Survival of Escherichia coli O157:H7 in private drinking water wells: influences of protozoan grazing and elevated copper concentrations

The rdm genes B, C and E from Streptomyces purpurascens encode enzymes that tailor aklavinone and aclacinomycins. We report that in addition to hydroxylation of aklavinone to epsilon-rhodomycinone, RdmE (aklavinone-11-hydroxylase) hydroxylated 11-deoxy-beta-rhodomycinone to beta-rhodomycinone both in vivo and in vitro. 15-Demethoxyaklavinone and decarbomethoxyaklavinone did not serve as substrates. RdmC (aclacinomycin methyl esterase) converted aclacinomycin T (AcmT) to 15-demethoxyaclacinomycin T, which was in turn converted to 10-decarbomethoxyaclacinomycin T and then to rhodomycin B by RdmB (aclacinomycin-10-hydroxylase). RdmC and RdmB were most active on AcmT, the one-sugar derivative, with their activity decreasing by 70-90% on two- and three-sugar aclacinomycins. Aclacinomycin A competitively inhibited the AcmT modifications at C-10. The results presented here suggest that in vivo the modifications at C-10 take place principally after addition of the first sugar.     

Nucleotide sequences and expression of genes from Streptomyces purpurascens that cause the production of new anthracyclines in Streptomyces galilaeus.

Six open reading frames, rdmA to rdmF, in a 6,077-bp segment of Streptomyces purpurascens DNA which caused the production of hybrid anthracyclines were identified. The minimal fragment that produced anthracyclines modified at the 10th position contained rdmB to rdmD; rdmE is the gene for aklavinone-11-hydroxylase. RdmC is similar to a putative open reading frame in the daunorubicin biosynthetic cluster of Streptomyces peucetius and is likely to participate in the removal of the side chain at the 10th position.     

Crystal structure of aclacinomycin methylesterase with bound product analogues: implications for anthracycline recognition and mechanism

Aclacinomycin methylesterase (RdmC) is one of the tailoring enzymes that modify the aklavinone skeleton in the biosynthesis of anthracyclines in Streptomyces species. The crystal structures of this enzyme from Streptomyces purpurascens in complex with the product analogues 10-decarboxymethylaclacinomycin T and 10-decarboxymethylaclacinomycin A were determined to nominal resolutions of 1.45 and 1.95 A, respectively. RdmC is built up of two domains. The larger alpha/beta domain shows the common alpha/beta hydrolase fold, whereas the smaller domain is alpha-helical. The active site and substrate binding pocket are located at the interface between the two domains. Decarboxymethylaclacinomycin T and decarboxymethylaclacinomycin A bind close to the catalytic triad (Ser102-His276-Asp248) in a hydrophobic pocket, with the sugar moieties located at the surface of the enzyme. The binding of the ligands is dominated by hydrophobic interactions, and specificity appears to be controlled mainly by the shape of the binding pocket rather than through specific hydrogen bonds. Mechanistic key features consistent with the structure of complexes of RdmC with product analogues are Ser102 acting as nucleophile and transition state stabilization by an oxyanion hole formed by the backbone amides of residues Gly32 and Met103.     

链霉菌AC-57及其产生的阿克拉霉素A的研究

During the course of screening for new antitumor antibiotics, a new anthracycline antibiotic--aclacinomycin A was separated from the broth and mycelium of Streptomyces AC-57. The strain AC-57 was isolated from the soil collected in the Shanghai suburbs. According to its culture and physiological characteristics the producer was identified as Str. galilaeus AC-57. The broth and mycelium were extracted and treated with solvents as usual way. The aclacinomycin A was separated by silica-gel column chromatography eluted with chrolo-form-methanol. Aclacinomycin A, its aglycone and sugar components were identified by comparison of their physico-chemical and spectral data (MS, UV, IR, 1H-NMR, and 13C-NMR) with authentic compound, purified from the market sample.     

