activity against both RNA and DNA viruses e.g. encephalomyocarditis (EMC) virus, Semlike Forest virus, foot and mouth disease virus and Herpes Simplex. At least part of their activity is due to induction of interferons in the cells of the host. The LD50 in mice of these complexes is less than the LD50 of the RNA alone.

Description

"Antiviral substance, process for its preparation and these

Medicinal preparations containing substance "It is known per se that double-stranded ribonucleic acids, which are abbreviated to RNA below, are highly effective Interfer-or-inducers and therefore of great importance for broad-spectrum prophylaxis of viral infections and, to a lesser extent, are used to treat such Infections can be used. Both the synthetic and the ribonucleic acids of natural origin show interferon inducer activity as well as antiviral activity in tissue cultures and in animals. Double-stranded ribonucleic acids with antiviral Activity can e.g.

can be extracted from virus particles that are found in certain infected Fungi occur, as in some strains of Penicillium chrysogenum, Penicillium funiculosum, Penicillium stoloniferum, Aspergillus niger and Aspergillus roetidus. In addition, the term ribonucleic acids occur in cytoplasmic polyhedrosis viruses, in Reovirus-3 virion and in the replicative phage form MS2 from E. coli and in the replicative phage form of MU9 of a mutant E. coli.

However, there is evidence that double-stranded ribonucleic acids of natural origin in humans and animals too high a toxic side effect to have. Their use in human and veterinary medicine is therefore limited.

There is therefore a need for an antiviral agent that is less is toxic than double stranded ribonucleic acid alone, and its antiviral activity is comparable or better.

It is known per se that nucleic acids with many basic polypeptides, like protamines and polylysine, form ionic complexes. Most of this work however, left with the complexes of polybases and deoxyribonucleic acid and single stranded ribonucleic acid. These polybase-nucleic acid complexes are against Nuclease degradation and thermal denaturation more stable than the parent nucleic acid. When it was discovered that synthetic double-stranded ribonucleic acids were interferon inducers it was believed that treating double-stranded ribonucleic acid with Polybases lead to a stabilization against the degradation by nbenuclcase and thus to improved or prolonged antiviral activity in vivo. The results however, this work has not been very encouraging. Billiau and coworkers (see Ann. N.Y. Acad. Sci., 173 (1), pp. 657 (1970)) reported that the stimulation by double-stranded ribonucleic acid 4eç interferon mechanism in tissue cultures increased up to 100 times can be made by adding polybasic Substances such as neomycin, streptomycin, diethyla.minoäthyldextran, methylated Albumin, protamine, histone and colistin. These compounds were known to that they inhibit the action of the ribonuclease or the uptake of ribonucleic acid increase in the cell. Billiau et al suggest that "some of these are basic Substances suitable for the therapy of virus infections by interferon inducers could be "but that" limit the induction of interferon by poly-I : Poly-C in vivo by diethylaminoethyldextran, but not by neomycin or Protamine would increase ".

High molecular weight poly-D-lysine increases the induction of interferon Poly-I: Poly-C in mice and is superior to diethylaminoethyldextran in this regard (see Rice and co-workers in 1,? ppl.

Microbiol. 19 (5), p. 867 (1970)). Those with a combination of Poly-I : Poly-C and poly-D-lysine treated animals showed no immediate signs of toxicity, but the dose of the material was well below the dose that the toxic effects of Poly-I: Poly-C occur alone.

The FR-PS 178 953 discloses a preparation that 1 mg double-stranded Contains ribonucleic acid, 200 µg polyornithine and 50 mg vitamin B6. The polyornithine is said to increase the uptake of ribonucleic acid in the cells.

