Antibiotics produced by Kibdelosporangium aridum Shearer gen. nov., sp. nov. ATCC 39323

SUMMARY OF THE INVENTION
This invention relates to new antibiotics of the vancomycin-class and the production and recovery thereof. This invention also relates to the new microorganism Kibdelosporangium aridum Shearer, gen. nov., sp. nov. SK&F-AAD 216 (ATCC 39323). More particularly, this invention relates to an antibiotic, designated herein AAD 216 complex, said complex being produced by cultivating K. aridum in an aqueous nutrient medium, containing assimilable sources of nitrogen and carbon, under submerged aerobic conditions until a substantial amount of AAD 216 complex is produced by said microorganism in said medium and optionally recovering AAD 216 complex from the culture medium.
Also provided for in this invention are the novel bioactive components of the AAD 216 complex; AAD 216A, AAD 216B and AAD 216C, which are prepared by the separation and isolation of the individual antibiotic compounds from the AAD 216 complex by chromatographic means. The antibiotic, AAD 216 complex and its major bioactive components; AAD 216A, AAD 216B and AAD 216C all exhibit antibacterial activity. The AAD 216 complex, AAD 216A, AAD 216B and AAD 216C are also useful in animal health applications, such as a growth promotant and the treatment of bovine mastitis.
DETAILED DESCRIPTION
The new antibiotics, AAD 216 complex and its major bioactive components; AAD 216A, AAD 216B and AAD 216C, are produced by the fermentation of a new microorganism Kibdelosporangium aridum Shearer gen. nov., sp. nov. SK&F-AAD 216. The above microorganism was isolated from a soil sample collected in a desert area near Pima, Ariz. A culture of the biologically pure microorganism has been deposited in the American Type Culture Collection, Rockville, Md. as the type culture under accession number ATCC 39323.
The AAD 216 complex refers to the mixture of the individual antibiotics produced by the fermentation of K. aridum. As is readily understood by those familiar with antibiotics fermentation processes, the ratios of the individual or factor antibiotics and their presence in the AAD 216 complex will vary, depending on the conditions of the fermentation process. The AAD 216 complex may be recovered from the fermentation medium by clarifying the whole fermentation broth by filtration and by precipitating the crude AAD 216 complex at 0.degree. to 10.degree. C. with hydrochloric acid at a pH of 3. The precipitate is then dissolved in water by adjusting the pH to about 6 to 8 and applied to a resin column from which it is eluted with aqueous methanol. The resultant eluant is lyophilized to yield the AAD 216 complex which is chromatographed to afford the enriched AAD 216 complex. Typically, the enriched AAD 216 complex contains 40 to 85 percent by weight of a mixture of AAD 216 A, AAD 216B and AAD 216C.
The enriched AAD 216 complex at a pH of about 6 which by analytical HPLC contains by weight 29 percent AAD 16A, 10 percent AAD 216B and 10 percent AAD 216C has the following characteristics:
(a) pale-white-yellww solid which decomposes at 300.degree. to 350.degree. C.;
(b) an approximate elemental composition of 53.22 percent carbon, 6.14 percent hydrogen, 3.73 percent nitrogen and 0.28 percent ash;
(c) an infrared spectrum in potassium bromide which exhibits peaks at the following wave numbers in cm.sup.1 : 3400, 2920, 1660, 1600, 1510, 1460, 1430, 1390, 1320, 1240, 1150, 1060 and 1020;
(d) an ultraviolet spectrum in acetonitrile:water (1:1) which exhibits an absorption maximum at 280 nm under neutral and acid conditions with an E.sub.1% =43.9 and at 301 nm under basic conditions with an E.sub.1% =56.8;
(e) a positive reaction with periodate and negative reaction with ninhydrin; and
(f) soluble in H.sub.2 O, methanol, dimethylsulfoxide and dimethylformamide and insoluble in ethanol, acetonitrile, acetone, diethylether and aliphatic hydrocarbons.
The individual pure antibiotic components, AAD 216A, AAD 216B and AAD 216C can be isolated from the AAD complex utilizing preparative high pressure liquid chromatography (HPLC). Typically, the AAD 216 complex is chromatographed with a step gradient elution with 20 to 28 percent acetonitrile in 0.1 N phosphate buffer at pH 6. The appropriate fractions, as determined by analytical HPLC, are combined and desalted on a resin column and after lyophilization affords the desired individual antibiotic components, as pure AAD 216A, AAD 216B and AAD 216C.
AAD 216A antibiotic at a pH of about 6 has the following characteristics:
(a) pale white-yellow solid which decomposes at 300.degree. to 350.degree. C.;
(b) an empirical formula C.sub.81 H.sub.82 N.sub.8 O.sub.30 Cl.sub.4
(c) an approximate elemental composition of 48.20 percent carbon, 5.01 percent hydrogen, 5.21 percent nitrogen, 6.43 percent chlorine, no sulfur or organic phosphorus, when the water content was 10.80 percent;
(d) an infrared absorption spectrum in potassium bromide which exhibits peaks at the following wave numbers in cm.sup.-1 :3400, 2920, 1660, 1600, 1510, 1460, 1430, 1390, 1320, 1300, 1240, 1150, 1060 and 1020;
(e) a fast atom bombardment (FAB) mass spectrum with M+H at 1787 (major cluster);
(f) an ultraviolet spectrum in acetonitrile: water (1:1) which exhibits an absorption maximum at 280 nm under neutral and acidic conditions with an E.sub.1% =51 and at 301 nm under basic conditions with an E.sub.1% =73;
(g) a carbon magnetic resonance spectrum at 90.56 MHz in CD.sub.3 OD:D.sub.2 O(1:9) at a pH of 8.5 which exhibits the following chemical shifts in part per million (ppm) relative to TMS as standard: 177.7, 177.5, 175.5, 174.6, 171.5, 170.8, 170.4, 170.2, 169.1, 161.8, 158.6, 157.9, 155.1, 155.0, 152.5, 151.9, 151.6, 150.7, 146.0, 144.3, 141.7, 138.8, 138.3, 136.0, 134.6, 134.5, 133.7, 130.8, 129.8, 129.4, 128.9 128.6, 127.4, 127.0, 126.2, 125.6, 125.1, 122.7, 122.3, 120.9, 119.6, 118.3, 116.4, 110.5, 109.6, 108.3, 104.2, 103.3, 103.1, 100.7, 98.1, 78.4, 74.4; 73.9, 73.3, 72.0, 71.6, 71.3, 70.7, 67.3, 65.6, 63.6, 62.3, 61.6, 60.2, 56.8, 56.3, 55.8, 54.9, 37.2, 32.7, 32.2, 29.8, 29.6, 29.5, 26.2, 23.0 and 14.5;
(h) a specific rotation [.alpha.].sub.D.sup.25 =-66.degree. (C=0.3 in H.sub.2 O);
(i) positive reaction with periodate and negative reaction with ninhydrin;
(j) soluble in H.sub.2 O, methanol, dimethylsulfoxide, dimethylformamide and insoluble in ethanol, acetonitrile, acetone, diethylether and aliphatic hydrocarbons; and.
(k) pKa values in acetonitrile:water (3:7) as follows: 3.0, 4.9, 7.4, 8.4, 10.0 and 10.3 pK.sub.a values above 10.3 not determined.
AAD 216B antibiotic at a pH of about 6 has the following characteristics:
(a) pale white-yellow solid which decomposes at 300.degree. to 350.degree. C.,
(b) an empirical formula C.sub.82 H.sub.84 N.sub.8 O.sub.30 Cl.sub.4
(c) an approximate elemental composition of 49.67 percent carbon, 5.07 percent hydrogen, 5.19 percent nitrogen, 6.70 percent chlorine, no sulfur or organic phosphorus, when the water content is 10.8 percent;
(d) an infrared absorption spectrum in potassium bromide which exhibits peaks at the following wave numbers in cm.sup.-1 : 3400, 2920, 1660, 1600, 1510, 1460, 1430, 1390, 1300, 1240, 1150, 1060 and 1020;
(e) a fast atom bombardment (FAB) mass spectrum with M+H at 1801 (major cluster);
(f) an ultraviolet spectrum in acetonitrile: water (1:1) which exhibits an absorption maximum at 280 nm under neutral and acidic conditions with an E.sub.1% =55 and at 301 nm under basic conditions with an E.sub.1% =72.5;
(g) a carbon magnetic resonance spectrum at 90.56 MHz in CD.sub.3 OD:D.sub.2 O(1:9) at a pH of 8.5 which exhibits the following chemical shifts in parts per million (ppm) relative to TMS as standard: 177.9, 177.4, 175.6, 174.4, 171.6, 170.9, 170.5, 170.4, 169.3, 162.4, 158.7, 158.1, 155.2, 155.0, 152.6, 151.3, 150.7, 146.0, 144.3, 141.3, 138.8, 138.3, 136.1, 134.7, 133.6, 130.7, 129.9, 129.8, 129.4, 129.0, 128.7, 127.7, 127.5, 127.0, 126.3, 125.7, 124.7, 122.8, 122.3, 120.9, 119.9, 119.6, 118.4, 116.7, 110.5, 109.6, 108.5, 104.2, 103.3, 103.1, 100.6, 98.1, 78.5, 74.4, 73.9, 73.4, 72.1, 71.7, 71.2, 70.8, 67.3, 65.5, 63.7, 62.3, 61.6, 60.3, 56.8, 56.2, 55.9, 55.0, 39.6, 37.3, 32.7, 30.2, 30.0, 29.7, 28.4, 27.8, 26.3 and 23.3;
(h) a specific rotation [.alpha.].sub.D.sup.25 =-59.degree. (C=1.0 in H.sub.2 O);
(i) positive reaction with periodate and negative reaction with ninhydrin;
(j) soluble in H.sub.2 O, methanol, dimethylsulfoxide, dimethylformamide and insoluble in ethanol, acetonitrile, acetone, diethylether, and aliphatic hydrocarbons; and
(k) pK.sub.a values in acetonitrile:water (3:7) as follows: 3.0, 4.5, 7.5, 8.5 and 9.7 pK.sub.a values above 9.7 not determined.
