Chrysospermins, active peptides from apiocrea chrysosperma having a pharmacological effect and a use thereof

The invention relates to the active peptides chrysospermins, which are synthesized during fermentation by the fungus Apiocrea chrysosperma and accumulate in the culture broth, to a process for their preparation, to the use of the chrysospermins as pharmacological active compounds, in particular as an active compound against bacteria, fungi and/or nematodes as well as for the treatment of rejection reactions in organ transplantations and of neoplastic disorders, and to the microorganism Apiocrea chrysosperma DSM 7444.
Peptides possessing up to 20 amino acids, some of which are structurally unusual, are produced by bacteria and fungi by way of their secondary metabolism using nonribosomal peptide synthetases. Many of the previously known secondary metabolites having a peptide structure possess interesting biological effects as antibiotics, enzyme inhibitors, cardiotonic agents, immunomodulators, insecticides, nematocides, etc. (see, e.g., Grafe, U. Biochemie der Antibiotika (Biochemistry of Antibiotics), Spektrum Heidelberg, 1992; Sasaki et al., J. Antibiot., 45, 692 to 697, 1992; Hamano et al., J. Antibiot., 45, 899 to 905, 1992; Tomoda et al., J. Antibiot., 45, 1207 to 1215, 1992.
Pharmacologically active secondary metabolites can be detected with the aid of biological screening processes; for example, the formation of pigments can be stimulated in strains of the genus Phoma. (Hubner, R.; Schlegel, B.; Fleck, W. F.: Fungal cells as screening models for microbial metabolites affecting differentiation; p. 90 in: Abstracts of 2nd International Bioactive Metabolites from Microorganisms, May 2 to 7, 1988 Gera, FRG).
Within the structural class of the active peptides, the so-called peptaibols (peptaibophols in the presence of phenylalaninol as the C-terminal substituent) are notable for the fact that they contain an unusually large number of amino acids (up to 20, including a high proportion of alpha-aminoisobutyric acid) (Bruckner, H., Konig, W. A., Greiner, M., Jung, G. Angew. Chem. Int. Ed. Engl. 18 (1979), 476 to 477).
Some representatives of the peptaibophols of the alamethicin/suzukacillin type (alamethicins, suzukacillin, paracelcins, hypelcin, trichotoxin, antiamoabin, emerimycin, cerexins, zervamicin and trichorzianins) have been demonstrated to possess antibacterial, antifungal, antiprotozoal and nematocidal activities, as well as antitumorigenic, antiinflammatory, hemolytic and antihelmintic effects, and to promote the formation of helically organized ion channels in biological membranes. (Gale, E. F. et al. in: The Molecular Basis of Antibiotic Action J. Wiley, N.Y., Sydney, Toronto; 1981; Bycroft, B. W.: Dictionary of Antibiotics and Related Substances Chapman and Hall, London, N.Y. 1988).
However the previously known active peptides often possess disadvantages which are expressed in the form of an unsatisfactory level of efficacy, in a high level of toxicity and/or in undesirable side effects.
To date, there are few descriptions of active peptides possessing up to 20 amino acids, some of which are unusual, having effects as antitumorigenic agents. Many of the known antitumorigenic agents give rise, as side effects during therapy, to nausea, vomiting and diarrhoea which also necessitate medical treatment in hospital. In addition, these pharmaceuticals also alter the speed of growth of other cells occurring in the body, leading in turn to symptoms such as, for example, loss of hair or anemia. It is also not previously known to employ these peptides as active compounds or pharmaceuticals for the treatment of rejection reactions. In 1990, 15,000 organ transplantations were carried out in the USA. The majority of the transplantations concerned the kidney, but heart, skin, lung, liver and pancreas are also being transplanted to an increasing degree. In many of the patients receiving transplants, a rejection reaction occurs in the body against the organ which has been transferred from another person. Three forms of rejection reaction are distinguished: i.e. hyperacute, acute and chronic rejection.
Hyperacute rejection is in the main brought about by antibodies circulating in the blood, which antibodies are directed against the tissue of the transferred organ (transplant) and lead in a very short space of time--frequently in minutes--to necroses in the transplant.
The object of the invention is to seek novel microbial active peptides possessing improved properties and novel mechanisms of effect.
In accordance with the invention, this object is achieved by fermenting Apiocrea chrysosperma in a nutrient solution containing carbon and nitrogen sources and the customary inorganic salts until the chrysospermin active peptides accumulate in the culture, and then isolating the chrysospermins from the culture broth and, where appropriate, fractionating the chrysospermins into chrysospermins A, B, C and D. The active peptides possess pharmacological activity and can be employed, in particular, as active compounds against bacteria, fungi and/or nematodes, as well as for the treatment of rejection reactions associated with organ transplantations and of neoplastic disorders.
The invention consequently relates to:
1. A compound of the formula I
AcPhe-Aib-Ser-Aib-x-Leu-Gln-Gly-Aib-Aib-Ala-Ala-Aib-Pro-y-Aib-Aib-Gln-Trp-ol (SEQ ID NO: 1)
in which x and y, independently of each other, denote Aib or Iva.
2. A process for the preparation of a compound of the formula I, wherein Apiocrea chrysosperma is cultivated in a nutrient medium until a compound of the formula I accumulates in the culture broth, and this compound is isolated from the culture broth.
3. A use of a compound of the formula I as a pharmacologically active compound.
4. Apiocrea chrysosperma DSM 7444.
The invention is described in detail below, in particular in its preferred embodiments. In addition, it is determined by the content of the patent claims.
Terms and abbreviations are defined as follows:
Compounds of the formula I are also designated chrysospermins or active peptides.
The nutrient medium containing the fungal mycelium which has grown in it is designated the culture broth.
AcPhe stands for N-acetylphenylalanine, Aib stands for .alpha.-aminobutyric acid, Iva stands for isovaline and Trp-ol stands for tryptophanol.
Chrysospermin A (1896 Daltons) denotes a compound of the formula I in which Aib is present at positions x and y.
Chrysospermin B (1910 Daltons) denotes a compound of the formula I in which Aib is present at position x and Iva is present at position y.
Chrysospermin C (1910 Daltons) denotes a compound of the formula I in which Iva is present at position x and Aib is present at position y.
Chrysospermin D (1924 Daltons) denotes a compound of the formula I in which Iva is present at positions x and y.
The term organ is understood to mean all the organs in mammals, in particular those of man, for example kidney, heart, skin, liver, pancreas, muscle, bone, intestine or stomach, as well as blood or hair.
Rejection reactions mean all the defensive measures of the recipient organism which lead in the end to destruction of the cells or tissue of the transferred organ or which impair the viability of the transferred organ.
Chrysospermins are produced by Apiocrea chrysosperma, preferably Apiocrea chrysosperma DSM 7444.
Apiocrea chrysosperma (older designation Hypomyces chrysospermus, in: Compendium of Soil Fungi, K. H. Domsch, W. Gams and T.-H. Anderson (eds.) Academic Press, vol. 1, 398 to 399) is very widespread in temperate climatic zones as a parasitic microorganism in the fruiting bodies of Boletales and is obtained from soil samples. Morphologically, the anamorphic form of Apiocrea chrysosperma sperma is notable for
branched conidiophores,
yellowish, round, occasionally also blastic, conidia, which occur in large numbers
wart-shaped or spiny conidia possessing a thick, multilayered wall.
Pure cultures can be isolated from such soil samples by methods familiar to the person skilled in the art by setting up dilution series, and plating out and incubating on nutrient agar media.