Crystal structure of aclacinomycin-10-hydroxylase, a S-adenosyl-L-methionine-dependent methyltransferase homolog involved in anthracycline biosynthesis in Streptomyces purpurascens

Anthracyclines are aromatic polyketide antibiotics, and several of these compounds are widely used as anti-tumor drugs in chemotherapy. Aclacinomycin-10-hydroxylase (RdmB) is one of the tailoring enzymes that modify the polyketide backbone in the biosynthesis of these metabolites. RdmB, a S-adenosyl-L-methionine-dependent methyltransferase homolog, catalyses the hydroxylation of 15-demethoxy-epsilon-rhodomycin to beta-rhodomycin, one step in rhodomycin biosynthesis in Streptomyces purpurascens. The crystal structure of RdmB, determined by multiwavelength anomalous diffraction to 2.1A resolution, reveals that the enzyme subunit has a fold similar to methyltransferases and binds S-adenosyl-L-methionine. The N-terminal domain, which consists almost exclusively of alpha-helices, is involved in dimerization. The C-terminal domain contains a typical alpha/beta nucleotide-binding fold, which binds S-adenosyl-L-methionine, and several of the residues interacting with the cofactor are conserved in O-methyltransferases. Adjacent to the S-adenosyl-L-methionine molecule there is a large cleft extending to the enzyme surface of sufficient size to bind the substrate. Analysis of the putative substrate-binding pocket suggests that there is no enzymatic group in proximity of the substrate 15-demethoxy-epsilon-rhodomycin, which could assist in proton abstraction and thus facilitate methyl transfer. The lack of a suitably positioned catalytic base might thus be one of the features responsible for the inability of the enzyme to act as a methyltransferase.     

Purification and characterization of a novel extracellular Streptomyces lividans 66 enzyme inactivating fusidic acid.

The wild-type strain Streptomyces lividans 66 is resistant against the steroid-like antibiotic fusidic acid. Comparative studies of the wild-type strain and a fusidic acid-sensitive mutant allowed the identification of an extracellular enzyme which inactivates fusidic acid. With the help of a combination of ultrafiltration and chromatographies with Phenyl-Sepharose and an anion exchanger, the enzyme was highly purified. Its apparent molecular mass is 48 kDa, its optimal activity ranges between 45 and 55 degrees C, and its optimal pH is 6.0 to 9.0. It is stimulated by neither monovalent nor divalent ions. The enzyme acts as a specific esterase which removes the acetyl group at C-16 from fusidic acid. The resulting intermediate is unstable, and spontaneous lactonization between C-21 and C-16 occurs rapidly.     

Metabolic conversion of aclacinomycins B and Y to A by pH shift during fermentation with Streptomyces lavendofoliae DKRS

Summary Aclacinomycin A, an antitumour antibiotic, was produced by fermentation with Streptomyces lavvendofoliae DKRS. Aclacinomycin A analogue compounds, such as aclacinomycins B and Y which are less effective as antitumour agents, were also produced in significant amounts. These analogue compounds could be converted to aclacinomycin A by incubation with the washed cell preparation as previously reported with S. galilaeus(Hoshino, T., Sekine, Y., Fujiwara, A. (1983) J.Antibiot. 36, 1458–1462). It was also found that the analogue compounds could be metabolically converted to aclacinomycin A by changing the pH of the culture broth at a later stage of fermentation. This metabolic conversion is expected to lead to additional benefits in the purification of aclacinomycin A as well as its increased production.     

Characterization of aklavinone-11-hydroxylase from Streptomyces purpurascens

Aklavinone-11-hydroxylase (RdmE) is a FAD monooxygenase participating in the biosynthesis of daunorubicin, doxorubicin and rhodomycins. The rdmE gene encodes an enzyme of 535 amino acids. The sequence of the Streptomyces purpurascens enzyme is similar to other Streptomyces aromatic polyketide hydroxylases. We overexpressed the gene in Streptomyces lividans and purified aklavinone-11-hydroxylase to apparent homogeneity with four chromatographic steps utilizing a kinetic photometric enzyme assay. The enzyme is active as the monomer with a molecular mass of 60 kDa; it hydroxylates aklavinone and other anthracyclinones. Aklavinone-11-hydroxylase can use both NADH and NADPH as coenzyme but it is slowly inactivated in the presence of NADH. The apparent Km for NADPH is 2 mM and for aklavinone 10 microM. The enzyme is inactivated in the presence of phenylglyoxal and 2,3-butanedione. NADPH protects against inactivation of aklavinone-11-hydroxylase by phenylglyoxal.     

