DE3935066A1 - Treatment of prophylaxis of polio and herpes virus infections - comprises admin. of 3-(di:hydro-5-(hydroxy-1H- indolyl-2-oxo-3H-pyrrolidene)-di:hydro-2H-indole - Google Patents

Abstract

Violacein (3-(1,2-dihydro-5-(5-hydroxy-1H-indol-3-yl)-2-oxo-3H pyrrole-3-ylidene)-1,3-dihydro-2H -indol-2-one) can be used in the treatment of virus diseases. Violacein can be prepd by cultivating chromobacterium violaceum in an aerated fermenter with turbulent mixing in a batch operation lasting 5-7 days at 20-25 degC in a medium contg peptone glucose and common salt at a pH of 6-7. Native violacein (90% violacein, up to 10% desoxyviolacein) can be isolated from the suspension culture by microfiltration to 10% of the vol, spray-drying or freeze-drying the concentrate, extracting the dry prod with a solvent (pref THF or dioxan), concentrating the extract by evapn and pptg the violacein with water, removing impurities from the filtered off ppte using non-polar solvents pref CHCl3 and recrystn from an organic solvent (pref THF or dioxan). Crude violacein can be recovered from chromobacterium violaceum by sepg the bacterium from the medium, lyophilising the sediment, and extracting using ethanol. The crude violacein can then be extd twice with n-heptane and subjected to DC-chromatography using CHC13/propanone/pyridine (50:40:10). Violacein is recovered by eluting the zone with Rf 0.64 with CHC13/Me0H (80:20 or 50:50) and rechromatographing and eluting, while desoxyviolacein is recovered by eluting the zone with Rf 0.71 with CHC13 and rechrommatographing, and eluting. Both fractions can be taken up in pyridine, the pyridine evapd in vacuo over H2S04 and the residue dried in vacuo at 65 deg C. USE/ADVANTAGE - Violacein is the main component (90%) of the blue-black pigment in chromobacterium violaceum which can be used as an antibiotic. The purified violacein has good antiviral activity and is esp effective against polio and herpes viruses.

Description

The invention relates to methods for isolating violacein and its use for the prophylaxis and treatment of viral diseases.

Violacein is the main constituent of a blue-black pigment in Chromobacte rium violaceum, a mic available from the soil and waters of tropical regions organism, wherein as a minor constituent deoxyviolacein occurs. Violacein and Deoxyviolacein has long been known [cf .: J. of Infect. Dis. 76, 1, 47 (1945); Black, M.E. and Shaphan, J., J.A.M.A. 110, 1270 (1938); R.D. De Moss: An tibiotics, Vol. 2, Ed. D. Gottlieb and P.D. Shaw, page 77, Springer 1967; N. You ran et. al., An. Acad. Bras. Cienc. 55 (3), 231 (1983)].

Chemically, violacein is 3- [1,2-dihydro-5- (5-hydroxy-1H-indol-3-yl) -2-oxo-3-H-pyr Rol-3-ylidene] -1,3-dihydro-2H-indol-2-one with the empirical formula C₂₀H₁₃N₃O₃ (Molecular weight 343.33). Violacein is almost insoluble in water but soluble in acetone, ethanol and dioxane.

The structural formula for violacein was determined by NMR spectrometric studies found as follows:

Violacein can continue to cha by its UV / VIS absorption spectrum in methanol be characterized:

λ _max = 570 nm; λ _min = 426 nm; λ _max = 366 nm.

For comparison, the absorption spectrum of the minor constituent deoxyviolacein:

λ _max = 560 nm; λ _min = 434 nm; λ _max = 370 nm.

It is also known that raw violacein has a bacteriostatic effect (see Lichtstein et al., J. of Infect., Dis., 76, No. 1, 47 (1945); De Moss in Antibiotics, Vol. 2, page 77 Ed: D. Gottlieb and P.D. Shaw, Springer 1967).

Recent studies have shown that the isolated crude pigment fraction in several individual components can be separated, the structurally related verbin However, the respective individual compounds a clear different solubility behavior as well as different antibacterial Own effects. See, for example, N. Duran et. al, An. Acad. brasil. Cienc., 55 (3), 231 (1983).

However, antiviral activity is not yet available for raw violacein known for one of the individual components.

Surprisingly, it has now been found that Violacein from Chromobacterium viola ceum has a good antiviral activity against DNA and RNA viruses.

1. Preparation of the crude product

Raw Violacein may be obtained from cultures of Chromobacterium violaceum, Janthinobacterium lividum and Chromobacterium livium.

The bacteria used as starting material can be solid or liquid Culture media, for example according to that described by P.H. A. Sneath Method [P. H. A. Sneath, J. Gen. Microbiol. 15, 70-98 (1956)]. Preferably The bacteria are bred in liquid nutrient media as they are from the nutrient medium can be easily separated by centrifugation. For breeding on solid Nutrient media is a medium of the following composition:

Meat Extract: | 3.0 g Peptone from meat: 5.0 g agar: 18.0 g Aqua dest .: 1000 ml pH 7.5

The bacterial lawn grown after incubation is detached and freeze-dried. Extraction of the raw violacein is done with ethanol in Soxhlet. The ethanol is distilled off in vacuo.