Using sequential isolation steps, a fungal colony can be isolated from Apiocrea chrysosperma which very efficiently accumulates the chrysospermin active peptides in the culture broth.
The strongly-producing fungal colony is propagated. An isolate of Apiocrea chrysosperma DSM 7444 was deposited with the Deutsche Sammlung von Mikroorganismen und Zellkulturen GmbH (German collection of microorganisms and cell cultures), Marschroder Weg 1B, 3300 Braunschweig, Germany, in accordance with the stipulations of the Budapest treaty of the 28.01.1993.
When cultivated on agar nutrient bases containing glucose and malt extract as the carbon source and yeast extract as the nitrogen source, the mycelium of the fungus is white after 14 days of incubation at 25.degree. C., and then subsequently golden yellow, with conidia of a truncated wart shape being present. The teleomorphic form is not produced in the culture.
Apiocrea chrysosperma, preferably Apiocrea chrysosperma DSM 7444, produce active peptides of the general formula I in a nutrient medium containing a carbon source, a nitrogen source and the customary mineral salts. Instead of the strain itself, mutants and variants of Apiocrea chrysosperma DSM 7444 can naturally also be employed.
All those microorganisms of the species which are able to synthesize the chrysospermin active peptides are regarded as mutants and variants.
Such mutants can be produced, in a manner known per se, by physical means, for example by irradiation with ultraviolet or X-rays, or with chemical mutagens, such as, for example, ethyl methanesulfonate (EMS), 2-hydroxy-4-methoxybenzophenone (MOB) or N-methyl-N'-nitro-N-nitrosoguanidine (MNNG).
Screening for mutants and variants which synthesize a compound of the general formula I is effected by determining pigment formation in test organisms of the genus Phoma, preferably Phoma sp., particularly preferably Phoma destructiva, which formation is stimulated by the active peptides of the general formula I which are secreted into the supernatant.
Alternatively, the biological activity of the active peptides secreted into the supernatant can also be assessed by testing their antibiotic effects on known test organisms using methods familiar to the person skilled in the art.
Carbohydrate-containing natural products, such as malt extract, as well as assimilable carbohydrates and alcohols, such as, for example, glucose, lactose and glycerol, or their mixtures in arbitrary proportions, are suitable for use as preferred carbon sources for the aerobic fermentation.
Amino acids, peptides and proteins, as well as their degradation products such as tryptones or peptones, are suitable for use as the nitrogen source as are meat extracts, ground seeds, for example from corn, wheat, beans, soya bean or the cotton plant, distillation residues from the preparation of alcohol, meat meals or yeast extracts, as well as ammonium salts and nitrates.
The formation of a compound of the general formula I is effected particularly favorably in nutrient media which contain 0.2 to 6% of malt extract, preferably 2 to 4% of malt extract, and 0.01 to 1% of yeast extract, preferably 0.1 to 0.4% of yeast extract.
Cultivation is effected aerobically, for example in a submerged manner with shaking and stirring in shaking flasks, preferably, however, on the surface as a stationary culture. It is carried out in a temperature range of between 15.degree. and 35.degree. C., preferably of between 23.degree. and 33.degree. C., particularly preferably of between 27.degree. and 30.degree. C.
The pH is between 4 and 7, preferably between 5.5 and 6.5.
The microorganism is cultivated under these conditions for 5 to 21 days, preferably 7 to 18 days.
The fermentation can be carried out on a laboratory scale (culture volumes of between 100 ml and 200 l) as well as on a production scale (volumes of up to several m.sup.3).
Advantageously, the cultivation is carried out in several steps, i.e. one or more precultures are first prepared in a liquid nutrient medium, which precultures are then inoculated into the actual production medium, the main culture, for example in the ratio 1:20.
The preculture is obtained by transferring a sporulated mycelium from malt agar nutrient bases, for example, into a nutrient solution, for example by inoculating agar pieces which are overgrown with mycelium, and then incubating these pieces for 11 to 21 days, preferably 15 to 18 days.
The sporulated mycelium can be obtained, for example, by allowing the strain to grow for about 11 to 21 days, preferably 15 to 18 days, on a solid nutrient base, e.g. malt agar.
The course of the fermentation and the appearance of the active peptides can be monitored in accordance with chromatographic methods which are known to the person skilled in the art, such as, for example, thin layer chromatography (TLC) or high performance liquid chromatography (HPLC), or by testing the biological activity towards test organisms.
The active peptides of general formula I are contained in the culture broth, preferably in the mycelium.
The active peptides are isolated from the culture medium by known methods, taking into account the chemical, physical and biological properties of the products.
Thin layer chromatography, for example on silica gel using chloroform/methanol mixtures as the eluent, can be used for testing the concentration of active compound in the culture medium or in the individual isolation steps. In the thin-layer chromatographic fractionation, detection can take place, for example, by means of coloring reagents, such as 2% vanillin/conc. sulfuric acid.
In order to isolate the active peptides, the culture broth and mycelium are extracted at the end of the fermentation once to five times, preferably three times, with organic lipophilic solvents, such as ethyl acetate and butyl acetate or dichloromethane, preferably ethyl acetate.
After concentrating the extract and precipitating out the chrysospermins A, B, C and D with aliphatic hydrocarbons such as n-hexane or n-heptane, the chrysospermins are separated chromatographically using customary chromatographic adsorbents and carrier materials, such as, for example, silica gels or organophilic dextran gels. The sequential use of column chromatography on silica gel or gel chromatography on organophilic dextran gels results in a mixture of chrysospermins A, B, C and D (molar masses 1896, 1910, 1910 and 1924 Daltons, respectively). Fractionation into the individual components is effected by means of preparative high performance liquid chromatography (HPLC).
The chemical identity of the chrysospermin active peptides A, B, C and D, which are formed by Apiocrea chrysosperma, preferably Apiocrea chrysosperma DSM 7444, is confirmed unequivocally by chemical degradation and analysis of the amino acids which have been formed, by mass spectroscopy (FAB-MS, electrospray-MS, MS-MS) and by NMR investigations.
The antibacterial and/or antifungal effects can be demonstrated invitro by methods known to the person skilled in the art, such as, for example, inhibitory halo tests or plate-diffusion tests.
A compound of the general formula I is effective against Gram-positive bacteria, e.g. Bacillus subtilis ATCC 6633 and Saphylococcus aureus, as well as against yeasts, e.g. Klyveromyces marxianus or filamentous fungi, e.g. Glomerella cingulata, as well as against Gram-negative bacteria, e.g. Klebsiella pneumoniae.
The minimal inhibitory concentration is within the range from >0.05 to <20 .mu.g/punched hole.
A nematocidal effect can likewise be demonstrated by an in-vitro test, in which replication and mobility of the nematodes is determined. The chrysospermin active peptides are effective against nematodes, e.g. Caenorhabditis, in quantities >10 .mu.g/ml.
As a further characteristic, chrysospermins induce the formation of brown pigments in Phoma sp. in the agarplate diffusion test when present in concentrations of >10 .mu.g/punched hole.
In addition, the chrysospermins exhibit inhibition of the formation of allophilic or xenophilic antibodies. This provides the possibility of treating hyperacute, acute and chronic rejection reactions of the recipient against the transplanted organ in an effective manner.
The compounds of the formula I and their physiologically tolerated salts are particularly suitable for treating a multiplicity of cancerous disorders. Those types of cancer which are particularly inhibited by these compounds include, for example, leukemia, in particular chronic leukemia of the T-cell and B-cell types, lymph node cancer, e.g. Hodgkin's or non-Hodgkin's lymphoma, carcinomas, sarcomas or skin cancer. The active compounds can either be administered on their own, for example in the form of microcapsules, in mixtures with each other, or in combination with suitable auxiliary and/or carrier substances.