AAD 216C antibiotic at a pH of about 6 has the following characteristics:
(a) pale white-yellow solid which decomposes at 300.degree. to 350.degree. C.;
(b) an empirical formula C.sub.83 H.sub.86 N.sub.8 O.sub.30 Cl.sub.4
(c) an approximate elemental composition of 47.89 percent carbon, 5.09 percent hydrogen, 4.95 percent nitrogen, 6.39 percent chlorine, 3.69 ash, no sulfur or organic phosphorus, when the water content was 8.2 percent;
(d) an infrared absorption spectrum in potassium bromide which exhibits peaks at the following wave numbers in cm.sup.-1 : 3400, 2920, 1660, 1600, 1505, 1430, 1390, 1295, 1240, 1150, 1060 and 1020;
(e) a fast atom bombardment (FAB) mass specturm with M+H at 1815 (major cluster);
(f) an ultraviolet spectrum in acetonitrile:water (1:1) which exhibits an absorption maximum at 280 nm under neutral and acid conditions with an E.sub.1% =51 and at 301 nm under basic conditions with an E.sub.1% =75;
(g) a carbon magnetic resonance spectrum at 90.56 MHz in CD.sub.3 OD:D.sub.2 O(1:9) at a pH of 8.5 which exhibits the following chemical shifts in parts per million (ppm) using TMS as the internal standard: 177.9, 177.2, 175.7, 173.6, 171.5, 170.8, 170.6, 170.2, 169.3, 158.6, 157.8, 155.2, 154.9, 152.7, 151.9, 150.9, 146.0, 144.3, 141.3, 138.8, 138.4, 136.0, 134.9, 134.7, 133.8, 130.8, 129.9, 129.8, 129.3, 129.1, 127.7, 127.5, 127.0, 126.4, 125.3, 122.7, 121.0, 119.7, 118.3, 116.1, 110.4, 109.6, 108.1, 104.1, 103.2, 101.5, 98.0 78.6, 74.6, 73.9, 73.4, 72.1, 71.7, 71.3, 70.3, 67.3, 65.1, 63.7, 62.5, 61,6, 60.3, 56.8, 56.3, 55.3, 54.9, 39.7, 37.4, 32.6, 32.3, 30.5, 30.4, 30.2, 29.9, 28.6, 28.1, 26.4, 23.4 and 22.0;
(h) a specific rotation [.alpha.].sub.D.sup.25 =50.6 (C=0.6 in H.sub.2 O);
(i) positive reaction with periodate and negative reaction with ninhydrin;
(j) soluble in H.sub.2 O, methanol, dimethylsulfoxide, dimethylformamide and insoluble in ethanol, acetonitrile, acetone, diethylether and aliphatic hydrocarbons; and
(k) pKa values in acetonitrile:water (3:7) as follows: 3.0, 4.2, 7.2, 8.2, 9.9 and 10.3 pK.sub.a values above 10.3 not determined.
The novelty of AAD 216 complex, and its major bioactive components, AAD 216A, AAD 216B and AAD 216C, was confirmed by comparison with known members of the vancomycin/ristocetin class of antibiotics. Specifically, the Rf values from thin layer chromatography against B. subtilis for AAD 216A, AAD 216B and AAD 216C were compared to known antibiotics as shown below in TABLE I.
TABLE I______________________________________ TLC (Avicel).sup.1 A B C______________________________________A-35512B 0.14 0.25 ##STR1##A-477 0.51 ##STR2## 0, 0.20 ##STR3##Actaplanin 0.16 0.06 0.11Actinoidins A 0.04, ##STR4## 0.05and B ##STR5##Avoparcin 0.15 0.13 0.07LL-AM-374 0.08 0.17 0.05Ristocetin 0.1 ##STR6## 0.04Teichomycin A-2 0.34 ##STR7## 0.77 0.47Vancomycin 0.17 ##STR8## ##STR9##AAD 216A 0.35 0.33 0.83AAD 216B 0.38 0.35 0.83AAD 216C 0.44 0.34 0.82______________________________________ 1. Rf values, detection: B. subtilis activity. Underlined value is major active component A. nBuOH:HOAc:H.sub.2 O (4:1:5) B. nPrOH:Petroleum Ether:conc. NH.sub.4 OH (4:1:2) C. nPrOH:H.sub.2 O (6:4)
Additionally, the retention times of AAD 216A, AAD 216B and AAD 216C in reverse phase high pressure liquid chromatography were compared to and found to differ from those of the known antibiotics as shown below in TABLE II.
TABLE II______________________________________ Retention Time, Min.Antibiotics System A.sup.(a) System B.sup.(b)______________________________________AAD 216A 15.3 14.5AAD 216B 15.9 15.2AAD 216C 17.2 16.1A 35512B 5.2* 6.1*A 477 11.7* 8.9*Actaplanin 6.3* 7.5*Actinoidin A/B 5.5* 8.1*Avoparcin 5.8* 7.6*LL-AM-374 5.1* 6.8*Ristocetin 3.6 5.4Teichomycin A-2 13.6* 13.8*Vancomycin 6.0 7.4______________________________________ *major component in multicomponent mixture .sup.(a) HPLC System A: column: Ultrasphere ODS, 5 micron, 4.6 .times. 15 mm solvent: 7-34% acetonitrile (7% for 1 minute, then ramp to 34% over 13 minutes and hold at 34%) in pH 3.2, 0.1 M phosphate. flow: 1.5 ml/min detection: uv 220 nm .sup.(b) HPLC System B: column: Ultrasphere ODS, 5 micron, 4.6 .times. 15 mm solvent: 5-35% acetonitrile (5% for 1 minute, then ramp to 35% over 13 minutes and hold at 35%) in pH 6.0, 0.025 M phosphate flow: 1.5 ml/min. detection: uv 220 nm
Total hydrolysis of AAD 216A, AAD 216A, AAD 216B and AAD 216C, individually, in 6N hydrochloric acid at reflux for 18 hours yielded no common amino acids which could be detected in a standard amino acid analysis. The presence of actinoidinic acid, which is common in the vancomycin class of antibiotics, was confirmed in the hydrolysis products by high pressure liquid chromatography and FAB mass spectrum when compared to an authentic sample. Further, hydrolysis of AAD 216A, AAD 216B and AAD 216C, individually, in IN hydrochloric acid at reflux for 4 hours yielded mannose but not ristosamine, glucosamine or vancosamine.
Bioactive hydrolysis products of the compounds of this invention, including the aglycone of the following structural formula (I) ##STR10## are disclosed and claimed in co-pending U.S. patent application, Attorney Docket No. SKB 14174, filed concurrently herewith.
THE MICROORGANISM
Stock cultures of Kibdelosporangium aridum SK&F-AAD 216 (ATCC 39323) were maintained on thin potato-carrot or oatmeal agar. Morphological observations were made on plates of water agar, thin potato-carrot agar, oatmeal agar and soil extract agar. Inoculum for the
iological tests was prepared by adding biochemical and physiological tests was prepared by adding the contents of a frozen vial of vegetative culture to a flask of glucose-yeast extract broth which was placed on a rotary shaker at 28.degree. C., 250 RPM for three to six days. The culture was harvested by centrifugation and washed three times with sterile distilled water. Incubation temperature for the biochemical and physiological tests was 28.degree. C. Readings of the results were made at various times up to 21 days for the plate media. Most of the tubed media were read at various times up to 28 days. However, the tests for decomposition of urea, allantoin and hippurate, as well as the tests for reduction of nitrates, were read for six weeks.