Heterologous expression and secretion of a Streptomyces scabies esterase in Streptomyces lividans and Escherichia coli.

The esterase gene from Streptomyces scabies FL1 was cloned and expressed in Streptomyces lividans on plasmids pIJ486 and pIJ702. In S. lividans, the esterase gene was expressed during later stages of growth and was regulated by zinc, as is seen with S. scabies. The 36-kDa secreted form of the esterase was purified from S. lividans. N-terminal amino acid sequencing indicated that the processing site utilized in S. lividans for the removal of the signal sequence was the same as that recognized for processing in S. scabies. Western blots (immunoblots) revealed the presence of a 40-kDa precursor form of the esterase in cytoplasmic extracts. A 23-amino-acid deletion was introduced into the putative signal sequence for the esterase. When this deleted form of the esterase was expressed in S. lividans, a cytoplasmic 38-kDa precursor protein was produced but no secreted esterase was detected, suggesting the importance of the deleted sequence for efficient processing and secretion. The esterase gene was also cloned into the pUC119 plasmid in Escherichia coli. By using the lac promoter sequence, the esterase gene was expressed, and the majority of the esterase was localized to the periplasmic space.     

A two-protein component 7 alpha-cephem-methoxylase encoded by two genes of the cephamycin C cluster converts cephalosporin C to 7-methoxycephalosporin C.

Two genes, cmcI and cmcJ, corresponding to open reading frames 7 and 8 (ORF7 and ORF8) of the cephamycin C cluster of Nocardia lactamdurans encode enzymes that convert cephalosporin C to 7-methoxycephalosporin C. Proteins P7 and P8 (the products of ORF7 and ORF8 expressed in Streptomyces lividans) introduce the methoxyl group at C-7 of the cephem nucleus. Efficient hydroxylation at C-7 and transfer of the methyl group from S-adenosylmethionine require both proteins P7 and P8, although P7 alone shows weak C-7 hydroxylase activity and strong cephalosporin-dependent NADH oxidase activity. Both P7 and P8 appear to be synthesized in a coordinated form by translational coupling of cmcI and cmcJ. Protein P7 contains domains that correspond to conserved sequences in cholesterol 7 alpha-monooxygenases and to the active center of O-methyltransferases by comparison with the crystal structure of catechol-O-methyltransferase. Protein P8 may act as a coupling protein for efficient hydroxylation at C-7 in a form similar to that of the two-component system of Pseudomonas putida p-hydroxyphenylacetate-3-hydroxylase.     

Aclacinomycin 10-hydroxylase is a novel substrate-assisted hydroxylase requiring S-adenosyl-L-methionine as cofactor

Aclacinomycin 10-hydroxylase is a methyltransferase homologue that catalyzes a S-adenosyl-L-methionine (AdoMet)-dependent hydroxylation of the C-10 carbon atom of 15-demethoxy-epsilon-rhodomycin, a step in the biosynthesis of the polyketide antibiotic beta-rhodomycin. S-Adenosyl-L-homocysteine is an inhibitor of the enzyme, whereas the AdoMet analogue sinefungin can act as cofactor, indicating that a positive charge is required for catalysis. 18O2 experiments show that the hydroxyl group is derived from molecular oxygen. The reaction further requires thiol reagents such as glutathione or dithiothreitol. Incubation of the enzyme with substrate in the absence of reductant leads to the accumulation of an intermediate with a molecular mass consistent with a perhydroxy compound. This intermediate is turned into product upon addition of glutathione. The crystal structure of an abortive enzyme-AdoMet product ternary complex reveals large conformational changes consisting of a domain rotation leading to active site closure upon binding of the anthracycline ligand. The data suggest a mechanism where decarboxylation of the substrate results in the formation of a carbanion intermediate, which is stabilized by resonance through the aromatic ring system of the anthracycline substrate. The delocalization of the electrons is facilitated by the positive charge of the cofactor AdoMet. The activation of oxygen and formation of a hydroxyperoxide intermediate occurs in a manner similar to that observed in flavoenzymes. Aclacinomycin-10-hydroxylase is the first example of a AdoMet-dependent hydroxylation reaction, a novel function for this cofactor. The enzyme lacks methyltransferase activity due to the positioning of the AdoMet methyl group unfavorable for a SN2-type methyl transfer to the substrate.     

