Metabolism of 1-, 3-, and 6-nitrobenzo[a]pyrene by intestinal microflora

Effects of gut microflora on pharmacokinetics of hesperidin: a study on non-antibiotic and pseudo-germ-free rats

Hesperidin is a biologically active flavanone glycoside occurring abundantly in citrus fruits. In the present study, effects of intestinal microflora on pharmacokinetics of hesperidin were investigated using a pseudo-germ-free rat model treated with antibiotics. After administration of hesperidin to rats, hesperetin, hesperetin glucuronides, and metabolites postulated to be eriodictyol, hemoeriodictyol, and their glucuronides were detected in urine while hesperetin glucuronide was predominantly found in plasma. The plasma concentration-time profile of hesperetin was compared between non-antibiotic-exposed and pseudo-germ-free rats administered this compound. The maximal concentration (C(max)) values of hesperetin in non-antibiotic-exposed and pseudo-germ-free rats were 0.58 and 0.20 μg/ml, respectively, and area under the curve (AUC) values were 6.3 and 2.8 μg-h/ml, respectively. Thus, systemic exposure as evidenced by AUC and C(max) was significantly higher in normal compared to pseudo-germ-free rats. Fecal β-glucosidase activities of non-antibiotic-exposed and pseudo-germ-free rats were 0.21 and 0.11 nmol/min/mg, while fecal α-rhamnosidase activities were 0.37 and 0.12 nmol/min/mg, respectively. The rate of hesperidin transformation to hesperetin was 6.9 and 2.9 nmol/min/g in fecal samples in non-antibiotic-exposed and pseudo-germ-free rats, respectively. Taken together, these results showed that pharmacokinetic differences between non-antibiotic-exposed and pseudo-germ-free rats may be attributed to differing hesperidin uptake, as well as alterations in metabolic activities of intestinal flora.

Distribution of nitroreductive activity toward nilutamide in rat

Nilutamide is a pneumotoxic and hepatotoxic nitroaromatic (R-NO2) antiandrogen used in the treatment of prostate carcinoma in man. Previously, we established that in the rat lung, the drug is metabolized into the corresponding hydroxylamine (R-NHOH) and amine (R-NH2) derivatives. These results evidenced a cytosolic oxygen-sensitive (type II) nitroreductase activity in lung. In the present studies, we extended the characterization of nilutamide metabolism in liver, brain, kidney, heart, blood, intestine (small, cecum, and large, and their respective luminal contents) of male Sprague-Dawley rats. Subcellular fractions for all tissues (except blood) examined (postmitochondrial, cytosolic, and microsomal) were prepared by differential ultracentrifugation. Blood and intestinal contents were sonicated before investigation. Incubations were run in the presence or absence of O2 to assess type I and II nitroreductase activities. Organic extracts were analyzed by HPLC methods and results were expressed as pmoles of R-NH2 formed per milligram protein per minute. Four distinct nitroreductive activities were evidenced. Cytosolic and microsomal type II nitroreductase activities were detected in all tissue samples studied. Type I NR activity was not observed in any of the cytosols, but was detected in the small intestine, lung, kidney, and liver microsomes. Nilutamide was also reduced in the intestinal lumen, possibly by a bacterial type I nitroreductase. Highest activities were observed in cytosols and were oxygen sensitive. These results evidence and characterize previously unknown nitroreductive activities toward nilutamide in rat tissues that might provide some explanation to the side effects of nilutamide and other nitroaromatic compounds observed in human therapeutics.

Metabolism of the plant toxins nitropropionic acid and nitropropanol by ruminal microorganisms

The nitro toxins 3-nitro-1-propionic acid (NPA) and 3-nitro-1-propanol (NPOH), which are found in many leguminous plants, are known to be detoxified by ruminal microorganisms. The rates of the detoxification reactions are critical to acquisition of tolerance to the plants by ruminant animals, but further information is needed about factors which influence reaction rates and about the nature of the detoxification reactions. We found that rates of disappearance of NPA and NPOH varied somewhat between samples of ruminal fluid but were usually about 0.4 and 0.1 mumol/ml of ruminal fluid per h, respectively, and that rates with threefold-concentrated cells from rumen fluid were correspondingly higher. We present evidence that ruminal microbes from both cattle and sheep reduce these nitro groups in situ, so that NPA is converted to bet-alanine and NPOH is converted to 3-amino-1-propanol. These products were identified by thin-layer chromatography and, as their dabsyl derivatives, separated by high-performance liquid chromatography. The product beta-alanine was itself metabolized by these mixed suspensions of rumen microbes, so its recovery was always less than what would be estimated from NPA loss, but as much as 87% of the NPOH lost from incubation mixtures was recovered as 3-amino-1-propanol. Addition of sulfide and ferrous ions to suspensions of ruminal microbes increased the rate of NPOH reduction about threefold, but rates of NPA reduction were not similarly increased. When incubations were under hydrogen gas instead of carbon dioxide, the addition of sulfide and ferrous ions led to even greater (five- to eightfold) increases in the rates of NPOH metabolism.(ABSTRACT TRUNCATED AT 250 WORDS)