Susceptibility of K. aridum to antibiotics was examined by placing BBL susceptibility disks on nutrient agar plates seeded with K. aridum as an overlay. Diameters of the zones of inhibition were measured after incubation for one week at 28.degree. C.
Morphology. K. aridum is a filamentous organism that forms a mycelium differentiated into: (1) a substrate mycelium that penetrates the agar and forms a compact layer on top of the agar, and (2) an aerial mycelium that bears chains of conidia and/or sporangium-like structures. No motile elements were observed in the aerial or substrate mycelium. On many media, K. aridum produces characteristic crystals in the agar.
Substrate Mycelium. K. aridum produces a well developed, non-fragmenting substrate mycelium. The long branching hyphae are septate and about 0.4 .mu.m-1.0 .mu.m in diameter. Present on the substrate mycelium are specialized structures which consist of dichotomously branched, septate hyphae radiating from a common stalk.
Aerial Mycelium. The aerial mycelium of K. aridum, produces chains of rod-shaped, smooth walled spores which are irregular in length (0.4 .mu.m.times.0.8 .mu.m -2.8 .mu.m). These spore chains are usually very long with more than 50 spores per chain, but a few short chains of ten spores or less are also usually present. The spore chains may be born apically or on short lateral branches.
On most media, the aerial mycelium of K. aridum also produces sporangium-like structures. These may be born apically or on short lateral branches. Sporangium-like structures and chains of spores may be born on the same aerial hyphae. At maturity these sporangium-like structures are round, approximately 9 .mu.m-22 .mu.m in diameter, and consist of septate, branched hyphae embedded in an amorphous matrix which is surrounded by a well-defined wall. When placed on agar, these sporangium-like structures germinate directly with the production of one or more germ tubes.
Chemotaxonomy. Purified cell wall preparations of K. aridum analyzed by the method of Becker [Becker et al. Appl. Microbiol. 12, 421-23 (1964)] contained the meso-isomer of 2,6-diaminopimelic acid, alanine, glutamic acid, glucosamine and muramic acid as well as galactose and a very minor amount of arabinose. Whole-cell hydrolysates analyzed by the method of Lechevalier [Lechevalier, M. P., J. Lab. Clin. Med. 71, 934-44 (1968)] contained galactose, glucose, mannose, ribose, rhamnose and arabinose; traces of madurose may also be present. No mycolic acids of any type were present in the cell extracts analyzed for lipid patterns by the method of Lechevalier [Lechevalier et al., Can. J. Microbiol. 19, 965-72 (1973) . The phospholipids present were phosphatidyl ethanolamine, phosphatidyl methylethanolamine, diPhosphatidyl glycerol, phosphatidyl inositol and phosphatidyl inositol mannosides. Thus K. aridum has a Type IV cell wall with a whole-cell sugar pattern of Type A with traces of madurose [Lechevalier et al., Int. J. Syst. Bacteriol. 20, 435-43 (1970)] and a phospholipid pattern of type PII with phosphatidyl methylethanolamine [Lechevalier et al., Biochem. System. Ecol. 5, 249-60 (1977)].
Physiological and Biochemical Characteristics. K. aridum is gram positive and not acid-fast. No growth takes place under anaerobic conditions. Temperature range for growth is 15.degree. C. to 42.degree. C. with a trace of growth at 45.degree. C.; no growth occurs at 10.degree. C. or 50.degree. C. Hydrogen sulfide is produced. Milk is peptonized. Gelatin is both hydrolyzed and liquified. Nitrate is not reduced to nitrite. Melanin pigments are produced. Casein, L-tyrosine, hypoxanthine, guanine, elastin and testosterone are hydrolyzed but adenine, xanthine and cellulose (Avicel) are not. Catalase and phosphatase are produced. Urea, esculin and hippurate are decomposed; tests for allantoin decomposition are weakly positive. There is no growth in 8% NaCl; growth in 5% to 7% NaCl is inconsistent. No growth occurs in lysozyme broth. Acid is produced from L-arabinose, D-cellobiose, dextrin, dextrose, D-fructose, glycerol, glycogen, D-galactose, i-inositol, lactose, D-mannitol, D-mannose, .alpha.-methyl-D-glucoside, .alpha.-methyl-D-mannoside, melibiose, D-melezitose, raffinose, rhamnose, D-ribose, sucrose, trehalose, D-xylose and maltose. No acid is produced from dulcitol, i-erythritol, inulin, D-sorbitol, or L-sorbose. Citrate, malate, succinate, oxalate, lactate, acetate, pyruvate, propionate and formate are utilized; benzoate and tartrate are not.
Susceptibility to Antibiotics. By the diffusion method, K. aridum was resistant to disks impregnated with gentamicin (10 .mu.g), tobramycin (10 .mu.g), streptomycin (10 .mu.g), vancomycin (30 .mu.g), penicillin (10 units), bacitracin (2 units), lincomycin (2 .mu.g), clindamycin (2 .mu.g), and cephalothin (30 .mu.g). Chlortetracycline (5 g) produced 18 mm zones of inhibition; tetracycline (5 .mu.g) 11-12 mm zones; rifampin (5 .mu.g) 11-15 mm zones; novobiocin (5 .mu.g) 27-28 mm zones. All zones of inhibition contained at least a few resistant colonies.
Description of K. aridum on Various Media
All cultures were incubated at 28.degree. C. in closed petri dish cans and observed at intervals up to 21 days. The colors of the culture were chosen by comparison with color chips from either the ISCC-NBS Centroid Color Charts or the Dictionary of Color [Maerz, A. and M. R. Paul 2nd. ed. New York: McGraw Hill Book Co., Inc. (1950)].
Yeast Extract-Malt Extract Agar--Growth excellent; vegetative growth grayish yellow brown; aerial mycelium, none to very sparse, white, spore chains and sporaggium-like structures present; yellow brown soluble pigment; characteristic crystals present in agar.
Oatmeal Agar-Growth good; vegetative growth off-white to yellow brown; aerial mycelium sparse, white, numerous spore chains and sporangium-like bodies present; no soluble pigment; characteristic crystals present in agar.
Glycerol-Asparagine Agar--Growth fair to good; vegetative growth pale yellow brown; aerial mycelium sparse to moderate, white, a few spore chains but few, if any, sporangium-like structures present; pale grayish yellow brown soluble pigment; characteristic crystals present in agar.
Inorganic-Salts Starch Agar--Growth good; vegetative growt off-white to yellow brown; aerial mycelium sparse, white, spore chains and sporangium-like structures present; no soluble pigment; characteristic crystals present in agar.
Czapek-Sucrose Agar--Growth good; vegetative growth off-white to yellow brown; aerial mycelium sparse, white, spore chains and sporangium-like structures present; pale grayish yellow to pale yellow brown soluble pigment present; characteristic crystals present in agar.
Bennett's Agar--Growth good to excellent; vegetative growth grayish yellow brown; aerial mycelium, none to sparse, white, spore chains and sporangium-like structures present; yellow brown soluble pigment; no crystals detected in agar.
Nutrient Agar--Growth fair to good; vegetative growth yellow brown; aerial mycelium sparse to moderate, white, few spore chains and few sporangium-like structures present; yellow brown soluble pigment; characteristic crystals variably present in agar.
Thin Potato-Carrot Agar--Growth fair, relatively flat; vegetative growth off-white to yellow brown; aerial mycelium sparse to mderate, white, numerous spore chains and sporangium-like structures present; no soluble pigment; no crystals detected in agar.
Peptone-Yeast Extract Iron Agar--Growth good; vegetative growth bronze brown (Maerz & Paul 16C9); aerial mycelium, none; dark brownish black soluble pigment; no crystals detected in agar.
Starch-Casein Nitrate Agar--Growth good; vegetative mycelium off-white to yellow brown; aerial mycelium sparse, white, spore chains and sporangium-like structures present; pale yellow brown soluble pigment variably present; characteristic crystals present in agar.
Yeast Extract-Glucose Agar--Growth good to excellent; vegetative growth dark yellow brown to grayish yellow brown; aerial mycelium, none visible, under 400.times. sparse spore chains but no sporangium-like structures present; dark yellow brown soluble pigment; characteristic crystals present in agar.
A comparison of the description of K. aridum with the descriptions of actinomycetes listed in Bergey's Manual of Determinative Bacteriology, the Approved List of Bacterial Names and other recent taxonomic literature indicates that K. aridum differs significantly from previously described species of actinomycetes and cannot be accommodated in any of the previously described genera of the actinomycetes. Sporangia, where present in other actinomycete genera, are true spore vesicles; at maturity they contain aplanospores or zoospores which are eventually released by rupture or dissolution of the sporangial wall. Despite extensive observation and manipulation, the release of spores from the sporangium-like structuress of K. aridum was never observed. When placed on agar, the sporangium-like structures of K. aridum germinate by the production of one or more germ tubes directly from the sporangium-like structure.