Cloning and characterization of Streptomyces galilaeus aclacinomycins polyketide synthase (PKS) cluster

We have cloned and sequenced polyketide synthase (PKS) genes from the aclacinomycin producer Streptomyces galilaeus ATCC 31,615. The sequenced 13.5-kb region contained 13 complete genes. Their organization as well as their protein sequences showed high similarity to those of other type II PKS genes. The continuous region included the genes for the minimal PKS, consisting of ketosynthase I (aknB), ketosynthase II (aknC), and acyl carrier protein (aknD). These were followed by the daunomycin dpsC and dpsD homologues (aknE2 and F, respectively), which are rare in type II PKS clusters. They are associated with the unusual starter unit, propionate, used in the biosynthesis of aklavinone, a common precursor of aclacinomycin and daunomycin. Accordingly, when aclacinomycins minimal PKS genes were substituted for those of nogalamycin in the plasmid carrying genes for auramycinone biosynthesis, aklavinone was produced in the heterologous hosts. In addition to the minimal PKS, the cloned region included the PKS genes for polyketide ketoreductase (aknA), aromatase (aknE1) and oxygenase (aknX), as well as genes putatively encoding an aklanonic acid methyl transferase (aknG) and an aklanonic acid methyl ester cyclase (aknH) for post-polyketide steps were found. Moreover, the region carried genes for an activator (aknI), a glycosyl transferase (aknK) and an epimerase (aknL) taking part in deoxysugar biosynthesis.     

Identification of catalytically important amino acid residues of Streptomyces lividans acetylxylan esterase A from carbohydrate esterase family 4

Multiple sequence alignment of Streptomyces lividans acetylxylan esterase A and other carbohydrate esterase family 4 enzymes revealed the following conserved amino acid residues: Asp-12, Asp-13, His-62, His-66, Asp-130, and His-155. These amino acids were mutated in order to investigate a functional role of these residues in catalysis. Replacement of the conserved histidine residues by alanine caused significant reduction of enzymatic activity. Maintenance of ionizable carboxylic group in side chains of amino acids at positions 12, 13, and 130 seems to be necessary for catalytic efficiency. The absence of conserved serine excludes a possibility that the enzyme is a serine esterase, in contrast to acetylxylan esterases of carbohydrate esterase families 1, 5, and 7. On the contrary, total conservation of Asp-12, Asp-13, Asp-130, and His-155 along with dramatic decrease in enzyme activity of mutants of either of these residues lead us to a suggestion that acetylxylan esterase A from Streptomyces lividans and, by inference, other members of carbohydrate esterase family 4 are aspartic deacetylases. We propose that one component of the aspartate dyad/triad functions as a catalytic nucleophile and the other one(s) as a catalytic acid/base. The ester/amide bond cleavage would proceed via a double displacement mechanism through covalently linked acetyl-enzyme intermediate of mixed anhydride type.     

