Degradation of caffeine and related methylxanthines bySerratia marcescens isolated from soil under coffee cultivation

A strain of Serratia marcescens showing the ability to degrade caffeine and other methylxanthines was isolated from soil under coffee cultivation. Growth was observed only with xanthines methylated at the 7 position (caffeine, 1,3,7-dimethylxanthine; paraxanthine, 1,7-dimethylxanthine; theobromine, 3,7-dimethylxanthine and 7-methylxanthine). Paraxanthine and theobromine were released in liquid medium when caffeine was used as the sole source of carbon and nitrogen. When paraxanthine or theobromine were used, 3-methylxanthine, 7-methylxanthine, and xanthine were detected in the liquid medium. Serratia marcescens did not grow with theophylline (1,3-dimethylxanthine), 1-methylxanthine, and 3-methylxanthine, and poor growth was observed with xanthine. Methyluric acid formation from methylxanthines was tested in cell-free extracts by measuring dehydrogenase reduction of tetrazolium salt in native-polyacrylamide gel electrophoresis gel. Activity was observed for all methylxanthines, even those with which no bacterial growth was observed. Our results suggest that in this strain of S. marcescens caffeine is degraded to theobromine (3,7-dimethylxanthine) and/or paraxanthine (1,7-dimethylxanthine), and subsequently to 7-methylxanthine and xanthine. Methyluric acid formation could not be confirmed. Correspondence to: Paulo Mazzafera.     

Engineering a microbial platform for de novo biosynthesis of diverse methylxanthines

Engineered microbial biosynthesis of plant natural products can support manufacturing of complex bioactive molecules and enable discovery of non-naturally occurring derivatives. Purine alkaloids, including caffeine (coffee), theophylline (antiasthma drug), theobromine (chocolate), and other methylxanthines, play a significant role in pharmacology and food chemistry. Here, we engineered the eukaryotic microbial host Saccharomyces cerevisiae for the de novo biosynthesis of methylxanthines. We constructed a xanthine-to-xanthosine conversion pathway in native yeast central metabolism to increase endogenous purine flux for the production of 7-methylxanthine, a key intermediate in caffeine biosynthesis. Yeast strains were further engineered to produce caffeine through expression of several enzymes from the coffee plant. By expressing combinations of different N-methyltransferases, we were able to demonstrate re-direction of flux to an alternate pathway and develop strains that support the production of diverse methylxanthines. We achieved production of 270 μg/L, 61 μg/L, and 3700 μg/L of caffeine, theophylline, and 3-methylxanthine, respectively, in 0.3-L bench-scale batch fermentations. The constructed strains provide an early platform for de novo production of methylxanthines and with further development will advance the discovery and synthesis of xanthine derivatives.     

N-methyltransferases and 7-methyl-N9-nucleoside hydrolase activity in Coffea arabica and the biosynthesis of caffeine

The incorporation of radioactivity from L-[¹⁴CH₃]-methionine into caffeine by coffee fruits was enhanced by additions of theobromine and paraxanthine but was reduced by additions of theophylline and caffeine. Cell-free extracts prepared from seedlings, partially ripe and unripe coffee fruits showed that only the unripe green fruits contained significant methyltransferase and 7-methyl-N⁹-nucleoside hydrolase activity. The cell-free extracts catalysed the transfer of methyl groups fromS-adenosyl-L-[¹⁴CH₃]-methionine to 7-methylxanthine, and 7-methylxanthosine, producing theobromine and to theobromine producing caffeine. The two enzymic methylations exhibited a sharp pH max at 8.5 and a similar pattern of effects with metal chelators, thiol reagents and Mg²⁺ ions, which were slightly stimulating though not essential to enzyme activity. Paraxanthine (1,7-dimethylxanthine) was sh own to be the most active among methylxanthines as methyl acceptors; however its formation from 1-methylxanthine and 7-methylxanthine was not detectable, and biosynthesis from paraxanthine in the intact plant would therefore appear not to occur. The apparent K_m values are as follows: 7-methylxanthine 0.2 mM, theobromine 0.2 mM, paraxanthine 0.07 mM and S-adenosyl-L-methionine with each substrate 0.01 mM. The results suggest the pathway for caffeine biosynthesis in Coffea arabica is: 7-methylxanthosine → 7-methylxanthine → theobromine → caffeine.     