These symptoms, which are known from the state of the art, cannot be observed when humans and animals are treated with the compounds of the formula I. In contrast to the previously known cytotoxic anti-cancer agents, these active compounds do not have the property of impairing the immune system (Bartlett, Int. J. Immunopharmac., 1986, 8: 199 to 204). This consequently opens up novel approaches to tumor therapy, since the body's own defence system is not impaired whereas the growth of tumor cells is prevented.
The invitro proliferation test with cell cultures is used as the test for the efficacy of chemotherapeutic agents.
Owing to their valuable pharmacological properties, chrysospermins are very suitable for use as pharmaceuticals.
A compound according to the invention, or its salts, can in principle be administered as the substance itself. Its use in admixture with suitable auxiliary agents or carrier materials is preferred. In the case of veterinary pharmaceuticals, the customary feedstuff mixtures can be used as carrier materials, as can all pharmacologically tolerated carrier materials and/or auxiliary substances in the case of humans.
Alkali metal, alkaline earth metal and ammonium salts, including those of organic ammonium bases, are examples of suitable physiologically tolerated salts of the compound of the formula I.
The use also relates to pharmaceutical preparations of the chrysospermins.
The pharmaceuticals according to the invention are generally administered orally or parenterally, but rectal use is in principle also possible. Suitable solid or liquid pharmaceutical preparation forms are, for example, granules, powders, tablets, coated tablets, (micro) capsules, suppositories, syrups, emulsions, suspensions, aerosols, drops or injectable solutions in ampoule form, and preparations with protracted release of the active compound, in association with the preparation of which carrier substances and additives and/or adjuvants such as disintegrants, binders, coating agents, swelling agents, glidants, lubricants, flavorants, sweeteners or solubilizers are customarily employed. Frequently used carrier or auxiliary substances which may be mentioned are, for example, magnesium carbonate, titanium dioxide, lactose, mannitol and other sugars, talc, lactalbumin, gelatin, starch, vitamins, cellulose and its derivatives, animal and vegetable oils, polyethylene glycols, and solvents, such as, for example, sterile water, alcohols, glycerol and polyhydric alcohols.
In addition, a compound according to the invention can be given in combination with further active compounds which have an identical or related mode of action. In the case of rejection reactions, for example, these are antiuricopathic agents, inhibitors of blood platelet aggregation, analgesics and steroidal or nonsteroidal antiinflammatory agents.
Where appropriate, the dosage units for oral administration can be microencapsulated, in order to delay release or to extend it over a relatively long period of time, for example by coating or by embedding the active compound in particulate form in suitable polymers, waxes or the like.
Preferably, the pharmaceutical preparations are produced and administered in dosage units such that each unit contains, as the active constituent, a specified dose of the chrysospermins. In the case of solid dosage units, such as tablets, capsules and suppositories, this dose can amount to up to about 200 mg, preferably, however, about 0.1 to 100 mg, per day, and, in the case of injection solutions in ampoule form, up to about 200 mg, preferably, however, about 0.5 to 100 mg, per day.
The daily dose to be administered depends on the body weight, age, sex and condition of the mammalian subject. However, higher or lower daily doses may sometimes be appropriate. The daily dose may be administered either uniquely in the form of a single dosage unit or else in several smaller dosage units or by the repeated administration of subdivided doses at predetermined intervals.
Finally, in association with the production of the abovementioned pharmaceutical preparation forms, the peptides of the formula I and/or at least one of their physiologically tolerated salts can also be formulated together with other suitable preparation forms and together with other suitable active compounds, for example other antitumor agents, immunoglobulins, monoclonal antibodies, immunostimulatory agents or antibiotics. These compounds can also be administered as an accompaniment to radiation therapy.
The pharmaceuticals according to the invention are produced by bringing one or more compounds of the formula I into the and/or a suitable form for administration using customary carrier substances and, where appropriate, additives and/or auxiliary substances.

EMBODIMENT EXAMPLES
The invention will now be illustrated in more detail by means of the following embodiment examples.
1. a) Preparation of a sporulated mycelium of the strain Apiocrea chrysosperma DSM 7444
In order to prepare a sporulated mycelium, Apiocrea chrysosperma DSM 7444 is incubated at 25.degree. C. for 15 days on nutrient bases (4% malt extract, 0.4% yeast extract, 1.5% agar sterilization at 110.degree. C. for 35 min; pH 6.0).
b) Preparation of an emersed (surface) stationary culture or preculture of Apiocrea chrysosperma DSM 7444 in Erlenmeyer flasks
In order to set up emersed stationary cultures, agar pieces from the agar culture mentioned in Example 1a, each of which is 2 cm.sup.2 in size and overgrown with mycelium, are inoculated into 500 ml Erlenmeyer flasks each of which contains 100 ml of liquid nutrient medium. The nutrient medium has the following composition (g/l): malt extract, 20 glucose, 10; yeast extract, 2; (NH.sub.4).sub.2 HPO.sub.4, 5; distilled water, pH 6.0 (sterilization at 110.degree. C. for 25 min). After incubating for 15 days at 28.degree. C., the content of chrysospermins in the stationary culture has reached its maximal value.
c) Preparation of submerged shaken cultures of Apiocrea chrysosperma DSM 7444
Cultures set up in 500 ml Erleumeyer flasks as in Examples 1a and 1b are shaken in a shaking incubator at 28.degree. C. and 90 revolutions/min for 5 days. 5 ml of each of these precultures is used for inoculating the main culture. This is effected, once again, in 500 ml Erlenmeyer flasks containing 100 ml of malt extract medium, as described under Example 1b, by fermenting at 28.degree. C. and at 90 revolutions/min for 7 days in a shaking incubator.
2. Preparation and purification of the chrysospermin active peptides
15-day old 5 l stationary cultures are stirred, in each case overnight, with 3.times.1 l of ethyl acetate the combined ethyl acetate extracts are dried over sodium sulfate and concentrated down to a volume of 50 ml. The major portion of the chrysospermins is subsequently precipitated out by adding 500 ml of n-hexane. The precipitate (about 750 mg) which has formed after the mixture has been left to stand at 4.degree. C. overnight is purified by column chromatography on silica gel 60 (pore diameter: 0.01 to 0.02 mm) using chloroform and chloroform/methanol (8:2; v/v) sequentially. The fractions containing chrysospermins are identified by their inhibitory effect on Bacillus subtilis ATCC 6633 and by the fact that they are characteristically stained red on a thin layer chromatogram by a solution of 2% vanillin in conc. sulfuric acid. Yield: 250 mg. Further purification can be effected by repeating the column chromatography on silica gel 60 and by chromatography on Sephadex LH-20 (using methanol as the eluent).
3. Chromatographic fractionation of the chrysospermins
Further purification, and fractionation of the chrysospermins into the individual components A and B as well as C and D, and into the individual components A to D, is effected by repeated preparative high performance liquid chromatography using silica gel RP 18 as the carrier material and acetonitrile/water mixtures as eluents. 10 mg of the product obtained in accordance with Example 2 are dissolved in 1 ml of methanol and loaded on an RP18 HPLC column (250.times.20 mm ID). Elution is carried out isocratically using acetonitrile/water (50:50 v/v) at a flow rate of 25 ml/min. The separated components are detected at 220 run.