Clinical studies on aclacinomycin A cardiotoxicity in adult patients with acute non lymphoblastic leukaemia

Nine patients with acute non lymphoblastic leukaemia (ANLL) were treated with Aclacinomycin in the doses of 20 mg/m2/day x 7 days in 30' lasting intravenous infusion and Cytosin arabinosid 100 mg/m2/day x 7 days in continuous infusion as well as control group consisted of 30 healthy people were examined by means of 24 hrs Holter ECG monitoring and ultrasonocardiography (UCG) to evaluate the influence of Aclacinomycin A (Aclaplastin - Behring) on cardiac rhythm and function. The UCG and Holter examinations were performed before Aclacinomycin and after 7-10 days from the beginning of the therapy. There were no statistical differences between the results of UCG examination in Aclacinomycin-treated group before the therapy and the control group. A slight nonsignificant decrease in left ventricular stroke volume and ejection fraction were observed after Aclacinomycin. Cardiac index decreased after the therapy (p less than 0.05) but was of normal value. The only true significant (p less than 0.001) decrease was observed in the contractility of cardiac fibres but the cardiac failure was not observed. No alterations in left ventricular posterior wall and intraventricular septum thickness were found. The effusion to pericardium was observed in 2 pts in the initial study and in 1 of them also after the therapy. The obtained results supported the clinical observations that Aclacinomycin A is promising agent for the treatment of ANLL because of its low cardiotoxicity.     

Characterization of the Streptomyces clavuligerus argC gene encoding N-acetylglutamyl-phosphate reductase: expression in Streptomyces lividans and effect on clavulanic acid production.

The argC gene of Streptomyces clavuligerus encoding N-acetylglutamyl-phosphate reductase (AGPR) has been cloned by complementation of argC mutants Streptomyces lividans 1674 and Escherichia coli XC33. The gene is contained in an open reading frame of 1,023 nucleotides which encodes a protein of 340 amino acids with a deduced molecular mass of 35,224 Da. The argC gene is linked to argE, as shown by complementation of argE mutants of E. coli. Expression of argC from cloned DNA fragments carrying the gene leads to high levels of AGPR in wild-type S. lividans and in the argC mutant S. lividans 1674. Formation of AGPR is repressed by addition of arginine to the culture medium. The protein encoded by the argC gene is very similar to the AGPRs of Streptomyces coelicolor, Bacillus subtilis, and E. coli and, to a lesser degree, to the homologous enzymes of Saccharomyces cerevisiae and Anabaena spp. A conserved PGCYPT domain present in all the AGPR sequences suggests that this may be the active center of the protein. Transformation of S. clavuligerus 328, an argC auxotroph deficient in clavulanic acid biosynthesis, with plasmid pULML30, carrying the cloned argC gene, restored both prototrophy and antibiotic production.     

The aromatization of (7 -3H) androstenedione by human placental mitochondria

A metabolite of 2,3-dihydroxyestra-1,3,5(10)-trien-17-one-6, 7-³H isolated from rat bile, was partially characterized by mass spectrometry as a methyl ether of 2,3,16-trihydroxyestra-1,3,5(10)-trien-17-one. The α configuration of the 16-hydroxy function was established by chromatographic comparison of the sodium borohydride reduced metabolite with synthetic 2-methoxy-estra-1, 3,5(10)-triene-3,16α,17β-triol and 2-methoxy-estra-1, 3,5(10)-triene-3,16β,17β-triol. The methyl group was located on the C-2 position by comparison with authentic 2- and 3- monomethyl ethers of 2,3-dihydroxy-estra-1, 3,5(10)-trien-17-one following pyrolytic removal of the 16α-hydroxyl group.3,16α-dihydroxy-2-methoxyestra-1,3,5(10)-trien-17-one was found to constitute 2% and 15% of the biliary radioactivity following administration of estrone-6,7-³H and 2,3-dihydroxyestra-1,3,5(10)-trien-17-one-6,7-³H respectively.     

Biosynthesis of anthraquinones by interspecies cloning of actinorhodin biosynthesis genes in streptomycetes: clarification of actinorhodin gene functions.