Genetic and Phytochemical Analysis to Evaluate the Diversity and Relationships of Mate (Ilex paraguariensis A.St.‐Hil.) Elite Genetic Resources in a Germplasm Collection

The aim of this study was to evaluate the phytochemical and genetic diversity, relationships and identification of mate (Ilex paraguariensis A.St .‐Hil .) elite genetic resources belonging to the Brazilian germplasm collection and mate breeding program. Mate has been studied due to the presence of phytochemical compounds, especially methylxanthines and phenolic compounds. The samples were collected from the leaves of 76 mate elite genetic resources (16 progenies × 5 localities). Total DNA was extracted from mate leaves and 20 random primers were used for DNA amplification. Methylxanthines (caffeine and theobromine) and phenolic compounds (chlorogenic, neochlorogenic, and criptochlorogenic acids) were quantified by HPLC. The genetic divergence estimated was higher within (92%) than among (8%) the different populations. Analysis of genetic distance between origins provided the formation of two groups by UPGMA cluster analysis, with higher polymorphism (94.9%). The average content of caffeine ranged from 0.01 to 1.38% and theobromine of 0.10 – 0.85% (w/w). The caffeoylquinic acids concentrations (1.43 – 5.38%) showed a gradient 3‐CQA > 5‐CQA > 4‐CQA. The coefficient of genetic variation (CVg) was of low magnitude for all mono‐caffeoylquinics acids. Significant correlations (positive and negative) were observed between the phytochemical compounds. Genetic diversity analysis performed by RAPD markers showed a greater intra‐populational diversity; genetic resources with low caffeine and higher theobromine content were identified and can be used in breeding programs; the correlation between methylxanthines and phenolic compounds can be used as a good predictor in future studies.     

Potentiating effects of methylxanthines on teratogenicity of mitomycin C in mice

A previous study demonstrated that caffeine strongly potentiated the teratogenic action of mitomycin C in mice. In the present study the effect of methylxanthines including caffeine, theophylline, theobromine (theobromine sodium salicylate), paraxanthine, and 1-methylxanthine was compared in order to analyze the structure-activity relationship. Jcl:ICR mice were injected IP with 3 mg/kg of mitomycin C, immediately followed by SC injection of each methylxanthine on day 11 of gestation. The doses of methylxanthines were calculated so that the mice received 50 mg/kg of caffeine or the equimolecular amount of the other methylxanthines. Fetuses were examined for external malformations on day 18 of gestation. Mitomycin C at 3 mg/kg and the methylxanthines at the doses used were not teratogenic. Combined administration of caffeine or theophylline with mitomycin C produced more than 80% of malformed fetuses. Although less effective than caffeine or theophylline, paraxanthine also significantly increased the incidence of malformed fetuses. Theobromine and 1-methylxanthine were virtually ineffective. From these findings, it is suggested that the methyl group at N-1 position of the xanthines is important for the enhancement but the N-1 methylation alone is ineffective unless accompanied with the substitution of the methyl moiety at the other position(s).     

Purine base pattern of camellia irrawadiensis

Theobromine and caffeine in the flush shoot leaves of hybrids of tea and other camellia plants were assayed by HPLC. In C. sinensis and C. taliensis of section Thea the caffeine content exceeded 2% and the theobromine content was below 0.2%. However, in C. irrawadiensis of the same section, the theobromine content was more than 0.5% while the caffeine content was below 0.02%. The theobromine content of tea hybrids was also below 0.2%. In sections other than Thea, C. sasanqua, C. japonica and C. vernalis did not contain detectable amounts of theobromine or caffeine.     

Biosynthesis of caffeine by tea-leaf extracts. Enzymic formation of theobromine from 7-methylxanthine and of caffeine from theobromine.