For breeding in liquid cultures different nutrient media are suitable. As op Timal for bacterial growth and pigment yield, the following medium has proved:

Casein peptone: | 7.8 g / l Glucose: 1.0 g / l Saline: 5.6 g / l pH 6.3

This medium is for fermenter cultures as well as for stand or Schüttelkul suitable.

In the culture in the fermenter, both the batch and the semikontinuierli operation.

After harvesting the cultures, the liquid phase is separated and the dye extractively isolated from the sediment.

2. Purification of Violacein

To isolate violacein, the crude violacein is extracted twice with n-Hep tan and filtered off. The residue is dissolved in a mixture of chloro form / acetone / pyridine 50:40:10 and separates the dye mixture by means of silica gel Thin layer chromatography on.

In the final chromatogram can be four individual fractions with the following charac Identify teristika:

• a) a blue zone with R _f 0.58
• b) a pale blue colored zone with R _f 0.2
• c) a deep Prussian blue to violet zone with R _f 0.64
• d) a pale violet zone with R _f 0.71.

The zone (c), which appears deep Prussian blue on the plate, corresponds Violacein and the zone (d), which stained pure purple on the damp DC plate appears, corresponds to deoxyviolavein.

For further purification, dissolve the silica gel in the zone of violacein and / or deoxyviolacein and elutes the dye with chloroform / methanol 50:50 for violacein and chloroform or chloroform / methanol 80:20 for deoxyvio lace in.

After evaporation of the solvent in vacuo, the residue is purified again by TLC chromatography, with the solvent mixture chloro form / acetone / pyridine 50: 50: 10 for violacein and chloroform / acetone / pyridine 60:30:10 for deoxyviolacein.

The silica gel is again dissolved in the area of the corresponding zones, eluted the dye with chloroform / methanol 50:50 for violacein and chloroform / methanol 80:20 for deoxyviolacein and the solvent is removed by evaporation in vacuo vacuum at 35 ° C bath temperature. The residue is taken up in a little pyridine. to closing the pyridine is removed in a vacuum desiccator over concentrated Sulfuric acid. The black-violet residue is dried at 65 ° C in a vacuum.

3. Antiviral activity

The test of the virustatic effect is carried out with virus-infected animal Cell cultures in a color test as described by Finter (J.G. Virol. 5, 419 (1969)) wrote. The test is based on the fact that the cells destroyed by the viruses can not be colored anymore. The more cells by the virustatic effect a substance will be protected so the more dye is bound. The color Substance can be extracted from the stained cells, and its amount can in egg nem photometer z. B. when using crystal violet at 546 nm. Thus, the test allows measurable and reproducible information both on the viru static, as well as by parallel experiments with cell cultures without viruses on the cytotoxic effect of substances.

5 mg of violacein were dissolved in 100 ml of ethyl alcohol. Using the medium for cell culture, a concentration of 0.25 μg / ml violacein was adjusted. This solution is further diluted in two stages and relied on 24-hour-old helicopters. Cells are given these after 45 minutes to infection with a Sus  pension of herpes simplex viruses had been overlaid. To check the Cytotoxicity are parallel approaches without virus addition analogous with the various covered by dilution levels of the test substance. The experimental approaches with Virus and Violacein or only Violacein are incubated at 37 ° C for 72 hours. to closing the cells are fixed and stained for 15 minutes. After rinsing with Water, the dye bound to the cells is extracted with ethanol and in measured the absorbance at 546 nm (crystal violet) on a photometer. The ent corresponding results are given in Table I. Absorbance at 50% Cell protection (ZK + VK) / 2 is 0.355. A concentration of 0.198 μg / ml Viola cein causes a cell protection of 50%.

TABLE I Determination of the antiviral activity against herpes simplex viruses in Hela cell cultures

Since the violacein has no significant cytotoxic property, its Antiviral protective effect in percent can also be calculated according to the following formula:

E₃ = extinction of the cell control, E₂ = extinction of the virus control, E₃ = Ex of the experimental preparations with virus and violacein.

The results of this evaluation are given in Table II.  

Table II: Cell protection (%) of violacein in Hela cell cultures against herpes simplex viruses

With the same experimental arrangement (see above), the effect of violacein against Polio viruses are determined. The investigation for poliovirus type I revealed the in Table III values for cell protection in Hela cells.

Table III: Cell protection (%) of violacein in Hela cell cultures against polio viruses

The above results show that violacein has excellent virustati properties that are of use in therapy and prophylaxis, especially for herpes and poliovirus infections, as beneficial to let.

Claims (11)

1. Use of violacein for the treatment of viral diseases. 2. Use according to claim 1, characterized in that the virus Herpes virus is. 3. Use according to claim 1, characterized in that the virus Poliovirus is. 4. Use according to one of the preceding claims, characterized records that violacein from the suspension culture of a to form this Pigmentes capable of bacterium, preferably Chromobacterium violaceum, iso is liert. 5. Use according to claim 4, wherein the cultivated Chromobakterium violaceum in a ventilated fermenter be with turbulent mixing, characterized in that

• (i) the fermentation is carried out batchwise with a culture time of 5-7 days,
• (ii) the temperature in the culture is between 20-25 ° Celsius,
• (iii) the medium used is a nutrient solution of peptone, glucose and saline,
• (iv) keeping the pH of the culture broth between 6 and 7.