Streptomyces galilaeus ATCC 31133 and ATCC 31671, producers of the anthracyclines aclacinomycin A and 2-hydroxyaklavinone, respectively, formed an anthraquinone, aloesaponarin II, when they were transformed with DNA from Streptomyces coelicolor containing four genetic loci, actI, actIII, actIV, and actVII, encoding early reactions in the actinorhodin biosynthesis pathway. Subcloning experiments indicated that a 2.8-kilobase-pair XhoI fragment containing only the actI and actVII loci was necessary for aloesaponarin II biosynthesis by S. galilaeus ATCC 31133. Aloesaponarin II was synthesized via the condensation of 8 acetyl coenzyme A equivalents, followed by a decarboxylation reaction as demonstrated by [1,2-13C2]acetate feeding experiments. S. coelicolor B22 and B159, actVI blocked mutants, also formed aloesaponarin II as an apparent shunt product. Mutants of S. coelicolor blocked in several other steps in actinorhodin biosynthesis did not synthesize aloesaponarin II or other detectable anthraquinones. When S. galilaeus ATCC 31671 was transformed with the DNA carrying the actI, actIII, and actVII loci, the recombinant strain produced both aloesaponarin II and aklavinone, suggesting that the actinorhodin biosynthesis DNA encoded a function able to deoxygenate 2-hydroxyaklavinone to aklavinone. When S. galilaeus ATCC 31671 was transformed with a plasmid carrying only the intact actIII gene (pANT45), aklavinone was formed exclusively. These experiments indicate a function for the actIII gene, which is the reduction of the keto group at C-9 from the carboxy terminus of the assembled polyketide to the corresponding secondary alcohol. In the presence of the actIII gene, anthraquinones or anthracyclines formed as a result of dehydration and aromatization lack an oxygen function on the carbon on which the keto reductase operated. When S. galilaeus ATCC 31671 was transformed with the DNA carrying the actI, actVII, and actIV loci, the recombinant strain produced two novel anthraquinones, desoxyerythrolaccin, the 3-hydroxy analog of aloesaponarin II, and 1-O-methyldesoxyerythrolaccin. The results obtained in these experiments together with earlier data suggest a pathway for the biosynthesis of actinorhodin and related compounds by S. coelicolor.     

Comparative effects of fagaronine,Adriamycin and aclacinomycin on K562 cell sensitivity to natural-killer-mediated lysis

Little is known about membrane target antigens for natural killer (NK) cells. Transferrin receptor and CD15 antigen might be two of these target structures. A novel antileukemic alkaloid, fagaronine, is able to induce hemoglobin synthesis in the K562 cell line. Numerous reports suggest relations between the expression of natural killer target structures and the differentiation stage of malignant cells. Effects of fagaronine on the expression of glycophorin A, transferrin receptor and CD15 antigen and susceptibility to NK-mediated lysis have been investigated in K562 cells and compared to those of two anthracyclines (Adriamycin and aclacinomycin A) known to be erythroid-differentiation inducers. When comparing the balance of differentiating effect and toxicity, the dose and time-dependent effects of the drugs, fagaronine and aclacinomycin, are equivalent on K562 cells. In experimental conditions where fagaronine (3500 nM), Adriamycin (40 nM) and aclacinomycin (15 nM) recruit the same percentage of hemoglobin-containing cells (40%-50%), glycophorin A expression increases and transferrin receptor expression decreases. Only Adriamycin treatment decreases CD15 antigen expression. In addition, Adriamycin and aclacinomycin, but not fagaronine, induce resistance to NK-mediated lysis. These data suggest that (a) it is unlikely that CD15 antigen and transferrin receptor, separately considered, can be unique target structures for NK cells; and (b) fagaronine is a potent erythroid inducer which, in our system, has similar effects to aclacinomycin without induced resistance to NK attack.     

Methylation of 23S ribosomal RNA due to carB, an antibiotic-resistance determinant from the carbomycin producer, Streptomyces thermotolerans.

A resistance gene, carB, originally isolated from the carbomycin-producing organism, Streptomyces thermotolerans, confers on Streptomyces lividans high-level resistance to the drug. However, ribosomes from S. lividans expressing carB show only moderate resistance to this macrolide in vitro, although they are highly resistant to the action of lincosamide antibiotics. The carB product monomethylates the amino group of the adenosine residue located at position 2058 in 23S ribosomal RNA. In contrast, ribosomes from S. lividans expressing ermE, in which 23S RNA is dimethylated at this same position, are much more highly resistant to macrolides and insensitive to lincosamides.