1. Extracts prepared from tea leaves with Polyclar AT (insoluble polyvinylpyrrolidine) contained two methyltransferase activities catalysing the transfer of methyl groups from S-adenosylmethionine to 7-methylxanthine, producing theobromine, and to theobromine, producing caffeine. 2. The methyltransferases exhibited the same pH optimum (8.4) and a similar pattern of effects by metal ions, thiol inhibitors and metal-chelating reagents, both for theobromine and caffeine synthesis. Mg2+, Mn2+ and Ca2+ slightly stimulated enzyme activity but they were not essential. Paraxanthine was shown to be most active among methylxanthines, as the methyl acceptor. However, the formation of paraxanthine from 1-methylxanthine was very low and that from 7-methylxanthine was nil, suggesting that the synthesis of caffeine from paraxanthine is of little importance in intact plants. Xanthine, xanthosine, XMP and hypoxanthine were all inactive as methyl acceptors, whereas [2(-14)C]xanthine and [8(-14)C]hypoxanthine were catabolized to allantoin and urea by tea-leaf extracts. The apparent Km values are as follows: 7-methylxanthine, 1.0 times 10(-14)M; theobromine, 1.0 times 10(-3)M; paraxanthine, 0.2 times 10(-3)M; S-adenosylmethionine, 0.25 times 10(-4)M (with each of the three substrates). 3. The results suggest that the pathway for caffeine biosynthesis is as follows: 7-methylxanthine leads to theobromine leads to caffeine. In contrast, it is suggested that theophylline is synthesized from 1-methylxanthine. The methyl groups of the purine ring of caffeine are all derived directly from the methyl group of S-adenosylmethionine. Little is known about the pathways leading to the formation of 7-methylxanthine. 4. A good correlation between caffeine synthesis and shoot formation or growth of tea seedlings was shown, suggesting that the methylating systems in caffeine synthesis are closely associated with purine nucleotide and nucleic acid metabolism in tea plants.     

Degradation Kinetics of Caffeine and Related Methylxanthines by Induced Cells of <Emphasis Type="Italic">Pseudomonas</Emphasis> sp.

In this study, the kinetics of degradation of caffeine and related methylxanthines by induced cells of Pseudomonas sp. was performed. The kinetics data showed that degradation of caffeine, theobromine, and 7-methylxanthine followed Michealis–Menten kinetics. The values of K _m are low for caffeine and 7-methylxanthine and high for theobromine. Degradation of caffeine and theobromine was enhanced in the presence of NADH and NADPH, whereas the degradation of 7-methylxanthine was unaffected. Among the various metal ions tested, Fe²⁺ was found to enhance the rate of degradation for all three substrates, whereas Zn²⁺ and Cu²⁺ inhibited the degradation of caffeine and theobromine but not 7-methylxanthine. The differences in kinetic parameters and cofactor requirement suggest the possibility of the involvement of more than one N-demethylases in the caffeine catabolic pathway in Pseudomonas sp. The induced cells can serve as effective biocatalysts for the development of biodecaffeination techniques.     

Theobromine Inhibits Uric Acid Crystallization. A Potential Application in the Treatment of Uric Acid Nephrolithiasis

Purpose

To assess the capacity of methylxanthines (caffeine, theophylline, theobromine and paraxanthine) to inhibit uric acid crystallization, and to evaluate their potential application in the treatment of uric acid nephrolithiasis.

Materials and Methods

The ability of methylxathines to inhibit uric acid nucleation was assayed turbidimetrically. Crystal morphology and its modification due to the effect of theobromine were evaluated by scanning electron microscopy (SEM). The ability of theobromine to inhibit uric acid crystal growth on calculi fragments resulting from extracorporeal shock wave lithotripsy (ESWL) was evaluated using a flow system.

Results

The turbidimetric assay showed that among the studied methylxanthines, theobromine could markedly inhibit uric acid nucleation. SEM images showed that the presence of theobromine resulted in thinner uric acid crystals. Furthermore, in a flow system theobromine blocked the regrowth of post-ESWL uric acid calculi fragments.