The literature suggested that complexes of certain polybases with double-stranded ribonucleic acid increase the levels of interferon in vitro and in vivo and / or have been extended. It is However known that the interferon level does not necessarily parallel antiviral activity. A connection that has only a slight interferon-inducing effect, but it can be a very good one be antiviral and vice versa. In addition, there is no consensus in the literature about what kind of polybase is necessary to raise interferon levels in vivo to reach. Combinations of protamine and double stranded ribonucleic acid appear to be less satisfactory than double-stranded ribonucleic acids alone, whereas combinations of double-stranded ribonucleic acid and diethylaminoethyldextran are superior to her. These contradicting results make it impossible to say whether and which combination of double-stranded ones forming an ionic complex Ribonucleic acid with a polybase for interferon-inducing activity, x less antiviral activity, double-stranded ribonueleic acid alone is superior.

The usefulness of an antiviral agent essentially depends depends on two factors: On the duration of the achieved by a certain dose of the agent Protective effect and toxicity of the agent.

The duration of the protective effect does not necessarily depend on the ability induce interferon production, and therefore will not, according to the Literature influenced by the addition of a polybase. As for the toxicity of an antiviral Concerning means, nothing can be found in the literature.

It has now been found that complexes of double-stranded ribonucleic acid of natural origin with polyarginine are less tcx-c ', at least for small ones Mammals, than the double-stranded Parent ribonucleic acid, and that these complexes have a longer antiviral protective effect than the corresponding one Ribonucleic acid.

The invention thus provides an antiviral substance that is in the is essentially an ionic complex, which is characterized in that the Cations Polycations of a linear polyarginine molecule with at least 5 arginine units and the anions either a) polyanions of a double-stranded ribonucleic acid of natural origin or b) polyanions of a double-stranded derivative of a are natural double stranded ribonucleic acid.

The term "double stranded" refers to the fact that two separated ribonucleic acid molecules by hydrogen bonding between the complementary bases are associated along the molecule. The ribonucleic acids can be "double-stranded" to different degrees.

The term "double-stranded ribonucleic acid of natural origin" refers to any double-stranded ribonucleic acid obtained from the mushrooms listed above can be extracted, and includes synthetic double-stranded ribonucleic acids, such as polyinosinyl: polycytidylic acid (poly-I: poly-C), polyadenyl: polyuridylic acid (Poly-A: Poly-U) and polyguanidyl-: polycytidylic acid (Poly-G: Poly-C).

The term "double-stranded derivative of a natural double-stranded Ribonucleic Acid "refers to any natural double-stranded Ribonucleic acid, which are subjected to a chemical or biochemical (e.g. enzymatic) reaction which changes the primary and / or secondary and / or tertiary structure (e.g. the N-oxides according to GB-PS 1 284 150 or the alkali-modified double-stranded Ribonucleic acids according to DT-OS 2 201 513). The prerequisite is that the Derivative still has a substantial part of the base pairs of the complementary strands.

The double-stranded nature of a double-stranded ribonucleic acid or its derivative can be characterized by two parameters, the hyperchromicity and the Tm value will. These parameters are determined by recording the UV absorption of the material obtained at 260 nm while gradually increasing the temperature. The UV absorption a double-stranded ribonueleic acid at this wavelength increases with increasing Temperature until a constant value is reached, that of the absorption of the thermal denatured (e.g. 3 single-stranded) ribonucleic acid corresponds. The difference between the two limit values of the absorption expressed as a percentage of the absorption of double stranded material, is called the "hyperchromicity" of that material designated.

The UV absorption at 260 nm of a double-stranded material Plotted against the temperature, it is found that the absorption at high Temperatures is greater than at low temperatures. The temperature at which the absorption in the middle between the absorption of the double stranded material and that of the thermally denatured (e.g. single-stranded) material is called Denotes the Tm value of this material.

The polyarginine molecule used as a cation in the complex according to the invention has a molecular weight of 1,500 to 1,000,000, preferably about 6,500. "Linear" means that there are no crosslinks between the basic amino groups in the polyarginine molecule of arginine units.

A poly-D, poly-L or poly-D, L-arginine molecule is suitable as a polyarginine molecule. A poly-L-arginine molecule is preferred.

