Novel, highly specific N-demethylases enable bacteria to live on caffeine and related purine alkaloids.

The molecular basis for the ability of bacteria to live on caffeine as a sole carbon and nitrogen source is unknown. Pseudomonas putida CBB5, which grows on several purine alkaloids, metabolizes caffeine and related methylxanthines via sequential N-demethylation to xanthine. Metabolism of caffeine by CBB5 was previously attributed to one broad-specificity methylxanthine N-demethylase composed of two subunits, NdmA and NdmB. Here, we report that NdmA and NdmB are actually two independent Rieske nonheme iron monooxygenases with N(1)- and N(3)-specific N-demethylation activity, respectively. Activity for both enzymes is dependent on electron transfer from NADH via a redox-center-dense Rieske reductase, NdmD. NdmD itself is a novel protein with one Rieske [2Fe-2S] cluster, one plant-type [2Fe-2S] cluster, and one flavin mononucleotide (FMN) per enzyme. All ndm genes are located in a 13.2-kb genomic DNA fragment which also contained a formaldehyde dehydrogenase. ndmA, ndmB, and ndmD were cloned as His(6) fusion genes, expressed in Escherichia coli, and purified using a Ni-NTA column. NdmA-His(6) plus His(6)-NdmD catalyzed N(1)-demethylation of caffeine, theophylline, paraxanthine, and 1-methylxanthine to theobromine, 3-methylxanthine, 7-methylxanthine, and xanthine, respectively. NdmB-His(6) plus His(6)-NdmD catalyzed N(3)-demethylation of theobromine, 3-methylxanthine, caffeine, and theophylline to 7-methylxanthine, xanthine, paraxanthine, and 1-methylxanthine, respectively. One formaldehyde was produced from each methyl group removed. Activity of an N(7)-specific N-demethylase, NdmC, has been confirmed biochemically. This is the first report of bacterial N-demethylase genes that enable bacteria to live on caffeine. These genes represent a new class of Rieske oxygenases and have the potential to produce biofuels, animal feed, and pharmaceuticals from coffee and tea waste.

Role of hypoxia-inducible factors in epigenetic regulation via histone demethylases.

Eukaryotic chromatin is subject to multiple posttranslational histone modifications such as acetylation, methylation, phosphorylation, and ubiquitination. These various covalent modifications have been proposed to constitute a "histone code," playing important roles in the establishment of global chromatin environments, transcription, DNA repair, and DNA replication. Among these modifications, histone methylation specifies regulatory marks that delineate transcriptionally active and inactive chromatin. These histone methyl marks were considered irreversible; however, recent identification of site-specific histone demethylases demonstrates that histone methylation is dynamically regulated, which may allow cells to rapidly change chromatin conformation to adapt to environmental stresses or intrinsic stimuli. Of major interest is the observation that these histone demethylase enzymes, which are in the Jumonji gene family, require oxygen to function and, in some cases, are induced by hypoxia in an HIFalpha-dependent manner. This provides a new mechanism for regulation of the response to hypoxia.

Allele and genotype frequencies of cytochrome P450 2B6 gene in a Mongolian population.

CYP2B6 plays an important role in metabolizing various drugs in common clinical use. Increasing interest in CYP2B6 genetic polymorphism was stimulated by revelations of a specific CYP2B6 genotype significantly affecting the metabolism of efavirenz, an anti-HIV type-1 agent. The present study determined the CYP2B6 haplotype in 100 healthy unrelated Mongolian volunteers by analyzing the genotypes of nine single nucleotide polymorphism (SNP) positions (-82T>C, 64C>T, 499C>T, 516G>T, 777C>A, 785A>G, 983T>C, 1375A>G, and 1459C>T) in the CYP2B6 gene. The CYP2B6 *1 allele was the most frequent in the Mongolian population tested at 64.5%, higher than the equivalent frequency in African-Americans and Ghanaians. The second most frequent allele was CYP2B6 *6 (21.0%), although this allele was less frequent than that in Ghanaians. Only one CYP2B6 *5 allele was identified in our Mongolian subjects (0.5%), although it is the third most frequent allele in white and African-American populations. These CYP2B6 genotypes revealed seven slow efavirenz metabolizers in 100 Mongolians, which is significantly fewer than the same group among Ghanaians. Overall, the Mongolian CYP2B6 allele distribution was comparable with that in Japanese, Koreans, and Han Chinese. This is the first report of CYP2B6 genotype frequency in a Mongolian population, and it could provide clinically useful information on drug metabolism in this population group.

Erasing the methyl mark: histone demethylases at the center of cellular differentiation and disease.