Conclusions

Theobromine, a natural dimethylxanthine present in high amounts in cocoa, acts as an inhibitor of nucleation and crystal growth of uric acid. Therefore, theobromine may be clinically useful in the treatment of uric acid nephrolithiasis.     

Diversity of Methylxanthine Content inIlex cassine L. andIlex vomitoria Ait.: Assessing Sources of the North American Stimulant Cassina

Indigenous people of southeastern North America drank cassina, a stimulant and emetic decoction that the colonial British termed “black drink.” Though most authors citeIlex vomitoria Ait. as the botanical source of cassina, confusion persists because some researchers identify the source asI. cassine L. To clarify the link between plant and product, the methylxanthine alkaloid contents ofI. vomitoria andI. cassine were compared. Since methylxanthines (i.e., caffeine, theobromine, and theophylline) have pharmacological properties congruent with the recorded effects of cassina consumption, the alkaloids provide a chemical basis for the evaluation of both taxa as sources of the beverage. Methylxanthine levels are higher inI. vomitoria than inI. cassine, and the principal alkaloid of the former is caffeine. Based on its alkaloid content,I. vomitoria is the best-supported candidate source of cassina.     

Two Distinct Pathways for Metabolism of Theophylline and Caffeine Are Coexpressed in Pseudomonas putida CBB5