The double-stranded polyanions used as polyanions are preferably derived Ribonucleic acids from virus particles that are present in certain infected fungi are, e.g. in certain fungi of the genus Penicillia, e.g.? .chrysogenu: ri (GB-PS 1 170 929), P. stolontperum (Banks and co-workers, Nature, Vol. 223, p. 155 (1968)) and Aspergilli, e.g., A. niger and A. foetidus (G3-PS 1,300,259). Preferably varieties the polyanions (4 and (b)) induce interferon production in living mammals (this can be done by the method of G.P. Lampson, A.A. Tytell, A.K. Field, M.M. Nemes and M.R. Hilleman in "Proc.Nat.Acad.Sci.", Vol. 58, p. 782 (1967)).

The antiviral substance of the present invention is essentially ionic Complex of the by a strong electrostatic interaction between the cationic Characterized polyarginine content and the anionic content of ribonucleic acid is. However, other types of interactions are also possible; Exactly about however, these types of ties are not known.

In the complexes according to the invention, practically all are anionic Place the double-stranded ribonucleic acid through corresponding cationic places of the polyarginine neutralized, the cationic sites being the basic amino groups of arginine monomers. To this neutralization of the cationic and anionic To reach places, one uses the polyarginine either as a single molecule with one corresponding to the anionic sites of double-stranded ribonucleic acid Number of cationic sites or as smaller polyarginine molecules, with the Sum of the cationic sites and the anionic sites of the double-stranded ribonucleic acid is equivalent to. With these "1: complexes one obtains a long antiviral protection period and low toxicity.

The invention also relates to a method for producing the antiviral Substance which is characterized in that in solution there is linear polyarginine or its salt either with a) polyanions of a double-stranded ribonucleic acid of natural origin or b) polyanions of a double-stranded derivative of a converts natural double-stranded ribonucleic acid.

You can use the polyarginine polycations in aqueous solution with the Implement ribonucleic acid polyanions. So you can polar gine hydrochloride in the aqueous solution of an inorganic salt, e.g. sodium chloride, and dissolve with mix with an appropriate solution of ribonucleic acid. When the molarity the resulting saline solution is not too high, the complex fails immediately.

If this is not the case, the solution can be to reduce it the Dilute the molarity, the complex then precipitates.

But you can also use a mixture of the neutral polyarginine and the Add ribonucleic acid or its derivative to a salt solution and the resulting If necessary, dilute the solution to precipitate the complex.

A small excess of polyarginine polycations is preferably used, the excess based on the basic amino groups with the phosphoric acid groups the ribonucleic acid polyanions can react is calculated.

The complexes of the invention have antiviral activity with a broad spectrum against a number of deoxyribonucleic acid and ribonucleic acid viruses, e.g. Encephalomyocarditls virus, Semliki Forest virus, against foot and mouth disease causing virus and against the herpes simplex virus. Presumably they induce Complexes according to the invention protect the interferon production in the host cells and thus against the attack of viruses.

Surprisingly, the toxicity of these complexes (measured as ID in mice) lower than that of ribonucleic acid alone.

The invention thus relates to medicinal preparations which, by means of a content of the antiviral substance according to the invention as an active ingredient, optionally in combination labeled with pharmacologically acceptable carriers and / or diluents are.

The choice of carrier depends on the preferred type of Administration. You can use the pharmaceutical preparations according to the invention z +, B. subcutaneous or inject intramuscularly. The antiviral substance according to the invention is then in the diluent either dissolved or suspended as a fine dispersion. For local use, e.g. on the mucous membrane of the nose or throat, the carrier is a diluent.

The examples illustrate the invention. The abbreviation "d.s.-RNS" means double stranded ribonucleic acid.