Type culture ATCC 39323 is hereby described as a species of a new genus Kibdelosporangium aridum, (from kibdelos, Gr. adj., false, ambiguous; spora Gr. n., a seed; angium Gr. n., a vessel); the specific epithet, aridum, (aridus Gr. n., L. adj., dry, arid) refers to the desert soil from which the culture was isolated.
PREPARATION OF THE AAD 216 COMPLEX
The AAD 216 complex may be produced by cultivating a strain of Kibdelosporangium having the characteristics of ATCC 39323 or an active mutant or derivative thereof, obtained by procedures known to the art, under submerged aerobic conditions in an aqueous nutrient medium. The organism is grown in a nutrient medium containing an assimilable carbon source, for example an assimilable carbohydrate. Examples of suitable carbon sources include sucrose, lactose, maltose, mannose, fructose, glucose, and soluble starch. The nutrient medium should also contain an assimilable nitrogen source such as fish meal, peptone, soybean flour, peanut meal, cotton seed meal or corn steep liquor. Nutrient inorganic salts can also be incorporated in the medium. Such salts may comprise any of the usual salts capable of providing sodium, potassium, ammonium, calcium, phosphate, sulfate, chloride, bromide, nitrate, carbonate or like ions.
Production of the AAD 216 complex can be effected at any temperature conducive to satisfactory growth of the organism, e.g., 15.degree.-42.degree. C., and is conveniently carried out at a temperature of about 25.degree. to 28.degree. C.
The medium normally is neutral, but the exact pH can be varied between 5.0 and 9.0 depending on the particular medium used.
The fermentation may be carried out in Erlenmeyer flasks or in laboratory or industrial fermentors of various capacities. When tank fermentation is to be used, it is desirable to produce a vegetative inoculum in a nutrient broth by inoculating a small volume of the culture medium with the vegetative cells of the organism After obtaining an inoculum in this manner, it is transfered aseptically to the fermentation tank medium for large scale production of the antibiotics. The medium used for the vegetative inoculum can be the same as that employed for larger fermentations, although other media can be employed.
As is customary in aerobic submerged culture processes, sterile air is sparged through the culture medium. Agitation may be maintained by means of agitators generally familar to those in the fermentation industry
In general, optimum production of the complex is achieved after incubation periods of about 144-186 hours in stir-jar fermentors or tank fermentors. The course of the fermentation can be followed by analytical HPLC.
The AAD 216 complex so produced contains the novel bioactive components or individual antibiotic factors, AAD 216A, AAD 216B and AAD 216C which can be isolated as described above.
BIOLOGICAL ACTIVITY DATA
The in vitro minimum inhibitory concentration (MIC) of the AAD 216 complex, enriched AAD 216 complex, AAD 216A, AAD 216B, AAD 216C and vancomycin were determined for a number of microorganisms using the standard microtiter assay procedures. The results are shown in the following Tables A-E.
TABLE A__________________________________________________________________________Antimicrobial Spectrum MIC in .mu.g/ml AAD AAD AAD AAD 216 216 216 216Test Organism Complex A B C Vancomycin__________________________________________________________________________Staph. aureus HH127 6.3 3.1 3.1 3.1 1.6Staph. aureus SK & F 910 12.5 3.1 3.1 3.1 1.6Strep. faecilis HH34358 1.6 0.4 0.4 0.8 3.1Proteus mirabilis SK & F 444 >100 >100 >100 >100 100E. coli 12140 (SK & F 809) >100 >100 >100 >100 100Kleb. pneumoniae >100 >100 >100 >100 >1004200 (SK & F 798)Pseudomonas aeruginosa >100 >100 >100 >100 >100HH63Serratia marcesens >100 >100 >100 >100 >100ATCC 13880Proteus morgani SK & F 179 >100 >100 >100 >100 >100Providencia SK & F 276 >100 >100 >100 >100 >100Enterobacter cloacae >100 >100 >100 >100 >100HH31254Salmonella gallinarum >100 >100 >100 >100 25BC595Staph. epidermidis 25 6.3 6.3 6.3 1.6SK & F 2479Listeria monocytogenes 3.1 0.8 0.4 .about.0.4 1.6SK & F 2255Staph. epidermidis SK & F 651 100 50 25 25 1.6__________________________________________________________________________
TABLE B__________________________________________________________________________(Methicillin Sensitive) MIC in .mu.g/ml AAD 216Test Organism Complex AAD 216 A AAD 216 B AAD 216 C Vancomycin__________________________________________________________________________Staph. aureus HH127 12.5 1.6-3.1 3.1 3.1 1.6Staph. aureus SK & F 674 12.5 3.1-6.3 6.3 12.5 1.6Staph. aureus SK & F 910 12.5 3.1 6.3 6.3 1.6Staph. aureus SK & F 1761 12.5 3.1 3.1 3.1 1.6Staph. aureus SK & F 2593 25 6.3 6.3 6.3 1.6Staph. aureus SK & F 2666 12.5 3.1 3.1 6.3 1.6Staph. aureus SK & F 2677 25 6.3 3.1 6.3 1.6Staph. aureus SK & F 2678 25 6.3 6.3 6.3 1.6Staph. aureus SK & F 2680 12.5 3.1-6.3 6.3 6.3 1.6Staph. aureus SK & F 2682 25 3.1-6.3 6.3 3.1 1.6Staph. aureus SK & F 2736 25 3.1-6.3 6.3 6.3 1.6Staph. aureus SK & F 2776 50 12.5 6.3 12.5 1.6Staph. aureus SK & F 2777 12.5 3.1 3.1 3.1 0.8Staph. aureus SK & F 2613 6.3 1.6 1.6 1.6 1.6Staph. aureus SK & F 2615 12.5 3.1-6.3 6.3 6.3 3.1__________________________________________________________________________
TABLE C__________________________________________________________________________(Methicillin Resistant) MIC in .mu.g/ml AAD 216Test Organism Complex AAD 216 A AAD 216 B AAD 216 C Vancomycin__________________________________________________________________________Staph. aureus SK & F 675 50 12.5 6.3 12.5 1.6Staph. aureus SK & F 2612 12.5 6.3 3.1 6.3 1.6Staph. aureus SK & F 2614 6.3 3.1 3.1 3.1 1.6Staph. aureus SK & F 2616 25 6.3-12.5 6.3 6.3 0.8Staph. aureus SK & F 2620 25 6.3 12.5 12.5 3.1Staph. aureus SK & F 2621 25 6.3 6.3 6.3 1.6Staph. aureus SK & F 2594 25 6.3-12.5 6.3 6.3 1.6Staph. aureus SK & F 2589 25 6.3-12.5 6.3 6.3 1.6Staph. aureus SK & F 2590 25 6.3-12.5 3.1 6.3 1.6Staph. aureus SK & F 2591 25 6.3 6.3 6.3 1.6Staph. aureus SK & F 2592 50 6.3 12.5 12.5 3.1Staph. aureus SK & F 2595 25 6.3-12.5 6.3 6.3 .about.1.6Staph. aureus SK & F 2596 25 6.3-12.5 6.3 6.3 3.1Staph. aureus SK & F 2597 25 6.3-12.5 6.3 12.5 3.1__________________________________________________________________________
TABLE D__________________________________________________________________________(Anaerobes) MIC in .mu.g/ml AAD 216Test Organism Complex AAD 216 A AAD 216 B AAD 216 C Vancomycin__________________________________________________________________________Bacteroides fragilis >32 32 32 32 32ATCC 25285B. fragilis H145 >32 16 16 8 32B. fragilis SK & F 3060 >32 32 16 16 32B. loeochii SK & F 3087 >32 8-16 16 4 32B. thetaiotamicron >32 >32 32 32 32SK & F 3089Fusobacterium nucleatum >32 32 32 32 32ATCC 25586Clostridium perfringens .ltoreq.0.016 .ltoreq.0.016 0.125 .ltoreq.0.016 0.5MCP-1C. perfringens MCP-2 .ltoreq.0.016 .ltoreq.0.016 0.125 .ltoreq.0.016 0.5C. perfringens 0.25 0.031-0.063 0.125 0.125 1.0ATCC 19408Clastridium difficile 1.0 0.25 0.25 0.5 2SK & F 3062C. difficile SK & F 3065 1.0 0.5 0.25 0.5 4C. difficile SK & F 3091 .ltoreq.0.016 0.125-0.25 0.25 0.031 2C. difficile SK & F 3092 1.0 0.125 0.25 0.25 2C. difficile SK & F 3096 1.0 0.25 2 0.25 2C. difficile SK & F 3098 .ltoreq.0.016 .ltoreq.0.016 2 0.031 2__________________________________________________________________________
TABLE E__________________________________________________________________________ MIC in .mu.g/ml EnrichedTest Organism AAD 216 Complex AAD 216A Vancomycin__________________________________________________________________________Staph. aureus HH 127 6.3 6.3 3.1Staph. aureus SK & F 910 .about.6.3 6.3 3.1Staph. aureus 209P 1.6 1.6 1.6Staph. aureus 100 100 >100209P-MutantStaph. aureus SK & F 674 6.3 3.1 1.6Staph. aureus .about.100 .about.100 >100SK & F 674-P6 MutantStaph. aureus SK & F 675 12.5 12.5 3.1Staph. epidermidis SK & F 2479 25 25 6.3Staph. epidermidis SK & F 2683 100 100 6.3Staph. epidermidis SK & F 651 100 100 6.3Staph. epidermidis SK & F 2265 100 100 6.3Strep. faecalis HH 34358 0.4 1.6 6.3Strep. faecalis SK & F 657 0.4 0.8 3.1Listeria monocytogenes 0.8 1.6 3.1SK & F 2255E. coli 12140 (SK & F 809) >100 >100 >100Salmonella gallinarum >100 >100 > 100BC595__________________________________________________________________________
The in vivo activity of the AAD 216A, AAD 216B, AAD 216C and vancomycin, measured as ED.sub.50, was demonstrated against intraperitoneal s.c. infections with 46.8 LD.sub.50 's of Staph. aureus HH 127 in mice by treatments with the antibiotics 1 and 5 hours post infections. The ED.sub.50 's were as follows: AAD 216A, 5.0 mg/kg; AAD 216B, 5.0 mg/kg; AAD 216C, 7.5 mg./kg; vancomycin, 1.76 mg/kg.