Pseudomonas putida CBB5 was isolated from soil by enrichment on caffeine. This strain used not only caffeine, theobromine, paraxanthine, and 7-methylxanthine as sole carbon and nitrogen sources but also theophylline and 3-methylxanthine. Analyses of metabolites in spent media and resting cell suspensions confirmed that CBB5 initially N demethylated theophylline via a hitherto unreported pathway to 1- and 3-methylxanthines. NAD(P)H-dependent conversion of theophylline to 1- and 3-methylxanthines was also detected in the crude cell extracts of theophylline-grown CBB5. 1-Methylxanthine and 3-methylxanthine were subsequently N demethylated to xanthine. CBB5 also oxidized theophylline and 1- and 3-methylxanthines to 1,3-dimethyluric acid and 1- and 3-methyluric acids, respectively. However, these methyluric acids were not metabolized further. A broad-substrate-range xanthine-oxidizing enzyme was responsible for the formation of these methyluric acids. In contrast, CBB5 metabolized caffeine to theobromine (major metabolite) and paraxanthine (minor metabolite). These dimethylxanthines were further N demethylated to xanthine via 7-methylxanthine. Theobromine-, paraxanthine-, and 7-methylxanthine-grown cells also metabolized all of the methylxanthines mentioned above via the same pathway. Thus, the theophylline and caffeine N-demethylation pathways converged at xanthine via different methylxanthine intermediates. Xanthine was eventually oxidized to uric acid. Enzymes involved in theophylline and caffeine degradation were coexpressed when CBB5 was grown on theophylline or on caffeine or its metabolites. However, 3-methylxanthine-grown CBB5 cells did not metabolize caffeine, whereas theophylline was metabolized at much reduced levels to only methyluric acids. To our knowledge, this is the first report of theophylline N demethylation and coexpression of distinct pathways for caffeine and theophylline degradation in bacteria.Caffeine (1,3,7-trimethylxanthine) and related methylxanthines are widely distributed in many plant species. Caffeine is also a major human dietary ingredient that can be found in common beverages and food products, such as coffee, tea, and chocolates. In pharmaceuticals, caffeine is used generally as a cardiac, neurological, and respiratory stimulant, as well as a diuretic (3). Hence, caffeine and related methylxanthines enter soil and water easily through decomposed plant materials and other means, such as effluents from coffee- and tea-processing facilities. Therefore, it is not surprising that microorganisms capable of degrading caffeine have been isolated from various natural environments, with or without enrichment procedures (3, 10). Bacteria use oxidative and N-demethylating pathways for catabolism of caffeine. Oxidation of caffeine by a Rhodococcus sp.-Klebsiella sp. mixed-culture consortium at the C-8 position to form 1,3,7-trimethyluric acid (TMU) has been reported (8). An 85-kDa, flavin-containing caffeine oxidase was purified from this consortium (9). Also, Mohapatra et al. (12) purified a 65-kDa caffeine oxidase from Alcaligenes sp. strain CF8. Cells of a caffeine-degrading Pseudomonas putida strain (ATCC 700097) isolated from domestic wastewater (13) showed a fourfold increase in a cytochrome P450 absorption spectrum signal compared to cells grown on glucose. Recently, we reported a novel non-NAD(P)⁺-dependent heterotrimeric caffeine dehydrogenase from Pseudomonas sp. strain CBB1 (20). This enzyme oxidized caffeine to TMU stoichiometrically and hydrolytically, without producing hydrogen peroxide. Further metabolism of TMU has not been elucidated.Several caffeine-degrading bacteria metabolize caffeine via the N-demethylating pathway and produce theobromine (3,7-dimethylxanthine) or paraxanthine (1,7-dimethylxanthine) as the initial product. Theophylline (1,3-dimethylxanthine) has not been reported to be a metabolite in bacterial degradation of caffeine. Subsequent N demethylation of theobromine or paraxanthine to xanthine is via 7-methyxanthine. Xanthine is further oxidized to uric acid by xanthine dehydrogenase/oxidase (3, 10). Although the identities of metabolites and the sequence of metabolite formation for caffeine N demethylation are well established, there is very little information on the number and nature of N-demethylases involved in this pathway.The lack of adequate information on the metabolism and enzymology of theophylline, caffeine, and related methylxanthines prompted us to investigate the degradation of these compounds in detail. We isolated a unique caffeine-degrading bacterium, P. putida CBB5, from soil via enrichment with caffeine as the sole source of carbon and nitrogen. Here we describe a detailed study of the metabolism of theophylline, caffeine, and related di- and monomethylxanthines by CBB5. Our results indicate that CBB5 initially N demethylated caffeine to produce theobromine (major product) and paraxanthine (minor product) before the pathways converged to 7-methylxanthine and xanthine. Surprisingly, CBB5 was also capable of utilizing theophylline as a sole carbon and nitrogen source. CBB5 N demethylated theophylline to 1-methylxanthine and 3-methylxanthine, which were further N demethylated to xanthine. Theophylline N-demethylase activity was detected in cell extracts prepared from theophylline-grown CBB5 cells. 1-Methylxanthine and 3-methylxanthine were detected as products of this NAD(P)H-dependent reaction. To our knowledge, this is the first report of a theophylline degradation pathway in bacteria and coexpression of distinct caffeine and theophylline degradation pathways.     

INHIBITION OF 5''-NUCLEOTIDASE IN RAT BRAIN BY METHYLXANTHINES

—Rat brain 5′-nucleotidase (EC 3.1.3.5) is inhibited by methylxanthines such as theophylline. Inhibition of the 5′-nucleotidase by theophylline appears more efficient than the inhibition of cAMP phosphodiesterase by this drug. A similar inhibition is observed with caffeine, theobromine, 7′-methyl-xanthine and 1-methylxanthine.     

Metabolic Relations between Methylxanthines and Methyluric Acids in Coffea L

Metabolism of purine alkaloids in the leaves of Coffea dewevrei De Wild et Durand var excelsa Chev, Coffea liberica Bull ex Hiern and Coffea abeokutae Cramer was studied by analyzing leaf discs collected during vegetative development and by feeding the following radioactive tracers: [¹⁴C]theobromine, [¹⁴C]caffeine, and [¹⁴C]theacrine (1,3,7,9-tetramethyluric acid). Their principal metabolites were quantitatively and qualitatively determined. All three species convert the precursors to the same radioactive products, and proceed through the same four maturity stages characterized by the alkaloid accumulation pattern and by a particular transformation potency: (stage 1) young plant accumulating caffeine, transforms theobromine to caffeine; (stage 2) caffeine is gradually replaced by theacrine, theobromine and caffeine are converted to theacrine; (stage 3) theacrine disappears whereas liberine (O(2), 1,9-thrimethyluric acid) accumulates, theacrine is metabolized to liberine; (stage 4) branched-out plant containing liberine but no theacrine, caffeine is converted rapidly to liberine via theacrine. Methylliberine (O(2),1,7,9-tetramethyluric acid), presumably the direct precursor of liberine, is occasionally found in low concentrations at stage 3 and 4.