In the first separatory phase, the constituent complexes A+B (retention time 20 min) and C+D (retention time 30 min) are obtained. The eluates, which are collected separately, are concentrated down to the aqueous phase on a rotary evaporator and then lyophilized.
12 mg of chrysospermin A+B and 58 mg of chrysospermin C+D are obtained from 100 mg of crude product employed.
Further fractionation into the components A to D is achieved by renewed preparative HPLC of the constituent complexes A+B and C+D under the conditions given above.
4. Physicochemical properties of the chrysospermins
Appearance: colorless crystalline substance
Chromatographic behavior (TLC, silica gel-aluminum foil Merck): R.sub.f 0.3 to 0.4 (chloroform/methanol 7:3)
Staining by chromatographic detection reagents: 2% vanillin/conc. sulfuric acid: carmine red staining
Ninhydrin: weak staining
Amino acids in the hydrolysate: Ala, Aib, Leu, Gly, Glu, Pro, Ser, Phe and two further components (Iva, Trp-ol) (detection by GC-MS)
FAB-MS: Mol peaks m/z 1897 (M.sup.+ +H.sup.+); 1911 (M.sup.+ +H.sup.+), 1925 (M.sup.+ +H.sup.+).
5. Influence of substances on the mitogen-induced proliferation of spleen lymphocytes
The following abbreviations are used:
AV=Average value
Units=Units
SD=Standard deviation
Con A=concanavalin A
LPS=Lipopolysaccharide
PWM=Pokeweed mitogen
SI=Stimulation index
Chryso=Chrysospermin
SS=Stock solution
Basic medium
Click's medium/RPMI 1640 medium (50:50) containing L-glutamine without NaHCO.sub.3 in powder form for 10 l (Seromed, Biochrom, Berlin, FRG) is dissolved in 9 l of doubly distilled water and filtered sterile in 900 ml volume bottles.
Washing medium
900 ml of basic medium are buffered with 9.5 ml of 7.5% strength sodium hydrogen carbonate solution and 5 ml of HEPES (N-2-hydroxyethylpiperazine-N-2-ethanesulfonic acid) (Gibco, Eggenstein, FRG).
Working medium
900 ml of basic medium plus 19 ml of NaHCO.sub.3 solution (7.5%; 10 ml of HEPES solution and 10 ml of L-glutamine solution (200 mM)).
Medium for the mitogen-induced proliferation of lymphocytes:
Working medium is charged with 1% of heat-inactivated (56.degree. C., 30 min) fetal calf serum (FCS).
Isolation and processing of the spleen cells for the mitogen-induced proliferation of lymphocytes
The mice are killed by cervical dislocation and the spleens are removed under sterile conditions. The spleens are cut up on a sterile sieve having a mesh grade of 80 and are strained carefully into a Petri dish containing working medium using the piston of a plastic syringe (10 ml). To remove the erythrocytes from the spleen cell suspension, the mixture is incubated at room temperature for about 1 minute, and with occasional shaking, in hypotonic, 0.17M ammonium chloride solution. Under these conditions, the erythrocytes are lysed, whereas the vitality and reactivity of the lymphocytes are not affected. After centrifugation (7 min/340 g), the lysate is discarded and the cells are washed twice, taken up in the test medium, and adjusted to a cell density of 5.times.10.sup.6 cells/ml.
Test sample
The proliferation test is carried out in flatbottomed microtiter plates, the total volume per well being 200 .mu.l.
Formula I and mitogens are dissolved in test medium and diluted to the desired concentration. 50 .mu.l each of formula dilution and mitogen dilution are introduced into the wells (in the test, the values are determined four times) and 100 .mu.l of the spleen cell suspension (5.times.10.sup.6 cells/ml) are added. The mitogens bring about proliferation of different lymphocyte populations and are employed in suboptimal to optimal stimulation concentrations as follows:
(Con A) concavalin A: 0.5-0.25-0.12 .mu.g/ml
(LPS) lipopolysaccharide: 1.0-0.5-0.25 g/ml
(PWM) pokeweed mitogen: 0.5-0.25-0.12% stock solution.
The plates are sealed and incubated at 37.degree. C. and 5% CO.sub.2 for 48 h. The degree of proliferation is then determined by radioactively labeling the DNA of dividing cells. For this purpose, 25 .mu.l volumes of tritiated thymidine (from Amersham) having an activity of 0.25 .mu.Ci/well (specific activity 29 Ci/mmol) are added to the wells, and the incubation is continued for a further 16 hours.
In order to evaluate the test, the plates are harvested on glass fiber filters using a cell-harvesting appliance (from Skatron), with unincorporated tritiated thymidine being collected in separate waste bottles and only radioactivity which is cellularly bound (in the DNA) being measured. The filters are subsequently dried, sealed in plastic bags and then enclosed in cassettes after the addition of 10 ml of scintillator (from Pharmacia). Measurement takes place in a beta counter (Beta-plate Plate System 1205 from Wallac).
Calculation
Positive control; Spleen lymphocytes with the different mitogens but without the addition of the substance.
Negative control: Spleen lymphocytes in medium (without stimulant) and without addition of the substance.
Negative control for the preparation groups: Spleen lymphocytes in medium (without stimulant) but with the addition of the substance. The % change in proliferation is calculated in comparison with the positive control, the same concentration of the respective mitogen always being used on each occasion.
The stimulation index provides information on the ability of the cells to be stimulated by comparison with the negative control of the respective preparation group.