The enzymes catalyzing lysine and arginine methylation of histones are essential for maintaining transcriptional programs and determining cell fate and identity. Until recently, histone methylation was regarded irreversible. However, within the last few years, several families of histone demethylases erasing methyl marks associated with gene repression or activation have been identified, underscoring the plasticity and dynamic nature of histone methylation. Recent discoveries have revealed that histone demethylases take part in large multiprotein complexes synergizing with histone deacetylases, histone methyltransferases, and nuclear receptors to control developmental and transcriptional programs. Here we review the emerging biochemical and biological functions of the histone demethylases and discuss their potential involvement in human diseases, including cancer.

The emerging functions of histone demethylases.

Epigenetic information refers to heritable changes in gene function that are stable between cell divisions but which is not a result of changes in the DNA sequence. Part of the epigenetic mechanism has been ascribed to modifications of histones or DNA that affects the transcription of specific genes. In this context, post-translational modifications of histone tails, in particular methylation of lysines, are regarded as important for the storage of epigenetic information. Regulation of this information plays an important role during cellular differentiation where cells with different characteristic features evolve from the same ancestor, despite identical genomic material. The characterization of several enzymes catalyzing histone lysine methylation have supported this concept by showing the requirement of these enzymes for normal development and their involvement in diseases such as cancer. The recent identification of proteins with histone demethylase activity has shown that the methylated mark is much more dynamic than previously anticipated, thereby potentially challenging the concept of histone-methylation in stable epigenetic programming.

The function and regulation of the JARID1 family of histone H3 lysine 4 demethylases: the Myc connection.

Epigenetic regulation of transcription refers to reversible, heritable changes in gene expression that occur in the absence of changes in DNA sequence. A major epigenetic mechanism involves the covalent modification of nucleosomal histones to create binding sites for transcriptional regulators and chromatin remodeling complexes that mediate activation or repression of transcription. While it has been known for a number of years that many histone modifications are reversible, it has only recently been shown that methyl groups are enzymatically removed from lysine residues. Here we discuss the recent characterization of a new class of demethylase enzyme, the JARID1 family, which catalyzes the removal of methyl groups from lysine 4 of histone H3. We summarize recent findings regarding the function of this family of proteins, focusing on our characterization of Little imaginal discs (Lid), the sole JARID1 family protein in Drosophila, which is rate-limiting for Myc-induced cell growth. Finally, we propose models to explain the role of Lid in Myc-mediated growth and discuss the relevance of these findings to human disease and tumor formation.

Identification of histone demethylases in Saccharomyces cerevisiae.

Based on the prediction that histone lysine demethylases may contain the JmjC domain, we examined the methylation patterns of five knock-out strains (ecm5Delta, gis1Delta, rph1Delta, jhd1Delta, and jhd2Delta (yjr119cDelta)) of Saccharomyces cerevisiae. Mass spectrometry (MS) analyses of histone H3 showed increased modifications in all mutants except ecm5Delta. High-resolution MS was used to unequivocally differentiate trimethylation from acetylation in various tryptic fragments. The relative abundance of specific fragments indicated that histones K36me3 and K4me3 accumulate in rph1Delta and jhd2Delta strains, respectively, whereas both histone K36me2 and K36me accumulate in gis1Delta and jhd1Delta strains. Analyses performed with strains overexpressing the JmjC proteins yielded changes in methylation patterns that were the reverse of those obtained in the complementary knock-out strains. In vitro enzymatic assays confirmed that the JmjC domain of Rph1 specifically demethylates K36me3 primarily and K36me2 secondarily. Overexpression of RPH1 generated a growth defect in response to UV irradiation. The demethylase activity of Rph1 is responsible for the phenotype. Collectively, in addition to Jhd1, our results identified three novel JmjC domain-containing histone demethylases and their sites of action in budding yeast S. cerevisiae. Furthermore, the methodology described here will be useful for identifying histone demethylases and their target sites in other organisms.

Histone demethylation by a family of JmjC domain-containing proteins.

Covalent modification of histones has an important role in regulating chromatin dynamics and transcription. Whereas most covalent histone modifications are reversible, until recently it was unknown whether methyl groups could be actively removed from histones. Using a biochemical assay coupled with chromatography, we have purified a novel JmjC domain-containing protein, JHDM1 (JmjC domain-containing histone demethylase 1), that specifically demethylates histone H3 at lysine 36 (H3-K36). In the presence of Fe(ii) and alpha-ketoglutarate, JHDM1 demethylates H3-methyl-K36 and generates formaldehyde and succinate. Overexpression of JHDM1 reduced the level of dimethyl-H3-K36 (H3K36me2) in vivo. The demethylase activity of the JmjC domain-containing proteins is conserved, as a JHDM1 homologue in Saccharomyces cerevisiae also has H3-K36 demethylase activity. Thus, we identify the JmjC domain as a novel demethylase signature motif and uncover a protein demethylation mechanism that is conserved from yeast to human.