The collective term `liberio-excelsoid' introduced by geneticists for the numerous races or species of Pachycoffea is in accordance with the phytochemical equality found in this work.

     

Coadministration of methylxanthines and inhibitor compounds potentiates teratogenicity in Xenopus embryos

Inhibitors of DNA synthesis (hydroxyurea and cytosine arabinoside), protein synthesis (cycloheximide and emetine), and nucleic acid synthesis (5-fluorouracil) were administered with each of three methylxanthines (caffeine, theophylline, and theobromine) to determine if teratogenic effects could be potentiated in Xenopus laevis embryos. The animals were exposed for 96 hours to methylxanthine and inhibitor concentrations that, alone, produced low percentages of malformations. Coadministration of caffeine or theophylline with each inhibitor greatly increased the incidence of malformed embryos. Similar potentiation was induced when theobromine and the protein synthesis inhibitors were tested. A lesser potentiative response was produced when theobromine and the nucleic acid synthesis inhibitor were administered together. Teratogenic potentiation did not occur when theobromine was administered in conjunction with the DNA synthesis inhibitors. Growth reduction in the treatments proved to be the most sensitive indicator of the potentiative effects. This study had two significant findings: the teratogenicity of the protein synthesis inhibitors was greatly increased upon coadministration with each methylxanthine, even though they are typically not very teratogenic by themselves, and coadministration of the DNA synthesis inhibitors with theobromine did not result in teratogenic potentiation. Additionally, this study serves as one method of validating the frog embryo teratogenesis assay-Xenopus (FETAX), since the results obtained concur with results from similar mammalian studies.     

Theobromine, theophylline, and caffeine in 42 samples and products of Guaraná (Paullinia cupana, Sapindaceae)

Guaranás, the carbonated beverages (sodas) of choice throughout much of Brazil, are mandated by Brazilian law to contain at least 300 mg guara’a (Paullinia cupana, Sapindaceae) seed per 100 ml soda. Were all the soda manufacturers adhering to the law, they would be consuming almost three times the annual production of seed. Guaraná seeds contain unusually high levels of caffeine, along with smaller amounts of the related purine alkaloids theobromine and theophylline. We investigated the purine alkaloid content of three ethnobotanical guaraná collections and 39 commercial products using HPLC/UV. Many of the products did contain caffeine as the major alkaloid, with traces of theobromine and theophylline. Numerous sodas and syrups contained up to ten times more theobromine than caffeine, and we suspect that these products were adulterated with cacao (Theobroma cacao, Sterculiaceae), the major source of theobromine.     

Caffeine biosynthesis and adenine metabolism in transgenic Coffea canephora plants with reduced expression of N-methyltransferase genes

In anti-sense and RNA interference transgenic plants of Coffea canephora in which the expression of CaMXMT1 was suppressed, caffeine biosynthesis from [8-(14)C]adenine was investigated, together with the overall metabolism of [8-(14)C]adenine. Compared with wild type control plants, total purine alkaloid biosynthesis from adenine and conversion of theobromine to caffeine were both reduced in the transgenic plants. As found previously, [8-(14)C]adenine was metabolised to salvage products (nucleotides and RNA), to degradation products (ureides and CO(2)) and to purine alkaloids (theobromine and caffeine). In the transgenic plants, metabolism of [8-(14)C]adenine shifted from purine alkaloid synthesis to purine catabolism or salvage for nucleotides. HPLC analysis revealed a significantly reduced caffeine content in the transgenic plants. A small quantity (less than 20 nmol g(-1) fresh weight) of xanthosine had accumulated in at least one of the transgenic plants.     