__________________________________________________________________________Mitogen Dose Units n AV SD SD in % % change SI__________________________________________________________________________Positive controlCon A 0.5 .mu.g/ml 4 95347 7382 8 0 52.1Con A 0.25 .mu.g/ml 4 51945 6111 12 0 28.4Con A 0.12 .mu.g/ml 3 18408 3777 21 0 10.1LPS 1.0 .mu.g/ml 4 61044 2354 4 0 33.4LPS 0.5 .mu.g/ml 4 44816 1866 4 0 24.5LPS 0.25 .mu.g/ml 4 30710 2205 7 0 16.6PWM 0.5 % SS 4 28193 6757 24 0 15.4PWM 0.25 % SS 4 19343 3952 20 0 10.5PWM 0.12 % SS 4 17912 2073 12 0 9.8Medium 0.0 -- 4 1829 601 33 0 1.0CsA 10 .mu.g/mlCon A 0.5 .mu.g/ml 4 236 174 74 -100 14.7Con A 0.25 .mu.g/ml 4 229 145 64 -100 16.4Con A 0.12 .mu.g/ml 4 36 10 29 -100 2.2LPS 1.0 .mu.g/ml 4 23 2 9 -100 1.4LPS 0.5 .mu.g/ml 4 30 6 19 -100 1.9LPS 0.25 .mu.g/ml 4 19 5 29 -100 1.2PWM 0.5 % SS 4 29 3 9 -100 1.8PWN 0.25 % SS 4 24 1 6 -100 1.5PWM 0.12 % SS 4 33 13 41 -100 2.1Medium 0.0 -- 4 16 4 23 -99 1.0CsA 2 .mu.g/mlCon A 0.5 .mu.g/ml 4 9733 373 4 -90 28.5Con A 0.25 .mu.g/ml 4 3574 367 10 -93 10.4Con A 0.12 .mu.g/ml 4 1405 127 9 -92 4.1LPS 1.0 .mu.g/ml 3 9536 1110 12 - 84 27.9LPS 0.5 .mu.g/ml 4 5274 824 16 -88 15.4LPS 0.25 .mu.g/ml 4 3080 64 2 -90 9.0PWM 0.5 % SS 4 2354 182 8 -92 6.9PWM 0.25 % SS 4 1778 55 3 -91 5.2PWM 0.12 % SS 4 1478 194 13 -92 4.3Medium 0.0 -- 4 342 47 14 -81 1.0CsA 1 .mu.g/mlCon A 0.5 .mu.g/ml 4 11823 507 4 -88 29.3Con A 0.25 .mu.g/ml 4 3673 652 18 -93 9.1Con A 0.12 .mu.g/ml 4 1526 101 7 -92 3.8LPS 1.0 .mu.g/ml 4 13284 1374 10 -78 33.0LPS 0.5 .mu.g/ml 4 6982 699 10 -84 17.3LPS 0.25 .mu.g/ml 4 4832 613 13 -84 12.0PWM 0.5 % SS 4 2964 332 11 -89 7.3PWN 0.25 % SS 4 2156 78 4 -89 5.3PWM 0.12 % SS 4 1925 144 7 -89 4.8Medium 0.0 -- 4 403 19 5 -78 1.0CsA 0.2 .mu.g/mlCon A 0.5 .mu.g/ml 4 18370 579 3 -81 35.5Con A 0.25 .mu.g/ml 4 5766 386 7 -89 11.3Con A 0.12 .mu.g/ml 4 2010 80 4 -89 3.9LPS 1.0 .mu.g/ml 4 23773 4940 21 -61 45.9LPS 0.5 .mu.g/ml 4 16727 670 4 -63 32.3LPS 0.25 .mu.g/ml 4 10136 336 3 -67 19.6PWM 0.5 % SS 4 3928 306 8 -86 7.6PWM 0.25 % SS 4 3085 257 8 -84 6.0PWM 0.12 % SS 4 2430 270 11 -86 4.7Medium 0.0 -- 4 518 48 9 -72 1.0CsA 0.1 .mu.g/mlCon A 0.5 .mu.g/ml 4 20737 1584 8 -78 3.7Con A 0.25 .mu.g/ml 4 5711 465 8 -89 10.4Con A 0.12 .mu.g/ml 4 1938 213 11 -89 3.5LPS 1.0 .mu.g/ml 4 29219 1486 5 -52 53.1LPS 0.5 .mu.g/ml 4 18066 1086 6 -60 32.8LPS 0.25 .mu.g/ml 4 11171 238 2 -64 20.3PWM 0.5 % SS 4 4819 215 4 -83 8.8PWM 0.25 % SS 4 3198 183 6 -83 5.8PWM 0.12 % SS 4 2575 162 6 -86 4.7Medium 0.0 -- 4 550 35 6 -70 1.0Chryso A/B 10 .mu.g/mlCon A 0.5 .mu.g/ml 3 10830 3368 31 -89 12.0Con A 0.25 .mu.g/ml 4 12891 548 4 -75 14.2Con A 0.12 .mu.g/ml 4 8274 1192 14 -55 9.0LPS 1.0 .mu.g/ml 3 6101 457 7 -90 6.7LPS 0.5 .mu.g/ml 4 5697 231 4 -87 6.3LPS 0.25 .mu.g/ml 4 4452 719 16 -86 4.9PWM 0.5 % SS 4 5090 534 10 -82 5.6PWM 0.25 % SS 4 5621 265 5 -71 6.2PWM 0.12 % SS 3 3979 686 17 -78 4.4Medium 0.0 -- 4 905 311 34 -50 1.0Chryso A/B 2 .mu.g/mlCon A 0.5 .mu.g/ml 4 174598 2230 1 83 47.1Con A 0.25 .mu.g/ml 4 129118 2880 2 149 34.8Con A 0.12 .mu.g/ml 4 62937 11224 18 242 17.0LPS 1.0 .mu.g/ml 4 74404 1886 3 22 20.1LPS 0.5 .mu.g/ml 4 58285 1669 3 30 15.7LPS 0.25 .mu.g/ml 4 47409 3056 6 54 12.8PWM 0.5 % SS 4 51533 3863 7 83 13.9PWM 0.25 % SS 4 43847 1837 4 127 11.8PWM 0.12 % SS 4 32537 1237 4 82 8.8Medium 0.0 -- 4 3708 264 7 103 1.0Chryso A/B 1 .mu.g/mlCon A 0.5 .mu.g/ml 4 150893 6464 4 58 36.7Con A 0.25 .mu.g/ml 4 119556 1975 2 130 29.1Con A 0.12 .mu.g/ml 4 60761 3799 6 230 14.8LPS 1.0 .mu.g/ml 4 61155 8047 13 0 14.9LPS 0.5 .mu.g/ml 4 54958 2463 4 23 13.4LPS 0.25 .mu.g/ml 4 44582 1861 4 45 10.8PWM 0.5 % SS 4 53906 3318 6 91 13.1PWM 0.25 % SS 4 42879 1725 4 122 10.4PWM 0.12 % SS 4 31055 1013 3 73 7.5Medium 0.0 -- 4 4114 485 12 125 1.0Chryso A/B 0.2 .mu.g/mlCon A 0.5 .mu.g/ml 4 168295 4045 2 77 50.4Con A 0.25 .mu.g/ml 4 124940 3446 3 141 37.4Con A 0.12 .mu.g/ml 4 67198 8378 12 265 20.1LPS 1.0 .mu.g/ml 4 70965 4476 6 16 21.2LPS 0.5 .mu.g/ml 4 59873 1326 2 34 17.9LPS 0.25 .mu.g/ml 4 44695 660 1 46 13.4PWM 0.5 % SS 4 49539 1364 3 76 14.8PWM 0.25 % SS 4 41145 1357 3 113 12.3PWM 0.12 % SS 4 31056 1722 6 73 9.3Medium 0.0 -- 4 3338 280 8 83 1.0Chryso A/B 0.1 .mu.g/mlCon A 0.5 .mu.g/ml 4 167376 6191 4 76 44.7Con A 0.25 .mu.g/ml 4 134097 6943 5 158 35.8Con A 0.12 .mu.g/ml 4 62049 2175 4 237 16.5LPS 1.0 .mu.g/ml 4 68121 8000 12 12 18.2LPS 0.5 .mu.g/ml 4 61682 2884 5 38 16.5LPS 0.25 .mu.g/ml 4 44654 1859 4 45 11.9PWM 0.5 % SS 4 52551 1348 3 86 14.0PWM 0.25 % SS 4 41341 473 1 114 11.0PWM 0.12 % SS 4 30586 219 1 71 8.2Medium 0.0 -- 4 3747 354 9 105 1.0Chryso C/D 10 .mu.g/mlCon A 0.5 .mu.g/ml 4 219 29 13 -100 4.7Con A 0.25 .mu.g/ml 4 171 35 20 -100 3.7Con A 0.12 .mu.g/ml 4 85 13 15 -100 1.8LPS 1.0 .mu.g/ml 4 47 4 8 -100 1.0LPS 0.5 .mu.g/ml 4 100 37 37 -100 2.2LPS 0.25 .mu.g/ml 4 66 20 30 -100 1.4PWM 0.5 % SS 4 87 17 19 -100 1.9PWM 0.25 % SS 4 61 4 7 -100 1.3PWM 0.12 % SS 4 67 14 21 -100 1.5Medium 0.0 -- 4 46 12 25 -98 1.0Chryso C/D 2 .mu.g/mlCon A 0.5 .mu.g/ml 4 168994 2499 1 77 46.1Con A 0.25 .mu.g/ml 4 127101 3894 3 145 34.7Con A 0.12 .mu.g/ml 4 55318 1539 3 201 15.1LPS 1.0 .mu.g/ml 3 46853 1529 3 -23 12.8LPS 0.5 .mu.g/ml 4 34354 892 3 -23 9.4LPS 0.25 .mu.g/ml 4 26359 1482 6 -14 7.2PWM 0.5 % SS 4 31481 815 3 12 8.6PWM 0.25 % SS 4 26621 3468 13 38 7.3PWM 0.12 % SS 4 19632 690 4 10 5.4Medium 