The antibiotic compounds of the present invention including AAD 216 complex and its major bioactive components; AAD 216A, AAD 216B and AAD 216C and mixtures thereof, exhibit antibacterial activity. The invention includes within its scope pharmaceutical compositions containing at least one of the above-mentioned antibiotic compounds and a pharmaceutically acceptable carrier. The compositions may also contain other active antibacterial agents. The compositions may be made up in any pharmaceutical form appropriate for the route of administration in question. Such compositions are exemplified by solid compositions for oral administration, such as tablets, capsules, pills, powders and granules; liquid compositions for oral administration such as solutions, suspensions, syrups and elixers; and preparations for parenteral administration sch as sterile solutions, suspensions or emulsions.
For use as an antibacterial agent, the compositions are administered so that the concentration of the active ingredient is greater than the minimum inhibitory concentration for the particular organism treated.
The activity of the AAD 216 complex, and its components; AAD 216A, AAD 216B and AAD 216C was demonstrated in vitro against a total of 58 bovine mastitis isolates using the conventional agar dilution method to determine minimum inhibitory concentrations (MICs). The MICs for the AAD 216 complex, AAD 216A, AAD 216B and AAD 216C ranged from 0.25 to >128 .mu.g/ml, 0.13 to >128 .mu.g/ml, 0.06 to >28 .mu.g/ml and 0.06 to >128 .mu.g/ml respectively. In comparison, vancomycin has MICs for the same microorganisms ranging from 0.25 to >128 .mu.g/ml.
GROWTH PROMOTANT ACTIVITY
The growth promotant activities of the AAD 216 complex, and its components; AAD 216A, AAD 216B and AAD 216C were determined in a swine in vitro model to predict utility in monogastric animals, such as swine and poultry; a rumen in vitro model to predict utility in beef, dairy and sheep production and in vivo in a chick growth model.
Swine in vitro model
A Yorksire barrow is surgically prepared either with an ileal cannula, which is placed 15 cm. from the ileo-cecocolic junction, or a cecal cannula, which placed midway between the apex and origin of the cecum. The animal is fed 4 times daily to restrict intake to 4.5% of body weight in a 30 kg animal or 2.5% of body weight in a 100 kg animal. The swine grower ration is:
______________________________________ (% w/w) (lbs/ton)______________________________________Medium ground shelled corn 70.60 1412Soybean meal, 44% 22.00 440Dehydrated alfalfa meal, 17% 4.50 90Calcium propionate 0.15 3Vitamin/mineral premix 2.75 55______________________________________
Sampling of the material, via the cannula, begins 150-180 minutes following the first morning feeding and continues any time from 30-120 minutes thereafter, depending on the quantity of material needed. The sample is maintained in crushed ice, no cooler than 5.degree. C., and is gassed continuously with carbon dioxide. The collected material is filtered. The filtrate is the inoculum used for incubations of the test and control samples. The gassed inoculum, 2.25 ml, is placed in each of 10 gassed test tubes, each containing 0.75 ml of a nutrient solution and 0.5 mg of each test compound. Four blank control tubes, along with the test compound tubes, are incubated 5 hours at 37.degree. C. with agitation. Four more killed tubes are included which are not incubated.
The tubes are each treated with 0.60 ml of a 25% solution of metaphosphoric acid, then, stored at -4.degree. C. until analysis. Samples are thawed and centrifuged for 25 minutes at 20,000 r.p.m. The supernatant liquid is decanted, sampled for gas chromatography and automatic analysis. The results are fed into a computer for finishing to give figures in which the blank control value is 100%. Virginiamycin and vancomycin are used as positive controls.
______________________________________ VFA* LYS* GLU* LAC* (% (% (% (%Compound (ppm) Control) Control) Control) Control)______________________________________Virginiamycin(166.67) 93 163 197 81(16.67) 130 127 191 76(1.67) 248 82 182 70Vancomycin(166.67) 250 48 190 64(16.67) 280 42 189 59(1.67) 92 83 100 99AAD 216 Complex(666.67)** 267 44 189 58(166.67) 345 50 195 51(66.67) 390 53 188 46(16.67) 124 81 113 93(6.67) 90 101 96 100AAD 216A(166.67) 326 63 187 58(16.67) 379 50 191 47(1.67) 101 94 97 99AAD 216B(166.67) 290 50 190 56(16.67) 365 55 184 47(1.67) 102 98 97 98AAD 216C(166.67) 294 42 191 57(16.67) 398 53 188 45(1.67) 101 95 96 98______________________________________ *VFA refers to the total of volatile fatty acids, namely acetate, propionate, isobutyrate, butyrate, isovalerate and valerate. LYS is lysine, GLU is glucose and LAC is Llactic acid. **AAD 216 complex contains 25% of a mixture of AAD 216A, AAD 216B and AAD 216C.
Rumen in vitro model
The portocol for the rumen in vitro model is analogous to the protocol for the swine in vitro model with the following modifications:
(1) A 400 kg steer is surgically prepared with a rumen cannula.
(2) The animal is fed one time a day with the following ration:
______________________________________Finished Feed % w/w______________________________________Cottonseed hulls 44.0Cracked corn 22.0Alfalfa Hay 1" 20.0Pellet Supplement* 10.0Liquid Molasses 4.0 100.0______________________________________*Pellet Supplement % w/w______________________________________Soybean Oil Meal (50% protein) 50.0Medium Ground Corn 32.5D/Calcium Phosphate 6.50Plain salt 2.50Ground limestone (Thomasville) 3.50Urea 2.50Vitamin A & D.sub.2 Premix** 2.50 100.00______________________________________**Vitamin A & D.sub.2 Premix % w/w______________________________________Vitamin A (30,000 IU/gm) 5.87Vitamin D.sub.2 (16,000,000 IU/lb) 0.50Fine ground corn 93.63 100.00______________________________________
(3) Manipulation of VFA production is described as the production ratio of propionate as a percentage of total VFA produced.
(4) Sampling of the material, via the cannula, is at 120 minutes post feeding.
______________________________________ VFA* LYS* GLU* Propionate (% (% (% % (%Compound (ppm) Control) Control) Control) Control)______________________________________Vancomycin(50.0) 107 97 189 127(5.0) 108 85 165 130(0.5) 97 83 17 105Avoparcin(50.0) 113 97 141 132(5.0) 105 85 166 121(0.5) 103 96 116 106Monensin Sodium(50.0) 109 147 0 156(5.0) 104 141 126 149(0.5) 94 109 11 119AAD 216 Complex(200.0)** 118 116 78 159(50.0)** 117 101 11 159(20.0)** 115 95 193 130(2.0)** 101 92 60 102AAD 216A(50.0) 111 114 153 146(5.0) 93 90 28 135(0.5) 94 96 121 105AAD 216B(50.0) 111 124 20 148(5.0) 121 107 0 141(0.5) 100 103 45 103AAD 216C(50.0) 101 110 0 151(5.0) 111 96 45 136(0.5) 83 103 29 120______________________________________ *VFA refers to the total of volatile fatty acids, namely acetate, propionate, isobutyrate, butyrate, isovalerate and valerate. LYS is lysine, and GLU is glucose. **AAD 216 complex contains 25% of a mixture of AAD 216A, AAD 216B and AAD 216C.