Molecular Rearrangement of Longifolene by Arthrobacter ilicis T 2

Arthrobacter ilicis T 2 brings about a unique type of cometabolic structural rearrangement of longifolene, a sesquiterpene, resulting in the formation of an acid. Infrared, nuclear magnetic resonance, mass spectrometry, and decoupling studies indicate that the acid product has a sativenelike structure, which is confirmed by conversion of the acid to its methyl ester and hydrocarbon.

The reduction of azo dyes by the intestinal microflora

Azo dyes are widely used in the textile, printing, paper manufacturing, pharmaceutical, and food industries and also in research laboratories. When these compounds either inadvertently or by design enter the body through ingestion, they are metabolized to aromatic amines by intestinal microorganisms. Reductive enzymes in the liver can also catalyze the reductive cleavage of the azo linkage to produce aromatic amines. However, evidence indicates that the intestinal microbial azoreductase may be more important than the liver enzymes in azo reduction. In this article, we examine the significance of the capacity of intestinal bacteria to reduce azo dyes and the conditions of azo reduction. Many azo dyes, such as Acid Yellow, Amaranth, Azodisalicylate, Chicago Sky Blue, Congo Red, Direct Black 38, Direct Blue 6, Direct Blue 15, Direct Brown 95, Fast Yellow, Lithol Red, Methyl Orange, Methyl Red, Methyl Yellow, Naphthalene Fast Orange 2G, Neoprontosil, New Coccine, Orange II, Phenylazo-2-naphthol, Ponceau 3R, Ponceau SX, Red 2G, Red 10B, Salicylazosulphapyridine, Sunset Yellow, Tartrazine, and Trypan Blue, are included in this article. A wide variety of anaerobic bacteria isolated from caecal or fecal contents from experimental animals and humans have the ability to cleave the azo linkage(s) to produce aromatic amines. Azoreductase(s) catalyze these reactions and have been found to be oxygen sensitive and to require flavins for optimal activity. The azoreductase activity in a variety of intestinal preparations was affected by various dietary factors such as cellulose, proteins, fibers, antibiotics, or supplementation with live cultures of lactobacilli.

Inhibition of dinitropyrene mutagenicity in vitro and in vivo using Salmonella typhimurium and the intrasanguinous host-mediated assay

Dinitropyrenes (DNP), present in polluted air, are potent direct-acting mutagens in Salmonella typhimurium TA98. This mutagenicity is markedly reduced in the presence of rat-liver S9 or microsomes. This has now been confirmed using mouse hepatic fractions. Since most in vitro test systems do not adequately simulate conditions encountered in the intact animal, we have investigated dinitropyrene mutagenicity to Salmonella in the host-mediated assay. 1,8-Dinitropyrene (1,8-DNP) given p.o. to BALB/c mice induced a weak mutagenic effect in S. typhimurium TA98 recovered from the liver 1 h after i.v. administration (optimum time). Over the entire dose range tested no toxicity to bacterial cells was detected. Mutation induction in vivo was dose-related with maximum response at 1 mg DNP/kg body weight. This optimum dose, however, was non-mutagenic to strains TA98/1,8-DNP6 (O-transacetylase-deficient) or TA98NR/1,8-DNP6 (nitroreductase- and O-transacetylase-deficient). 1,3-Dinitropyrene and 1,6-dinitropyrene were weakly mutagenic to TA98 at doses similar to 1,8-DNP. Studies with [14C]1,8-DNP showed that 1 h after oral dosing (1 mg/kg), over 100 ng of 1,8-DNP equivalents were present in the liver (= 0.73% dose). However, only about 5.5 ng were present in the bacterial pellet, suggesting that hepatic components in vivo, as in vitro, bind to DNP, thus interfering with its interaction with Salmonella.