Example 1 Preparation of a complex from ds-RNA obtained from P.chrysogenum, ATCC 10002 virus-like particles was isolated, and polyarginine was stirred Solution of 100 mg of ds-iNS sodium salt in 200 ml of 0.15 M sodium chloride is made at room temperature with a solution of 200 mg poly-L-arginine with a molecular weight of 6500 in 200 ml of 0.15 M sodium chloride are added. A precipitate forms immediately. That The reaction mixture is stirred for 16 hours at room temperature and then centrifuged. According to the W spectrum, the supernatant solution does not contain any nucleic acid. The precipitation is washed with 200 ml of water, then with 200 ml of methanol and at room temperature dried under reduced pressure. ; 4an receives 162 mg of the complex as a white Solid. The product is insoluble in 3M sodium chloride. To the biological The complex according to the invention is used as a suspension for experiments.

Biological data (a) Toxicity in mice The toxicity of the starting material used double-stranded ribonucleic acid and that prepared according to Example 1 Complex is compared in 16 to 20 g mice, strain CD1.

The compounds are injected intraperitoneally, the animals become Observed for 10 days. Table I summarizes the results.

Table 1 Toxicity of the antiviral complex according to the invention. The dose relates to the amount of double-stranded ribonucleic acid present in each case. The dying time is given in the number of dead animals / number of animals in a group Dose Mortal LD50 Compound (mg / kg) ability (mg / kg) ds-RMS-polyarginine- Complex in 1.5 M NaCl (Suspension) 25 0/5 7 100 50 o / 5 100 0/5 ds-RNA in 0.15 M NaCl 12.5 1/10 25 25 5/10 50 9/10 (b) Antiviral A: The compounds are injected intraperitoneally into mice weighing 16 to 20 g, strain CD1. Twenty-four or 72 hours later, they must be injected intraperitoneally with one or two dilutions of encephalomyocarditis virus. The animals are observed for 12 days and the mortality is compared with that of untreated control mice. Table II summarizes the results. Table II Short-term antiviral activity of the ds-RNA-polyarginine complex according to the invention. Number of dead animals out of 10 in each group Antiviral data (encephalomyocarditis virus) Connection 3 days before connection 1 day before Viral Infection Administered Viral Infection Administered Compound virus dose virus dose virus dose virus dose 10-4 10-5 10-4 10-5 Compound Dose (mg / kg) 5 0.5 0.05 5 0.5 0.05 5 0.5 0.05 5 0.5 0.05 ds-RNA in 0.15 M NaCl 9 9 7 3 4 7 4 3 6 0 2 2 ds-RNA / poly-L-arginine Complex, suspension in 1.5 m NaCl 10 10 10 8 7 6 10 10 9 5 10 9 untreated controls Viral Dose Viral Dose Mortality 10-4 20/20 10-5 18/20 EXAMPLE 2 Preparation of a complex of ds-RNA, which was isolated from P.chrysogenum ATCC 10002 virus-like particles, and polyarginine A stirred solution of 500 mg of ds-RNA sodium salt in 500 ml of 0.15 M sodium chloride is mixed with a solution at room temperature of 318 mg of poly-L-arginine hydrochloride (Miles code no. 71-103A) in 100 ml of 0.15 M sodium chloride. A precipitate separates out. The mixture is stirred for 3 hours at room temperature, then left to stand at 4 ° C. overnight. The precipitate is centrifuged. According to the UV spectrum, the supernatant solution does not contain any nucleic acid. The precipitate is suspended in 0.15 ml of sodium chloride and centrifuged again.

The precipitate is suspended in 0.15 M sodium chloride and comminuted. A fine suspension of the complex is obtained with a ds-RNA content of 20 mg / ml. The product is insoluble in 3M sodium chloride. Pür the biological experiments will it used as a suspension.