The above-reported rumen in vitro data are detailed in the following table in which ETOH means ethanol, ACE means acetate, PRO means propionate, IBU means isobutyrate, BUT means butyrate, IvA means isovalerate and VAL means valerate and LAC, VFA, LYS and GLU are as defined above.
__________________________________________________________________________ % ETOH ACE PRO IBU BUT IVA VAL TOTAL PR UREA LYS AMO GLU DLAC LLACCompound (ppm) PERCENT OF CONTROL__________________________________________________________________________Vancomycin50.00 0 87 136 164 111 212 83 107 127 0 97 0 189 0 9995.00 0 93 141 137 98 99 90 108 130 0 85 0 165 0 430.50 0 95 103 115 96 82 95 97 105 0 83 0 17 0 0Avoparcin50.00 0 92 149 172 110 217 91 113 132 0 97 0 141 0 9995.00 0 90 127 136 107 119 96 105 121 0 85 0 166 0 930.50 0 96 109 99 107 114 107 103 106 0 96 0 116 0 10Monensin Sodium50.00 0 73 171 196 98 278 107 109 156 0 147 0 0 0 9995.00 0 74 154 221 93 265 99 104 149 0 141 0 126 0 1780.50 0 78 112 138 100 219 101 94 119 0 109 0 11 0 0AAD 216 Complex200.00 0 84 188 346 93 405 57 118 159 0 116 0 78 0 99950.00 0 91 186 132 90 107 64 117 159 0 101 0 11 0 18520.00 0 96 149 163 105 199 120 115 130 0 95 0 193 0 02.00 0 98 102 123 102 150 106 101 102 0 92 0 60 0 3AAD 216A50.00 0 86 162 177 98 241 58 111 146 0 114 0 153 0 9995.00 0 66 126 169 101 165 105 93 135 0 90 0 28 0 40.50 0 91 99 90 96 70 92 94 105 0 96 0 121 0 0AAD 216B50.00 0 87 164 175 96 224 53 111 148 0 124 0 20 0 9995.0 0 99 171 138 104 120 110 121 141 0 107 0 0 0 1860.50 0 98 102 95 100 83 94 100 103 0 103 0 45 0 0AAD 216C50.00 0 69 153 254 97 302 65 101 151 0 110 0 0 0 9995.00 0 88 151 156 105 158 118 111 136 0 96 0 45 0 1010.50 0 65 99 79 95 82 94 83 120 0 103 0 29 0 0__________________________________________________________________________
These data demonstrate that the AAD 216 antibiotics can increase propionate production in the rumen without significantly adversely affecting butyrate levels. This effect is seen at 20, 50 and 200 ppm of AAD 216 Complex and at 5 and 50 ppm of AAD 216A, B and C. Acetate levels appear to drop considerably at 0.5 and 50 ppm of AAD 216C and at 5 ppm of AAD 216B, but in the context of all results, these data show that acetate generally is not significantly reduced by an AAD 216 antibiotic.
A similar experiment was carried out using rumen fluid from dairy cows fed a typical dairy cow diet of two parts corn silage and three parts dairy concentrate. Specifically, strained rumen fluid (10 ml) was obtained, from an animal fed two hours earlier, via cannula and was mixed with 10 ml of a nutrient broth comprising a 2:3 mix of corn silage and dairy concentrate. After adding a selected growth promotant, the mixture was incubated at 39.degree. C. for about 23 hours, with oscillation.
__________________________________________________________________________ TO- % ETOH ACE PRO IBU BUT IVA VAL TAL PR NH--N LYS AMO GLU DLAC LLACCompound (ppm) PERCENT OF CONTROL__________________________________________________________________________AAD 216 Complex50.00 0 105 139 124 95 114 92 109 128 161 101 159 0 0 05.00 0 103 115 132 98 114 119 105 109 138 85 113 0 0 00.50 0 104 101 105 100 104 104 102 99 108 85 92 0 0 0Avoparcin50.00 0 108 137 116 88 104 99 107 128 148 88 123 0 0 05.00 0 94 112 146 91 115 103 99 113 122 92 107 0 0 00.50 0 100 102 122 100 101 97 1200 101 92 91 79 0 0 0Monensin Sodium50.00 0 76 159 55 59 45 58 86 185 84 120 274 0 0 05.00 0 102 145 91 71 75 81 99 146 105 95 238 0 0 00.50 0 100 122 104 94 114 105 104 117 137 96 115 0 0 0Saloinomycin50.00 0 76 168 61 63 46 60 89 188 82 114 268 0 0 05.00 0 99 148 108 66 75 83 98 152 116 117 226 0 0 00.50 0 95 124 153 83 110 94 99 126 136 119 117 0 0 0Lasalocid50.00 0 65 151 51 62 41 53 81 186 78 150 278 0 0 05.00 0 109 144 164 79 91 90 106 136 131 130 198 0 0 00.50 0 95 112 119 94 102 87 99 114 106 106 93 0 0 0__________________________________________________________________________
AAD 216 complex was also fed to 80 steers, weighing 400-500 pounds, in a mixture with a corn silage feed. Rumen fluid was obtained on Day 85 via a stomach tube, 3 to 8 hours after feeding. Upon collection, aliquots of strained rumen fluid were treated to stop fermentation.
______________________________________ ppm Control 15 30 60______________________________________Total VFA mmol/l 84.2 78.5 80.3 76.3Acetate (molar %) 58.0 56.5 56.7 54.9Propionate (molar %) 18.5 20.5 22.0 24.3Isobutyrate (molar %) 1.1 1.2 1.2 1.2Butyrate (molar %) 16.5 16.6 15.4 14.8Isovalerate (molar %) 3.1 2.7 2.1 2.0Valerate (molar %) 2.8 2.5 2.6 2.8______________________________________
In addition to increasing propionate (e.g at .circle.1 18% at 30 ppm) without significantly decreasing acetate and butyrate (e.g., 5% and 7%, respectively, at 30 ppm) the oral administration of AAD 216 also decreased isovalerate (e at .circle.1 32% at 30 ppm). Isovalerate is derived from microbial destruction of branched chain amino acids of dietary protein in the rumen. The decrease in rumen isovalerate indicates that dietary protein is being protected from rumen degradation. These data, combined with additional data showing that AAD 216 protects amino acids from rumen breakdown, indicate that milk protein levels, as well as fat-corrected milk yield, is improved by AAD 216. Such additional data include, for example, data from a rumen in vitro study in which rumen fluid from steers was incubated in nutrient media with AAD 216 complex; at 0.5 ppm, the alpha amino nitrogen (a marker for amino acids) disappearance after 23 hours was 97%; at 5 ppm, it was 64%; and at 50 ppm, it was 15%. To effect improvement in milk production, the AAD 216 complex, such as the enriched complex, or AAD 216 A, B or C is orally administered, such as in the feed, to a lactating ruminant in an effective, non-toxic amount, typicall about 10 to 1500 mg/head/day, preferably about 50 to 500 mg/head/day.
Chick Growth Study
One day old broiler chicks, selected for weight, health and sex, are housed in an environmentally controlled room with temperature at 80.degree. F. and humidity at 40%. Chicks are fed ad libitum. Water is offered ad libitum. A rye or corn basal ration is fed during the
1 and 2), then, mixed with the acclimation period (days compound under test or control conditions on days 3-17. Either 8 pens (64 chicks) or 16 pens (128 chicks) are used for each test or control group.
__________________________________________________________________________Basal Rye DietDiet Ingredients (% w/w) (lbs/ton)__________________________________________________________________________Ground Rye (fine grind) 54.4 1088Soybean Meal (49% protein) 27 540Meat & Bone meal (50% protein) 10 200Dehydrated Alfalfa meal 1.25 25Fat, animal 4 80Dried Whey (or lactose) 1 20Ground Limestone 0.67 13.4Dicalcium Phosphate 0.50 10Iodized salt 0.23 4.6Vitamin premix 0.175 *Trace mineral premix 0.25 5DL methionine (98%) 0.45 9Choline Chloride (50% aqueous sol.) 0.150** 3__________________________________________________________________________ *Vitamin premix will be mixed into diets when test chemicals are added. 87.5 g vitamin premix/49,912.5 g of basal rye diet. **Since choline is added as a 50% aqueous solution, percentage in diet is doubled.