Defining relationships between the known members of the cytochrome P450 3A subfamily, including five putative chimpanzee members.

An analysis of the cytochrome P450 3A subfamily (CYP3A) was undertaken in order to define relationships across species among subfamily members. Some members were excluded due to incomplete sequences, while others were held in abeyance because of their almost complete homology. This is the first publication of five chimpanzee CYP3A genes-CYP3A4, CYP3A5, CYP3A7, CYP3A43, and CYP3A67. This project utilized two approaches for characterizing possible relationships-phylogenetic analysis and genomic structure. For the phylogenetic analysis, both nucleotide and amino acid sequences were aligned in silico using the CLUSTAL algorithm, and then visually inspected for accuracy. Three different computer software packages were utilized: MEGA 2.1, TREECON 1.3b, and PHYLIP 3.5. Multiple methods were used: neighbor-joining (NJ), minimum evolution (ME), maximum parsimony (MP), and maximum likelihood (ML). The resulting topologies were compared against each other to define the consensus topology. In addition, the chimpanzee, human, mouse, and rat genome databases were searched for intron/exon information pertaining to the included genes. Both methods suggest the same conclusion, defining orthologs is plausible between similar species (i.e., mouse and rat), but is less useful between species of different orders (i.e., primate and rodent) or classes (i.e., mammal and avian).

Predominantly neuronal expression of cytochrome P450 isoforms CYP3A11 and CYP3A13 in mouse brain.

Despite the very small amounts of cytochrome P450 enzymes expressed in different areas and cell populations of the brain as compared with the liver, there is significant evidence for their specific involvement in brain development, function, and plasticity. Nevertheless, the current discussion about occurrence and importance of cerebral cytochrome P450 isoforms is determined by controversial interpretations of their function in general and with respect to single isoforms. Continuing a series of publications about brain P450 isoforms, we now present evidence for the expression of cytochrome P450 3A11 and 3A13 in mouse brain. Immunocytochemical and non-radioactive in situ hybridization studies revealed identical distribution of their proteins and mRNAs throughout the brain especially in neuronal populations, and to some extent in astrocytes. The cerebral expression of these P450 isoforms was confirmed by Western blot and RNAse protection assay analysis. The well-known testosterone-metabolizing capacity and the inducibility of cytochrome P450 3a isoforms by xenobiotics as well as their presence in steroid hormone-sensitive areas and neurons (e.g. hippocampus) clarify the significance of these isoforms for impairment of steroid hormone actions by P450-inducing environmental substances. Therefore, investigation of inducible cerebral P450 isoforms which are able to metabolize xenobiotics as well as steroid hormones might help us to understand neuroendocrine regulation of brain's plasticity.

Folate utilization by monomeric versus heterotetrameric sarcosine oxidases.

There are two types of bacterial sarcosine oxidases. The heterotetrameric enzymes contain subunits ranging in size from about 10 to 100 kDa, noncovalently bound FAD and NAD+, and covalently bound FMN attached to the beta subunit (42-45 kDa). Monomeric sarcosine oxidases are similar in size to the beta subunit in the heterotetramers and contain covalently bound FAD. Formaldehyde formation during sarcosine oxidation by several heterotetrameric sarcosine oxidases was suppressed in the presence of 50 microM [6S]-tetrahydrofolate, accompanied by a 25-50% increase in the rate of sarcosine oxidation. In contrast, [6S]-tetrahydrofolate caused only a modest decrease in the rate of formaldehyde production with monomeric sarcosine oxidases (approximately 25%), an effect which was virtually entirely attributable to an accompanying decrease in the rate of sarcosine oxidation. In the presence of 100 microM [6R,S]-tetrahydropteroyltriglutamate [H4Pte(Glu)3], the heterotetrameric enzymes catalyzed the formation of 5,10-methylenetetrahydropteroyltriglutamate [5,10-CH2-H4Pte(Glu)3] at a rate which was 35-60% faster than the rate of sarcosine oxidation in the absence of folate. An apparent Km value of 3.1 microM was estimated for [6S]-H4Pte(Glu)3 with the heterotetrameric corynebacterial sarcosine oxidase. In contrast, slow formation of 5,10-CH2-H4Pte(glu)3 was detected during sarcosine oxidation with monomeric sarcosine oxidases, attributable to the nonenzymatic reaction of free formaldehyde with H4Pte(Glu)3. The results show that only the heterotetrameric sarcosine oxidases can use tetrahydrofolates as substrates and, in this regard, they resemble mammalian sarcosine and dimethylglycine dehydrogenases.