Principaux effets neurotropes et psychotropes des méthylxanthines (caféine, théophylline, théobromine, paraxanthine)

Caffeine, the main alkaloid in coffee, corresponds to the 1-3-7 trimethylxanthine. Its concentration is lower in tea and chocolate, where it is associated with theophylline, 1-3 dimethylxanthine, in tea and with theobromine, 3-7 dimethylxanthine, in chocolate. Paraxanthine, 1-7dimethylxanthine, for its part, is produced by the hepatic metabolism of caffeine operated by a cytochrome of 1A2 type. The effects of these methylxanthines on awaking, anxiety, neuroprotection in Alzheimer’s and Parkinson’s diseases, mood, schizophrenia and nociception are briefly considered. This review is concluded by indicating that these effects of methylxanthines may be modified by various associated substances, such as polyphenols displaying antioxydant properties.     

Catabolism of caffeine and related purine alkaloids in leaves ofCoffea arabica L.

In a study of purine alkaloid catabolism pathways in coffee,¹⁴C-labelled theobromine, caffeine, theophylline and xanthine were incubated with leaves ofCoffea arabica. Incorporation of label into¹⁴CO₂ was determined and methanol-soluble metabolites were analysed by high-performance liquid chromatography-radiocounting. The data obtained demonstrate catabolism of caffeine theophylline 3-methylxanthine xanthine. Xanthine is degraded further by the conventional purine catabolism pathway to CO₂ and NH₃ via uric acid, allantoin and allantoic acid. The conversion of caffeine to theophylline is the rate-limiting step in purine alkaloid catabolism and provides a ready explanation for the high concentration of endogenous caffeine found inC. arabica leaves. Although theobromine is converted primarily to caffeine, a small portion of the theobromine pool appears to be degraded to xanthine by a caffeine-independent pathway. In addition to being broken down to CO₂, via the purine catabolism pathway, xanthine is metabolised to 7-methylxanthine. Metabolism of [2-¹⁴C]xanthine byC. arabica leaves in the presence of 5 mM allopurinol results in very large increases in incorporation of radioactivity into 7-methylxanthine as degradation of the substrate via the purine catabolism pathway is blocked. The identity of 7-methylxanthine in these studies was confirmed by gas chromatography-mass spectrometry analysis.Abbreviations HPLC-RC high-performance liquid chromatography-radiocounting This work was supported by the British Council which provided H.A. with Japan-UK travel grants. F.M.G. was supported by a Biotechnology and Biological Sciences Research Council grant to A.C.     

Inhibitory effects of methylxanthines on the activity of xanthine oxidase

The $\text{in vitro}$ and $\text{in vivo}$ effects of three methylxanthines caffeine, theophylline and theobromine on the activity of the enzyme xanthine oxidase (EC 1.2.3.2.) was investigated with a view to understand their biochemical action. The studies revealed all the three methylxanthines to be inhibitors of the milk xanthine oxidase activity and the inhibition was found to be competitive in nature. The preincubation studies indicated a greater inhibition of the enzyme with the methylxanthines. Excessive amount of the substrate (2.5 × 10^?4M) resulted in progressive inhibition of the enzyme activity. Low concentrations of methylxanthines exerted a definite inhibitory effect on the xanthine oxidase activity at lower substrate concentrations. At higher concentrations of the substrate, the inhibitory effect due to the same concentration of methylxanthines did not produce any added inhibition of the enzyme activity to that produced by the substrate alone. However, added inhibition by high concentrations of methylxanthines was detectable even when the enzyme activity was markedly inhibited by higher concentrations of the substrate. The $\text{in vivo}$ administration of methylxanthines caused a significant inhibition of the xanthine oxidase activity in lungs, kidneys, heart and brain of rats. Consequently, the level of uric acid in the tissues of the drug treated animals was also found to be reduced.