0.0 -- 4 3663 319 9 100 1.0Chryso C/D 1 .mu.g/mlCon A 0.5 .mu.g/ml 4 186499 5377 3 96 46.8Con A 0.25 .mu.g/ml 4 131375 1171 1 153 33.0Con A 0.12 .mu.g/ml 4 62219 4252 7 238 15.6LPS 1.0 .mu.g/ml 4 66784 8884 13 9 16.8LPS 0.5 .mu.g/ml 4 52076 1741 3 16 13.1LPS 0.25 .mu.g/ml 4 38876 1957 5 27 9.8PWM 0.5 % SS 4 57400 12906 22 104 14.4PWM 0.25 % SS 4 37675 1814 5 95 9.5PWM 0.12 % SS 4 31638 2867 9 77 7.9Medium 0.0 -- 4 3981 462 12 118 1.0Chryso C/D 0.2 .mu.g/mlCon A 0.5 .mu.g/ml 4 174176 1882 1 83 37.9Con A 0.25 .mu.g/ml 4 131338 3245 2 153 28.6Con A 0.12 .mu.g/ml 4 62224 3767 6 238 13.5LPS 1.0 .mu.g/ml 4 67510 8444 13 11 14.7LPS 0.5 .mu.g/ml 4 58617 1115 2 31 12.8LPS 0.25 .mu.g/ml 4 47545 1183 2 55 10.3PWM 0.5 % SS 4 56805 2137 4 101 12.3PWM 0.25 % SS 4 43419 1990 5 124 9.4PWM 0.12 % SS 4 30425 2844 9 70 6.6Medium 0.0 -- 4 4596 188 4 151 1.0Chryso C/D 0.1 .mu.g/mlCon A 0.5 .mu.g/ml 4 174085 1944 1 83 40.5Con A 0.25 .mu.g/ml 4 122841 1477 1 136 28.6Con A 0.12 .mu.g/ml 4 61752 5629 9 235 14.4LPS 1.0 .mu.g/ml 4 70069 2049 3 15 16.3LPS 0.5 .mu.g/ml 4 59291 3267 6 32 13.8LPS 0.25 .mu.g/ml 4 42247 1788 4 38 9.8PWM 0.5 % SS 4 55930 2910 5 98 13.0PWM 0.25 % SS 4 47362 1848 4 145 11.0PWM 0.12 % SS 4 30606 5959 19 71 7.1Medium 0.0 -- 4 4295 271 6 135 1.0__________________________________________________________________________
6. Tumor cell proliferation (in vitro):
The proliferation test is carried out in round-bottomed microtiter plates. Tumor cells, originally obtained from the American Type Culture Collection (ATCC), are grown in a permanent stock holding in serum-free medium (CG medium from Vitromex) and are used for the test in their logarithmic phase of growth. The following tumor cell lines are used routinely:
1) A 20.2 J=plasmacytoma
2) 20-10-5S=hybridoma
3) EL4=T-helper cell lymphoma
4) K562=undifferentiated myelomonocytic line
The cells are adjusted in serum-free CG medium to a cell density of 4.times.10.sup.4 cells/ml and 100 .mu.l are pipetted into each well. Formula I is dissolved in CG medium and diluted down to the desired concentration, and 100 .mu.l are added to the cells (total volume, 200 .mu.l containing 4.times.10.sup.3 cells). The respective values are also ascertained by 4-fold determination.
After incubating for 48 hours, the proliferation of the cells is ascertained by the incorporation of radioactive tritiated thymidine in analogy with the procedure described under number 5.
Calculation
Positive control: Cells of each cell line are incubated in medium=normal proliferation
% Changes in proliferation of the individual preparation concentrations are calculated by comparison with the positive control.
______________________________________ %Preparation .mu.g/ml n AV SD SD in % Change______________________________________Cell line: EL 4Cyclosporin A 10.000 4 17 5 29 -100 5.000 4 14 1 9 -100 2.500 4 22 8 35 -100 1.000 4 30 6 21 -100 0.500 4 2608 409 16 -97 0.100 4 27333 1725 6 -73Chrysospermin 10.000 4 27 23 85 -100A/B 5.000 4 65835 4013 6 -35 2.500 4 87715 3042 3 -14 1.000 4 90812 2784 3 -11 0.500 4 92122 5037 5 -10 0.100 4 93904 4574 5 -8Chrysospermin 10.000 4 22 4 17 -100C/D 5.000 4 25 9 35 -100 2.500 4 72404 3527 5 -29 1.000 4 90971 2212 2 -11 0.500 4 90831 574 1 -11 0.100 4 91906 4771 5 -10Cell line: K 562Cyclosporin A 10.000 4 33 6 17 -100 5.000 4 1027 67 7 -99 2.500 4 19191 978 5 -85 1.000 4 83706 4384 5 -36 0.500 4 100838 5169 5 -23 0.100 4 126497 6596 5 -4Chrysospermin 10.000 4 1560 403 26 -99A/B 5.000 4 18441 1733 9 -86 2.500 4 52008 1459 3 -60 1.000 4 123531 2903 2 -6 0.500 4 124321 5204 4 -5 0.100 4 130717 6127 5 -1Chrysospermin 10.000 4 19 3 18 -100C/D 5.000 4 1143 265 23 -99 2.500 4 16716 1384 8 -87 1.000 4 112024 8598 8 -15 0.500 4 124858 2260 2 -5 0.100 4 130525 5893 5 -1 CT = 2501 =-
Cell line: A20.2.JCyclosporin A 10.000 4 17 3 18 -100 5.000 4 31 9 28 -100 2.500 4 1495 436 29 -99 1.000 4 24936 1278 5 -85 0.500 4 58911 1357 2 -64 0.100 4 136012 4587 3 -16Chrysospermin 10.000 4 35 9 25 -100A/B 5.000 4 39511 3265 8 -76 2.500 4 148134 5418 4 -8 1.000 4 156242 4857 3 -3 0.500 4 157810 4028 3 -2 0.100 4 154432 6877 4 -5Chrysospermin 10.000 4 31 9 31 -100C/D 5.000 4 74 41 55 -100 2.500 4 80974 2016 2 -50 1.000 4 160019 5467 3 -1 0.500 4 156971 8541 5 -3 0.100 4 152791 8817 6 -6Cell line: 20-10-5SCyclosporin A 10.000 4 20 5 28 -100 5.000 4 58 51 88 -100 2.500 4 19 10 54 -100 1.000 4 44 46 105 -100 0.500 4 29 17 57 -100 0.100 4 33784 5010 15 -42Chrysospermin 10.000 4 16 5 29 -100A/B 5.000 4 20865 5059 24 -64 2.500 4 62699 6069 10 +8 1.000 4 62344 2851 5 +7 0.500 4 60208 1632 3 +4 0.100 4 65147 2830 4 +12Chrysospermin 10.000 4 16 3 20 -100C/D 5.000 4 28 19 67 -100 2.500 4 47995 1248 3 -17 1.000 4 60538 1657 3 4 0.500 4 61930 4507 7 7 0.100 4 59966 1819 3 3______________________________________
7. Influence of CSA and chrysospermin A/B and C/D on the production of interleukin 2/3
The method for isolating the lymphocytes is described under point 5. Mixture for isolating interleukin: Macroplates possessing in each case 12 wells: 5.times.10.sup.6 NMRI spleen cells in 4 ml of CTL medium (=cytotoxic T-lymphocyte medium)+2 .mu.l/ml concanavalin A or without stimulant and CSA (cyclosporin A), chrysospermin A/B or C/D in various concentrations. 24 h stimulation: supernatant is isolated cell-free.