Duration of action The protection that the complexes according to the invention against low (8 x LDso) to) and high (80 x LD50) infection values of the encephalomyocarditis virus guarantee is assessed in individual time intervals of up to 5 weeks. 16 to In mice weighing 20 g, strain CD1, the antiviral substance according to the invention is applied subcutaneously injected. 0, 1, 7, 21 or 35 days after these mice are given one or two dilutions of rncephalornyocarditis virus injected intraparitoneally. The animals are 12 days observed the death rate of treated with complex Animals are compared with that of control mice given an appropriate dose of ds-RNA either intraperitoneally or subcutaneously and appropriate amounts of encephalomyocarditis virus had received. The time intervals, the dose amounts and the mode of administration are summarized in Tables III and IV. Because the animals at the end of the pretreatment period were unusually large, became necessary for this experiment on the seventh day Virus dose determined that kills 50% of the test animals. Accordingly, could then the virus doses are chosen.

EMC LD50 in the test: 10-6.9 at the end: 10-6.6 where LD50 is the dose of virus that kills 50 ffi of the animals.

Table III Duration of the protective effect of the complex according to the invention in mice which have been injected with encephalomyocarditis virus in an 8 × LD50 amount. The number of dead animals / animals in a group is given Pretreatment time (days) binding dose administration 1 7 21 35 (mg / kg) range ds-RNS 5 ip 0/10 3/10 - - ds-RNS 5 sc 0/10 7/10 - - Complex 100 sc 6/10 3/10 1/9 2/10 Controls - - 10/10 - - - Table IV Protective effect in mice injected with encephalomyocarditis virus in an amount of 80 x LD50. The number of dead animals / animals in a group is given. Hardening time (days) Compound Dose Ad 1 7 21 35 (mg / kg) range s-RNS 5 ip 0/10 10/10 - - s-RNS 5 sc 2/10 10/10 - - Complex 100 sc 10/10 5/10 5/10 9/10 roll up - - 10/10

Claims (12)

Claims che 1. Antiviral substance, which is essentially a Ionic complex is, as indicated by the fact that the cations are polycations a linear polyarginine molecule with at least 5 arginine units and the anions either a) polyanions of a double-stranded ribonucleic acid of natural origin or b) polyanions of a double-stranded derivative of a natural double-stranded one Are ribonucleic acid. 2. Antiviral substance according to claim 1, characterized in that the cations are poly-L-arginine cations. 3. Antiviral substance according to claim 1 and 2, characterized in that that the double-stranded ribonucleic acid from virus particles from infected strains from Penicillium chrysogenum, Penicillium stoloniferum, Aspergillus nieger or Aspergillus foetidus originates. 4. Antiviral substance according to claim 1 and 2, characterized in that that the double-stranded ribonucleic acid is the replicative form of a phage. 5. Antiviral substance according to claim 1, 2 and 4, characterized in that that the double-stranded ribonucleic acid is the replicative form of a phage mutant MU9 of an MS2 Escherichia coli phage. 6. Antiviral substance according to claim 1 to 5, characterized in that that essentially all anions of double-stranded ribonucleic acid or their Derivative involved in an ionic bond with the polyarginine cations. 7. A method for producing the antiviral substance according to claim 1 to 6, characterized in that linear polyarginine or its Salt with either a) polyanions of a double-stranded ribonucleic acid natural Origin or b) polyanions of a double-stranded derivative of a natural one converts double-stranded ribonucleic acid. 8. The method according to claim 7, characterized in that one aqueous electrolyte solution of a polyarginine with an xinS aqueous electrolyte solution a double-stranded ribonucleic acid or its double-stranded derivative mixed. 9. Medicinal preparation, characterized by a content of an antiviral Substance according to claim 1 to 6 as an active ingredient, optionally in combination with customary pharmacologically acceptable carriers and / or diluents. 10. Medicinal preparation according to claim 9, characterized by additional errQn Content of a live or killed virus 11. Medicinal preparation according to claim 9 and 10 in a form suitable for injections. 12. Medicinal preparation according to claim 9 and 10 in one for the application suitable shape on the mucous membrane of the nose or throat.