6. Use according to claim 4, in which one cultivates Chromobakterium violaceum in a ventilated be fermenter under turbulent mixing, characterized in that

• (i) the fermentation is semicontinuous with a harvest cycle of 3-6 days,
• (ii) the temperature in the culture is between 20-25 ° Celsius,
• (iii) the medium used is a nutrient solution of peptone, glucose and saline,
• (iv) keeping the pH of the culture broth between 6 and 7.

7. A process for isolating the native Violaceins (mixture of Violacein with up to 10% deoxyviolacein) from suspension cultures according to claim 5 or 6, characterized in that one

• (i) the suspension is reduced to less than 10% of the initial volume by microfiltration,
• (ii) the thickened suspension is dried, preferably by spraying or freeze-drying,
• (iii) extracting the dry product with a suitable solvent, preferably THF or sioxane,
• (iv) concentrating the extract according to 7 (iii) by means of distillation or vacuum evaporation,
• (v) the concentrate of 7 (iv) is added with water to precipitate the violacein,
• (vi) filtering off the precipitate formed,
• (vii) separating impurities by treatment of the precipitate with suitable non-polar organic solvents, preferably chloroform,
• (viii) performs a final purification by recrystallization from suitable organic solvents, preferably THF or dioxane.

8. A method for isolating the native Violaceins (mixture of Violacein with up to 10% deoxyviolacein) from suspension cultures according to claim 5 or 6, as gekennkeichnet that one

• (i) separating the bacteria and the pigment from the cell medium by centrifugation,
• (ii) drying the sediment preferably by spray drying or freeze drying,
• (iii) extracting the dry product with a suitable solvent, preferably THF or dioxane,
• (iv) concentrating the extract of 8 (iii) by distillation or vacuum evaporation.
• (v) the concentrate of 8 (iv) is added with water to precipitate the violacein,
• (vi) filtering off the precipitate formed,
• (vii) separating impurities by treatment of the precipitate with suitable non-polar organic solvents, preferably chloroform,
• (viii) performs a final purification by recrystallization from suitable organic solvents, preferably THF or dioxane.

9. A process for isolating the native Violaceins (mixture of Violacein with up to 10% deoxyviolacein) from suspension cultures according to claim 5 and 6, characterized in that one

• (i) the bacteria and the pigment acc. Enriches 7 (i) or 8 (i),
• (ii) extracting the thickened suspension with a suitable solvent, preferably THF or dioxane,
• (iii) removing the solid, insoluble constituents by filtration or centrifugation,
• (iv) concentrating the extract of 9 (iii) by distillation or vacuum evaporation,
• (v) the concentrate of 9 (iv) is added with water to precipitate the violacein,
• (vi) filtering off the precipitate formed,
• (vii) separating impurities by treatment of the precipitate with suitable non-polar organic solvents, preferably chloroform,
• (viii) performs a final purification by recrystallization from suitable organic solvents, preferably THF or dioxane.

10. A process for the isolation of Violacein from Chromobacterium violaceum, in which the bacteria are separated by centrifugation from the medium, the lyo philionized sediment, isolated therefrom by ethanol extraction Roh-Violacein, characterized in that one for the isolation of Violacein

• (i) extracting the crude violacein twice with n-heptane,
• (ii) subjecting the residue to a TLC chromotography with the solvent mixture chloroform / acetone / pyridine 50: 40: 10,
• (iii) stripping the zone with an R _f of 0.64, eluting the dye with a mixture of chloroform / methanol 80:20 or 50:50, and subjecting the substance to a second TLC plot as in step (ii) described in U.S. Pat this chromatogram contained zone with the R _f 0.64 again separates and isolated as described above, then
• (iv) the solvent is removed, the residue is taken up in pyridine and the pyridine is evaporated off in vacuo over sulfuric acid and the residue is dried at 65 ° C. in vacuo.

11. A process for the isolation of deoxyviolacein from Chromobacterium violaceum, in which the bacteria are separated from the medium by centrifugation, lyophilized the sediment, isolated therefrom by ethanol extraction Roh-Violacein, characterized in that one for the isolation of deoxyviolacein

• (i) extracting the crude violacein twice with n-heptane,
• (ii) subjecting the residue to a TLC chromotography with the solvent mixture chloroform / acetone / pyridine 50: 40: 10,
• (iii) dissolving the zone with an R _f of 0.71, eluting the dye with chloroform, and subjecting the substance to a second TLC plot as in step (ii), the R _f 0.71 zone contained in this chromatogram again detached and isolated as described above, then
• (iv) the solvent is removed, the residue is taken up in pyridine and the pyridine is evaporated off in vacuo over sulfuric acid and the residue is dried at 65 ° C. in vacuo.