Cytotox. T-lymphocyte CIR medium (from Biochrom) medium:+5% fetal calf serum+1% NEA (=non-essential amino acids)+1% pyruvate+ME (.beta.-mercaptoethanol 5.times.10.sup.-5 ml); all from Gibco
This supernatant is added to cell lines which are growing independently of interleukin 2/3 and the content of interleukin is measured from the proliferation.
CTLL cells.fwdarw.IL-2 detection
DA 1 cells.fwdarw.IL-3 detection
Mixture for testing the content of interleukin in the supernatant:
4.times.10.sup.3 of the abovementioned cells/100 .mu.l+100 .mu.l of supernatant=50%}+50 .mu.l of supernatant=25%} total volume 200 .mu.l per well+25 .mu.l of supernatant=12.5%}+12.5 .mu.l of supernatant=6.25%}
The plates are incubated for 48 hours and proliferation of the cells is ascertained by incorporation of radioactive tritiated thymidine in analogy with the procedure described under point 5.
Calculation
Spleen cells produce interleukin 2 and 3 without the substance and with concanavalin A as the stimulant. This supernatant is used as the positive reference control, and the respective dilutions of the supernatants of the individual preparation concentrations are compared with it.
Calculation for significance using p.ltoreq.0.5.
Internal test standard: To check the magnitude of the content of interleukin 2 and 3 in the individual groups, interleukin 2 and interleukin 3 of known concentrations are included in the test as controls.
Microscopic assessment after 20 h. 50 .mu.g/ml and 20 .mu.g/ml of all 3 substances 100% dead cells
__________________________________________________________________________Interleukin 2 control: Counts__________________________________________________________________________(1) 80 .mu.g/ml 200 U/ml 233,430(2) 40 .mu.g/ml 100 U/ml 229,583(3) 20 .mu.g/ml 50 U/ml 230,215(4) 10 .mu.g/ml 25 U/ml 225,827(5) 5 .mu.g/ml 12.5 U/ml 183,303(6) 2.5 .mu.g/ml 6.25 U/ml 78,836(7) 1.25 .mu.g/ml 3.125 U/ml 42,751(8) Medium Medium 43__________________________________________________________________________Interleukin 3 control:__________________________________________________________________________(1) 20% 44,525(2) 10% 38,252(3) 5% 33,018(4) 2.5% 24,826(5) 1.25% 12,102(6) 0.6 .multidot. 125% 5,305(7) 0.3 .multidot. 2% 2,580(8) Medium 20__________________________________________________________________________ Control 50 .mu.g/ml 20 .mu.g/ml 10 .mu.g/ml 2 .mu.g/ml 0.2 .mu.g/ml__________________________________________________________________________Interleukin 3Cyclosporin A 50% 9798 .0. .0. .0. .0. .0. 25% 4300 .0. .0. .0. .0. .0.12.5% 1218 .0. .0. .0. .0. .0.6.25% 181 .0. .0. .0. .0. .0.ChrysosperminA/B 50% 9798 .0. .0. 9864 15671* 11.0 14766 * 59.8 25% 4300 .0. .0. 3468 5969 * 5568 *12.5% 1218 .0. .0. 685 2403 * 2165 *6.25% 181 .0. .0. 42 515 * 498 *C/D 50% 9798 .0. .0. 321 15121 * 15613 * 25% 4300 .0. .0. .0. 5907 * 5817 *12.5% 1218 .0. .0. .0. 2170 * 1863 *6.25% 181 .0. .0. .0. 519 * 292 *Interleukin 2CSA 50% 73812 2090 162 .0. .0. .0. 25% 30347 982 153 .0. .0. .0.12.5% 2766 .0. .0. .0. .0. .0.6.25% 270 .0. .0. .0. .0. .0.A/B 50% 73812 .0. 3663 70918 85632 83622 25% 30347 .0. 796 45892 * 42054 * 72513 *12.5% 2766 .0. 693 13617 * 5821 * 9610 *6.25% 270 .0. .0. 458 347 419C/D 50% 73812 .0. .0. 19483 92026 * 81028 25% 30347 .0. .0. 11524 53193 * 52904 *12.5% 2766 .0. .0. 696 8812 * 19025 *6.25% 170 .0. .0. 165 614 4514 *__________________________________________________________________________
8. Chemiluminescence invitro
Teflon pouch cultivation method: Both the femurs are removed under sterile conditions from 6-10 week-old NMRI mice in such a way that they are as free of muscle as possible. The bone marrow is flushed out with 10 ml of working medium (see point 5) by inserting a cannula on one side of the bone, and dispersed into individual cells by repeatedly drawing it up into the syringe.
Teflon foil (Biofolie 25, from Heraeus) is welded into the form of pouches of the size 5 cm.times.30 cm with the hydrophilic side directed inwards and then steam-sterilized at 121.degree. C. and 1.1 bar for 20 minutes. 4.times.10.sup.6 stock cells in 60 ml of working medium (see point 5) containing 20% FCS and 30% L929 supernatant (as the source of colony stimulating factor 1 CSF1 for the differentiation into macrophages) are added to these sterile pouches, which are then incubated at 37.degree. C. and 5% CO.sub.2 for 8 days.
The teflon pouch method enables macrophages to be raised from an NMRI mouse. The cells are given 8 days to differentiate. Subsequently they are stained with Giemsa stain in order to be able to determine the number of macrophages.
Mixture
200 .mu.l of substance at the respective concentration
350 .mu.l of RPMI medium 1640 (Biochrom) without phenol red
100 .mu.l of luminol (200 .mu.M)
100 .mu.l of macrophages (2.5.times.10.sup.6 /ml)
250 .mu.l of PMA (3.5 .mu.M=Phorbol myristate acetate) ##EQU1##
Chemiluminescence is measured in a Picolite 6500 (from Packard, USA); photons per 10 seconds.