Dose # of Weight Feed/Gain # of PPM Reps Day 10 Day 17 3-10 10-17 3-17 D.Cks__________________________________________________________________________ % of ControlVirginiamycin 10.0 8 103.8 116.0 97.4 83.6 90.4 2Virginiamycin 50.0 8 105.0 121.3 93.2 74.6 83.2 1AAD 216 Complex* 40.0 8 107.7 132.4 90.9 69.6 79.6 2AAD 216 Complex* 160.0 8 106.1 117.1 91.0 80.1 85.3 3 GRAMS GRAMS/GRAMControl 0.0 8 164.2 280.4 1.577 2.815 2.209 2RyeHistoric Control 169.1 298.4 1.566 2.563 2.080C.V. Among Pens - 3.71%__________________________________________________________________________ *AAD 216 complex contains 25% of a mixture of AAD 216A, AAD 216B and AAD 216C.
The feed compositions of this invention comprise the normal feed rations of the meat and milk producing animals supplemented by a quantity of an active ingredient selected from the group consisting af AAD 216 complex, AAD 216A, AAD 216B, AAD 216C or a mixture thereof which is effective for improving the growth rate and feed efficiency of the animals but which is not toxic or noxious to a degree that the animals will reduce ingestion of the ration. The quantity of the active ingredient will vary, as is known to the art, with factors such as the cost of the ingredient, the species and the size of animal, the relative activity of the compound of formula I or the type of feed ration used as the basal feed.
Representative feed rations for swine and poultry are as follows:
A swine ration for growing hogs of 40-100 pounds body weight is prepared using the following formula:
______________________________________Corn, ground 78.15%Soybean oil meal, 44% 17.0%Meat scraps, 50% 3.0%Oyster shell flavor 0.4%Bone meal 0.5%Zinc oxide 0.01%Vitamin A, B, B.sub.12 & D optionalsupplement______________________________________
A chinken ratio for broilers is prepared using the following formula:
______________________________________Yellow corn meal 67.35%Soybean oil meal 24.00%Menhaden fish meal 6.00%Steamed bone meal 1.00%Ground limestone 1.00%Iodized salt 0.34%25% choline chloride 0.13%Vitamin B.sub.12 0.10%Manganese sulfate 0.02%Vitamin mix 0.06%______________________________________
Swine feed from weanling to fattening or finishing rations may be supplemented. Swine eat from about 2 lb. of ration per day (for a 25 lb. pig) to 9 lb. per day (for a 150 lb. pig). Most rations are comprised of a corn base supplemented with legume silage, wheat bran, oats, barley, molasses or a protein supplement.
Poultry feeds comprise starter rations, broiler rations and laying rations. The rations are usually based on ground corn, corn meal or soybean meal. The broiler rations, often, contain high energy supplements such as added fats, proteins and vitamins. Turkey rations are similar, but comprise only a starting ration and a growing ration. Chickens or pheasants eat from 0.03-0.3 lbs. of feed per day, turkeys twice that much. Estimated intake of feed is dependent on the weight and age of the meat producing animal.
The active ingredients selected from the group consisting of AAD 216 complex, AAD 216A, AAD 216B, AAD 216C or a mixture thereof are mixed uniformly with such feed rations to give supplemented rations which are, then fed as to custom, which is, most often, ad libitum. Conveniently, to do this, a premix of the supplemental growth promotant of this invention, optionally combined with or without other supplements known to this art such as an anthelmintic, a nitrogen source or an antibiotic, for example, virginiamycin or oxytetracycline is prepared by the manufacturer for sale to the formulators or feed lot operators. The concentration of the active ingredients selected from the group consisting of AAD 216 complex, AAD 216A, AAD 216B, AAD 216C or a mixture thereof in the premix is usually from 5-75% by weight or a concentration 100-2000 times greater than that in the complete feed ration. The premix form may be liquid or solid. Premix vehicles are corn oil, cottonseed oil, molasses or distillers solubles to form a liquid premix preparation. Sucrose, lactose, corn meal, ground corn, flour, calcium carbonate or soybean meal are often used as bases for solid premix preparations. The premix composition is, then, mixed uniformly with whole ration which is fed to the target animal. Such premix compositions are included in the term "feed compositions" as used herein.
The concentration of the active ingredients selected from the group consisting of AAD 216 complex, AAD 21AA, AAD 216B, AAD 216C or a mixture thereof in the complete ration is a nontoxic but active quantity chosen, for example, from a range of about 1-1000 parts of active ingredient by weight per million parts of whole feed (ppm) or about 2-115 grams per ton. Advantageously, a nontoxic quantity of active ingredient is chosen from the range of 10-50 ppm.
The method of this invention comprises feeding to monogastric or ruminant, meat or milk producing animals, especially beef and dairy cattle, sheep, swine and poultry, an effective growth promoting but nontoxic quantity of an active ingredient selected from the group consisting of AAD 216 complex, AAD 216A, AAD 216B, AAD 216C or a mixture thereof. Other monogastric animals whose digestive tract also features fermentation in a cecum or cecum-like chamber are rabbits and horses.
The supplemented feed rations, described above, are presented to the animal by methods known to the art. Ad libitum feeding in the pasture, pen or growing shed is most convenient to increase the growth and milking rate of the animal and to increase the feed efficiency of the operation.
The following examples are illustrative of the production, isolation and purification of the antibiotics of the present invention and are not therefore to be considered in limiting the present invention as described in the claims appended hereto.
The nutrient media employed in the following examples have the compositions listed below. The yields for the fermentations were obtained by analytical HPLC by comparison to quantitated authentic samples.
Medium 13 (H) was used for the seed growth of SK&F-AAD 216 throughout the experiments. Ingredients of medium 13H are: starch, 15 g/l; sucrose, 5 g/l; dextrose, 5 g/l; HY-soy, 7.5 g/l; corn steep liquor, 5 g/l; K.sub.2 HPO.sub.4, 1.5 g/l; NaCl, 0.5 g/l; CaCO.sub.3, 1.5 g/l; and Mineral "S", 5 ml/l; pH to 7.0.
Mineral "S" has the following compositions: ZnSO.sub.4 7H.sub.2 O, 2.8 g/l; Fe(NH.sub.4).sub.2 HC.sub.6 H.sub.5 O.sub.7, 2.7 g/l; CuSO.sub.4.5H.sub.2 O, 0.125 g/l; MnSO.sub.4.H.sub.2 O, 1.0 g/l; CoCl.sub.2.6H.sub.2 O, 0.1 g/l; Na.sub.2 B.sub.4 O.sub.7.H.sub. O, 0.09 g/l; and Na.sub.2 MoO.sub.4.2H.sub.2 O, 0.05 g/l.
The ingredients of medium V-2 are: soybean flour, 15 g/l; beet molasses, 10 g/l; glucose, 10 g/l; Estrasan 4 (methyl oleate), 10 g/l; and NaCl, 0.3 g/l to a pH of 7.2.

EXAMPLE 1
First Seed Staqe
The entire growth of a slant of K. aridum was suspended in 10 ml of sterile water and aseptically innoculated into a 4l. aspirator bottle containing 500 ml of medium 13 H. After incubation on a rotatory shaker, 250 rpm, at 28.degree. C. for 3 days, the mature culture was then employed to innoculate the 14l. glass vessel fermentor of Example 2 to produce a second seed stage.
EXAMPLE 2
Second Seed Stage
A 14l. glass vessel fermentor (New Brunswick Model 19 with 10 1 of sterile medium 13H was aseptically inoculated with 500 ml of vegetative culture from Example 1. The vessel was operated according to the following schedule:
Agitation: 400 rpm from 0-72 hr.
Aeration: 0.4 v/v/m* from 0-72 hr.
Temp.: 28.degree. C.
*v/v/m-vol. of air per vol. of medium per minute
Five liters of the resultant vegetative culture was then employed to inoculate the 75l. fermentor of Example 3 to produce a third seed stage.
EXAMPLE 3
Third Seed Stage
A 75l. fermentator (Chemapec) was run in similar fashion to Example 2. Five liters of the vegetative culture from Example 2 was used to inoculate the 75l. fermentor containing 50l. of medium 13H. The fermentation apparatus was operated as follows:
Agitation: 250 rpm from 0-72 hr.
Aeration: 0.4 v/v/m from 0-72 hr.
Temp.: 28.degree. C.
Fifty liters of the resultant vegetative culture was then employed to inoculate the 750l. fermentor of Example 4 to produce the desired AAD 216 complex.
EXAMPLE 4
Production of AAD 216 Complex
A 750 l. fermentor (ABEC) was operated in a similar fashion to Example 3. Fifty liters of the vegetative culture of Example 3 was used to aseptically inoculate the 750 l. fermentor containing 600l. of medium V-2. The fermentor was operated as follows:
Agitation: 120 rpm from 0-168 hr.