The macrophages are activated by the addition of PMA. 2 mixtures per preparation concentration (results=X=average values)
Without preincubation: Test substance+PMA and measure subsequently
1 h. Preincubation: Test substance at 37.degree. C. for 1 h., then PMA and measure subsequently
______________________________________Without preincubation 1 h. PreincubationMinutes Positive control Positive control______________________________________ 0' 23835 34360 2' 92600 95605 4' 74465 74940 6' 66300 55480 8' 57955 4745010' 51580 4221012' 45850 3679514' 39460 3274516' 35065 3005018' 33790 29225______________________________________Without preincubation 1. Preincubation CsA A/B C/D CsA A/B C/D 50 50 50 50 50 50Minutes .mu.g/ml .mu.g/ml .mu.g/ml .mu.g/ml .mu.g/ml .mu.g/ml______________________________________ 0' 16425 14910 16155 14680 18405 22425 2' 13869 45610 25090 14405 42450 30470 4' 15784 29505 22215 18630 27295 21060 6' 21995 24615 21090 21315 23805 18330 8' 23950 22760 22085 21715 21115 1766010' 24820 20460 22175 21345 18530 1761012' 23425 17564 21035 20455 17715 1760014' 22400 17505 20070 20335 17985 1696516' 22625 15169 18255 21340 16245 1708018' 21930 13835 17309 21055 15835 15765______________________________________Without preincubation 1 h. Preincubation CsA A/B C/D CsA A/B C/D 10 10 10 10 10 10Minutes .mu.g/ml .mu.g/ml .mu.g/ml .mu.g/ml .mu.g/ml .mu.g/ml______________________________________ 0' 11051 31205 27095 10960 46290 44245 2' 17060 111849 97595 15675 129315 124995 4' 36365 81980 76105 37100 84195 89300 6' 30455 77230 69970 30080 72935 77950 8' 29755 70430 64035 26065 62390 7323010' 28555 66800 64465 25060 57820 7007012' 27960 61285 61940 24075 52245 6965514' 26665 56980 59810 46040 47335 6311016' 25605 515151 58130 41630 43650 5931018' 24175 46940 54050 20990 42065 56880______________________________________Without preincubation 1 h. Preincubation CsA A/B C/D CsA A/B C/D 5 5 5 5 5 5Minutes .mu. g/ml .mu.g/ml .mu.g/ml .mu.g/ml .mu.g/ml .mu.g/ml______________________________________ 0' 13755 22210 24520 10270 53265 38675 2' 35215 106665 105205 26905 131975 120450 4' 43660 77080 76620 44155 97245 90695 6' 37095 72010 75345 34020 83945 79420 8' 35505 69565 70915 29475 77030 7443010' 33465 67640 68440 28080 69515 7231512' 30935 62835 67550 25685 64360 6552014' 29235 58885 65280 23775 57995 6327716' 27800 55405 58435 22855 56035 5903018' 25775 52860 54015 21225 52560 57400______________________________________Without preincubation 1 h. Preincubation CsA A/B C/D CsA A/B C/D 1 1 1 1 1 1Minutes .mu.g/ml .mu.g/ml .mu.g/ml .mu.g/ml .mu.g/ml .mu.g/ml______________________________________ 0' 12100 16595 19710 24570 16550 23400 2' 60880 948255 97040 75020 110160 113455 4' 47915 69665 71185 59415 75800 76945 6' 39600 64225 64900 44310 61185 60380 8' 38210 61365 57805 37860 58505 5493010' 36230 58231 51410 33715 55910 4770512' 32615 54115 46950 31295 51265 4105514' 28520 49605 61420 27260 46470 3643016' 25930 44700 36790 25870 44145 3348518' 24570 39165 32015 24200 40125 31520______________________________________
9. MLR one way (mixed lymphocyte reaction) NMRI spleen cells against EL4 tumor cells
mitomycin C treatment: (EL4 are no longer able to proliferate)
7.75.times.10.sup.6 EL4 cells are incubated with 30 .mu.g of mitomycin C in 2 ml.apprxeq.(1.times.10.sup.6 cells+3.9 .mu.g of mitomycin in 258 .mu.l of medium) at 37.degree. C. for 1 h. in a water bath, and subsequently left to incubate for a further 30 minutes in fresh medium in a water bath. Finally, the cells are washed twice with basic medium.
Mixture
100 .mu.l of NMRI spleen cells 5.times.10.sup.5 /well
50 .mu.l of EL4 cells (2.3.times.10.sup.4) or (4.7.times.10.sup.4) per well
50 .mu.l of substance (4.times.conc.) in CTL medium (CTL medium containing 5% fetal calf serum; 1% NEA; 1% Pyruvate+ME) in flat-bottomed microtiter plates.
Four-fold mixture; 5 days of incubation;
16 h. H.sup.3 -thymidine incorporation.
Concentrations of the substances:
1 10 .mu.g/ml
2 5 .mu.g/ml
3 1 .mu.g/ml
4 0.5 .mu.g/ml
5 0.1 .mu.g/ml
6 0.05 .mu.g/ml
7 0.01 .mu.g/ml
__________________________________________________________________________.alpha. 2.3 .times. 10.sup.4 EL4 Cells .alpha. 4.7 .times. 10.sup.4 EL4-ZellenCsA A/B C/D CsA A/B C/D % % % % % %.mu.g/ml cpm Inhibition cpm Inhibition cpm Inhibition cpm Inhibition cpm Inhibition cpm Inhibition__________________________________________________________________________ 10 43 -99.9% 672 -99.0% 38 -99.9% 31 -99.9% 1024 -98.4% 66 -99.9% 5 89 -99.9% 18108 -74.3% 5507 -92.2% 143 -99.8% 47392 -26.7% 5113 -92.1% 1 848 -98.8% 40113 -43.2% 53037 -25.9% 588 -89.1% 46947 -27.3% 40940 -36.6% 0,5 1027 -98.5% 58355 -17.3% 61539 -12.8% 1225 -98.1% 60116 -7.0% 42461 -34.3% 0,1 2861 -95.9% 53836 -23.7% 63522 -10.0% 2155 -96.7% 62910 -2.6% 52197 -19.2%0,05 3596 -94.9% 56839 -19.5% 50163 -28.9% 4607 -92.9% 69001 +6.8% 48498 -24.9%0,01 22514 -68.1% 57942 -17.9% 39954 -43.4% 24015 -62.8% 64675 +0.1% 50310 -22.1%0,00 70589 70589 70589 64621 64621 64621__________________________________________________________________________
__________________________________________________________________________SEQUENCE LISTING(1) GENERAL INFORMATION:(iii) NUMBER OF SEQUENCES: 1(2) INFORMATION FOR SEQ ID NO:1:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 19 amino acids(B) TYPE: amino acid(D) TOPOLOGY: linear(ii) MOLECULE TYPE: peptide(ix) FEATURE:(A) NAME/KEY: Modified-site(B) LOCATION: 1(D) OTHER INFORMATION: /note="Xaa stands forN- acetylphenylalanine (AcPhe)."(ix) FEATURE:(A) NAME/KEY: Modified-site(B) LOCATION: one-of(2, 4, 9, 10, 13, 16, 17)(D) OTHER INFORMATION: /note="Xaa stands foralpha- aminobutyric acid (Aib)."(ix) FEATURE:(A) NAME/KEY: Modified-site(B) LOCATION: 5( D) OTHER INFORMATION: /note="Xaa stands foralpha- aminobutyric acid (Aib) or isovaline (Iva)."(ix) FEATURE:(A) NAME/KEY: Modified-site(B) LOCATION: 15(D) OTHER INFORMATION: /note="Xaa stands foralpha- aminobutyric acid (Aib) or isovaline (Iva)."(ix) FEATURE:(A) NAME/KEY: Modified-site(B) LOCATION: 19(D) OTHER INFORMATION: /note="Xaa stands for tryptophanol (Trp-ol)."(xi) SEQUENCE DESCRIPTION: SEQ ID NO:1:XaaXaaSerXaaXaaLeuGlnGlyXaaXaaAlaAlaXaaProXaaXaa151015XaaGlnXaa

Chrysospermins, active peptides from apiocrea chrysosperma having a pharmacological effect and a use thereof

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Entry
Bruckner et al., "The Sequences of the Membrane-Modifying Peptide Antibotic Trichotoxin A-40," Angew. Chem. Int. Ed. Engl. 18(6):476-477 (1979).
Przybylski et al., "Elucidation of Structure and Microheterogeneity of the Polypeptide Antibiotics Paracelsin and Trichotoxin A-50 by Fast Atom Bombardment Mass Spectrometry in Combination with Selective in situ Hydrolysis," Biomedical Mass Spectrometry, 11(11):569-582 (1984).