Aeration 0.3 v/v/m from 0-168 hr.
Temp.: 26.degree. C.
The fermentation broth contained the AAD 216 complex which was composed of the individual factor antibiotics as follows:
AAD 216A=50 g/ml;
AAD 216B=60.8 g/ml; and
AAD 216C=43.5 g/ml.
EXAMPLE 5
Production of AAD 216 Complex
A 450l. fermentor (Chemapec) was operated in a similar fashion to Example 4. Thirty liters of vegetative culture (third seed stage) produced according to Example 3 was used to aseptically inoculate the 450 l. fermentor containing 300 l. of medium V-2. The fermentor was operated as follows:
Agitation: 120 rpm from 0-168 hr.
Aeration: 0.4-0.5 v/v/m
Temperature: 26.degree. C.
The fermentation broth contained the AAD 216 complex which was composed of the individual factor antibiotics as follows: AAD 216A=46.2 g/ml
AAD 216B=75 g/ml
AAD 216C=48 g/ml.
EXAMPLE 6
Isolation of AAD 216 Complex
Whole fermentation broth (600l.) from Example 4 was clarified by rotary drum filtration (Komline-Sanderson, Laboratory Scale Model) using filter aid (Hyflo Supercel, Johns-Manville Products Corp.) at existing broth pH (pH 7.7-8.2). The broth filtrate (420l.) was chilled to 4.degree. C. by batch treatment of 100 L. volumes in a vat placed in a cold bath (methanol/dry ice). The chilled broth filtrate was then precipitated by slow addition of concentrated hydrochloric acid, with mixing to pH 3.0. The resulting precipitate was recovered by rotary vacuum filtration using filter aid as previously described. The filter aid-product precipitate cake was extracted by mixing with deionized water (55l.) and adjusting to pH 7.0 for 10 minutes. The aqueous extract thus obtained was filtered through Whatman #4 filter paper to remove the filter aid. The filtrate so obtained was applied to two XAD-7 resin columns (8.5.times.110 cm.) at a flow rate of 0.5 vols./hr. After washing with 8 volumes of deionized water (pH 7.0) the desired AAD 216 complex was recovered by elution with aqueous methanol (50-100%). The methanolic eluate(s) containing the desired AAD 216 complex was concentrated by evaporation using a rising film evaporator at 35.degree. C. The resulting aqueous concentrate was freeze-dried on a Virtis shelf lyophilizer, yielding 85.1 g of AAD 216 complex.
This AAD 216 complex was chromatographed on Whatman Partisil.RTM. Prep 40 ODS-3 (1 kg) in a Jobin Yvon Chromatospac-Prep 100 (step gradient 15 to 33 percent acetonitrile-0.1 M pH 3.2 phosphate buffer) to yield an enriched AAD 216 complex which by analytical HPLC contained 1.88 g. of AAD 216A, 2.6 g. of AAD 216B and 2.8 g of AAD 216C.
EXAMPLE 7
Isolation of AAD 216A, AAD 216B and AAD 216C
A sample of an enriched AAD 216 complex isolated according to Example 6 (38 g. non-desalted) which by analytical HPLC contained 0.42 g. of AAD 216A, 1.39 g. of AAD 216B and 0.08 g. of AAD 216C, was dissolved in one liter 15% acetonitrile in 0.1 M pH 6 phosphate buffer and the pH adjusted to 6.3. This solution was loaded onto a Waters Prep 500.RTM. HPLC with a column of Whatman Partisil.RTM. 40 (ODS-3) (50 cm..times.4.8 cm) at a flow rate of 200 ml/minute. The column was then eluted using the following gradient:
(1) 20% aqueous acetonitrile and buffer solution until polar material (ultraviolet detector at 210 nm) was eluted;
(2) 24% acetonitrile buffer solution until AAD 216A was eluted;
(3) 26% acetonitrile buffer solution until AAD 216B was eluted;
(4) 28% acetonitrile buffer solution until AAD 216C was eluted; and
(5) 50% aqueous acetonitrile.
The appropriate fractions which were.eluted from the HPLC column were then desalted as described below to afford the pure individual antibiotics: AAD 216A, 0.25 g; AAD 216B, 1.05 g; and AAD 216C, 0.06 g.
The desalting procedure involved a pooling of the appropriate fractions from the HPLC and removal of the acetonitrile at reduced pressure. The resulting aqueous samples were loaded onto an XAD-7 resin column and eluted with deionized water until the conductivity of the outflow was less than 25 micro MHO. The column was then eluted with aqueous acetonitrile (40-60%) and the eluant lyophilized to afford the desired products.
EXAMPLE 8
Isolation of Enriched AAD 216 Complex
A 10 gram sample of AAD 216 complex isolated according to the XAD-7 protocol of Example 6 which contained 0.69 g AAD 216A, 0.23 g AAD 216B and 0.21 g. AAD 216C (HPLC analysis) was dissolved 17.5 percent acetonitrile and 0.1 M pH 6 phosphate buffer solution. The pH of the solution was adjusted to 6.3 and this solution was loaded onto a Waters Prep 500.RTM. high pressure liquid chromatograph equipped with a 50 cm.times.4.8 cm column packed with Whatman Partisil.RTM. Prep 40 (ODS-3). The column was eluted with 20 percent acetonitrile and buffer solution to remove polar material and then eluted with 28% acetonitrile buffer solution to obtain the enriched AAD 216 complex in the acetonitrile-buffer solution. The acetonitrile in the eluant was removed at reduced pressure and the resulting aqueous solution was loaded onto an XAD-7 resin column and washed with deionized water until the conductivity of the outflow was less than 25 micro MHO. The column was then eluted with aqueous acetonitrile (40-60%) and the eluant lyophilized to afford 2.05 g. enriched AAD 216 complex which contained 0.59 g AAD 216A, 0.20 g AAD 216B and 0.20 g AAD 216C.
EXAMPLE 9
Alternate Isolation Procedure
Alternately, the AAD 216 complex after XAD-7 purification was chromatographed utilizing the procedure in Example 7 to maximize recovery affording AAD 216A, AAD 216B and AAD 216C in relatively pure state.
The AAD 216A so obtained from four individual runs (containing 3.9 g., 2.6 g and 2.2 g of AAD 216A by analytical HPLC) was combined and rechromatographed on the same HPLC isocratically eluting with 22% acetonitrile and 0.1 M pH 6 phosphate buffer to afford, after desalting, 4.6 g of AAD 216A from a middle cut in a highly purified state. The other fractions were recycled for further purification.
The AAD 216B so obtained from the same individual runs (containing 2.5 g, 3.7 g, 3.7 g and 1.4 g by analytical HPLC) was combined and rechromatographed on the same HPLC isocratically eluting with 26% acetonitrile and 0.1 M pH 6 phosphate buffer to afford, after desalting 2.7 g of AAD 216B from a middle cut in a highly purified state. The other fractions were recycled for further purification.
EXAMPLE 10
ALTERNATE ISOLATION OF ENRICHED AAD 216 COMPLEX
AAD 216 complex isolated according to the protocol of Example 6 which contained approximately 720 mg of AAD 216A, AAD 216B and AAD 216C was dissolved in water (200 ml) and filtered. The filtrate was mixed with 70 ml of an affinity chromatography sorbent of Affi-Gel.RTM. 10 -D ala-D ala (633 mg D ala-D ala) in 0.02 M pH 7.0 sodium phosphate buffer [see Cuatrecasas et al., Biochemistry, Vol. 11, No. 12, pp 2291-2298 (1972) for general procedure] and gently stirred for 1/2 hour. The mixture was poured into a column and the aqueous phase eluted off. The column was washed with: 0.02 M pH 7.0 phosphate buffer (2.times.250 ml); 0.5 M NH.sub.4 OAc pH 7.8 (2.times.250 ml.); H.sub.2 0 (250 ml); 0.1 M pH 7.8 NH.sub.4 OAc (250 ml); H.sub.2 O (250 ml.); 40% aqueous acetonitrile (70 ml.); 40% aqueous acetonitrile (1400 ml); and 30% acetonitrile in 0.4 M NaHCO.sub.3 (2.times.250 ml). The 1400 ml -40% aqueous acetonitrile fraction was lyophilized to yield 607 mg of the enriched AAD 216 complex containing 224 mg AAD 216A, 133 mg AAD 216B and 158 mg AAD 216C.

Number	Name	Date
4430328	Scheifinger	Feb 1984
B14430328	Scheifinger	Nov 1986
4534969	Phillips	Aug 1985
4548974	Bowie et al.	Oct 1985

Antibiotics produced by Kibdelosporangium aridum Shearer gen. nov., sp. nov. ATCC 39323

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